Announcing the <br>GHC DevOps Group

Manuel M T Chakravarty

As Haskell is increasingly used in production environments, the Haskell toolchain is of critical importance to a growing number of people and organisations. At the heart of this toolchain is GHC (The Glasgow Haskell Compiler). Conceived nearly thirty years ago as a research project by Simon Peyton Jones, GHC has long existed at the intersection of research and commercial use, due to the increasing popularity of Haskell. To provide stability and a basic level of support, the project was generously supported by Microsoft Research for many years. However, as more and more companies and others are using GHC in mission-critical ways, the bar is going up. We need a solid, reliable, well-engineered, predictable GHC toolchain; and we need to achieve that without compromising GHC innovation and vitality.

Shared responsibility

In response to this situation, GHC HQ and several stakeholder organisations decided to work together to improve the situation and to provide shared leadership and a broader pool of resources for the DevOps aspects of GHC development. As a concrete first step in this new partnership, we announced the formation of the GHC DevOps Group at the 2017 Haskell Implementors’ Workshop in Oxford.

Our mission

As set out in the group’s charter, the mission of the GHC DevOps Group is threefold:

• to take leadership of the DevOps aspects of GHC,
• to resource it better, and
• to broaden the sense of community ownership and control of GHC.

As important as the goals are the group’s non-goals. The GHC DevOps group is exclusively concerned with the processes and tools for code development, community contributions, and regular, reliable & well-tested releases. It is about how and when features get into GHC and are shipped to users. In contrast, it is not concerned with the choice of which features go into GHC, let alone the content of the libraries it ships with. This is the responsibility of the GHC Steering Committee and proposals process and the Core Libraries Committee, respectively.

Our current goals

During its formation, the group identified two initial goals:

1. moving to two calendar-based GHC releases per year, and
2. lowering the barrier to contributing to GHC.

Quality calendar-based releases every six months

As Ben Gamari documented in detail in his Reflections on GHC’s release schedule, actual GHC release dates are hard to predict and initial release quality is often low due to critical bugs. These are the typical symptoms that modern DevOps processes, such as continuous and automated integration, testing, and delivery, are designed to eliminate. Hence, we are working towards reliable continuous building and testing of GHC as well as pre-merge commit testing. Automating everything leads to the entire set of release artefacts being built and provided during that same process.

The main choice that we are currently facing is whether to build our own solution and maintain our own infrastructure based on Jenkins or whether to use 3rd party services, such as CircleCI and AppVeyor, instead. Jenkins provides more flexibility (especially with respect to the supported architectures and operating systems), but at the expense of greater development and maintenance costs — that is, developer time that could otherwise be invested in improving GHC itself. In principle, the use of CircleCI and AppVeyor minimises the work needed to set up and maintain the infrastructure, but at the cost of being dependent on those 3rd parties, including their choice of directly supported architectures and operating systems.

Other key requirements involve security and the ability for anyone that forks GHC to also trivially fork and then modify the build infrastructure at will. For a summary of the requirements as well as the pros and cons of the two alternative approaches, have a look at the CI Trac Wiki page.

Lowering the barrier to entry

Although only a limited number of developers will feel confident in, say, extending GHC’s type checker, there are many parts of the compiler and associated tools and libraries that are well within reach of any competent Haskell developer. Hence, we feel that —just like other prominent open-source projects— we should make it as easy as possible to build, modify, and contribute to GHC. For better or worse, today, the gold standard for source control and processing code contributions is GitHub — if only, because virtually every professional developer, especially if engaged in open source work, is already familiar with it.

In contrast, GHC currently requires contributors to use the Phabricator tool. This is not only unfamiliar to most, but also requires the local installation of the command line tool Arcanist. In addition, Phabricator requires maintaining our own Phabricator installation and is known to be cumbersome to integrate with CI tool chains (tying this in with the first goal).

Lowering the barrier to entry involves other changes too of course (e.g., documentation structure). But to start with, what we are discussing is an attempt at encouraging more contributions while simultaneously lowering our set up and maintenance costs. This may well involve moving from Phabricator to GitHub.

Transparency and contributions

If you are interested in the details of the discussion, please have a look at the ghc-dev-ops@haskell.org archives. To provide transparency to the wider GHC user and developer community, all discussions of the GHC DevOps Group will be recorded on that mailing list.

Please let us know what you think. Feel free to approach any member of the GHC DevOps Group with feedback or suggestions. For a broader discussion, you may want to follow up on the general ghc-devs mailing list.

All this requires resources: time and money. To make this work, we will need significant contributions from companies that get value from GHC (which is itself free). But in exchange we get something valuable: a GHC ecosystem that we can rely on. If you think your company could help, in cash or kind, please get in touch.

October 19, 2017 12:00 AM

Advice for Haskell beginners

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This post summarizes advice that I frequently give to Haskell beginners asking how to start out learning the language

First, in general I recommend reading the Haskell Programming from first principles book, mainly because the book teaches Haskell without leaving out details and also provides plenty of exercises to test your understanding. This is usually good enough if you are learning Haskell as your first language.

However, I would like to give a few additional tips for programmers who are approaching Haskell from other programming languages.

Learn Haskell for the right reasons

Some people learn Haskell with the expectation that they will achieve some sort of programming enlightenment or nirvana. You will be disappointed if you bring these unrealistic expectations to the language. Haskell is not an achievement to unlock or a trophy to be won because learning is a never-ending process and not a finish line.

I think a realistic expectation is to treat Haskell as a pleasant language to use that lets you focus on solving real problems (as opposed to wasting your time fixing silly self-induced problems like null pointers and "undefined is not a function").

Avoid big-design-up-front

Haskell beginners commonly make the mistake of trying to learn as much of the language as possible before writing their first program and overengineering the first draft. This will quickly burn you out.

You might come to Haskell from a dynamically typed background like JavaScript, Python, or Ruby where you learned to avoid refactoring large code bases due to the lack of static types. This aversion to refactoring promotes a culture of "big-design-up-front" where you try to get your project as close to correct on the first try so that you don't have to refactor your code later.

This is a terrible way to learn Haskell, for two reasons. First, Haskell has a much higher ceiling than most other programming languages, so if you wait until you hit that ceiling before building something you will wait a looooooong time. Second, refactoring is cheap in Haskell so you don't need to get things right the first time.

You will accelerate your learning process if you get dirty and make mistakes. Write really ugly and embarrassing code and then iteratively refine your implementation. There is no royal road to learning Haskell.

Avoid typeclass abuse

Specifically, avoid creating new typeclasses until you are more comfortable with the language.

Functional programming languages excel because many language features are "first class". For example, functions and effects are first class in Haskell, meaning that you can stick them in a list, add them, nest them, or pass them as arguments, which you can't (easily) do in imperative languages.

However, typeclasses are not first-class, which means that if you use them excessively you will quickly depend on advanced language features to do even simple things. Programming functionally at the term-level is much simpler and more enjoyable than the type-level Prolog that type-classes encourage.

Begin by learning how to solve problems with ordinary functions and ordinary data structures. Once you feel like you understand how to solve most useful problems with these simple tools then you can graduate to more powerful tools like typeclasses. Typeclasses can reduce a lot of boilerplate in proficient hands, but I like to think of them as more of a convenience than a necessity.

You can also take this approach with you to other functional languages (like Elm, Clojure, Elixir, or Nix). You can think of "functions + data structures" as a simple and portable programming style that will improve all the code that you write, Haskell or not.

Build something useful

Necessity is the mother of invention, and you will learn more quickly if you try to build something that you actually need. You will quickly convince yourself that Haskell is useless if you only use the language to solve Project Euler exercises or Sudoku puzzles.

You are also much more likely to get a Haskell job if you have a portfolio of one or two useful projects to show for your time. These sorts of projects demonstrate that you learned Haskell in order to build something instead of learning Haskell for its own sake.

Conclusion

Hopefully these tips will help provide some guard rails for learning the language for the first time. That's not to say that Haskell is perfect, but I think you will enjoy the language if you avoid these common beginner pitfalls.

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by Gabriel Gonzalez (noreply@blogger.com) at October 16, 2017 02:45 PM

[duimuqdd] Compressing prime numbers

Given a large prime number p not of any special form, can one data-compress it to specify it in less than log_2(p) bits?

Straightforward is to say it is the m-th prime.  Expressing m will take about log_2(p/log(p)) bits by the prime number theorem.  This is the theoretical optimum by some measure, because the m's map 1-to-1 with the primes.  The number of bits saved is log_2(p)- log_2(p/log(p)) = log_2(p) - [log_2(p) - log_2(log(p))] = log_2(log(p)) which, because of the twice-iterated logarithm, is a very small savings.  For 370-bit primes around exp(256), the savings is 8 bits, or a reduction of 1 part in 46.  For larger primes, the relative savings is even less.  Around exp(2^16), the reduction is 1 part in 5909.

Despite the mostly uselessness of this endeavor, we charge forward.

Computing m is not practical for large primes.  For a practical method, we form a new number x = 2^k * floor(p / 2^k), equivalent to setting k lower bits of p to zero.  Then we can encode p as the n-th prime larger than x.  For small k, n is easy to compute, and it is easy to recover p from n and x (e.g., with a prime sieve starting from x).  Storing n instead of the lower bits of p results in some data savings because primes are less dense.  Curiously, the number of bits saved on average is log_2(log(p)), which is the theoretical maximum, and not dependent on k.  However, we also need to store k, which eats up some of those savings.  Because the number of bits saved is constant, this method paradoxically works less and less well for larger k.  However, with small k, n might vary significantly from the average, which could be good or bad.  Here is some Haskell code to compute n.  Here is some example output on the prime 3^233 + 176, which is around exp(2^8).  We can see there is generally around 8 bits of savings, except for 2^21 where we got lucky.

input 1476564251485392778927857721313837180933869708288569663932077079002031653266328641356763872492873429131586567699
prime # 1 after 2^ 9 * 2883914553682407771343472111941088244011464274001112624867338044925843072785798127649929438462643416272630015
prime # 3 after 2^ 10 * 1441957276841203885671736055970544122005732137000556312433669022462921536392899063824964719231321708136315007
prime # 8 after 2^ 11 * 720978638420601942835868027985272061002866068500278156216834511231460768196449531912482359615660854068157503
prime # 12 after 2^ 12 * 360489319210300971417934013992636030501433034250139078108417255615730384098224765956241179807830427034078751
prime # 24 after 2^ 13 * 180244659605150485708967006996318015250716517125069539054208627807865192049112382978120589903915213517039375
prime # 59 after 2^ 14 * 90122329802575242854483503498159007625358258562534769527104313903932596024556191489060294951957606758519687
prime # 129 after 2^ 15 * 45061164901287621427241751749079503812679129281267384763552156951966298012278095744530147475978803379259843
prime # 252 after 2^ 16 * 22530582450643810713620875874539751906339564640633692381776078475983149006139047872265073737989401689629921
prime # 526 after 2^ 21 * 704080701582619084800652371079367247073111395019802886930502452374473406441845246008283554312168802800935
prime # 8789 after 2^ 22 * 352040350791309542400326185539683623536555697509901443465251226187236703220922623004141777156084401400467

Future exploration:  "Luck" above is easily explained by long internal strings of zeroes in the binary representation of p: the least significant 21 bits of p are 000011111111000010011.  We could also try to take advantage of long internal strings of ones.  More generally, sieving for primes works well for regions defined by arithmetic progressions.  We might search generally for representations of p as the "a-th prime number of the form b*x + c larger/smaller than d*e^k".  Above we explored b=1, c=0, "larger", e=2, d unrestricted.  We could also explore anchor expressions more complicated than d*e^k.

Previously a completely different way to encode large prime numbers in a small amount of space.

by Ken (noreply@blogger.com) at October 16, 2017 09:26 AM

Counting increasing sequences with Burnside's lemma

[ I started this article in March and then forgot about it. Ooops! ]

Back in February I posted an article about how there are exactly 715 nondecreasing sequences of 4 digits. I said that was the set of such sequences and was the number of such sequences, and in general $$C(d,n) = \binom{n+d-1}{d-1} = \binom{n+d-1}{n}$$ so in particular $$C(10,4) = \binom{13}{4} = 715.$$

I described more than one method of seeing this, but I didn't mention the method I had found first, which was to use the Cauchy-Frobenius-Redfeld-Pólya-Burnside counting lemma. I explained the lemma in detail some time ago, with beautiful illustrated examples, so I won't repeat the explanation here. The Burnside lemma is a kind of big hammer to use here, but I like big hammers. And the results of this application of the big hammer are pretty good, and justify it in the end.

To count the number of distinct sequences of 4 digits, where some sequences are considered “the same” we first identify a symmetry group whose orbits are the equivalence classes of sequences. Here the symmetry group is , the group that permutes the elements of the sequence, because two sequences are considered “the same” if they have exactly the same digits but possibly in a different order, and the elements of acting on the sequences are exactly what you want to permute the elements into some different order.

Then you tabulate how many of the 10,000 original sequences are left fixed by each element of , which is exactly the number of cycles of . (I have also discussed cycle classes of permutations before.) If contains cycles, then leaves exactly of the sequences fixed.

Cycle class	Number of cycles	How many permutations?	Sequences left fixed
	4	1	10,000
	3	6	1,000
	2	3 + 8 = 11	100
	1	6	10
		24	17,160

(Skip this paragraph if you already understand the table. The four rows above are an abbreviation of the full table, which has 24 rows, one for each of the 24 permutations of order 4. The “How many permutations?” column says how many times each row should be repeated. So for example the second row abbreviates 6 rows, one for each of the 6 permutations with three cycles, which each leave 1,000 sequences fixed, for a total of 6,000 in the second row, and the total for all 24 rows is 17,160. There are two different types of permutations that have two cycles, with 3 and 8 permutations respectively, and I have collapsed these into a single row.)

Then the magic happens: We average the number left fixed by each permutation and get which we already know is the right answer.

Now suppose we knew how many permutations there were with each number of cycles. Let's write for the number of permutations of things that have exactly cycles. For example, from the table above we see that $$\st 4 4 = 1,\quad \st 4 3 = 6,\quad \st 4 2 = 11,\quad \st 4 1 = 6.$$

Then applying Burnside's lemma we can conclude that $$S(d, n) = \frac1{n!}\sum_i \st ni d^i .\tag{$\spadesuit$}$$ So for example the table above computes .

At some point in looking into this I noticed that $$\def\rp#1#2{#1^{\overline{#2}}}% \def\fp#1#2{#1^{\underline{#2}}}% S(d,n) = \frac1{n!}\rp dn$$ where is the so-called “rising power” of : $$\rp dn = d\cdot(d+1)(d+2)\cdots(d+n-1).$$ I don't think I had a proof of this; I just noticed that and (both obvious), and the Burnside's lemma analysis of the case had just given me . Even if one doesn't immediately recognize this latter polynomial it looks like it ought to factor and then on factoring it one gets . So it's easy to conjecture and indeed, this is easy to prove from : The obey the recurrence $$\st{n+1}k = n \st nk + \st n{k-1}\tag{$\color{green}{\star}$}$$ (by an easy combinatorial argument¹) and it's also easy to show that the coefficients of obey the same recurrence.²

In general so we have which ties the knot with the formula from the previous article. In particular, .

I have a bunch more to say about this but this article has already been in the oven long enough, so I'll cut the scroll here.

---

[1] The combinatorial argument that justifies is as follows: The Stirling number counts the number of permutations of order with exactly cycles. To get a permutation of order with exactly cycles, we can take one of the permutations of order with cycles and insert the new element into one of the existing cycles after any of the elements. Or we can take on of the permutations with only cycles and add the new element in its own cycle.)

[2] We want to show that the coefficients of obey the same recurrence as . Let's say that the coefficient of the term in is . We have $$\rp n{k+1} = \rp nk\cdot (n+k) = \rp nk \cdot n + \rp nk \cdot k $$ so the coefficient of the the term on the left is .

by Mark Dominus (mjd@plover.com) at October 15, 2017 11:09 PM

A tail we don't need to wag

Introduction

I've been reading a little about concentration inequalities recently. I thought it would be nice to see if you can use the key idea, if not the actual theorems, to reduce the complexity of computing the probability distribution of the outcome of stochastic simulations. Examples might include random walks, or queues.

The key idea behind concentration inequalities is that very often most of the probability is owned by a small proportion of the possible outcomes. For example, if we toss a fair coin enough (say ) times we expect the number of heads to lie within of the mean about 99.99% of the time despite there being different total numbers possible. The probable outcomes tend to concentrate around the expectation. On the other hand, if we consider not the total number of heads, but the possible sequences of tosses, there are possibilities, all equally likely. In this case there is no concentration. So a key ingredient here is a reduction operation: in this case reducing a sequence of tosses to a count of the number that came up heads. This is something we can use in a computer program.

I (and many others) have written about the "vector space" monad that can be used to compute probability distributions of outcomes of simulations and I'll assume some familiarity with that. Essentially it is a "weighted list" monad which is similar to the list monad except that in addition to tracking all possible outcomes, it also propagates a probability along each path. Unfortunately it needs to follow through every possible path through a simulation. For example, in the case of simulating coin tosses it needs to track different possiblities, even though we're only interested in the possible sums. If, after each bind operation of the monad, we could collect together all paths that give the same total then we could make this code much more efficient. The catch is that to collect together elements of a type the elements need to be comparable, for example instances of Eq or Ord. This conflicts with the type of Monad which requires that we can use the >>= :: m a -> (a -> m b) -> m b and return :: a -> m a functions with any types a and b.

I'm going to deal with this by adapting a technique presented by Oleg Kiselyov for efficiently implementing the Set monad. Instead of Set I'm going to use the Map type to represent probability distributions. These will store maps saying, for each element of a type, what the probability of that element is. So part of my code is going to be a direct translation of that code to use the Map type instead of the Set type.

> {-# LANGUAGE GADTs, FlexibleInstances #-}
> {-# LANGUAGE ViewPatterns #-}


> module Main where


> import Control.Monad
> import Control.Arrow
> import qualified Data.Map as M
> import qualified Data.List as L

The following code is very similar to Oleg's. But for first reading I should point out some differences that I want you to ignore. The type representing a probability distribution is P:

> data P p a where
>     POrd :: Ord a => p -> M.Map a p -> P p a
>     PAny :: p -> [(a, p)] -> P p a

But note how the constructors take two arguments - a number that is a probability, in addition to a weighted Map or list. For now pretend that first argument is zero and that the functions called trimXXX act similarly to the identity:

> instance (Ord p, Num p) => Functor (P p) where
>     fmap = liftM


> instance (Ord p, Num p) => Applicative (P p) where
>     pure = return
>     (<*>) = ap


> instance (Ord p, Num p) => Monad (P p) where
>     return x = PAny 0 [(x, 1)]
>     m >>= f = 
>         let (e, pdf) = unP m
>         in trimAdd e $ collect $ map (f *** id) pdf


> returnP :: (Ord p, Num p, Ord a) => a -> P p a
> returnP a = POrd 0 $ M.singleton a 1


> unP :: P p a -> (p, [(a, p)])
> unP (POrd e pdf) = (e, M.toList pdf)
> unP (PAny e pdf) = (e, pdf)


> fromList :: (Num p, Ord a) => [(a, p)] -> M.Map a p
> fromList = M.fromListWith (+)


> union :: (Num p, Ord a) => M.Map a p -> M.Map a p -> M.Map a p
> union = M.unionWith (+)


> scaleList :: Num p => p -> [(a, p)] -> [(a, p)]
> scaleList weight = map (id *** (weight *))


> scaleMap :: (Num p, Ord a) => p -> M.Map a p -> M.Map a p
> scaleMap weight = fromList . scaleList weight . M.toList

This is a translation of Oleg's crucial function that allows us to take a weighted list of probability distributions and flatten them down to a single probability distribution:

> collect :: Num p => [(P p a, p)] -> P p a
> collect []  = PAny 0 []
> collect ((POrd e0 pdf0, weight) : rest) =
>     let wpdf0 = scaleMap weight pdf0
>     in case collect rest of
>       POrd e1 pdf1 -> POrd (weight*e0+e1) $ wpdf0 `union` pdf1
>       PAny e1 pdf1 -> POrd (weight*e0+e1) $ wpdf0 `union` fromList pdf1
> collect ((PAny e0 pdf0, weight) : rest) =
>     let wpdf0 = scaleList weight pdf0
>     in case collect rest of
>       POrd e1 pdf1 -> POrd (weight*e0+e1) $ fromList wpdf0 `union` pdf1
>       PAny e1 pdf1 -> PAny (weight*e0+e1) $ wpdf0 ++ pdf1

But now I really must explain what the first argument to POrd and PAny is and why I have all that "trimming".

Even though the collect function allows us to reduce the number of elements in our PDFs, we'd like to take advantage of concentration of probability to reduce the number even further. The trim function keeps only the top probabilities in a PDF, discarding the rest. To be honest, this is the only point worth taking away from what I've written here :-)

When we throw away elements of the PDF our probabilities no longer sum to 1. So I use the first argument of the constructors as a convenient place to store the amount of probability that I've thrown away. The trim function keeps the most likely outcomes and sums the probability of the remainder. I don't actually need to keep track of what has been discarded. In principle we could reconstruct this value by looking at how much the probabilities in our trimmed partial PDFs fall short of summing to 1. But confirming that our discarded probability and our partial PDF sums to 1 gives a nice safety check for our code and can give us some warning if numerical errors start creeping in. I'll call the total discarded probability the tail probability.

Here is the core function to keep the top values. In this case is given by a global constant called trimSize. (I'll talk about how to do this better later.)

> trimList :: (Ord p, Num p) => [(a, p)] -> (p, [(a, p)])
> trimList ps =
>     let (keep, discard) = L.splitAt trimSize (L.sortOn (negate . snd) ps)
>     in (sum (map snd discard), keep)


> trimAdd :: (Ord p, Num p) => p -> P p a -> P p a
> trimAdd e' (POrd e pdf) =
>     let (f, trimmedPdf) = trimList (M.toList pdf)
>     in POrd (e'+e+f) (M.fromList trimmedPdf)
> trimAdd e' (PAny e pdf) =
>     let (f, trimmedPdf) = trimList pdf
>     in PAny (e'+e+f) trimmedPdf


> runP :: (Num p, Ord a) => P p a -> (p, M.Map a p)
> runP (POrd e pdf) = (e, pdf)
> runP (PAny e pdf) = (e, fromList pdf)

And now some functions representing textbook probability distributions. First the uniform distribution on a finite set. Again this is very similar to Oleg's chooseOrd function apart from the fact that it assigns weights to each element:

> chooseP :: (Fractional p, Ord p, Ord a) =>
>            [a] -> P p a
> chooseP xs = let p = 1/fromIntegral (length xs)
>              in POrd 0 $ fromList $ map (flip (,) p) xs

And the Bernoulli distribution, i.e. tossing a Bool coin that comes up True with probability :

> bernoulliP :: (Fractional p, Ord p) =>
>               p -> P p Bool
> bernoulliP p = POrd 0 $ fromList $ [(False, 1-p), (True, p)]

Now we can try a random walk in one dimension. At each step we have a 50/50 chance of standing still or taking a step to the right:

> random_walk1 :: Int -> P Double Int
> random_walk1 0 = returnP 0
> random_walk1 n = do
>     a <- random_walk1 (n-1)
>     b <- chooseP [0, 1]
>     returnP $ a+b

Below in main we take 2048 steps but only track 512 probabilities. The tail probability in this case is about . So only tracking 1/4 of the outcomes has had almost no impact on the numbers. This also illustrates why it is good to track the tail probabilities rather than inferring them from the missing probabilities in the bulk of the PDF - they can be so small they vanish compared to floating poimnt errors. We can afford to track a lot fewer than 512 (out of 2049 possible) outcomes and still have a good representative PDF.

Now here's a two-dimensional random walk for 32 steps. The tail probability is about so we are getting a reasonably representative PDF. We have to run fewer steps than before, however, because the space of possible outcomes spans two dimensions, meaning that reduction doesn't help as much as it does in one dimension.

> random_walk2 :: Int -> (Int, Int) -> P Double (Int, Int)
> random_walk2 0 (x, y) = returnP (x, y)
> random_walk2 n (x, y) = do
>     (x',y') <- random_walk2 (n-1) (x, y)
>     dx <- chooseP [-1, 1]
>     dy <- chooseP [-1, 1]
>     returnP (x'+dx, y'+dy)

One last simulation. This is a queing scenario. Tasks come in once every tick of the clock. There are four queues a task can be assigned to. A task is assigned to the shortest queue. Meanwhile each queue as a 1/4 probability of clearing one item at each tick of the clock. We build the PDF for the maximum length any queue has at any time.

The first argument to queue is the number of ticks of the clock. The second argument is the list of lengths of the queues. It returns a PDF, not just on the current queue size, but also on the longest queue it has seen.

> queue :: Int -> [Int] -> P Double (Int, [Int])
> queue 0 ls = returnP (maximum ls, ls)
> queue n ls = do
>     (longest, ls1) <- queue (n-1) ls
>     ls2 <- forM ls1 $ \l -> do
>         served <- bernoulliP (1/4)
>         returnP $ if served && l > 0 then l-1 else l
>     let ls3 = L.sort $ head ls2+1 : tail ls2
>     returnP (longest `max` maximum ls3, ls3)

For the queing simulation the tail probability is around despite the fact that we have discarded a vast possible set of possible outcomes.

It's a little ugly that trimSize is a global constant:

> trimSize = 512

The correct solution is probably to separate the probability "syntax" from its "semantics". In other words, we should implement a free monad supporting the language of probability with suitable constructors for bernoulliP and choiceP. We can then write a separate interpreter which takes a trimSize as argument. This has another advantage too: the Monad above isn't a true monad. It uses a greedy approach to discarding probabilities and different rearrangements of the code, that ought to give identical results, may end up diferent. By using a free monad we ensure that our interface is a true monad and we can put the part of the code that breaks the monad laws into the interpreter. The catch is that my first attempt at writing a free monad resulted in code with poor performance. So I'll leave an efficient version as an exercise :-)

> main = do
>     print $ runP $ random_walk1 2048
>     print $ runP $ random_walk2 32 (0, 0)
>     print $ runP $ do
>         (r, _) <- queue 128 [0, 0, 0, 0]
>         returnP r

by Dan Piponi (noreply@blogger.com) at October 14, 2017 08:42 PM

Analytics Developer for a mobile app at EmployeeChannel, Inc. (Full-time)

Who we are

EmployeeChannel is a leading provider of award-winning mobile apps for employee engagement and communication, enabling HR and Internal Communications teams to boost the impact and effectiveness of employee communication, to create a positive employee experience, and to drive cultural and business outcomes. The EmployeeChannel app extends the knowledge and reach of organizational experts to employees anytime, anywhere and is dedicated to the interactions between an organization and its employees.

Employees can find and receive organizational information easier and faster, get personalized responses to requests, and react quickly to time-sensitive events. HR and Internal Communications teams can respond real-time to organizational imperatives and employee needs using behavioral insights from Voice of the Employee analytics. To learn more about the EmployeeChannel app and how it can be used to engage and communicate with employees, please visit www.employeechannelinc.com.

What we are looking for

We are an early stage start-up in downtown San Francisco with great product, a solid business model, and tremendous upside. Fully funded and about to scale – a great time to join!

We are searching for talented and motivated individuals who like a good challenge, enjoy teamwork, and are passionate about building something of real value. You’ll be joining an experienced team that knows how to execute to a market-defining strategy. We work hard, because we enjoy what we are doing and the people we work with. We are confident that EmployeeChannel is the team to beat in what is panning out as a huge opportunity. The person we're looking for is first and foremost a developer, who understands and does functional programming, with Haskell experience, and enough math background to understand statistics and analytics. Sound like what you’re looking for? Read on…

What you will do

As a member of our Product team, you will contribute to both leading edge research and rapid development in our delivery of high-quality, engaging, SaaS-based products. Machine learning, NLP, and analytics drive a significant portion of our product’s value proposition. You will engage with our highly experienced research team to explore and model state-of-the-art use of these frameworks to provide unique insights for our customers.

Your work with other developers can have a big impact, heavily influencing our approach to delivering high quality products. We are committed to delivering robust, scalable products that bring a consumer best-in-class feel to the Enterprise market.

Here¹s a sample of what that would look like:

• You will work with data scientists and software engineers to implement analytics and machine learning algorithms in production-quality Haskell code and deploy them to production servers. You will learn a ton and be challenged regularly in this role. • You will devise tests of integrity and consistency for both data and analytics results. • You¹ll work in an Agile environment with a team whose track record of meeting or exceeding their commitments is strong. • You¹ll enjoy partnering with other developers, knowing that collaborative design sessions and the occasional pair programming are part of how we operate. • We deliver quality code, because we are committed to test-driven development and we take pride in our work. • 1 + 1 = 3 here. We look to leverage open source wherever it makes sense, knowing that we can move faster as a result. Speed matters. • You won¹t feel pigeon-holed here. Working together with Product Managers and our Hosted Ops counterparts is a daily occurrence. • You¹ll have a measurable impact on the success of our product and company. If you¹re looking for a place where you can get your fingerprints all over the product, this is a good place to call home.

Your qualifications

• The ideal candidate we're looking for is first and foremost a developer, who understands and does functional programming, with Haskell experience, and enough math background to understand statistics and analytics. And above all, our ideal candidate loves functional programming. • 2-3 years of relevant work experience is required. • You have experience with, and appreciation for, functional programming and where it can be advantageously applied. • You have produced production-quality code for a high scale commercial application. • You have used Haskell in projects. You know your way around GHCi, stack, and cabal. • You have designed database schema and worked with databases like Postgres. • You have built the back-end of a web service. • While developing, you formally test your code with unit-test packages such as HSpec. • You are no stranger to mathematics, statistics, and data analysis. If you encountered this with Python, we will not hold that against you. • You have worked as part of an Agile development team. • Git, Apache, and HSpec are all used in our shop. • A BS in a Mathematics-intensive degree (Comp Sci, Math, Physics) or equivalent is required.

Get information on how to apply for this position.

October 12, 2017 08:48 PM

Isabelle functions: Always total, sometimes undefined

Often, when I mention how things work in the interactive theorem prover [Isabelle/HOL] (in the following just “Isabelle”¹) to people with a strong background in functional programming (whether that means Haskell or Coq or something else), I cause confusion, especially around the issue of what is a function, are function total and what is the business with undefined. In this blog post, I want to explain some these issues, aimed at functional programmers or type theoreticians.

Note that this is not meant to be a tutorial; I will not explain how to do these things, and will focus on what they mean.

HOL is a logic of total functions

If I have a Isabelle function f :: a ⇒ b between two types a and b (the function arrow in Isabelle is ⇒, not →), then – by definition of what it means to be a function in HOL – whenever I have a value x :: a, then the expression f x (i.e. f applied to x) is a value of type b. Therefore, and without exception, every Isabelle function is total.

In particular, it cannot be that f x does not exist for some x :: a. This is a first difference from Haskell, which does have partial functions like

spin :: Maybe Integer -> Bool
spin (Just n) = spin (Just (n+1))

Here, neither the expression spin Nothing nor the expression spin (Just 42) produce a value of type Bool: The former raises an exception (“incomplete pattern match”), the latter does not terminate. Confusingly, though, both expressions have type Bool.

Because every function is total, this confusion cannot arise in Isabelle: If an expression e has type t, then it is a value of type t. This trait is shared with other total systems, including Coq.

Did you notice the emphasis I put on the word “is” here, and how I deliberately did not write “evaluates to” or “returns”? This is because of another big source for confusion:

Isabelle functions do not compute

We (i.e., functional programmers) stole the word “function” from mathematics and repurposed it². But the word “function”, in the context of Isabelle, refers to the mathematical concept of a function, and it helps to keep that in mind.

What is the difference?

• A function a → b in functional programming is an algorithm that, given a value of type a, calculates (returns, evaluates to) a value of type b.
• A function a ⇒ b in math (or Isabelle) associates with each value of type a a value of type b.

For example, the following is a perfectly valid function definition in math (and HOL), but could not be a function in the programming sense:

definition foo :: "(nat ⇒ real) ⇒ real" where
  "foo seq = (if convergent seq then lim seq else 0)"

This assigns a real number to every sequence, but it does not compute it in any useful sense.

From this it follows that

Isabelle functions are specified, not defined

Consider this function definition:

fun plus :: "nat ⇒ nat ⇒ nat"  where
   "plus 0       m = m"
 | "plus (Suc n) m = Suc (plus n m)"

To a functional programmer, this reads

plus is a function that analyses its first argument. If that is 0, then it returns the second argument. Otherwise, it calls itself with the predecessor of the first argument and increases the result by one.

which is clearly a description of a computation.

But to Isabelle, the above reads

plus is a binary function on natural numbers, and it satisfies the following two equations: …

And in fact, it is not so much Isabelle that reads it this way, but rather the fun command, which is external to the Isabelle logic. The fun command analyses the given equations, constructs a non-recursive definition of plus under the hood, passes that to Isabelle and then proves that the given equations hold for plus.

One interesting consequence of this is that different specifications can lead to the same functions. In fact, if we would define plus' by recursing on the second argument, we’d obtain the the same function (i.e. plus = plus' is a theorem, and there would be no way of telling the two apart).

Termination is a property of specifications, not functions

Because a function does not evaluate, it does not make sense to ask if it terminates. The question of termination arises before the function is defined: The fun command can only construct plus in a way that the equations hold if it passes a termination check – very much like Fixpoint in Coq.

But while the termination check of Fixpoint in Coq is a deep part of the basic logic, in Isabelle it is simply something that this particular command requires for its internal machinery to go through. At no point does a “termination proof of the function” exist as a theorem inside the logic. And other commands may have other means of defining a function that do not even require such a termination argument!

For example, a function specification that is tail-recursive can be turned in to a function, even without a termination proof: The following definition describes a higher-order function that iterates its first argument f on the second argument x until it finds a fixpoint. It is completely polymorphic (the single quote in 'a indicates that this is a type variable):

partial_function (tailrec)
  fixpoint :: "('a ⇒ 'a) ⇒ 'a ⇒ 'a"
where
  "fixpoint f x = (if f x = x then x else fixpoint f (f x))"

We can work with this definition just fine. For example, if we instantiate f with (λx. x-1), we can prove that it will always return 0:

lemma "fixpoint (λ n . n - 1) (n::nat) = 0"
  by (induction n) (auto simp add: fixpoint.simps)

Similarly, if we have a function that works within the option monad (i.e. |Maybe| in Haskell), its specification can always be turned into a function without an explicit termination proof – here one that calculates the Collatz sequence:

partial_function (option) collatz :: "nat ⇒ nat list option"
 where "collatz n =
        (if n = 1 then Some [n]
         else if even n
           then do { ns <- collatz (n div 2);    Some (n # ns) }
           else do { ns <- collatz (3 * n + 1);  Some (n # ns)})"

Note that lists in Isabelle are finite (like in Coq, unlike in Haskell), so this function “returns” a list only if the collatz sequence eventually reaches 1.

I expect these definitions to make a Coq user very uneasy. How can fixpoint be a total function? What is fixpoint (λn. n+1)? What if we run collatz n for a n where the Collatz sequence does not reach 1?³ We will come back to that question after a little detour…

HOL is a logic of non-empty types

Another big difference between Isabelle and Coq is that in Isabelle, every type is inhabited. Just like the totality of functions, this is a very fundamental fact about what HOL defines to be a type.

Isabelle gets away with that design because in Isabelle, we do not use types for propositions (like we do in Coq), so we do not need empty types to denote false propositions.

This design has an important consequence: It allows the existence of a polymorphic expression that inhabits any type, namely

undefined :: 'a

The naming of this term alone has caused a great deal of confusion for Isabelle beginners, or in communication with users of different systems, so I implore you to not read too much into the name. In fact, you will have a better time if you think of it as arbitrary or, even better, unknown.

Since undefined can be instantiated at any type, we can instantiate it for example at bool, and we can observe an important fact: undefined is not an extra value besides the “usual ones”. It is simply some value of that type, which is demonstrated in the following lemma:

lemma "undefined = True ∨ undefined = False" by auto

In fact, if the type has only one value (such as the unit type), then we know the value of undefined for sure:

lemma "undefined = ()" by auto

It is very handy to be able to produce an expression of any type, as we will see as follows

Partial functions are just underspecified functions

For example, it allows us to translate incomplete function specifications. Consider this definition, Isabelle’s equivalent of Haskell’s partial fromJust function:

fun fromSome :: "'a option ⇒ 'a" where
  "fromSome (Some x) = x"

This definition is accepted by fun (albeit with a warning), and the generated function fromSome behaves exactly as specified: when applied to Some x, it is x. The term fromSome None is also a value of type 'a, we just do not know which one it is, as the specification does not address that.

So fromSome None behaves just like undefined above, i.e. we can prove

lemma "fromSome None = False ∨ fromSome None = True" by auto

Here is a small exercise for you: Can you come up with an explanation for the following lemma:

fun constOrId :: "bool ⇒ bool" where
  "constOrId True = True"

lemma "constOrId = (λ_.True) ∨ constOrId = (λx. x)"
  by (metis (full_types) constOrId.simps)

Overall, this behavior makes sense if we remember that function “definitions” in Isabelle are not really definitions, but rather specifications. And a partial function “definition” is simply a underspecification. The resulting function is simply any function hat fulfills the specification, and the two lemmas above underline that observation.

Nonterminating functions are also just underspecified

Let us return to the puzzle posed by fixpoint above. Clearly, the function – seen as a functional program – is not total: When passed the argument (λn. n + 1) or (λb. ¬b) it will loop forever trying to find a fixed point.

But Isabelle functions are not functional programs, and the definitions are just specifications. What does the specification say about the case when f has no fixed-point? It states that the equation fixpoint f x = fixpoint f (f x) holds. And this equation has a solution, for example fixpoint f _ = undefined.

Or more concretely: The specification of the fixpoint function states that fixpoint (λb. ¬b) True = fixpoint (λb. ¬b) False has to hold, but it does not specify which particular value (True or False) it should denote – any is fine.

Not all function specifications are ok

At this point you might wonder: Can I just specify any equations for a function f and get a function out of that? But rest assured: That is not the case. For example, no Isabelle command allows you define a function bogus :: () ⇒ nat with the equation bogus () = Suc (bogus ()), because this equation does not have a solution.

We can actually prove that such a function cannot exist:

lemma no_bogus: "∄ bogus. bogus () = Suc (bogus ())" by simp

(Of course, not_bogus () = not_bogus () is just fine…)

You cannot reason about partiality in Isabelle

We have seen that there are many ways to define functions that one might consider “partial”. Given a function, can we prove that it is not “partial” in that sense?

Unfortunately, but unavoidably, no: Since undefined is not a separate, recognizable value, but rather simply an unknown one, there is no way of stating that “A function result is not specified”.

Here is an example that demonstrates this: Two “partial” functions (one with not all cases specified, the other one with a self-referential specification) are indistinguishable from the total variant:

fun partial1 :: "bool ⇒ unit" where
  "partial1 True = ()"
partial_function (tailrec) partial2 :: "bool ⇒ unit" where
  "partial2 b = partial2 b"
fun total :: "bool ⇒ unit" where
  "total True = ()"
| "total False = ()"

lemma "partial1 = total ∧ partial2 = total" by auto

If you really do want to reason about partiality of functional programs in Isabelle, you should consider implementing them not as plain HOL functions, but rather use HOLCF, where you can give equational specifications of functional programs and obtain continuous functions between domains. In that setting, ⊥ ≠ () and partial2 = ⊥ ≠ total. We have done that to verify some of HLint’s equations.

You can still compute with Isabelle functions

I hope by this point, I have not scared away anyone who wants to use Isabelle for functional programming, and in fact, you can use it for that. If the equations that you pass to `fun are a reasonable definition for a function (in the programming sense), then these equations, used as rewriting rules, will allow you to “compute” that function quite like you would in Coq or Haskell.

Moreover, Isabelle supports code extraction: You can take the equations of your Isabelle functions and have them expored into Ocaml, Haskell, Scala or Standard ML. See Concon for a conference management system with confidentially verified in Isabelle.

While these usually are the equations you defined the function with, they don't have to: You can declare other proved equations to be used for code extraction, e.g. to refine your elegant definitions to performant ones.

Like with code extraction from Coq to, say, Haskell, the adequacy of the translations rests on a “moral reasoning” foundation. Unlike extraction from Coq, where you have an (unformalized) guarantee that the resulting Haskell code is terminating, you do not get that guarantee from Isabelle. Conversely, this allows you do reason about and extract non-terminating programs, like fixpoint, which is not possible in Coq.

There is currently ongoing work about verified code generation, where the code equations are reflected into a deep embedding of HOL in Isabelle that would allow explicit termination proofs.

Conclusion

We have seen how in Isabelle, every function is total. Function declarations have equations, but these do not define the function in an computational sense, but rather specify them. Because in HOL, there are no empty types, many specifications that appear partial (incomplete patterns, non-terminating recursion) have solutions in the space of total functions. Partiality in the specification is no longer visible in the final product.

PS: Axiom undefined in Coq

This section is speculative, and an invitation for discussion.

Coq already distinguishes between types used in programs (Set) and types used in proofs Prop.

Could Coq ensure that every t : Set is non-empty? I imagine this would require additional checks in the Inductive command, similar to the checks that the Isabelle command datatype has to perform⁴, and it would disallow Empty_set.

If so, then it would be sound to add the following axiom

Axiom undefined : forall (a : Set), a.

wouldn't it? This axiom does not have any computational meaning, but that seems to be ok for optional Coq axioms, like classical reasoning or function extensionality.

With this in place, how much of what I describe above about function definitions in Isabelle could now be done soundly in Coq. Certainly pattern matches would not have to be complete and could sport an implicit case _ ⇒ undefined. Would it “help” with non-obviously terminating functions? Would it allow a Coq command Tailrecursive that accepts any tailrecursive function without a termination check?

---

1. Isabelle is a metalogical framework, and other logics, e.g. Isabelle/ZF, behave differently. For the purpose of this blog post, I always mean Isabelle/HOL.↩

2. Isabelle is a metalogical framework, and other logics, e.g. Isabelle/ZF, behave differently. For the purpose of this blog post, I always mean Isabelle/HOL.↩

3. Let me know if you find such an n. Besides n = 0.↩

4. Like fun, the constructions by datatype are not part of the logic, but create a type definition from more primitive notions that is isomorphic to the specified data type.↩

by Joachim Breitner (mail@joachim-breitner.de) at October 12, 2017 05:54 PM

Array fusion with vector

Manuel M T Chakravarty

This is the fourth post in a series about array programming in Haskell — you might be interested in the first, second, and third, too.

In the previous post of this series, we explored the basic, down-to-earth, index-based array interfaces that have their roots in the Haskell standard libraries. We also discussed the need for strictness, unboxing, and a two-phase initialisation strategy, freezing mutable structures after they have been populated. With those basics out of the way, we can now explore the design of higher-level, collection-oriented array interfaces whose efficient implementation critically relies on those basic techniques.

The vector package is probably the most popular array library in Haskell, and it is a prime example of this approach. The package, implemented by Roman Leshchinskiy, is a spin off from the Data Parallel Haskell project . Specifically, Data Parallel Haskell is organised as multiple layers of array libraries, and vector is a generalisation of what used to be the lowest layer: sequential, int-indexed arrays combined with a powerful array-fusion framework that makes the composition of successive collective operations efficient.

Collective

Collective operations that process all elements of an array in a single operation, such as map, fold, zip, filter, and so forth, fit more naturally into a functional style than the index-based loops that originated in FORTRAN. This is not just to favour combinator-based code, but also because index-based, one-element-at-a-time processing quickly leads to the use of mutable arrays. Indexed-based operations are sometimes inevitable, but they ought to be used sparingly; often we only need to extract individual or only a few elements of an array. In cases, where random data-driven access is required, collective index-based operations often suffice — such as, for example, backpermute:

backpermute (fromList ['a', 'b', 'c', 'd']) (fromList [0, 3, 2, 3, 1, 0])
  = fromList ['a', 'd', 'c', 'd', 'b', 'a']

The function backpermute returns a result of the same length as its second argument, where the integer values of the second argument are used to determine the index positions of the elements to pick from the first argument. (The function fromList turns a list into a Vector.)

Array fusion

Consider the following pipeline of collective vector operations, where we assume import Data.Vector as V to disambiguate vector operations from the standard list operations of the same name:

  V.map fst
$ V.filter (\t -> snd t > 0)
$ V.zip points cs

First, we combine a vector of points :: Vector (Double, Double) with a vector cs :: Vector Double by way of V.zip to obtain a value of type Vector ((Double, Double), Double). Then, we V.filter to only retain those ((Double, Double), Double) triples whose last component is strictly positive. Finally, we project the points out of the filtered vector. Overall, this pipeline drops all points whose corresponding (index-wise) cs value is zero or negative.

While this is a compact functional specification, its naive implementation would be rather inefficient. Each of the three collective operations creates a new immutable vector. All this, only to finally get a vector containing a subset of the elements of points. The main problem with this is not that it is wasteful to allocate those intermediate arrays, but that initialising and then consuming those intermediates generates a lot of memory traffic — this is rather unfortunate as memory bandwidth is the most severe limiting factor of current hardware.

Hence, it is absolutely crucial that a library, such as vector, performs array fusion, a compiler optimisation that eliminates intermediate arrays and combines multiple successive array traversals into one. In fact, the vector package, compiles the above code consisting of V.map, V.filter, and V.zip into a single traversal without any intermediates. It achieves this using a fusion framework known as stream fusion.

From generic to concrete

The vector package is architected in a flexible manner with generic type classes Vector (for immutable vectors) and MVector (for mutable vectors), defined in Data.Vector.Generic. Vector is a subclass of MVector , as the latter provides mutating methods on top of the pure ones.

The modules Data.Vector and Data.Vector.Unboxed instantiate the generic framework with concrete boxed and unboxed vector types — both again providing an immutable and a mutable flavour. In addition, there is variant of unboxed vectors, called storable, in Data.Vector.Storable, which ties in with the Storable class of the foreign function interface and is useful for interoperability with C code.

Due to this generic set up, array algorithms can be implemented generically and, then, used with all of the concrete instances. It is also perfectly possible to extend vector with your own flavour of arrays; for example, for interoperability with another array library.

Convex hull

One of the algorithms included in the benchmarks that are part of vector is the quickhull algorithm for computing the convex hull of a set of points. Quickhull is —just like quicksort— a split-based divide-and-conquer algorithm. It begins by cutting the set of points into two by drawing a line between the leftmost and rightmost point in the set. Then, it recursively operates on these two sets of points. In each recursive invocation, the point furthest from the last dividing line gives rise to two new lines (using the two end points of that last dividing line). This is illustrated by the following animation from Wikimedia Commons.

Given a Vector of x/y-coordinates, we can implement the initial step of quickhull, namely determining the left and rightmost point, as follows:

import Data.Vector.Unboxed as V

quickhull :: Vector (Double, Double) -> Vector (Double, Double)
quickhull points = hsplit points pmin pmax V.++ hsplit points pmax pmin
  where
    xs   = V.map fst points
    pmin = points V.! V.minIndex xs
    pmax = points V.! V.maxIndex xs

The functions V.minIndex and V.maxIndex return the index position of the smallest and largest element of the argument vector, respectively (here, of the x-coordinates xs of all points). We use those to extract the leftmost (pmin) and rightmost (pmax) point. When invoking the recursive component of quickhull —here, implemented by hsplit— we pass the points and the dividing line in the form of its starting and end point. As the latter are swapped in the two recursive calls, one call processes the points above the dividing line and the other call processes the points below that line.

The function hsplit, first, computes the distance cs of all points to the line from p1 to p2. Second, it uses the pipeline of collective operations that we discussed above to remove all points that are below that line. The remaining points, packed, are passed into the two recursive calls together with pm, the point that is furthest from the line.

hsplit :: (Ord b, Num b, Unbox b) 
       => Vector (b, b) -> (b, b) -> (b, b) -> Vector (b, b)
hsplit points p1 p2
  | V.length packed < 2 = p1 `V.cons` packed
  | otherwise = hsplit packed p1 pm V.++ hsplit packed pm p2
  where
    cs     = V.map (\p -> cross p p1 p2) points
    packed = V.map fst
           $ V.filter (\t -> snd t > 0)
           $ V.zip points cs

    pm     = points V.! V.maxIndex cs

-- cross p p1 p2 = distance of p from line between p1 and p2
cross :: Num a => (a, a) -> (a, a) -> (a, a) -> a
cross (x,y) (x1,y1) (x2,y2) = (x1-x)*(y2-y) - (y1-y)*(x2-x)

The function cross that we use to compute the distance of a point p from the line between points p1 and p2 returns a signed distance; i.e., a positive distance value is for a point above the line and a negative distance value for a point below the line. This is crucial for V.filter (\t -> snd t > 0) to remove all points located on or below the line.

Fusion interrupted

The vector package optimises the quickhull code rather well and gets within about a factor of two of the performance of hand-optimised C code. However, there are two kinds of obstacles that may prevent stream fusion and other fusion systems from optimising code as expected: (1) the interaction with other compiler optimisations and (2) the strength of the fusion system.

Concerning Point (1), the interaction of multiple compiler optimisations and finding the right order in which to apply them are a topic for PhD theses as well as a black art of skilled engineers. In the Glasgow Haskell Compiler (GHC), it is especially inlining, let floating, strictness analysis, and various forms of rewriting and specialisation that can have a huge impact on the effectiveness of fusion. The details are beyond the scope of this post, but some of it is covered in the rather extensive GHC optimization and fusion.

Concerning Point (2), practical fusion systems generally cannot fuse all fusable programs. In other words, given a particular fusion system, it will spot and optimise certain types of computations that can be fused. However, there are other types of computations that can also be fused, but this particular fusion system will not be able to recognise and exploit those opportunities.

In fact, the algorithmic structure of quickhull does expose a specific limit of vector’s array fusion framework (i.e., stream fusion for arrays). That limit is the reason why vector can only get within about a factor of two of the performance of hand-optimised C code for quickhull. The details of this limitation as well as a proposal to overcome it are explored in the paper Data flow fusion with series expressions in Haskell (PDF). The paper also contains concrete benchmark results, including results for quickhull. Finally, the latest insights into overcoming this specific kind of limitation are described in Machine fusion: merging merges, more or less (PDF).

Conclusion

The vector package is a tool that should be in every Haskell developers tool box. It is versatile, efficient, and widely used. Consequently, there is a range of add ons; in particular, vector-algorithms, which implements search and sorting algorithms, is quite popular.

The vector package works hard to achieve excellent sequential performance. However, it, by design, ignores the option of improving performance by parallelisation. This will be the topic of the next post in this series.

October 12, 2017 12:00 AM

Functor-Oriented Programming

My style of Haskell programming has been evolving over the 15 years that I have been working with it. It is turning into something that I would like to call “functor oriented programming”. The traditional use of typed functional programming focuses on data types. One defines data types to model the data structures that your program operates on, and one writes functions to transform between these structures. One of the primary goals in this traditional methodology is to create data structures that exclude erroneous states to the extent that is reasonably possible. As long as one ensures that pattern matching is complete, then the type system catches many errors that would otherwise lead to these erroneous states, which have been crafted to be unrepresentable.

Functor oriented programming is a refinement of this traditional focus on data types. I was reminded of this concept recently when I was working with wren’s fantastic unification-fd library. With functor oriented programming, one divides data structures into layers of functors that, when composed together, form the data structures that your program operates on. Instead of writing transformations between data structures, one writes natural transformations between functors, where a natural transformation between functors F and G is a polymorphic function of type forall a. F a -> G a. While traditional functions often operate on products of multiple inputs and/or outputs, with functor oriented programming one will often see functions operating on compositions of functors, including but not limited to distribution functions of type forall a. F (G a) -> G (F a) and half-way distribution functions forall a. F (G a) -> G (H a), and many others.

By dividing data structures up into layers of functors, one can create a separation of concerns that does not occur in traditional functional programming. With functor oriented programming, polymorphism is not necessarily about using functions polymorphically. Instead, polymorphism provides correctness guarantees by ensuring that a particular function can only touch the specific layers of functors in its type signature and is independent of the rest of the data structure. One benefits from polymorphism even when a function is only ever invoked at a single type.

The appearance of many natural transformations is one hallmark of functor oriented programming. Higher-order natural transformations will invoke Rank2Types and RankNTypes, which is another hallmark of functor oriented programming. Other hallmarks of functor oriented programming include open recursive types, which allows one to divide up recursive types into their layers of recursion and create natural transformations that operate on a single layer at a time. Open recursive types plays an important role in wren’s unification library.

As fine of a language that Haskell is, it is not actually that suitable for functor oriented programming. The problem is that, under normal circumstances, there is no reduction or equivalence classes at the type level. For example, the identity functor does not transparently disappear during composition, the Compose functor is not transparently associative, and the Swap functor composed with itself does not reduce to the identity functor. To cope with this one must litter one’s code with newtype wrapper and unwrappers to make all these natural transformations explicit. In principle, these transformations should have no run-time consequences, but when they are used in higher-order ways, unfortunately they sometimes do. Despite the problems, I am not aware of any another practical language that better supports this style of programming. I think Haskell’s higher-kinded type classes and the progression of Monad, Applicative, Foldable, Traversable, etc. classes have been instrumental in leading to the development of this style of programming as they further motivate the division of one’s data structures into these layers of functors.

I have been thinking about writing this post for a few years now, and wanted to write something convincing; however, I do not think I am up to the task. Instead of trying to persuade the reader, I have elected to try to simply name and describe this style of programming so that the reader might notice it themselves when reading and writing code. Hopefully someone more capable than me can evangelize this approach, and perhaps even create a practical language suitable for this style of programming.

October 10, 2017 12:17 AM

Taking Propositions as Types Seriously

A while back I decided to try my hand at using Agda and I wrote a proof of the Church-Rosser theorem in it. It was a fun exercise. I took all the knowledge I have picked up over the years about using dependent types to represent binders, to define well-typed terms, and what I have learned about the Category of Contexts and applied it to my definition of Terms for a simply typed lambda calculus. I am proud of the result.

They say you do not understand a topic in mathematics until you can teach it. And you do not really understand it until you can prove it in Coq. And you do not really really understand it until you can prove it in Agda. What really struck me was how my exercise in Adga affected my understanding of “Propositions as Types”.

I view types as being divided into roughly two categories. Some types are propositions. They are the types that have at most one inhabitant, which is to say types for which you can prove that all their inhabitants are equal. Other types are data types. They are types with potentially more than one inhabitant. As such you can distinguish between values by (possibly indirectly) doing case analysis on them. Indeed, HoTT defines propositions in exactly this way.

This classification of types is not fundamental in the theory of types. The theory of types treats both propositions and data types uniformly. I simply find it a useful way of characterizing types when programming and reasoning about programs with dependent type theory. The void and unit types, ⊥ and ⊤ respectively, are both propositions. We can define a function from the Boolean type to the universe of types which map the two Boolean values to these two types. In this way we can covert any Boolean valued (computable) predicate into a logical (type-theoretical) predicate.

To me the phrase “Proposition as Types” just meant the embedding of logical proposition as types with at most one inhabitant. For example, given a decidable type A, we can compute if a given value of type A is a member of a given list of As. This computable predicate can be lifted to a logical predicate to define a logical membership relationship. Expressions using this logical membership relationship are propositions according to the above definition of proposition.

This is a fine way to do formal reasoning. However, this is not the way that membership is typically defined in Agda. Instead, Agda defines the membership relation as an inductive family whose constructors witness that an element is either the head of the list, or is a member of the tail of the list. (Coq also defines the membership relation this way; however it is marked as non-extractable for computation by virtue of being a proposition.) The type (a ∈ l) is, in general, a data type rather than a proposition. When the value a occurs multiple times in l, then the type (a ∈ l) has multiple different “proofs” corresponding the the different occurrences of a within l. Values of this type act as “the type of indexes where a occurs in l”, and one can write programs that operate over this type.

Given two lists, l₁ and l₂, the “proposition” that one list is a subset of the other states that any element of l₁ is also an element of l₂:

l₁ ⊆ l₂ ≔ ∀a. a∈l₁ → a∈l₂

In dependent type theory this implication is represented as a function. Because our membership relation is a data type, this subset relation is represented by a real program. Specifically it is a program that, for any value, maps each index where it occurs in l₁ to some index where it occurs in l₂; you can really evaluate this function. This subset type is also, in general, a data type because there can be multiple such functions, which represent all the possible permutations that maps l₁ onto l₂.

The consequences of this are fantastic. For example, what you normally think of as a theorem for weakening,

weaken : ∀ {Γ₁ Γ₂ A} → Γ₁ ⊆ Γ₂ → Term Γ₁ A → Term Γ₂ A

also captures contraction and exchange due to this definition of subset. All the structural rules of the lambda calculus are subsumed within a single theorem!

It took me several attempts before I learned to take full advantage of this sort of logic. For example, I originally defined a module as an inductive family. However, I eventually settled on a functional representation for modules:

-- A Module is a list of terms of types Δ all in the same context Γ.
-- A Module is a block of terms for simultaneous substitution.
-- A Module is an arrow in the category of contexts.
-- A Module is a profuctor.
Module : List Type → List Type → Set
Module Γ Δ = ∀ {A} → A ∈ Δ → Term Γ A

This definition means a module can evaluate. In particular modules can be partially evaluated during type-checking, which greatly simplified many of my proofs as compared to using the inductive family way of defining modules.

Notice how we make use of values of A ∈ Δ as data defining an index into the context Δ. If Δ has multiple occurrences of A, then the term generated by the module can be different depending on which occurrence the index is referencing.

In conclusion, although I do like thinking of types as divided between propositional types and data types, it can be fruitful to view expressions that mathematics traditionally treats as propositions instead as real data types, and really program with them. This is what I mean by taking "Propositions as Types" seriously.

October 08, 2017 10:27 PM

Why do our programs need to read input and write output?

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I wrote this post to challenge basic assumptions that people make about software architecture, which is why I chose a deliberately provocative title. You might not agree with all the points that I am about to make, but I do hope that this post changes the way that you think about programming

This post is an attempt to restate in my own words what Conal Elliot (and others before him) have been saying for a while: modern programming is a Rube-Goldberg machine that could be much simpler if we change the way we compose code.

Most programmers already intuitively understand this at some level. They will tell you that the programming ecosystem is deeply flawed, fragmented, and overly complex. I know that I felt that way myself for a long time, but in retrospect I believe that my objections at the time were superficial. There were deeper issues with programming that I was blind to because they are so ingrained in our collective psyche.

Disclaimer: This post uses my pet configuration language Dhall to illustrate several points, mainly because Dhall is a constructive proof-of-concept of these ideas. The purpose of this post is not so much to convince you to use Dhall but rather to convince you to think about software in a new way

Input and output

Consider the title of this post for example:

"Why do our programs need to read input and write output?"

Most people will answer the title with something like:

• "Our programs need a way to communicate with the outside world"
• "Programs need to do something other than heat up CPUs"

Now suppose I phrased the question in a different way:

"What if only the compiler could read input and write output?"

"What's the difference?", you might ask. "Surely you mean that the language provides some library function that I can call to read or write input to some handles, whether they be file handles or standard input/output."

No, I mean that only the compiler implementation is allowed to read input or write output, but programs written within the compiled language cannot read input or write output. You can only compute pure functions within the language proper.

Again, this probably seems ridiculous. How could you communicate at all with the program?

Imports

Most languages have some way to import code, typically bundled in the form of packages. An imported function or value is something that our compiler reads as input statically at compile time as opposed to a value read by our program dynamically at run time.

Suppose I told you that our hypothetical programming language could only read input values by importing them

"Ridiculous!" you exclaim as you spit out your coffee. "Nobody would ever use such a language." You probably wouldn't even know where to begin since so many things seem wrong with that proposal

Perhaps you would object to the heavyweight process for publishing and subscribing to new values. You would recite the package management process for your favorite programming language:

• Create a source module containing your value
• Create a standard project layout
• Create a package description file
• Check your project into version control
• Publish your package to a package repository

Perhaps you would object to the heavyweight process for configuring programs via imports? Your favorite programming language would typically require you to:

• Retrieve the relevant program from version control
• Modify the project description file to reference the newly published dependency
• Modify project code to import your newly published value
• Compile the program
• Run the program

Why would a non-technical end user do any of that just to read and write values?

This is exactly the Rube-Goldberg machine I'm referring to. We have come to expect a heavyweight process for source code to depend on other source code

Importing paths

Distributing code doesn't have to be heavyweight, though. Consider Dhall's import system which lets you reference expressions directly by their paths. For example, suppose we saved the value True to a file named example.dhall:

$ echo 'True' > example.dhall

Another Dhall program can reference the above file anywhere the program expects a boolean value:

$ dhall <<< './example.dhall || False'
Bool

True

This is the exact same as if we had just replaced the path with the file's contents:

$ dhall <<< 'True || False'
Bool

True

Dhall doesn't need to support an explicit operation to read input because Dhall can read values by just importing them

Similarly, Dhall doesn't need to support an explicit write operation either. Just save a Dhall expression to a file using your favorite text editor.

"What if I need a way to automate the generation of files?"

You don't need to automate the process of saving a file because one file is always sufficiently rich to store as much information as you need. Dhall is a programmable configuration language which supports lists and records so any one file can store or programmatically generate any number of values. Files are human-generated artifacts which exist purely for our convenience but Dhall code does not behave any differently whether or not the program spans multiple files or a single file.

Most of the time people need to automate reads and writes because they are using non-programmable configuration file formats or data storage formats

Programmable configuration

You might object: "Configuration files shouldn't be Turing-complete!"

However, Dhall is not Turing-complete. Dhall is a total programming language, meaning that evaluation eventually halts. In practice, we don't actually care that much if Dhall halts, since we cannot guarantee that the program halts on reasonable human timescales. However, we can statically analyze Dhall and most of the Halting Problem objections to static analysis don't apply.

For example, Dhall can statically guarantee that programs never fail or throw exceptions (because obviously a configuration file should never crash). Dhall also lets you simplify confusing files by eliminating all indirection because Dhall can reduce every program to a canonical normal form.

In fact, most objections to programmable configuration files are actually objections to Turing-completeness

Importing URLs

Dhall also lets you import code by URL instead of path. Dhall hosts the Prelude of standard utilities online using IPFS (a distributed hashtable for the web),and you can browse the Prelude using this link, which redirects to the latest version of the Prelude:

• http://prelude.dhall-lang.org/

For example, you can browse the above Prelude to find the not function hosted here:

• https://ipfs.io/ipfs/QmQ8w5PLcsNz56dMvRtq54vbuPe9cNnCCUXAQp6xLc6Ccx/Prelude/Bool/not

... which has the following contents:

$ curl https://ipfs.io/ipfs/QmQ8w5PLcsNz56dMvRtq54vbuPe9cNnCCUXAQp6xLc6Ccx/Prelude/Bool/not
{-
Flip the value of a `Bool`

Examples:

```
./not True = False

./not False = True
```
-}
let not : Bool → Bool
    =   λ(b : Bool) → b == False

in  not

... and we can "apply" our URL to our file as if they were both just ordinary functions and values:

$ dhall <<< 'https://ipfs.io/ipfs/QmQ8w5PLcsNz56dMvRtq54vbuPe9cNnCCUXAQp6xLc6Ccx/Prelude/Bool/not ./example.dhall'
Bool

False

... or we could use let-expressions to improve readability without changing the result:

    let not = https://ipfs.io/ipfs/QmQ8w5PLcsNz56dMvRtq54vbuPe9cNnCCUXAQp6xLc6Ccx/Prelude/Bool/not

in  let example = ./example.dhall

in  not example

"That's a security vulnerability!", you protest. "You are ... literally ... injecting remote code into your program."

Playing the devil's advocate, I ask you what is wrong with remote code injection

"Well, for starters, if the URL is compromised the attacker can run arbitrary code like ..."

... reading and writing files? Dhall is totally pure and doesn't support any effects at all (besides heating up CPUs ☺).

This brings us full circle back to our original question:

"Why do our programs need to read input and write output?"

Conclusion

Software doesn't have to be so complex if we challenge our assumptions that got us into this mess

These ideas were heavily inspired the following post by Conal Elliot:

• Can functional programming be liberated from the von Neumann paradigm?

... and this post is not about Dhall so much as Conal's vision of an effect-free purely functional future for programming. I believe explicitly reading input and writing output will eventually become low-level implementation details of higher-level languages, analogous to allocating stack registers or managing memory.

</body></html>

by Gabriel Gonzalez (noreply@blogger.com) at October 08, 2017 08:34 PM

e.g. in TeX

When I learned TeX, I was told to not write e.g. something, because TeX would think the period after the “g” ends a sentence, and introduce a wider, inter-sentence space. Instead, I was to write e.g.\␣.

Years later, I learned from a convincing, but since forgotten source, that in fact e.g.\@ is the proper thing to write. I vaguely remembering that e.g.\␣ supposedly affected the inter-word space in some unwanted way. So I did that for many years.

Until I recently was called out for doing it wrong, and that infact e.g.\␣ is the proper way. This was supported by a StackExchange answer written by a LaTeX authority and backed by a reference to documentation. The same question has, however, another answer by another TeX authority, backed by an analysis of the implementation, which concludes that e.g.\@ is proper.

What now? I guess I just have to find it out myself.

The problem and two solutions

The above image shows three variants: The obviously broken version with e.g., and the two contesting variants to fix it. Looks like they yield equal results!

So maybe the difference lies in how \@ and \␣ react when the line length changes, and the word wrapping require differences in the inter-word spacing. Will there be differences? Let’s see;

Expanding whitespace, take 1

Expanding whitespace, take 2

I cannot see any difference. But the inter-sentence whitespace ate most of the expansion. Is there a difference visible if we have only inter-word spacing in the line?

Expanding whitespace, take 3

Expanding whitespace, take 4

Again, I see the same behaviour.

Conclusion: It does not matter, but e.g.\␣ is less hassle when using lhs2tex than e.g.\@ (which has to be escaped as e.g.\@@), so the winner is e.g.\␣!

(Unless you put it in a macro, then \@ might be preferable, and it is still needed between a captial letter and a sentence period.)

by Joachim Breitner (mail@joachim-breitner.de) at October 08, 2017 07:08 PM

Review: Bananas, Lenses, Envelopes and Barbed Wire

<article> <header>

Review: Bananas, Lenses, Envelopes and Barbed Wire

</header>

← <time>October 6, 2017</time>

Today’s classic functional programming paper we will review is Meijer et al.’s Functional Programming with Bananas, Lenses, Envelopes and Barbed Wire. The exciting gist of the paper is that all explicit recursion can be factored out into a few core combinators. As such, the reasoning is that we should instead learn these combinators (or “recursion schemes” as they’re called), rather than doing our own ad-hoc recursion whenever we need it.

Despite being a marvelous paper, it falls into the all-too-common flaw of functional programming papers, which is to have an absolutely horrible title. “Bananas”, “lenses”, “envelopes” and “barbed wire” correspond to obscure pieces of syntax invented to express these ideas. In our treatment of the literature, we will instead use standard Haskell syntax, and refer to the paper as Functional Programming with Recursion Schemes.

Specialized Examples of Recursion Schemes

Catamorphisms over Lists

Catamorphisms refer to a fold over a datastructure. A mnemonic to remember this is that a catamorphism tears down structures, and that if that structure were our civilization it’d be a catastrophe.

By way of example, Meijer et al. present the following specialization of a catamorphism over lists:

Let default :: b and step :: a -> b -> b, then a list-catamorphism h :: [a] -> b if a function of the following form:

h [] = default
h (a : as) = step a (h as)

This definition should look pretty familiar; if you specialize the function foldr to lists, you’ll see it has the type:

foldr :: (a -> b -> b) -> b -> [a] -> b

We can view foldr as taking our values step :: a -> b -> b and default :: b, and then giving back a function that takes an [a] and computes some b. For example, we can write a few of the common prelude functions over lists as catamorphisms of this form.

length :: [a] -> Int
length = foldr (\_ n -> n + 1) 0

filter :: forall a. (a -> Bool) -> [a] -> [a]
filter p = foldr step []
  where
    step :: a -> [a] -> [a]
    step a as = if p a
                   then a : as
                   else as

When written this way – Meijer et al. are quick to point out – the so-called “fusion” law is easily seen:

f . foldr step default = foldr step' default'
  where
    step' a b = step a (f b)
    default'  = f default

which intuitively says that you can “fuse” a catamorphism with a subsequent composition into a single catamorphism.

Anamorphisms over Lists

If a catamorphism refers to a “fold”, an anamorphism corresponds to an unfold of a data structure. A good mnemonic for this is that an anamorphism builds things up, just like anabolic steroids can be an easy way to build up muscle mass.

Meijer et al. present this concept over lists with the following (again, very specialized) definition:

unfoldr :: (b -> Maybe (a, b)) -> b -> [a]

Given a function produce :: b -> Maybe (a, b), a list-anamorphism h :: b -> [a] is defined as:

h seed = case produce seed of
           Just (a, b) = a : h b
           Nothing     = []

As expected, this corresponds to the unfoldr :: (b -> Maybe (a, b)) -> b -> [a] function from Data.List.

By way of example, they provide the following:

zip :: ([a], [b]) -> [(a, b)]
zip = unfoldr produce
  where
    produce (as, bs) =
      if null as || null bs
         then Nothing
         else Just ((head as, head bs), (tail as, tail bs))

and

iterate :: (a -> a) -> a -> [a]
iterate f = unfoldr (\a -> Just (a, f a))

An interesting case is that of map :: (a -> b) -> [a] -> [b]. We note that both the input and output of this function are lists, and thus might suspect the function can be written as either a catamorphism or an anamorphism. And indeed, it can be:

cataMap :: (a -> b) -> [a] -> [b]
cataMap f = foldr (\a bs -> f a : bs) []

anaMap :: (a -> b) -> [a] -> [b]
anaMap f = unfoldr produce
  where
    produce [] = Nothing
    produce (a : as) = Just (f a, as)

Neat!

Hylomorphisms over Lists

A hylomorphism over lists is a recursive function of type a -> b whose call-tree is isomorphic to a list. A hylomorphism turns out to be nothing more than a catamorphism following an anamorphism; the anamorphism builds up the call-tree, and the catamorphism evaluates it.

An easy example of hylomorphisms is the factorial function, which can be naively (ie. without recursion schemes) implemented as follows:

fact :: Int -> Int
fact 0 = 1
fact n = n * fact (n - 1)

When presented like this, it’s clear that fact will be called a linear number of times in a tail-recursive fashion. That sounds a lot like a list to me, and indeed we can implement fact as a hylomorphism:

fact :: Int -> Int
fact = foldr (*) 1 . unfoldr (\n -> if n == 0
                                       then Nothing
                                       else Just (n, n - 1))

The hylomorphic representation of fact works by unfolding its argument n into a list [n, n-1 .. 1], and then folding that list by multiplying every element in it.

However, as Meijer et al. point out, this implementation of fact is a little unsatisfactory. Recall that the natural numbers are themselves an inductive type (data Nat = Zero | Succ Nat), however, according to the paper, there is no easy catamorphism (nor anamorphism) that implements fact.

Paramorphisms

Enter paramorphisms: intuitively catamorphisms that have access to the current state of the structure-being-torn-down. Meijer et al.:

[Let init :: b and merge :: Nat -> b -> b. ] For type Nat, a paramorphism is a function h :: Nat -> b of the form:

h Zero = init
h (Succ n) = merge n (h n)

As far as I can tell, there is no function in the Haskell standard library that corresponds to this function-as-specialized, so we will write it ourselves:

paraNat :: (Nat -> b -> b) -> b -> Nat -> b
paraNat _ init Zero = init
paraNat merge init (Succ n) = merge n (paraNat merge init n)

We can thus write fact :: Nat -> Nat as a paramorphism:

fact :: Nat -> Nat
fact = paraNat (\n acc -> (1 + n) * acc) 1

Similarly, we can define paramorphisms over lists via the function:

paraList :: (a -> [a] -> b -> b) -> b -> [a] -> b
paraList _ init [] = init
paraList merge init (a : as) = merge a as (paraList merge init as)

with which we can write the function tails :: [a] -> [[a]]:

tails :: forall a. [a] -> [[a]]
tails = paraList merge []
  where
    merge :: a -> [a] -> [[a]] -> [[a]]
    merge a as ass = (a : as) : ass

General Recursion Schemes

Intuition

As you’ve probably guessed, the reason we’ve been talking so much about these recursion schemes is that they generalize to all recursive data types. The trick, of course, is all in the representation.

Recall the standard definition of list:

data List a = Nil
            | Cons a (List a)

However, there’s no reason we need the explicit recursion in the Cons data structure. Consider instead, an alternative, “fixable” representation:

data List' a x = Nil'
               | Cons' a x

If we were somehow able to convince the typesystem to unify x ~ List' a x, we’d get the type List' a (List' a (List' a ...)), which is obviously isomorphic to List a. We’ll look at how to unify this in a second, but a more pressing question is “why would we want to express a list this way?”.

It’s a good question, and the answer is we’d want to do this because List' a x is obviously a functor in x. Furthermore, in general, any datastructure we perform this transformation on will be a functor in its previously-recursive x parameter.

We’re left only more curious, however. What good is it to us if List' a x is a functor in x? It means that we can replace x with some other type b which is not isomorphic to List a. If you squint and play a little loose with the type isomorphisms, this specializes fmap :: (x -> b) -> List' a x -> List' a b to (List a -> b) -> List' a x -> List' a b.

Notice the List a -> b part of this function – that’s a fold of a List a into a b! Unfortunately we’re still left with a List' a b, but this turns out to be a problem only in our handwaving of x ~ List' a x, and the actual technique will in fact give us just a b at the end of the day.

Algebras

An f-algebra is a function of type forall z. f z -> z, which intuitively removes the structure of an f. If you think about it, this is spiritually what a fold does; it removes some structure as it reduces to some value.

As it happens, the type of an f-algebra is identical to the parameters required by a catamorphism. Let’s look at List' a-algebras and see how the correspond with our previous examples of catamorphisms.

length :: [a] -> Int
length = foldr (\_ n -> n + 1) 0

lengthAlgebra :: List' a Int -> Int
lengthAlgebra Nil'        = 0
lengthAlgebra (Cons' _ n) = n + 1

filter :: forall a. (a -> Bool) -> List a -> List a
filter p = foldr step Nil
  where
    step a as =
      if p a
         then Cons a as
         else as

filterAlgebra :: (a -> Bool) -> List' a (List a) -> (List a)
filterAlgebra _  Nil'        = Nil
filterAlgebra p (Cons' a as) =
  if p a
    then Cons a as
    else as

Coalgebras

f-algebras correspond succinctly to the parameters of catamorphisms over fs. Since catamorphisms are dual to anamorphisms, we should expect that by turning around an algebra we might get a representation of the anamorphism parameters.

And we’d be right. Such a thing is called an f-coalgebra of type forall z. z -> f z, and corresponds exactly to these parameters. Let’s look at our previous examples of anamorphisms through this lens:

zip :: (List a, List b) -> List (a, b)
zip = unfoldr produce
  where
    produce (as, bs) =
      if null as || null bs
         then Nothing
         else Just ((head as, head bs), (tail as, tail bs))

zipCoalgebra :: ([a], [b]) -> List' (a, b) ([a], [b])
zipCoalgebra (as, bs) =
  if null as || null bs
     then Nil'
     else Cons (head as, head bs) (tail as, tail bs)

iterate :: (a -> a) -> a -> [a]
iterate f = unfoldr (\a -> Just (a, f a))

iterateAlgebra :: (a -> a) -> a -> List' a a
iterateAlgebra f a = Cons a (f a)

You might have noticed that these coalgebras don’t line up as nicely as the algebras did, due namely to the produce functions returning a type of Maybe (a, b), while the coalgebras return a List' a b. Of course, these types are isomorphic (Nothing <=> Nil', Just (a, b) <=> Cons a b), it’s just that the authors of unfoldr didn’t have our List' functor to play with.

From Algebras to Catamorphisms

As we have seen, f-algebras correspond exactly to the parameters of a catamorphism over an f. But how can we actually implement the catamorphism? We’re almost there, but first we need some machinery.

type family Fixable t :: * -> *

The type family Fixable takes a type to its fixable functor representation. For example, we can use it to connect our List a type to List' a:

type instance Fixable (List a) = List' a

Now, assuming we have a function toFixable :: t -> Fixable t t, which for lists looks like this:

toFixable :: List a -> Fixable (List a) (List a)
-- equivalently: toFixable :: List a -> List' a (List a)
toFixable Nil         = Nil'
toFixable (Cons a as) = Cons' a as

We can now write our catamorphism!

cata :: (Fixable t z -> z) -> (t -> z)
cata algebra = algebra
             . fmap (cata algebra)
             . toFixable

Very cool. What we’ve built here is general machinery for tearing down any inductive data structure t. All we need to do it is its Fixable t representation, and a function project :: t -> Fixable t t. These definitions turn out to be completely mechanical, and thankfully, can be automatically derived for you via the recursion-schemes package.

Coalgebras and Catamorphisms

We can turn all of our machinery around in order to implement anamorphisms. We’ll present this material quickly without much commentary, since there are no new insights here.

Given fromFixable :: Fixable t t -> t, we can implement ana:

ana :: (z -> Fixable t z) -> z -> t
ana coalgebra = fromFixable
              . fmap (ana coalgebra)
              . coalgebra

General Paramorphisms

Because there is nothing interesting about hylomorphisms when viewed via our Fixable machinery, we skip directly to paramorphisms.

Recall that a paramorphism is a fold that has access to both the accumulated value being constructed as well as the remainder of the structure at any given point in time. We can represent such a thing “algebraically:” Fixable t (t, z) -> z. With a minor tweak to cata, we can get para:

para :: (Fixable t (t, z) -> z) -> t -> z
para alg = teardown
  where
    teardown = alg
             . fmap (\t -> (t, teardown t))
             . toFixable

Miscellaneous Findings

All Injective Functions are Catamorphisms

Meijer et al. make the somewhat-unsubstantiated claim that all injective functions are catamorphisms. We will reproduce their proof here, and then work through it to convince ourselves of its correctness.

Let f :: A -> B be a strict function with left-inverse g. Then for any φ :: F A -> A, we have:

g . f = id

f . cata φ = cata (f . φ . fmap g)

Taking `φ = fromFixable$ we immediately get that any strict injective function can be written as a catamorphism:

f = cata (f . fromFixable . fmap g)

Sounds, good? I guess? Meijer et al. must think I’m very smart, because it took me about a week of bashing my head against this proof before I got it. There were two stumbling blocks for me which we’ll tackle together.

To jog our memories, we’ll look again at the definition of cata:

cata φ = φ . fmap (cata φ) . toFixable

There are two claims we need to tackle here, the first of which is that given φ = fromFixable:

f . cata φ = cata (f . φ . fmap g)

We can show this by mathematical induction. We’ll first prove the base case, by analysis of the [] case over list-algebras.

  cata (f . φ . fmap g) []
  -- definition of cata
= f . φ . fmap g . fmap (cata (f . φ . fmap g)) $ toFixable []
  -- definition of toFixable
= f . φ . fmap g . fmap (cata (f . φ . fmap g)) $ NilF
  -- fmap fusion
= f . φ . fmap (g . cata (f . φ . fmap g)) $ NilF
  -- NilF is a constant functor
= f . φ $ NilF
  -- substitute φ = fromFixable
= f $ fromFixable NilF
  -- definition of fromFixable
= f []

Great! That’s the base case tackled. It’s easy to see why this generalizes away from lists to any data structure; the only way to terminate the recursion of a cata is for one of the type’s data constructors to not be recursive (such as Nil). If the data constructor isn’t recursive, its Fixable representation must be a constant functor, and thus the final fmap will always fizzle itself out.

Let’s tackle the inductive case now. We’ll look at cases of cata that don’t fizzle out immediately:

  cata (f . φ . fmap g)
  -- definition of cata
= f . φ . fmap g . fmap (cata (f . φ . fmap g)) . toFixable
  -- fmap fusion
= f . φ . fmap (g . cata (f . φ . fmap g)) . toFixable
  -- definition of cata
= f . φ . fmap (g . f . φ . fmap g . fmap (cata (f . φ . fmap g)) . toFixable) . toFixable
  -- fmap fusion
= f . φ . fmap (g . f . φ . fmap (g . cata (f . φ . fmap g)) . toFixable) . toFixable
  -- g . f = id
= f . φ . fmap (id . φ . fmap (g . cata (f . φ . fmap g)) . toFixable) . toFixable
  -- definition of id
= f . φ . fmap (φ . fmap (g . cata (f . φ . fmap g)) . toFixable) . toFixable

As you can see here, subsequent expansions of cata line their gs and fs up in such a way that they cancel out. Also, we know from our experience looking at the base case that the final g will always sizzle out, and so we don’t need to worry about it only being a left-inverse.

The other stumbling block for me was that cata fromFixable = id, but this turns out to be trivial:

  cata fromFixable
= fromFixable . fmap (cata fromFixable) . toFixable

Eventually this will all bottom out when it hits the constant functor, which will give us a giant chain of fromFixable . toFixables, which is obviously id.

To circle back to our original claim that all injective functions are catamorphisms, we’re now ready to tackle it for real.

f . cata φ           = cata (f . φ . fmap g)
f . cata fromFixable = cata (f . fromFixable . fmap g)
f . id               = cata (f . fromFixable . fmap g)
f                    = cata (f . fromFixable . fmap g)

\(\blacksquare\)

All Surjective Functions are Anamorphisms

Anamorphisms are dual to catamorphisms, and surjective functions are dual (in \(\mathbb{Set}\)) to injective functions. Therefore, we can get this proof via duality from the proof that injective functions are catamorphisms. \(\blacksquare\)

Closing Remarks

Functional Programming with Recursion Schemes has some other (in my opinion) minor contributions about this stuff, such as how catamorphisms preserve strictness, but I feel like we’ve tackled the most interesting pieces of it. It is my hope that this review will serve as a useful complement in understanding the original paper.

←

</article>

October 06, 2017 12:00 AM

Comparing Persistent with Ecto and ActiveRecord

Rejected title: You’re not special

I saw this article comparing Ecto and ActiveRecord: https://www.dailydrip.com/blog/ecto-vs-activerecord.html

I thought I would track alongside that post and show what the equivalent code looks like if you’re using the Persistent Haskell library.

Some examples from their side-by-side comparison

I’ll start by simply translating some small, simple examples linked to at the beginning of their article.

Get all records

ActiveRecord

Model.all

Ecto

Repo.all(App.Model)

Persistent

getAllUsers :: DB [Entity User]
getAllUsers = selectList [] []

Search by name

ActiveRecord

Model.find_by(name: name)

Ecto

Repo.one(from t in App.Model, where: t.name == ^name, limit: 1)

Persistent

getFirstUserByEmail :: Text -> DB (Maybe (Entity User))
getFirstUserByEmail email =
  selectFirst [UserEmail ==. email] []

Fetch a single record based on id=1

ActiveRecord

Model.find(1)

Ecto

Model |> Repo.get!(1)

Persistent

getIdOneUser :: DB (Maybe (Entity User))
getIdOneUser = getEntity (toSqlKey 1)

Comparing against the rest of the article

I’ll do my usual thing and cite what the original article said, then reply with either code or prose.

Let’s talk about the main ideas behind Ecto, and try to compare it with ActiveRecord.

Main difference ActiveRecord: We can represent data using: behaviors + state.

Ecto: We need to represent data using: functions.

It’s just functions and data in Haskell too.

Active Record pattern ActiveRecord has a general pattern of accessing data used in Object-oriented languages. So, this is not specfically the Active Record pattern.

Using ActiveRecord, we can do:

artist = Artist.get(1)
artist.name = "Name"
artist.save

This makes a lot of sense for Object-Oriented languages. Data has behavior and state. This is pretty straightforward. How does Ecto handle that?

Repository Pattern

As a functional language we don’t have data with state, nor do we have behavior. We only have functions.

In general, if you want to talk with the database, you need to talk with the Repository first.

artist = Repo.get(Artist, 1)
changeset = Artist.changeset(artist, name: "Changed name")
Repo.update(changeset)

If we check side-by-side what Active Record and repository does, we cannot see when Active Record touches the Database. We just do a save and it hits the database implicitly. In Ecto, you always interact with the database explicitly.

Ecto will not talk to the database without you asking it to. Everything is totally explicit. Any interaction with the database should pass through the Repository.

This is true of Haskell too, it only talks to the database when you ask it to. Most people have a function named runDB or similar which makes it easy to audit what code actually talks to the database. It also serves to tell you where your transaction boundaries are which is tremendously helpful for atomicity and correctly using your SQL database. Here’s the name-changing example above in Haskell:

updateFirstUserName :: Text -> DB ()
updateFirstUserName newName = do
  update (toSqlKey 1) [UserName =. newName]

If you wanted something that could do the same for any primary key:

updateFirstUserName' :: Key User -> Text -> DB ()
updateFirstUserName' userKey newName = do
  update userKey [UserName =. newName]

updateFirstUserName :: Text -> DB ()
updateFirstUserName = updateFirstUserName' (toSqlKey 1)

Schema

Schema is normally a map between your types and your database. But not necessarily.

If we check the documentation:

An Ecto schema is used to map any data source into an Elixir struct. One of such use cases is to map data coming from a repository, usually a table, into Elixir structs. An interesting thing to mention is that we don’t need a schema for using Ecto. We can bypass the use of Schemas by using the table name as a string. Schemas are very flexible.

Here is an example of Schema definition in Ecto.

defmodule SlackPosting.Journals.Post do
  use Ecto.Schema
  import Ecto.Changeset
  alias SlackPosting.Journals.Post

  schema "posts" do
    field :user_slack_id, :string
    field :user_name, :string
    field :text, :string
    many_to_many :tags, SlackPosting.Journals.Tag, join_through: SlackPosting.Journals.PostTag
    has_many :comments, SlackPosting.Journals.Comment

    timestamps()
  end

  @doc false
  def changeset(%Post{} = post, attrs) do
    post
    |> cast(attrs, [:text, :user_slack_id, :user_name])
    |> validate_required([:text, :user_slack_id])
  end
end

Then in Persistent, with a little more of the mentioned tables fleshed out:

share [mkPersist sqlSettings, mkMigrate "migrateAll"] [persistLowerCase|
Post
  userSlackId Text
  userName Text
  someText Text
  someOtherText Text
  deriving Show

Comment
  comment Text
  post PostId
  deriving Show
  
Tag
  tagName Text

PostTags
  tag TagId
  post PostId
|]

Migrations

Migrations Ecto also has migrations. This is not really different from what ActiveRecord offers to us.

defmodule SlackPosting.Repo.Migrations.CreatePosts do
  use Ecto.Migration

  def change do
    create table(:posts) do
      add :text, :text
      add :user_slack_id, :string
      add :user_name, :string

      timestamps()
    end

  end
end

Persistent does too, but approaches it differently by focusing on generating fresh and differential migrations against the database rather than creating a migration DSL. The macros generate the code necessary to see what migrations it recommends or to run the migrations directly automatically. The usual runDB function for running a database action against the database works for this.

dumpMigration :: DB ()
dumpMigration = printMigration migrateAll

runMigrations :: DB ()
runMigrations = runMigration migrateAll

If we were to dump the post/comment/tag schema from earlier for SQLite, the migration would look like:

CREATE TABLE "post"("id" INTEGER PRIMARY KEY,"user_slack_id" VARCHAR NOT NULL,"user_name" VARCHAR NOT NULL,"some_text" VARCHAR NOT NULL,"some_other_text" VARCHAR NOT NULL);

CREATE TABLE "comment"("id" INTEGER PRIMARY KEY,"comment" VARCHAR NOT NULL,"post" INTEGER NOT NULL REFERENCES "post");

CREATE TABLE "tag"("id" INTEGER PRIMARY KEY,"tag_name" VARCHAR NOT NULL);

CREATE TABLE "post_tags"("id" INTEGER PRIMARY KEY,"tag" INTEGER NOT NULL REFERENCES "tag","post" INTEGER NOT NULL REFERENCES "post");

Changeset

I have no idea what this is about and their post doesn’t make it clearer. Validation is orthogonal to Persistent, you usually validate stuff at the edges so that any value of type MyModel is only ever a valid value for that database table.

Associations

We covered this a little earlier with the Post/Comment/Tag example but I’ll explain a little:

Comment
  comment Text
  post PostId
  deriving Show

Tag
  tagName Text

PostTags
  tag TagId
  post PostId

You can reference the primary key column of a model defined elsewhere in the quasiquoter, so TagId is something the code understands is primary key of the Tag table. From there, it’s able to generate the foreign key relationships in the migrations automatically. It also gives you better type-safety with managing keys:

Prelude> :t Comment
Comment :: Text -> Key Post -> Comment
Prelude> let tagKey :: Key Tag; tagKey = toSqlKey 1
Prelude> Comment "my comment" tagKey

<interactive>:12:22: error:
    • Couldn't match type ‘Tag’ with ‘Post’
      Expected type: Key Post
        Actual type: Key Tag
    • In the second argument of ‘Comment’, namely ‘tagKey’
      In the expression: Comment "my comment" tagKey
      In an equation for ‘it’: it = Comment "my comment" tagKey

When our keys aren’t just strings or numbers, we can avoid a lot of unnecessary mistakes!

Lazy loading

Ecto does not support Lazy Loading.

Persistent doesn’t either. If you want to pull related data together you can do so via separate database actions in a transaction or you can use Esqueleto to do in so:

def list_posts do
    Repo.all(Post)
    |> Repo.preload([:comments, :tags])
end

Here’s a somewhat serious (this is modeled after some production code I wrote) example of how to do this with Esqueleto on top of Persistent, by returning a mapping of posts, the comments on the posts, and all tags associated with the posts.

tagsForPosts :: [Key Post] -> DB [(Key Post, Entity Tag)]
tagsForPosts postKeys =
  unValueThePostKeys $
  select $
  from $ \ ( postTag `InnerJoin` tag ) -> do
    on (tag ^. TagId
        E.==. postTag ^. PostTagTag)
    where_ (postTag ^. PostTagPost
            `in_` valList postKeys)
    return (postTag ^. PostTagPost, tag)
  where unValueThePostKeys :: DB [(E.Value (Key Post), Entity Tag)]
                           -> DB [(Key Post, Entity Tag)]
        unValueThePostKeys = (fmap . fmap) (first E.unValue)

postsWithCommentsAndTags :: DB (Map
                                (Key Post)
                                (Entity Post, [Entity Comment], [Entity Tag]))
postsWithCommentsAndTags = do
  postsAndComments <- posts
  let postKeys = fmap (entityKey . fst) postsAndComments
  postKeysWithTags <- tagsForPosts postKeys
  let initialMap = postsInitialMap postsAndComments
      postsWithTags = addTagsToMap postKeysWithTags initialMap
  return postsWithTags
  where
    posts =
      select $
      from $ \ ( post
                 `InnerJoin`
                 comment ) -> do
        on (post ^. PostId
            E.==. (comment ^. CommentPost))
        return (post, comment)

    postsInitialMap :: [(Entity Post, Entity Comment)]
                    -> Map (Key Post) (Entity Post, [Entity Comment], [Entity Tag])
    postsInitialMap postsAndComments =
      foldl' insertPostCom M.empty postsAndComments
      where insertPostCom m (post, comment) =
              M.insertWith
              (\ _ (post, comments, tags) -> (post, comment : comments, tags))
              (entityKey post) (post, [comment], []) m

    addTagsToMap :: [(Key Post, Entity Tag)]
                 -> Map (Key Post) (Entity Post, [Entity Comment], [Entity Tag])
                 -> Map (Key Post) (Entity Post, [Entity Comment], [Entity Tag])
    addTagsToMap postKeysTags initialMap =
      foldl' insertPostKeyTag initialMap postKeysTags
      where insertPostKeyTag :: Map (Key Post)
                                (Entity Post, [Entity Comment], [Entity Tag])
                             -> (Key Post, Entity Tag)
                             -> Map (Key Post)
                                (Entity Post, [Entity Comment], [Entity Tag])
            insertPostKeyTag m (postKey, tagEntity) =
              M.adjust
              (\(post, comment, tags) ->
                  (post, comment, tagEntity : tags))
              postKey
              m

Then running this code with some test data:

migrateFixturesTest :: IO ()
migrateFixturesTest = do
  runDB $ do
    runMigrations
    pk1 <- insert $ Post "slack1" "name1" "" ""
    pk2 <- insert $ Post "slack2" "name2" "" ""
    pk3 <- insert $ Post "slack2" "name3" "" ""
    _ <- insert $ Comment "pk1 c1" pk1
    _ <- insert $ Comment "pk1 c2" pk1
    _ <- insert $ Comment "pk2 c3" pk2
    tg1 <- insert $ Tag "tag1"
    ptg1 <- insert $ PostTag tg1 pk1
    pwcat <- postsWithCommentsAndTags
    liftIO $ pPrint pwcat

We get the following output, which looks right!

Prelude> migrateFixturesTest 
Migrating: CREATE TABLE "post"("id" INTEGER PRIMARY KEY,"user_slack_id" VARCHAR NOT NULL,"user_name" VARCHAR NOT NULL,"some_text" VARCHAR NOT NULL,"some_other_text" VARCHAR NOT NULL)
Migrating: CREATE TABLE "comment"("id" INTEGER PRIMARY KEY,"comment" VARCHAR NOT NULL,"post" INTEGER NOT NULL REFERENCES "post")
Migrating: CREATE TABLE "tag"("id" INTEGER PRIMARY KEY,"tag_name" VARCHAR NOT NULL)
Migrating: CREATE TABLE "post_tag"("id" INTEGER PRIMARY KEY,"tag" INTEGER NOT NULL REFERENCES "tag","post" INTEGER NOT NULL REFERENCES "post")
fromList
  [ ( PostKey { unPostKey = SqlBackendKey { unSqlBackendKey = 1 } }
    , ( Entity
          { entityKey =
              PostKey { unPostKey = SqlBackendKey { unSqlBackendKey = 1 } }
          , entityVal =
              Post
                { postUserSlackId = "slack1"
                , postUserName = "name1"
                , postSomeText = ""
                , postSomeOtherText = ""
                }
          }
      , [ Entity
            { entityKey =
                CommentKey { unCommentKey = SqlBackendKey { unSqlBackendKey = 2 } }
            , entityVal =
                Comment
                  { commentComment = "pk1 c2"
                  , commentPost =
                      PostKey { unPostKey = SqlBackendKey { unSqlBackendKey = 1 } }
                  }
            }
        , Entity
            { entityKey =
                CommentKey { unCommentKey = SqlBackendKey { unSqlBackendKey = 1 } }
            , entityVal =
                Comment
                  { commentComment = "pk1 c1"
                  , commentPost =
                      PostKey { unPostKey = SqlBackendKey { unSqlBackendKey = 1 } }
                  }
            }
        ]
      , [ Entity
            { entityKey =
                TagKey { unTagKey = SqlBackendKey { unSqlBackendKey = 1 } }
            , entityVal = Tag { tagTagName = "tag1" }
            }
        ]
      )
    )
  , ( PostKey { unPostKey = SqlBackendKey { unSqlBackendKey = 2 } }
    , ( Entity
          { entityKey =
              PostKey { unPostKey = SqlBackendKey { unSqlBackendKey = 2 } }
          , entityVal =
              Post
                { postUserSlackId = "slack2"
                , postUserName = "name2"
                , postSomeText = ""
                , postSomeOtherText = ""
                }
          }
      , [ Entity
            { entityKey =
                CommentKey { unCommentKey = SqlBackendKey { unSqlBackendKey = 3 } }
            , entityVal =
                Comment
                  { commentComment = "pk2 c3"
                  , commentPost =
                      PostKey { unPostKey = SqlBackendKey { unSqlBackendKey = 2 } }
                  }
            }
        ]
      , []
      )
    )
  ]

This stuff could get abstracted away or code-gen’d but I haven’t had cause to bother yet. Incidentally, this happens to be a decent example of how to pull together data associated by one-to-many and many-to-many relationships using Esqueleto and Persistent.

If you’d like a working, running git repository of what I did in this article, take a look here.

Some relevant libraries:

• Persistent
• Persistent SQLite
• Persistent code-gen
• Esqueleto, has the ability to perform joins and otherwise compose relational queries, whereas Persistent is limited to basic CRUD.
• pretty-show has a nice pretty printer I used in my code.

I know this site is a bit of a disaster zone, but if you like my writing or think you could learn something useful from me, please take a look at the Haskell book I've been writing. There's a free sample available too!

Posted on October 6, 2017

October 06, 2017 12:00 AM

Type-safe enums in C, using a clang plugin

The C programming language generally treats enums as integers (see “Appendix: For Language Lawyers” for reference).

Wouldn’t it be nice if we could do more with enums, and do it safely?

Some other languages have anything from integer-incompatible enums to full-blown sum types. It would be nice to have something like that in C.

I wrote the enums_conversion clang plugin aiming to do just that, by treating enums as incompatible with integers (except via explicit casting).

A motivating example

Some people are surprised at the goals of this plugin. Here is a simple example to explain the motivation.

Consider the following (totally fabricated) API:

enum OpGetResult {
    OP_GET_ERROR,
    OP_GET_OK,
};

enum OpGetResult get_items(void);

/* Implementation: */

enum OpGetResult get_items(void)
{
    /* ... do something with side effects ... */
    return OP_GET_OK;
}

So far so good. Safe it as test.c and compile this program with gcc:

gcc -std=c11 -Wall -Wextra -Werror -c test.c

No errors, yay!

A simple bug

Now, let’s introduce a bug. Someone decided the API is no good, and get_items should just return the number of items it “got”. So the new API is:

/* This enum is in use elsewhere... */
enum OpGetResult {
    OP_GET_ERROR,
    OP_GET_OK,
};

int get_items(void); /* return value changed to 'int' */

/* Implementation: */

int get_items(void)
{
    /* ... do something with side effects ... */
    return OP_GET_OK; /* oops! forgot to change this */
}

The bug is that get_items still returns the enum value OP_GET_OK instead of a number.

Save as test2.c and compile (tested on gcc 6.3.0):

gcc -std=c11 -Wall -Wextra -Werror -c test2.c

Oh no! No error! Let’s try with clang 5.0 and the wonderful -Weverything which enables all warnings:

clang -std=c11 -Weverything -Werror  -c test2.c

Nope! Still no error.

The compilers are ok with this code because it’s allowed. However, it’s clearly not what we intended.

A bunch of other possible bugs

Here is a snippet with different ‘bad code’ examples: (for testing it can be appended to one of the previous files)

int func(enum OpGetResult e, unsigned int x, unsigned int y);
int func(enum OpGetResult e, unsigned int x, unsigned int y)
{
  handle_result(x); /* passing arbitrary integer where one of several enum values was expected */

  enum OpGetResult e2 = x; /* assigning from arbitrary integer (which may not be a valid enum value) */

  if (e2 == y) { /* comparing enum to arbitrary integer */
  }

  return e; /* returning enum where arbitrary integer is expected by caller */
}

Neither gcc 6.3.0 nor clang 5.0 emit any kind of warning about the above code.

# Let's try gcc with some extra warnings:
gcc -std=c11 -Wall -Wextra -Werror -Wconversion -Wenum-compare -Wswitch-enum -Wsign-conversion  -c test2.c

# clang with -Weverything:
clang -std=c11 -Weverything -Werror  -c test2.c

clang plugin to the rescue

The enums_converesion clang plugin detects and warns about all of the above.

# clang -std=c11 -Weverything  -c test2.c -Xclang -load -Xclang ./clang_plugins.so -Xclang -add-plugin -Xclang enums_conversion
test2.c:22:23: error: enum conversion to or from enum OpGetResult
        handle_result(x); /* passing arbitrary integer where one of several enum values was expected */
                      ^
test2.c:24:31: error: enum conversion to or from enum OpGetResult
        enum OpGetResult e2 = x; /* assigning from arbitrary integer (which may not be a valid enum value) */
                              ^
test2.c:26:13: error: enum conversion to or from enum OpGetResult
        if (e2 == y) { /* comparing enum to arbitrary integer */
            ^
test2.c:29:16: error: enum conversion to or from enum OpGetResult
        return e; /* returning enum where arbitrary integer is expected by caller */
               ^
4 errors generated.

Frequently Asked Questions

1. But this isn’t standard C!

Correct, it is a restrictive subset of C. Some “valid” C programs will be flagged by this plugin. I believe writing code in the spirit of this plugin will improve your code’s readability while preventing a class of bugs from ever occurring.

2. How is this different from gcc’s -Wenum-compare?

The warning flag -Wenum-compare find comparisons between different enums, but does not look at comparing enums to integers, implicit casting to/from integers, etc. In the following program only the second if is flagged by -Wenum-compare:

enum A { A_FIRST, A_SECOND };
enum B { B_FIRST, B_SECOND };

int foo(enum A a, unsigned int x);
int foo(enum A a, unsigned int x) {
      if (x == a) { // no warning emitted
          return 1;
      }
      if (B_FIRST == a) { // will cause warning: comparison between ‘enum B’ and ‘enum A’
          return 2;
      }
      return 0;
}

3. How is this different from clang’s -Wenum-conversion?

-Wenum-conversion doesn’t catch implicit casts to/from integral types (the plugin does).

-Wenum-conversion does catch conversion from one enum type to another, like so:

enum EnumA { E_A };
enum EnumB { E_B };
enum EnumA do_something(void) {
    return E_B;
}

4. What about enums being used as combinable bits? Won’t the plugin disallow them?

A common pattern is using an enum to describe the allowed bits for an “options” value that can be ORed together. For example:

enum Flags {
    FLAG_NONE = 0,
    FLAG_READ = 1,
    FLAG_WRITE = 2,
};
enum Flags do_something(void);
enum Flags do_something(void) {
    return FLAG_WRITE | FLAG_READ;
}

The plugin is OK with this. clang -Weverything doesn’t like this (-Wassign-enum):

clang -std=c11 -c /tmp/test.c -Weverything
/tmp/test.c:8:12: warning: integer constant not in range of enumerated type 'enum Flags' [-Wassign-enum]
    return FLAG_WRITE | FLAG_READ;
           ^
1 warning generated.

That’s a false error (if you use | with a runtime variable, -Wassign-enum seems to not flag this). However, the plugin does catch errors of putting an invalid value in the OR expression:

...
return FLAG_WRITE | 5;

Now clang -Weverything doesn’t complain (despite the possible bug).

Running with the plugin gives:

/tmp/test.c:10:16: error: enum conversion to or from enum Flags
        return FLAG_WRITE | 5;

5. I’m afraid to use this in production.

The plugin only analyzes the AST produced by clang, and does not affect the emitted code in any way.

6. I don’t use clang! Can I benefit from this plugin?

At elastifile, the plugin is being used as part of the CI process. Code that is being merged into master must pass the plugin’s checks (as well as other plugins from this suite). The actual production executable is built by gcc (for various unrelated reasons).

The plugin is available as part of the elfs-clang-plugins suite github.

Appendix: For Language Lawyers

The C11 standard (draft) says:

An enumeration comprises a set of named integer constant values. Each distinct enumeration constitutes a different enumerated type. The type char, the signed and unsigned integer types, and the enumerated types are collectively called integer types…

by sinelaw at October 05, 2017 07:10 PM

How to compose streaming programs

Facundo Domínguez

In our first blog post about streaming, we discussed how streaming libraries strengthen types to catch more errors. However, when we strengthen types, we need to be careful to not hinder program composition. After all, precise type information can make it more onerous to convince the compiler that a particular program is well formed. In this post, we show that streaming libraries handle this issue well, as they allow programs to be composed conveniently. To illustrate this point, we will discuss the most important composition forms for streaming programs and illustrate the explained concepts at the example of four concrete streaming libraries, namely pipes, conduit, streaming, and io-stream. This ensures that the discussed concepts are of a general nature and not specific to just one particular library.

Composition forms

Generally speaking, streaming libraries offer two flavors of composition: appending and pipelining. When appending, the values produced by one program are being followed by the values produced by another. When pipelining, some values produced by one streaming program are processed by another while the first program still has more values to produce.

Different libraries implement these forms of composition in different ways. Some streaming libraries have a first-class notion of stream processors, not streams. Generally, a stream processor SP i o m r gets a stream of values of type i, yields a stream of values of type o, and finally yields a value of type r when it terminates. The parameter m represents the monad in which the effects of the processors are sequenced. For example, we have,

conduit:    ConduitM i o m r
pipes:      Pipe i o m r

pipes and conduit define the monad bind operation (>>=) as an appending composition. In p >>= \r -> q, the input stream is first passed to p, and when p completes the unconsumed elements from the input stream are passed to q. As a result, the output stream of p is followed by the output stream of q.

In contrast to pipes and conduit, the streaming and io-stream packages manipulate streams directly. Consequently, there is no notion of an input stream. Still, monadic composition works in a similar manner in the case of the streaming package. The stream p >>= \r -> q starts with the output stream of values produced by p, followed by the output stream of values produced by q. The involved types are

streaming:  Stream (Of a) m r
io-streams: InputStream a

Values of type Stream (Of a) m r are streams of values of type a, which might be produced by performing effectful computations in the monad m. When there are no more elements of type a, a value of type r is produced. Values of type InputStream a are also streams of values of type a, and values might be produced by performing computations in the monad IO.

Although the package io-stream does not define a monad instance (and hence, does not overload (>>=)) for InputStream, it provides a separate function for the purpose of concatenating streams:

appendInputStream :: InputStream a -> InputStream a -> IO (InputStream a)

The second form of composition, namely pipelining, is realised by the following two combinators in the libraries based on stream processors:

conduit:    (.|)  :: Monad m => ConduitM a b m () -> ConduitM b c m r -> ConduitM a c m r
pipes:      (>->) :: Monad m => Pipe a b m r      -> Pipe b c m r     -> Pipe a c m r

In p .| q, the output stream of p is fed into q as its input stream and so it happens with p >-> q as well. But there is a difference in the types of the left operand. In conduit, the left operand yields () when it terminates. The right operand is free to continue producing values in the output stream for as long as it wants. Not so in pipes, where the termination of the left operand produces a value of type r and causes the composition to terminate and yield the same value.

In streaming and io-streams, pipelines are constructed by composing functions which transform streams. For instance

streaming:  map        :: (a -> b) -> Stream (Of a) m r -> Stream (Of b) m r
io-streams: decompress :: InputStream ByteString -> IO (InputStream ByteString)

The function decompress takes an input stream of bytestrings carrying compressed data in the zlib format and outputs a stream of bytestrings carrying the result of decompression.

Leftovers and parsing

Most streaming libraries offer the ability to push back a value from the input. The returned inputs are sometimes called leftovers. This facilitates looking ahead in the input stream to peek at some elements needed to decide on alternative behaviors of the program.

To illustrate the need for looking ahead, consider the following conduit program, which acts as a parser. It yields the number of 'a' characters in the input followed by the number of 'b' characters.

abConduit :: Monad m => Consumer Char m (Int, Int)
abConduit =
    (,) <$> (takeWhileC (== 'a') .| lengthC)
        <*> (takeWhileC (== 'b') .| lengthC)

As conduit implements leftovers, the first takeWhileC can return an element to the input stream upon discovering that it isn't an 'a' character. Then the following takeWhileC has the opportunity to examine that same element again.

However, it is important to note that pipelining composition only allows the left operand to put values back. That is, in p .| q, only p can return values to the input stream; q's leftovers are ignored. This is a constraint stemming from the type of the composition:

(.|) :: Monad m => ConduitM a b m () -> ConduitM b c m r -> ConduitM a c m r

The input stream provides values of type a, but the leftovers of the right operand are of type b. To address this, conduit offers the following composition operator that resolves the type mismatch with a conversion function.

fuseLeftovers :: Monad m => ([b] -> [a]) -> ConduitM a b m () -> ConduitM b c m r -> ConduitM a c m r

In contrast to conduit, the pipes package does not implement leftovers, but there is an additional package pipes-parse, which defines Parsers in terms of the core abstraction of Pipes. Parsers in turn use lenses of the input to return values back. This is what an implementation with pipes-parse looks like for our example.

abPipes :: Monad m => Pipes.Parse.Parser Text m (Int, Int)
abPipes =
   (,) <$> zoom (Pipes.Text.span (== 'a')) lengthP
       <*> zoom (Pipes.Text.span (== 'b')) lengthP

lengthP :: (Monad m, Num n) => Pipes.Parse.Parser Text m n
lengthP =
    Pipes.Parse.foldAll (\n txt -> n + fromIntegral (Text.length txt)) 0 id

The function zoom is a primitive offered by packages implementing lenses. It changes the state of a stateful computation in a given scope, and a lens explains how the state is changed.

zoom :: Monad m => Lens' a b -> StateT b m c -> StateT a m c

In the case of zoom (Pipes.Text.span (== 'a')) p, it changes the input fed to the parser p by only giving the greatest prefix containing 'a's. The rest of the input, even the first character failing the predicate, is left for the next parser.

The parser lengthP is defined to count the amount of characters in the input. Thus

zoom (Pipes.Text.span (== 'a')) lengthP :: Parser Text m Int

stands for the same computation as

takeWhileC (== 'a') .| lengthC :: Consumer Char m Int

Turning our attention to the packages directly manipulating streams, Streams from streaming provide a function cons to push values back into a stream. The package io-streams provides unRead, for the same purpose. While the cons function just constructs a new stream, the function unRead modifies the input stream. We have,

cons   :: Monad m => a -> Stream (Of a) m r -> Stream (Of a) m r
unRead :: a -> InputStream a -> IO ()

More generally, you may wonder, whether streaming libraries should try to do the job of parsers, for which the Haskell ecosystem already provides plenty of alternatives? To answer this question, consider that parsing libraries like parsec or attoparsec do not place any bounds on their memory consumption. In particular, the parsers of neither library return a result value before the entire input has been parsed. For instance, if a parser is parsing a list, it can't yield the first elements of the list as they are discovered. Instead, the list is handed back to the caller only when all of it resides in memory. The attoparsec package is even more problematic, as it retains all of the input, no matter what the parser does.

More sophisticated parsing libraries can do better; e.g., uu-parsinglib. This package, however, returns the parser results lazily and so it is a challenge to test whether specific parts of the result are available without blocking the program. Overall, this means that to parse unbounded streams of input in a bounded amount of memory, we do actually require the streaming libraries to provides the discussed parser functionality. After all, they provide a crucial resource usage guarantee that we cannot obtain from conventional parser libraries.

Folds and non-linear uses of streams

Finally, we need to discuss reductions, where we consume a stream to compute a non-stream result. For example, consider the following naive and incorrect attempt at computing the average of a stream of values:

average0 :: Stream (Of Double) IO () -> IO Double
average0 xs = (/) <$> Streaming.Prelude.sum_ xs
                  <*> (fromIntegral <$> Streaming.Prelude.length_ xs)

The problem with this program is that the same stream is traversed twice. Even if the stream is not effectful, this program does not run in bounded memory. If the stream is, however, effectful, the situation is even worse, as each traversal produces different results leading to an inconsistent computation. To fix these problems, we need to compute the length and the average in a single pass.

average1 :: Stream (Of Double) IO () -> IO Double
average1 xs = uncurry (/) <$>
    Streaming.Prelude.fold_ (\(!s, !c) d -> (s + 1, c + 1)) (0, 0) id xs

With conduit and pipes both the mistake as well as the required fix are similar. Thus, streaming libraries seem to require that the programmer takes care to only consume streaming sources in linear manner, that is, at most once in a program.

Interestingly, conduit offers an alternative solution, where existing stream processors can be reused and combined using ZipSinks instead of explicitly using a fold. A ZipSink is a combination of stream processors, all of which are fed the same input stream, and a final result is produced from the outputs of all the output streams. This results in the following solution to our example, which is quite close to the original naive attempt to solving the problem:

average2 :: Monad m => Consumer Double m Double
average2 = toConsumer $
    getZipSink ((/) <$> ZipSink sumC <*> fmap fromIntegral (ZipSink lengthC))

Facilities, such as this, are one of advantages of libraries based on stream processors as opposed to those manipulating streams directly. ZipSinks are an incarnation of the ideas in the foldl package for stream processors, while the ecosystem of pipes offers the pipes-transduce package.

Summary

While strengthening types to catch more errors, streaming libraries are still sufficiently expressive to allow for many data flow patterns of streaming programs. The basic compositional forms are complemented by additional concepts to cover even more patterns. Leftovers, for instance, support parsing challenges that cannot be easily delegated to standard parsing libraries while still keeping an upper bound on the consumed memory. In turn, ZipSinks simplify the sharing of a single input stream by multiple stream processors.

October 05, 2017 12:00 AM

Metamorphisms

It appears that I have insufficient time, or at least insufficient discipline, to contribute to this blog, except when I am on sabbatical. Which I now am… so let’s see if I can do better.

Hylomorphisms

I don’t think I’ve written about them yet in this series—another story, for another day—but hylomorphisms consist of a fold after an unfold. One very simple example is the factorial function: is the product of the predecessors of . The predecessors can be computed with an unfold:

and the product as a fold:

and then factorial is their composition:

Another example is a tree-based sorting algorithm that resembles Hoare’s quicksort: from the input list, grow a binary search tree, as an unfold, and then flattern that tree back to a sorted list, as a fold. This is a divide-and-conquer algorithm; in general, these can be modelled as unfolding a tree of subproblems by repeatedly dividing the problem, then collecting the solution to the original problem by folding together the solutions to subproblems.

An unfold after a fold

The post is about the opposite composition, an unfold after a fold. Some examples:

• to reformat a list of lists to a given length;
• to sort a list;
• to convert a fraction from base to base ;
• to encode a text in binary by “arithmetic coding”.

In each of these cases, the first phase is a fold, which consumes some structured representation of a value into an intermediate unstructured format, and the second phase is an unfold, which generates a new structured representation. Their composition effects a change of representation, so we call them metamorphisms.

Hylomorphisms always fuse, and one can deforest the intermediate virtual data structure. For example, one need not construct the intermediate list in the factorial function; since each cell gets constructed in the unfold only to be immediately deconstructed in the fold, one can cut to the chase and go straight to the familiar recursive definition. For the base case, we have:

and for non-zero argument , we have:

In contrast, metamorphisms only fuse under certain conditions. However, when they do fuse, they also allow infinite representations to be processed, as we shall see.

Fusion seems to depend on the fold being tail-recursive; that is, a :

For the unfold phase, we will use the usual list unfold:

We define a metamorphism as their composition:

This transforms input of type to output of type : in the first phase, , it consumes all the input into an intermediate value of type ; in the second phase, , it produces all the output.

Streaming

Under certain conditions, it is possible to fuse these two phases—this time, not in order to eliminate an intermediate data structure (after all, the intermediate type need not be structured), but rather in order to allow some production steps to happen before all the consumption steps are complete.

To that end, we define the function as follows:

This takes the same arguments as . It maintains a current state , and produces an output element when it can; and when it can’t produce, it consumes an input element instead. In more detail, it examines the current state using function , which is like the body of an unfold; this may produce a first element of the result and a new state ; when it yields no element, the next element of the input is consumed using function , which is like the body of a ; and when no input remains either, we are done.

The streaming condition for and is that

Consider a state from which the body of the unfold is productive, yielding some . From here we have two choices: we can either produce the output , move to intermediate state , then consume the next input to yield a final state ; or we can consume first to get the intermediate state , and again try to produce. The streaming condition says that this intermediate state will again be productive, and will yield the same output and the same final state . That is, instead of consuming all the inputs first, and then producing all the outputs, it is possible to produce some of the outputs early, without jeopardizing the overall result. Provided that the streaming condition holds for and , then

for all finite lists .

As a simple example, consider the `buffering’ process , where

Note that , so is just a complicated way of writing as a . But the streaming condition holds for and (as you may check), so may be streamed. Operationally, the streaming version of consumes one list from the input list of lists, then peels off and produces its elements one by one; when they have all been delivered, it consumes the next input list, and so on.

Flushing

The streaming version of is actually rather special, because the production steps can always completely exhaust the intermediate state. In contrast, consider the `regrouping’ example where

from the introduction (here, yields where , with when and otherwise). This transforms an input list of lists into an output list of lists, where each output `chunk’ except perhaps the last has length —if the content doesn’t divide up evenly, then the last chunk is short. One might hope to be able to stream , but it doesn’t quite work with the formulation so far. The problem is that is too aggressive, and will produce short chunks when there is still some input to consume. (Indeed, the streaming condition does not for and —why not?) One might try the more cautious producer :

But this never produces a short chunk, and so if the content doesn’t divide up evenly then the last few elements will not be extracted from the intermediate state and will be lost.

We need to combine these two producers somehow: the streaming process should behave cautiously while there is still remaining input, which might influence the next output; but it should then switch to a more aggressive strategy once the input is finished, in order to flush out the contents of the intermediate state. To achieve this, we define a more general flushing stream operator:

This takes an additional argument ; when the cautious producer is unproductive, and there is no remaining input to consume, it uses to flush out the remaining output elements from the state. Clearly, specializing to retrieves the original operator.

The corresponding metamorphism uses an apomorphism in place of the unfold. Define

Then behaves like , except that if and when stops being productive it finishes up by applying to the final state. Similarly, define flushing metamorphisms:

Then we have

for all finite lists if the streaming condition holds for and . In particular,

on finite inputs : the streaming condition does hold for and the more cautious , and once the input has been exhausted, the process can switch to the more aggressive .

Infinite input

The main advantage of streaming is that it can allow the change-of-representation process also to work on infinite inputs. With the plain metamorphism, this is not possible: the will yield no result on an infinite input, and so the will never get started, but the may be able to produce some outputs before having consumed all the inputs. For example, the streaming version of also works for infinite lists, providing that the input does not end with an infinite tail of empty lists. And of course, if the input never runs out, then there is no need ever to switch to the more aggressive flushing phase.

As a more interesting example, consider converting a fraction from base 3 to base 7:

We assume that the input digits are all either 0, 1 or 2, so that the number being represented is in the unit interval.

The fold in is of the wrong kind; but we have also

Here, the intermediate state can be seen as a defunctionalized representation of the function , and applies this function to :

Now there is an extra function between the and the ; but that’s no obstacle, because it fuses with the :

However, the streaming condition does not hold for and . For example,

That is, , but , so it is premature to produce the first digit 2 in base 7 having consumed only the first digit 1 in base 3. The producer is too aggressive; it should be more cautious while input remains that might invalidate a produced digit.

Fortunately, on the assumption that the input digits are all 0, 1, or 2, the unconsumed input—a tail of the original input—again represents a number in the unit interval; so from the state the range of possible unproduced outputs represents a number between and . If these both start with the same digit in base 7, then (and only then) is it safe to produce that digit. So we define

and we have

Now, the streaming condition holds for and (as you may check), and therefore

on finite digit sequences in base 3. Moreover, the streaming program works also on infinite digit sequences, where the original does not.

(Actually, the only way this could possibly produce a finite output in base 7 would be for the input to be all zeroes. Why? If we are happy to rule out this case, we could consider only the case of taking infinite input to infinite output, and not have to worry about reaching the end of the input or flushing the state.)

by jeremygibbons at October 04, 2017 09:45 AM

September 2017 1HaskellADay 1Liner problems and solutions

• September 26th, 2017:
  art2RawNames art = Raw (artId art) <$> (Map.lookup "Person" $ metadata art)
  curry away the 'art' var. ref: Y2017.M09.D26.Exercise 
• September 19th, 2017:  The #1Liner to follow (next tweet) is a question based off a code snippet from Y2017.M09.D18.Solution. What is a better/more elegant definition?
  

  fmap (wordStrength . wc) (BL.readFile filename) >>= \dict ->
  return (Map.insert filename dict m)

  Reformulate. Curry the dict-ref.

by geophf (noreply@blogger.com) at October 03, 2017 06:58 PM

September 2017 1HaskellADay problems and solutions

• September 29th, 2017: Friday's #haskell problem uses name-parsing to post parsed names into PostgreSQL database and join them to articles. Today's #haskell solution extracts rows of raw names associated with articles, parses then stores them in PostgreSQL.
  
• September 28th, 2017: Thursday's #haskell problem inserts reified articles into PostgreSQL database, including names, and throws confetti! Today's #haskell solution inserts the articles from our compressed archive. YAY! Throw confetti! 
  
• September 27th, 2017: Wednesday's #haskell problem looks at parsing names in various formats. Today's #haskell solution solves the name-parsing problem by parsing each name-form in turn. 
• September 26th, 2017: Tuesday's #haskell problem looks at staging data on PostgreSQL for deferred processing using Haskell for ETL. Today's #haskell solution transforms RawNames to JSON and uploads it to a staging table on the PostgreSQL database.
   
• September 25th, 2017: Friday we took a compressed archive and broke that into individual articles. Today we divide articles into sections. Today's #haskell solution uncovers structure bit by bit as we reify an article structure from a block of text. 
• September 22nd, 2017: Today's #haskell problem we're going to scan into an 'unstructured' set of documents and start to look for structure. Welp, today's #haskell solution is a 'start': from one blob to 11 blocks of raw text. We'll dig in deeper next week. 
• September 21st, 2017: TOMORROW's #haskell problem (announced a wee bit early) queries PostgreSQL database to fetch keyword dictionary state. Today's #haskell solution picks up where we left off yesterday then computes the top keywords across articles. 
  
• September 20th, 2017: Today's #haskell problem asks to push keywords extracted from article onto a PostgreSQL data table. Today's #haskell solution pushes keywords – PUSHES KEYWORDS REAL GOOD – to a PostgreSQL database. 
  
  
  
  
• September 19th, 2017: So we've encoded keywords into Ints, today's #haskell problem decodes those ints back to the keywords. Today's #haskell solution 'reverses the arrows' of the Map, decoding a keyword from an index 
• September 18th, 2017: Today's #haskell problem computes the relative word 'strength' of each word in a document. Today's #haskell solution breaks the word-strength problem into small pieces then foldM's over the small pieces. 
• September 15th, 2017: Today's #haskell problem takes a look at KEA/Keyword Extraction Algorithm. Ooh, doggies! State IO Map KeyWord something-or-otherfor today's #haskell solution.
• September 14th, 2017: Today's #haskell problem involves using the simple interface to PostgreSQL to insert rows of data. Ooh! Exciting! Today's #haskell solution uses ToRow and ToField to insert Haskell values into #PostgreSQL #DaaS instance! lolneat! 
  
• September 13th, 2017: Today's #haskell problem asks the article names have encoded Julian dates ... OR DO THEY? So, in solving today's #haskell problem, I realized THOSE AREN'T JULIAN DATES! THOSE ARE DATE DATES! 
• September 8th, 2017: Continuing our ETL exploration with a load/compress/storefor today's #haskell exercise. Today's #haskell solution shows load/compress/store ... that's a word now. 
• September 5th, 2017: Today's #haskell exercise is to build a directory web serviceusing the Snap framework [or a framework you prefer] 
• September 4th, 2017: Today's #haskell problem reads in source documents and does some word frequency analyses. Today's #haskell solution shows, surprisingly, 'the' is the most popular English word. Or, not so surprisingly. 
• September 1st, 2017: Today's #haskell problem #SPARQL-queries wikidata.org to fetch countries' populations for FB analysis. Yesterday, India won FB by population, today we have a surprise winner in Thailand for FB by percentage user base. 

by geophf (noreply@blogger.com) at September 30, 2017 02:24 PM

Yesod Tutorial 1. My First Web Site

This is the first in the series of tutorials introducing a new approach to web development using Haskell and Yesod. Haskell is a functional language and Yesod is a web development framework written in Haskell by Michael Snoyman who also wrote a book about it. Michael is a member of the FP Complete team and he provided a lot of valuable feedback for this tutorial.

by Bartosz Milewski (bartosz@fpcomplete.com) at September 28, 2017 11:34 PM

It's time for Functional Programming

by Aaron Contorer - CEO

In 1999 I went to Bill Gates with an idea to create a software tools group dedicated to shipping complex software faster. Engineers’ time is valuable, and more importantly, software that ships on time with fewer defects is worth a lot. I organized a team that analyzed what was missing from the old toolsets for our most valuable products. Based on developers’ input, we conceived and delivered five in-house tools within our first year, spanning areas from build to source control to localization. I'm proud of the talented and motivated people who chose to be on that team, and the positive impact it had: If you have a copy of Windows or Office today, it probably arrived on your desk a little sooner and a little better thanks to the Productivity Tools Team. From a business point of view, Microsoft got its tools investment back many times over.

by Aaron Contorer (aaron@fpcomplete.com) at September 28, 2017 11:34 PM

Asynchronous API in C++ and the Continuation Monad

The latest C++11 Standard was a brave attempt, after many years of neglect, at catching up with the reality of concurrent programming. The result is a new memory model -- a solid foundation for concurrency -- and a collection of random concurrency features, many of them either obsolete or inadequate. But there is hope on the horizon: the next C++ Standard, on which the work started even before C++11 saw the light of day. In my last blog I reported on the first meeting of the C++ study group on concurrency and parallelism that took place in Bellevue, WA.

Erik Meijer

One of the hot topics at that meeting was building better support for asynchronous calls, either through libraries or new language extensions. The C# group dazzled us with their very mature solution. Honestly, I am impressed with their work. And I know

by Bartosz Milewski (bartosz@fpcomplete.com) at September 28, 2017 11:33 PM

The Downfall of Imperative Programming

Imperative programming is in my bloodstream. I've been a C++ programmer for most of my life. I wrote a book about C++. I helped Andrei and Walter design an imperative language D. If I dabbled in functional programming, it was mostly to make my imperative programs better.

by Bartosz Milewski (bartosz@fpcomplete.com) at September 28, 2017 11:33 PM

The Functor Pattern in C++

The Gang of Four book introduced many a C++ programmer to the world of patterns. Those patterns are mostly based on everyday examples, although there are a few more abstract ones like Strategy. In Haskell (and other functional languages) most patterns are very abstract. They are often based on mathematical constructs; category theory being a major source of ideas.

by Bartosz Milewski (bartosz@fpcomplete.com) at September 28, 2017 11:33 PM

Engineering Manager at Takt (Full-time)

Takt’s Engineering organization is growing rapidly, and we’re looking for Engineering Managers to lead and scale the team. Takt distills complex customer data into uniquely tailored experiences; we orchestrate physical and digital exchanges into one seamless journey. Our business is building lasting, trusted relationships between people and brands — and making it look easy.

As an Engineering Manager at Takt, you deeply value and understand the work your team is accomplishing, and serve to inspired and develop each individual while ensuring business objectives are met. As we continue to expand our business, your team will build a rich, complex real-time product that serves our enterprise partners and their end customers while you enrich the lives and careers of your team.

Key Responsibilities:

• Build and manage a team of up to 8 software engineers, including coaching, mentorship, and performance management
• Develop and optimize development processes and practices to maintain the balance between building a complex innovative product with shipping quickly
• Instill a pragmatic, delivery-focused support-oriented mindset that values long-term efficiency and value
• Collaborate with engineers and software architects to design and develop software components for current and prospective Takt clients
• Be accountable for technical components, including planning, prioritization, and delivery
• Partner with the recruiting organization to fill the pipeline with exceptional talent, promote referrals, nurture relationships through informal meetings, and serve as an ambassador for Takt at events and conferences
• Promote continuous feedback, address growth areas for team members, and celebrate strengths and contributions of your team
• Be emblematic of Takt’s values and lead by example, set the right context, and inspire the team to do their best work by fostering an environment that’s open, transparent and respectful of each other
• Develop Engineering onboarding processes and documentation practices, ensure new team members have a seamless experience and are productive quickly

Skills and Experience:

• Prior experience in technical leadership and proven ability to build and develop successful teams consisting of varied levels of experience
• Technical expertise with Functional Programming in Scala or Haskell
• Demonstrated understanding of software design and a deep appreciation for Customer Success
• Excellent interpersonal, written, presentation and closing skills
• Prior success with hiring top technical talent and contributing to recruiting processes
• Experience running projects and understanding of agile development methodologies
• Select teams may have domain specific requirements (e.g. Machine Learning, Infrastructure, Security)
• Experience managing team members in a distributed environment is a plus
• Both mid-large company and startup experience would be a plus

About Takt:

Takt distills complex customer data into uniquely tailored experiences; we orchestrate physical and digital exchanges into one seamless journey. Our business is building lasting, trusted relationships between people and brands—and making it look easy.

We're already reaching millions of people a day, and we're just getting started. Our founding leadership is equal parts business, design, and engineering—because we believe differing perspectives + passionate discourse achieve the greatest outcomes. We are collectively talented, but also humble. We give our whole selves. We love learning new things.

Takt is committed to inclusion and diversity and is an equal opportunity employer. All applicants will receive consideration without regard to race, color, religion, gender, gender identity, sexual orientation, national origin, disability, or veteran status.

If you're up for the challenge of a lifetime, we're looking for outstanding talent to join our team.

Get information on how to apply for this position.

September 28, 2017 08:09 PM

Type-driven strictness

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I was recently trying to optimize Dhall's performance because the interpreter was performing poorly on some simple examples.

For example, consider this tiny expression that prints 3000 exclamation marks:

Natural/fold +3000 Text (λ(x : Text) → x ++ "!") ""

The above Dhall expression takes over 14 seconds to evaluate to normal form, which is not acceptable:

$ bench 'dhall <<< './exclaim'
benchmarking dhall <<< ./exclaim
time                 14.42 s    (14.23 s .. 14.57 s)
                     1.000 R²   (1.000 R² .. 1.000 R²)
mean                 14.62 s    (14.54 s .. 14.66 s)
std dev              70.22 ms   (0.0 s .. 77.84 ms)
variance introduced by outliers: 19% (moderately inflated)

Strict

The performance suffers because Dhall is lazy in the accumulator, meaning that the accumulator builds up a gigantic expression like this:

(λ(x : Text) → x ++ "!")
( (λ(x : Text) → x ++ "!")
  ( (λ(x : Text) → x ++ "!")
    ( (λ(x : Text) → x ++ "!")
      ( (λ(x : Text) → x ++ "!")
        ...
        {Repeat this nesting 3000 times}
        ...
        ""
      )
    )
  )
)

... and then attempts to normalize the entire expression, which takes a long time and wastes a lot of memory.

The reason for this lazy behavior is the following code for evaluating Natural/fold in the Dhall interpreter:

normalize (App (App (App (App NaturalFold (NaturalLit n0)) _) succ') zero)
    = normalize (go n0)
  where
    go !0 = zero
    go !n = App succ' (go (n - 1))

You can read that as saying:

• Given an expression of the form Natural/Fold n succ zero
• Wrap the value zero in n calls of the function succ
  • i.e. succ (succ (succ (... {n times} ... (succ zero) ...)))
• Then normalize that

A smarter approach would be to keep the accumulator strict, which means that we evaluate as we go instead of deferring all evaluation to the end. For example, the accumulator starts off as just the empty string:

""

... then after one iteration of the loop we get the following accumulator:

(λ(x : Text) → x ++ "!") ""

... and if we evaluate that accumulator immediately we get:

"!"

Then the next iteration of the loop produces the following accumulator:

(λ(x : Text) → x ++ "!") "!"

... which we can again immediately evaluate to get:

"!!"

This is significantly more efficient than leaving the expression unevaluated.

We can easily implement such a strict loop by making the following change to the interpreter:

normalize (App (App (App (App NaturalFold (NaturalLit n0)) _) succ') zero)
    = go n0
  where
    go !0 = normalize zero
    go !n = normalize (App succ' (go (n - 1)))

The difference here is that we still build up a chain of n calls to succ but now we normalize our expression in between each call to the succ function instead of waiting until the end to normalize.

Once we do this runtime improves dramatically, going down from 15 seconds to 90 milliseconds:

$ bench 'dhall <<< './example'
benchmarking dhall <<< ./example
time                 88.92 ms   (87.14 ms .. 90.74 ms)
                     0.999 R²   (0.999 R² .. 1.000 R²)
mean                 86.06 ms   (84.98 ms .. 87.15 ms)
std dev              1.734 ms   (1.086 ms .. 2.504 ms)

... or in other words about 30 microseconds per element. We could still do more to optimize this but at least we're now in the right ballpark for an interpreter. For reference, Python is 4x faster on my machine for the following equivalent program:

print ("!" * 3000)

$ bench 'python exclaim.py'
benchmarking python exclaim.py
time                 24.55 ms   (24.09 ms .. 25.02 ms)
                     0.998 R²   (0.996 R² .. 1.000 R²)
mean                 24.53 ms   (24.16 ms .. 24.88 ms)
std dev              798.4 μs   (559.8 μs .. 1.087 ms)

However, these results don't necessarily imply that a strict accumulator is always better.

Lazy

Sometimes laziness is more efficient, though. Consider this program:

List/build
Integer
(   λ(list : Type)
→   λ(cons : Integer → list → list)
→   Natural/fold +6000 list (cons 1)
)

The above example uses Natural/fold to build a list of 6000 1s.

In this case the accumulator of the fold is a list that grows by one element after each step of the fold. We don't want to normalize the list on each iteration because that would lead to quadratic time complexity. Instead we prefer to defer normalization to the end of the loop so that we get linear time complexity.

We can measure the difference pretty easily. A strict loop takes over 6 seconds to complete:

bench 'dhall <<< ./ones'
benchmarking dhall <<< ./ones
time                 6.625 s    (6.175 s .. 7.067 s)
                     0.999 R²   (0.998 R² .. 1.000 R²)
mean                 6.656 s    (6.551 s .. 6.719 s)
std dev              95.98 ms   (0.0 s .. 108.3 ms)
variance introduced by outliers: 19% (moderately inflated)

... whereas a lazy loop completes in about 180 milliseconds:

$ bench 'dhall <<< ./g'
benchmarking dhall <<< ./g
time                 182.5 ms   (175.1 ms .. 191.3 ms)
                     0.998 R²   (0.995 R² .. 1.000 R²)
mean                 177.5 ms   (172.1 ms .. 180.8 ms)
std dev              5.589 ms   (2.674 ms .. 8.273 ms)
variance introduced by outliers: 12% (moderately inflated)

Moreover, the difference in performance will only worsen with larger list sizes due to the difference in time complexity.

Also, in case you were wondering, Python is about 7x faster:

print ([1] * 6000)

$ bench 'python ones.py'
benchmarking python ones.py
time                 25.36 ms   (24.75 ms .. 25.92 ms)
                     0.998 R²   (0.996 R² .. 0.999 R²)
mean                 25.64 ms   (25.16 ms .. 26.03 ms)
std dev              917.8 μs   (685.7 μs .. 1.348 ms)

Why not both?

This poses a conundrum because we'd like to efficiently support both of these use cases. How can we know when to be lazy or strict?

We can use Dhall's type system to guide whether or not we keep the accumulator strict. We already have access to the type of the accumulator for our loop, so we can define a function that tells us if our accumulator type is compact or not:

compact :: Expr s a -> Bool
compact Bool             = True
compact Natural          = True
compact Integer          = True
compact Double           = True
compact Text             = True
compact (App List _)     = False
compact (App Optional t) = compact t
compact (Record kvs)     = all compact kvs
compact (Union kvs)      = all compact kvs
compact _                = False

You can read this function as saying:

• primitive types are compact
• lists are not compact
• optional types are compact if the corresponding non-optional type is compact
• a record type is compact if all the field types are compact
• a union type is compact if all the alternative types are compact

Now, all we need to do is modify our fold logic to use this compact function to decide whether or not we use a strict or lazy loop:

normalize (App (App (App (App NaturalFold (NaturalLit n0)) t) succ') zero) =
    if compact (normalize t) then strict else lazy
  where
    strict =            strictLoop n0
    lazy   = normalize (  lazyLoop n0)

    strictLoop !0 = normalize zero
    strictLoop !n = normalize (App succ' (strictLoop (n - 1)))

    lazyLoop !0 = zero
    lazyLoop !n = App succ' (lazyLoop (n - 1))

Now we get the best of both worlds and our interpreter gives excellent performance in both of the above examples.

Fizzbuzz

Here's a bonus example for people who got this far!

The original Dhall expression that motivated this post was an attempt to implement FizzBuzz in Dhall. The program I ended up writing was:

    let pred =
            λ(n : Natural)
          →     let start = { next = +0, prev = +0 }
            
            in  let step =
                        λ(state : { next : Natural, prev : Natural })
                      → { next = state.next + +1, prev = state.next }
            
            in  let result =
                      Natural/fold
                      n
                      { next : Natural, prev : Natural }
                      step
                      start
            
            in  result.prev

in  let not = λ(b : Bool) → b == False

in  let succ =
            λ ( state
              : { buzz : Natural, fizz : Natural, index : Natural, text : Text }
              )
          →     let fizzy = Natural/isZero state.fizz
            
            in  let buzzy = Natural/isZero state.buzz
            
            in  let line =
                            if fizzy && buzzy then "FizzBuzz"
                      
                      else  if fizzy && not buzzy then "Fizz"
                      
                      else  if not fizzy && buzzy then "Buzz"
                      
                      else  Integer/show (Natural/toInteger state.index)
            
            in  { buzz  = pred (if buzzy then +5 else state.buzz)
                , fizz  = pred (if fizzy then +3 else state.fizz)
                , index = state.index + +1
                , text  = state.text ++ line ++ "\n"
                }

in  let zero = { buzz = +5, fizz = +3, index = +0, text = "" }

in  let fizzBuzz =
            λ(n : Natural)
          →     let result =
                      Natural/fold
                      n
                      { buzz  : Natural
                      , fizz  : Natural
                      , index : Natural
                      , text  : Text
                      }
                      succ
                      zero
            
            in  result.text

in  fizzBuzz

However, this program runs incredibly slowly, taking over 7 seconds just to compute 20 elements:

bench 'dhall <<< "./fizzbuzz +20"'
benchmarking dhall <<< "./fizzbuzz +20"
time                 7.450 s    (7.194 s .. 7.962 s)
                     0.999 R²   (NaN R² .. 1.000 R²)
mean                 7.643 s    (7.512 s .. 7.739 s)
std dev              145.0 ms   (0.0 s .. 165.6 ms)
variance introduced by outliers: 19% (moderately inflated)

However, if you use a strict fold then the program takes half a second to go through 10,000 elements:

$ bench 'dhall <<< "./fizzbuzz +10000"'
benchmarking dhall <<< "./fizzbuzz +10000"
time                 591.5 ms   (567.3 ms .. NaN s)
                     1.000 R²   (0.999 R² .. 1.000 R²)
mean                 583.4 ms   (574.0 ms .. 588.8 ms)
std dev              8.418 ms   (0.0 s .. 9.301 ms)
variance introduced by outliers: 19% (moderately inflated)

Conclusion

Many people associate dynamic languages with interpreters, but Dhall is an example of a statically typed interpreter. Dhall's evaluator is not sophisticated at all but can still take advantage of static type information to achieve comparable performance with Python (which is a significantly more mature interpreter). This makes me wonder if the next generation of interpreters will be statically typed in order to enable better optimizations.

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by Gabriel Gonzalez (noreply@blogger.com) at September 27, 2017 01:17 PM

Immutability and unboxing in array programming

Manuel M T Chakravarty

This is the third post in a series about array programming in Haskell — you might be interested in the first and second, too.

In the previous post of this series, we discussed commonly used vector and matrix routines, which are available in highly-optimised implementations in most programming languages. However, often we need to implement our own custom array algorithms. To this end, the Haskell standard (Haskell 2010) already comes with a simple array API in the form of the Data.Array standard module. These arrays are immutable, boxed, and non-strict. This allows for the elegant, high-level description of many array algorithms, but it is suboptimal for compute-intensive applications as boxing and non-strictness, especially in combination with the reliance on association lists for array construction, lead to code that is very difficult for the Haskell compiler to optimise, resulting in rather limited performance.

Strictness

The extra expressiveness granted by non-strictness is nicely displayed by the following example, courtesy of the classic A Gentle Introduction to Haskell. The wavefront function defines an nxn array whose leftmost column and topmost row are populated with 1s (by the first two list comprehensions below). All other array elements are defined as the sum of the three elements to their left, top, and top-left (by the third list comprehension in the definition).

wavefront :: Int -> Array (Int,Int) Int
wavefront n = arr
  where
    arr = array ((1,1),(n,n))
                ([((1,j), 1) | j <- [1..n]] ++
                 [((i,1), 1) | i <- [2..n]] ++
                 [((i,j), arr!(i,j-1) + arr!(i-1,j-1) + arr!(i-1,j))
                             | i <- [2..n], j <- [2..n]])

The ! infix operator implements array indexing:

(!) :: Ix i => Array i e -> i -> e

Moreover, the function array constructs an array from an association list mapping indexes to values:

array :: Ix i => (i, i) -> [(i, e)] -> Array i e

The elegance of wavefront is in the recursive definition of the array arr. In the expression arr!(i,j-1) + arr!(i-1,j-1) + arr!(i-1,j), we access the elements to the left, top, and top-left of the current one by appropriate indexing of the very array that we are currently in the process of defining. Such a recursive dependency is only valid for a non-strict data structure.

Boxing

Unfortunately, the expressiveness of non-strict arrays comes at a price, especially if the array elements are simple numbers. Instead of being able to store those numeric elements in-place in the array, non-strict arrays require a boxed representation, where the elements are pointers to heap objects containing the numeric values. This additional indirection requires extra memory and drastically reduces the efficiency of array access, especially in tight loops. The layout difference between an unboxed (left) and a boxed (right) representation is illustrated below.

While both strict and non-strict data structures admit boxed representations, non-strict structures typically require boxing. To provide an alternative to the standard non-strict arrays, the array package provides strict, unboxed arrays of type Data.Array.Unboxed.UArray i e. By way of overloading via the type class Data.Array.IArray.IArray, they provide the same API as the standard non-strict, boxed arrays. However, the element type is restricted to basic types that can be stored unboxed, such as integral and floating-point numeric types.

Unfortunately, array construction based on association lists, such as the array function, still severely limits the performance of immutable UArrays. Nevertheless, at least, array access by way of (!) is efficient for unboxed arrays.

Immutability

While immutable arrays —i.e., arrays that cannot directly be in-place updated— are semantically simpler, it turns out that indexed-based array construction is drastically more efficient for mutable arrays. Hence, computationally demanding Haskell array code typically adopts a two-phase array life cycle: (1) arrays are allocated as mutable arrays and initialised using in-place array update; once initialised, (2) they are frozen by making them immutable.

This usage pattern is supported by the interface provided by the Data.Array.MArray.MArray class and we use it in the following example function generate to initialise an array of Doubles with an index-based generator function gen:

generate :: Ix i => (i, i) -> (i -> Double) -> UArray i Double
generate bnds gen
  = runSTUArray $ do
      arr <- newArray_ bnds
      mapM_ (\i -> writeArray arr i (gen i)) (range bnds)
      return arr

Mutable arrays come in various flavours that are, in particularly, distinguished by the monad in which the array operations take place. Usually, this is either IO or ST, and the array package provides both boxed and unboxed variants for both monads. We have the boxed IOArray and the unboxed IOUArray as well as the boxed STArray and the unboxed STUArray. The above definition of generate uses STUArray to initialise the array, and then, freezes it into a UArray, which is returned. The choice of STUArray is implicit in the use of runSTUArray, which executes the code in the state transformer monad ST and freezes the STUArray into a UArray.

The function newArray_ provides a fresh uninitialised array:

newArray_ :: (MArray a e m, Ix i) => (i, i) -> m (a i e)

We can read and write a mutable array with

readArray  :: (MArray a e m, Ix i) => a i e -> i      -> m e
writeArray :: (MArray a e m, Ix i) => a i e -> i -> e -> m ()

In the definition of generate, we use writeArray once on each index in the range range bnds of the mutable array to initialise the value at index i with the value of the generator function at that index, gen i.

Generally, we can freeze a mutable array, obtaining an immutable array, with

freeze :: (Ix i, MArray a e m, IArray b e) => a i e -> m (b i e)

There is also the unsafe variant unsafeFreeze that avoids copying the array during freezing, but puts the onus on the programmer to ensure that the mutable argument is subsequently not updated anymore. In the code for generate above, we indirectly use unsafeFreeze by way of runSTUArray. As runSTUArray makes it impossible to use the mutable array after freezing, this encapsulated use of unsafeFreeze is always safe.

An expression, such as, generate (1,100) ((^2) . fromIntegral) produces an unboxed array with the first one hundred square numbers. Internally, it is based on the initialisation of a mutable array, but this is completely abstracted over by the definition of generate. While there is no inbuilt need to ever freeze a mutable array, good functional programming style requires to keep mutable code as localised as possible and to avoid passing mutable data structures around.

Summary

Well written code based on unboxed arrays and using the discussed pattern to create arrays by initialising a mutable version, which is subsequently frozen, can achieve performance comparable to low-level C code. In fact, the collection-oriented high-performance array frameworks that we will discuss in subsequent blog posts work exactly in this manner.

September 27, 2017 12:00 AM

StrataConf NY 2017

If you're in New York for Strata this week come join me on Wednesday for a book signing at 10:55 ( https://conferences.oreilly.com/strata/strata-ny/public/content/author-signings ), talk at 2:55 ( https://conferences.oreilly.com/strata/strata-ny/public/schedule/detail/60802 ), and office hours at 4:35 ( https://conferences.oreilly.com/strata/strata-ny/public/schedule/detail/63328 ) :)

by Holden Karau (noreply@blogger.com) at September 25, 2017 07:35 PM

Haskell or Scala engineer at Courex (Full-time)

What we do

Courex, a subsidiary of Keppel T&T, is an 8 year old ecommerce logistics company driven by technology. We help our customers manage their supply chain so they can focus on selling. We do the following

• last mile delivery
• warehousing
• omnichannel integration

Our operations is driven by technology. Some interesting stuff

• We run a hybrid crowd-sourced(uber style) + fixed fleet model.
• We built an automated parcel dimension measurement machine using Kinect
• We have autonomous robots coming in late 2017 to pick and sort parcels

Experience a different sort of scale. Not bits and bytes, but parcels, machines and people. Your work affects the real world in a huge traditional industry.

As part of the Keppel group, your work will reach the supply chain across Southeast Asia and China. Help us digitise the supply chain.

What are we looking for

We have openings in 2 teams. The inventory management product, which is written in Haskell, and the inventory synchronisation product which is written in Scala. Getting the inventory right is crucial in the supply chain, and functional programming gives us the confidence to do that.

The inventory management product manages how inventory flows in and out of the various warehouses in the region. Whereas the inventory synchronisation team synchronises the state of the inventory to various places such as Amazon, Lazada and Shopee.

We are looking for people interested in functional programming. It doesn't matter if you don't have working experience in them. Qualifications are not necessary. We like people who are practical and prolific. We are expanding to Southeast Asia. Our HQ is in Singapore, but you can work from one of Malaysia, Indonesia or Vietnam.

Get information on how to apply for this position.

September 25, 2017 07:34 AM

Alternatives to Typed Holes for talking to your compiler

Rejected title: Type Praxis

I frequently see people recommend that others use typed holes. I think people are more apt to recommend typed holes than the alternatives because it’s a bespoke feature intended to enable discovering the type of a sub-expression more easily. Which is fair enough, except it doesn’t really have a good use-case! I will demonstrate in this post why.

I frequently find myself relying on GHC Haskell’s features in order to off-load brain effort. The idea behind typed holes is that if you have an incomplete expression and aren’t sure what type the remaining part should be, you can ask the compiler! Lets reuse the example from the Haskell Wiki: https://wiki.haskell.org/GHC/Typed_holes

pleaseShow :: Show a => Bool -> a -> Maybe String
pleaseShow False _ = Nothing
pleaseShow True a = Just (show _a)

The idea here is that we aren’t sure what should go at the end of the final line and we’re using _a to ask GHC what the type of _a should be. You get a type error that tries to describe the typed hole as follows:

    • Found hole: _a :: a0
      Where: ‘a0’ is an ambiguous type variable
      Or perhaps ‘_a’ is mis-spelled, or not in scope
    • In the first argument of ‘show’, namely ‘_a’
      In the first argument of ‘Just’, namely ‘(show _a)’
      In the expression: Just (show _a)
    • Relevant bindings include
        a :: a
        pleaseShow :: Bool -> a -> Maybe String

Okay so here’s the problem. There’s a Show constraint on a but the typed hole message doesn’t bother saying so:

    • Found hole: _a :: a0

This represents sort of a problem. Typeclass constraints aren’t always as syntactically obvious as they are from the declaration of pleaseShow here:

pleaseShow :: Show a => Bool -> a -> Maybe String

Sometimes they arise from other sub-expressions in your code and aren’t manifest in the type of your declaration!

You can’t productively point new people to typed holes because they’ll get extremely confused about type variables that have no constraints. If they’re reading good learning material, they’ll know that means they can’t actually do anything with something that is parametrically polymorphic. Even that framing aside, they just won’t know what terms are available to them for anything polymorphic.

Then we come to the expert. The expert is more likely to be working with code leveraging typeclasses and polymorphism and therefore…typed holes is of less help to them. If they’re aware of what typeclass constraints are attached to a type variable, fine, but the compiler is still forcing the programmer to juggle more context in their head than is really necessary.

In which I offer a better alternative

pleaseShow :: Show a => Bool -> a -> Maybe String
pleaseShow False _ = Nothing
pleaseShow True a =
  let x :: z
      x = a
  in Just (show undefined)

This time we get an error that mentions where the original type came from along with the relevant typeclass constraints:

    • Couldn't match expected type ‘z’ with actual type ‘a’
      ‘a’ is a rigid type variable bound by
        the type signature for:
          pleaseShow :: forall a. Show a => Bool -> a -> Maybe String
      ‘z’ is a rigid type variable bound by
        the type signature for:
          x :: forall z. z

Keep in mind, this isn’t perfect! It’s not strictly the same as typed holes either as it’s more about contradicting the compiler about what type a had in order to discover what its type is. However, at least this way, we get a more complete picture of what the type of a is. Also note how I used undefined in order to ignore the parts of my code I wasn’t interested in getting errors about. This isn’t a perfect fit here as it results in GHC wanting to know which type it’s meant to expect from undefined, but in more typical circumstances, it works great for positing hypotheticals without bothering to write the actual code.

We’re about to do something more gnarly looking in the next section, the tl;dr is this:

TL;DR

Use let expressions, undefined, impossible types and the like instead of typed holes. And don’t recommend Typed Holes to new people, they’re more confusing than helpful and the facilities of typed holes don’t scale well to more complicated contexts anyway.

Tackling slightly more complicated situations

---

Warning: If you haven’t worked through about 2/3s of the Haskell Book or possess the equivalent practice and knowledge, you are unlikely to grok this section.

---

Sometimes you want to be able to posit something or lay down types for sub-expressions in a situation where you have a polymorphic type arising from a typeclass instance or function declaration. In those situations, knowing how to combine ScopedTypeVariables, InstanceSigs, and let expressions can be very valuable!

What if we’re stumped on something like this?

doubleBubble :: ( Applicative f1
                , Applicative f2 )
             => f1 (f2 (a -> b))
             -> f1 (f2 a)
             -> f1 (f2 b)
doubleBubble f ffa =
  undefined

So we try to start by assigning a type to a sub-expression:

doubleBubble :: ( Applicative f1
                , Applicative f2 )
             => f1 (f2 (a -> b))
             -> f1 (f2 a)
             -> f1 (f2 b)
doubleBubble f ffa =
  let x :: z
      x = f
  in undefined

And get the following type error:

    • Couldn't match expected type ‘z’
                  with actual type ‘f1 (f2 (a -> b))’

Fair enough, what if we try to make the types agree?

doubleBubble :: ( Applicative f1
                , Applicative f2 )
             => f1 (f2 (a -> b))
             -> f1 (f2 a)
             -> f1 (f2 b)
doubleBubble f ffa =
  let x :: f1 (f2 (a -> b))
      x = f
  in undefined

We get a type error?!

    • Couldn't match type ‘f1’ with ‘f4’
      ‘f1’ is a rigid type variable bound by
        the type signature for:
          doubleBubble :: forall (f1 :: * -> *) (f2 :: * -> *) a b.
                          (Applicative f1, Applicative f2) =>
                          f1 (f2 (a -> b)) -> f1 (f2 a) -> f1 (f2 b)
      ‘f4’ is a rigid type variable bound by
        the type signature for:
          x :: forall (f4 :: * -> *) (f5 :: * -> *) a1 b1. f4 (f5 (a1 -> b1))

The issue is that types usually only last the scope of a single type signature denoted by ::, so the variables f1, a, b, and the like can only be referenced in our declaration. That kinda sucks, how do we keep referring to the same type variables under our declaration? ScopedTypeVariables!

{-# LANGUAGE ScopedTypeVariables #-}

doubleBubble :: forall f1 f2 a b
              . ( Applicative f1
                , Applicative f2 )
             => f1 (f2 (a -> b))
             -> f1 (f2 a)
             -> f1 (f2 b)
doubleBubble f ffa =
  let x :: f1 (f2 (a -> b))
      x = f
  in undefined

This now type-checks because we used forall to tell GHC that we wanted those variables to be lexically scoped! Now we’re really cooking with gas. Lets follow a chain of experiments and how they change our type errors:

doubleBubble :: forall f1 f2 a b
              . ( Applicative f1
                , Applicative f2 )
             => f1 (f2 (a -> b))
             -> f1 (f2 a)
             -> f1 (f2 b)
doubleBubble f ffa =
  let x :: z
      x = fmap (<*>) f
  in undefined

    • Couldn't match expected type ‘z’
                  with actual type ‘f1 (f2 a -> f2 b)’

doubleBubble :: forall f1 f2 a b
              . ( Applicative f1
                , Applicative f2 )
             => f1 (f2 (a -> b))
             -> f1 (f2 a)
             -> f1 (f2 b)
doubleBubble f ffa =
  let x :: z
      x = (fmap (<*>) f) <*> ffa
  in undefined

    • Couldn't match expected type ‘z’ with actual type ‘f1 (f2 b)’

-- this typechecks.
doubleBubble :: forall f1 f2 a b
              . ( Applicative f1
                , Applicative f2 )
             => f1 (f2 (a -> b))
             -> f1 (f2 a)
             -> f1 (f2 b) -- <---
doubleBubble f ffa =      ------ hmm
  let x :: f1 (f2 b) -- <--------
      x = (fmap (<*>) f) <*> ffa
  in undefined

And now we’re done:

doubleBubble :: forall f1 f2 a b
              . ( Applicative f1
                , Applicative f2 )
             => f1 (f2 (a -> b))
             -> f1 (f2 a)
             -> f1 (f2 b) -- <---
doubleBubble f ffa =      ------ hmm
  let x :: f1 (f2 b) -- <--------
      x = (fmap (<*>) f) <*> ffa
  in x

The intuition here is that we have to applicatively (monoidal functor, remember?) combine the * -> * kinded structure twice,

   f1 (f2 (a -> b))
-- <>  <>
-> f1 (f2     a)

Once for f1 of the function and f1 of the value, once for f2 of the function and f2 of the value.

Prelude> :t (\f a -> f <*> a)
(\f a -> f <*> a) :: Applicative f => f (a -> b) -> f a -> f b
Prelude> :t (\f a -> (fmap (<*>) f) <*> a)
(\f a -> (fmap (<*>) f) <*> a)
  :: (Applicative f, Applicative f1) =>
     f1 (f (a -> b)) -> f1 (f a) -> f1 (f b)

The following doesn’t fit because we end up triggering the Reader (function type) Applicative:

Prelude> :t (\f a -> ((<*>) f) <*> a)
(\f a -> ((<*>) f) <*> a)
  :: (a1 -> a -> b) -> ((a1 -> a) -> a1) -> (a1 -> a) -> b

Rewriting the working solution a little:

apply = (<*>)
doubleAp f a = apply (fmap apply f) a

Prelude> let apply = (<*>)
Prelude> let doubleAp f a = apply (fmap apply f) a
Prelude> :t doubleAp
doubleAp
  :: (Applicative f1, Applicative f) =>
     f1 (f (a -> b)) -> f1 (f a) -> f1 (f b)

Then breaking down:

doubleAp f a = apply (fmap apply f) a
--             [1]    [2]  [3]

1. This apply grafts in the pre-lifted apply, cf.

Prelude> import Data.Void
Prelude> let v :: Void; v = undefined
Prelude> let doubleAp f a = v (fmap apply f) a

<interactive>:104:20: error:
    • Couldn't match expected type ‘f1 (f a -> f b) -> t1 -> t’
                  with actual type ‘Void’

2. This fmap lifts a regular apply into a type that can graft together two values embedded in f such that the type is: f a -> f b, cf.

Prelude> let doubleAp f a = apply (v apply f) a

<interactive>:105:27: error:
    • Couldn't match expected type ‘(f0 (a0 -> b0) -> f0 a0 -> f0 b0)
                                    -> t -> f (a -> b)’
                  with actual type ‘Void’

3. This is the apply lifted by fmap, transformed from:

(f0 (a0 -> b0) into f0 a0 -> f0 b0

(The void error here is less useful)

Kicking in the contradiction we get for a if we replace it with the Void typed v variable:

Prelude> let doubleAp f a = apply (fmap apply f) v

<interactive>:107:41: error:
    • Couldn't match expected type ‘f1 (f a)’ with actual type ‘Void’
    • In the second argument of ‘apply’, namely ‘v’
      In the expression: apply (fmap apply f) v

Not bad eh? I find it’s better to teach people these techniques than to point them to typed holes, but reasonable minds disagree. Even when a learner is relatively early in the learning process, these techniques can be made approachable/digestible.

That’s all folks. Below is just a demonstration of the missing-constraint problem with an example from the Haskell Wiki.

Re-demonstration of the missing constraint problem using the Haskell Wiki’s example

module FreeMonad where
 
data Free f a
  = Pure a
  | Free (f (Free f a))

-- These are just to shut the compiler up, we
-- are not concerned with these right now.
instance Functor f => Functor (Free f) where
  fmap = undefined

instance Functor f => Applicative (Free f) where
  pure = undefined
  (<*>) = undefined

-- Okay, we do care about the Monad though.
instance Functor f => Monad (Free f) where
  return a     = Pure a
  Pure a >>= f = f a
  Free f >>= g = Free _a

code/FreeMonad.hs:20:23: error:
    • Found hole: _a :: f (Free f b)
      Where: ‘f’ is a rigid type variable bound by
               the instance declaration at code/FreeMonad.hs:17:10
             ‘b’ is a rigid type variable bound by
               the type signature for:
                 (>>=) :: forall a b. Free f a -> (a -> Free f b) -> Free f b
               at code/FreeMonad.hs:19:10
      Or perhaps ‘_a’ is mis-spelled, or not in scope
    • In the first argument of ‘Free’, namely ‘_a’
      In the expression: Free _a
      In an equation for ‘>>=’: (Free f) >>= g = Free _a
    • Relevant bindings include
        g :: a -> Free f b (bound at code/FreeMonad.hs:20:14)
        f :: f (Free f a) (bound at code/FreeMonad.hs:20:8)
        (>>=) :: Free f a -> (a -> Free f b) -> Free f b
          (bound at code/FreeMonad.hs:19:3)
Failed, modules loaded: none.

^^ Look ma, no Functor.

_a :: f (Free f b)

instance Functor f => Monad (Free f) where

Not consistently, but I’m more likely to get better type errors when I create contradictions manually via let expressions than I am using typed holes.

I know this site is a bit of a disaster zone, but if you like my writing or think you could learn something useful from me, please take a look at the Haskell book I've been writing. There's a free sample available too!

Posted on September 23, 2017

September 23, 2017 12:00 AM

GHC compiler plugins in the wild:<br/> typing Java

Facundo Domínguez, Mathieu Boespflug

Previously, we discussed how to use inline-java to call any Java function from Haskell. The reverse is also possible, though that will be a topic for a future post. In this post, we'll peek underneath the hood to talk a little about how inline-java does its deed.

You might find it an interesting read for at least the following reason: since the latest v0.7 release of inline-java, it's an example use of a recent feature of GHC called compiler plugins. These allow you to introspect and transform types and the abstract syntax tree before handing them off to later stages of the compiler pipeline. We use this to good effect in order to check that argument and return types on the Java side line up with those on the Haskell side (and vice versa).

Calling Java

inline-java makes it possible to invoke code written in Java using a Haskell language feature known as quasiquotes.

{-# LANGUAGE QuasiQuotes #-}
import Language.Java (withJVM)
import Language.Java.Inline

main :: IO ()
main = withJVM [] $ do
    let x = 1.5 :: Double
    y <- [java| { System.out.println($x);
                  return $x + 1;
                } |]
    print (y :: Double)

The function withJVM starts an instance of the Java Virtual Machine (JVM), and the java quasiquotation executes the Java code passed to it as a block of statements.

In this example, the Haskell value x of type Double is coerced into a Java value of primitive type double, which is then used whenever the antiquoted variable $x appears inside the quasiquotation. When the quasiquotation finishes executing, the Java value resulting from evaluating $x + 1 is coerced back to a Haskell value of type Double.

GHC doesn't parse or generate any Java. Neither does inline-java. So how can this program possibly work? The answer is that inline-java feeds the quasiquotation to the javac compiler, which generates some bytecode that is stored in the object file of the module. At runtime, inline-java arranges for the bytecode to be handed to the JVM using the jni package. Finally, inline-java makes use of the jvm package to have the bytecode executed.

Type safety

A notable characteristic of this approach is that we know at compile time if types are correct. We know that Java won't return an object if on the Haskell side we expect a double, because the Java side knows it's on the hook for handing us a double. javac will raise a compile time error if the Java code doesn't do that. Even if the Haskell side expected an object, say of type java.util.List, the Java quasiquotation can't return an object of type java.lang.String either. And conversely for arguments, Java and Haskell need to agree on the type of arguments, or a compile-time error ensues.

Given that no one compiler analyses both languages, how can type-checking work across language boundaries? Fortunately, both compilers can be put to cooperate on the task. First, GHC infers the types of the antiquoted variables and the return type which is expected of the quasiquotation. Then, these types are translated to Java types. The translation is conducted by a machinery of type classes living in the jvm package. The details of this process are not important at this point. What matters is that it enables us to translate types across languages. For instance,

Haskell type	Java type
Double	double
[Double]	double[]
ByteString	byte[]
Text	java.lang.String

The translated types are passed to javac together with the rest of the quasiquoted Java code. In our running example this would be

double fresh_name(double $x) {
    System.out.println($x);
    return $x + 1;
}

Finally, the javac compiler type checks the quasiquotation. Type mismatches will be discovered and reported at this stage.

It turns out that the first step is by far the most intricate. Specifically, for inline-java to query the types that GHC inferred for the antiquoted variables, and also query the type of the entire quasiquotation.

Looking for the types

At first, it appears as if determining these types is trivial. There is a Template Haskell primitive called reify.

reify :: Name -> Q Info

data Info =
      ...
    | VarI Name Type (Maybe Dec)	
      ...

Given an antiquoted variable $x, we ought to be able to use reify 'x to determine its Haskell type. Well, except that this doesn't quite work, because type checking is not finished when reify gets evaluated. From there, we went down a rabbit hole of trying to propose patches to Template Haskell to reliably get our hands on the inferred types. If you want to follow the intricacies of our journey, here are the related GHC issues for your amusement: initial discussion, 12777, 12778, 13608.

After many discussions with Simon Peyton Jones, and some deal of creative hacking, we could kind of get the inferred types for antiquoted variables, but only for as long as the java quasiquotation didn't appear inside Template Haskell brackets ([| ... |]). Moreover, we made no progress getting the expected type of the quasiquotation. Every idea we came up with required difficult compromises in the design. In the meantime, we had to choose between checking the type of the values returned by quasiquotations at runtime or using unsafe coercions, neither of which is an attractive option.

Eventually, we learnt that Template Haskell was not the only way to query the output of the type checker.

Enter GHC Core plugins

The GHC compiler uses an explicitly typed intermediate language known as Core. All type applications of terms in Core are explicit, making it possible to learn the types inferred at the type checking phase by inspecting Core terms. In order to get our hands on Core terms, we can use Core plugins. We could think of a Core plugin as a set of Core-to-Core passes that we can ask GHC to add to the compilation pipeline. The passes can be inserted anywhere in the Core pipeline, and in particular, they can be inserted right after desugaring, the phase which generates Core from the abstract syntax tree of a Haskell program.

Quasiquotations disappear from the abstract syntax tree when Template Haskell is executed. This happens well before the plugin passes. In order to enable the plugin to find the location of the quasiquotations, the quasiquoter can insert some artificial function call as a beacon or marker. In inline-java, our example program looks something as follows after Template Haskell runs.

main :: IO ()
main = withJVM [] $ do
    let x = 1.5 :: Double
    y <- qqMarker
	   "{ System.out.println($x); return $x + 1; }"
	   x
    print (y :: Double)

qqMarker :: forall args r. String -> args -> IO r
qqMarker = error "inline-java: The Plugin is not enabled."

The GHC Plugin is supposed to replace the call to qqMarker with an appropriate call to the generated Java method. The all-important point, however, is that the calls to qqMarker are annotated with the types we want to determine in Core.

main :: IO ()
main = ...
       qqMarker
         @ Double
         @ Double
         "{ System.out.println($x); return $x + 1; }"
	   ...

The type parameters provide us with the type of the antiquoted variable and the expected type of the quasiquotation. From here, the plugin has all the information it needs to generate the Java code to feed to javac. In addition, the plugin can inject the generated bytecode in the object file of the module, and it arranges for this bytecode to be located at runtime so it can be loaded in the JVM.

Now the user needs to remember to tell GHC to use the plugin by passing it the option -fplugin=Language.Java.Inline.Plugin. But this is only until Template Haskell learns the ability to tell GHC which plugins to use.

Summary

By using a GHC plugin, we have simplified inline-java from a complicated spaghetti which sprung from attempting to use Template Haskell's reify and didn't fully addressed the type lookup problem in a robust way. Now we have a straight forward story which starts by introducing the qqMarker beacons, attaches the Java bytecode in the plugin phase and ends by loading it at runtime into the JVM.

Writing a compiler plugin is similar to writing Template Haskell code. Both approaches need to manipulate abstract syntax trees. The plugin approach can be regarded as more coupled with a particular version of the compiler, since it relies on the internal Core language. However, Core changes relatively little over the years, and anyway, a pass that looks for some markers is hardly going to change a lot even if Core did change.

Many thanks to Simon Peyton Jones for his patience to walk with us over our attempts to fix Template Haskell. Without this dialog with the compiler implementors, it would have been difficult for us to explore as much of the design space as we needed to.

September 22, 2017 12:00 AM

New baby, and Haskell Alphabet

My wife and I just had a baby!

If you missed seeing me at ICFP, this is why.

In honor of my son’s birth (he will need to learn the alphabet and Haskell soon)—and at the instigation of Kenny Foner—I revived the Haskell Alphabet by converting it to modern Hakyll and updating some of the broken or outdated links. Some of it is a bit outdated (I wrote it seven years ago), but it’s still a fun little piece of Haskell history. Enjoy!

by Brent at September 21, 2017 06:46 PM

Shake 0.16 - revised rule definitions

Summary: I've just released shake v0.16. A lot has changed, but it's probably only visible if you have defined your own rules or oracles.

Shake-0.16 is now out, 8 months since the last release, and with a lot of improvements. For full details read the changelog, but in this post I'm going to go through a few of the things that might have the biggest impact on users.

Rule types redefined

Since the first version of Shake there has been a Rule key value type class defining all rule types - for instance the file rule type has key of filename and value of modification time. With version 0.16 the type class is gone, rules are harder to write, but offer higher performance and more customisation. For people using the builtin rule types, you'll see those advantages, and in the future see additional features that weren't previously possible. For people defining custom rule types, those will require rewriting - read the docs and if things get tough, ask on StackOverflow.

The one place many users might encounter the changes are that oracle rules now require a type instance defining between the key and value types. For example, if defining an oracle for the CompilerVersion given the CompilerName, you would have to add:

type instance RuleResult CompilerName = CompilerVersion

As a result of this type instance the previously problematic askOracle can now infer the result type, removing possible sources of error and simplifying callers.

The redefining of rule types represents most of the work in this release.

Add cmd_

The cmd_ function is not much code, but I suspect will turn out to be remarkably useful. The cmd function in Shake is variadic (can take multiple arguments) and polymorphic in the return type (you can run it in multiple monads with multiple results). However, because of the overloading, if you didn't use the result of cmd it couldn't be resolved, leading to ugly code such as () <- cmd args. With cmd_ the result is constrained to be m (), so cmd_ args can be used.

Rework Skip/Rebuild

Since the beginning Shake has tried to mirror the make command line flags. In terms of flags to selectively control rebuilding, make is based entirely on ordered comparison of timestamps, and flags such as --assume-new don't make a lot of sense for Shake. In this release Shake stops trying to pretend to be make, removing the old flags (that never worked properly) and adding --skip (don't build something even if it is otherwise required) and --build (build something regardless). Both these flags can take file patterns, e.g, --build=**/*.o to rebuild all object files. I don't think these flags are finished with, but it's certainly less of a mess than before.

by Neil Mitchell (noreply@blogger.com) at September 20, 2017 07:53 PM

Gompertz' law for wooden utility poles

Gompertz' law says that the human death rate increases exponentially with age. That is, if your chance of dying during this year is , then your chance of dying during next year is for some constant . The death rate doubles every 8 years, so the constant is empirically around . This is of course mathematically incoherent, since it predicts that sufficiently old people will have a mortality rate greater than 100%. But a number of things are both true and mathematically incoherent, and this is one of them. (Zipf's law is another.)

The Gravity and Levity blog has a superb article about this from 2009 that reasons backwards from Gompertz' law to rule out certain theories of mortality, such as the theory that death is due to the random whims of a fickle god. (If death were entirely random, and if you had a 50% chance of making it to age 70, then you would have a 25% chance of living to 140, and a 12.5% chance of living to 210, which we know is not the case.)

Gravity and Levity says:

Surprisingly enough, the Gompertz law holds across a large number of countries, time periods, and even different species.

To this list I will add wooden utility poles.

A couple of weeks ago Toph asked me why there were so many old rusty staples embedded in the utility poles near our house, and this is easy to explain: people staple up their yard sale posters and lost-cat flyers, and then the posters and flyers go away and leave behind the staples. (I once went out with a pliers and extracted a few dozen staples from one pole; it was very satisfying but ultimately ineffective.) If new flyer is stapled up each week, that is 52 staples per year, and 1040 in twenty years. If we agree that 20 years is the absolute minimum plausible lifetime of a pole, we should not be surprised if typical poles have hundreds or thousands of staples each.

But this morning I got to wondering what is the expected lifetime of a wooden utility pole? I guessed it was probably in the range of 40 to 70 years. And happily, because of the Wonders of the Internet, I could look it up right then and there, on the way to the trolley stop, and spend my commute time reading about it.

It was not hard to find an authoritative sounding and widely-cited 2012 study by electric utility consultants Quanta Technology.

Summary: Most poles die because of fungal rot, so pole lifetime varies widely depending on the local climate. An unmaintained pole will last 50–60 years in a cold or dry climate and 30-40 years in a hot wet climate. Well-maintained poles will last around twice as long.

Anyway, Gompertz' law holds for wooden utility poles also. According to the study:

Failure and breakdown rates for wood poles are thought to increase exponentially with deterioration and advancing time in service.

The Quanta study presents this chart, taken from the (then forthcoming) 2012 book Aging Power Delivery Infrastructures:

The solid line is the pole failure rate for a particular unnamed utility company in a median climate. The failure rate with increasing age clearly increases exponentially, as Gompertz' law dictates, doubling every 12½ years or so: Around 1 in 200 poles fails at age 50, around 1 in 100 of the remaining poles fails at age 62.5, and around 1 in 50 of the remaining poles fails at age 75.

(The dashed and dotted lines represent poles that are removed from service for other reasons.)

From Gompertz' law itself and a minimum of data, we can extrapolate the maximum human lifespan. The death rate for 65-year-old women is around 1%, and since it doubles every 8 years or so, we find that 50% of women are dead by age 88, and all but the most outlying outliers are dead by age 120. And indeed, the human longevity record is currently attributed to Jeanne Calment, who died in 1997 at the age of 122½.

Similarly we can extrapolate the maximum service time for a wooden utility pole. Half of them make it to 90 years, but if you have a large installed base of 110-year-old poles you will be replacing about one-seventh of them every year and it might make more sense to rip them all out at once and start over. At a rate of one yard sale per week, a 110-year-old pole will have accumulated 5,720 staples.

The Quanta study does not address deterioration of utility poles due to the accumulation of rusty staples.

by Mark Dominus (mjd@plover.com) at September 20, 2017 06:41 PM

Scrap Your Reprinter

Back in 2013, Andrew Rice and I were doing some initial groundwork on how to build tools to help scientists write better code (e.g., with the help of refactoring tools and verification tools). We talked to a lot of scientists who wrote Fortran almost exclusively, so we started creating infrastructure for building tools to work on Fortran. This was the kernel of the CamFort project for which we got an EPSRC grant in 2015 (which is ongoing). The CamFort tool now has a couple of fairly well developed specification/verification features, and a few refactoring features. Early on, I started building everything in Haskell using the brilliant uniplate library, based on the Scrap Your Boilerplate [1] work. This helped us to get the tool off the ground quickly by utilising the power of datatype generic programming. Fairly quickly we hit upon an interesting problem with building refactoring tools: how do you output source code for a refactored AST whilst preserving all the original comments and white space? It is not enough just to pretty print the AST, unless your AST contains all the comments and layout information. Building a parser to capture all this information is extremely hard, and we use a parser generator which limits flexibility (but is really useful for a large grammar). Another approach is to output patch/edit information for the original source code, calculated from the AST.

In the end, I came up with a datatype generic algorithm which I call the reprinter. The reprinter takes the original source code and an updated AST (which contains location information) and maps them into a new piece of source code. Here is an illustration which I’ll briefly explain:

Some source text (arithmetic code in prefix notation here) is parsed into an AST. The AST contains the “spans” of each syntactic fragment: the start position and end position in the original source code (for simplicity in this illustration, just the column number is represented). Some transformation/refactoring is applied next. In this case, the transformation rewrites redundant additions of 0, which happens in the node coming from source locations 10 to 16. The refactored node is marked in red. The reprinting then runs, stitching together the original source code with the updated source tree. A pretty printer is used to generate code for any new nodes, but all the original source text for the other nodes is preserved. The cool thing about this algorithm is that it is datatype generic: it works for any datatype, with some modest side conditions about storing source spans. The implementation uses the Scrap Your Zipper [2] library to do a context-dependent generic traversal of a datatype. In essence, the algorithm is similar to what one might do if you were to spit out edit information from an AST, then apply this to a piece of source text. But, the algorithm does this generically, and in a single simultaneous pass of the AST and the input source text.

I’ve always thought it was a cute and useful algorithm, which combined some cool techniques from functional programming.  As with all the “Scrap Your X” libraries it saves huge amounts of time and messing around, especially when your AST representation keeps changing (which it did/does for us). The algorithm is really useful anywhere you need to update human-written source code in a layout-preserving way; for example, IDEs and refactoring tools but also in interactive theorem provers and program synthesis tools, where you need to synthesise source text into some existing human-written code. This is one of the ways it is used in CamFort, where specifications are synthesised from code analysis data and then inserted as comments into user code.

This summer, I was fortunate enough to have the resources to hire several interns. One of the interns, Harry Clarke, (amongst other things) worked with me to tidy up the code for the reprinter, add some better interfaces, make it usable as a library for others, and write it all up. He presented the work at IFL 2017 and the pre-proceedings version of the paper is available. We are working on a post-proceedings version for December, so any comments gratefully appreciated.

---

[1] Lämmel, Ralf, and Simon Peyton Jones. Scrap your boilerplate: a practical design pattern for generic programming. Vol. 38. No. 3. ACM, 2003.

[2] Adams, Michael D. “Scrap your zippers: a generic zipper for heterogeneous types.” Proceedings of the 6th ACM SIGPLAN workshop on Generic programming. ACM, 2010.

by dorchard at September 20, 2017 03:20 PM

Registration for Haskell in Leipzig 2017 is open

Haskell in Leipzig 2017 opened its gates for everyone interested in Haskell and generally functional programming. Expect a great day of talks, tutorials, and a performance with a focus on FRP, followed by a Hackathon. Register early and get your ticket at a reduced rate. Looking forward to meeting you in Leipzig.

About

Haskell is a modern functional programming language that allows rapid development of robust and correct software. It is renowned for its expressive type system, its unique approaches to concurrency and parallelism, and its excellent refactoring capabilities. Haskell is both the playing field of cutting-edge programming language research and a reliable base for commercial software development.

The workshop series Haskell in Leipzig (HaL), now in its 12th year, brings together Haskell developers, Haskell researchers, Haskell enthusiasts, and Haskell beginners to listen to talks, take part in tutorials, join in interesting conversations, and hack together. To support the latter, HaL will include a one-day hackathon this year. The workshop will have a focus on functional reactive programming (FRP) this time, while continuing to be open to all aspects of Haskell. As in the previous year, the workshop will be in English.

Invited Speaker

• Ivan Perez, University of Nottingham, UK

Invited Performer

• Lennart Melzer, Robert-Schumann-Hochschule Düsseldorf, Germany

Registration

Registration information is available on the web page of the local organizers.

Program Committee

• Edward Amsden, Plow Technologies, USA
• Heinrich Apfelmus, Germany
• Jurriaan Hage, Utrecht University, The Netherlands
• Petra Hofstedt, BTU Cottbus-Senftenberg, Germany
• Wolfgang Jeltsch, Tallinn University of Technology, Estonia (chair)
• Andres Löh, Well-Typed LLP, Germany
• Keiko Nakata, SAP SE, Germany
• Henrik Nilsson, University of Nottingham, UK
• Ertuğrul Söylemez, Intelego GmbH, Germany
• Henning Thielemann, Germany
• Niki Vazou, University of Maryland, USA
• Johannes Waldmann, HTWK Leipzig, Germany

Tagged: conference, FRP, functional programming, Haskell

by Wolfgang Jeltsch at September 20, 2017 02:56 PM

August 2017 1HaskellADay 1Liners Problems and Solutions

• August 1st, 2017:
f :: (Maybe a, b) -> Maybe (a, b) Define points-free.
• August 1st, 2017:
  Given f above and f a and f b are mutually exclusive in Maybe monad, define
  g :: Maybe (a, b) -> Maybe (a, b) -> (Maybe a, b)
  points free
• August 1st, 2017:
  Now, let's define the dual of f
  f' :: Maybe (a, b) -> (Maybe a, b)
  points free

by geophf (noreply@blogger.com) at September 19, 2017 03:47 PM

Visualizing lazy evaluation

<script> function addScript(filename) { var scriptBlock=document.createElement('script') scriptBlock.setAttribute("type","text/javascript") scriptBlock.setAttribute("src", filename) document.getElementsByTagName("head")[0].appendChild(scriptBlock) } addScript("../../../aux/files/foldrl-animated/length-naive.js"); addScript("../../../aux/files/foldrl-animated/length-acc.js"); addScript("../../../aux/files/foldrl-animated/length-acc-strict.js"); addScript("../../../aux/files/foldrl-animated/mapM_Maybe.js"); </script>

Haskell and other call-by-need languages use lazy evaluation as their default evaluation strategy. For beginners and advanced programmers alike this can sometimes be confusing. At Well-Typed a core part of our business is teaching Haskell, which we do through public courses (such as the upcoming Skills Matter courses Fast Track to Haskell, Haskell Performance and Optimization and The Haskell Type System), private in-house courses targeted at specific client needs, and of course through writing blog posts.

In order to help us design these courses, we developed a tool called visualize-cbn. It is a simple interpreter for a mini Haskell-like language which outputs the state of the program at every step in a human readable format. It can also generate a HTML/JavaScript version with “Previous” and “Next” buttons to step through a program. We released the tool as open source to github and Hackage, in the hope that it will be useful to others.

The README.md file in the repo explains how to run the tool. In this blog post we will illustrate how one might take advantage of it. We will revisit the infamous triple of functions foldr, foldl, foldl', and show how they behave. As a slightly more advanced example, we will also study the memory behaviour of mapM in the Maybe monad. Hopefully, this show-rather-than-tell blog post might help some people understand these functions better.

Throughout this section we will use this definition of enumFromTo:

enumFromTo n m =
  if n <= m then n : enumFromTo (n + 1) m
            else []

so that, say, [1..3] corresponds to (enumFromTo 1 3).

foldr/foldrl/foldl'

In this section we will examine the difference between these three functions. We will not study these functions directly, however, but study a slightly simpler variant in the form of three definitions of length on lists. For a more in-depth discussion of this triple of functions, see our earlier blog post on this topic.

foldr

Consider the naive definition of length:

length xs =
  case xs of
    []      -> 0
    (x:xs') -> 1 + length xs'

This corresponds to defining length = foldr (\x n -> 1 + n) 0.

Let’s consider what happens when we compute length [1..3]; you can click on Prev and Next to step through the execution:

Prev Next (step Step, Status)

Term

Heap

When you step through this, notice what is going on:

• We first apply the definition of length.
• Then in step 1, length needs to do a case analysis, which forces us apply enumFromTo, and evaluate it until we have a top-level Cons constructor (in step 4)
• At that point we can execute the pattern match and the process continues.
• When we evaluate enumFromTo (add 1 1) 3 in step 6, note that the expression add 1 1 is only evaluated once, although it is used twice; this sharing of computation is what makes Haskell a true lazy (call-by-need) language (as opposed to a call-by-name language).
• In these animations these shared expressions are shown separately below the expression; you can think of this as the “heap”, and accordingly the animation also shows when these expressions are garbage collected (e.g. step 14).

Note as you step through that we have a build up of calls to add which are only resolved until the very end. This is the source of the memory leak in this definition of length (corresponding to foldr).

foldl

In a foldl-style definition of length, we introduce an accumulator:

length acc xs =
  case xs of
    []    -> acc
    x:xs' -> length (1 + acc) xs'

This corresponds to defining length = foldl (\n x -> 1 + n) 0.

Unlike the previous definition, this is tail-recursive; however, it still suffers from a memory leak due to Haskell’s extremely lazy nature. You will see why when you step through the execution:

Prev Next (step Step, Status)

Term

Heap

Notice how we are still building up a chain of additions, except they are now in the accumulator instead. This chain is only resolved (and garbage collected) at the very end (step 26).

foldl'

In the final definition, we make sure to evaluate the accumulator as we go:

length acc xs =
  case xs of
    []    -> acc
    x:xs' -> let acc' = add 1 acc in seq acc' (length acc' xs')

This corresponds to defining length = foldl' (\n x -> 1 + n) 0.

If you step through this note that we evaluate the accumulator immediately at each step, and moreover that garbage collection can now happen as we compute as well:

Prev Next (step Step, Status)

Term

Heap

mapM over the Maybe monad

As a final example of a slightly more advanced nature, try predicting what will happen when we run this in ghci:

case mapM return [1..] of Just (x:_) -> x

If you try it out and the result is not what you expected, perhaps stepping through the following evaluation of mapM return [1..3] to weak-head normal form (whnf: when there is a constructor at the top-level) will help you understand:

Prev Next (step Step, Status)

Term

Heap

Note that this expression reduces to whnf only after the entire list has been evaluated, and moreover that this requires an O(n) nested pattern matches. The take-away point from this example is that mapM should not be applied to long lists in most monads, as this will result in a memory leak.

Conclusion

Laziness can be tricky to understand sometimes, and being able to go through the evaluation of a program step by step can be very helpful. The visualize-cbn tool can be used to generate HTML/JavaScript files that can be used to visualize this evaluation as shown on this blog post; alternatively, it can also write the evaluation trace to the console. The source files (the various definitions of length) can be found in the repo. Feedback and pull requests are of course always welcome :)

by edsko at September 18, 2017 03:45 PM

Existential Serialisation

Summary: Using static pointers you can perform binary serialisation of existentials.

Many moons ago I asked how to write a Binary instance for a type including an existential, such as:

data Foo = forall a . (Typeable a, Binary a) => Foo a

Here we have a constructor Foo which contains a value. We don't statically know the type of the contained value, but we do know it has the type classes Typeable (so we can at runtime switch on its type) and Binary (so we can serialise it). But how can we deserialise it? We can store the relevant TypeRep when serialising, but when deserialising there is no mechanism to map from TypeRep to a Binary instance.

In Shake, I needed to serialise existentials, as described in the S4.1 of the original paper. My solution was to build a global mapping table, storing pairs of TypeRep and Binary instances for the types I knew were relevant. This solution works, but cannot deserialise anything that has not already been added to the global table, which required certain functions to live in weird places to ensure that they were called before deserialisation. Effective, but ugly.

Recently Abhiroop Sarkar suggested using the relatively new static pointers extension. This extension lets you turn top-level bindings with no arguments into a StaticPtr which can then be serialised/deserialsed, even between different instances of a process. To take advantage of this feature, we can redefine Foo as:

data Foo = forall a . (StaticFoo a, Binary a) => Foo a

class StaticFoo a where
    staticFoo :: a -> StaticPtr (Get Foo)

The approach is to switch from serialising the TypeRep (from which we try to look up Get Foo), to serialising the Get Foo directly. We can write a Binary Foo instance by defining put:

put :: Foo -> Put
put (Foo x) = do
    put $ staticKey $ staticFoo x
    put x

Here we simply grab a StaticPtr (Get Foo) which can deserialise the object, then use staticKey to turn it into something that can be serialised itself. Next, we write out the payload. To reverse this process we define get:

get :: Get Foo
get = do
    ptr <- get
    case unsafePerformIO (unsafeLookupStaticPtr ptr) of
        Just value -> deRefStaticPtr value :: Get Foo
        Nothing -> error "Binary Foo: unknown static pointer"

We first get the staticKey, use unsafeLookupStaticPtr to turn it into a StaticPtr (Get Foo) followed by deRefStaticPtr to turn it into a Get Foo. The unsafe prefix on these functions is justified - bugs while developing this code resulted in segfaults.

The final piece of the puzzle is defining StaticFoo instances for the various types we might want to serialise. As an example for String:

instance StaticFoo String where
    staticFoo _ = static (Foo <$> (get :: Get String))

We perform the get, wrap a Foo around it, and then turn it into a StaticPtr. All other types follow the same pattern, replacing String with Int (for example). The expression passed to static must have no free variables, including type variables, so we cannot define an instance for a, or even an instance for [a] - it must be [Char] and [Int] separately.

A complete code sample and test case is available here.

This approach works, and importantly allows extra constraints on the existential. The two disadvantages are: 1) that static isn't very flexible or easy to abstract over, resulting in a lot of StaticFoo boilerplate; 2) the static pointer is not guaranteed to be valid if the program changes in any way.

Will Shake be moving over to this approach? No. The next version of Shake has undergone an extensive rewrite, and in the process, moved away from needing this feature. A problem I had for 8 years has been solved, just as I no longer need the solution!

by Neil Mitchell (noreply@blogger.com) at September 17, 2017 11:46 AM

State of luminance

I’ve been a bit surprised for a few days now. Some rustaceans posted two links about my spectra and luminance crates on reddit – links here and here. I didn’t really expect that: the code is public, on Github, but I don’t communicate about them that much.

However, I saw interested people, and I think it’s the right time to write a blog post about some design choices. I’ll start off with luminance and I’ll speak about spectra in another blog post because I truly think spectra starts to become very interesting (I have my own shading language bundled up within, which is basically GLSL on steroids).

luminance and how it copes with fast and as-stateless-as-possible graphics

Origins

luminance is a library that I wrote, historically, in Haskell. You can find the package here if you’re interested – careful though, it’s dying and the Rust version has completely drifted path with it. Nevertheless, when I ported the library to Rust, I imported the same “way of programming” that I had·have in Haskell – besides the allocation scheme; remember, I’m a demoscener, I do care a lot about performance, CPU usage, cache friendliness and runtime size. So the Rust luminance crate was made to be hybrid: it has the cool functional side that I imported from my Haskell codebase, and the runtime performance I wanted that I had when I wrote my two first 64k in C++11. I had to remove and work around some features that only Haskell could provide, such as higher-kinded types, type families, functional dependencies, GADTs and a few other things such as existential quantification (trait objects saved me here, even though I don’t use them that much in luminance now).

I have to admit, I dithered a lot about the scope of luminance — both in Haskell and Rust. At first, I thought that it’d be great to have a “base” crate, hosting common and abstracted code, and “backend” crates, implementing the abstract interface. That would enable me to have several backends – OpenGL, Vulkan, Metal, a software implementation, something for Amiigaaaaaaa, etc. Though, time has passed, and now, I think it’s:

• Overkill.
• A waste of framework.

The idea is that if you need to be very low-level on the graphics stack of your application, you’re likely to know what you are doing. And then, your needs will be very precise and well-defined. You might want very specific piece of code to be available, related to a very specific technology. That’s the reason why abstracting over very low-level code is not a good path to me: you need to expose as most as posssible the low-level interface. That’s the goal of luminance: exposing OpenGL’s interface in a stateless, bindless and typesafe way, with no or as minimal as possible runtime overhead.

More reading here.

Today

Today, luminance is almost stable – it still receives massive architecture redesign from time to time, but it’ll hit the 1.0.0 release soon. As discussed with kvark lately, luminance is not about the same scope as gfx’s one. The goals of luminance are:

• To be a typesafe, stateless and bindless OpenGL framework.
• To provide a friendly experience and expose as much as possible all of the OpenGL features.
• To be very lightweight (the target is to be able to use it without std nor core).

To achieve that, luminance is written with several aspects in mind:

• Allocation must be explicitely stated by the user: we must avoid as much as possible to allocate things in luminance since it might become both a bottleneck and an issue to the lightweight aspect.
• Performance is a first priority; safety comes second. If you have a feature that can be either exclusively performant or safe, it must then be performant. Most of the current code is, for our joy, both performant and safe. However, some invariants are left around the place and you might shoot your own feet. This is an issue and some reworking must be done (along with tagging some functions and traits unsafe).
• No concept of backends will ever end up in luminance. If it’s decided to switch to Vulkan, the whole luminance API will and must be impacted, so that people can use Vulkan the best possible way.
• A bit like the first point, the code must be written in a way that the generated binary is as small as possible. Generics are not forbidden – they’re actually recommended – but things like crate dependencies are likely to be forbidden (exception for the gl dependency, of course).
• Windowing must not be addressed by luminance. This is crucial. As a demoscener, if I want to write a 64k with luminance, I must be able to use a library over X11 or the Windows API to setup the OpenGL context myself, set the OpenGL pointers myself, etc. This is not the typical usecase – who cares besides demosceners?! – but it’s still a good advantage since you end up with loose coupling for free.

The new luminance

luminance has received more attention lately, and I think it’s a good thing to talk about how to use it. I’ll add examples on github and its docs.rs online documentation.

I’m going to do that like a tutorial. It’s easier to read and you can test the code in the same time. Let’s render a triangle!

Note: keep in mind that you need a nightly compiler to compile luminance.

Getting your feet wet

I’ll do everything from scratch with you. I’ll work in /tmp:

$ cd /tmp

First thing first, let’s setup a lumitest Rust binary project:

$ cargo init --bin lumitest
  Created binary (application) project
$ cd lumitest

Let’s edit our Cargo.toml to use luminance. We’ll need two crates:

• The luminance crate.
• A way to open the OpenGL context; we’ll use GLFW, so the luminance-glfw crate.

At the time of writing, corresponding versions are luminance-0.23.0 and luminance-glfw-0.3.2.

Have the following [dependencies] section

[dependencies]
luminance = "0.23.0"
luminance-glfw = "0.3.2"

$ cargo check

Everything should be fine at this point. Now, let’s step in in writing some code.

extern crate luminance;
extern crate luminance_glfw;

use luminance_glfw::{Device, WindowDim, WindowOpt};

const SCREEN_WIDTH: u32 = 960;
const SCREEN_HEIGHT: u32 = 540;

fn main() {
  let rdev = Device::new(WindowDim::Windowed(SCREEN_WIDTH, SCREEN_HEIGHT), "lumitest", WindowOpt::default());
}

The main function creates a Device that is responsible in holding the windowing stuff for us.

Let’s go on:

match rdev {
  Err(e) => {
    eprintln!("{:#?}", e);
    ::std::process::exit(1);
  }

  Ok(mut dev) => {
    println!("let’s go!");
  }
}

This block will catch any Device errors and will print them to stderr if there’s any.

Let’s write the main loop:

'app: loop {
  for (_, ev) in dev.events() { // the pair is an interface mistake; it’ll be removed
    match ev {
      WindowEvent::Close | WindowEvent::Key(Key::Escape, _, Action::Release, _) => break 'app,
      _ => ()
    }
  }
}

This loop runs forever and will exit if you hit the escape key or quit the application.

Setting up the resources

Now, the most interesting thing: rendering the actual triangle! You will need a few things:

type Position = [f32; 2];
type RGB = [f32; 3];
type Vertex = (Position, RGB);

const TRIANGLE_VERTS: [Vertex; 3] = [
  ([-0.5, -0.5], [0.8, 0.5, 0.5]), // red bottom leftmost
  ([-0., 0.5], [0.5, 0.8, 0.5]), // green top
  ([0.5, -0.5], [0.5, 0.5, 0.8]) // blue bottom rightmost
];

Position, Color and Vertex define what a vertex is. In our case, we use a 2D position and a RGB color.

You have a lot of choices here to define the type of your vertices. In theory, you can choose any type you want. However, it must implement the Vertex trait. Have a look at the implementors that already exist for a faster start off!

Important: do not confuse between [f32; 2] and (f32, f32). The former is a single 2D vertex component. The latter is two 1D components. It’ll make a huge difference when writing shaders.

The TRIANGLE_VERTS is a constant array with three vertices defined in it: the three vertices of our triangle. Let’s pass those vertices to the GPU with the Tess type:

// at the top location
use luminance::tess::{Mode, Tess, TessVertices};

// just above the main loop
let triangle = Tess::new(Mode::Triangle, TessVertices::Fill(&TRIANGLE_VERTS), None);

This will pass the TRIANGLE_VERTS vertices to the GPU. You’re given back a triangle object. The Mode is a hint object that states how vertices must be connected to each other. TessVertices lets you slice your vertices – this is typically enjoyable when you use a mapped buffer that contains a dynamic number of vertices.

We’ll need a shader to render that triangle. First, we’ll place its source code in data:

$ mkdir data

Paste this in data/vs.glsl:

layout (location = 0) in vec2 co;
layout (location = 1) in vec3 color;

out vec3 v_color;

void main() {
  gl_Position = vec4(co, 0., 1.);
  v_color = color;
}

Paste this in data/fs.glsl:

in vec3 v_color;

out vec4 frag;

void main() {
  frag = vec4(v_color, 1.);
}

And add this to your main.rs:

const SHADER_VS: &str = include_str!("../data/vs.glsl");
const SHADER_FS: &str = include_str!("../data/fs.glsl");

Note: this is not a typical workflow. If you’re interested in shaders, have a look at how I do it in spectra. That is, hot reloading it via SPSL (Spectra Shading Language), which enables to write GLSL modules and compose them in a single file but just writing functions. The functional programming style!

Same thing as for the tessellation, we need to pass the source to the GPU’s compiler to end up with a shader object:

// add this at the top of your main.rs
use luminance::shader::program::Program;

// below declaring triangle
let (shader, warnings) = Program::<Vertex, (), ()>::from_strings(None, SHADER_VS, None, SHADER_FS).unwrap();

for warning in &warnings {
  eprintln!("{:#?}", warning);
}

Finally, we need to tell luminance in which framebuffer we want to make the render. It’s simple: to the default framebuffer, which ends up to be… your screen’s back buffer! This is done this way with luminance:

use luminance::framebuffer::Framebuffer;

let screen = Framebuffer::default([SCREEN_WIDTH, SCREEN_HEIGHT]);

And we’re done for the resources. Let’s step in the actual render now.

The actual render: the pipeline

luminance’s approach to render is somewhat not very intuitive yet very simple and very efficient: the render pipeline is explicitly defined by the programmer in Rust, on the fly. That means that you must express the actual state the GPU must have for the whole pipeline. Because of the nature of the pipeline, which is an AST (Abstract Syntax Tree), you can batch sub-parts of the pipeline (we call such parts nodes) and you end up with minimal GPU state switches. The theory is as following:

• At top most, you have the pipeline function that introduces the concept of shading things to a framebuffer.
• Nested, you find the concept of a shader gate. That is, an object linked to its parent (pipeline) and that gives you the concept of shading things with a shader.
  • Nested, you find the concept of rendering things. That is, can set on such nodes GPU states, such as whether you want a depth test, blending, etc.
  • Nested, you find the concept of a tessellation gate, enabling you to render actual Tess objects.

That deep nesting enables you to batch your objects on a very fine granularity. Also, notice that the functions are not about slices of Tess or hashmaps of Program. The allocation scheme is completely ignorant about how the data is traversed, which is good: you decide. If you need to borrow things on the fly in a shading gate, you can.

Let’s get things started:

use luminance::pipeline::{entry, pipeline};

entry(|_| {
  pipeline(&screen, [0., 0., 0., 1.], |shd_gate| {
    shd_gate.shade(&shader, |rdr_gate, _| {
      rdr_gate.render(None, true, |tess_gate| {
        let t = ▵
        tess_gate.render(t.into());
      });
    });
  });
});

We just need a final thing now: since we render to the back buffer of the screen, if we want to see anything appear, we need to swap the buffer chain so that the back buffer become the front buffer and the front buffer become the back buffer. This is done by wrapping our render code in the Device::draw function:

dev.draw(|| {
  entry(|_| {
    pipeline(&screen, [0., 0., 0., 1.], |shd_gate| {
      shd_gate.shade(&shader, |rdr_gate, _| {
        rdr_gate.render(None, true, |tess_gate| {
          let t = ▵
          tess_gate.render(t.into());
        });
      });
    });
  });
});

You should see this:

As you can see, the code is pretty straightforward. Let’s get deeper, and let’s kick some time in!

use std::time::Instant;

// before the main loop
let t_start = Instant::now();
// in your main loop
let t_dur = t_start.elapsed();
let t = (t_dur.as_secs() as f64 + t_dur.subsec_nanos() as f64 * 1e-9) as f32;

We have the time. Now, we need to pass it down to the GPU (i.e. the shader). luminance handles that kind of things with two concepts:

• Uniforms.
• Buffers.

Uniforms are a good match when you want to send data to a specific shader, like a value that customizes the behavior of a shading algorithm.

Because buffers are shared, you can use buffers to share data between shader, leveraging the need to pass the data to all shader by hand – you only pass the index to the buffer that contains the data.

We won’t conver the buffers for this time.

Because of type safety, luminance requires you to state which types the uniforms the shader contains are. We only need the time, so let’s get this done:

// you need to alter this import
use luminance::shader::program::{Program, ProgramError, Uniform, UniformBuilder, UniformInterface, UniformWarning};

struct TimeUniform(Uniform<f32>);

impl UniformInterface for TimeUniform {
  fn uniform_interface(builder: UniformBuilder) -> Result<(Self, Vec<UniformWarning>), ProgramError> {
    // this will fail if the "t" variable is not used in the shader
    //let t = builder.ask("t").map_err(ProgramError::UniformWarning)?;

    // I rather like this one: we just forward up the warning and use the special unbound uniform
    match builder.ask("t") {
      Ok(t) => Ok((TimeUniform(t), Vec::new())),
      Err(e) => Ok((TimeUniform(builder.unbound()), vec![e]))
    }
  }
}

The UniformBuilder::unbound is a simple function that gives you any uniform you want: the resulting uniform object will just do nothing when you pass values in. It’s a way to say “— Okay, I don’t use that in the shader yet, but don’t fail, it’s not really an error”. Handy.

And now, all the magic: how do we access that uniform value? It’s simple: via types! Have you noticed the type of our Program? For the record:

let (shader, warnings) = Program::<Vertex, (), ()>::from_strings(None, SHADER_VS, None, SHADER_FS).unwrap();

See the type is parametered with three type variables:

• The first one – here Vertex, our own type – is for the input of the shader program.
• The second one is for the output of the shader program. It’s currently not used at all by luminance by is reserved, as it will be used later for enforcing even further type safety.
• The third and latter is for the uniform interface.

You guessed it: we need to change the third parameter from () to TimeUniform:

let (shader, warnings) = Program::<Vertex, (), TimeUniform>::from_strings(None, SHADER_VS, None, SHADER_FS).unwrap();

And that’s all. Whenever you shade with a ShaderGate, the type of the shader object is being inspected, and you’re handed with the uniform interface:

shd_gate.shade(&shader, |rdr_gate, uniforms| {
  uniforms.0.update(t);

  rdr_gate.render(None, true, |tess_gate| {
    let t = ▵
    tess_gate.render(t.into());
  });
});

Now, change your fragment shader to this:

in vec3 v_color;

out vec4 frag;

uniform float t;

void main() {
  frag = vec4(v_color * vec3(cos(t * .25), sin(t + 1.), cos(1.25 * t)), 1.);
}

And enjoy the result! Here’s the gist that contains the whole main.rs.

by Dimitri Sabadie (noreply@blogger.com) at September 14, 2017 03:58 PM

PPDP & LOPSTR 2017: Call for Participation

***********************************************

           CALL FOR PARTICIPATION


PPDP 2017

  19th International Symposium on
  Principles and Practice of Declarative Programming
  Namur, Belgium, October 9-11

  http://complogic.cs.mcgill.ca/ppdp2017

co-located with


LOPSTR 2017

  27th International Symposium on
  Logic-Based Program Synthesis and Transformation
  Namur, Belgium, October 10-12

  https://www.sci.unich.it/lopstr17/

***********************************************

Registration is now open:

https://events.info.unamur.be/ppdp-lopstr-2017/

** Early registration deadline: September 15, 2017 **


INVITED TALKS:

Marieke Huisman (Universiteit Twente)
A Verification Technique for Deterministic Parallel Programs
(joint PPDP/LOPSTR speaker)

Sumit Gulwani (Microsoft)
Programming by Examples: Applications, Algorithms, and Ambiguity Resolution
(joint PPDP/LOPSTR speaker)

Serge Abiteboul (INRIA)
Ethical issues in data management
(PPDP)

Grigore Rosu (University of Illinois at Urbana-Champaign)
K: A Logic-Based Framework for Program Transformation and Analysis
(LOPSTR)

Please consult the conferences' webpages for a list of accepted papers.

Hope to see you in Namur !

by Tom Schrijvers (noreply@blogger.com) at September 12, 2017 07:27 AM

Less parentheses

Yesterday, at the Haskell Implementers Workshop 2017 in Oxford, I gave a lightning talk titled ”syntactic musings”, where I presented three possibly useful syntactic features that one might want to add to a language like Haskell.

The talked caused quite some heated discussions, and since the Internet likes heated discussion, I will happily share these ideas with you

Context aka. Sections

This is probably the most relevant of the three proposals. Consider a bunch of related functions, say analyseExpr and analyseAlt, like these:

analyseExpr :: Expr -> Expr
analyseExpr (Var v) = change v
analyseExpr (App e1 e2) =
  App (analyseExpr e1) (analyseExpr e2)
analyseExpr (Lam v e) = Lam v (analyseExpr flag e)
analyseExpr (Case scrut alts) =
  Case (analyseExpr scrut) (analyseAlt <$> alts)

analyseAlt :: Alt -> Alt
analyseAlt (dc, pats, e) = (dc, pats, analyseExpr e)

You have written them, but now you notice that you need to make them configurable, e.g. to do different things in the Var case. You thus add a parameter to all these functions, and hence an argument to every call:

type Flag = Bool

analyseExpr :: Flag -> Expr -> Expr
analyseExpr flag (Var v) = if flag then change1 v else change2 v
analyseExpr flag (App e1 e2) =
  App (analyseExpr flag e1) (analyseExpr flag e2)
analyseExpr flag (Lam v e) = Lam v (analyseExpr (not flag) e)
analyseExpr flag (Case scrut alts) =
  Case (analyseExpr flag scrut) (analyseAlt flag <$> alts)

analyseAlt :: Flag -> Alt -> Alt
analyseAlt flag (dc, pats, e) = (dc, pats, analyseExpr flag e)

I find this code problematic. The intention was: “flag is a parameter that an external caller can use to change the behaviour of this code, but when reading and reasoning about this code, flag should be considered constant.”

But this intention is neither easily visible nor enforced. And in fact, in the above code, flag does “change”, as analyseExpr passes something else in the Lam case. The idiom is indistinguishable from the environment idiom, where a locally changing environment (such as “variables in scope”) is passed around.

So we are facing exactly the same problem as when reasoning about a loop in an imperative program with mutable variables. And we (pure functional programmers) should know better: We cherish immutability! We want to bind our variables once and have them scope over everything we need to scope over!

The solution I’d like to see in Haskell is common in other languages (Gallina, Idris, Agda, Isar), and this is what it would look like here:

type Flag = Bool
section (flag :: Flag) where
  analyseExpr :: Expr -> Expr
  analyseExpr (Var v) = if flag then change1 v else change2v 
  analyseExpr (App e1 e2) =
    App (analyseExpr e1) (analyseExpr e2)
  analyseExpr (Lam v e) = Lam v (analyseExpr e)
  analyseExpr (Case scrut alts) =
    Case (analyseExpr scrut) (analyseAlt <$> alts)

  analyseAlt :: Alt -> Alt
  analyseAlt (dc, pats, e) = (dc, pats, analyseExpr e)

Now the intention is clear: Within a clearly marked block, flag is fixed and when reasoning about this code I do not have to worry that it might change. Either all variables will be passed to change1, or all to change2. An important distinction!

Therefore, inside the section, the type of analyseExpr does not mention Flag, whereas outside its type is Flag -> Expr -> Expr. This is a bit unusual, but not completely: You see precisely the same effect in a class declaration, where the type signature of the methods do not mention the class constraint, but outside the declaration they do.

Note that idioms like implicit parameters or the Reader monad do not give the guarantee that the parameter is (locally) constant.

More details can be found in the GHC proposal that I prepared, and I invite you to raise concern or voice support there.

Curiously, this problem must have bothered me for longer than I remember: I discovered that seven years ago, I wrote a Template Haskell based implementation of this idea in the seal-module package!

Less parentheses 1: Bulleted argument lists

The next two proposals are all about removing parentheses. I believe that Haskell’s tendency to express complex code with no or few parentheses is one of its big strengths, as it makes it easier to visualy parse programs. A common idiom is to use the $ operator to separate a function from a complex argument without parentheses, but it does not help when there are multiple complex arguments.

For that case I propose to steal an idea from the surprisingly successful markup language markdown, and use bulleted lists to indicate multiple arguments:

foo :: Baz
foo = bracket
        • some complicated code
          that is evaluated first
        • other complicated code for later
        • even more complicated code

I find this very easy to visually parse and navigate.

It is actually possible to do this now, if one defines (•) = id with infixl 0 •. A dedicated syntax extension (-XArgumentBullets) is preferable:

• It only really adds readability if the bullets are nicely vertically aligned, which the compiler should enforce.
• I would like to use $ inside these complex arguments, and multiple operators of precedence 0 do not mix. (infixl -1 • would help).
• It should be possible to nest these, and distinguish different nesting levers based on their indentation.

Less parentheses 1: Whitespace precedence

The final proposal is the most daring. I am convinced that it improves readability and should be considered when creating a new language. As for Haskell, I am at the moment not proposing this as a language extension (but could be convinced to do so if there is enough positive feedback).

Consider this definition of append:

(++) :: [a] -> [a] -> [a]
[]     ++ ys = ys
(x:xs) ++ ys = x : (xs++ys)

Imagine you were explaining the last line to someone orally. How would you speak it? One common way to do so is to not read the parentheses out aloud, but rather speak parenthesised expression more quickly and add pauses otherwise.

We can do the same in syntax!

(++) :: [a] -> [a] -> [a]
[]   ++ ys = ys
x:xs ++ ys = x : xs++ys

The rule is simple: A sequence of tokens without any space is implicitly parenthesised.

The reaction I got in Oxford was horror and disgust. And that is understandable – we are very used to ignore spacing when parsing expressions (unless it is indentation, of course. Then we are no longer horrified, as our non-Haskell colleagues are when they see our code).

But I am convinced that once you let the rule sink in, you will have no problem parsing such code with ease, and soon even with greater ease than the parenthesised version. It is a very natural thing to look at the general structure, identify “compact chunks of characters”, mentally group them, and then go and separately parse the internals of the chunks and how the chunks relate to each other. More natural than first scanning everything for ( and ), matching them up, building a mental tree, and then digging deeper.

Incidentally, there was a non-programmer present during my presentation, and while she did not openly contradict the dismissive groan of the audience, I later learned that she found this variant quite obvious to understand and more easily to read than the parenthesised code.

Some FAQs about this:

• What about an operator with space on one side but not on the other? I’d simply forbid that, and hence enforce readable code.
• Do operator sections still require parenthesis? Yes, I’d say so.
• Does this overrule operator precedence? Yes! a * b+c == a * (b+c).
• What is a token? Good question, and I am not not decided. In particular: Is a parenthesised expression a single token? If so, then (Succ a)+b * c parses as ((Succ a)+b) * c, otherwise it should probably simply be illegal.
• Can we extend this so that one space binds tighter than two spaces, and so on? Yes we can, but really, we should not.
• This is incompatible with Agda’s syntax! Indeed it is, and I really like Agda’s mixfix syntax. Can’t have everything.
• Has this been done before? I have not seen it in any language, but Lewis Wall has blogged this idea before.

Well, let me know what you think!

by Joachim Breitner (mail@joachim-breitner.de) at September 10, 2017 10:10 AM

What's new in Cabal/cabal-install 2.0 — improved new-build, Backpack, foreign libraries and more!

A couple of weeks ago we’ve quietly released versions 2.0 of both Cabal and cabal-install after approximately a year of development. The 2.0 release incorporates more than 1500 commits by 64 different contributors. This post serves as a formal release announcement and describes what’s new and improved in version 2.0.

There is a number of backwards-incompatible Cabal library API changes in this release that affect packages with Custom setup scripts. Therefore cabal-install will by default use a previous version of Cabal to build setup scripts that don’t explicitly declare compatibility with Cabal 2.0. The 2.0 migration guide gives advice for package authors on how to adapt Custom setup scripts to backwards-incompatible changes in this release.

Major new features

• Much improved new-build feature (also known as nix-style local builds), that solves many long-standing problems and is going to become the default mode of operation of cabal-install in version 3.0 (tentative release date: Autumn 2018). Killer features of new-build are reproducible isolated builds with global dependency caching and multi-package projects. For a more extensive introduction to new-build, see this blog post by Edward Z. Yang.

• Support for Backpack, a new system for mix-in packages. See this article by Edward Z. Yang for an introduction to Backpack and its features.

• Native suport for foreign libraries: Haskell libraries that are intended to be used by non-Haskell code. See this section of the user guide for an introduction to this feature.

• Convenience/internal libraries are now supported (#269). An internal library is declared using the stanza library 'libname' and can be only used by other components inside a package.

• Package components can be now built and installed in parallel. This is especially handy when compiling packages with large numbers of independent components (usually those are executables). As a consequence, the Setup.hs command-line interface now allows to specify the component to be configured.

• Nix package manager integration (#3651).

• New cabal-install command: outdated, for listing outdated version bounds in a .cabal file or a freeze file (#4201). Work on this feature was sponsored by Scrive AB.

• New cabal-install command reconfigure, which re-runs configure with the most recently used flags (#2214).

• Package repos are now assumed to be hackage-security-enabled by default. If a remote-repo section in ~/.cabal/config doesn’t have an explicit secure field, it now defaults to secure: True, unlike in cabal-install 1.24. See this post on the Well-Typed blog for an introduction to hackage-security and what benefits it brings.

• New caret-style version range operator ^>= (#3705) that is equivalent to >= intersected with an automatically inferred major upper bound. For example, foo ^>= 1.3.1 is equivalent to foo >= 1.3.1 && < 1.4. Besides being a convenient syntax sugar, ^>= allows to distinguish “strong” and “weak” upper bounds: foo >= 1.3.1 && < 1.4 means “I know for sure that my package doesn’t work with foo-1.4”, while foo ^>= 1.3.1 means “I don’t know whether foo-1.4, which is not out yet, will break my package, but I want to be cautious and follow PVP”. In the future, this feature will allow to implement automatic version bounds relaxation in a formally sound way (work on this front is progressing on matrix.hackage.haskell.org). See this section of the manual for more information.

• Changed cabal upload to upload a package candidate by default (#3419). Same applies to uploading documentation. Also added a new cabal upload flag --publish for publishing a package on Hackage instead of uploading a candidate (#3419).

• Support for --allow-older (dual to --allow-newer) (#3466).

• New build-tool-depends field that replaces build-tools and has a better defined semantics (#3708, #1541). cabal-install will now install required build tools and add them to PATH automatically.

• New autogen-modules field for automatically generated modules (like Paths_PACKAGENAME) that are not distributed inside the package tarball (#3656).

• Added a new scope field to the executable stanza (#3461). Executable scope can be either public or private; private executables are those that are expected to be run by other programs rather than users and get installed into $libexecdir/$libexecsubdir. Additionally, $libexecdir now has a subdir structure similar to $lib(sub)dir to allow installing private executables of different packages and package versions alongside one another.

• New --index-state flag for requesting a specific version of the package index (#3893, #4115).

• Added CURRENT_PACKAGE_VERSION CPP constant to cabal_macros.h (#4319).

Minor improvements and bug fixes

• Dropped support for versions of GHC earlier than 6.12 (#3111). Also, GHC compatibility window for the Cabal library has been extended to five years (#3838).

• Added a technical preview version of the ‘cabal doctest’ command (#4480).

• Cabal now invokes GHC with -Wmissing-home-modules, if that flag is supported (added in version 8.2). This means that you’ll get a warning if you forget to list a module in other-modules or exposed-modules (#4254).

• Verbosity -v now takes an extended format which allows specifying exactly what you want to be logged. The format is [silent|normal|verbose|debug] flags, where flags is a space separated list of flags. At the moment, only the flags +callsite and +callstack are supported; these report the call site/stack of a logging output respectively (these are only supported if Cabal is built with GHC 8.0/7.10.2 or greater, respectively).

• The -v/--verbosity option no longer affects GHC verbosity (except in the case of -v0). Use --ghc-options=-v to enable verbose GHC output (#3540, #3671).

• Packages which use internal libraries can result in multiple registrations; thus --gen-pkg-config can now output a directory of registration scripts rather than a single file.

• Changed the default logfile template from .../$pkgid.log to .../$compiler/$libname.log (#3807).

• Macros in ‘cabal_macros.h’ are now #ifndef’d, so that they don’t cause an error if the macro is already defined (#3041).

• Added qualified constraints for setup dependencies. For example, --constraint="setup.bar == 1.0" constrains all setup dependencies on bar, and --constraint="foo:setup.bar == 1.0" constrains foo’s setup dependency on bar (part of #3502).

• Non-qualified constraints, such as –constraint=“bar == 1.0”, now only apply to top-level dependencies. They don’t constrain setup or build-tool dependencies. The new syntax --constraint="any.bar ==1.0" constrains all uses of bar.

• Added a new solver flag, --allow-boot-library-installs, that allows normally non-upgradeable packages like base to be installed or upgraded (#4209). Made the ‘template-haskell’ package non-upgradable again (#4185).

• Fixed password echoing on MinTTY (#4128).

• Added optional solver output visualisation support via the tracetree package (#3410). Mainly intended for debugging.

• New ./Setup configure flag --cabal-file, allowing multiple .cabal files in a single directory (#3553). Primarily intended for internal use.

• Removed the --check option from cabal upload (#1823). It was replaced by Hackage package candidates.

• Removed the --root-cmd parameter of the ‘install’ command and deprecated cabal install --global (#3356).

• Removed the top-down solver (#3598).

• Cabal no longer supports using a version bound to disambiguate between an internal and external package (#4020). This should not affect many people, as this mode of use already did not work with the dependency solver.

• Miscellaneous minor and/or internal bug fixes and improvements.

See the full Cabal 2.0 and cabal-install 2.0 changelogs for the complete list of changes in the 2.0 release.

Acknowledgements

Thanks to everyone who contributed code and bug reports. Full list of people who contributed patches to Cabal/cabal-install 2.0 is available here.

Looking forward

We plan to make a new release of Cabal/cabal-install before the end of the year – that is, around December 2017. We want to decouple the Cabal release cycle from the GHC one; that’ll allow us to release a new version of Cabal/cabal-install approximately every six months in the future. Main features that are currently targeted at the 2.2 milestone are:

• Further improvements in new-build, incorporating work done by Francesco Gazzetta during HSOC 2017. Currently we are planning to make new-build the default in the 3.0 release (tentative release date: Autumn 2018).

• New Parsec-based parser for .cabal files, joint work by Oleg Grenrus and Duncan Coutts. Faster, less memory hungry, and easier to extend.

• A revamped homepage for Cabal, rewritten user manual, and automated build bots for binary releases. Help in this area would be appreciated!

We would like to encourage people considering contributing to take a look at the bug tracker on GitHub, take part in discussions on tickets and pull requests, or submit their own. The bug tracker is reasonably well maintained and it should be relatively clear to new contributors what is in need of attention and which tasks are considered relatively easy. Additionally, the list of potential projects from the latest hackathon and the tickets marked “easy” and “newcomer” can be used as a source of ideas for what to work on.

For more in-depth discussion there is also the cabal-devel mailing list and the #hackage IRC channel on FreeNode.

September 09, 2017 12:00 AM

Backend Ruby and Haskell engineer at Health eFilings (Full-time)

Our backend engineering team manages the ingestion and normalization of data sets, from data extraction through to product delivery. We want to work smarter instead of harder, and create domain specific languages, meta-programming etc. where possible.

Our current code base is written in Ruby and Coffee Script, but some new modules are being written in Haskell. You will be on the front lines of creating a Haskell-based infrastructure that is maintainable and can scale to support our needs as we grow.

We currently expect that about 80% of your work will be in Ruby/CoffeeScript, and 20% in Haskell, but that ratio will decrease over time as we move more of our functionality to Haskell. (The faster you can work to migrate functionality to Haskell, the more Haskell you will be doing.)

WHAT WE WILL EXPECT FROM YOU

You will have ownership of an entire module, including responsibility for:

• Creating new features in a clean and maintainable way
• Re-factoring existing code to ensure that we stay agile
• Reviewing teammates’ code and providing feedback
• Keeping yourself focused and your projects on track
• An “I can run through walls” mentality to ensure that goals are met
• Answering questions from our implementation team and squashing bugs on a monthly support rotation

We are a small team (four engineers), and so it is critical that you be a team player, willing to pitch in and help out your colleagues.

WHAT YOU CAN EXPECT FROM US

• Autonomy to solve problems in the way you best see fit
• A manager who is accountable for ensuring you meet your professional goals
• A team who helps each other and always strives to improve
• The time to focus on creating the right solution, instead of the easiest one

REQUIREMENTS

• Professional experience as a software engineer
• Experience with Haskell and Ruby
• A desire for continual self-improvement
• An understanding of best practices regarding maintainability and scalability
• Must have US work authorization and be located in the US (we cannot sponsor visas at this time)
• There are no formal education requirements for this position

BONUS POINTS

• Experience with data scraping and parsing

LOCATION

This is expected to be a remote position, although our Madison, Wisconsin office is also available as a work location.

Get information on how to apply for this position.

September 08, 2017 09:43 PM

ICFP / FSCD day 1 – rough notes

(Blog posts for Day 1, Day 2, Day 3, Day 4 (half day))

I decided to take electronic notes at ICFP and FSCD (colocated) this year, and following the example of various people who put their conference notes online (which I’ve found useful), I thought I would attempt the same. However, there is a big caveat: my notes are going to be partial and may be incorrect; my apologies to the speakers for any mistakes.

• (ICFP Keynote) Computational Creativity, Chris Martens
• (FSCD Keynote) Brzozowski Goes Concurrent, Alexandra Silva
• (ICFP) Faster Coroutine Pipelines, Mike Spivey
• (ICFP) A pretty but not greedy printer (Functional pearl), Jean-Philippe Bernardy
• (ICFP) Generic Functional Parallel Algorithms: Scan and FFT, Conal Elliott
• (ICFP) A Unified Approach to Solving Seven Programming Problems (Functional Pearl) – William E. Byrd, Michael Ballantyne, Gregory Rosenblatt, Matthew Might
• (FSCD) Relating System F and λ2: A Case Study in Coq, Abella and Beluga – Jonas Kaiser, Brigitte Pientka, Gert Smolka
• (ICFP) A Framework for Adaptive Differential Privacy, Daniel Winograd-Cort, Andreas Haeberlen, Aaron Roth, Benjamin C. Pierce
• (ICFP) Symbolic Conditioning of Arrays in Probabilistic Programs, Praveen Narayanan, Chung-chieh Shan
• (ICFP) Abstracting Definitional Interpreters, David Darais, Nicholas Labich, Phúc C. Nguyễn, David Van Horn
• (ICFP) On the Expressive Power of User-Defined Effects: Effect Handlers, Monadic Reflection, Delimited Control, Yannick Forster, Ohad Kammar, Sam Lindley, Matija Pretnar
• (ICFP) Imperative Functional Programs That Explain Their Work, Wilmer Ricciotti, Jan Stolarek, Roly Perera, James Cheney
• (ICFP) Effect-Driven QuickChecking of Compilers, Jan Midtgaard, Mathias Nygaard Justesen, Patrick Kasting, Flemming Nielson, Hanne Riis Nielson

---

(ICFP keynote #1) Computational Creativity, Chris Martens (slides)

In the early days, automated theorem proving by computers was seen as an AI activity. Theorem proving, program synthesis, and AI planning are search procedures but can be viewed as creative procedures.

Linear logic is useful for describing plots (story telling).

There is a difference between what an AI opponent and AI cooperator should do: an opponent need not make intelligible moves, but a cooperator needs to act in a way that is intelligible/understandable to the human player.

Applied Grice’s maxims of conversation to build an “intentional” cooperative player for the Hanabi game. Grice’s maxims are: quantity (not too much or little), quality (tell the truth), relation (be relevant), manner (avoid ambiguity).

Theory of mind: forming mental models of other people’s mental models.

Dynamic epistemic logic, has two indexed modalities:
  (agent ‘a’ believes A)
  (A holds true after action ).

Actions are defined inductively:

Semantics is based on a possible worlds formulation (current actions change future possible worlds). Ostari (Eger & Martens) is a full epistemic logic language that can capture lots of different games with different kinds of knowledge between players.

Key point: use compositionally (of various kinds) as a design principle

Three research challenges:

• Dynamic logics with functional action languages
• Constructive/lambda-calculable DEL
• Epistemic session types

---

(FSCD keynote #1) Brzozowski Goes Concurrent – Alexandra Silva

Ongoing project CoNeCo (Concurrency, Networks, and Coinduction)

SDN – Software Defined Network architectures let you write a program for the network controller. Requires languages for the controller to interact with the underlying switches / routers. Goals of new network PL: raise the level of abstraction beyond the underlying OpenFlow API– make it easier to reason about. Based on Kleene algebra.

NetKat – based on regular expression (Kleene algebra) with tests (KAT) + additional specialized constructions relating to networking. This is compiled to OpenFlow.

Kleene algebra, e.g., – multiples of 3 in binary.

For reasoning about imperative programs, this can be extended with the idea of ‘tests’ (Kozen). Need to capture more of the control flow graph, but there are guards (tests). The solution is to split the underlying alphabet of the Kleene algebra into two: one for actions and one for tests: combine a Kleene algebra and a Boolean algebra (where there is negation), e.g. $\bar{b}$ is the negation of b. Then the three standard control flow constructs of an imperative language are defined:

Subsumes Hoare logic, i.e.:

Decidable in PSPACE.

What is the minimum number of constructs needed to be added to KAT to deal with packet flow?

A packet is an assignment of constant values n to fields x a packet history is a nonempty sequence of packets. Include assignments (field <- value) and tests on fields (filed = value). e.g.,

sw = 6; pt = 88; dest <- 10.0.0.1; pt <- 50

For all packets incoming on port 88 of switch 6 set the destination IP to 10.0.0.1 and send the packet to port 50.

Can then reason about reachability (can two hosts communicate)? Security (does all untrusted traffic pass through an intrusion detection)? loop detection (packet to be stuck in a forwarding cycle).

Since networks are non-deterministic, this has been adapted to probabilistic NetKAT.

Can we add concurrency to NetKAT (deal with interaction between different components): within this paradigm, can we add concurrency to Kleene algebra? Concurrent Kleene algebra adds a parallel composition || (cf. Hoare 2011). Would like to reason about weak memory model like behaviour (cf. Sewell’s litmus tests). There were developments in concurrent Kleene algebra, but a solid foundations was not yet available.

Have proved a Kleene theorems: equivalence between Kleene algebra and finite automata. In this case, the corresponding automata to a concurrent Kleene algebra is a pomset automata.

Can make Concurrent Kleene algebras into regular subsets of pomsets (useful model of concurrency, cf Gischer) i.e., .

Pomset automata- has the idea of splitting into two threads (two paths) that once they reach their accept states, then go onto the next state of the originating state (can be expressed as multiple automata). This reminds me of Milner’s interleaving semantics (for atomic actions) in CCS. Alphabet of the automata is a pomset over some other alphabet of actions.

Showed the (Brzozowski) construction to build an automata from a Concurrent Kleene algebra term, and then how to go back from automata to expressions.

The exchange law captures the interaction of sequential and parallel interaction. Currently working on extending the Kleene theorem in this work to include the exchange law.

---

(ICFP) Faster Coroutine Pipelines, Mike Spivey

(I missed the start and had some trouble catching up).

Coroutine pipelines are a way to structure stream-processing programs. There are libraries for doing this that are based on a term encoding that is then interpreted which suffers serious slow-down when there is process nesting. This paper proposes an alternate approaching using continuation which doesn’t suffer these slow down problems.

The direct style can be mapped to the CPS style which is a monad morphism between two Pipe monads (capturing the coroutine pipelines). To show that the two models are equivalent could be done with logical relations (Mike recommended Relating models of backtracking by Wand and Vaillancourt (2004)).

Termination. Consider a situation:

where then terminates.

Need to end up with not . (I wasn’t sure if this was an open question or whether there was a solution in this paper).

Ohad Kammar asked on the ICFP slack whether this relates to
Ploeg and Kiselyov’s paper at Haskell 2014 but this didn’t get asked.

---

(ICFP) A pretty but not greedy printer (Functional pearl), Jean-Philippe Bernardy

(slides: https://github.com/jyp/prettiest/blob/master/talk/Outline.org)

Hughes proposed a pretty printing approach, which was improved upon by Wadler. For example, if you want to pretty print some SExpr but with a maximum column width: when do you spill onto the next line?

Proposes three laws of pretty-printing:
1). Do not print beyond the right margin
2). Do not reveal the structure of the input
3). Use as few lines as possible.

(Hughes breaks 3 and Wadler breaks 2 (I didn’t spot how in the talk)).
These three rules are not compatible with a greedy approach.
This work trades performance for being law-abiding instead.

A small API is provided to write pretty printers (four combinators:
text, flush, (horizontal composition), ).

Phil Wadler asked how you represent hang in the library. JP quickly typed up the solution:
hang x y = (x text " " y) (x $$ (text " " y))

Phil countered that he could do the same, but JP answered that it didn’t have the expected behaviour. I’m not entirely sure what hang does, but in the Hughes-based library (https://hackage.haskell.org/package/pretty-1.1.3.5/docs/Text-PrettyPrint.html), hang :: Doc -> Int -> Doc -> Docwith behaviour like:

Prelude Text.PrettyPrint> hang (text "Foo\nBar") 0 (text "Bar")
Foo
Bar Bar

(not sure what the extra Int argument is for).

---

(ICFP) Generic Functional Parallel Algorithms: Scan and FFT – Conal Elliott

Arrays are the dominant type for parallel programming, but FP uses a variety of data types. Generic programming decomposes data types into fundamental building blocks (sums, products, composition).

Perfect trees can be represented as a n-wise composition of a functor $h$.

Prefix sum (left scan)

for , e.g., scan [1,2,3,4] = [1,3,6,10]
Define more generally as:

class Functor f => LScan f where
  lscan :: Monoid a => f a -> f a x a

Instances were then given for the components of a datatype generic representation, (constant types, type variable, sum, product, composition) which gives data type generic scan. (Insight: Do left scans on left vectors, not left scans on right vectors! The latter adds a lot of overhead).

Data types were describe numerically, e.g., 2 is a pair, is a 4-vector.

Can do the esame with Discrete Fourier Transform. A nice property is that a
DFT can be factored into separate parts (Johnson 2010, e.g., a 1D DFT of size N = N1*N2 is equivalent to a 2D DFT of size N1xN2– I couldn’t see this so well on the slide as I was in the overflow room).

---

(ICFP) A Unified Approach to Solving Seven Programming Problems (Functional Pearl) – William E. Byrd, Michael Ballantyne, Gregory Rosenblatt, Matthew Might

Started off referencing http://matt.might.net/articles/i-love-you-in-racket/ – 99 ways to say “I love you” in Racket (all based on different list operations). But what if you wanted more, for some other language? How could you generate this, to say get 1000, or 10000 such examples? The solution put forward here is to using miniKanren, the constraint logic language. The eval function is turned into a relation then can be “run” in reverse, (i.e., run 99 (q) (evalo q '(I love you)) gives 99 S-expressions that evaluate to ​(I love you)). What about for generating quines (programs that evaluate to themselves)? (run 1 (e) (evalo e e)) produced just the 0 expression and getting three results was just 0, #t and #f but with 4 it produced a more interesting quine.

Then, William showed (run n (p q) (eval p q) (evalo q p) (/= q p) generating “twines” (pair of mutually producing programs). This was then applied to a proof checker to turn it into an automated theorem prover! The same technology was used then for program synthesis (although some additional work was needed under the hood to make it fast enough).

---

(FSCD) Relating System F and λ2: A Case Study in Coq, Abella and Beluga – Jonas Kaiser, Brigitte Pientka, Gert Smolka

System F (Girard ’72): Two-sorted, types and terms, based on the presentation of System F in Harper’13. Meanwhile, study of CC lead to Pure Type Systems- System F appeared in the Lambda Cube at the corner . This work shows the formal relation (that indeed these two systems are equivalent). A proof is partially given in Geuvers ’93, but a full Coq formalisation was given by Kaiser, Tebbi and Smolka at POPL 2017. In this work, the proof is replayed across three tools to provide a useful comparison of the three systems: Coq, Abella and Beluga.

A complication is that the syntax is non-uniform on the System F side: in PTS can correspond to and . Have to also keep track of context assumptions. One (of many) “topics of interest” in this comparison is how to manage contexts (which is interesting to me as I am quite interested in CMTT in Beluga).

The approaches were:

• Coq – first-order de Bruijn indices, parallel substitutions (Autosubst library), and invariants (e.g, a context can be extended with a new term variable). Inductive predicate for typing judgments. Traversal of binders requires context adjustments.
• Abella – HOAS, nominal quantification (fresh names handled internally), relation proof search [Abella has two layers: specification and logic]. Contexts represented by lists (as in Coq). A compound inductive predicate is define to relate the different context representations (and to keep them all consistent).
• Beluga – HOAS, 1st class contexts (via Contextual Modal Type Theory) and context schemas. Object K (e.g., terms, types, deriviations) are alway paired with a 1-st class context that gives it meaning . There is no concept of free variable., e.g., in Coq is provable but in Belluga is not even well formed (accessing the first variable 0 (think de Bruijns) in an empty context). Context schemas provide a way to give the structure of the typed contexts (as a dependent record).

---

(ICFP) A Framework for Adaptive Differential Privacy – Daniel Winograd-Cort, Andreas Haeberlen, Aaron Roth, Benjamin C. Pierce

Associated GitHub: https://github.com/dwincort/AdaptiveFuzz

They created a new language, Adaptive Fuzz for adaptive differential privacy (DP), uses Fuzz type checking to verify individual pieces in a piecewise static way.

DFuzz is a dependently typed version of Fuzz, can we use this? Privacy cost dependent on feature selection: which could depend on values in the databases: but this is practically useless as we don’t know what is in the database. We can still get static guarantees if it is done piece-wise in two modes: data mode (access to sensitive data, uses the Fuzz type checker to provide DP proofs) and adaptive mode (computation between pieces). End up with “light” dependent types.

These two modes have the same syntax though (code it one works in the other). Here is an example type for a function that scales one number by the other (multiplication by abs):

(scale the second number by the first argument). In adaptive mode the annotations are ignored, in data mode the first argument is forced to be a constant (partial evaluation happens under the hood so we don’t need dependent types really).

General scheme is: analyst (program) writes data mode code, it is partially evaluated and the Fuzz type checker works out a cost, which is the compared against a privacy filter (where/how is this defined?) Can write a gradient descent algorithm with different levels of randomness provided by different privacy budgets (how much information do we want to reveal at the end, e.g., if budget is infinite then you get not noise in the result). (another example in the paper is feature selection).

This seems like a really interesting mix of a static and semi-static approach (via partial evaluation). I wonder how this relates to fine-grained cost-tracking type systems?

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(ICFP) – Symbolic Conditioning of Arrays in Probabilistic Programs –
Praveen Narayanan, Chung-chieh Shan

(tag line: Bayesian inference via program transformation).
Say you are benchmarking some iterative code, which you model by for some startup cost and iterations and a cost for the loop. You might then collect some results and do linear regression (best fist line) to see if this model is confirmed. Bayesian linear regression gives you many lines for different kinds of fit.

1. Write a generative model, e.g., some normally distributed to generate a set of possible lines (normally distributed gradients), to which we maybe then add some additional normally distributed noise for each point.  (k measurements)
2. Observe running times
3. Infer distribution of lines. Delete those candidates from the generative model that weren’t observed (from step 2), keep the ones that were.

Bayesian inference is compositional: you can build it from different components, by treating distributions as programs (e.g., a program normal (a * n_1 + b) is gives us one of the lines in the generative model) and then transforming the program. A program transformation implements the model-theoretic notion of “disintegration” but the existing approach for this is problematic (I wasn’t quite clear on how). A new transformation approach is proposed which provides a smaller output program via some additional combinators which replace an unrolled set of observations into a replication like combination (plate).

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(ICFP) Abstracting Definitional Interpreters – David Darais, Nicholas Labich, Phúc C. Nguyễn, David Van Horn

Definitional interpreters: programs that take ASTs and run them, giving an executable semantics. Key challenge: a parameterised interpreter that recovers both concrete and abstract semantics.

A concrete interpreter for the lambda calculus: exp -> m (val) where m is a monad which (at least) captures the environment and the store (which is used for representing the variable environment). The definition is written non-recursive “unfixed” (unrolled), which can be fixed (e.g., apply to Y combinator) later to run the interpreter. By leaving it unfixed, we can interpose different behaviour in the recursive cases.

To make the interpreter abstract, abstract the primitive operations and types, e.g., integers are extended with an ‘abstract’ value, i.e., where 'N represents the abstract integer. The semantics is then main non-deterministic so that an iszero? predicate on 'N splits into two execution traces. But its partial (could run forever).

How to make it total (always terminating). Look for states that it has already seen before, sufficient for termination but unsound for abstraction. If you observe fact 'N then one branch fails (non-terminating as visit previous state) and the 1 branch succeeds, so the result is just 1 (not ideal). Instead, look in a “cache” of precomputed values to return something like [[fact 'N]] = {1} U {'N x $[fact 'N]}. Intercept recursion points to evaluate through a cache and to stop when a previously computed value is hit (sounds space intensive?).

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(ICFP) – On the Expressive Power of User-Defined Effects: Effect Handlers, Monadic Reflection, Delimited Control – Yannick Forster, Ohad Kammar, Sam Lindley, Matija Pretnar

Say you want to write a program like:

toggle = { x <- get!
           y <- not! x
           put! y
           x }

If we don’t have effects, then we can do explicit state passing, but you have to do a full rewrite. Ideally want only local transformations. (Ohad showed this in three different styles, see below).

Relative expressiveness in language design, compare/contrast: (1 – Eff) algebraic effects and handlers (2 – Mon) monads (3 – Del) delimited control. Did this by extending CBPV in these three directions (and formalised this in Abella) and defining macro translations between every pair of these extended languages. Expressivity is stated as formal translations between calculi. Then this was considering in the typed setting. Interestingly there is no typed macro translation from Eff to Del nor from Eff to Mon.

[There is a large design space which yields lots of different languages, this study is a start. Inexpressivity is brittle: adding other language features can change the result.]

In the Eff version, we give standard state handlers to implement get and put. Its type contains the effect-system like information State = {get : 1 -> bit, put : bit -> 1}where toggle : U_State F bit.

In the Mon version, monadic reflection is used with a state monad.
(Q: put was of type U (bit -> F) but I thought the monad would be T = U F?)

(Q: In the translation from Mon -> Eff, how do generate the effect type if the source program only uses put or get ? I guess it just maps to the set of all effect operations).

(Q: the talked showed just simple state effects; are the results shown for any other kind of effect).

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(ICFP) – Imperative Functional Programs That Explain Their Work – Wilmer Ricciotti, Jan Stolarek, Roly Perera, James Cheney

https://github.com/jstolarek/slicer

Slicing can be used to explain particular (parts of) a program output: which parts of the source code contributed to a value. Extend TML (Transparent ML) to Imperative TML.

Construct backwards and forward slicing as a Galois connection (between two lattices). The lattices are based on the idea of definedness: where ‘holes’ make programs more undefined, e.g., is above and (partial expressions). Forward slicing preserves meets in the lattice; backward slicing should be consistent and minimal with respect to forward slicing (I missed what this meant exactly, but I talked to Janek later to clarify: consistency is ). The idea then is that we have and which form a Galois connection, i.e., . [Given one of the slicings we don’t necessarily get the other for free].

Given a small program l1 := 0; (!l1, !l2) a partial version of it ; (!l1, !l) and an initial store [l1 -> 1, l2 -> 2] should forward slice to (, 2) by propagating the “hole” through the store.

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(ICFP) Effect-Driven QuickChecking of Compilers – Jan Midtgaard, Mathias Nygaard Justesen, Patrick Kasting, Flemming Nielson, Hanne Riis Nielson

They made a generator for writing OCaml programs: useful for automated testing, e.g., comparing two compilers against each other (compile -> run -> diff, any difference will be suspicious).

Generated a program let k = (let i = print_newline () in fun q -> fun i -> "") () in 0 which found a bug: different behaviour between the native code generator and the bytecode generator due to effects being delayed (indefinitely). Another example was found (related), due to effects being removed.

Program generation, how to do it:

• Try: generate arbitrary strings?! Most won’t lex or parse).
• Instead, follow the grammar (see Celento et al ’80). Most won’t type check!
• Instead, follow the simply-typed lambda calculus (Palka et al. ’11) by bottom-up reading of a typing relation. This will make it through the type checker (I guess you can generalise the type rules).

Observed behaviour in OCaml depends on evaluation order (when effects are involved). OCaml bytecode uses right-to-left but sometimes native code backend uses left-to-right (hm!) But the specification is itself a bit loose. Can we avoid generating such programs since they are not well specified for anyway?

• Instead, following a type-and-effect systems which has one bit for marking pure/effectful (boolean lattice effect system). Extend to a pair of bits, where the second bit is order dependence (extend the effect algebra a bit more). Our goal is then a program which may have effects but may not have order-dependent effects.

Have an effect-dependent soundness theorem (that the effect bits correctly anticipate the effects).

Next, there is a type preserving shrinker to reduce huge ugly generated programs into a minimal (much nicer) example. e.g., replace a pure integer expression by a literal 0 and large literals by small literals, replace beta-redexes by let bindings, etc. Shrunk tests are checked whether they still show a difference.

A question was asked whether the effect-based mechanism could be used to rule-out other allowed difference, e.g., in floating point. Jan answered that floating point isn’t generated anyway, but an interesting idea.

Another question: how do you avoid generating non-terminating programs? Jan explained that since it is STLC (+ extension) only total terms are generated.

by dorchard at September 08, 2017 01:05 PM

FSCD day 4 – rough notes

(Blog posts for Day 1, Day 2, Day 3, Day 4 (half day))

I decided to take electronic notes at ICFP and FSCD (colocated) this year, and following the example of various people who put their conference notes online (which I’ve found useful), I thought I would attempt the same. However, there is a big caveat: my notes are going to be partial and may be incorrect; my apologies to the speakers for any mistakes.

• (FSCD Keynote #3) Type systems for the relational verification of higher order programs, Marco Gaboardi
• (FSCD) Arrays and References in Resource Aware ML, Benjamin Lichtman, Jan Hoffmann
• (FSCD) The Complexity of Principal Inhabitation, Andrej Dudenhefner, Jakob Rehof
• (FSCD) Types as Resources for Classical Natural Deduction, Delia Kesner, Pierre Vial

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(FSCD Keynote #3) Type systems for the relational verification of higher order programs, Marco Gaboardi

Relational properties . For example, take and to be notions of program equivalence (equivalent inputs produce equivalent outputs). Another relation might be in information-flow security where relations mean “these two programs are low-level equivalent” (low-security).
Another is differential privacy where means two programs differ in one individual data point and  .

In relational cost analysis, we want to compute the difference in cost (the relative cost) between the two programs (may depend on the input and the underlying relation), e.g., (giving an upper bound computed in terms of the inputs and underlying relations). This is useful for guaranteeing compile optimisations (not worse, or definitely better), ruling out side-channel attacks (i.e., the , such that different inputs do not yield different costs thus information about the inputs is not leaked).

Motivating example 1: find in a list of lists (2D data structure). We want to prove that one implementation of this algorithm is faster than the other (I’ve omitted the code that Marco showed us, which was expressed via a common higher-order function with two different parameter functions to give the two implementations).
Motivating example 2: prove a precise upper bound on the relative cost of insertion sort between two lists (different by in length).

[Clarkson, Schneider ’08] – formalises the idea of ‘hyperproperties’. Properties are sets of traces, hyperproperties are sets of sets of traces. Relation verification is a set of pair of traces (a 2-property). They show how to reduce verification of hyperproperties into the verification of properties. Using these kind of results requires encodings, they do not reflect the relational nature of the property, and they do not reflect the connection of the relational reasoning to the programs syntax (see the talk from ICFP day 2, on A Relational Logic for Higher-order Programs). Lots of previous work (going back to Abadi’s System R).

Relational typing: . Talk about relational properties of the input and relational properties of the output. Usually, if we interpret to relations then we want to prove soundness as: .\
How can we reason about the cost? Two approaches from here: (1) lightweight typing  (bottom up) extending type system with the necessary constructors, (2) heavyweight typing (top down) use a powerful type system and encode the needed constructions. (In the future, we want to find a balance between the two approaches).

Approach (1) (lightweight) called Relcost a relational refinement type-and-effect system. The idea is to take advantage of structural similarities between programs and inputs as much as possible. There will be two sorts of type (unary and relational). Typing judgments where is the upper bound and is the lower bound execution cost, which are thought of as a unary effect. A relational judgement where is the upper bound on the relative cost of the two programs. The types have an annotation function type (like in normal effect systems) and data types for integers and lists have indices to express dependencies.

e.g. .
But if we know that is known to be this can be refined (with the type in the indices, which will change the bound to $\vdash^{k+1}_{k+1}$.

The relational types are a little different. There is still a latent effect on function types, but is now a single relative cost .
Judgements are like the following, which says equal integers have zero cost: .

The unary cost and relational cost are connected as follows:

Thus, we can drop into the unary cost to compute a worst and best run time individual, and then combine these into a relative cost.
There is a box modality which captures terms which have the same cost and allow a reseting therefore of the differential cost, e.g., if we have identical terms then:
.
The type captures lists which differ in less than positions. This interacts with the type in order to capture the notion of differing numbers of elements in the list.
In the semantics, the relative cost is pushed inside the semantics (some step-indexed logical relations are used, details not shown).
Going back to the earlier example of searching nested lists, we see a typing of and meaning has a relatively smaller cost. Plugging this into the higher-order function and doing the type derivation again gives a looser bound.

Approach (2) is the heavyweight approach was presented earlier at ICFP (A Relational Logic for Higher-order Programs), the language RHOL (Relational Higher Order Logic). Has relational and unary judgments, where the relational rule is which contains term variable assertions and relational assertion . In the type system, some rules are synchronous (building up the related two terms with the same syntactic construct) or asynchronous (building up one of the terms).

HOL terms can be encoded into RHOL, and vice versa (a bit like the hyperproperty result of Clarkson/Schneider), but RHOL is much easier to work with for relational reasoning but also all the power of HOL can be embedded into RHOL.
The system is a monadic meta language with a specific cost effect (with introducing a cost. Intuition: if a term is closed and $m \Downarrow_n v$ then $m \cong \textsf{cstep}_n(v)$.We can define formulae in HOL which all us to reason about these explicit cost terms and their quantities: we can define what we need in the logic.

For computing a relative upper bound on the insertion sort, we want to prove . Using the system , we can prove this property, using a suitable invariant/predicate over the input and output list(s).

Take home: type-based relational verification is a large research space that needs more work.

Q: what about recursion? In the first system, letrec is included straightforwardly, in the second system the assumption is terminating (general) recursion.
Q: are the costs tied to a specific evaluation strategy? Yes, but one can encode different ones in the system. (Both systems are parametric in the way you count cost). In the first system, this is part of the typing, in the second, this comes where you put monadic cost operations .

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(FSCD) Arrays and References in Resource Aware ML, Benjamin Lichtman, Jan Hoffmann

Resource-aware ML (RAML) – model resource usages of programs with cost semantics, e.g., implement Quicksort and it produce the bound (I forgot what the constant c was). This work introduces references and arrays to enable analysis of programs where resource consumption depends on the data stored in mutable structures (references and arrays).

How does it work? Automatic amortized resource analysis. Assign “potential” functions to a data structures, which will pay the resource consumption cost, then hopefully there is some left over for later. This propagates backwards to give the overall upper bound cost.

Each variable in scope may contribute (carry) potential, e.g., recursive data types (such as that is it can contribute units of potential where is the length of the list.

Based on an affine type system (all variable used at most once). Subexpressions are bound to variables whenever possible (share-let normal form) in order to explicitly track when things are evaluated (via variables). When a variable carrying potential needs to be shared, the potential can be explicitly split share x as (x1, x2) in e in order to use a variable more than once (gives you contraction). This splits the potential of across the two variables. Benjamin walked us through a nice example with appending to a list.

Now let’s add references.

g l = 
  let t = ref l in 
  share r as (r1, r2) in  -- r2 : L^1 (int)
  let _ = h r1 in   -- h : (L^q int) ref -> int  
                    -- (need to make the type of this stronger)
  append (!r2, []) -- append : L^1(int) * L^0(int) -> L^0(int)

One approach is to carry around extra information about possible effects, but they want to keep effects out of the type system because they seem them as cumbersome and difficult to use. Instead, strengthen contracts by require that potential annotations of data inside references are fixed.

g l = 
  let t = ref l in 
  share r as (r1, r2) in  -- the restricted h means r1 and r2 have 
                          -- to have the same type
  let _ = h r1 in   -- h : (L^1 int) ref -> int  
  append (!r2, [])

Introduce a swap command as the only way to update a cell, that behaves like:

swap (r, l) = let x = !r in (let _ = r := l in x)

Requires that data placed into a cell has the same type as data being taken out, ensures that potential annotations of mutable cells never change (the only way to update a cell). Thus, swap is the well-typed version of dereference in situations where you need to work with potential. Thus, require the previous program to use swap on r2 with an empty list instead of a direct dereference in the last line.

The paper has a detailed example of depth-first search (stateful) which shows more of the details related to how to work with state and potentials. This also utilises an idea of “wrapper” types.

Introduce a notion of “memory typing”, which tracks all memory locations pointed to by mutual references, this is require to prove the soundness of the cost analysis (based on the free potential of the system, the potential of the context, and the potential of each mutable memory reference).

Mutable arrays were then a natural extension from this basis, with an array-swap operation for updating an array cell.

In the future, they’d like to create some syntactic sugar so that the programming style is not affected as much by having to instead swap, aswap, and wrapper types. Would like to investigate how fixed potential annotations restrict the inhabitants of a type (Yes, yes, this is very interesting!)

I asked about what happens if you write down Landin’s Knot to get recursion via higher-order state: Benjamin answered that functions don’t get given potential so storing and updating functions in a reference would type correctly. I still wonder if this would let me get the correct potential bounds for a recursive algorithm (like DFS) if the recursion was implemented via higher-order state.

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(FSCD) The Complexity of Principal Inhabitation, Andrej Dudenhefner, Jakob Rehof

In the simply-typed lambda calculus (STLC), with principle types. We say is the principle type of if and for all types such that there exists a substitution such that .

Definition: (Normal Principal Inhabitant), We say that a term M in beta-normal form is a normal principal inhabitant of a type t, if t is the principal type of M.

This work shows that principal inhabitation for STLC is PSPACE-complete (in 1979 it was shown that inhabitation (not considering) principality is PSPACE-complete).  Thus, this work seeks to answer the following: since principality is a global property of derivations, does it increase the complexity of inhabitation? This is also practically interesting for type-based program synthesis, since a normal principal inhabitant of a type is a natural implementation of the type.

For example, is inhabited by the K combinator but is not principally inhabited (I haven’t understood why yet).

The proof is based on the subformula calculus. The subformula calculus provides paths to index types (as trees) which are strings of either 1 or 2.  This is useful for reasonable about subformulae, where the usual STLC rules are re-expressed in terms of type paths, e.g., . Define relations on paths, as the minimal equivalence relation for a beta-normal term (capture constraints on subformulae of terms) and  which defines an equivalence relation on paths of paths with common subpaths (capture constraints on subformulae on types).

(I had to step out, so missed the end).

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(FSCD) Types as Resources for Classical Natural Deduction, Delia Kesner, Pierre Vial

Quantitative types seen as resources (can’t be duplicated); they provide simple arithmetical arguments to prove operational equivalences. These ideas are extended to classical logic in this talk.

In simple types, typability implies normalisation. With intersection types this is an equivalence, i.e., normalising also implies typability. In an intersection type system, a variable can be assigned several types, e.g. (note the two occurrences of ) where intersection is associative, commutative and (possibly) idempotent. In 1994, Gardner introduces a system which is not idempotent, where types are now multisets (rather than sets in the earlier formulations). This has the flavour of linear logic resources (my interpretation: the types can then capture how many times a variable is used (quantitative) if we contraction takes the intersection of the two types and intersection is non-idempotent, e.g., ).

In the literature, we see how to build a computational interpretation of classical natural deduction: Intuitionistic Logic + Peirce’s law gives classical logic and Felleisen’s call-cc operator gives the computational interpretation. Relatedly, the lambda_mu calculus (Parigot 92) give a direct interpretation of classical natural deduction.

Types are strict where intersection can only appear on the left-hand side of a function arrow.

Interestingly, you can have a situation where the type of a lambda abstraction has an empty intersection of types in its source type. In order to get normalisation in this context, the system was extended a bit to deal with this (I didn’t capture this part, see paper). The full system had rules to ensure this didn’t happen.

A notion of “weighted” subject reduction is defined, where the size of a derivation tree is strictly decreasing during reduction.

by dorchard at September 07, 2017 10:58 AM

ICFP / FSCD day 2 – rough notes

(Blog posts for Day 1, Day 2, Day 3, Day 4 (half day))

I decided to take electronic notes at ICFP and FSCD (colocated) this year, and following the example of various people who put their conference notes online (which I’ve found useful), I thought I would attempt the same. However, there is a big caveat: my notes are going to be partial and may be incorrect; my apologies to the speakers for any mistakes.

• (ICFP) ICFP day 2 keynote – Challenges in Assuring AI, John Launchbury
• (FSCD) FSCD day 2 keynote – Uniform resource analysis by rewriting: strengths and weakeness, Georg Moser
• (FSCD) Continuation Passing Style for Effect Handlers, Daniel Hillerström, Sam Lindley, Bob Atkey, KC Sivaramakrishnan
• (ICFP How to Prove Your Calculus Is Decidable: Practical Applications of Second-Order Algebraic Theories and Computation, Makoto Hamana
• (ICFP) A Relational Logic for Higher-Order Programs, Alejandro Aguirre, Gilles Barthe, Marco Gaboardi, Deepak Garg, Pierre-Yves Strub
• (ICFP) Foundations of Strong Call by Need, Thibaut Balabonski, Pablo Barenbaum, Eduardo Bonelli, Delia Kesner
• (ICFP) No-Brainer CPS Conversion, Milo Davis, William Meehan, Olin Shivers
• (ICFP) Compiling to Categories, Conal Elliott
• (ICFP) Visitors Unchained, François Pottier
• (ICFP) Staged Generic Programming, Jeremy Yallop

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(ICFP Keynote #2) – Challenges in Assuring AI, John Launchbury

The moment we think we’ve got our (verification) hands round the world’s systems (e.g., compilers), a whole new set of systems appear: AI.

The dual of “have I tested enough?” is “how good is my model?” (in a verification-based approach). What is the model we have for AI systems?

What is intelligence? Information processing. But there are different kinds of information processing ability; asking if a system is ‘intelligent’ is too coarse/binary. John breaks this down into ‘perceiving’ P, ‘learning’ L, ‘abstracting’ A (create new meanings), and ‘reasoning’ R (plan and decide).

AI wave 1 : rule-based, hand-crafted knowledge: P 1, L 0, A 0, R 3 (poor handling of uncertainty, no learning). Type systems are a little like this (perceiving, didn’t have to tell it everything). Can do some pretty amazing stuff: see smart security systems that analysis code and patch bugs.

AI wave 2: statistical learning. Specific problem domains, train them on big data. Still requires a lot of engineering work (to get the right models and statistical techniques for the task). P 3, L 3, A 1, R 1 (less good at reasoning).

What does it mean to prove a vision system correct?

Manifold hypothesis – data coming in is high-dimensional but the features you are interested in form lower-dimensional structures. E.g., with cars, lots of data comes in but understanding the data means separating the manifolds (of low dimensionality).
Another example, a 28×28 image is a 784 dimensional space (as in 784 numbers, 784-length vector). Variation in handwritten digits form 10 distinct manifolds within the 784 dimensional space. High-degree of coherence between all data samples for a particular digit. (“Manifold” here may be slightly more informally used than the full mathematical definition).

Imagine two interlocking spiral arms which are really 1-dimensional manifolds in a 2-dimensional space. By continuous transforms on the 2-dimensional space these can morphed into linearly separable components. Sometimes stretching into a new dimension enables enclosed manifolds to be separated.

Neural nets separate manifolds; each layer of a neural network stretches and squashes the data space until the manifolds are cleanly separated. Non-linear functions at each step (otherwise multiple linear transformations would collapse into just one layer). Use calculus to adjust the weights (error propagation backwards through the layers).

Structured neural nets have different kinds of layers, e.g., feature maps (which perform a local analysis over the whole input); generated potentially via convolutions (i.e., turn a 28×28 image into 20 24×24 images), do some subsampling. Programming these requires some trial-and-error.

Models to explain decisions: “why did you classify this image as a cat?”; not just “I ran it through  my calculations and ‘cat’ came up as highest”. A deep neural net could produce a set of words (fairly abstract) and then a language-generating recurrent neural net (RNN) translates these into captions (sentences). Currently, statistically impressive but individual unreliable.

Adversarial perturbations: Panda + <1% computed distortion, becomes classified as a Gibbon. Whilst the two images are indistinguishable to a human, the noise interferes with the manifold separation. There are even universal adversarial perturbations that throw-off classification of all images.

Assured control code (e.g., in a helicopter): a physical machine is modelled (system dynamics, power, inertia), a control system design is created, from which controller code is generated. But this does not produce a very nice to fly system. Need some kind of refinement back to the control code. Given the correct structure for the control code framework then the fine tuning from feedback on the actual system is very effective. This can be overlayed with different goals (different fitness functions), e.g., safety over learning.

AI wave 3: combining wave 1 and 2 techniques. Perceive into a contextual model on which abstractions are computed and which can be tuned (learning) to produce reasoning. Aim to get a better intelligence profile: P 3, L 3, A 2, R 3. Hand assurance arguments on the contextual model part instead.
e.g., build models that are specialised based on our knowledge, e.g., we know the probably number of strokes in each digit 0-9 and its trajectory. The generative model generates explanation of how a test character was generated (go from the model of whats its looking for to what it sees; how likely is the thing seen generatable from the model of a particular digit).

Need to be able to specify intent in a variety of ways; all real world specifications are partial and humans can’t always communicate the full intent of what they want (cf., trying to explain how to drive a car).

What are we trying to assure? Mistakes in sensing/reasoning leading to undesirable actions, undesirable emergent behaviours, hackable systems being subverted, misalignment between human/machine values.

(AlphaGo is a wave3-like system as it combined the neural net-based classification of moves with traditional planning/reasoning/tree-based pruning/search).

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(FSCD Keynote #2) – Uniform Resource Analysis by Rewriting: Strengths and Weaknesses, George Moser

Can we use complexity measures on term rewriting systems to make complexity arguments about higher-order functions?

The main scheme is to convert a program via a complexity reflecting transformation into a Term Rewriting System (TRS), then do automated resource analysis on the TRSS to get an asymptotic bound. The first half of the talk is some background on doing complexity analysis (which was a bit fast for me so my notes are a bit incoherent below). There are some really nice complexity analysis tools for programs coming out of this work (links near the end).

Some preliminaries: Example, set up list reverse as a finite set of rewrite rules (a Term Rewriting System, TRS):

rev(xs)            -> rev'(xs, nil)
rev'(nil, acc)     -> acc
rev'(x :: xs, acc) -> rev'(xs, x :: acc)

A computation of this set of rules is the application of the rules from left to right. The rules are non-overlapping.

Can see rewriting as an abstraction of functional programming, or can see it as part of equational reasoning (universal algebra); but this really generalises functional programming (function symbols can appear nested on the left-hand side).

Definition: A TRS is terminating if the rewriting relation is “well-founded”.
Definition: A function symbol f is “defined” if it is the root symbol on the left of a rule (other f is a constructor).
Definition: Runtime complexity wrt. a terminating TRS is defined:

.

RC is the runtime complexity; Q: is this a “natural notion” for rewriting? (I don’t know how one defined natural here).
Derivational complexity has no restriction on the terms,
This has been used mainly to make termination arguments.
See “Termination proofs and the length of derivations” (Hofbauer, Lautemann, 1989).

Definition: Multiset Path Order. A precedence order induces a multiset path order , (whose definition I’m not going to transcribe, Wikipedia has a definition) It basically says that if is all of , or is some .

The Hydra Battle- is this terminating? (Dershowitz and Jouannaud designed the TRS as a termination problem, later rectified by Dershowitz): The beast is a finite tree, each leaf corresponds to a head. Hercules chops off heads of the Hydra, but the Hydra regrows:

• If the cut head has a pre-predecessor (grandmother) then the remaining subtree is multiplied by the stage of the game (heads regrowing and multiplying).
• Otherwise, nothing happens (the head doesn’t regrow)

Can show it is terminating by an inductive argument over transfinite numbers. (but complexity is quite bad). See “The Hydra battle and Cicho’s principle” (Moser, 2009). 

The RTA list of open problem was mentioned: http://www.win.tue.nl/rtaloop/

TRSes can be represented via a matrix interpretation (details were too fast for me).
These techniques were developed into a fully automated complexity analysis tool for TRSes called tct-trs (modular complexity analysis framework).

Going back to the original goal: can we use this for higher-order programs? Consider the textbook example of reverse defined by a left-fold. Need to do a complexity preserving conversion into a TRS (complexity preserving transformation ensures lower bounds, complexity reflexing ensures upper bounds). First, defunctionalise via a rewrite system into a first-order system. Built a tool tct-hoca which works well for various small higher-order functional programs (with complexity proofs taking up to 1 minute to compute).  See the tools at:

• https://github.com/ComputationWithBoundedResources/tct-trs
• https://github.com/ComputationWithBoundedResources/tct-hoca

What about “real” programs or “imperative” programs? Use ‘integer transition systems’ for modelling imperative programs, which is integrated into the tools now.

Some related work: Multivariate amortized source analysis (Hoffman, Aehlig, Hofmann, 2012) and a type-based approach “Towards automatic resource bound analysis for OCaml” (Hofmann, Das, Weng, POPL 2017) (note to self: read this!).

A previous challenge from Tobias Nipkow: how do you do this with data structures like splay trees (cf Tarjan)? There is some new work in progress. Build on having sized types so that we can account for tree size. An annotated signature then decorates function types with the size polynomial, e.g. (recursive function to create a splay tree). A type system for this was shown, with cost annotation judgment (no time to copy down any details).

The strength of the uniform resource analysis approach is its modularity and extensibility (different intermediate languages and complexity problems).
Weaknesses: the extensibility/modularity required some abstraction which weakens the proving power, so adding new kinds of analysis (e.g., constant amortised / logarithmic amortised) requires a lot of work.
Audience question: can I annotate my program with the expected complexity and get a counter-example if its false? (counter-examples, not yet).

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(FSCD) Continuation Passing Style for Effect Handlers, Daniel Hillerström, Sam Lindley, Bob Atkey, KC Sivaramakrishnan

Consider two effects: nondeterminism and exceptions, in the drunk toss example (a drunk person tosses a coin and either catches it and gets a bool for head or tails, or drops the coin [failure/exception]).

drunkToss : Toss ! {Choose:Bool; Fail:Zero}
drunkToss = if do Choose
            then if do Choose then Heads else Tails
            else absurd do Fail

Induces a simple computation tree.

A modular handler, using row polymorphism (with variable r below)

allChoices : a ! {Choose : Bool; r} => List a ! {r}
allChoices = return x |-> [x]
             Choose k |-> k true ++ k false

fail : a ! {Fail: Zero; r} => List a ! {r}
fail = return x |-> [x]
       Fail k   |-> []

The ! is an annotation explaining the effect operations, k are continuations, r are row variables (universally quantified).  Two possible interpretations:

(1) handle the computation with fail first, then handle that with allChoices
returns the result [[Heads, Tails], []].

(2) handle with allChoices first then fail gives the result [].

So the order of the handling matters. The operational semantics for handlers is based on a substitution in the computation tree for the relevant operations.

How do handlers get compiled? Use CPS! (restricted subset of the lambda calculus, good for implementing control flow). Based on (Hillerstrom, Lindley 2016) – lambda calculus with effect handlers (separate syntactic category but contains lambda terms), row polymorphism, and monadic metalanguage style constructs for effectful let binding and ‘return’. The CPS translation is a homomorphism on all the lambda calculus syntax, but continuation passing on the effectful fragment (effectful let and return).  One part of the interpretation for the effectful operation term: (see the paper for the full translation!)

A key part of the translation is to preserve the stack of handlers so that the order is preserved and (the interpretation) of operations can access up and down the stack.
A problem with the translation is that it yields administrative redexes (redundant beta-redexes) and is not tail-recursive. Use an uncurried CRPS where the stack of continuations is explicit (see Materzok and Biernacki 2012), this leads to a new translation which can manipulate the continuation stack directly (see paper). However, this still yields some administrative redexes. Solution: adopt a two-level calculus (Danvy, Nielsen 2033) which has two kinds of continuations: static (translation time) and dynamic (run time), where you can reify/reflect between the two. This let’s you squash out administrative redexes from the runtime to the static part, which can then be beta-reduced immediately at compile time (end up with no static redexes).
The paper proves that this translation preserves the operational semantics.
Implementation in the ‘links’ language: https://github.com/links-lang/links

I was going to ask about doing this typed: this is shown in the paper.

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(ICFP) How to Prove Your Calculus Is Decidable: Practical Applications of Second-Order Algebraic Theories and Computation, Makoto Hamana

SOL (Second-Order Laboratory) – tool for analysing confluence and termination of second-order rewrite rules within Haskell. Provides an embedded Haskell DSL (via Template Haskell) for describing rewrite rules. SOL can then automatically check termination and confluence.

Confluence + termination => decidability. Can use this to prove a calculi is decidable.

Based on a higher-order version of Knuth-Bendix critical pair checking using extended HO pattern unification (Libal,Miller 2016).

For example, the theory of monads is decidable: given two well-typed terms s, t consistent of return, bind, and variables, the question  is s = t derivable from the three laws is decidable. How? First, orient the monad laws as rewrite laws. Check confluence (Church-Rosser, CR) and Strong Normalisation (SN)– together these imply their exists unique normal forms, which are then used to prove equivalence (reduce terms to their normal forms). So, how to prove CR and SN?

One way to prove Strong Normalisation is to assign weights and show that reductions reduce weights. Unfortunately, this does not work in the higher-order context of the monad operations. Another standard technique is to, use the “reducibility method” (see Tait,Girard and Lindley,Stark’05). SOL uses the ‘general schema criterion’ which works for general rewrite rules (Blanqui’00,’16) using various syntactic conditions (positivity, accessibility, safe use of recursive calls, metavariables). [sound but obviously not complete due to halting problem]. (Uses also Newman’s Lemma– a terminating TRS is confluent when it is locally confluent).

This tool can be applied to various calculi (see paper, 8 different systems). Sounds really useful when building new calculi. The tool was applied to a database of well know termination/confluence problems and could check 93/189 termination and 82/96 confluence problems.

“Let’s prove your calculus is decidable using SOL” (Makoto is happy to assist!)

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(ICFP) A Relational Logic for Higher-Order Programs
Alejandro Aguirre, Gilles Barthe, Marco Gaboardi, Deepak Garg, Pierre-Yves Strub

Relational properties are things like, if X and Y are related by R then F(X) and F(Y) are related by R, or over two properties, e.g., the results are related instead by S.

Relational refinement types: These can be used to express monotonicity properties, are syntax directed, and exploit structural similarities of code. However, say we want to prove the naturality of take, but formulating the right relational refinement type is difficult because the computations are structurally different.

Start with a basic logic with lambda-terms over simple inductive types, and a separate layer of predicates

RHOL has judgements where is a binary predicate on properties of the two terms and gives assertions about the free variables. A key idea here is that the types and assertions are separate.

An example rule two-sided rule (where we inductively construct terms with the same syntactic constructor on both sides of a relation):

.
This seems quite natural to me: abstraction introduces a universal quantification over the constraints attached to the free variables.

Rules can also be one side (where you construct a term on just one side of a relation).
The paper shows that RHOL is as expressive as HOL (by a mutual encoding).

Other relational typing system can be embedded into RHOL: Relational Refinement Types, DCC (Dependency Core Calculus, and RelCost (relational cost).

Q: if HOL and RHOL are equivalent (rather than their just being an embedding of HOL into RHOL say) then why have RHOL? Relational reasoning was gained which was not built into HO. Update: I discussed this further later with one of the authors, and they made the point that people have done relational-style reasoning in HOL but it requires taking a pairing of programs and building all the relational machinery by hand which is very cumbersome. RHOL has all this built in and the one-side and two-side rules let you reason about differently-structured terms much more easily. I can see this now.

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(ICFP)
Foundations of Strong Call by Need
Thibaut Balabonski, Pablo Barenbaum, Eduardo Bonelli, Delia Kesner

What does this lambda term reduce to:  ? It depends on call-by-value, call-by-name, call-by-need, or full beta then you get different answers. The call-by-value, call-by-name, and call-by-need strategies are called weak because they do not reduce underneath lambda abstraction. As a consequence, they do not compute normal forms on their own.

Weak call-by-need strategy (the usual strategy outlined in the literature): procrastinate and remember. Beta reduction into a let binding (don’t evaluate the right-hand side of an application). (There was some quite technical reduction work here, but I noted this interesting rule on “bubbling” reductions out by splitting a nested reduction into two: ).

Strong call-by-need provide the call-by-need flavour of only evaluating needed values once, but crucially computes normal forms (by reducing under a lambda). This strong approach has two properties (conservative) the strong strategy first does whatever the weak strategy will do; and (complete) if there is a beta-normal form it will reach (a representative of) it. This comes by reducing under the lambda at some points. Consequently, this approach only ever duplicates values, not computations.

Q: If you implemented this in Haskell, would it make it faster? I didn’t quite hear the answer, but this would completely change the semantics as Haskell is impure with respect to exceptions and non-termination. It sounded like it would be more useful for something pure like Coq/Agda (where it could provide some performance improvement).

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(ICFP) – No-Brainer CPS Conversion, Milo Davis, William Meehan, Olin Shivers

The Fischer/Reynolds algorithm for CPS transformation introduces administrative redexes. Since then, other algorithms have improved on this considerably (Danvy/Filinsky). In this approach, some additional reductions are applied to the term to get a smaller CPS term out. The moral of the story (or the key idea) is to treat the CPS converter like a compiler (use abstract representations, symbol tables).

Rules of the game: make the terms strictly smaller (greedy reductions), should be strongly normalisation, and confluent, keep the original algorithmic complexity of the CPS transforms (linear time).

Approach:
– Variables are the same size, so do beta redexes on variables
– Beta reduce application of a lambda to a lambda only when the number of reference to in is less than or equal to 1 (so things don’t explode).
– Eta reduce (??only when there are no references to the variable in the body??) (I think this is what was said, but I think I might have made a mistake here).

Relies on some machinery: doing reference counts (variable use count), abstract representation of continuations (halt, variables, function continuations, and application continuations) rather than going straight to syntax and syntax constructor functions (which can do reductions) to dovetail with this, and explicit environments to be used with function closures.

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(ICFP) Compiling to Categories, Conal Elliott

Why overload? Get a common vocabulary, laws for modular reasoning.

But generally doesn’t apply to lambda, variables, and application. So what to do? Eliminate them! Rewrite lambda terms into combinators: const, id, apply, pairing of functions (fork), curry, and keep going…. and you can automate this via a compiler plugin (so you don’t have to write code like this yourself).

This is implemented by the interface (algebra) of a category (for function composition / identities) + Cartesian (product) structure + coproducts + exponents: giving you (bi)Cartesian-closed categories. Implement this as class/interface so you can give different realisations/compilations, e.g., a graph drawing implementation (Conal showed some pretty pictures generated from this).

Another implementation is to generate Verilog (hardware descriptions), or to graphics shader code.

What about compiling to the derivative of a program? Represent this via the type:
newtype D a b = D (a -> b x (a -o b)) i.e., a differentiable function is a function which produces its result and its derivative as a linear map (an implementation was then shown, see paper). You can then compose interpretations, e.g., graph interpretation with derivative interpretation.

Another interpretation: interval analysis (e.g., Interval Double = (Double, Double)). There are more examples in the paper, including constraint solving via SMT by writing functions to Bool which are then compiled directly into SMT constraints (rather than using existing embeddings, e.g., SBV).

Q: what about recursion? Can be done (compiling from a letrec into a fix-point combinator class).

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 (ICFP) Visitors Unchained, François Pottier

(Humorous tagline from Francois: Objects at ICFP?! Binders again?!)

Manipulating abstract syntax with binding can be a chore: nameplate (boilerplate on names, term coined by James Cheney). Large and easy to get wrong (especially in weakly typed languages, non-dependent languages). This paper is a way of getting rid of nameplate in OCaml via a library and an syntax extension. Supports multiple representations, complex binding, is modular, and relies on just a small amount of code generation.

Several Haskell libraries support this via its support for datatype generic programming. This will use OCaml’s object technology. Annotating a data type with [@@deriving visitors { variety = 'map' }] automatically generates a visitor pattern (a class) for doing a map-operations on the datatype. To use this, create a local object inheriting the visitor class and override one or more methods, e.g., for a syntax tree type, override the visit method for the “add” node in order to implement the rewriting of e+0 -> e.
Visitors are quite versatile: easy to customise behaviour via inheritance which is something you can’t do in FP without a lot of redesign to your algorithms.

Want to traverse syntax with binders, considering three things (from three perspectives or “users” in the talk here):
(1) “End user” describes the structure of an AST, parameterised by types of bound names and free names and using a parametric data type abs whenever a binding is needed (e.g., in a lambda). This should also deriving the map visitor(see above) with option ["BindingForms.map"].
(2) “Binding library” (provided as part of this work) defines the abs type which capture the binding construct, but they leave the scope extrusion function extend as a parameter (extend gets used when you traverse a binder to go inside a scope, e.g., going into the body of a lambda and extending the context by the bound variable).
(3) The last part defines how to represent environments (and lookups) via an overriding a visitor, nominal terms, and scope extrusion. (The work provides some implementations of these part in a library too).

As seen above, the structure of this library is fairly modular. The “end user” has to glue all these things together.
One limitation is that nonlinear patterns (e.g., as in Erlang) can’t be represented (I didn’t immediately see why though).

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(ICFP) – Staged Generic Programming, Jeremy Yallop

Advert at the start: if you have an abstract library that is not very high-performance, then the techniques here could be useful to you.

Generic programming a la Scrap Your Boilerplate, for any data type get automatic traversals e.g., listify (matches c) for some constant c, gives you a list of all nodes in a data type matching c; as a programming you don’t need to write listify or matches: they are generated. Requires internally a way to represent types as data and to map data types into a generic form, a collection of traversals over the general form, and generic schemes which plug together the traversals with parameter generic queries. (In Haskell see the syb). However, the overhead of this roughly 20x writing the code manually! This overhead was quite portable: reimplementing Scrap Your Boilerplate into OCaml had about the same amount of slow down compared with manual traversals.

Why this slow? Type comparisons are slow, lots of indirection, and lots of unnecessary applications of applications. (Dominic: to me it seems like it ends up a bit like the slowness involved in dynamically typed languages).

Solution: use staging to optimise the datatype generic implementation. Staging lets you explain which parts of the program can be evaluated early, and which bits need to be evaluated later (due to waiting for inputs)– these are the quoted bits (inside  with the option to jump back into the early part by backquoting ~).

Naively staging SYB keeps the type representation unchanged, but the shallow traversals and recursion schemes can be quoted judiciously such that type comparison, indirect calls, and polymorphism are all eliminated. (Jeremy showed us the code output.. but it has lots of noise and opportunities for improvement).

Instead, use a special fixed-point operator that inlines non-recursive functions and perform (semantics preserving) code transformations as well: e.g., decomposing the generic map operation.

One technique is to allow equations on “partially-static data” e.g., if you have [] @ x @ [] (i.e., static empty list concat dynamic list x concat static empty list []) this still can be statically rewritten into x. Thus apply laws on the static parts as far as possible.
Another technique was to eta reduces matches that have identical branches.
(I think there were a few more thing here). Ends up with much tighter code which performs very close to or even better than the hand-written code.

Q: How does this compare to the Template-your-Boilerplate library for Haskell?
I completely missed the answer as I was looking up this library which I really should be using…!

by dorchard at September 07, 2017 10:48 AM

ICFP / FSCD day 3 – rough notes

(Blog posts for Day 1, Day 2, Day 3, Day 4 (half day))

I decided to take electronic notes at ICFP and FSCD (colocated) this year, and following the example of various people who put their conference notes online (which I’ve found useful), I thought I would attempt the same. However, there is a big caveat: my notes are going to be partial and may be incorrect; my apologies to the speakers for any mistakes.

• (ICFP) A Specification for Dependent Types in Haskell, Stephanie Weirich, Antoine Voizard, Pedro Henrique Avezedo de Amorim, Richard A. Eisenberg
• (ICFP) Parametric Quantifiers for Dependent Type Theory Andreas Nuyts, Andrea Vezzosi, Dominique Devriese
• (ICFP) – Normalization by Evaluation for Sized Dependent Types, Andreas Abel, Andrea Vezzosi, Theo Winterhalter
• (ICFP) – A Metaprogramming Framework for Formal Verification, Gabriel Ebner, Sebastian Ullrich, Jared Roesch, Jeremy Avigad, Leonardo De Moura
• (FSCD) – A Fibrational Framework for Substructural and Modal Logics, Dan Licata, Michael Shulman, Mitchell Riley
• (FSCD) – Dinaturality between syntax and semantics, Paolo Pistone
• (FSCD) – Models of Type Theory Based on Moore Paths, Andrew Pitts, Ian Orton
• (ICFP) – Theorems for Free for Free: Parametricity, With and Without Types, Amal Ahmed, Dustin Jamner, Jeremy G. Siek, Philip Wadler
• (ICFP) – On Polymorphic Gradual Typing, Yuu Igarashi, Taro Sekiyama, Atsushi Igarashi
• (ICFP) – Constrained Type Families, J. Garrett Morris, Richard A. Eisenberg
• (ICFP) – Automating Sized-Type Inference for Complexity Analysis, Martin Avanzini, Ugo Dal Lago
• (ICFP) – Inferring Scope through Syntactic Sugar, Justin Pombrio, Shriram Krishnamurthi, Mitchell Wand

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(ICFP) – A Specification for Dependent Types in Haskell, Stephanie Weirich, Antoine Voizard, Pedro Henrique Avezedo de Amorim, Richard A. Eisenberg

Haskell already has dependent types! ish! (ICFP’14) But singletons are “gross”! (mock discussion between Stephanie and Richard). This work describes a semantics for dependent types in Haskell, along with a replacement for GHC’s internal (Core) language, along with the high-level type theory and fully mechanized metatheory.

But isn’t Haskell already dependently typed? Cf Haskell indexed type for vectors. The following cannot be written in GHC at the moment:

vreplicate :: Pi(n :: Nat) -> Int -> Vec n
vreplicate Zero _ = Nil
vreplicate (Succ n) a = Cons a (vreplicate n a)

The reason this can’t be typed is due to n being erased (after compilation, i.e., it doesn’t appear in the run time) but it is needed dynamically in the first argument. In Dependent Haskell this can be done.

But… it’s not your usual system. For example, what about infinite data?

inf :: Nat
inf = S inf
vinf :: Vec inf
vinf = Cons 2 vinf  -- yields equality demand Vec (S inf) = Vec inf

Idealized Haskell (IH) = System F_omega + GADTs (has uncediable type checking!)

System FC (GHC Core) is a reified version of Idealized Haskell with enough annotations so that type checking is decidable, trivial, and syntax directed. Terms in Core can be see as type derivations of IH terms: contains type annotations and type equalities. (These can all be erased to get back into IH.) The first contribution of this work is a dependent System FC (DC). But its very complicated (needs also type soundness (progress/preservation), erasable coercions, ).
Instead, they introduce System D, the dependently typed analog of Idealized Haskell: its a stripped down dependent Haskell in Curry style (implicit types) and similarly to IH its type checking is undecidable. It has dependent types, non-termination, and coercion abstraction.

Coercion abstraction: for example

g : Int -> Int |- \v -> \c -> \v -> v : Pi n . (g n ~ 7) -> Vec (g n) -> Vec 7

Here the variable v (which has type Vec (g n) when passed in) is implicitly cast using the coercion c (which is passed in as a parameter) to Vec 7. This is translated into DC using an explicit coercion operator, applying c to coerce v.

System D and System DC were mechanized (in Coq) during the design using Ott (to input the rules of the language) & LNgen (for generating lemmas). Currently working on dependent pattern matching, a full implementation in GHC, and roles. (Hence, this is the specification of the type system so far).

Q: type inference for Dependent Haskell?
A: Not sure yet (but see Richard Eisenberg’s thesis)
Q: How do you get decidable type checking in the presence of infinite terms?
A: I didn’t understand the answer (will followup later).
Q: Why is coercion abstraction explicit in D while coercion application is implicit?
A: “Coercion application *is* explicit in D, it’s the use of coercion to cast a type that is implicit, but if you were to apply it to a value it would be explicit.”

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(ICFP) – Parametric Quantifiers for Dependent Type Theory Andreas Nuyts, Andrea Vezzosi, Dominique Devriese

A type variable is parameteric if is only used for type-checking (free well-behavedness theorems): i.e., can’t be inspected by pattern matching so you have the same algorithm on all types, e.g. flatten : forall X . Tree X -> List X. Parametericity is well studied in the System F world. This work looks at parametericity in dependent type theory.; some results carry over, some can be proved internally, but some are lost. This work formulates a sound dependent type system ParamDTT which .

Parametricity gives representation independence (in System F):

(This result follows by parametricity, using the result that implies which can be provided by relational parametricity, see Reynolds “related things map to related things”, applies identity extension lemma).

Can we do the same thing for DTT and can we prove the result internally?
is however not parametric. For example if we convert to . Suppose $B = U$ then we can leak details of the implementation (rerepresentation type is returned as data) (has this type). This violates the identity extension lemma used in the above proof for System F.

So instead, add a parametric quantifier to DTT to regain representation independence, making the above ill typed. The proof of parametricity for can  now be proved internally. This uses the relational interval type (cf Bernardy, Coquand, and Moulin 2015, on bridge/path-based proofs) which gives a basis for proving the core idea of “related things map to related things” where is connected with the type (in the above type) and is connected to the type via a switching term (see paper for the proof) (I think this is analogous to setting up a relation between and in the usual relational parametricity proof).

They extended Agda with support for this.

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(ICFP) – Normalization by Evaluation for Sized Dependent Types
Andreas Abel, Andrea Vezzosi, Theo Winterhalter

(context, DTT a la Martin-Lof, and you can add subtpying to this, where definitional equality implies subtyping). Definitional equality is decideable (for the purposes of type checking), but the bigger the better (want to be able to know as many things equal as possible).

Termination is needed for consistency, general fix gives you inconsistency. Instead, you can used data types indexed by tree height, where , you can define .

However, size expressions are not unique, which is problematic for proofs. e.g., but also . Intuition: sizes are irrelevant in terms, but relevant in types only.

Andreas set up some standard definitions of inductive Nat then tried to define a Euclidean division on Nat (where monus is minus cutting off at 0).

div : Nat → Nat → Nat
div zero y = zero
div (suc x) y = {! suc (div (monus x y) y) !}

However, Agda fails to termination check this. The solution is to “size type”-up everything, i.e., redefine the usual inductive Nat to have a size index:

data Nat : Size → Set where
 zero : ∀ i → Nat (↑ i)
 suc : ∀ i → Nat i → Nat (↑ i)

All the other definitions were given sized type parameters (propogated through) and then div was redefined (type checking to):

div : ∀ i → Nat i → Nat ∞ → Nat i
div .(↑ i) (zero i) y = zero i
div .(↑ i) (suc i x) y = suc _ (div i (monus i _ x y) y)

So far this is the usual technique. However, now we have difficulty proving a lemma (which was straightforward before sizing that minus of x with itself gives 0. Now this looks like:

monus-diag : ∀ i (x : Nat i) → Eq ∞ (monus i i x x) (zero ∞)

In the case: monus-diag .(↑ i) (suc i x) = monus-diag i x Agda gets the error i != ↑ i of type Size.

In the Church-style, dependent type functions = polymorphic functions, so you can’t have irrelevant arguments.  In Curry-style (with forall) this is okay. (see the previous talk, this could be a possible alternate solution?)

Instead, we want “Churry”-style where size arguments are used for type checking but can be ignored during equality checking: thus we want typing rules for irrelevant sizes. This was constructed via a special “irrelevant” modality , where sizes uses as indexes can be marked as irrelevant in the context. Here is one of the rules for type formation when abstracting over an irrelevantly typed argument:

This seemed to work really nicely (I couldn’t get all the details down, but the typing rules were nice and clean and made a lot of sense as a way of adding irrelevancy).

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(ICFP) – A Metaprogramming Framework for Formal Verification
Gabriel Ebner, Sebastian Ullrich, Jared Roesch, Jeremy Avigad, Leonardo De Moura

(Context: Lean is a dependently-typed theorem prover that aims to bridge the gap between interactive and automatic theorem proving. It has a very small trusted kernel (no pattern matching and termination checking), based on Calculus of Inductive Constructions + proof irrelevance + quotient types.)

They want to extend Lean with tactics, but its written in C++ (most tactic approaches are defined internally, cf Coq). Goal: to extend Lean using Lean by making Lean a reflective metaprogramming language (a bit like Idris) does, in order to build and run tactics within Lean. Do this by exposing Lean internals to Lean (Unification, type inference, type class resolution, etc.). Also needed an efficient evaluator to run meta programs.

lemma simple (p q : Prop) (hp : p) (hq : q) : q := 
by assumption

Assumption is a tactic, a meta program in the tactic monad:

meta def assumption : tactic unit := do
  ctx <- local_context,
  t   <- target
  h   <- find t ctx,
  exact h

(seems like a really nice DSL for building the tactics). Terms are reflected so there is a meta-level inductive definition of Lean terms, as well as quote and unquote primitives built in, but with a shallow (constant-time) reflection and reification mechanism.

The paper shows an example that defines a robust simplifier that is only about 40 locs (applying a congruence closure). They built a bunch of other things, including a bigger prover (~3000 loc) as well as command-line VM debugger as a meta program (~360 loc).

Next need a DSL for actually working with tactics (not just defining them). Initially quite ugly (with lots of quoting/unquoting). So to make things cleaner they let the tactics define their own parsers (which can then hook into the reflection mechanism). They then reused this to allow user-defined notations.

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(FSCD) A Fibrational Framework for Substructural and Modal Logics, Dan Licata, Michael Shulman, Mitchell Riley

Background/context: model logic core for necessity (true without any hypotheses) (if something A is possible true then possibility can propagate to the context– doesn’t change the “possibleness”). Various intuitionistic substructural and modal logics/type systems: linear/affine, relevant, ordered, bunched (separation logic), coeffects, etc.  Cohesive HoTT: take dependent type theory and add modalities (int, sharp, flat). S-Cohesion (Finster, Licata, Morehouse, Riley: a comonad and monad that themselves are adjoint, ends up with two kind of products which the modality maps between). Motivation: what are the common patterns in substructural and modal logics? How do we construct these things more systematically from a a small basic calculus.

With S4 modality (in sequent calculus), its common to make two contexts, one of modality formulae and one of normal, e.g., which is modelled by . In the sequent calculus style,  use the notion of context to form the type. Linear logic ! is similar (but with no weakening). The rules for follow the same kind of pattern: e.g., where the context “decays” into the logical operator (rather than being literally equivalent): the types inherent the properties of the context (cf. also exchange).

The general pattern: operations on contexts, with explicit or admissible structure properties, then have a type constructor (an operator) that internalises the implementation and inherits the properties. This paper provides a framework for doing this, and abstracting the common aspects of many intuitionistic substructural and modal logicas based on a sequent calculus (has cut elimination for all its connectives, equational theory, and categorical semantics).

Modal operators are decomposed in the same way as adjoint linear logic (Benton&Wadler’94), see also Atkey’s lambda-calculus for resource logic (2004) and Reed (2009).

So.. how? Sequents are completely Cartesian but are annotated with a description of the context and its properties/substructurality by a first order term (a context descriptor) where is this context descriptor. Context descriptors are built on “modes”. e.g., the meaning of this sequent depends on the equations/inequations on the context descriptor:, e.g.,if you have associativity of you get ordered logic, if you have contraction then you get a relevant logic, etc. Bunched implication will have two kinds of nodes in the context descriptor. For a modality, unary function symbols, e.g. means that the left part of the context is wrapped by a modality.

A subtlety of this is “weakening over weakening”, e.g., where we have weakend in the sequent calculus but the context descriptor is unchanged (i.e., we can’t use to prove ).

The F types give you a product structured according to a context descriptor, e.g. . All of the left rules become instances of one rule on F: which gives you all your left-rules (a related dual rule gives the right sequent rules).

Categorical semantics is based on a cartesian 2-multicategory (see paper!)
Q: is this like display logics? Yes in the sense of “punctuating” the shape of the context, but without the “display” (I don’t know what this means though).

This is really beautiful stuff. It looks like it could extend okay with graded modalities for coeffects, but I’ll have to go away and try it myself.

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(FSCD) – Dinaturality between syntax and semantics, Paolo Pistone

Multivariate functions and where the first parameter is contravariant and second is covariant may have dinatural transformations between them. (Dinaturality is weaker than naturality). Yields a family of maps which separate the contravariant and covariant actions in the coherence condition (see Wiki for the hexagonal diagram which is the generalisation of the usual naturality property into the dinatural setting).

A standard approach in categorical semantics is to interpret open formula by multivariant functor and proofs/terms by dinautral transformations.  Due to Girard, Scedrov, Scott 1992 there is the theorem that: if is closed and then is dinatural. The aim of the paper is to prove the converse result: if is closed and -normal and (syntactically) dinatural then (i.e., implies typability).

Syntactic dinaturality examples where shown (lambda terms which exhibit the dinaturality property). Imagine a transformation on a Church integer – this is a dinatural transformation and its dinaturality hexagon is representable by lambda terms. (I didn’t get a chance to grok all the details here and serialise them).

Typability of a lambda term was characterised by its tree structure and properties of its shape and size (e.g., then $n \leq h$, there are various others; see paper).

The theorem then extends from typability to parametricity (implies that the syntactically dinatural terms are parametric) when the type is “interpretable” (see paper for definition).

(sorry my notes don’t go further as I got a bit lost, entirely my fault, I was flagging after lunch).

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(FSCD) – Models of Type Theory Based on Moore Paths, Andrew Pitts, Ian Orton

In MLTT (Martin-Lof Type Theory), univalence is an extensional property (e.g., ) of types in a universe : given every identification induces an (Id)-isomorphism . U is univalent “if all Id-isomorphisms is U are induced by some identification ” (want this expressed in type theory) (this is a simpler restating of Voevodsky’s original definition due to Licata, Shulman, et al.). This paper: towards answering, are there models for usual type theory which contain such univalent universes?

Univalence is inconsistent with extensional type theory where implies . Univalence is telling you that the notion of identification is richer subsuming ETT where there is an identification between two types then they are already equal, which is much smaller/thinner.

Need a source of models of “intensional” identification types (i.e., not the extensional ones ^^^): homotopy type theory provides a source of such models via paths: are paths from point to point  in a space where is a “constant path” (transporting along such a path does nothing to the element).

So we need to find some structure for these identifications, but we need to restrict to families of type carrying structure to guarantee substitution operations (in this DTT context).  “Holes” is diagrams are filled using path reversals and path composition. Solution is “Moore” paths.

A Moore path from to in a topological space is specified by a shape (its length) in and an extent function satisfying and . These paths have a reversal operator by truncated subtraction . (note this is idempotent on constant paths as required, allowing holes in square paths to be filled (I had to omit the details, too many diagrams)). But topological spaces don’t give us a model of MLTT, so they replace it by an arbitrary topos (modelling extensional type theory) and instead of for path length/shape use any totally ordered commutative ring. All the definition/properties of Moore paths are the expressed in the internal language of the topos.  This successfully gives you a category with families (see Dybjer) modelling intensional Martin-Lof type theory (with Pi). This also satisfies dependent functional extensionality thus its probably a good model as univalence should imply extensionality. But haven’t yet got a proof that this does contain a univalence universe (todo).

Q: can it just be done with semirings? Yes.

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(ICFP) – Theorems for Free for Free: Parametricity, With and Without Types, Amal Ahmed, Dustin Jamner, Jeremy G. Siek, Philip Wadler

Want gradual typing AND parametricity. There has been various work integrating polymorphic types and gradual typing (with blame) but so far there have been no (published) proofs of parametricity. This paper proposes a variant of the polymorphic blame calculus [Ahmed, Findler, Siek, Wadler POPL’11] (fixed a few problems) and proves parametricity for it.

Even dynamically typed code cast to universal type should behave parametrically., e.g. consider the increment function which is typed dynamically and cast to a parametric type returns 5 but we want to raise a “blame” for the coercion here (coercing a monomorphic to polymorphic type is bad!).

The language has coercions and blame, and values can be tagged with a coercion (same for function values). Some rules:
 (that is, casts to the dynamic type and back again cancel out).
But, if you cast to a different type (tag) then blame pops out: (or maybe that was blame q?)

this has a type that makes it look like a constant function . When executing this we want to raise blame rather than actually produce a value (e.g. for ). Solution: use runtime type generation rather than substitution for type variables.

A type-name store provides a dictionary mapping type variables to types.
i.e., instead of substituting the in the application, create a fresh type name that is then mapped to in the store. Then we extend this with types and coercion:  where (I think!) means replace occurrences of B with .

Casts out a polymorphic type are instantiated with the dynamic type. Casts into polymorphic types are delayed like function casts.

Parametricity is proved via step-indexed Kripke logical relations. The set of worlds are tuples of the type-name stores, and relations about when concealed values should be related.  See paper: also shows soundness of the logical relations wrt. contextual equivalence. There was some cool stuff with “concealing” that I missed really.

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(ICFP) – On Polymorphic Gradual Typing, Yuu Igarashi, Taro Sekiyama, Atsushi Igarashi

Want to smoothly integrate polymorphism/gradual. e.g., apply dynamically-typed arguments into polmorphically typed parameters, and vice versa. Created two systems: System Fg (polymorphic gradually typed lambda cal) which translates to System Fc.

Want conservativity: A non-dynamically typed term in System F should be convertible into System Fg, and vice versa.  The following rule shows the gradual typing “consistency” rule for application (in System Fg and gradual lambda calculus):
where defines type consistency. Idea: extend this to include notions of consistency between polymorphic and dynamic types. An initial attempt breaks conservativity since there are ill-typed System F terms which are well-typed in System Fg then.

The gradual guarantee conjecture: coercions without changes to the operational semantics.

They introduce “type precision” (which I think replaces consistency) which is not symmetric where – I didn’t yet get the importance of this asymmetry). But there are some issues again… a solution is to do fresh name generation to prevent non-parametric behaviour (Ahmed et al. ’11, ’17 the last talk) But making types less precise still changes behaviour (create blame exceptions). Their approach to fix this is to restrict the term precision relation so that it can not be used inside of (term level) and (type level).
Still need to prove the gradual guarantee for this new approach (and adapt the parametricity results from Ahmed et al. ’17).

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(ICFP) – Constrained Type Families, J. Garrett Morris, Richard A. Eisenberg

(Recall type families = type-level functions)
Contribution 1: Discovery: GHC assumes that all type families are total
Contribution 2: First type-safety proof with non-termination and non-linear patterns
Contribution 2.5 (on the way): simplified metatheory
The results are applicable to any language with partiality and type-level functions (e.g. Scala)
(Haskellers leave no feature unabused!)

-- Example type family:

type family Pred n
type instance Pred (S n) = n
type instance Pred Z = Z

Can define a closed version:

type family Pred n where
            Pred (S n) = n
            Pred Z = Z

Definition: A ground type has no type families.
Definition: A total type family, when applied to ground types, always produces a ground type.

In the new proposal: all partial type families must be associated type families.

type family F a                 -- with no instances
x = fst (5, undefined :: F Int) -- is typeable, but there are no instance of F!

Instead, put it into a class:

class CF a where
    type F a
x = fst (5, undefined :: F Int) -- now get error "No instance for (CF Int)"

Can use closed type families for type equality.

type family EqT a b where
       EqT a a = Char
       EqT a b = Bool
f :: a -> EqT a (Maybe a) -- This currently fails to type check but it should work
f _ = False

Another example:

type family Maybes a 
type instance Maybes a = Maybe (Maybes a)
justs = Just justs -- GHC says we can't have an infinite type a ~ Maybe a
-- But we clearly do with this type family!

Why not just ban ​Maybes? Sometimes we need recursive type families.

By putting (partial) type classes inside a class means we are giving a constraint that explains there should be a type at the bottom of (once we’ve evaluated) a type family. Therefore we escape the totality trap and avoid the use of bogus types.

Total type families need not be associated. Currently GHC has a termination checker, but it is quite weak, so often people turn it off with UndecideableInstances.
But, wrinkle: backwards compatibility (see paper) (lots of partial type families that are not associated).

Forwards compatibility: dependent types, terminating checking, is Girard’s paradox encodable?

This work also lets us simplify injective type family constraints (this is good, hard to understand at the moment). It makes closed type families more powerful (also great).

---

(ICFP) – Automating Sized-Type Inference for Complexity Analysis, Martin Avanzini, Ugo Dal Lago

(for higher-order functional programs automatically). Instrument a program with a step counter by turning them into state monad which gives a dynamic count.
Sized typed (e.g., sized vectors), let you type ‘reverse’ of a list as . But inference is highly non-trivial.

Novel sized-type system with polymorphic recursion and arbitrary rank polymorphism on sizes with inference procedure for the size types. Constructor definitions define size measure, e.g., for lists of nats: and (here the natural number has a size too).
Can generalise size types in the application rules, (abs, app, and var rules deal with abstraction and instantiation of size parameters).

Theorem (soundness of sizes): (informally) the sizes attached to the a well-typed program gives you a bound on the number of execution steps that actually happen dynamically (via the state encoding). [also implies termination].

Inference step 1: add template annotations, e.g., . Then we need to find a concrete interpretation of .
Step 2: constraint generation, which arise from subtyping which approximate sizes, plus the constructor sizes. These collect together to constraint the meta variables introduced in step 1.
Step 3: constraint solving: replace meta variable by Skolem terms. Then use an SMT solver (the constraints are non-linear integer constraints). (from a question) The solution may not be affine (but if it is then it is easier to find).

The system does well at inferring the types of lots of standard higher-order functions with lists. But cross product on lists produces a type which is too polymorphic: with a little more annotation you can give it a useful type.
Q: What happens with quicksort? Unfortunately it can’t be done in the current system. Insertion sort is fine though.
Q: What about its relation to RAML? The method is quite different (RAML uses an amortized analysis). The examples that each can handle are quite different.

(ICFP) – Inferring Scope through Syntactic Sugar, Justin Pombrio, Shriram Krishnamurthi, Mitchell Wand

[Github]

Lots of languages use syntactic sugar, but then its hard to understand what the scoping rules are for these syntactic sweets.

E.g. list comprehension [e | p <- L] desugars to map (\p . e) L. The approach in this work is a procedure of scope inference which takes these rewrite patterns (where e and p and L are variables/parameters). We know the scoping rules for the core language (i.e., the binding on the right) [which parameterises the scope inference algorithm]. Desugaring shouldn’t change scope (i.e., if there is path between two variables then it should be preserved). So the scope structure is homomorphic to the desugared version, but smaller.  (A scope preorder was defined, I didn’t get to write down the details).

Theorem: if resugaring succeeds, then desugaring will preserve scope.

Evaluation: the techniques was tested on Pyret (educational language), Haskell (list comprehensions), and Scheme (all of the binding constructs in R5RS). It worked for everything apart from ‘do’ in R5RS.

by dorchard at September 07, 2017 10:46 AM

Modeling Music

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Modeling Music

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← → <time>September 6, 2017</time>

One of my long-term goals since forever has been to get good at music. I can sightread music, and I can play music by ear – arguably I can play music well. But this isn’t to say that I am good at music; I’m lacking any theory which might take me from “following the path” of music to “navigating” music.

Recently I took another stab at learning this stuff. Every two years or so I make an honest-to-goodness attempt at learning music theory, but inevitably run into the same problems over and over again. The problem is that I have yet to find any music education resources that communicate on my wavelength.

Music education usually comes in the form of “here are a bunch of facts about music; memorize them and you will now know music.” As someone who got good at math because it was the only subject he could find that didn’t require a lot of memorization, this is a frustrating situation to be in for me. Math education, in other words, presents too many theorems and too few axioms.

My learning style prefers to know the governing fundamentals, and derive results when they’re needed. It goes without saying that this is not the way most music theory is taught.

Inspired by my recent forays into learning more mathematics, I’ve had an (obvious) insight into how to learn things, and that’s to model them in systems I already understand. I’m pretty good at functional programming, so it seemed like a pretty reasonable approach.

I’ve still got a long way to go, but this post describes my first attempt at modeling music, and, vindicating my intuitions, shows how we can derive value out of this model.

Music from First Principles

I wanted to model music, but it wasn’t immediately obviously how to actually go about doing that. I decided to write down the few facts about music theory I did know: there are notes.

data Note = C | C' | D | D' | E | F | F' | G | G'| A | A' | B
  deriving (Eq, Ord, Show, Enum, Bounded, Read)

Because Haskell doesn’t let you use # willy-nilly, I decided to mark sharps with apostrophes.

I knew another fact, which is that the sharp keys can also be described as flat keys – they are enharmonic. I decided to describe these as pattern synonyms, which may or may not have been a good idea. Sometimes the name of the note matters, but sometimes it doesn’t, and I don’t have a great sense of when that is. I resolved to reconsider this decision if it caused issues down the road.

{-# LANGUAGE PatternSynonyms #-}

pattern Ab = G'
pattern Bb = A'
pattern Db = C'
pattern Eb = D'
pattern Gb = F'

The next thing I knew was that notes have some notion of distance between them. This distance is measured in semitones, which correspond to the pitch difference you can play on a piano. This distance is called an interval, and the literature has standard names for intervals of different sizes:

data Interval
  = Uni    -- 0 semitones
  | Min2   -- 1 semitone
  | Maj2   -- 2 semitones
  | Min3   -- etc.
  | Maj3
  | Perf4
  | Tri
  | Perf5
  | Min6
  | Maj6
  | Min7
  | Maj7
  deriving (Eq, Ord, Show, Enum, Bounded, Read)

It’s pretty obvious that intervals add in the usual way, since they’re really just names for different numbers of semitones. We can define addition over them, with the caveat that if we run out of interval names, we’ll loop back to the beginning. For example, this will mean we’ll call an octave a Unison, and a 13th a Perf4. Since this is “correct” if you shift down an octave every time you wrap around, we decide not to worry about it:

iAdd :: Interval -> Interval -> Interval
iAdd a b = toEnum $ (fromEnum a + fromEnum b) `mod` 12

We can similarly define subtraction.

This “wrapping around” structure while adding should remind us of our group theory classes; in fact intervals are exactly the group \(\mathbb{Z}/12\mathbb{Z}\) – a property shared by the hours on a clock where \(11 + 3 = 2\). That’s certainly interesting, no?

If intervals represent distances between notes, we should be able to subtract two notes to get an interval, and add an interval to a note to get another note.

iBetween :: Note -> Note -> Interval
iBetween a b = toEnum $ (fromEnum a - fromEnum b) `mod` 12

iAbove :: Note -> Interval -> Note
iAbove a b = toEnum $ (fromEnum a + fromEnum b) `mod` 12

Let’s give this all a try, shall we?

> iAdd Maj3 Min3
Perf5

> iBetween E C
Maj3

> iAbove D Maj3
F'

Looks good so far! Encouraged by our success, we can move on to trying to model a scale.

Scales

This was my first stumbling block – what exactly is a scale? I can think of a few: C major, E major, Bb harmonic minor, A melodic minor, and plenty others! My first attempt was to model a scale as a list of notes.

Unfortunately, this doesn’t play nicely with our mantra of “axioms over theorems”. Represented as a list of notes, it’s hard to find the common structure between C major and D major.

Instead, we can model a scale as a list of intervals. Under this lens, all major scales will be represented identically, which is a promising sign. I didn’t know what those intervals happened to be, but I did know what C major looked like:

cMajor :: [Note]
cMajor = [C, D, E, F, G, A, B]

We can now write a simple helper function to extract the intervals from this:

intsFromNotes :: [Note] -> [Interval]
intsFromNotes notes = fmap (\x -> x `iBetween` head notes) notes

major :: [Interval]
major = intsFromNotes cMajor

To convince ourselves it works:

> major
[Uni,Maj2,Maj3,Perf4,Perf5,Maj6,Maj7]

Seems reasonable; the presence of all those major intervals is probably why they call it a major scale. But while memorizing the intervals in a scale is likely a fruitful exercise, it’s no good to me if I want to actually play a scale. We can write a function to add the intervals in a scale to a tonic in order to get the actual notes of a scale:

transpose :: Note -> [Interval] -> [Note]
transpose n = fmap (iAbove n)

> transpose A major
[A,B,C',D,E,F',G']

Looking good!

Modes

The music theory I’m actually trying to learn with all of this is jazz theory, and my jazz theory book talks a lot about modes. A mode of a scale, apparently, is playing the same notes, but starting on a different one. For example, G mixolydian is actually just the notes in C major, but starting on G (meaning it has an F♮, rather than F#).

By rote, we can scribe down the names of the modes:

data Mode
  = Ionian
  | Dorian
  | Phrygian
  | Lydian
  | Mixolydian
  | Aeolian
  | Locrian
  deriving (Eq, Ord, Show, Enum, Bounded, Read)

If you think about it, playing the same notes as a different scale but starting on a different note sounds a lot like rotating the order of the notes you’re playing. I got an algorithm for rotating a list off stack overflow:

rotate :: Int -> [a] -> [a]
rotate _ [] = []
rotate n xs = zipWith const (drop n (cycle xs)) xs

which we can then use in our dastardly efforts:

modeOf :: Mode -> [a] -> [a]
modeOf mode = rotate (fromEnum mode)

> modeOf Mixolydian $ transpose C major
[G,A,B,C,D,E,F]

That has a F♮, all right. Everything seems to be proceeding according to our plan!

Something that annoys me about modes is that “G mixolydian” has the notes of C, not of G. This means the algorithm I need to carry out in my head to jam with my buddies goes something as follows:

• G mixolydian?
• Ok, mixolydian is the fifth mode.
• So what’s a major fifth below G?
• It’s C!
• What’s the C major scale?
• OK, got it.
• So I want to play the C major scale but starting on a different note.
• What was I doing again?

That’s a huge amount of thinking to do on a key change. Instead, what I’d prefer is to think of “mixolydian” as a transformation on G, rather than having to backtrack to C. I bet there’s an easier mapping from modes to the notes they play. Let’s see if we can’t tease it out!

So to figure out what are the “mode rules”, I want to compare the intervals of C major (ionian) to C whatever, and report back any which are different. As a sanity check, we know from thinking about G mixolydian that the mixolydian rules should be Maj7 => Min7 in order to lower the F# to an F♮.

modeRules :: Mode -> [(Interval, Interval)]
modeRules m = filter (uncurry (/=))
            . zip (intsFromNotes $ transpose C major)
            . intsFromNotes
            . transpose C
            $ modeOf m major

What this does is construct the notes in C ionian, and then in C whatever, turns both sets into intervals, and then removes any groups which are the same. What we’re left with is pairs of intervals that have changed while moving modes.

> modeRules Mixolydian
[(Maj7,Min7)]

> modeRules Dorian
[(Maj3,Min3), (Maj7,Min7)]

Very cool. Now I’ve got something actionable to memorize, and it’s saved me a bunch of mental effort to compute on my own. My new strategy for determining D dorian is “it’s D major but with a minor 3rd and 7th”.

Practicing

My jazz book suggests that practicing every exercise along the circle of fifths would be formative. The circle of fifths is a sequence of notes you get by successively going up or down a perfect 5th starting from C. In jazz allegedly it is more valuable to go down, so we will build that:

circleOfFifths :: [Note]
circleOfFifths = iterate (`iMinus` Perf5) C

This is an infinite list, so we’d better be careful when we look at it:

> take 5 circleOfFifths
[C,F,A',D',G']

Side note, we get to every note via the circle of fifths because there are 12 distinct notes (one for each semitone on C). A major fifth, being 7 semitones, is semi-prime with 12, meaning, meaning it will never get into a smaller cycle. Math!

Ok, great! So now I know which notes to start my scales on. An unfortunate property of the jazz circle of fifths is that going down by fifths means you quickly get into the freaky scales they don’t teach 7 year olds. You get into the weeds where the scales start on black notes and don’t adhere to your puny human intuitions about fingerings.

A quick google search suggested that there is no comprehensive reference for “what’s the fingering for scale X”. However, that same search did provide me with a heuristic – “don’t use your thumb on a black note.”

That’s enough for me to go on! Let’s see if we can’t write a program to solve this problem for us. It wasn’t immediately obvious to me how to generate potential fingerings, but it seems like we’ll need to know which notes are black:

isBlack :: Note -> Bool
isBlack A' = True
isBlack C' = True
isBlack D' = True
isBlack F' = True
isBlack G' = True
isBlack _ = False

For the next step, I thought I’d play it safe and hard code the list of fingering patterns for the right hand that I already know.

fingerings :: [[Int]]
fingerings = [ [1, 2, 3, 1, 2, 3, 4, 5]  -- C major
             , [1, 2, 3, 4, 1, 2, 3, 4]  -- F major
             ]

That’s it. That’s all the fingerings I know. Don’t judge me. It’s obvious that none of my patterns as written will avoid putting a thumb on a black key in the case of, for example, Bb major, so we’ll make a concession and say that you can start anywhere in the finger pattern you want.

allFingerings :: [[Int]]
allFingerings = do
  amountToRotate <- [0..7]
  fingering      <- fingerings
  pure $ rotate amountToRotate fingering

With this list of mighty potential fingerings, we’re ready to find one that fits a given scale!

fingeringOf :: [Note] -> [Int]
fingeringOf notes = head $ do
  fingers <- allFingerings
  guard . not
        . or
        . fmap (\(n, f) -> isBlack n && f == 1)
        . zip notes
        $ fingers
  pure fingers

We can test it:

> fingeringOf $ transpose C major
[1,2,3,1,2,3,4,5]

> fingeringOf $ transpose F major
[1,2,3,4,1,2,3,4]

> fingeringOf $ transpose A' major
[2,3,1,2,3,4,5,1]

So it doesn’t work amazingly, but it does in fact find fingerings that avoid putting a thumb on a black key. We could tweak how successful this function is by putting more desirable fingerings earlier in allFingerings, but as a proof of concept this is good enough.

That’s about as far as I’ve taken this work so far, but it’s already taught me more about music theory than I’d learned in 10 years of lessons (in which, admittedly, I skipped the theory sections). More to come on this topic, probably.

As usual, you can find the associated code on Github.

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September 06, 2017 12:00 AM