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5 Commits
| Author | SHA1 | Date | |
|---|---|---|---|
 radrow
|
a5cbf2fd79 | ||
|
Radosław Rowicki
|
83e03f3013 | ||
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Radosław Rowicki
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d7fa4d65ec | ||
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Radosław Rowicki
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bd7ed2ef8c | ||
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Radosław Rowicki
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2bf65cfd98 |
@@ -6,7 +6,12 @@ and this project adheres to [Semantic Versioning](https://semver.org/spec/v2.0.0
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## [Unreleased]
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### Added
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- Added documentation (actually, moved from `protocol`)
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- Added standard library docs. Moved builtin docs from `sophia.md` to
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`sophia_stdlib.md`
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- Added library for rational numbers
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### Changed
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- Optimized `List.aes` library
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### Removed
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## [4.2.0] - 2020-01-15
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@@ -2,13 +2,19 @@
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This is the __sophia__ compiler for the æternity system which compiles contracts written in __sophia__ code to the æternity VM code.
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For more information about æternity smart contracts and the sophia language see [Smart Contracts](https://github.com/aeternity/protocol/blob/master/contracts/contracts.md) and the [Sophia Language](https://github.com/aeternity/protocol/blob/master/contracts/sophia.md).
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It is an OTP application written in Erlang and is by default included in
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[the æternity node](https://github.com/aeternity/epoch). However, it can
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also be included in other systems to compile contracts coded in sophia which
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can then be loaded into the æternity system.
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## Documentation
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* [Smart Contracts on aeternity Blockchain](https://github.com/aeternity/protocol/blob/master/contracts/contracts.md).
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* [Sophia Documentation](docs/sophia.md).
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* [Sophia Standard Library](docs/sophia_stdlib.md).
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## Versioning
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`aesophia` has a version that is only loosely connected to the version of the
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@@ -17,6 +23,7 @@ minor/patch version. The `aesophia` compiler version MUST be bumped whenever
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there is a change in how byte code is generated, but it MAY also be bumped upon
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API changes etc.
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## Interface Modules
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The basic modules for interfacing the compiler:
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+1064
File diff suppressed because it is too large
Load Diff
File diff suppressed because it is too large
Load Diff
@@ -0,0 +1,176 @@
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namespace Frac =
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private function gcd(a : int, b : int) =
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if (b == 0) a else gcd(b, a mod b)
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private function abs_int(a : int) = if (a < 0) -a else a
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datatype frac = Pos(int, int) | Zero | Neg(int, int)
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/** Checks if the internal representation is correct.
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* Numerator and denominator must be positive.
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* Exposed for debug purposes
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*/
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function is_sane(f : frac) : bool = switch(f)
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Pos(n, d) => n > 0 && d > 0
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Zero => true
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Neg(n, d) => n > 0 && d > 0
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function num(f : frac) : int = switch(f)
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Pos(n, _) => n
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Neg(n, _) => -n
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Zero => 0
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function den(f : frac) : int = switch(f)
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Pos(_, d) => d
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Neg(_, d) => d
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Zero => 1
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function to_pair(f : frac) : int * int = switch(f)
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Pos(n, d) => (n, d)
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Neg(n, d) => (-n, d)
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Zero => (0, 1)
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function sign(f : frac) : int = switch(f)
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Pos(_, _) => 1
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Neg(_, _) => -1
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Zero => 0
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function to_str(f : frac) : string = switch(f)
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Pos(n, d) => String.concat(Int.to_str(n), if (d == 1) "" else String.concat("/", Int.to_str(d)))
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Neg(n, d) => String.concat("-", to_str(Pos(n, d)))
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Zero => "0"
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/** Reduce fraction to normal form
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*/
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function simplify(f : frac) : frac =
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switch(f)
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Neg(n, d) =>
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let cd = gcd(n, d)
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Neg(n / cd, d / cd)
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Zero => Zero
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Pos(n, d) =>
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let cd = gcd(n, d)
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Pos(n / cd, d / cd)
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/** Integer to rational division
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*/
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function make_frac(n : int, d : int) : frac =
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if (d == 0) abort("Division by zero")
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elif (n == 0) Zero
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elif ((n < 0) == (d < 0)) simplify(Pos(abs_int(n), abs_int(d)))
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else simplify(Neg(abs_int(n), abs_int(d)))
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function eq(a : frac, b : frac) : bool =
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let (na, da) = to_pair(a)
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let (nb, db) = to_pair(b)
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(na == nb && da == db) || na * db == nb * da // they are more likely to be normalized
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function neq(a : frac, b : frac) : bool =
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let (na, da) = to_pair(a)
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let (nb, db) = to_pair(b)
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(na != nb || da != db) && na * db != nb * da
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function geq(a : frac, b : frac) : bool = num(a) * den(b) >= num(b) * den(a)
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function leq(a : frac, b : frac) : bool = num(a) * den(b) =< num(b) * den(a)
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function gt(a : frac, b : frac) : bool = num(a) * den(b) > num(b) * den(a)
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function lt(a : frac, b : frac) : bool = num(a) * den(b) < num(b) * den(a)
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function min(a : frac, b : frac) : frac = if (leq(a, b)) a else b
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function max(a : frac, b : frac) : frac = if (geq(a, b)) a else b
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function abs(f : frac) : frac = switch(f)
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Pos(n, d) => Pos(n, d)
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Zero => Zero
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Neg(n, d) => Pos(n, d)
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function from_int(n : int) : frac =
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if (n > 0) Pos(n, 1)
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elif (n < 0) Neg(-n, 1)
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else Zero
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function floor(f : frac) : int = switch(f)
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Pos(n, d) => n / d
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Zero => 0
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Neg(n, d) => -(n + d - 1) / d
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function ceil(f : frac) : int = switch(f)
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Pos(n, d) => (n + d - 1) / d
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Zero => 0
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Neg(n, d) => -n / d
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function round_to_zero(f : frac) : int = switch(f)
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Pos(n, d) => n / d
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Zero => 0
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Neg(n, d) => -n / d
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function round_from_zero(f : frac) : int = switch(f)
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Pos(n, d) => (n + d - 1) / d
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Zero => 0
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Neg(n, d) => -(n + d - 1) / d
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/** Round towards nearest integer. If two integers are in the same
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* distance, choose the even one.
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*/
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function round(f : frac) : int =
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let fl = floor(f)
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let cl = ceil(f)
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let dif_fl = abs(sub(f, from_int(fl)))
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let dif_cl = abs(sub(f, from_int(cl)))
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if (gt(dif_fl, dif_cl)) cl
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elif (gt(dif_cl, dif_fl)) fl
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elif (fl mod 2 == 0) fl
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else cl
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function add(a : frac, b : frac) : frac =
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let (na, da) = to_pair(a)
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let (nb, db) = to_pair(b)
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if (da == db) make_frac(na + nb, da)
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else make_frac(na * db + nb * da, da * db)
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function neg(a : frac) : frac = switch(a)
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Neg(n, d) => Pos(n, d)
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Zero => Zero
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Pos(n, d) => Neg(n, d)
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function sub(a : frac, b : frac) : frac = add(a, neg(b))
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function inv(a : frac) : frac = switch(a)
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Neg(n, d) => Neg(d, n)
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Zero => abort("Inversion of zero")
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Pos(n, d) => Pos(d, n)
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function mul(a : frac, b : frac) : frac = make_frac(num(a) * num(b), den(a) * den(b))
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function div(a : frac, b : frac) : frac = mul(a, inv(b))
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/** `b` to the power of `e`
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*/
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function int_exp(b : frac, e : int) : frac =
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if (sign(b) == 0 && e == 0) abort("Zero to the zero exponentation")
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elif (e < 0) inv(int_exp_(b, -e))
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else int_exp_(b, e)
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private function int_exp_(b : frac, e : int) =
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if (e == 0) from_int(1)
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elif (e == 1) b
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else
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let half = int_exp_(b, e / 2)
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if (e mod 2 == 1) mul(mul(half, half), b)
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else mul(half, half)
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/** Reduces the fraction's in-memory size by dividing its components by two until the
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* the error is bigger than `loss` value
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*/
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function optimize(f : frac, loss : frac) : frac =
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require(geq(loss, Zero), "negative loss optimize")
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let s = sign(f)
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mul(from_int(s), run_optimize(abs(f), loss))
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private function run_optimize(f : frac, loss : frac) : frac =
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let t = make_frac((num(f) + 1) / 2, (den(f) + 1)/2)
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if(gt(abs(sub(t, f)), loss)) f
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elif (eq(t, f)) f
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else run_optimize(t, loss)
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+41
-10
@@ -12,35 +12,66 @@ namespace Func =
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function rapply(x : 'a, f : 'a => 'b) : 'b = f(x)
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/* The Z combinator - replacement for local and anonymous recursion.
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*/
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/** The Z combinator - replacement for local and anonymous recursion.
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*/
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function recur(f : ('arg => 'res, 'arg) => 'res) : 'arg => 'res =
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(x) => f(recur(f), x)
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/** n-times composition with itself
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*/
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function iter(n : int, f : 'a => 'a) : 'a => 'a = iter_(n, f, (x) => x)
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private function iter_(n : int, f : 'a => 'a, acc : 'a => 'a) : 'a => 'a =
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if(n == 0) acc
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elif(n == 1) comp(f, acc)
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else iter_(n / 2, comp(f, f), if(n mod 2 == 0) acc else comp(f, acc))
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function curry2(f : ('a, 'b) => 'c) : 'a => ('b => 'c) =
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/** Turns an ugly, bad and disgusting arity-n function into
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* a beautiful and sweet function taking the first argument
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* and returning a function watiting for the remaining ones
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* in the same manner
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*/
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function curry2(f : ('a, 'b) => 'x) : 'a => ('b => 'x) =
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(x) => (y) => f(x, y)
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function curry3(f : ('a, 'b, 'c) => 'd) : 'a => ('b => ('c => 'd)) =
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function curry3(f : ('a, 'b, 'c) => 'x) : 'a => ('b => ('c => 'x)) =
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(x) => (y) => (z) => f(x, y, z)
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function curry4(f : ('a, 'b, 'c, 'd) => 'x) : 'a => ('b => ('c => ('d => 'x))) =
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(x) => (y) => (z) => (w) => f(x, y, z, w)
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function curry5(f : ('a, 'b, 'c, 'd, 'e) => 'x) : 'a => ('b => ('c => ('d => ('e => 'x)))) =
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(x) => (y) => (z) => (w) => (q) => f(x, y, z, w, q)
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function uncurry2(f : 'a => ('b => 'c)) : ('a, 'b) => 'c =
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/** Opposite of curry. Gross
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*/
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function uncurry2(f : 'a => ('b => 'x)) : ('a, 'b) => 'x =
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(x, y) => f(x)(y)
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function uncurry3(f : 'a => ('b => ('c => 'd))) : ('a, 'b, 'c) => 'd =
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function uncurry3(f : 'a => ('b => ('c => 'x))) : ('a, 'b, 'c) => 'x =
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(x, y, z) => f(x)(y)(z)
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function uncurry4(f : 'a => ('b => ('c => ('d => 'x)))) : ('a, 'b, 'c, 'd) => 'x =
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(x, y, z, w) => f(x)(y)(z)(w)
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function uncurry5(f : 'a => ('b => ('c => ('d => ('e => 'x))))) : ('a, 'b, 'c, 'd, 'e) => 'x =
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(x, y, z, w, q) => f(x)(y)(z)(w)(q)
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function tuplify2(f : ('a, 'b) => 'c) : (('a * 'b)) => 'c =
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/** Turns an arity-n function into a function taking n-tuple
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*/
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function tuplify2(f : ('a, 'b) => 'x) : (('a * 'b)) => 'x =
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(t) => switch(t)
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(x, y) => f(x, y)
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function tuplify3(f : ('a, 'b, 'c) => 'd) : 'a * 'b * 'c => 'd =
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function tuplify3(f : ('a, 'b, 'c) => 'x) : 'a * 'b * 'c => 'x =
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(t) => switch(t)
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(x, y, z) => f(x, y, z)
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function tuplify4(f : ('a, 'b, 'c, 'd) => 'x) : 'a * 'b * 'c * 'd => 'x =
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(t) => switch(t)
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(x, y, z, w) => f(x, y, z, w)
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function tuplify5(f : ('a, 'b, 'c, 'd, 'e) => 'x) : 'a * 'b * 'c * 'd * 'e => 'x =
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(t) => switch(t)
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(x, y, z, w, q) => f(x, y, z, w, q)
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|
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function untuplify2(f : 'a * 'b => 'c) : ('a, 'b) => 'c =
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/** Opposite of tuplify
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*/
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function untuplify2(f : 'a * 'b => 'x) : ('a, 'b) => 'x =
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(x, y) => f((x, y))
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function untuplify3(f : 'a * 'b * 'c => 'd) : ('a, 'b, 'c) => 'd =
|
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function untuplify3(f : 'a * 'b * 'c => 'x) : ('a, 'b, 'c) => 'x =
|
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(x, y, z) => f((x, y, z))
|
||||
function untuplify4(f : 'a * 'b * 'c * 'd => 'x) : ('a, 'b, 'c, 'd) => 'x =
|
||||
(x, y, z, w) => f((x, y, z, w))
|
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function untuplify5(f : 'a * 'b * 'c * 'd * 'e => 'x) : ('a, 'b, 'c, 'd, 'e) => 'x =
|
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(x, y, z, w, q) => f((x, y, z, w, q))
|
||||
|
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+44
-11
@@ -19,10 +19,15 @@ namespace List =
|
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[x] => Some(x)
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_::t => last(t)
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|
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/** Finds first element of `l` fulfilling predicate `p` as `Some` or `None`
|
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* if no such element exists.
|
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*/
|
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function find(p : 'a => bool, l : list('a)) : option('a) = switch(l)
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[] => None
|
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h::t => if(p(h)) Some(h) else find(p, t)
|
||||
|
||||
/** Returns list of all indices of elements from `l` that fulfill the predicate `p`.
|
||||
*/
|
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function find_indices(p : 'a => bool, l : list('a)) : list(int) = find_indices_(p, l, 0, [])
|
||||
private function find_indices_( p : 'a => bool
|
||||
, l : list('a)
|
||||
@@ -50,14 +55,22 @@ namespace List =
|
||||
_::t => length_(t, acc + 1)
|
||||
|
||||
|
||||
/** Creates an ascending sequence of all integer numbers
|
||||
* between `a` and `b` (including `a` and `b`)
|
||||
*/
|
||||
function from_to(a : int, b : int) : list(int) = [a..b]
|
||||
|
||||
/** Creates an ascending sequence of integer numbers betweeen
|
||||
* `a` and `b` jumping by given `step`. Includes `a` and takes
|
||||
* `b` only if `(b - a) mod step == 0`. `step` should be bigger than 0.
|
||||
*/
|
||||
function from_to_step(a : int, b : int, s : int) : list(int) = from_to_step_(a, b, s, [])
|
||||
private function from_to_step_(a, b, s, acc) =
|
||||
if (a > b) reverse(acc) else from_to_step_(a + s, b, s, a :: acc)
|
||||
|
||||
|
||||
/* Unsafe. Replaces `n`th element of `l` with `e`. Crashes on over/underflow */
|
||||
/** Unsafe. Replaces `n`th element of `l` with `e`. Crashes on over/underflow
|
||||
*/
|
||||
function replace_at(n : int, e : 'a, l : list('a)) : list('a) =
|
||||
if(n<0) abort("insert_at underflow") else replace_at_(n, e, l, [])
|
||||
private function replace_at_(n : int, e : 'a, l : list('a), acc : list('a)) : list('a) =
|
||||
@@ -66,7 +79,8 @@ namespace List =
|
||||
h::t => if (n == 0) reverse(e::acc) ++ t
|
||||
else replace_at_(n-1, e, t, h::acc)
|
||||
|
||||
/* Unsafe. Adds `e` to `l` to be its `n`th element. Crashes on over/underflow */
|
||||
/** Unsafe. Adds `e` to `l` to be its `n`th element. Crashes on over/underflow
|
||||
*/
|
||||
function insert_at(n : int, e : 'a, l : list('a)) : list('a) =
|
||||
if(n<0) abort("insert_at underflow") else insert_at_(n, e, l, [])
|
||||
private function insert_at_(n : int, e : 'a, l : list('a), acc : list('a)) : list('a) =
|
||||
@@ -75,6 +89,9 @@ namespace List =
|
||||
[] => abort("insert_at overflow")
|
||||
h::t => insert_at_(n-1, e, t, h::acc)
|
||||
|
||||
/** Assuming that cmp represents `<` comparison, inserts `x` before
|
||||
* the first element in the list `l` which is greater than it
|
||||
*/
|
||||
function insert_by(cmp : (('a, 'a) => bool), x : 'a, l : list('a)) : list('a) =
|
||||
insert_by_(cmp, x, l, [])
|
||||
private function insert_by_(cmp : (('a, 'a) => bool), x : 'a, l : list('a), acc : list('a)) : list('a) =
|
||||
@@ -109,6 +126,8 @@ namespace List =
|
||||
[] => reverse(acc)
|
||||
h::t => map_(f, t, f(h)::acc)
|
||||
|
||||
/** Effectively composition of `map` and `flatten`
|
||||
*/
|
||||
function flat_map(f : 'a => list('b), l : list('a)) : list('b) =
|
||||
ListInternal.flat_map(f, l)
|
||||
|
||||
@@ -117,7 +136,8 @@ namespace List =
|
||||
[] => reverse(acc)
|
||||
h::t => filter_(p, t, if(p(h)) h::acc else acc)
|
||||
|
||||
/* Take `n` first elements */
|
||||
/** Take `n` first elements
|
||||
*/
|
||||
function take(n : int, l : list('a)) : list('a) =
|
||||
if(n < 0) abort("Take negative number of elements") else take_(n, l, [])
|
||||
private function take_(n : int, l : list('a), acc : list('a)) : list('a) =
|
||||
@@ -126,7 +146,8 @@ namespace List =
|
||||
[] => reverse(acc)
|
||||
h::t => take_(n-1, t, h::acc)
|
||||
|
||||
/* Drop `n` first elements */
|
||||
/** Drop `n` first elements
|
||||
*/
|
||||
function drop(n : int, l : list('a)) : list('a) =
|
||||
if(n < 0) abort("Drop negative number of elements")
|
||||
elif (n == 0) l
|
||||
@@ -134,18 +155,23 @@ namespace List =
|
||||
[] => []
|
||||
h::t => drop(n-1, t)
|
||||
|
||||
/* Get the longest prefix of a list in which every element matches predicate `p` */
|
||||
/** Get the longest prefix of a list in which every element
|
||||
* matches predicate `p`
|
||||
*/
|
||||
function take_while(p : 'a => bool, l : list('a)) : list('a) = take_while_(p, l, [])
|
||||
private function take_while_(p : 'a => bool, l : list('a), acc : list('a)) : list('a) = switch(l)
|
||||
[] => reverse(acc)
|
||||
h::t => if(p(h)) take_while_(p, t, h::acc) else reverse(acc)
|
||||
|
||||
/* Drop elements from `l` until `p` holds */
|
||||
/** Drop elements from `l` until `p` holds
|
||||
*/
|
||||
function drop_while(p : 'a => bool, l : list('a)) : list('a) = switch(l)
|
||||
[] => []
|
||||
h::t => if(p(h)) drop_while(p, t) else l
|
||||
|
||||
/* Splits list into two lists of elements that respectively match and don't match predicate `p` */
|
||||
/** Splits list into two lists of elements that respectively
|
||||
* match and don't match predicate `p`
|
||||
*/
|
||||
function partition(p : 'a => bool, l : list('a)) : (list('a) * list('a)) = partition_(p, l, [], [])
|
||||
private function partition_( p : 'a => bool
|
||||
, l : list('a)
|
||||
@@ -155,7 +181,8 @@ namespace List =
|
||||
[] => (reverse(acc_t), reverse(acc_f))
|
||||
h::t => if(p(h)) partition_(p, t, h::acc_t, acc_f) else partition_(p, t, acc_t, h::acc_f)
|
||||
|
||||
|
||||
/** Flattens list of lists into a single list
|
||||
*/
|
||||
function flatten(ll : list(list('a))) : list('a) = foldr((l1, l2) => l1 ++ l2, [], ll)
|
||||
|
||||
function all(p : 'a => bool, l : list('a)) : bool = switch(l)
|
||||
@@ -171,7 +198,9 @@ namespace List =
|
||||
function product(l : list(int)) : int = foldl((a, b) => a * b, 1, l)
|
||||
|
||||
|
||||
/* Zips two list by applying bimapping function on respective elements. Drops longer tail. */
|
||||
/** Zips two list by applying bimapping function on respective elements.
|
||||
* Drops longer tail.
|
||||
*/
|
||||
function zip_with(f : ('a, 'b) => 'c, l1 : list('a), l2 : list('b)) : list('c) = zip_with_(f, l1, l2, [])
|
||||
private function zip_with_( f : ('a, 'b) => 'c
|
||||
, l1 : list('a)
|
||||
@@ -181,7 +210,8 @@ namespace List =
|
||||
(h1::t1, h2::t2) => zip_with_(f, t1, t2, f(h1, h2)::acc)
|
||||
_ => reverse(acc)
|
||||
|
||||
/* Zips two lists into list of pairs. Drops longer tail. */
|
||||
/** Zips two lists into list of pairs. Drops longer tail.
|
||||
*/
|
||||
function zip(l1 : list('a), l2 : list('b)) : list('a * 'b) = zip_with((a, b) => (a, b), l1, l2)
|
||||
|
||||
function unzip(l : list('a * 'b)) : list('a) * list('b) = unzip_(l, [], [])
|
||||
@@ -199,7 +229,8 @@ namespace List =
|
||||
h::t => switch (partition((x) => lesser_cmp(x, h), t))
|
||||
(lesser, bigger) => sort(lesser_cmp, lesser) ++ h::sort(lesser_cmp, bigger)
|
||||
|
||||
|
||||
/** Puts `delim` between every two members of the list
|
||||
*/
|
||||
function intersperse(delim : 'a, l : list('a)) : list('a) = intersperse_(delim, l, [])
|
||||
private function intersperse_(delim : 'a, l : list('a), acc : list('a)) : list('a) = switch(l)
|
||||
[] => reverse(acc)
|
||||
@@ -207,6 +238,8 @@ namespace List =
|
||||
h::t => intersperse_(delim, t, delim::h::acc)
|
||||
|
||||
|
||||
/** Effectively a zip with an infinite sequence of natural numbers
|
||||
*/
|
||||
function enumerate(l : list('a)) : list(int * 'a) = enumerate_(l, 0, [])
|
||||
private function enumerate_(l : list('a), n : int, acc : list(int * 'a)) : list(int * 'a) = switch(l)
|
||||
[] => reverse(acc)
|
||||
|
||||
+20
-2
@@ -10,13 +10,18 @@ namespace Option =
|
||||
None => false
|
||||
Some(_) => true
|
||||
|
||||
|
||||
/** Catamorphism on `option`. Also known as inlined pattern matching.
|
||||
*/
|
||||
function match(n : 'b, s : 'a => 'b, o : option('a)) : 'b = switch(o)
|
||||
None => n
|
||||
Some(x) => s(x)
|
||||
|
||||
/** Escape option providing default if `None`
|
||||
*/
|
||||
function default(def : 'a, o : option('a)) : 'a = match(def, (x) => x, o)
|
||||
|
||||
/** Assume it is `Some`
|
||||
*/
|
||||
function force(o : option('a)) : 'a = default(abort("Forced None value"), o)
|
||||
|
||||
function on_elem(o : option('a), f : 'a => unit) : unit = match((), f, o)
|
||||
@@ -40,10 +45,14 @@ namespace Option =
|
||||
(Some(x1), Some(x2), Some(x3)) => Some(f(x1, x2, x3))
|
||||
_ => None
|
||||
|
||||
/** Like `map`, but the function is in `option`
|
||||
*/
|
||||
function app_over(f : option ('a => 'b), o : option('a)) : option('b) = switch((f, o))
|
||||
(Some(ff), Some(xx)) => Some(ff(xx))
|
||||
_ => None
|
||||
|
||||
/** Monadic bind
|
||||
*/
|
||||
function flat_map(f : 'a => option('b), o : option('a)) : option('b) = switch(o)
|
||||
None => None
|
||||
Some(x) => f(x)
|
||||
@@ -53,22 +62,31 @@ namespace Option =
|
||||
None => []
|
||||
Some(x) => [x]
|
||||
|
||||
/** Turns list of options into a list of elements that are under `Some`s.
|
||||
* Safe.
|
||||
*/
|
||||
function filter_options(l : list(option('a))) : list('a) = filter_options_(l, [])
|
||||
private function filter_options_(l : list (option('a)), acc : list('a)) : list('a) = switch(l)
|
||||
[] => List.reverse(acc)
|
||||
None::t => filter_options_(t, acc)
|
||||
Some(x)::t => filter_options_(t, x::acc)
|
||||
|
||||
/** Just like `filter_options` but requires all elements to be `Some` and returns
|
||||
* None if any of them is not
|
||||
*/
|
||||
function seq_options(l : list (option('a))) : option (list('a)) = seq_options_(l, [])
|
||||
private function seq_options_(l : list (option('a)), acc : list('a)) : option(list('a)) = switch(l)
|
||||
[] => Some(List.reverse(acc))
|
||||
None::t => None
|
||||
Some(x)::t => seq_options_(t, x::acc)
|
||||
|
||||
|
||||
/** Choose `Some` out of two if possible
|
||||
*/
|
||||
function choose(o1 : option('a), o2 : option('a)) : option('a) =
|
||||
if(is_some(o1)) o1 else o2
|
||||
|
||||
/** Choose `Some` from list of options if possible
|
||||
*/
|
||||
function choose_first(l : list(option('a))) : option('a) = switch(l)
|
||||
[] => None
|
||||
None::t => choose_first(t)
|
||||
|
||||
@@ -6,12 +6,18 @@ namespace Pair =
|
||||
function snd(t : ('a * 'b)) : 'b = switch(t)
|
||||
(_, y) => y
|
||||
|
||||
/** Map over first
|
||||
*/
|
||||
function map1(f : 'a => 'c, t : ('a * 'b)) : ('c * 'b) = switch(t)
|
||||
(x, y) => (f(x), y)
|
||||
|
||||
/** Map over second
|
||||
*/
|
||||
function map2(f : 'b => 'c, t : ('a * 'b)) : ('a * 'c) = switch(t)
|
||||
(x, y) => (x, f(y))
|
||||
|
||||
/** Map over both
|
||||
*/
|
||||
function bimap(f : 'a => 'c, g : 'b => 'd, t : ('a * 'b)) : ('c * 'd) = switch(t)
|
||||
(x, y) => (f(x), g(y))
|
||||
|
||||
|
||||
@@ -10,15 +10,23 @@ namespace Triple =
|
||||
(_, _, z) => z
|
||||
|
||||
|
||||
/** Map over first
|
||||
*/
|
||||
function map1(f : 'a => 'm, t : ('a * 'b * 'c)) : ('m * 'b * 'c) = switch(t)
|
||||
(x, y, z) => (f(x), y, z)
|
||||
|
||||
/** Map over second
|
||||
*/
|
||||
function map2(f : 'b => 'm, t : ('a * 'b * 'c)) : ('a * 'm * 'c) = switch(t)
|
||||
(x, y, z) => (x, f(y), z)
|
||||
|
||||
/** Map over third
|
||||
*/
|
||||
function map3(f : 'c => 'm, t : ('a * 'b * 'c)) : ('a * 'b * 'm) = switch(t)
|
||||
(x, y, z) => (x, y, f(z))
|
||||
|
||||
/** Map over all elements
|
||||
*/
|
||||
function trimap( f : 'a => 'x
|
||||
, g : 'b => 'y
|
||||
, h : 'c => 'z
|
||||
@@ -29,9 +37,13 @@ namespace Triple =
|
||||
function swap(t : ('a * 'b * 'c)) : ('c * 'b * 'a) = switch(t)
|
||||
(x, y, z) => (z, y, x)
|
||||
|
||||
/** Right rotation
|
||||
*/
|
||||
function rotr(t : ('a * 'b * 'c)) : ('c * 'a * 'b) = switch(t)
|
||||
(x, y, z) => (z, x, y)
|
||||
|
||||
/** Left rotation
|
||||
*/
|
||||
function rotl(t : ('a * 'b * 'c)) : ('b * 'c * 'a) = switch(t)
|
||||
(x, y, z) => (y, z, x)
|
||||
|
||||
|
||||
@@ -2072,7 +2072,8 @@ unify1(_Env, {qcon, _, Name}, {qcon, _, Name}, _When) ->
|
||||
true;
|
||||
unify1(_Env, {bytes_t, _, Len}, {bytes_t, _, Len}, _When) ->
|
||||
true;
|
||||
unify1(Env, {fun_t, _, Named1, Args1, Result1}, {fun_t, _, Named2, Args2, Result2}, When) ->
|
||||
unify1(Env, {fun_t, _, Named1, Args1, Result1}, {fun_t, _, Named2, Args2, Result2}, When)
|
||||
when length(Args1) == length(Args2) ->
|
||||
unify(Env, Named1, Named2, When) andalso
|
||||
unify(Env, Args1, Args2, When) andalso unify(Env, Result1, Result2, When);
|
||||
unify1(Env, {app_t, _, {Tag, _, F}, Args1}, {app_t, _, {Tag, _, F}, Args2}, When)
|
||||
|
||||
@@ -623,6 +623,28 @@ failing_contracts() ->
|
||||
"Empty record/map update\n"
|
||||
" r {}">>
|
||||
])
|
||||
, ?TYPE_ERROR(bad_number_of_args,
|
||||
[<<?Pos(3, 39)
|
||||
"Cannot unify () => unit\n"
|
||||
" and (int) => 'a\n",
|
||||
"when checking the application at line 3, column 39 of\n"
|
||||
" f : () => unit\n"
|
||||
"to arguments\n"
|
||||
" 1 : int">>,
|
||||
<<?Pos(4, 20)
|
||||
"Cannot unify (int, string) => 'e\n"
|
||||
" and (int) => 'd\n"
|
||||
"when checking the application at line 4, column 20 of\n"
|
||||
" g : (int, string) => 'e\n"
|
||||
"to arguments\n"
|
||||
" 1 : int">>,
|
||||
<<?Pos(5, 20)
|
||||
"Cannot unify (int, string) => 'c\n"
|
||||
" and (string) => 'b\n"
|
||||
"when checking the application at line 5, column 20 of\n"
|
||||
" g : (int, string) => 'c\nto arguments\n"
|
||||
" \"Litwo, ojczyzno moja\" : string">>
|
||||
])
|
||||
].
|
||||
|
||||
-define(Path(File), "code_errors/" ??File).
|
||||
|
||||
@@ -0,0 +1,6 @@
|
||||
contract Test =
|
||||
entrypoint f() = ()
|
||||
entrypoint g(x : int, y : string) = f(1)
|
||||
entrypoint h() = g(1)
|
||||
entrypoint i() = g("Litwo, ojczyzno moja")
|
||||
|
||||
Reference in New Issue
Block a user