// RUN: %verify "%s" /******************************************************************************* * Copyright by the contributors to the Dafny Project * SPDX-License-Identifier: MIT *******************************************************************************/ include "../Wrappers.dfy" include "../Functions.dfy" include "../Collections/Sequences/Seq.dfy" include "Unicode.dfy" /** * A Unicode encoding form assigns each Unicode scalar value to a unique code unit sequence. * * A concrete `EncodingForm` MUST define the following: * - The type `CodeUnit`. * - The predicate `IsMinimalWellFormedCodeUnitSubsequence`, which defines the set of encodings of scalar values, * known as "minimal well-formed code unit subsequences". * - The function `SplitPrefixMinimalWellFormedCodeUnitSubsequence`, which defines the algorithm by which to parse * a minimal well-formed code unit subsequence from the beginning of a code unit sequence. * - The function `EncodeScalarValue`, which defines the mapping from scalar values to minimal well-formed code unit * subsequences. * - The function `DecodeMinimalWellFormedCodeUnitSubsequence`, which defines the mapping from minimal well-formed * code unit subsequences to scalar values. */ abstract module {:options "-functionSyntax:4"} UnicodeEncodingForm { import opened Wrappers import Functions import Seq import Unicode type CodeUnitSeq = seq type WellFormedCodeUnitSeq = s: CodeUnitSeq | IsWellFormedCodeUnitSequence(s) witness [] type MinimalWellFormedCodeUnitSeq = s: CodeUnitSeq | IsMinimalWellFormedCodeUnitSubsequence(s) witness * // // Begin abstract items. // /** * A code unit is the minimal bit combination that can represent a unit of encoded text for processing or * interchange. (Section 3.9 D77.) */ type CodeUnit /** * A well-formed Unicode code unit sequence that maps to a single Unicode scalar value. * (Section 3.9 D85a.) */ function IsMinimalWellFormedCodeUnitSubsequence(s: CodeUnitSeq): (b: bool) ensures b ==> && |s| > 0 && forall i | 0 < i < |s| :: !IsMinimalWellFormedCodeUnitSubsequence(s[..i]) decreases |s| /** * Returns the shortest prefix of `s` that is a minimal well-formed code unit subsequence, * or None if there is no such prefix. */ function SplitPrefixMinimalWellFormedCodeUnitSubsequence(s: CodeUnitSeq): (maybePrefix: Option) ensures |s| == 0 ==> maybePrefix.None? ensures (exists i | 0 < i <= |s| :: IsMinimalWellFormedCodeUnitSubsequence(s[..i])) <==> && maybePrefix.Some? ensures maybePrefix.Some? ==> && var prefix := maybePrefix.Extract(); && 0 < |prefix| <= |s| && prefix == s[..|prefix|] && forall i | 0 < i < |prefix| :: !IsMinimalWellFormedCodeUnitSubsequence(s[..i]) /** * Returns the minimal well-formed code unit subsequence that this encoding form assigns to the given scalar value. * The Unicode standard requires that this is injective. * * TODO: enforce that implementations satisfy Functions.Injective */ function EncodeScalarValue(v: Unicode.ScalarValue): (m: MinimalWellFormedCodeUnitSeq) /** * Returns the scalar value that this encoding form assigns to the given minimal well-formed code unit subsequence. */ function DecodeMinimalWellFormedCodeUnitSubsequence(m: MinimalWellFormedCodeUnitSeq): (v: Unicode.ScalarValue) ensures EncodeScalarValue(v) == m // // End abstract items. // /** * If `ms` is the concatenation of a minimal well-formed code unit subsequence `m` and a code unit sequence `s`, * then the shortest minimal well-formed code unit subsequence prefix of `ms` is simply `m`. */ lemma LemmaSplitPrefixMinimalWellFormedCodeUnitSubsequenceInvertsPrepend(m: MinimalWellFormedCodeUnitSeq, s: CodeUnitSeq) ensures SplitPrefixMinimalWellFormedCodeUnitSubsequence(m + s) == Some(m) { var ms := m + s; assert IsMinimalWellFormedCodeUnitSubsequence(ms[..|m|]); var prefix := SplitPrefixMinimalWellFormedCodeUnitSubsequence(ms).Extract(); calc ==> { IsMinimalWellFormedCodeUnitSubsequence(m); |prefix| <= |m|; prefix == ms[..|prefix|] == m[..|prefix|] == m; } } /** * Returns the unique partition of the given code unit sequence into minimal well-formed code unit subsequences, * or None if no such partition exists. */ function PartitionCodeUnitSequenceChecked(s: CodeUnitSeq): (maybeParts: Option>) ensures maybeParts.Some? ==> Seq.Flatten(maybeParts.Extract()) == s decreases |s| { if s == [] then Some([]) else var prefix :- SplitPrefixMinimalWellFormedCodeUnitSubsequence(s); // Recursing/iterating on subsequences leads to quadratic running time in most/all Dafny runtimes as of this writing. // This definition (and others in the Unicode modules) emphasizes clarity and correctness, // and while the by-method implementation avoids stack overflows due to non-tail-recursive recursion, // it doesn't yet avoid the subsequences. // The best solution would be to ensure all Dafny runtimes implement subsequences as an O(1) // operation, so this implementation would become linear. var restParts :- PartitionCodeUnitSequenceChecked(s[|prefix|..]); Some([prefix] + restParts) } by method { if s == [] { return Some([]); } var result: seq := []; var rest := s; while |rest| > 0 invariant PartitionCodeUnitSequenceChecked(s).Some? <==> PartitionCodeUnitSequenceChecked(rest).Some? invariant PartitionCodeUnitSequenceChecked(s).Some? ==> && PartitionCodeUnitSequenceChecked(s).value == result + PartitionCodeUnitSequenceChecked(rest).value { var prefix :- SplitPrefixMinimalWellFormedCodeUnitSubsequence(rest); result := result + [prefix]; rest := rest[|prefix|..]; } assert result + [] == result; return Some(result); } /** * Returns the unique partition of the given well-formed code unit sequence into minimal well-formed code unit * subsequences. */ function PartitionCodeUnitSequence(s: WellFormedCodeUnitSeq): (parts: seq) ensures Seq.Flatten(parts) == s { PartitionCodeUnitSequenceChecked(s).Extract() } /** * The partitioning of a minimal well-formed code unit subsequence is the singleton sequence * containing exactly the minimal well-formed code unit subsequence. */ lemma LemmaPartitionMinimalWellFormedCodeUnitSubsequence(m: MinimalWellFormedCodeUnitSeq) ensures PartitionCodeUnitSequenceChecked(m) == Some([m]) { LemmaSplitPrefixMinimalWellFormedCodeUnitSubsequenceInvertsPrepend(m, []); calc == { Some(m); SplitPrefixMinimalWellFormedCodeUnitSubsequence(m + []); { assert m + [] == m; } SplitPrefixMinimalWellFormedCodeUnitSubsequence(m); } calc == { PartitionCodeUnitSequenceChecked(m); Some([m] + []); { assert [m] + [] == [m]; } Some([m]); } } /** * A code unit sequence is well-formed iff it can be partitioned into a sequence of minimal well-formed code unit subsequences. */ function IsWellFormedCodeUnitSequence(s: CodeUnitSeq): (b: bool) { PartitionCodeUnitSequenceChecked(s).Some? } /** * A minimal well-formed code unit subsequence is a well-formed code unit sequence. */ lemma LemmaMinimalWellFormedCodeUnitSubsequenceIsWellFormedSequence(m: MinimalWellFormedCodeUnitSeq) ensures IsWellFormedCodeUnitSequence(m) { LemmaPartitionMinimalWellFormedCodeUnitSubsequence(m); } /** * The concatenation of a minimal well-formed code unit subsequence and a well-formed code unit sequence * is itself a well-formed code unit sequence. */ lemma LemmaPrependMinimalWellFormedCodeUnitSubsequence(m: MinimalWellFormedCodeUnitSeq, s: WellFormedCodeUnitSeq) ensures IsWellFormedCodeUnitSequence(m + s) { LemmaPartitionMinimalWellFormedCodeUnitSubsequence(m); LemmaSplitPrefixMinimalWellFormedCodeUnitSubsequenceInvertsPrepend(m, s); assert PartitionCodeUnitSequenceChecked(m + s).Some?; } /** * The concatenation of minimal well-formed code unit subsequences is itself a well-formed code unit sequence. */ lemma LemmaFlattenMinimalWellFormedCodeUnitSubsequences(ms: seq) ensures IsWellFormedCodeUnitSequence(Seq.Flatten(ms)) { if |ms| == 0 { assert IsWellFormedCodeUnitSequence(Seq.Flatten(ms)); } else { var head := ms[0]; var tail := ms[1..]; LemmaFlattenMinimalWellFormedCodeUnitSubsequences(tail); var flatTail := Seq.Flatten(tail); LemmaPrependMinimalWellFormedCodeUnitSubsequence(head, flatTail); assert IsWellFormedCodeUnitSequence(head + flatTail); } } /** * The concatenation of well-formed code unit sequences is itself a well-formed code unit sequence. */ lemma LemmaConcatWellFormedCodeUnitSubsequences(s: WellFormedCodeUnitSeq, t: WellFormedCodeUnitSeq) ensures IsWellFormedCodeUnitSequence(s + t) { var partsS := PartitionCodeUnitSequence(s); var partsT := PartitionCodeUnitSequence(t); var partsST := partsS + partsT; Seq.LemmaFlattenConcat(partsS, partsT); assert s + t == Seq.Flatten(partsST); assert forall part | part in partsST :: && |part| > 0 && IsMinimalWellFormedCodeUnitSubsequence(part); LemmaFlattenMinimalWellFormedCodeUnitSubsequences(partsST); } /** * Returns the well-formed Unicode string that is the encoding of the given scalar value sequence. */ function EncodeScalarSequence(vs: seq): (s: WellFormedCodeUnitSeq) { var ms := Seq.Map(EncodeScalarValue, vs); LemmaFlattenMinimalWellFormedCodeUnitSubsequences(ms); Seq.Flatten(ms) } by method { // Optimize to to avoid allocating the intermediate unflattened sequence. // We can't quite use Seq.FlatMap easily because we need to prove the result // is not just a seq but a WellFormedCodeUnitSeq. // TODO: We can be even more efficient by using a JSON.Utils.Vectors.Vector instead. s := []; ghost var unflattened: seq := []; for i := |vs| downto 0 invariant unflattened == Seq.Map(EncodeScalarValue, vs[i..]) invariant s == Seq.Flatten(unflattened) { var next: MinimalWellFormedCodeUnitSeq := EncodeScalarValue(vs[i]); unflattened := [next] + unflattened; LemmaPrependMinimalWellFormedCodeUnitSubsequence(next, s); s := next + s; } } /** * Returns the scalar value sequence encoded by the given well-formed Unicode string. */ function DecodeCodeUnitSequence(s: WellFormedCodeUnitSeq): (vs: seq) ensures EncodeScalarSequence(vs) == s { var parts := PartitionCodeUnitSequence(s); var vs := Seq.Map(DecodeMinimalWellFormedCodeUnitSubsequence, parts); calc == { s; Seq.Flatten(parts); { assert parts == Seq.Map(EncodeScalarValue, vs); } Seq.Flatten(Seq.Map(EncodeScalarValue, vs)); EncodeScalarSequence(vs); } vs } /** * Returns the scalar value sequence encoded by the given code unit sequence, or None if the given Unicode string * is not well-formed. */ function DecodeCodeUnitSequenceChecked(s: CodeUnitSeq): (maybeVs: Option>) ensures IsWellFormedCodeUnitSequence(s) ==> && maybeVs.Some? && maybeVs.Extract() == DecodeCodeUnitSequence(s) ensures !IsWellFormedCodeUnitSequence(s) ==> && maybeVs.None? { // IsWellFormedCodeUnitSequence and DecodeCodeUnitSequence each call PartitionCodeUnitSequence, // so for efficiency we avoid recomputing the partition in the by-method. if IsWellFormedCodeUnitSequence(s) then Some(DecodeCodeUnitSequence(s)) else None } by method { var maybeParts := PartitionCodeUnitSequenceChecked(s); if maybeParts.None? { return None; } var parts := maybeParts.value; var vs := Seq.Map(DecodeMinimalWellFormedCodeUnitSubsequence, parts); calc == { s; Seq.Flatten(parts); { assert parts == Seq.Map(EncodeScalarValue, vs); } Seq.Flatten(Seq.Map(EncodeScalarValue, vs)); EncodeScalarSequence(vs); } return Some(vs); } }