Datasets:

emugnier
/

DafnyGym

	// RUN: %verify "%s" --unicode-char:false ../Unicode/UnicodeStringsWithoutUnicodeChar.dfy
	// RUN: %verify "%s" --unicode-char:true ../Unicode/UnicodeStringsWithUnicodeChar.dfy

	/// ==================================================
	/// Deserialization from JSON.Grammar to JSON.Values
	/// ==================================================
	///
	/// For the spec, see ``JSON.Spec.dfy``.

	include "../Collections/Sequences/Seq.dfy"
	include "../BoundedInts.dfy"

	include "Utils/Views.dfy"
	include "Utils/Vectors.dfy"
	include "Errors.dfy"
	include "Values.dfy"
	include "Grammar.dfy"
	include "Spec.dfy"

	module {:options "-functionSyntax:4"} JSON.Deserializer {
	import Seq

	import opened Wrappers
	import opened BoundedInts
	import opened Logarithm
	import opened Power
	import opened Utils.Str
	import opened UnicodeStrings

	import Values
	import Spec
	import opened Errors
	import opened Utils.Vectors
	import opened Grammar
	import opened Utils.Views.Core

	function Bool(js: Grammar.jbool): bool {
	assert js.Bytes() in {Grammar.TRUE, Grammar.FALSE};
	js.At(0) == 't' as byte
	}

	function UnsupportedEscape16(code: seq<uint16>): DeserializationError {
	UnsupportedEscape(FromUTF16Checked(code).UnwrapOr("Couldn't decode UTF-16"))
	}

	module Uint16StrConversion refines Str.ParametricConversion {
	import opened BoundedInts

	type Char = uint16
	}

	const HEX_TABLE_16: map<Uint16StrConversion.Char, nat> :=
	map[
	'0' as uint16 := 0, '1' as uint16 := 1, '2' as uint16 := 2, '3' as uint16 := 3, '4' as uint16 := 4,
	'5' as uint16 := 5, '6' as uint16 := 6, '7' as uint16 := 7, '8' as uint16 := 8, '9' as uint16 := 9,
	'a' as uint16 := 0xA, 'b' as uint16 := 0xB, 'c' as uint16 := 0xC, 'd' as uint16 := 0xD, 'e' as uint16 := 0xE, 'f' as uint16 := 0xF,
	'A' as uint16 := 0xA, 'B' as uint16 := 0xB, 'C' as uint16 := 0xC, 'D' as uint16 := 0xD, 'E' as uint16 := 0xE, 'F' as uint16 := 0xF
	]

	function ToNat16(str: Uint16StrConversion.String): uint16
	requires \|str\| <= 4
	requires forall c \| c in str :: c in HEX_TABLE_16
	{
	Uint16StrConversion.ToNat_bound(str, 16, HEX_TABLE_16);
	var hd := Uint16StrConversion.ToNat_any(str, 16, HEX_TABLE_16);
	assert hd < 0x1_0000 by { reveal Pow(); }
	hd as uint16
	}

	function {:tailrecursion} {:vcs_split_on_every_assert} Unescape(str: seq<uint16>, start: nat := 0, prefix: seq<uint16> := []): DeserializationResult<seq<uint16>>
	decreases \|str\| - start
	{ // Assumes UTF-16 strings
	if start >= \|str\| then Success(prefix)
	else if str[start] == '\\' as uint16 then
	if \|str\| == start + 1 then
	Failure(EscapeAtEOS)
	else
	var c := str[start + 1];
	if c == 'u' as uint16 then
	if \|str\| <= start + 6 then
	Failure(EscapeAtEOS)
	else
	var code := str[start + 2..start + 6];
	if exists c \| c in code :: c !in HEX_TABLE_16 then
	Failure(UnsupportedEscape16(code))
	else
	var hd := ToNat16(code);
	Unescape(str, start + 6, prefix + [hd])
	else
	var unescaped: uint16 := match c
	case 0x22 => 0x22 as uint16 // \" => quotation mark
	case 0x5C => 0x5C as uint16 // \\ => reverse solidus
	case 0x62 => 0x08 as uint16 // \b => backspace
	case 0x66 => 0x0C as uint16 // \f => form feed
	case 0x6E => 0x0A as uint16 // \n => line feed
	case 0x72 => 0x0D as uint16 // \r => carriage return
	case 0x74 => 0x09 as uint16 // \t => tab
	case _ => 0 as uint16;
	if unescaped as int == 0 then
	Failure(UnsupportedEscape16(str[start..start+2]))
	else
	Unescape(str, start + 2, prefix + [unescaped])
	else
	Unescape(str, start + 1, prefix + [str[start]])
	}

	function String(js: Grammar.jstring): DeserializationResult<string> {
	var asUtf32 :- FromUTF8Checked(js.contents.Bytes()).ToResult'(DeserializationError.InvalidUnicode);
	var asUint16 :- ToUTF16Checked(asUtf32).ToResult'(DeserializationError.InvalidUnicode);
	var unescaped :- Unescape(asUint16);
	FromUTF16Checked(unescaped).ToResult'(DeserializationError.InvalidUnicode)
	}

	module ByteStrConversion refines Str.ParametricConversion {
	import opened BoundedInts
	type Char = byte
	}

	const DIGITS :=
	map[
	'0' as uint8 := 0, '1' as uint8 := 1, '2' as uint8 := 2, '3' as uint8 := 3,
	'4' as uint8 := 4, '5' as uint8 := 5, '6' as uint8 := 6, '7' as uint8 := 7,
	'8' as uint8 := 8, '9' as uint8 := 9
	]

	const MINUS := '-' as uint8

	function ToInt(sign: jsign, n: jnum): DeserializationResult<int> {
	var n: int := ByteStrConversion.ToNat_any(n.Bytes(), 10, DIGITS);
	Success(if sign.Char?('-') then -n else n)
	}

	function Number(js: Grammar.jnumber): DeserializationResult<Values.Decimal> {
	var JNumber(minus, num, frac, exp) := js;
	var n :-
	ToInt(minus, num);
	var e10 :- match exp
	case Empty => Success(0)
	case NonEmpty(JExp(_, sign, num)) => ToInt(sign, num);
	match frac
	case Empty => Success(Values.Decimal(n, e10))
	case NonEmpty(JFrac(_, num)) =>
	var pow10 := num.Length() as int;
	var frac :- ToInt(minus, num);
	Success(Values.Decimal(n * Pow(10, pow10) + frac, e10 - pow10))
	}

	function KeyValue(js: Grammar.jKeyValue): DeserializationResult<(string, Values.JSON)> {
	var k :- String(js.k);
	var v :- Value(js.v);
	Success((k, v))
	}

	function Object(js: Grammar.jobject): DeserializationResult<seq<(string, Values.JSON)>> {
	Seq.MapWithResult(d requires d in js.data => KeyValue(d.t), js.data)
	}

	function Array(js: Grammar.jarray): DeserializationResult<seq<Values.JSON>> {
	Seq.MapWithResult(d requires d in js.data => Value(d.t), js.data)
	}

	function Value(js: Grammar.Value): DeserializationResult<Values.JSON> {
	match js
	case Null(_) => Success(Values.Null())
	case Bool(b) => Success(Values.Bool(Bool(b)))
	case String(str) => var s :- String(str); Success(Values.String(s))
	case Number(dec) => var n :- Number(dec); Success(Values.Number(n))
	case Object(obj) => var o :- Object(obj); Success(Values.Object(o))
	case Array(arr) => var a :- Array(arr); Success(Values.Array(a))
	}

	function JSON(js: Grammar.JSON): DeserializationResult<Values.JSON> {
	Value(js.t)
	}
	}