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use crate::front::wgsl::error::NumberError;
use crate::front::wgsl::parse::lexer::Token;
/// When using this type assume no Abstract Int/Float for now
#[derive(Copy, Clone, Debug, PartialEq)]
pub enum Number {
/// Abstract Int (-2^63 ≤ i < 2^63)
AbstractInt(i64),
/// Abstract Float (IEEE-754 binary64)
AbstractFloat(f64),
/// Concrete i32
I32(i32),
/// Concrete u32
U32(u32),
/// Concrete i64
I64(i64),
/// Concrete u64
U64(u64),
/// Concrete f32
F32(f32),
/// Concrete f64
F64(f64),
}
pub(in crate::front::wgsl) fn consume_number(input: &str) -> (Token<'_>, &str) {
let (result, rest) = parse(input);
(Token::Number(result), rest)
}
enum Kind {
Int(IntKind),
Float(FloatKind),
}
enum IntKind {
I32,
U32,
I64,
U64,
}
#[derive(Debug)]
enum FloatKind {
F16,
F32,
F64,
}
// The following regexes (from the WGSL spec) will be matched:
// int_literal:
// | / 0 [iu]? /
// | / [1-9][0-9]* [iu]? /
// | / 0[xX][0-9a-fA-F]+ [iu]? /
// decimal_float_literal:
// | / 0 [fh] /
// | / [1-9][0-9]* [fh] /
// | / [0-9]* \.[0-9]+ ([eE][+-]?[0-9]+)? [fh]? /
// | / [0-9]+ \.[0-9]* ([eE][+-]?[0-9]+)? [fh]? /
// | / [0-9]+ [eE][+-]?[0-9]+ [fh]? /
// hex_float_literal:
// | / 0[xX][0-9a-fA-F]* \.[0-9a-fA-F]+ ([pP][+-]?[0-9]+ [fh]?)? /
// | / 0[xX][0-9a-fA-F]+ \.[0-9a-fA-F]* ([pP][+-]?[0-9]+ [fh]?)? /
// | / 0[xX][0-9a-fA-F]+ [pP][+-]?[0-9]+ [fh]? /
// You could visualize the regex below via https://debuggex.com to get a rough idea what `parse` is doing
// (?:0[xX](?:([0-9a-fA-F]+\.[0-9a-fA-F]*|[0-9a-fA-F]*\.[0-9a-fA-F]+)(?:([pP][+-]?[0-9]+)([fh]?))?|([0-9a-fA-F]+)([pP][+-]?[0-9]+)([fh]?)|([0-9a-fA-F]+)([iu]?))|((?:[0-9]+[eE][+-]?[0-9]+|(?:[0-9]+\.[0-9]*|[0-9]*\.[0-9]+)(?:[eE][+-]?[0-9]+)?))([fh]?)|((?:[0-9]|[1-9][0-9]+))([iufh]?))
// Leading signs are handled as unary operators.
fn parse(input: &str) -> (Result<Number, NumberError>, &str) {
/// returns `true` and consumes `X` bytes from the given byte buffer
/// if the given `X` nr of patterns are found at the start of the buffer
macro_rules! consume {
($bytes:ident, $($pattern:pat),*) => {
match $bytes {
&[$($pattern),*, ref rest @ ..] => { $bytes = rest; true },
_ => false,
}
};
}
/// consumes one byte from the given byte buffer
/// if one of the given patterns are found at the start of the buffer
/// returning the corresponding expr for the matched pattern
macro_rules! consume_map {
($bytes:ident, [$( $($pattern:pat_param),* => $to:expr),* $(,)?]) => {
match $bytes {
$( &[ $($pattern),*, ref rest @ ..] => { $bytes = rest; Some($to) }, )*
_ => None,
}
};
}
/// consumes all consecutive bytes matched by the `0-9` pattern from the given byte buffer
/// returning the number of consumed bytes
macro_rules! consume_dec_digits {
($bytes:ident) => {{
let start_len = $bytes.len();
while let &[b'0'..=b'9', ref rest @ ..] = $bytes {
$bytes = rest;
}
start_len - $bytes.len()
}};
}
/// consumes all consecutive bytes matched by the `0-9 | a-f | A-F` pattern from the given byte buffer
/// returning the number of consumed bytes
macro_rules! consume_hex_digits {
($bytes:ident) => {{
let start_len = $bytes.len();
while let &[b'0'..=b'9' | b'a'..=b'f' | b'A'..=b'F', ref rest @ ..] = $bytes {
$bytes = rest;
}
start_len - $bytes.len()
}};
}
macro_rules! consume_float_suffix {
($bytes:ident) => {
consume_map!($bytes, [
b'h' => FloatKind::F16,
b'f' => FloatKind::F32,
b'l', b'f' => FloatKind::F64,
])
};
}
/// maps the given `&[u8]` (tail of the initial `input: &str`) to a `&str`
macro_rules! rest_to_str {
($bytes:ident) => {
&input[input.len() - $bytes.len()..]
};
}
struct ExtractSubStr<'a>(&'a str);
impl<'a> ExtractSubStr<'a> {
/// given an `input` and a `start` (tail of the `input`)
/// creates a new [`ExtractSubStr`](`Self`)
fn start(input: &'a str, start: &'a [u8]) -> Self {
let start = input.len() - start.len();
Self(&input[start..])
}
/// given an `end` (tail of the initial `input`)
/// returns a substring of `input`
fn end(&self, end: &'a [u8]) -> &'a str {
let end = self.0.len() - end.len();
&self.0[..end]
}
}
let mut bytes = input.as_bytes();
let general_extract = ExtractSubStr::start(input, bytes);
if consume!(bytes, b'0', b'x' | b'X') {
let digits_extract = ExtractSubStr::start(input, bytes);
let consumed = consume_hex_digits!(bytes);
if consume!(bytes, b'.') {
let consumed_after_period = consume_hex_digits!(bytes);
if consumed + consumed_after_period == 0 {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
let significand = general_extract.end(bytes);
if consume!(bytes, b'p' | b'P') {
consume!(bytes, b'+' | b'-');
let consumed = consume_dec_digits!(bytes);
if consumed == 0 {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
let number = general_extract.end(bytes);
let kind = consume_float_suffix!(bytes);
(parse_hex_float(number, kind), rest_to_str!(bytes))
} else {
(
parse_hex_float_missing_exponent(significand, None),
rest_to_str!(bytes),
)
}
} else {
if consumed == 0 {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
let significand = general_extract.end(bytes);
let digits = digits_extract.end(bytes);
let exp_extract = ExtractSubStr::start(input, bytes);
if consume!(bytes, b'p' | b'P') {
consume!(bytes, b'+' | b'-');
let consumed = consume_dec_digits!(bytes);
if consumed == 0 {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
let exponent = exp_extract.end(bytes);
let kind = consume_float_suffix!(bytes);
(
parse_hex_float_missing_period(significand, exponent, kind),
rest_to_str!(bytes),
)
} else {
let kind = consume_map!(bytes, [b'i' => IntKind::I32, b'u' => IntKind::U32]);
(parse_hex_int(digits, kind), rest_to_str!(bytes))
}
}
} else {
let is_first_zero = bytes.first() == Some(&b'0');
let consumed = consume_dec_digits!(bytes);
if consume!(bytes, b'.') {
let consumed_after_period = consume_dec_digits!(bytes);
if consumed + consumed_after_period == 0 {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
if consume!(bytes, b'e' | b'E') {
consume!(bytes, b'+' | b'-');
let consumed = consume_dec_digits!(bytes);
if consumed == 0 {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
}
let number = general_extract.end(bytes);
let kind = consume_float_suffix!(bytes);
(parse_dec_float(number, kind), rest_to_str!(bytes))
} else {
if consumed == 0 {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
if consume!(bytes, b'e' | b'E') {
consume!(bytes, b'+' | b'-');
let consumed = consume_dec_digits!(bytes);
if consumed == 0 {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
let number = general_extract.end(bytes);
let kind = consume_float_suffix!(bytes);
(parse_dec_float(number, kind), rest_to_str!(bytes))
} else {
// make sure the multi-digit numbers don't start with zero
if consumed > 1 && is_first_zero {
return (Err(NumberError::Invalid), rest_to_str!(bytes));
}
let digits = general_extract.end(bytes);
let kind = consume_map!(bytes, [
b'i' => Kind::Int(IntKind::I32),
b'u' => Kind::Int(IntKind::U32),
b'l', b'i' => Kind::Int(IntKind::I64),
b'l', b'u' => Kind::Int(IntKind::U64),
b'h' => Kind::Float(FloatKind::F16),
b'f' => Kind::Float(FloatKind::F32),
b'l', b'f' => Kind::Float(FloatKind::F64),
]);
(parse_dec(digits, kind), rest_to_str!(bytes))
}
}
}
}
fn parse_hex_float_missing_exponent(
// format: 0[xX] ( [0-9a-fA-F]+\.[0-9a-fA-F]* | [0-9a-fA-F]*\.[0-9a-fA-F]+ )
significand: &str,
kind: Option<FloatKind>,
) -> Result<Number, NumberError> {
let hexf_input = format!("{}{}", significand, "p0");
parse_hex_float(&hexf_input, kind)
}
fn parse_hex_float_missing_period(
// format: 0[xX] [0-9a-fA-F]+
significand: &str,
// format: [pP][+-]?[0-9]+
exponent: &str,
kind: Option<FloatKind>,
) -> Result<Number, NumberError> {
let hexf_input = format!("{significand}.{exponent}");
parse_hex_float(&hexf_input, kind)
}
fn parse_hex_int(
// format: [0-9a-fA-F]+
digits: &str,
kind: Option<IntKind>,
) -> Result<Number, NumberError> {
parse_int(digits, kind, 16)
}
fn parse_dec(
// format: ( [0-9] | [1-9][0-9]+ )
digits: &str,
kind: Option<Kind>,
) -> Result<Number, NumberError> {
match kind {
None => parse_int(digits, None, 10),
Some(Kind::Int(kind)) => parse_int(digits, Some(kind), 10),
Some(Kind::Float(kind)) => parse_dec_float(digits, Some(kind)),
}
}
// Float parsing notes
// The following chapters of IEEE 754-2019 are relevant:
//
// 7.4 Overflow (largest finite number is exceeded by what would have been
// the rounded floating-point result were the exponent range unbounded)
//
// 7.5 Underflow (tiny non-zero result is detected;
// for decimal formats tininess is detected before rounding when a non-zero result
// computed as though both the exponent range and the precision were unbounded
// would lie strictly between 2^−126)
//
// 7.6 Inexact (rounded result differs from what would have been computed
// were both exponent range and precision unbounded)
// The WGSL spec requires us to error:
// on overflow for decimal floating point literals
// on overflow and inexact for hexadecimal floating point literals
// (underflow is not mentioned)
// hexf_parse errors on overflow, underflow, inexact
// rust std lib float from str handles overflow, underflow, inexact transparently (rounds and will not error)
// Therefore we only check for overflow manually for decimal floating point literals
// input format: 0[xX] ( [0-9a-fA-F]+\.[0-9a-fA-F]* | [0-9a-fA-F]*\.[0-9a-fA-F]+ ) [pP][+-]?[0-9]+
fn parse_hex_float(input: &str, kind: Option<FloatKind>) -> Result<Number, NumberError> {
match kind {
None => match hexf_parse::parse_hexf64(input, false) {
Ok(num) => Ok(Number::AbstractFloat(num)),
// can only be ParseHexfErrorKind::Inexact but we can't check since it's private
_ => Err(NumberError::NotRepresentable),
},
Some(FloatKind::F16) => Err(NumberError::UnimplementedF16),
Some(FloatKind::F32) => match hexf_parse::parse_hexf32(input, false) {
Ok(num) => Ok(Number::F32(num)),
// can only be ParseHexfErrorKind::Inexact but we can't check since it's private
_ => Err(NumberError::NotRepresentable),
},
Some(FloatKind::F64) => match hexf_parse::parse_hexf64(input, false) {
Ok(num) => Ok(Number::F64(num)),
// can only be ParseHexfErrorKind::Inexact but we can't check since it's private
_ => Err(NumberError::NotRepresentable),
},
}
}
// input format: ( [0-9]+\.[0-9]* | [0-9]*\.[0-9]+ ) ([eE][+-]?[0-9]+)?
// | [0-9]+ [eE][+-]?[0-9]+
fn parse_dec_float(input: &str, kind: Option<FloatKind>) -> Result<Number, NumberError> {
match kind {
None => {
let num = input.parse::<f64>().unwrap(); // will never fail
num.is_finite()
.then_some(Number::AbstractFloat(num))
.ok_or(NumberError::NotRepresentable)
}
Some(FloatKind::F32) => {
let num = input.parse::<f32>().unwrap(); // will never fail
num.is_finite()
.then_some(Number::F32(num))
.ok_or(NumberError::NotRepresentable)
}
Some(FloatKind::F64) => {
let num = input.parse::<f64>().unwrap(); // will never fail
num.is_finite()
.then_some(Number::F64(num))
.ok_or(NumberError::NotRepresentable)
}
Some(FloatKind::F16) => Err(NumberError::UnimplementedF16),
}
}
fn parse_int(input: &str, kind: Option<IntKind>, radix: u32) -> Result<Number, NumberError> {
fn map_err(e: core::num::ParseIntError) -> NumberError {
match *e.kind() {
core::num::IntErrorKind::PosOverflow | core::num::IntErrorKind::NegOverflow => {
NumberError::NotRepresentable
}
_ => unreachable!(),
}
}
match kind {
None => match i64::from_str_radix(input, radix) {
Ok(num) => Ok(Number::AbstractInt(num)),
Err(e) => Err(map_err(e)),
},
Some(IntKind::I32) => match i32::from_str_radix(input, radix) {
Ok(num) => Ok(Number::I32(num)),
Err(e) => Err(map_err(e)),
},
Some(IntKind::U32) => match u32::from_str_radix(input, radix) {
Ok(num) => Ok(Number::U32(num)),
Err(e) => Err(map_err(e)),
},
Some(IntKind::I64) => match i64::from_str_radix(input, radix) {
Ok(num) => Ok(Number::I64(num)),
Err(e) => Err(map_err(e)),
},
Some(IntKind::U64) => match u64::from_str_radix(input, radix) {
Ok(num) => Ok(Number::U64(num)),
Err(e) => Err(map_err(e)),
},
}
}