| // Copyright 2020 The Tint Authors. |
| // |
| // Licensed under the Apache License, Version 2.0 (the "License"); |
| // you may not use this file except in compliance with the License. |
| // You may obtain a copy of the License at |
| // |
| // http://www.apache.org/licenses/LICENSE-2.0 |
| // |
| // Unless required by applicable law or agreed to in writing, software |
| // distributed under the License is distributed on an "AS IS" BASIS, |
| // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| // See the License for the specific language governing permissions and |
| // limitations under the License. |
| |
| #include "src/tint/lang/wgsl/reader/parser/lexer.h" |
| |
| #include <cctype> |
| #include <charconv> |
| #include <cmath> |
| #include <cstring> |
| #include <functional> |
| #include <limits> |
| #include <optional> |
| #include <tuple> |
| #include <type_traits> |
| #include <utility> |
| |
| #include "src/tint/lang/core/fluent_types.h" |
| #include "src/tint/lang/core/number.h" |
| #include "src/tint/utils/ice/ice.h" |
| #include "src/tint/utils/strconv/parse_num.h" |
| #include "src/tint/utils/text/unicode.h" |
| |
| using namespace tint::core::fluent_types; // NOLINT |
| |
| namespace tint::wgsl::reader { |
| namespace { |
| |
| // Unicode parsing code assumes that the size of a single std::string element is |
| // 1 byte. |
| static_assert(sizeof(decltype(tint::Source::FileContent::data[0])) == sizeof(uint8_t), |
| "tint::wgsl::reader requires the size of a std::string element " |
| "to be a single byte"); |
| |
| // A token is ~80bytes. The 4k here comes from looking at the number of tokens in the benchmark |
| // programs and being a bit bigger then those need (atan2-const-eval is the outlier here). |
| static constexpr size_t kDefaultListSize = 4092; |
| |
| bool read_blankspace(std::string_view str, size_t i, bool* is_blankspace, size_t* blankspace_size) { |
| // See https://www.w3.org/TR/WGSL/#blankspace |
| |
| auto* utf8 = reinterpret_cast<const uint8_t*>(&str[i]); |
| auto [cp, n] = tint::utf8::Decode(utf8, str.size() - i); |
| |
| if (n == 0) { |
| return false; |
| } |
| |
| static const auto kSpace = tint::CodePoint(0x0020); // space |
| static const auto kHTab = tint::CodePoint(0x0009); // horizontal tab |
| static const auto kL2R = tint::CodePoint(0x200E); // left-to-right mark |
| static const auto kR2L = tint::CodePoint(0x200F); // right-to-left mark |
| |
| if (cp == kSpace || cp == kHTab || cp == kL2R || cp == kR2L) { |
| *is_blankspace = true; |
| *blankspace_size = n; |
| return true; |
| } |
| |
| *is_blankspace = false; |
| return true; |
| } |
| |
| uint32_t dec_value(char c) { |
| if (c >= '0' && c <= '9') { |
| return static_cast<uint32_t>(c - '0'); |
| } |
| return 0; |
| } |
| |
| uint32_t hex_value(char c) { |
| if (c >= '0' && c <= '9') { |
| return static_cast<uint32_t>(c - '0'); |
| } |
| if (c >= 'a' && c <= 'f') { |
| return 0xA + static_cast<uint32_t>(c - 'a'); |
| } |
| if (c >= 'A' && c <= 'F') { |
| return 0xA + static_cast<uint32_t>(c - 'A'); |
| } |
| return 0; |
| } |
| |
| } // namespace |
| |
| Lexer::Lexer(const Source::File* file) : file_(file), location_{1, 1} {} |
| |
| Lexer::~Lexer() = default; |
| |
| std::vector<Token> Lexer::Lex() { |
| std::vector<Token> tokens; |
| tokens.reserve(kDefaultListSize); |
| |
| while (true) { |
| tokens.emplace_back(next()); |
| if (tokens.back().IsEof() || tokens.back().IsError()) { |
| break; |
| } |
| |
| // If the token can be split, we insert a placeholder element(s) into the stream to hold the |
| // split character. |
| size_t num_placeholders = tokens.back().NumPlaceholders(); |
| for (size_t i = 0; i < num_placeholders; i++) { |
| auto src = tokens.back().source(); |
| src.range.begin.column++; |
| tokens.emplace_back(Token::Type::kPlaceholder, src); |
| } |
| } |
| return tokens; |
| } |
| |
| const std::string_view Lexer::line() const { |
| if (file_->content.lines.size() == 0) { |
| static const char* empty_string = ""; |
| return empty_string; |
| } |
| return file_->content.lines[location_.line - 1]; |
| } |
| |
| size_t Lexer::pos() const { |
| return location_.column - 1; |
| } |
| |
| size_t Lexer::length() const { |
| return line().size(); |
| } |
| |
| const char& Lexer::at(size_t pos) const { |
| auto l = line(); |
| // Unlike for std::string, if pos == l.size(), indexing `l[pos]` is UB for |
| // std::string_view. |
| if (pos >= l.size()) { |
| static const char zero = 0; |
| return zero; |
| } |
| return l[pos]; |
| } |
| |
| std::string_view Lexer::substr(size_t offset, size_t count) { |
| return line().substr(offset, count); |
| } |
| |
| void Lexer::advance(size_t offset) { |
| location_.column += offset; |
| } |
| |
| void Lexer::set_pos(size_t pos) { |
| location_.column = pos + 1; |
| } |
| |
| void Lexer::advance_line() { |
| location_.line++; |
| location_.column = 1; |
| } |
| |
| bool Lexer::is_eof() const { |
| return location_.line >= file_->content.lines.size() && pos() >= length(); |
| } |
| |
| bool Lexer::is_eol() const { |
| return pos() >= length(); |
| } |
| |
| Token Lexer::next() { |
| if (auto t = skip_blankspace_and_comments(); t.has_value() && !t->IsUninitialized()) { |
| return std::move(t.value()); |
| } |
| |
| if (auto t = try_hex_float(); t.has_value() && !t->IsUninitialized()) { |
| return std::move(t.value()); |
| } |
| |
| if (auto t = try_hex_integer(); t.has_value() && !t->IsUninitialized()) { |
| return std::move(t.value()); |
| } |
| |
| if (auto t = try_float(); t.has_value() && !t->IsUninitialized()) { |
| return std::move(t.value()); |
| } |
| |
| if (auto t = try_integer(); t.has_value() && !t->IsUninitialized()) { |
| return std::move(t.value()); |
| } |
| |
| if (auto t = try_ident(); t.has_value() && !t->IsUninitialized()) { |
| return std::move(t.value()); |
| } |
| |
| if (auto t = try_punctuation(); t.has_value() && !t->IsUninitialized()) { |
| return std::move(t.value()); |
| } |
| |
| return {Token::Type::kError, begin_source(), |
| (is_null() ? "null character found" : "invalid character found")}; |
| } |
| |
| Source Lexer::begin_source() const { |
| Source src{}; |
| src.file = file_; |
| src.range.begin = location_; |
| src.range.end = location_; |
| return src; |
| } |
| |
| void Lexer::end_source(Source& src) const { |
| src.range.end = location_; |
| } |
| |
| bool Lexer::is_null() const { |
| return (pos() < length()) && (at(pos()) == 0); |
| } |
| |
| bool Lexer::is_digit(char ch) const { |
| return std::isdigit(static_cast<unsigned char>(ch)); |
| } |
| |
| bool Lexer::is_hex(char ch) const { |
| return std::isxdigit(static_cast<unsigned char>(ch)); |
| } |
| |
| bool Lexer::matches(size_t pos, std::string_view sub_string) { |
| if (pos >= length()) { |
| return false; |
| } |
| return substr(pos, sub_string.size()) == sub_string; |
| } |
| |
| bool Lexer::matches(size_t pos, char ch) { |
| if (pos >= length()) { |
| return false; |
| } |
| return line()[pos] == ch; |
| } |
| |
| std::optional<Token> Lexer::skip_blankspace_and_comments() { |
| for (;;) { |
| auto loc = location_; |
| while (!is_eof()) { |
| if (is_eol()) { |
| advance_line(); |
| continue; |
| } |
| |
| bool is_blankspace; |
| size_t blankspace_size; |
| if (!read_blankspace(line(), pos(), &is_blankspace, &blankspace_size)) { |
| return Token{Token::Type::kError, begin_source(), "invalid UTF-8"}; |
| } |
| if (!is_blankspace) { |
| break; |
| } |
| |
| advance(blankspace_size); |
| } |
| |
| auto t = skip_comment(); |
| if (t.has_value() && !t->IsUninitialized()) { |
| return t; |
| } |
| |
| // If the cursor didn't advance we didn't remove any blankspace |
| // so we're done. |
| if (loc == location_) { |
| break; |
| } |
| } |
| if (is_eof()) { |
| return Token{Token::Type::kEOF, begin_source()}; |
| } |
| |
| return {}; |
| } |
| |
| std::optional<Token> Lexer::skip_comment() { |
| if (matches(pos(), "//")) { |
| // Line comment: ignore everything until the end of line. |
| while (!is_eol()) { |
| if (is_null()) { |
| return Token{Token::Type::kError, begin_source(), "null character found"}; |
| } |
| advance(); |
| } |
| return {}; |
| } |
| |
| if (matches(pos(), "/*")) { |
| // Block comment: ignore everything until the closing '*/' token. |
| |
| // Record source location of the initial '/*' |
| auto source = begin_source(); |
| source.range.end.column += 1; |
| |
| advance(2); |
| |
| int depth = 1; |
| while (!is_eof() && depth > 0) { |
| if (matches(pos(), "/*")) { |
| // Start of block comment: increase nesting depth. |
| advance(2); |
| depth++; |
| } else if (matches(pos(), "*/")) { |
| // End of block comment: decrease nesting depth. |
| advance(2); |
| depth--; |
| } else if (is_eol()) { |
| // Newline: skip and update source location. |
| advance_line(); |
| } else if (is_null()) { |
| return Token{Token::Type::kError, begin_source(), "null character found"}; |
| } else { |
| // Anything else: skip and update source location. |
| advance(); |
| } |
| } |
| if (depth > 0) { |
| return Token{Token::Type::kError, source, "unterminated block comment"}; |
| } |
| } |
| return {}; |
| } |
| |
| std::optional<Token> Lexer::try_float() { |
| auto start = pos(); |
| auto end = pos(); |
| |
| auto source = begin_source(); |
| bool has_mantissa_digits = false; |
| |
| std::optional<size_t> first_significant_digit_position; |
| while (end < length() && is_digit(at(end))) { |
| if (!first_significant_digit_position.has_value() && (at(end) != '0')) { |
| first_significant_digit_position = end; |
| } |
| |
| has_mantissa_digits = true; |
| end++; |
| } |
| |
| std::optional<size_t> dot_position; |
| if (end < length() && matches(end, '.')) { |
| dot_position = end; |
| end++; |
| } |
| |
| size_t zeros_before_digit = 0; |
| while (end < length() && is_digit(at(end))) { |
| if (!first_significant_digit_position.has_value()) { |
| if (at(end) == '0') { |
| zeros_before_digit += 1; |
| } else { |
| first_significant_digit_position = end; |
| } |
| } |
| |
| has_mantissa_digits = true; |
| end++; |
| } |
| |
| if (!has_mantissa_digits) { |
| return {}; |
| } |
| |
| // Parse the exponent if one exists |
| std::optional<size_t> exponent_value_position; |
| bool negative_exponent = false; |
| if (end < length() && (matches(end, 'e') || matches(end, 'E'))) { |
| end++; |
| if (end < length() && (matches(end, '+') || matches(end, '-'))) { |
| negative_exponent = matches(end, '-'); |
| end++; |
| } |
| exponent_value_position = end; |
| |
| bool has_digits = false; |
| while (end < length() && isdigit(at(end))) { |
| has_digits = true; |
| end++; |
| } |
| |
| // If an 'e' or 'E' was present, then the number part must also be present. |
| if (!has_digits) { |
| const auto str = std::string{substr(start, end - start)}; |
| return Token{Token::Type::kError, source, |
| "incomplete exponent for floating point literal: " + str}; |
| } |
| } |
| |
| bool has_f_suffix = false; |
| bool has_h_suffix = false; |
| if (end < length() && matches(end, 'f')) { |
| has_f_suffix = true; |
| } else if (end < length() && matches(end, 'h')) { |
| has_h_suffix = true; |
| } |
| |
| if (!dot_position.has_value() && !exponent_value_position.has_value() && !has_f_suffix && |
| !has_h_suffix) { |
| // If it only has digits then it's an integer. |
| return {}; |
| } |
| |
| // Note, the `at` method will return a static `0` if the provided position is >= length. We |
| // actually need the end pointer to point to the correct memory location to use `from_chars`. |
| // So, handle the case where we point past the length specially. |
| auto* end_ptr = &at(end); |
| if (end >= length()) { |
| end_ptr = &at(length() - 1) + 1; |
| } |
| |
| auto ret = tint::ParseDouble(std::string_view(&at(start), end - start)); |
| double value = ret ? ret.Get() : 0.0; |
| bool overflow = !ret && ret.Failure() == tint::ParseNumberError::kResultOutOfRange; |
| |
| // If the value didn't fit in a double, check for underflow as that is 0.0 in WGSL and not an |
| // error. |
| if (overflow) { |
| // The exponent is negative, so treat as underflow |
| if (negative_exponent) { |
| overflow = false; |
| value = 0.0; |
| } else if (dot_position.has_value() && first_significant_digit_position.has_value() && |
| first_significant_digit_position.value() > dot_position.value()) { |
| // Parse the exponent from the float if provided |
| size_t exp_value = 0; |
| bool exp_conversion_succeeded = true; |
| if (exponent_value_position.has_value()) { |
| auto exp_end_ptr = end_ptr - (has_f_suffix || has_h_suffix ? 1 : 0); |
| auto exp_ret = std::from_chars(&at(exponent_value_position.value()), exp_end_ptr, |
| exp_value, 10); |
| |
| if (exp_ret.ec != std::errc{}) { |
| exp_conversion_succeeded = false; |
| } |
| } |
| // If the exponent has gone negative, then this is an underflow case |
| if (exp_conversion_succeeded && exp_value < zeros_before_digit) { |
| overflow = false; |
| value = 0.0; |
| } |
| } |
| } |
| |
| advance(end - start); |
| |
| if (has_f_suffix) { |
| auto f = core::CheckedConvert<f32>(AFloat(value)); |
| if (!overflow && f) { |
| advance(1); |
| end_source(source); |
| return Token{Token::Type::kFloatLiteral_F, source, static_cast<double>(f.Get())}; |
| } |
| return Token{Token::Type::kError, source, "value cannot be represented as 'f32'"}; |
| } |
| |
| if (has_h_suffix) { |
| auto f = core::CheckedConvert<f16>(AFloat(value)); |
| if (!overflow && f) { |
| advance(1); |
| end_source(source); |
| return Token{Token::Type::kFloatLiteral_H, source, static_cast<double>(f.Get())}; |
| } |
| return Token{Token::Type::kError, source, "value cannot be represented as 'f16'"}; |
| } |
| |
| end_source(source); |
| |
| TINT_BEGIN_DISABLE_WARNING(FLOAT_EQUAL); |
| if (overflow || value == HUGE_VAL || -value == HUGE_VAL) { |
| return Token{Token::Type::kError, source, |
| "value cannot be represented as 'abstract-float'"}; |
| } else { |
| return Token{Token::Type::kFloatLiteral, source, value}; |
| } |
| TINT_END_DISABLE_WARNING(FLOAT_EQUAL); |
| } |
| |
| std::optional<Token> Lexer::try_hex_float() { |
| constexpr uint64_t kExponentBits = 11; |
| constexpr uint64_t kMantissaBits = 52; |
| constexpr uint64_t kTotalBits = 1 + kExponentBits + kMantissaBits; |
| constexpr uint64_t kTotalMsb = kTotalBits - 1; |
| constexpr uint64_t kMantissaMsb = kMantissaBits - 1; |
| constexpr uint64_t kMantissaShiftRight = kTotalBits - kMantissaBits; |
| constexpr int64_t kExponentBias = 1023; |
| constexpr uint64_t kExponentMask = (1 << kExponentBits) - 1; |
| constexpr int64_t kExponentMax = kExponentMask; // Including NaN / inf |
| constexpr uint64_t kExponentLeftShift = kMantissaBits; |
| constexpr uint64_t kOne = 1; |
| |
| auto start = pos(); |
| auto end = pos(); |
| |
| auto source = begin_source(); |
| |
| // 0[xX]([0-9a-fA-F]*.?[0-9a-fA-F]+ | [0-9a-fA-F]+.[0-9a-fA-F]*)(p|P)(+|-)?[0-9]+ // NOLINT |
| |
| // 0[xX] |
| if (matches(end, '0') && (matches(end + 1, 'x') || matches(end + 1, 'X'))) { |
| end += 2; |
| } else { |
| return {}; |
| } |
| |
| uint64_t mantissa = 0; |
| uint64_t exponent = 0; |
| |
| // TODO(dneto): Values in the normal range for the format do not explicitly |
| // store the most significant bit. The algorithm here works hard to eliminate |
| // that bit in the representation during parsing, and then it backtracks |
| // when it sees it may have to explicitly represent it, and backtracks again |
| // when it sees the number is sub-normal (i.e. the exponent underflows). |
| // I suspect the logic can be clarified by storing it during parsing, and |
| // then removing it later only when needed. |
| |
| // `set_next_mantissa_bit_to` sets next `mantissa` bit starting from msb to |
| // lsb to value 1 if `set` is true, 0 otherwise. Returns true on success, i.e. |
| // when the bit can be accommodated in the available space. |
| uint64_t mantissa_next_bit = kTotalMsb; |
| auto set_next_mantissa_bit_to = [&](bool set, bool integer_part) -> bool { |
| // If adding bits for the integer part, we can overflow whether we set the |
| // bit or not. For the fractional part, we can only overflow when setting |
| // the bit. |
| const bool check_overflow = integer_part || set; |
| // Note: mantissa_next_bit actually decrements, so comparing it as |
| // larger than a positive number relies on wraparound. |
| if (check_overflow && (mantissa_next_bit > kTotalMsb)) { |
| return false; // Overflowed mantissa |
| } |
| if (set) { |
| mantissa |= (kOne << mantissa_next_bit); |
| } |
| --mantissa_next_bit; |
| return true; |
| }; |
| |
| // Collect integer range (if any) |
| auto integer_range = std::make_pair(end, end); |
| while (end < length() && is_hex(at(end))) { |
| integer_range.second = ++end; |
| } |
| |
| // .? |
| bool hex_point = false; |
| if (matches(end, '.')) { |
| hex_point = true; |
| end++; |
| } |
| |
| // Collect fractional range (if any) |
| auto fractional_range = std::make_pair(end, end); |
| while (end < length() && is_hex(at(end))) { |
| fractional_range.second = ++end; |
| } |
| |
| // Must have at least an integer or fractional part |
| if ((integer_range.first == integer_range.second) && |
| (fractional_range.first == fractional_range.second)) { |
| return {}; |
| } |
| |
| // Is the binary exponent present? It's optional. |
| const bool has_exponent = (matches(end, 'p') || matches(end, 'P')); |
| if (has_exponent) { |
| end++; |
| } |
| if (!has_exponent && !hex_point) { |
| // It's not a hex float. At best it's a hex integer. |
| return {}; |
| } |
| |
| // At this point, we know for sure our token is a hex float value, |
| // or an invalid token. |
| |
| // Parse integer part |
| // [0-9a-fA-F]* |
| |
| bool has_zero_integer = true; |
| // The magnitude is zero if and only if seen_prior_one_bits is false. |
| bool seen_prior_one_bits = false; |
| for (auto i = integer_range.first; i < integer_range.second; ++i) { |
| const auto nibble = hex_value(at(i)); |
| if (nibble != 0) { |
| has_zero_integer = false; |
| } |
| |
| for (int bit = 3; bit >= 0; --bit) { |
| auto v = 1 & (nibble >> bit); |
| |
| // Skip leading 0s and the first 1 |
| if (seen_prior_one_bits) { |
| if (!set_next_mantissa_bit_to(v != 0, true)) { |
| return Token{Token::Type::kError, source, |
| "mantissa is too large for hex float"}; |
| } |
| ++exponent; |
| } else { |
| if (v == 1) { |
| seen_prior_one_bits = true; |
| } |
| } |
| } |
| } |
| |
| // Parse fractional part |
| // [0-9a-fA-F]* |
| for (auto i = fractional_range.first; i < fractional_range.second; ++i) { |
| auto nibble = hex_value(at(i)); |
| for (int bit = 3; bit >= 0; --bit) { |
| auto v = 1 & (nibble >> bit); |
| |
| if (v == 1) { |
| seen_prior_one_bits = true; |
| } |
| |
| // If integer part is 0, we only start writing bits to the |
| // mantissa once we have a non-zero fractional bit. While the fractional |
| // values are 0, we adjust the exponent to avoid overflowing `mantissa`. |
| if (!seen_prior_one_bits) { |
| --exponent; |
| } else { |
| if (!set_next_mantissa_bit_to(v != 0, false)) { |
| return Token{Token::Type::kError, source, |
| "mantissa is too large for hex float"}; |
| } |
| } |
| } |
| } |
| |
| // Determine if the value of the mantissa is zero. |
| // Note: it's not enough to check mantissa == 0 as we drop the initial bit, |
| // whether it's in the integer part or the fractional part. |
| const bool is_zero = !seen_prior_one_bits; |
| TINT_ASSERT(!is_zero || mantissa == 0); |
| |
| // Parse the optional exponent. |
| // ((p|P)(\+|-)?[0-9]+)? |
| uint64_t input_exponent = 0; // Defaults to 0 if not present |
| int64_t exponent_sign = 1; |
| // If the 'p' part is present, the rest of the exponent must exist. |
| bool has_f_suffix = false; |
| bool has_h_suffix = false; |
| if (has_exponent) { |
| // Parse the rest of the exponent. |
| // (+|-)? |
| if (matches(end, '+')) { |
| end++; |
| } else if (matches(end, '-')) { |
| exponent_sign = -1; |
| end++; |
| } |
| |
| // Parse exponent from input |
| // [0-9]+ |
| // Allow overflow (in uint64_t) when the floating point value magnitude is |
| // zero. |
| bool has_exponent_digits = false; |
| while (end < length() && isdigit(at(end))) { |
| has_exponent_digits = true; |
| auto prev_exponent = input_exponent; |
| input_exponent = (input_exponent * 10) + dec_value(at(end)); |
| // Check if we've overflowed input_exponent. This only matters when |
| // the mantissa is non-zero. |
| if (!is_zero && (prev_exponent > input_exponent)) { |
| return Token{Token::Type::kError, source, "exponent is too large for hex float"}; |
| } |
| end++; |
| } |
| |
| // Parse optional 'f' or 'h' suffix. For a hex float, it can only exist |
| // when the exponent is present. Otherwise it will look like |
| // one of the mantissa digits. |
| if (end < length() && matches(end, 'f')) { |
| has_f_suffix = true; |
| end++; |
| } else if (end < length() && matches(end, 'h')) { |
| has_h_suffix = true; |
| end++; |
| } |
| |
| if (!has_exponent_digits) { |
| return Token{Token::Type::kError, source, "expected an exponent value for hex float"}; |
| } |
| } |
| |
| advance(end - start); |
| end_source(source); |
| |
| if (is_zero) { |
| // If value is zero, then ignore the exponent and produce a zero |
| exponent = 0; |
| } else { |
| // Ensure input exponent is not too large; i.e. that it won't overflow when |
| // adding the exponent bias. |
| const uint64_t kIntMax = static_cast<uint64_t>(std::numeric_limits<int64_t>::max()); |
| const uint64_t kMaxInputExponent = kIntMax - kExponentBias; |
| if (input_exponent > kMaxInputExponent) { |
| return Token{Token::Type::kError, source, "exponent is too large for hex float"}; |
| } |
| |
| // Compute exponent so far |
| exponent += static_cast<uint64_t>(static_cast<int64_t>(input_exponent) * exponent_sign); |
| |
| // Bias exponent if non-zero |
| // After this, if exponent is <= 0, our value is a denormal |
| exponent += kExponentBias; |
| |
| // We know the number is not zero. The MSB is 1 (by construction), and |
| // should be eliminated because it becomes the implicit 1 that isn't |
| // explicitly represented in the binary32 format. We'll bring it back |
| // later if we find the exponent actually underflowed, i.e. the number |
| // is sub-normal. |
| if (has_zero_integer) { |
| mantissa <<= 1; |
| --exponent; |
| } |
| } |
| |
| // We can now safely work with exponent as a signed quantity, as there's no |
| // chance to overflow |
| int64_t signed_exponent = static_cast<int64_t>(exponent); |
| |
| // Shift mantissa to occupy the low 23 bits |
| mantissa >>= kMantissaShiftRight; |
| |
| // If denormal, shift mantissa until our exponent is zero |
| if (!is_zero) { |
| // Denorm has exponent 0 and non-zero mantissa. We set the top bit here, |
| // then shift the mantissa to make exponent zero. |
| if (signed_exponent <= 0) { |
| mantissa >>= 1; |
| mantissa |= (kOne << kMantissaMsb); |
| } |
| |
| while (signed_exponent < 0) { |
| mantissa >>= 1; |
| ++signed_exponent; |
| |
| // If underflow, clamp to zero |
| if (mantissa == 0) { |
| signed_exponent = 0; |
| } |
| } |
| } |
| |
| if (signed_exponent >= kExponentMax || (signed_exponent == kExponentMax && mantissa != 0)) { |
| std::string type = has_f_suffix ? "f32" : (has_h_suffix ? "f16" : "abstract-float"); |
| return Token{Token::Type::kError, source, "value cannot be represented as '" + type + "'"}; |
| } |
| |
| // Combine sign, mantissa, and exponent |
| uint64_t result_u64 = 0; |
| result_u64 |= mantissa; |
| result_u64 |= (static_cast<uint64_t>(signed_exponent) & kExponentMask) << kExponentLeftShift; |
| |
| // Reinterpret as f16 and return |
| double result_f64; |
| std::memcpy(&result_f64, &result_u64, 8); |
| |
| if (has_f_suffix) { |
| // Check value fits in f32 |
| if (result_f64 < static_cast<double>(f32::kLowestValue) || |
| result_f64 > static_cast<double>(f32::kHighestValue)) { |
| return Token{Token::Type::kError, source, "value cannot be represented as 'f32'"}; |
| } |
| // Check the value can be exactly represented, i.e. only high 23 mantissa bits are valid for |
| // normal f32 values, and less for subnormal f32 values. The rest low mantissa bits must be |
| // 0. |
| int valid_mantissa_bits = 0; |
| double abs_result_f64 = std::fabs(result_f64); |
| if (abs_result_f64 >= static_cast<double>(f32::kSmallestValue)) { |
| // The result shall be a normal f32 value. |
| valid_mantissa_bits = 23; |
| } else if (abs_result_f64 >= static_cast<double>(f32::kSmallestSubnormalValue)) { |
| // The result shall be a subnormal f32 value, represented as double. |
| // The smallest positive normal f32 is f32::kSmallestValue = 2^-126 = 0x1.0p-126, and |
| // the |
| // smallest positive subnormal f32 is f32::kSmallestSubnormalValue = 2^-149. Thus, the |
| // value v in range 2^-126 > v >= 2^-149 must be represented as a subnormal f32 |
| // number, but is still normal double (f64) number, and has a exponent in range -127 |
| // to -149, inclusive. |
| // A value v, if 2^-126 > v >= 2^-127, its binary32 representation will have binary form |
| // s_00000000_1xxxxxxxxxxxxxxxxxxxxxx, having mantissa of 1 leading 1 bit and 22 |
| // arbitrary bits. Since this value is represented as normal double number, the |
| // leading 1 bit is omitted, only the highest 22 mantissia bits can be arbitrary, and |
| // the rest lowest 40 mantissa bits of f64 number must be zero. |
| // 2^-127 > v >= 2^-128, binary32 s_00000000_01xxxxxxxxxxxxxxxxxxxxx, having mantissa of |
| // 1 leading 0 bit, 1 leading 1 bit, and 21 arbitrary bits. The f64 representation |
| // omits the leading 0 and 1 bits, and only the highest 21 mantissia bits can be |
| // arbitrary. |
| // 2^-128 > v >= 2^-129, binary32 s_00000000_001xxxxxxxxxxxxxxxxxxxx, 20 arbitrary bits. |
| // ... |
| // 2^-147 > v >= 2^-148, binary32 s_00000000_0000000000000000000001x, 1 arbitrary bit. |
| // 2^-148 > v >= 2^-149, binary32 s_00000000_00000000000000000000001, 0 arbitrary bit. |
| |
| // signed_exponent must be in range -149 + 1023 = 874 to -127 + 1023 = 896, inclusive |
| TINT_ASSERT((874 <= signed_exponent) && (signed_exponent <= 896)); |
| int unbiased_exponent = |
| static_cast<int>(signed_exponent) - static_cast<int>(kExponentBias); |
| TINT_ASSERT((-149 <= unbiased_exponent) && (unbiased_exponent <= -127)); |
| valid_mantissa_bits = unbiased_exponent + 149; // 0 for -149, and 22 for -127 |
| } else if (abs_result_f64 != 0.0) { |
| // The result is smaller than the smallest subnormal f32 value, but not equal to zero. |
| // Such value will never be exactly represented by f32. |
| return Token{Token::Type::kError, source, |
| "value cannot be exactly represented as 'f32'"}; |
| } |
| // Check the low 52-valid_mantissa_bits mantissa bits must be 0. |
| TINT_ASSERT((0 <= valid_mantissa_bits) && (valid_mantissa_bits <= 23)); |
| if (result_u64 & ((uint64_t(1) << (52 - valid_mantissa_bits)) - 1)) { |
| return Token{Token::Type::kError, source, |
| "value cannot be exactly represented as 'f32'"}; |
| } |
| return Token{Token::Type::kFloatLiteral_F, source, result_f64}; |
| } else if (has_h_suffix) { |
| // Check value fits in f16 |
| if (result_f64 < static_cast<double>(f16::kLowestValue) || |
| result_f64 > static_cast<double>(f16::kHighestValue)) { |
| return Token{Token::Type::kError, source, "value cannot be represented as 'f16'"}; |
| } |
| // Check the value can be exactly represented, i.e. only high 10 mantissa bits are valid for |
| // normal f16 values, and less for subnormal f16 values. The rest low mantissa bits must be |
| // 0. |
| int valid_mantissa_bits = 0; |
| double abs_result_f64 = std::fabs(result_f64); |
| if (abs_result_f64 >= static_cast<double>(f16::kSmallestValue)) { |
| // The result shall be a normal f16 value. |
| valid_mantissa_bits = 10; |
| } else if (abs_result_f64 >= static_cast<double>(f16::kSmallestSubnormalValue)) { |
| // The result shall be a subnormal f16 value, represented as double. |
| // The smallest positive normal f16 is f16::kSmallestValue = 2^-14 = 0x1.0p-14, and the |
| // smallest positive subnormal f16 is f16::kSmallestSubnormalValue = 2^-24. Thus, the |
| // value v in range 2^-14 > v >= 2^-24 must be represented as a subnormal f16 number, |
| // but is still normal double (f64) number, and has a exponent in range -15 to -24, |
| // inclusive. |
| // A value v, if 2^-14 > v >= 2^-15, its binary16 representation will have binary form |
| // s_00000_1xxxxxxxxx, having mantissa of 1 leading 1 bit and 9 arbitrary bits. Since |
| // this value is represented as normal double number, the leading 1 bit is omitted, |
| // only the highest 9 mantissia bits can be arbitrary, and the rest lowest 43 mantissa |
| // bits of f64 number must be zero. |
| // 2^-15 > v >= 2^-16, binary16 s_00000_01xxxxxxxx, having mantissa of 1 leading 0 bit, |
| // 1 leading 1 bit, and 8 arbitrary bits. The f64 representation omits the leading 0 |
| // and 1 bits, and only the highest 8 mantissia bits can be arbitrary. |
| // 2^-16 > v >= 2^-17, binary16 s_00000_001xxxxxxx, 7 arbitrary bits. |
| // ... |
| // 2^-22 > v >= 2^-23, binary16 s_00000_000000001x, 1 arbitrary bits. |
| // 2^-23 > v >= 2^-24, binary16 s_00000_0000000001, 0 arbitrary bits. |
| |
| // signed_exponent must be in range -24 + 1023 = 999 to -15 + 1023 = 1008, inclusive |
| TINT_ASSERT((999 <= signed_exponent) && (signed_exponent <= 1008)); |
| int unbiased_exponent = |
| static_cast<int>(signed_exponent) - static_cast<int>(kExponentBias); |
| TINT_ASSERT((-24 <= unbiased_exponent) && (unbiased_exponent <= -15)); |
| valid_mantissa_bits = unbiased_exponent + 24; // 0 for -24, and 9 for -15 |
| } else if (abs_result_f64 != 0.0) { |
| // The result is smaller than the smallest subnormal f16 value, but not equal to zero. |
| // Such value will never be exactly represented by f16. |
| return Token{Token::Type::kError, source, |
| "value cannot be exactly represented as 'f16'"}; |
| } |
| // Check the low 52-valid_mantissa_bits mantissa bits must be 0. |
| TINT_ASSERT((0 <= valid_mantissa_bits) && (valid_mantissa_bits <= 10)); |
| if (result_u64 & ((uint64_t(1) << (52 - valid_mantissa_bits)) - 1)) { |
| return Token{Token::Type::kError, source, |
| "value cannot be exactly represented as 'f16'"}; |
| } |
| return Token{Token::Type::kFloatLiteral_H, source, result_f64}; |
| } |
| |
| return Token{Token::Type::kFloatLiteral, source, result_f64}; |
| } |
| |
| Token Lexer::build_token_from_int_if_possible(Source source, |
| size_t start, |
| size_t prefix_count, |
| int32_t base) { |
| const char* start_ptr = &at(start); |
| // The call to `from_chars` will return the pointer to just after the last parsed character. |
| // We also need to tell it the maximum end character to parse. So, instead of walking all the |
| // characters to find the last possible and using that, we just provide the end of the string. |
| // We then calculate the count based off the provided end pointer and the start pointer. The |
| // extra `prefix_count` is to handle a `0x` which is not included in the `start` value. |
| const char* end_ptr = &at(length() - 1) + 1; |
| |
| int64_t value = 0; |
| auto res = std::from_chars(start_ptr, end_ptr, value, base); |
| const bool overflow = res.ec != std::errc(); |
| advance(static_cast<size_t>(res.ptr - start_ptr) + prefix_count); |
| |
| if (matches(pos(), 'u')) { |
| if (!overflow && core::CheckedConvert<u32>(AInt(value))) { |
| advance(1); |
| end_source(source); |
| return {Token::Type::kIntLiteral_U, source, value}; |
| } |
| return {Token::Type::kError, source, "value cannot be represented as 'u32'"}; |
| } |
| |
| if (matches(pos(), 'i')) { |
| if (!overflow && core::CheckedConvert<i32>(AInt(value))) { |
| advance(1); |
| end_source(source); |
| return {Token::Type::kIntLiteral_I, source, value}; |
| } |
| return {Token::Type::kError, source, "value cannot be represented as 'i32'"}; |
| } |
| |
| // Check this last in order to get the more specific sized error messages |
| if (overflow) { |
| return {Token::Type::kError, source, "value cannot be represented as 'abstract-int'"}; |
| } |
| |
| end_source(source); |
| return {Token::Type::kIntLiteral, source, value}; |
| } |
| |
| std::optional<Token> Lexer::try_hex_integer() { |
| auto start = pos(); |
| auto curr = start; |
| |
| auto source = begin_source(); |
| |
| if (matches(curr, '0') && (matches(curr + 1, 'x') || matches(curr + 1, 'X'))) { |
| curr += 2; |
| } else { |
| return {}; |
| } |
| |
| if (!is_hex(at(curr))) { |
| return Token{Token::Type::kError, source, |
| "integer or float hex literal has no significant digits"}; |
| } |
| |
| return build_token_from_int_if_possible(source, curr, curr - start, 16); |
| } |
| |
| std::optional<Token> Lexer::try_integer() { |
| auto start = pos(); |
| auto curr = start; |
| |
| auto source = begin_source(); |
| |
| if (curr >= length() || !is_digit(at(curr))) { |
| return {}; |
| } |
| |
| // If the first digit is a zero this must only be zero as leading zeros |
| // are not allowed. |
| if (auto next = curr + 1; next < length()) { |
| if (at(curr) == '0' && is_digit(at(next))) { |
| return Token{Token::Type::kError, source, "integer literal cannot have leading 0s"}; |
| } |
| } |
| |
| return build_token_from_int_if_possible(source, start, 0, 10); |
| } |
| |
| std::optional<Token> Lexer::try_ident() { |
| auto source = begin_source(); |
| auto start = pos(); |
| |
| // Must begin with an XID_Source unicode character, or underscore |
| { |
| auto* utf8 = reinterpret_cast<const uint8_t*>(&at(pos())); |
| auto [code_point, n] = tint::utf8::Decode(utf8, length() - pos()); |
| if (n == 0) { |
| advance(); // Skip the bad byte. |
| return Token{Token::Type::kError, source, "invalid UTF-8"}; |
| } |
| if (code_point != tint::CodePoint('_') && !code_point.IsXIDStart()) { |
| return {}; |
| } |
| // Consume start codepoint |
| advance(n); |
| } |
| |
| while (!is_eol()) { |
| // Must continue with an XID_Continue unicode character |
| auto* utf8 = reinterpret_cast<const uint8_t*>(&at(pos())); |
| auto [code_point, n] = tint::utf8::Decode(utf8, line().size() - pos()); |
| if (n == 0) { |
| advance(); // Skip the bad byte. |
| return Token{Token::Type::kError, source, "invalid UTF-8"}; |
| } |
| if (!code_point.IsXIDContinue()) { |
| break; |
| } |
| |
| // Consume continuing codepoint |
| advance(n); |
| |
| if (pos() - start == 2 && substr(start, 2) == "__") { |
| // Identifiers prefixed with two or more underscores are not allowed. |
| // We check for these in the loop to bail early and prevent quadratic parse time for |
| // long sequences of ____. |
| set_pos(start); |
| return {}; |
| } |
| } |
| |
| auto str = substr(start, pos() - start); |
| end_source(source); |
| |
| if (auto t = parse_keyword(str); t.has_value()) { |
| return Token{t.value(), source, str}; |
| } |
| |
| return Token{Token::Type::kIdentifier, source, str}; |
| } |
| |
| std::optional<Token> Lexer::try_punctuation() { |
| auto source = begin_source(); |
| auto type = Token::Type::kUninitialized; |
| |
| if (matches(pos(), '@')) { |
| type = Token::Type::kAttr; |
| advance(1); |
| } else if (matches(pos(), '(')) { |
| type = Token::Type::kParenLeft; |
| advance(1); |
| } else if (matches(pos(), ')')) { |
| type = Token::Type::kParenRight; |
| advance(1); |
| } else if (matches(pos(), '[')) { |
| type = Token::Type::kBracketLeft; |
| advance(1); |
| } else if (matches(pos(), ']')) { |
| type = Token::Type::kBracketRight; |
| advance(1); |
| } else if (matches(pos(), '{')) { |
| type = Token::Type::kBraceLeft; |
| advance(1); |
| } else if (matches(pos(), '}')) { |
| type = Token::Type::kBraceRight; |
| advance(1); |
| } else if (matches(pos(), '&')) { |
| if (matches(pos() + 1, '&')) { |
| type = Token::Type::kAndAnd; |
| advance(2); |
| } else if (matches(pos() + 1, '=')) { |
| type = Token::Type::kAndEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kAnd; |
| advance(1); |
| } |
| } else if (matches(pos(), '/')) { |
| if (matches(pos() + 1, '=')) { |
| type = Token::Type::kDivisionEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kForwardSlash; |
| advance(1); |
| } |
| } else if (matches(pos(), '!')) { |
| if (matches(pos() + 1, '=')) { |
| type = Token::Type::kNotEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kBang; |
| advance(1); |
| } |
| } else if (matches(pos(), ':')) { |
| type = Token::Type::kColon; |
| advance(1); |
| } else if (matches(pos(), ',')) { |
| type = Token::Type::kComma; |
| advance(1); |
| } else if (matches(pos(), '=')) { |
| if (matches(pos() + 1, '=')) { |
| type = Token::Type::kEqualEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kEqual; |
| advance(1); |
| } |
| } else if (matches(pos(), '>')) { |
| if (matches(pos() + 1, '=')) { |
| type = Token::Type::kGreaterThanEqual; |
| advance(2); |
| } else if (matches(pos() + 1, '>')) { |
| if (matches(pos() + 2, '=')) { |
| type = Token::Type::kShiftRightEqual; |
| advance(3); |
| } else { |
| type = Token::Type::kShiftRight; |
| advance(2); |
| } |
| } else { |
| type = Token::Type::kGreaterThan; |
| advance(1); |
| } |
| } else if (matches(pos(), '<')) { |
| if (matches(pos() + 1, '=')) { |
| type = Token::Type::kLessThanEqual; |
| advance(2); |
| } else if (matches(pos() + 1, '<')) { |
| if (matches(pos() + 2, '=')) { |
| type = Token::Type::kShiftLeftEqual; |
| advance(3); |
| } else { |
| type = Token::Type::kShiftLeft; |
| advance(2); |
| } |
| } else { |
| type = Token::Type::kLessThan; |
| advance(1); |
| } |
| } else if (matches(pos(), '%')) { |
| if (matches(pos() + 1, '=')) { |
| type = Token::Type::kModuloEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kMod; |
| advance(1); |
| } |
| } else if (matches(pos(), '-')) { |
| if (matches(pos() + 1, '>')) { |
| type = Token::Type::kArrow; |
| advance(2); |
| } else if (matches(pos() + 1, '-')) { |
| type = Token::Type::kMinusMinus; |
| advance(2); |
| } else if (matches(pos() + 1, '=')) { |
| type = Token::Type::kMinusEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kMinus; |
| advance(1); |
| } |
| } else if (matches(pos(), '.')) { |
| type = Token::Type::kPeriod; |
| advance(1); |
| } else if (matches(pos(), '+')) { |
| if (matches(pos() + 1, '+')) { |
| type = Token::Type::kPlusPlus; |
| advance(2); |
| } else if (matches(pos() + 1, '=')) { |
| type = Token::Type::kPlusEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kPlus; |
| advance(1); |
| } |
| } else if (matches(pos(), '|')) { |
| if (matches(pos() + 1, '|')) { |
| type = Token::Type::kOrOr; |
| advance(2); |
| } else if (matches(pos() + 1, '=')) { |
| type = Token::Type::kOrEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kOr; |
| advance(1); |
| } |
| } else if (matches(pos(), ';')) { |
| type = Token::Type::kSemicolon; |
| advance(1); |
| } else if (matches(pos(), '*')) { |
| if (matches(pos() + 1, '=')) { |
| type = Token::Type::kTimesEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kStar; |
| advance(1); |
| } |
| } else if (matches(pos(), '~')) { |
| type = Token::Type::kTilde; |
| advance(1); |
| } else if (matches(pos(), '_')) { |
| type = Token::Type::kUnderscore; |
| advance(1); |
| } else if (matches(pos(), '^')) { |
| if (matches(pos() + 1, '=')) { |
| type = Token::Type::kXorEqual; |
| advance(2); |
| } else { |
| type = Token::Type::kXor; |
| advance(1); |
| } |
| } else { |
| return {}; |
| } |
| |
| end_source(source); |
| |
| return Token{type, source}; |
| } |
| |
| std::optional<Token::Type> Lexer::parse_keyword(std::string_view str) { |
| if (str == "alias") { |
| return Token::Type::kAlias; |
| } |
| if (str == "bitcast") { |
| return Token::Type::kBitcast; |
| } |
| if (str == "break") { |
| return Token::Type::kBreak; |
| } |
| if (str == "case") { |
| return Token::Type::kCase; |
| } |
| if (str == "const") { |
| return Token::Type::kConst; |
| } |
| if (str == "const_assert") { |
| return Token::Type::kConstAssert; |
| } |
| if (str == "continue") { |
| return Token::Type::kContinue; |
| } |
| if (str == "continuing") { |
| return Token::Type::kContinuing; |
| } |
| if (str == "diagnostic") { |
| return Token::Type::kDiagnostic; |
| } |
| if (str == "discard") { |
| return Token::Type::kDiscard; |
| } |
| if (str == "default") { |
| return Token::Type::kDefault; |
| } |
| if (str == "else") { |
| return Token::Type::kElse; |
| } |
| if (str == "enable") { |
| return Token::Type::kEnable; |
| } |
| if (str == "fallthrough") { |
| return Token::Type::kFallthrough; |
| } |
| if (str == "false") { |
| return Token::Type::kFalse; |
| } |
| if (str == "fn") { |
| return Token::Type::kFn; |
| } |
| if (str == "for") { |
| return Token::Type::kFor; |
| } |
| if (str == "if") { |
| return Token::Type::kIf; |
| } |
| if (str == "let") { |
| return Token::Type::kLet; |
| } |
| if (str == "loop") { |
| return Token::Type::kLoop; |
| } |
| if (str == "override") { |
| return Token::Type::kOverride; |
| } |
| if (str == "return") { |
| return Token::Type::kReturn; |
| } |
| if (str == "requires") { |
| return Token::Type::kRequires; |
| } |
| if (str == "struct") { |
| return Token::Type::kStruct; |
| } |
| if (str == "switch") { |
| return Token::Type::kSwitch; |
| } |
| if (str == "true") { |
| return Token::Type::kTrue; |
| } |
| if (str == "var") { |
| return Token::Type::kVar; |
| } |
| if (str == "while") { |
| return Token::Type::kWhile; |
| } |
| if (str == "_") { |
| return Token::Type::kUnderscore; |
| } |
| return std::nullopt; |
| } |
| |
| } // namespace tint::wgsl::reader |