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NFC. This just makes sure every file is formatted following the formatting definition in .clang-format. Re-formatted with: $ clang-format -i $(find source tools include -name '*.cpp') $ clang-format -i $(find source tools include -name '*.h')
251 lines
9.6 KiB
C++
251 lines
9.6 KiB
C++
// Copyright (c) 2016 Google Inc.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#ifndef LIBSPIRV_UTIL_PARSE_NUMBER_H_
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#define LIBSPIRV_UTIL_PARSE_NUMBER_H_
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#include <functional>
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#include <string>
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#include <tuple>
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#include "spirv-tools/libspirv.h"
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#include "util/hex_float.h"
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namespace spvutils {
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// A struct to hold the expected type information for the number in text to be
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// parsed.
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struct NumberType {
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uint32_t bitwidth;
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// SPV_NUMBER_NONE means the type is unknown and is invalid to be used with
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// ParseAndEncode{|Integer|Floating}Number().
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spv_number_kind_t kind;
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};
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// Returns true if the type is a scalar integer type.
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inline bool IsIntegral(const NumberType& type) {
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return type.kind == SPV_NUMBER_UNSIGNED_INT ||
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type.kind == SPV_NUMBER_SIGNED_INT;
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}
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// Returns true if the type is a scalar floating point type.
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inline bool IsFloating(const NumberType& type) {
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return type.kind == SPV_NUMBER_FLOATING;
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}
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// Returns true if the type is a signed value.
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inline bool IsSigned(const NumberType& type) {
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return type.kind == SPV_NUMBER_FLOATING || type.kind == SPV_NUMBER_SIGNED_INT;
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}
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// Returns true if the type is unknown.
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inline bool IsUnknown(const NumberType& type) {
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return type.kind == SPV_NUMBER_NONE;
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}
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// Returns the number of bits in the type. This is only valid for integer and
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// floating types.
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inline int AssumedBitWidth(const NumberType& type) {
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switch (type.kind) {
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case SPV_NUMBER_SIGNED_INT:
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case SPV_NUMBER_UNSIGNED_INT:
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case SPV_NUMBER_FLOATING:
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return type.bitwidth;
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default:
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break;
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}
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// We don't care about this case.
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return 0;
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}
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// A templated class with a static member function Clamp, where Clamp sets a
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// referenced value of type T to 0 if T is an unsigned integer type, and
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// returns true if it modified the referenced value.
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template <typename T, typename = void>
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class ClampToZeroIfUnsignedType {
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public:
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// The default specialization does not clamp the value.
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static bool Clamp(T*) { return false; }
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};
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// The specialization of ClampToZeroIfUnsignedType for unsigned integer types.
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template <typename T>
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class ClampToZeroIfUnsignedType<
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T, typename std::enable_if<std::is_unsigned<T>::value>::type> {
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public:
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static bool Clamp(T* value_pointer) {
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if (*value_pointer) {
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*value_pointer = 0;
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return true;
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}
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return false;
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}
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};
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// Returns true if the given value fits within the target scalar integral type.
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// The target type may have an unusual bit width. If the value was originally
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// specified as a hexadecimal number, then the overflow bits should be zero.
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// If it was hex and the target type is signed, then return the sign-extended
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// value through the updated_value_for_hex pointer argument. On failure,
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// returns false.
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template <typename T>
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bool CheckRangeAndIfHexThenSignExtend(T value, const NumberType& type,
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bool is_hex, T* updated_value_for_hex) {
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// The encoded result has three regions of bits that are of interest, from
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// least to most significant:
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// - magnitude bits, where the magnitude of the number would be stored if
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// we were using a signed-magnitude representation.
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// - an optional sign bit
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// - overflow bits, up to bit 63 of a 64-bit number
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// For example:
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// Type Overflow Sign Magnitude
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// --------------- -------- ---- ---------
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// unsigned 8 bit 8-63 n/a 0-7
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// signed 8 bit 8-63 7 0-6
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// unsigned 16 bit 16-63 n/a 0-15
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// signed 16 bit 16-63 15 0-14
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// We'll use masks to define the three regions.
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// At first we'll assume the number is unsigned.
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const uint32_t bit_width = AssumedBitWidth(type);
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uint64_t magnitude_mask =
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(bit_width == 64) ? -1 : ((uint64_t(1) << bit_width) - 1);
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uint64_t sign_mask = 0;
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uint64_t overflow_mask = ~magnitude_mask;
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if (value < 0 || IsSigned(type)) {
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// Accommodate the sign bit.
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magnitude_mask >>= 1;
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sign_mask = magnitude_mask + 1;
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}
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bool failed = false;
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if (value < 0) {
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// The top bits must all be 1 for a negative signed value.
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failed = ((value & overflow_mask) != overflow_mask) ||
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((value & sign_mask) != sign_mask);
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} else {
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if (is_hex) {
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// Hex values are a bit special. They decode as unsigned values, but may
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// represent a negative number. In this case, the overflow bits should
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// be zero.
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failed = (value & overflow_mask) != 0;
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} else {
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const uint64_t value_as_u64 = static_cast<uint64_t>(value);
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// Check overflow in the ordinary case.
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failed = (value_as_u64 & magnitude_mask) != value_as_u64;
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}
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}
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if (failed) {
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return false;
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}
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// Sign extend hex the number.
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if (is_hex && (value & sign_mask))
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*updated_value_for_hex = (value | overflow_mask);
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return true;
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}
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// Parses a numeric value of a given type from the given text. The number
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// should take up the entire string, and should be within bounds for the target
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// type. On success, returns true and populates the object referenced by
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// value_pointer. On failure, returns false.
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template <typename T>
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bool ParseNumber(const char* text, T* value_pointer) {
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// C++11 doesn't define std::istringstream(int8_t&), so calling this method
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// with a single-byte type leads to implementation-defined behaviour.
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// Similarly for uint8_t.
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static_assert(sizeof(T) > 1,
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"Single-byte types are not supported in this parse method");
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if (!text) return false;
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std::istringstream text_stream(text);
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// Allow both decimal and hex input for integers.
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// It also allows octal input, but we don't care about that case.
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text_stream >> std::setbase(0);
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text_stream >> *value_pointer;
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// We should have read something.
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bool ok = (text[0] != 0) && !text_stream.bad();
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// It should have been all the text.
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ok = ok && text_stream.eof();
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// It should have been in range.
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ok = ok && !text_stream.fail();
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// Work around a bug in the GNU C++11 library. It will happily parse
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// "-1" for uint16_t as 65535.
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if (ok && text[0] == '-')
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ok = !ClampToZeroIfUnsignedType<T>::Clamp(value_pointer);
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return ok;
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}
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// Enum to indicate the parsing and encoding status.
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enum class EncodeNumberStatus {
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kSuccess = 0,
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// Unsupported bit width etc.
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kUnsupported,
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// Expected type (NumberType) is not a scalar int or float, or putting a
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// negative number in an unsigned literal.
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kInvalidUsage,
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// Number value does not fit the bit width of the expected type etc.
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kInvalidText,
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};
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// Parses an integer value of a given |type| from the given |text| and encodes
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// the number by the given |emit| function. On success, returns
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// EncodeNumberStatus::kSuccess and the parsed number will be consumed by the
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// given |emit| function word by word (least significant word first). On
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// failure, this function returns the error code of the encoding status and
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// |emit| function will not be called. If the string pointer |error_msg| is not
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// a nullptr, it will be overwritten with error messages in case of failure. In
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// case of success, |error_msg| will not be touched. Integers up to 64 bits are
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// supported.
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EncodeNumberStatus ParseAndEncodeIntegerNumber(
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const char* text, const NumberType& type,
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std::function<void(uint32_t)> emit, std::string* error_msg);
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// Parses a floating point value of a given |type| from the given |text| and
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// encodes the number by the given |emit| funciton. On success, returns
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// EncodeNumberStatus::kSuccess and the parsed number will be consumed by the
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// given |emit| function word by word (least significant word first). On
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// failure, this function returns the error code of the encoding status and
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// |emit| function will not be called. If the string pointer |error_msg| is not
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// a nullptr, it will be overwritten with error messages in case of failure. In
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// case of success, |error_msg| will not be touched. Only 16, 32 and 64 bit
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// floating point numbers are supported.
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EncodeNumberStatus ParseAndEncodeFloatingPointNumber(
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const char* text, const NumberType& type,
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std::function<void(uint32_t)> emit, std::string* error_msg);
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// Parses an integer or floating point number of a given |type| from the given
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// |text| and encodes the number by the given |emit| function. On success,
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// returns EncodeNumberStatus::kSuccess and the parsed number will be consumed
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// by the given |emit| function word by word (least significant word first). On
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// failure, this function returns the error code of the encoding status and
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// |emit| function will not be called. If the string pointer |error_msg| is not
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// a nullptr, it will be overwritten with error messages in case of failure. In
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// case of success, |error_msg| will not be touched. Integers up to 64 bits
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// and 16/32/64 bit floating point values are supported.
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EncodeNumberStatus ParseAndEncodeNumber(const char* text,
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const NumberType& type,
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std::function<void(uint32_t)> emit,
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std::string* error_msg);
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} // namespace spvutils
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#endif // LIBSPIRV_UTIL_PARSE_NUMBER_H_
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