source/assembly_grammar.cpp - external/github.com/KhronosGroup/SPIRV-Tools - Git at Google

 // Copyright (c) 2015-2016 The Khronos Group Inc.
 //
 // 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 "source/assembly_grammar.h"

 #include <algorithm>
 #include <cassert>
 #include <cstring>

 #include "source/ext_inst.h"
 #include "source/opcode.h"
 #include "source/operand.h"
 #include "source/table.h"

 namespace spvtools {
 namespace {

 /// @brief Parses a mask expression string for the given operand type.
 ///
 /// A mask expression is a sequence of one or more terms separated by '|',
 /// where each term a named enum value for the given type.  No whitespace
 /// is permitted.
 ///
 /// On success, the value is written to pValue.
 ///
 /// @param[in] operandTable operand lookup table
 /// @param[in] type of the operand
 /// @param[in] textValue word of text to be parsed
 /// @param[out] pValue where the resulting value is written
 ///
 /// @return result code
 spv_result_t spvTextParseMaskOperand(spv_target_env env,
                                      const spv_operand_table operandTable,
                                      const spv_operand_type_t type,
                                      const char* textValue, uint32_t* pValue) {
   if (textValue == nullptr) return SPV_ERROR_INVALID_TEXT;
   size_t text_length = strlen(textValue);
   if (text_length == 0) return SPV_ERROR_INVALID_TEXT;
   const char* text_end = textValue + text_length;

   // We only support mask expressions in ASCII, so the separator value is a
   // char.
   const char separator = '|';

   // Accumulate the result by interpreting one word at a time, scanning
   // from left to right.
   uint32_t value = 0;
   const char* begin = textValue;  // The left end of the current word.
   const char* end = nullptr;  // One character past the end of the current word.
   do {
     end = std::find(begin, text_end, separator);

     spv_operand_desc entry = nullptr;
     if (spvOperandTableNameLookup(env, operandTable, type, begin, end - begin,
                                   &entry)) {
       return SPV_ERROR_INVALID_TEXT;
     }
     value |= entry->value;

     // Advance to the next word by skipping over the separator.
     begin = end + 1;
   } while (end != text_end);

   *pValue = value;
   return SPV_SUCCESS;
 }

 // Associates an opcode with its name.
 struct SpecConstantOpcodeEntry {
   SpvOp opcode;
   const char* name;
 };

 // All the opcodes allowed as the operation for OpSpecConstantOp.
 // The name does not have the usual "Op" prefix. For example opcode SpvOpIAdd
 // is associated with the name "IAdd".
 //
 // clang-format off
 #define CASE(NAME) { SpvOp##NAME, #NAME }
 const SpecConstantOpcodeEntry kOpSpecConstantOpcodes[] = {
     // Conversion
     CASE(SConvert),
     CASE(FConvert),
     CASE(ConvertFToS),
     CASE(ConvertSToF),
     CASE(ConvertFToU),
     CASE(ConvertUToF),
     CASE(UConvert),
     CASE(ConvertPtrToU),
     CASE(ConvertUToPtr),
     CASE(GenericCastToPtr),
     CASE(PtrCastToGeneric),
     CASE(Bitcast),
     CASE(QuantizeToF16),
     // Arithmetic
     CASE(SNegate),
     CASE(Not),
     CASE(IAdd),
     CASE(ISub),
     CASE(IMul),
     CASE(UDiv),
     CASE(SDiv),
     CASE(UMod),
     CASE(SRem),
     CASE(SMod),
     CASE(ShiftRightLogical),
     CASE(ShiftRightArithmetic),
     CASE(ShiftLeftLogical),
     CASE(BitwiseOr),
     CASE(BitwiseAnd),
     CASE(BitwiseXor),
     CASE(FNegate),
     CASE(FAdd),
     CASE(FSub),
     CASE(FMul),
     CASE(FDiv),
     CASE(FRem),
     CASE(FMod),
     // Composite
     CASE(VectorShuffle),
     CASE(CompositeExtract),
     CASE(CompositeInsert),
     // Logical
     CASE(LogicalOr),
     CASE(LogicalAnd),
     CASE(LogicalNot),
     CASE(LogicalEqual),
     CASE(LogicalNotEqual),
     CASE(Select),
     // Comparison
     CASE(IEqual),
     CASE(INotEqual),
     CASE(ULessThan),
     CASE(SLessThan),
     CASE(UGreaterThan),
     CASE(SGreaterThan),
     CASE(ULessThanEqual),
     CASE(SLessThanEqual),
     CASE(UGreaterThanEqual),
     CASE(SGreaterThanEqual),
     // Memory
     CASE(AccessChain),
     CASE(InBoundsAccessChain),
     CASE(PtrAccessChain),
     CASE(InBoundsPtrAccessChain),
     CASE(CooperativeMatrixLengthNV)
 };

 // The 60 is determined by counting the opcodes listed in the spec.
 static_assert(60 == sizeof(kOpSpecConstantOpcodes)/sizeof(kOpSpecConstantOpcodes[0]),
               "OpSpecConstantOp opcode table is incomplete");
 #undef CASE
 // clang-format on

 const size_t kNumOpSpecConstantOpcodes =
     sizeof(kOpSpecConstantOpcodes) / sizeof(kOpSpecConstantOpcodes[0]);

 }  // namespace

 bool AssemblyGrammar::isValid() const {
   return operandTable_ && opcodeTable_ && extInstTable_;
 }

 CapabilitySet AssemblyGrammar::filterCapsAgainstTargetEnv(
     const SpvCapability* cap_array, uint32_t count) const {
   CapabilitySet cap_set;
   for (uint32_t i = 0; i < count; ++i) {
     spv_operand_desc cap_desc = {};
     if (SPV_SUCCESS == lookupOperand(SPV_OPERAND_TYPE_CAPABILITY,
                                      static_cast<uint32_t>(cap_array[i]),
                                      &cap_desc)) {
       // spvOperandTableValueLookup() filters capabilities internally
       // according to the current target environment by itself. So we
       // should be safe to add this capability if the lookup succeeds.
       cap_set.Add(cap_array[i]);
     }
   }
   return cap_set;
 }

 spv_result_t AssemblyGrammar::lookupOpcode(const char* name,
                                            spv_opcode_desc* desc) const {
   return spvOpcodeTableNameLookup(target_env_, opcodeTable_, name, desc);
 }

 spv_result_t AssemblyGrammar::lookupOpcode(SpvOp opcode,
                                            spv_opcode_desc* desc) const {
   return spvOpcodeTableValueLookup(target_env_, opcodeTable_, opcode, desc);
 }

 spv_result_t AssemblyGrammar::lookupOperand(spv_operand_type_t type,
                                             const char* name, size_t name_len,
                                             spv_operand_desc* desc) const {
   return spvOperandTableNameLookup(target_env_, operandTable_, type, name,
                                    name_len, desc);
 }

 spv_result_t AssemblyGrammar::lookupOperand(spv_operand_type_t type,
                                             uint32_t operand,
                                             spv_operand_desc* desc) const {
   return spvOperandTableValueLookup(target_env_, operandTable_, type, operand,
                                     desc);
 }

 spv_result_t AssemblyGrammar::lookupSpecConstantOpcode(const char* name,
                                                        SpvOp* opcode) const {
   const auto* last = kOpSpecConstantOpcodes + kNumOpSpecConstantOpcodes;
   const auto* found =
       std::find_if(kOpSpecConstantOpcodes, last,
                    [name](const SpecConstantOpcodeEntry& entry) {
                      return 0 == strcmp(name, entry.name);
                    });
   if (found == last) return SPV_ERROR_INVALID_LOOKUP;
   *opcode = found->opcode;
   return SPV_SUCCESS;
 }

 spv_result_t AssemblyGrammar::lookupSpecConstantOpcode(SpvOp opcode) const {
   const auto* last = kOpSpecConstantOpcodes + kNumOpSpecConstantOpcodes;
   const auto* found =
       std::find_if(kOpSpecConstantOpcodes, last,
                    [opcode](const SpecConstantOpcodeEntry& entry) {
                      return opcode == entry.opcode;
                    });
   if (found == last) return SPV_ERROR_INVALID_LOOKUP;
   return SPV_SUCCESS;
 }

 spv_result_t AssemblyGrammar::parseMaskOperand(const spv_operand_type_t type,
                                                const char* textValue,
                                                uint32_t* pValue) const {
   return spvTextParseMaskOperand(target_env_, operandTable_, type, textValue,
                                  pValue);
 }
 spv_result_t AssemblyGrammar::lookupExtInst(spv_ext_inst_type_t type,
                                             const char* textValue,
                                             spv_ext_inst_desc* extInst) const {
   return spvExtInstTableNameLookup(extInstTable_, type, textValue, extInst);
 }

 spv_result_t AssemblyGrammar::lookupExtInst(spv_ext_inst_type_t type,
                                             uint32_t firstWord,
                                             spv_ext_inst_desc* extInst) const {
   return spvExtInstTableValueLookup(extInstTable_, type, firstWord, extInst);
 }

 void AssemblyGrammar::pushOperandTypesForMask(
     const spv_operand_type_t type, const uint32_t mask,
     spv_operand_pattern_t* pattern) const {
   spvPushOperandTypesForMask(target_env_, operandTable_, type, mask, pattern);
 }

 }  // namespace spvtools
	// Copyright (c) 2015-2016 The Khronos Group Inc.
	//
	// 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 "source/assembly_grammar.h"

	#include <algorithm>
	#include <cassert>
	#include <cstring>

	#include "source/ext_inst.h"
	#include "source/opcode.h"
	#include "source/operand.h"
	#include "source/table.h"

	namespace spvtools {
	namespace {

	/// @brief Parses a mask expression string for the given operand type.
	///
	/// A mask expression is a sequence of one or more terms separated by '\|',
	/// where each term a named enum value for the given type. No whitespace
	/// is permitted.
	///
	/// On success, the value is written to pValue.
	///
	/// @param[in] operandTable operand lookup table
	/// @param[in] type of the operand
	/// @param[in] textValue word of text to be parsed
	/// @param[out] pValue where the resulting value is written
	///
	/// @return result code
	spv_result_t spvTextParseMaskOperand(spv_target_env env,
	const spv_operand_table operandTable,
	const spv_operand_type_t type,
	const char* textValue, uint32_t* pValue) {
	if (textValue == nullptr) return SPV_ERROR_INVALID_TEXT;
	size_t text_length = strlen(textValue);
	if (text_length == 0) return SPV_ERROR_INVALID_TEXT;
	const char* text_end = textValue + text_length;

	// We only support mask expressions in ASCII, so the separator value is a
	// char.
	const char separator = '\|';

	// Accumulate the result by interpreting one word at a time, scanning
	// from left to right.
	uint32_t value = 0;
	const char* begin = textValue; // The left end of the current word.
	const char* end = nullptr; // One character past the end of the current word.
	do {
	end = std::find(begin, text_end, separator);

	spv_operand_desc entry = nullptr;
	if (spvOperandTableNameLookup(env, operandTable, type, begin, end - begin,
	&entry)) {
	return SPV_ERROR_INVALID_TEXT;
	}
	value \|= entry->value;

	// Advance to the next word by skipping over the separator.
	begin = end + 1;
	} while (end != text_end);

	*pValue = value;
	return SPV_SUCCESS;
	}

	// Associates an opcode with its name.
	struct SpecConstantOpcodeEntry {
	SpvOp opcode;
	const char* name;
	};

	// All the opcodes allowed as the operation for OpSpecConstantOp.
	// The name does not have the usual "Op" prefix. For example opcode SpvOpIAdd
	// is associated with the name "IAdd".
	//
	// clang-format off
	#define CASE(NAME) { SpvOp##NAME, #NAME }
	const SpecConstantOpcodeEntry kOpSpecConstantOpcodes[] = {
	// Conversion
	CASE(SConvert),
	CASE(FConvert),
	CASE(ConvertFToS),
	CASE(ConvertSToF),
	CASE(ConvertFToU),
	CASE(ConvertUToF),
	CASE(UConvert),
	CASE(ConvertPtrToU),
	CASE(ConvertUToPtr),
	CASE(GenericCastToPtr),
	CASE(PtrCastToGeneric),
	CASE(Bitcast),
	CASE(QuantizeToF16),
	// Arithmetic
	CASE(SNegate),
	CASE(Not),
	CASE(IAdd),
	CASE(ISub),
	CASE(IMul),
	CASE(UDiv),
	CASE(SDiv),
	CASE(UMod),
	CASE(SRem),
	CASE(SMod),
	CASE(ShiftRightLogical),
	CASE(ShiftRightArithmetic),
	CASE(ShiftLeftLogical),
	CASE(BitwiseOr),
	CASE(BitwiseAnd),
	CASE(BitwiseXor),
	CASE(FNegate),
	CASE(FAdd),
	CASE(FSub),
	CASE(FMul),
	CASE(FDiv),
	CASE(FRem),
	CASE(FMod),
	// Composite
	CASE(VectorShuffle),
	CASE(CompositeExtract),
	CASE(CompositeInsert),
	// Logical
	CASE(LogicalOr),
	CASE(LogicalAnd),
	CASE(LogicalNot),
	CASE(LogicalEqual),
	CASE(LogicalNotEqual),
	CASE(Select),
	// Comparison
	CASE(IEqual),
	CASE(INotEqual),
	CASE(ULessThan),
	CASE(SLessThan),
	CASE(UGreaterThan),
	CASE(SGreaterThan),
	CASE(ULessThanEqual),
	CASE(SLessThanEqual),
	CASE(UGreaterThanEqual),
	CASE(SGreaterThanEqual),
	// Memory
	CASE(AccessChain),
	CASE(InBoundsAccessChain),
	CASE(PtrAccessChain),
	CASE(InBoundsPtrAccessChain),
	CASE(CooperativeMatrixLengthNV)
	};

	// The 60 is determined by counting the opcodes listed in the spec.
	static_assert(60 == sizeof(kOpSpecConstantOpcodes)/sizeof(kOpSpecConstantOpcodes[0]),
	"OpSpecConstantOp opcode table is incomplete");
	#undef CASE
	// clang-format on

	const size_t kNumOpSpecConstantOpcodes =
	sizeof(kOpSpecConstantOpcodes) / sizeof(kOpSpecConstantOpcodes[0]);

	} // namespace

	bool AssemblyGrammar::isValid() const {
	return operandTable_ && opcodeTable_ && extInstTable_;
	}

	CapabilitySet AssemblyGrammar::filterCapsAgainstTargetEnv(
	const SpvCapability* cap_array, uint32_t count) const {
	CapabilitySet cap_set;
	for (uint32_t i = 0; i < count; ++i) {
	spv_operand_desc cap_desc = {};
	if (SPV_SUCCESS == lookupOperand(SPV_OPERAND_TYPE_CAPABILITY,
	static_cast<uint32_t>(cap_array[i]),
	&cap_desc)) {
	// spvOperandTableValueLookup() filters capabilities internally
	// according to the current target environment by itself. So we
	// should be safe to add this capability if the lookup succeeds.
	cap_set.Add(cap_array[i]);
	}
	}
	return cap_set;
	}

	spv_result_t AssemblyGrammar::lookupOpcode(const char* name,
	spv_opcode_desc* desc) const {
	return spvOpcodeTableNameLookup(target_env_, opcodeTable_, name, desc);
	}

	spv_result_t AssemblyGrammar::lookupOpcode(SpvOp opcode,
	spv_opcode_desc* desc) const {
	return spvOpcodeTableValueLookup(target_env_, opcodeTable_, opcode, desc);
	}

	spv_result_t AssemblyGrammar::lookupOperand(spv_operand_type_t type,
	const char* name, size_t name_len,
	spv_operand_desc* desc) const {
	return spvOperandTableNameLookup(target_env_, operandTable_, type, name,
	name_len, desc);
	}

	spv_result_t AssemblyGrammar::lookupOperand(spv_operand_type_t type,
	uint32_t operand,
	spv_operand_desc* desc) const {
	return spvOperandTableValueLookup(target_env_, operandTable_, type, operand,
	desc);
	}

	spv_result_t AssemblyGrammar::lookupSpecConstantOpcode(const char* name,
	SpvOp* opcode) const {
	const auto* last = kOpSpecConstantOpcodes + kNumOpSpecConstantOpcodes;
	const auto* found =
	std::find_if(kOpSpecConstantOpcodes, last,
	[name](const SpecConstantOpcodeEntry& entry) {
	return 0 == strcmp(name, entry.name);
	});
	if (found == last) return SPV_ERROR_INVALID_LOOKUP;
	*opcode = found->opcode;
	return SPV_SUCCESS;
	}

	spv_result_t AssemblyGrammar::lookupSpecConstantOpcode(SpvOp opcode) const {
	const auto* last = kOpSpecConstantOpcodes + kNumOpSpecConstantOpcodes;
	const auto* found =
	std::find_if(kOpSpecConstantOpcodes, last,
	[opcode](const SpecConstantOpcodeEntry& entry) {
	return opcode == entry.opcode;
	});
	if (found == last) return SPV_ERROR_INVALID_LOOKUP;
	return SPV_SUCCESS;
	}

	spv_result_t AssemblyGrammar::parseMaskOperand(const spv_operand_type_t type,
	const char* textValue,
	uint32_t* pValue) const {
	return spvTextParseMaskOperand(target_env_, operandTable_, type, textValue,
	pValue);
	}
	spv_result_t AssemblyGrammar::lookupExtInst(spv_ext_inst_type_t type,
	const char* textValue,
	spv_ext_inst_desc* extInst) const {
	return spvExtInstTableNameLookup(extInstTable_, type, textValue, extInst);
	}

	spv_result_t AssemblyGrammar::lookupExtInst(spv_ext_inst_type_t type,
	uint32_t firstWord,
	spv_ext_inst_desc* extInst) const {
	return spvExtInstTableValueLookup(extInstTable_, type, firstWord, extInst);
	}

	void AssemblyGrammar::pushOperandTypesForMask(
	const spv_operand_type_t type, const uint32_t mask,
	spv_operand_pattern_t* pattern) const {
	spvPushOperandTypesForMask(target_env_, operandTable_, type, mask, pattern);
	}

	} // namespace spvtools