third_party/SPIRV-Tools/source/opt/module.cpp - SwiftShader - Git at Google

 // Copyright (c) 2016 Google 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/opt/module.h"

 #include <algorithm>
 #include <cstring>
 #include <ostream>

 #include "source/operand.h"
 #include "source/opt/ir_context.h"
 #include "source/opt/reflect.h"

 namespace spvtools {
 namespace opt {

 uint32_t Module::TakeNextIdBound() {
   if (context()) {
     if (id_bound() >= context()->max_id_bound()) {
       return 0;
     }
   } else if (id_bound() >= kDefaultMaxIdBound) {
     return 0;
   }

   return header_.bound++;
 }

 std::vector<Instruction*> Module::GetTypes() {
   std::vector<Instruction*> type_insts;
   for (auto& inst : types_values_) {
     if (IsTypeInst(inst.opcode())) type_insts.push_back(&inst);
   }
   return type_insts;
 }

 std::vector<const Instruction*> Module::GetTypes() const {
   std::vector<const Instruction*> type_insts;
   for (auto& inst : types_values_) {
     if (IsTypeInst(inst.opcode())) type_insts.push_back(&inst);
   }
   return type_insts;
 }

 std::vector<Instruction*> Module::GetConstants() {
   std::vector<Instruction*> const_insts;
   for (auto& inst : types_values_) {
     if (IsConstantInst(inst.opcode())) const_insts.push_back(&inst);
   }
   return const_insts;
 }

 std::vector<const Instruction*> Module::GetConstants() const {
   std::vector<const Instruction*> const_insts;
   for (auto& inst : types_values_) {
     if (IsConstantInst(inst.opcode())) const_insts.push_back(&inst);
   }
   return const_insts;
 }

 uint32_t Module::GetGlobalValue(SpvOp opcode) const {
   for (auto& inst : types_values_) {
     if (inst.opcode() == opcode) return inst.result_id();
   }
   return 0;
 }

 void Module::AddGlobalValue(SpvOp opcode, uint32_t result_id,
                             uint32_t type_id) {
   std::unique_ptr<Instruction> newGlobal(
       new Instruction(context(), opcode, type_id, result_id, {}));
   AddGlobalValue(std::move(newGlobal));
 }

 void Module::ForEachInst(const std::function<void(Instruction*)>& f,
                          bool run_on_debug_line_insts) {
 #define DELEGATE(list) list.ForEachInst(f, run_on_debug_line_insts)
   DELEGATE(capabilities_);
   DELEGATE(extensions_);
   DELEGATE(ext_inst_imports_);
   if (memory_model_) memory_model_->ForEachInst(f, run_on_debug_line_insts);
   DELEGATE(entry_points_);
   DELEGATE(execution_modes_);
   DELEGATE(debugs1_);
   DELEGATE(debugs2_);
   DELEGATE(debugs3_);
   DELEGATE(ext_inst_debuginfo_);
   DELEGATE(annotations_);
   DELEGATE(types_values_);
   for (auto& i : functions_) {
     i->ForEachInst(f, run_on_debug_line_insts,
                    /* run_on_non_semantic_insts = */ true);
   }
 #undef DELEGATE
 }

 void Module::ForEachInst(const std::function<void(const Instruction*)>& f,
                          bool run_on_debug_line_insts) const {
 #define DELEGATE(i) i.ForEachInst(f, run_on_debug_line_insts)
   for (auto& i : capabilities_) DELEGATE(i);
   for (auto& i : extensions_) DELEGATE(i);
   for (auto& i : ext_inst_imports_) DELEGATE(i);
   if (memory_model_)
     static_cast<const Instruction*>(memory_model_.get())
         ->ForEachInst(f, run_on_debug_line_insts);
   for (auto& i : entry_points_) DELEGATE(i);
   for (auto& i : execution_modes_) DELEGATE(i);
   for (auto& i : debugs1_) DELEGATE(i);
   for (auto& i : debugs2_) DELEGATE(i);
   for (auto& i : debugs3_) DELEGATE(i);
   for (auto& i : annotations_) DELEGATE(i);
   for (auto& i : types_values_) DELEGATE(i);
   for (auto& i : ext_inst_debuginfo_) DELEGATE(i);
   for (auto& i : functions_) {
     static_cast<const Function*>(i.get())->ForEachInst(
         f, run_on_debug_line_insts,
         /* run_on_non_semantic_insts = */ true);
   }
   if (run_on_debug_line_insts) {
     for (auto& i : trailing_dbg_line_info_) DELEGATE(i);
   }
 #undef DELEGATE
 }

 void Module::ToBinary(std::vector<uint32_t>* binary, bool skip_nop) const {
   binary->push_back(header_.magic_number);
   binary->push_back(header_.version);
   // TODO(antiagainst): should we change the generator number?
   binary->push_back(header_.generator);
   binary->push_back(header_.bound);
   binary->push_back(header_.reserved);

   size_t bound_idx = binary->size() - 2;
   DebugScope last_scope(kNoDebugScope, kNoInlinedAt);
   const Instruction* last_line_inst = nullptr;
   bool between_merge_and_branch = false;
   auto write_inst = [binary, skip_nop, &last_scope, &last_line_inst,
                      &between_merge_and_branch, this](const Instruction* i) {
     // Skip emitting line instructions between merge and branch instructions.
     auto opcode = i->opcode();
     if (between_merge_and_branch &&
         (opcode == SpvOpLine || opcode == SpvOpNoLine)) {
       return;
     }
     between_merge_and_branch = false;
     if (last_line_inst != nullptr) {
       // If the current instruction is OpLine and it is the same with
       // the last line instruction that is still effective (can be applied
       // to the next instruction), we skip writing the current instruction.
       if (opcode == SpvOpLine) {
         uint32_t operand_index = 0;
         if (last_line_inst->WhileEachInOperand(
                 [&operand_index, i](const uint32_t* word) {
                   assert(i->NumInOperandWords() > operand_index);
                   return *word == i->GetSingleWordInOperand(operand_index++);
                 })) {
           return;
         }
       } else if (opcode != SpvOpNoLine && i->dbg_line_insts().empty()) {
         // If the current instruction does not have the line information,
         // the last line information is not effective any more. Emit OpNoLine
         // to specify it.
         binary->push_back((1 << 16) | static_cast<uint16_t>(SpvOpNoLine));
         last_line_inst = nullptr;
       }
     }
     if (!(skip_nop && i->IsNop())) {
       const auto& scope = i->GetDebugScope();
       if (scope != last_scope) {
         // Emit DebugScope |scope| to |binary|.
         auto dbg_inst = ext_inst_debuginfo_.begin();
         scope.ToBinary(dbg_inst->type_id(), context()->TakeNextId(),
                        dbg_inst->GetSingleWordOperand(2), binary);
         last_scope = scope;
       }

       i->ToBinaryWithoutAttachedDebugInsts(binary);
     }
     // Update the last line instruction.
     if (IsTerminatorInst(opcode) || opcode == SpvOpNoLine) {
       last_line_inst = nullptr;
     } else if (opcode == SpvOpLoopMerge || opcode == SpvOpSelectionMerge) {
       between_merge_and_branch = true;
       last_line_inst = nullptr;
     } else if (opcode == SpvOpLine) {
       last_line_inst = i;
     }
   };
   ForEachInst(write_inst, true);

   // We create new instructions for DebugScope. The bound must be updated.
   binary->data()[bound_idx] = header_.bound;
 }

 uint32_t Module::ComputeIdBound() const {
   uint32_t highest = 0;

   ForEachInst(
       [&highest](const Instruction* inst) {
         for (const auto& operand : *inst) {
           if (spvIsIdType(operand.type)) {
             highest = std::max(highest, operand.words[0]);
           }
         }
       },
       true /* scan debug line insts as well */);

   return highest + 1;
 }

 bool Module::HasExplicitCapability(uint32_t cap) {
   for (auto& ci : capabilities_) {
     uint32_t tcap = ci.GetSingleWordOperand(0);
     if (tcap == cap) {
       return true;
     }
   }
   return false;
 }

 uint32_t Module::GetExtInstImportId(const char* extstr) {
   for (auto& ei : ext_inst_imports_)
     if (!strcmp(extstr,
                 reinterpret_cast<const char*>(&(ei.GetInOperand(0).words[0]))))
       return ei.result_id();
   return 0;
 }

 std::ostream& operator<<(std::ostream& str, const Module& module) {
   module.ForEachInst([&str](const Instruction* inst) {
     str << *inst;
     if (inst->opcode() != SpvOpFunctionEnd) {
       str << std::endl;
     }
   });
   return str;
 }

 }  // namespace opt
 }  // namespace spvtools
	// Copyright (c) 2016 Google 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/opt/module.h"

	#include <algorithm>
	#include <cstring>
	#include <ostream>

	#include "source/operand.h"
	#include "source/opt/ir_context.h"
	#include "source/opt/reflect.h"

	namespace spvtools {
	namespace opt {

	uint32_t Module::TakeNextIdBound() {
	if (context()) {
	if (id_bound() >= context()->max_id_bound()) {
	return 0;
	}
	} else if (id_bound() >= kDefaultMaxIdBound) {
	return 0;
	}

	return header_.bound++;
	}

	std::vector<Instruction*> Module::GetTypes() {
	std::vector<Instruction*> type_insts;
	for (auto& inst : types_values_) {
	if (IsTypeInst(inst.opcode())) type_insts.push_back(&inst);
	}
	return type_insts;
	}

	std::vector<const Instruction*> Module::GetTypes() const {
	std::vector<const Instruction*> type_insts;
	for (auto& inst : types_values_) {
	if (IsTypeInst(inst.opcode())) type_insts.push_back(&inst);
	}
	return type_insts;
	}

	std::vector<Instruction*> Module::GetConstants() {
	std::vector<Instruction*> const_insts;
	for (auto& inst : types_values_) {
	if (IsConstantInst(inst.opcode())) const_insts.push_back(&inst);
	}
	return const_insts;
	}

	std::vector<const Instruction*> Module::GetConstants() const {
	std::vector<const Instruction*> const_insts;
	for (auto& inst : types_values_) {
	if (IsConstantInst(inst.opcode())) const_insts.push_back(&inst);
	}
	return const_insts;
	}

	uint32_t Module::GetGlobalValue(SpvOp opcode) const {
	for (auto& inst : types_values_) {
	if (inst.opcode() == opcode) return inst.result_id();
	}
	return 0;
	}

	void Module::AddGlobalValue(SpvOp opcode, uint32_t result_id,
	uint32_t type_id) {
	std::unique_ptr<Instruction> newGlobal(
	new Instruction(context(), opcode, type_id, result_id, {}));
	AddGlobalValue(std::move(newGlobal));
	}

	void Module::ForEachInst(const std::function<void(Instruction*)>& f,
	bool run_on_debug_line_insts) {
	#define DELEGATE(list) list.ForEachInst(f, run_on_debug_line_insts)
	DELEGATE(capabilities_);
	DELEGATE(extensions_);
	DELEGATE(ext_inst_imports_);
	if (memory_model_) memory_model_->ForEachInst(f, run_on_debug_line_insts);
	DELEGATE(entry_points_);
	DELEGATE(execution_modes_);
	DELEGATE(debugs1_);
	DELEGATE(debugs2_);
	DELEGATE(debugs3_);
	DELEGATE(ext_inst_debuginfo_);
	DELEGATE(annotations_);
	DELEGATE(types_values_);
	for (auto& i : functions_) {
	i->ForEachInst(f, run_on_debug_line_insts,
	/* run_on_non_semantic_insts = */ true);
	}
	#undef DELEGATE
	}

	void Module::ForEachInst(const std::function<void(const Instruction*)>& f,
	bool run_on_debug_line_insts) const {
	#define DELEGATE(i) i.ForEachInst(f, run_on_debug_line_insts)
	for (auto& i : capabilities_) DELEGATE(i);
	for (auto& i : extensions_) DELEGATE(i);
	for (auto& i : ext_inst_imports_) DELEGATE(i);
	if (memory_model_)
	static_cast<const Instruction*>(memory_model_.get())
	->ForEachInst(f, run_on_debug_line_insts);
	for (auto& i : entry_points_) DELEGATE(i);
	for (auto& i : execution_modes_) DELEGATE(i);
	for (auto& i : debugs1_) DELEGATE(i);
	for (auto& i : debugs2_) DELEGATE(i);
	for (auto& i : debugs3_) DELEGATE(i);
	for (auto& i : annotations_) DELEGATE(i);
	for (auto& i : types_values_) DELEGATE(i);
	for (auto& i : ext_inst_debuginfo_) DELEGATE(i);
	for (auto& i : functions_) {
	static_cast<const Function*>(i.get())->ForEachInst(
	f, run_on_debug_line_insts,
	/* run_on_non_semantic_insts = */ true);
	}
	if (run_on_debug_line_insts) {
	for (auto& i : trailing_dbg_line_info_) DELEGATE(i);
	}
	#undef DELEGATE
	}

	void Module::ToBinary(std::vector<uint32_t>* binary, bool skip_nop) const {
	binary->push_back(header_.magic_number);
	binary->push_back(header_.version);
	// TODO(antiagainst): should we change the generator number?
	binary->push_back(header_.generator);
	binary->push_back(header_.bound);
	binary->push_back(header_.reserved);

	size_t bound_idx = binary->size() - 2;
	DebugScope last_scope(kNoDebugScope, kNoInlinedAt);
	const Instruction* last_line_inst = nullptr;
	bool between_merge_and_branch = false;
	auto write_inst = [binary, skip_nop, &last_scope, &last_line_inst,
	&between_merge_and_branch, this](const Instruction* i) {
	// Skip emitting line instructions between merge and branch instructions.
	auto opcode = i->opcode();
	if (between_merge_and_branch &&
	(opcode == SpvOpLine \|\| opcode == SpvOpNoLine)) {
	return;
	}
	between_merge_and_branch = false;
	if (last_line_inst != nullptr) {
	// If the current instruction is OpLine and it is the same with
	// the last line instruction that is still effective (can be applied
	// to the next instruction), we skip writing the current instruction.
	if (opcode == SpvOpLine) {
	uint32_t operand_index = 0;
	if (last_line_inst->WhileEachInOperand(
	[&operand_index, i](const uint32_t* word) {
	assert(i->NumInOperandWords() > operand_index);
	return *word == i->GetSingleWordInOperand(operand_index++);
	})) {
	return;
	}
	} else if (opcode != SpvOpNoLine && i->dbg_line_insts().empty()) {
	// If the current instruction does not have the line information,
	// the last line information is not effective any more. Emit OpNoLine
	// to specify it.
	binary->push_back((1 << 16) \| static_cast<uint16_t>(SpvOpNoLine));
	last_line_inst = nullptr;
	}
	}
	if (!(skip_nop && i->IsNop())) {
	const auto& scope = i->GetDebugScope();
	if (scope != last_scope) {
	// Emit DebugScope \|scope\| to \|binary\|.
	auto dbg_inst = ext_inst_debuginfo_.begin();
	scope.ToBinary(dbg_inst->type_id(), context()->TakeNextId(),
	dbg_inst->GetSingleWordOperand(2), binary);
	last_scope = scope;
	}

	i->ToBinaryWithoutAttachedDebugInsts(binary);
	}
	// Update the last line instruction.
	if (IsTerminatorInst(opcode) \|\| opcode == SpvOpNoLine) {
	last_line_inst = nullptr;
	} else if (opcode == SpvOpLoopMerge \|\| opcode == SpvOpSelectionMerge) {
	between_merge_and_branch = true;
	last_line_inst = nullptr;
	} else if (opcode == SpvOpLine) {
	last_line_inst = i;
	}
	};
	ForEachInst(write_inst, true);

	// We create new instructions for DebugScope. The bound must be updated.
	binary->data()[bound_idx] = header_.bound;
	}

	uint32_t Module::ComputeIdBound() const {
	uint32_t highest = 0;

	ForEachInst(
	[&highest](const Instruction* inst) {
	for (const auto& operand : *inst) {
	if (spvIsIdType(operand.type)) {
	highest = std::max(highest, operand.words[0]);
	}
	}
	},
	true /* scan debug line insts as well */);

	return highest + 1;
	}

	bool Module::HasExplicitCapability(uint32_t cap) {
	for (auto& ci : capabilities_) {
	uint32_t tcap = ci.GetSingleWordOperand(0);
	if (tcap == cap) {
	return true;
	}
	}
	return false;
	}

	uint32_t Module::GetExtInstImportId(const char* extstr) {
	for (auto& ei : ext_inst_imports_)
	if (!strcmp(extstr,
	reinterpret_cast<const char*>(&(ei.GetInOperand(0).words[0]))))
	return ei.result_id();
	return 0;
	}

	std::ostream& operator<<(std::ostream& str, const Module& module) {
	module.ForEachInst([&str](const Instruction* inst) {
	str << *inst;
	if (inst->opcode() != SpvOpFunctionEnd) {
	str << std::endl;
	}
	});
	return str;
	}

	} // namespace opt
	} // namespace spvtools