/* * Copyright 2018-2019 Arm Limited * * 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 "spirv_cross_parsed_ir.hpp" #include #include using namespace std; using namespace spv; namespace SPIRV_CROSS_NAMESPACE { ParsedIR::ParsedIR() { // If we move ParsedIR, we need to make sure the pointer stays fixed since the child Variant objects consume a pointer to this group, // so need an extra pointer here. pool_group.reset(new ObjectPoolGroup); pool_group->pools[TypeType].reset(new ObjectPool); pool_group->pools[TypeVariable].reset(new ObjectPool); pool_group->pools[TypeConstant].reset(new ObjectPool); pool_group->pools[TypeFunction].reset(new ObjectPool); pool_group->pools[TypeFunctionPrototype].reset(new ObjectPool); pool_group->pools[TypeBlock].reset(new ObjectPool); pool_group->pools[TypeExtension].reset(new ObjectPool); pool_group->pools[TypeExpression].reset(new ObjectPool); pool_group->pools[TypeConstantOp].reset(new ObjectPool); pool_group->pools[TypeCombinedImageSampler].reset(new ObjectPool); pool_group->pools[TypeAccessChain].reset(new ObjectPool); pool_group->pools[TypeUndef].reset(new ObjectPool); pool_group->pools[TypeString].reset(new ObjectPool); } // Should have been default-implemented, but need this on MSVC 2013. ParsedIR::ParsedIR(ParsedIR &&other) SPIRV_CROSS_NOEXCEPT { *this = move(other); } ParsedIR &ParsedIR::operator=(ParsedIR &&other) SPIRV_CROSS_NOEXCEPT { if (this != &other) { pool_group = move(other.pool_group); spirv = move(other.spirv); meta = move(other.meta); for (int i = 0; i < TypeCount; i++) ids_for_type[i] = move(other.ids_for_type[i]); ids_for_constant_or_type = move(other.ids_for_constant_or_type); ids_for_constant_or_variable = move(other.ids_for_constant_or_variable); declared_capabilities = move(other.declared_capabilities); declared_extensions = move(other.declared_extensions); block_meta = move(other.block_meta); continue_block_to_loop_header = move(other.continue_block_to_loop_header); entry_points = move(other.entry_points); ids = move(other.ids); addressing_model = other.addressing_model; memory_model = other.memory_model; default_entry_point = other.default_entry_point; source = other.source; loop_iteration_depth_hard = other.loop_iteration_depth_hard; loop_iteration_depth_soft = other.loop_iteration_depth_soft; } return *this; } ParsedIR::ParsedIR(const ParsedIR &other) : ParsedIR() { *this = other; } ParsedIR &ParsedIR::operator=(const ParsedIR &other) { if (this != &other) { spirv = other.spirv; meta = other.meta; for (int i = 0; i < TypeCount; i++) ids_for_type[i] = other.ids_for_type[i]; ids_for_constant_or_type = other.ids_for_constant_or_type; ids_for_constant_or_variable = other.ids_for_constant_or_variable; declared_capabilities = other.declared_capabilities; declared_extensions = other.declared_extensions; block_meta = other.block_meta; continue_block_to_loop_header = other.continue_block_to_loop_header; entry_points = other.entry_points; default_entry_point = other.default_entry_point; source = other.source; loop_iteration_depth_hard = other.loop_iteration_depth_hard; loop_iteration_depth_soft = other.loop_iteration_depth_soft; addressing_model = other.addressing_model; memory_model = other.memory_model; // Very deliberate copying of IDs. There is no default copy constructor, nor a simple default constructor. // Construct object first so we have the correct allocator set-up, then we can copy object into our new pool group. ids.clear(); ids.reserve(other.ids.size()); for (size_t i = 0; i < other.ids.size(); i++) { ids.emplace_back(pool_group.get()); ids.back() = other.ids[i]; } } return *this; } void ParsedIR::set_id_bounds(uint32_t bounds) { ids.reserve(bounds); while (ids.size() < bounds) ids.emplace_back(pool_group.get()); block_meta.resize(bounds); } static string ensure_valid_identifier(const string &name, bool member) { // Functions in glslangValidator are mangled with name( stuff. // Normally, we would never see '(' in any legal identifiers, so just strip them out. auto str = name.substr(0, name.find('(')); for (uint32_t i = 0; i < str.size(); i++) { auto &c = str[i]; if (member) { // _m variables are reserved by the internal implementation, // otherwise, make sure the name is a valid identifier. if (i == 0) c = isalpha(c) ? c : '_'; else if (i == 2 && str[0] == '_' && str[1] == 'm') c = isalpha(c) ? c : '_'; else c = isalnum(c) ? c : '_'; } else { // _ variables are reserved by the internal implementation, // otherwise, make sure the name is a valid identifier. if (i == 0 || (str[0] == '_' && i == 1)) c = isalpha(c) ? c : '_'; else c = isalnum(c) ? c : '_'; } } return str; } const string &ParsedIR::get_name(uint32_t id) const { auto *m = find_meta(id); if (m) return m->decoration.alias; else return empty_string; } const string &ParsedIR::get_member_name(uint32_t id, uint32_t index) const { auto *m = find_meta(id); if (m) { if (index >= m->members.size()) return empty_string; return m->members[index].alias; } else return empty_string; } void ParsedIR::set_name(uint32_t id, const string &name) { auto &str = meta[id].decoration.alias; str.clear(); if (name.empty()) return; // Reserved for temporaries. if (name[0] == '_' && name.size() >= 2 && isdigit(name[1])) return; str = ensure_valid_identifier(name, false); } void ParsedIR::set_member_name(uint32_t id, uint32_t index, const string &name) { meta[id].members.resize(max(meta[id].members.size(), size_t(index) + 1)); auto &str = meta[id].members[index].alias; str.clear(); if (name.empty()) return; // Reserved for unnamed members. if (name[0] == '_' && name.size() >= 3 && name[1] == 'm' && isdigit(name[2])) return; str = ensure_valid_identifier(name, true); } void ParsedIR::set_decoration_string(uint32_t id, Decoration decoration, const string &argument) { auto &dec = meta[id].decoration; dec.decoration_flags.set(decoration); switch (decoration) { case DecorationHlslSemanticGOOGLE: dec.hlsl_semantic = argument; break; default: break; } } void ParsedIR::set_decoration(uint32_t id, Decoration decoration, uint32_t argument) { auto &dec = meta[id].decoration; dec.decoration_flags.set(decoration); switch (decoration) { case DecorationBuiltIn: dec.builtin = true; dec.builtin_type = static_cast(argument); break; case DecorationLocation: dec.location = argument; break; case DecorationComponent: dec.component = argument; break; case DecorationOffset: dec.offset = argument; break; case DecorationArrayStride: dec.array_stride = argument; break; case DecorationMatrixStride: dec.matrix_stride = argument; break; case DecorationBinding: dec.binding = argument; break; case DecorationDescriptorSet: dec.set = argument; break; case DecorationInputAttachmentIndex: dec.input_attachment = argument; break; case DecorationSpecId: dec.spec_id = argument; break; case DecorationIndex: dec.index = argument; break; case DecorationHlslCounterBufferGOOGLE: meta[id].hlsl_magic_counter_buffer = argument; meta[argument].hlsl_is_magic_counter_buffer = true; break; case DecorationFPRoundingMode: dec.fp_rounding_mode = static_cast(argument); break; default: break; } } void ParsedIR::set_member_decoration(uint32_t id, uint32_t index, Decoration decoration, uint32_t argument) { meta[id].members.resize(max(meta[id].members.size(), size_t(index) + 1)); auto &dec = meta[id].members[index]; dec.decoration_flags.set(decoration); switch (decoration) { case DecorationBuiltIn: dec.builtin = true; dec.builtin_type = static_cast(argument); break; case DecorationLocation: dec.location = argument; break; case DecorationComponent: dec.component = argument; break; case DecorationBinding: dec.binding = argument; break; case DecorationOffset: dec.offset = argument; break; case DecorationSpecId: dec.spec_id = argument; break; case DecorationMatrixStride: dec.matrix_stride = argument; break; case DecorationIndex: dec.index = argument; break; default: break; } } // Recursively marks any constants referenced by the specified constant instruction as being used // as an array length. The id must be a constant instruction (SPIRConstant or SPIRConstantOp). void ParsedIR::mark_used_as_array_length(uint32_t id) { switch (ids[id].get_type()) { case TypeConstant: get(id).is_used_as_array_length = true; break; case TypeConstantOp: { auto &cop = get(id); for (uint32_t arg_id : cop.arguments) mark_used_as_array_length(arg_id); break; } case TypeUndef: break; default: assert(0); } } Bitset ParsedIR::get_buffer_block_flags(const SPIRVariable &var) const { auto &type = get(var.basetype); assert(type.basetype == SPIRType::Struct); // Some flags like non-writable, non-readable are actually found // as member decorations. If all members have a decoration set, propagate // the decoration up as a regular variable decoration. Bitset base_flags; auto *m = find_meta(var.self); if (m) base_flags = m->decoration.decoration_flags; if (type.member_types.empty()) return base_flags; Bitset all_members_flags = get_member_decoration_bitset(type.self, 0); for (uint32_t i = 1; i < uint32_t(type.member_types.size()); i++) all_members_flags.merge_and(get_member_decoration_bitset(type.self, i)); base_flags.merge_or(all_members_flags); return base_flags; } const Bitset &ParsedIR::get_member_decoration_bitset(uint32_t id, uint32_t index) const { auto *m = find_meta(id); if (m) { if (index >= m->members.size()) return cleared_bitset; return m->members[index].decoration_flags; } else return cleared_bitset; } bool ParsedIR::has_decoration(uint32_t id, Decoration decoration) const { return get_decoration_bitset(id).get(decoration); } uint32_t ParsedIR::get_decoration(uint32_t id, Decoration decoration) const { auto *m = find_meta(id); if (!m) return 0; auto &dec = m->decoration; if (!dec.decoration_flags.get(decoration)) return 0; switch (decoration) { case DecorationBuiltIn: return dec.builtin_type; case DecorationLocation: return dec.location; case DecorationComponent: return dec.component; case DecorationOffset: return dec.offset; case DecorationBinding: return dec.binding; case DecorationDescriptorSet: return dec.set; case DecorationInputAttachmentIndex: return dec.input_attachment; case DecorationSpecId: return dec.spec_id; case DecorationArrayStride: return dec.array_stride; case DecorationMatrixStride: return dec.matrix_stride; case DecorationIndex: return dec.index; case DecorationFPRoundingMode: return dec.fp_rounding_mode; default: return 1; } } const string &ParsedIR::get_decoration_string(uint32_t id, Decoration decoration) const { auto *m = find_meta(id); if (!m) return empty_string; auto &dec = m->decoration; if (!dec.decoration_flags.get(decoration)) return empty_string; switch (decoration) { case DecorationHlslSemanticGOOGLE: return dec.hlsl_semantic; default: return empty_string; } } void ParsedIR::unset_decoration(uint32_t id, Decoration decoration) { auto &dec = meta[id].decoration; dec.decoration_flags.clear(decoration); switch (decoration) { case DecorationBuiltIn: dec.builtin = false; break; case DecorationLocation: dec.location = 0; break; case DecorationComponent: dec.component = 0; break; case DecorationOffset: dec.offset = 0; break; case DecorationBinding: dec.binding = 0; break; case DecorationDescriptorSet: dec.set = 0; break; case DecorationInputAttachmentIndex: dec.input_attachment = 0; break; case DecorationSpecId: dec.spec_id = 0; break; case DecorationHlslSemanticGOOGLE: dec.hlsl_semantic.clear(); break; case DecorationFPRoundingMode: dec.fp_rounding_mode = FPRoundingModeMax; break; case DecorationHlslCounterBufferGOOGLE: { auto &counter = meta[id].hlsl_magic_counter_buffer; if (counter) { meta[counter].hlsl_is_magic_counter_buffer = false; counter = 0; } break; } default: break; } } bool ParsedIR::has_member_decoration(uint32_t id, uint32_t index, Decoration decoration) const { return get_member_decoration_bitset(id, index).get(decoration); } uint32_t ParsedIR::get_member_decoration(uint32_t id, uint32_t index, Decoration decoration) const { auto *m = find_meta(id); if (!m) return 0; if (index >= m->members.size()) return 0; auto &dec = m->members[index]; if (!dec.decoration_flags.get(decoration)) return 0; switch (decoration) { case DecorationBuiltIn: return dec.builtin_type; case DecorationLocation: return dec.location; case DecorationComponent: return dec.component; case DecorationBinding: return dec.binding; case DecorationOffset: return dec.offset; case DecorationSpecId: return dec.spec_id; case DecorationIndex: return dec.index; default: return 1; } } const Bitset &ParsedIR::get_decoration_bitset(uint32_t id) const { auto *m = find_meta(id); if (m) { auto &dec = m->decoration; return dec.decoration_flags; } else return cleared_bitset; } void ParsedIR::set_member_decoration_string(uint32_t id, uint32_t index, Decoration decoration, const string &argument) { meta[id].members.resize(max(meta[id].members.size(), size_t(index) + 1)); auto &dec = meta[id].members[index]; dec.decoration_flags.set(decoration); switch (decoration) { case DecorationHlslSemanticGOOGLE: dec.hlsl_semantic = argument; break; default: break; } } const string &ParsedIR::get_member_decoration_string(uint32_t id, uint32_t index, Decoration decoration) const { auto *m = find_meta(id); if (m) { if (!has_member_decoration(id, index, decoration)) return empty_string; auto &dec = m->members[index]; switch (decoration) { case DecorationHlslSemanticGOOGLE: return dec.hlsl_semantic; default: return empty_string; } } else return empty_string; } void ParsedIR::unset_member_decoration(uint32_t id, uint32_t index, Decoration decoration) { auto &m = meta[id]; if (index >= m.members.size()) return; auto &dec = m.members[index]; dec.decoration_flags.clear(decoration); switch (decoration) { case DecorationBuiltIn: dec.builtin = false; break; case DecorationLocation: dec.location = 0; break; case DecorationComponent: dec.component = 0; break; case DecorationOffset: dec.offset = 0; break; case DecorationSpecId: dec.spec_id = 0; break; case DecorationHlslSemanticGOOGLE: dec.hlsl_semantic.clear(); break; default: break; } } uint32_t ParsedIR::increase_bound_by(uint32_t incr_amount) { auto curr_bound = ids.size(); auto new_bound = curr_bound + incr_amount; ids.reserve(ids.size() + incr_amount); for (uint32_t i = 0; i < incr_amount; i++) ids.emplace_back(pool_group.get()); block_meta.resize(new_bound); return uint32_t(curr_bound); } void ParsedIR::remove_typed_id(Types type, uint32_t id) { auto &type_ids = ids_for_type[type]; type_ids.erase(remove(begin(type_ids), end(type_ids), id), end(type_ids)); } void ParsedIR::reset_all_of_type(Types type) { for (auto &id : ids_for_type[type]) if (ids[id].get_type() == type) ids[id].reset(); ids_for_type[type].clear(); } void ParsedIR::add_typed_id(Types type, uint32_t id) { if (loop_iteration_depth_hard != 0) SPIRV_CROSS_THROW("Cannot add typed ID while looping over it."); if (loop_iteration_depth_soft != 0) { if (!ids[id].empty()) SPIRV_CROSS_THROW("Cannot override IDs when loop is soft locked."); return; } if (ids[id].empty() || ids[id].get_type() != type) { switch (type) { case TypeConstant: ids_for_constant_or_variable.push_back(id); ids_for_constant_or_type.push_back(id); break; case TypeVariable: ids_for_constant_or_variable.push_back(id); break; case TypeType: case TypeConstantOp: ids_for_constant_or_type.push_back(id); break; default: break; } } if (ids[id].empty()) { ids_for_type[type].push_back(id); } else if (ids[id].get_type() != type) { remove_typed_id(ids[id].get_type(), id); ids_for_type[type].push_back(id); } } const Meta *ParsedIR::find_meta(uint32_t id) const { auto itr = meta.find(id); if (itr != end(meta)) return &itr->second; else return nullptr; } Meta *ParsedIR::find_meta(uint32_t id) { auto itr = meta.find(id); if (itr != end(meta)) return &itr->second; else return nullptr; } ParsedIR::LoopLock ParsedIR::create_loop_hard_lock() const { return ParsedIR::LoopLock(&loop_iteration_depth_hard); } ParsedIR::LoopLock ParsedIR::create_loop_soft_lock() const { return ParsedIR::LoopLock(&loop_iteration_depth_soft); } ParsedIR::LoopLock::~LoopLock() { if (lock) (*lock)--; } ParsedIR::LoopLock::LoopLock(uint32_t *lock_) : lock(lock_) { if (lock) (*lock)++; } ParsedIR::LoopLock::LoopLock(LoopLock &&other) SPIRV_CROSS_NOEXCEPT { *this = move(other); } ParsedIR::LoopLock &ParsedIR::LoopLock::operator=(LoopLock &&other) SPIRV_CROSS_NOEXCEPT { if (lock) (*lock)--; lock = other.lock; other.lock = nullptr; return *this; } } // namespace SPIRV_CROSS_NAMESPACE