SPIRV-Tools/source/val/validation_state.cpp

1114 lines
33 KiB
C++

// 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/val/validation_state.h"
#include <cassert>
#include <stack>
#include <utility>
#include "source/opcode.h"
#include "source/spirv_target_env.h"
#include "source/val/basic_block.h"
#include "source/val/construct.h"
#include "source/val/function.h"
#include "spirv-tools/libspirv.h"
namespace spvtools {
namespace val {
namespace {
bool IsInstructionInLayoutSection(ModuleLayoutSection layout, SpvOp op) {
// See Section 2.4
bool out = false;
// clang-format off
switch (layout) {
case kLayoutCapabilities: out = op == SpvOpCapability; break;
case kLayoutExtensions: out = op == SpvOpExtension; break;
case kLayoutExtInstImport: out = op == SpvOpExtInstImport; break;
case kLayoutMemoryModel: out = op == SpvOpMemoryModel; break;
case kLayoutEntryPoint: out = op == SpvOpEntryPoint; break;
case kLayoutExecutionMode:
out = op == SpvOpExecutionMode || op == SpvOpExecutionModeId;
break;
case kLayoutDebug1:
switch (op) {
case SpvOpSourceContinued:
case SpvOpSource:
case SpvOpSourceExtension:
case SpvOpString:
out = true;
break;
default: break;
}
break;
case kLayoutDebug2:
switch (op) {
case SpvOpName:
case SpvOpMemberName:
out = true;
break;
default: break;
}
break;
case kLayoutDebug3:
// Only OpModuleProcessed is allowed here.
out = (op == SpvOpModuleProcessed);
break;
case kLayoutAnnotations:
switch (op) {
case SpvOpDecorate:
case SpvOpMemberDecorate:
case SpvOpGroupDecorate:
case SpvOpGroupMemberDecorate:
case SpvOpDecorationGroup:
case SpvOpDecorateId:
case SpvOpDecorateStringGOOGLE:
case SpvOpMemberDecorateStringGOOGLE:
out = true;
break;
default: break;
}
break;
case kLayoutTypes:
if (spvOpcodeGeneratesType(op) || spvOpcodeIsConstant(op)) {
out = true;
break;
}
switch (op) {
case SpvOpTypeForwardPointer:
case SpvOpVariable:
case SpvOpLine:
case SpvOpNoLine:
case SpvOpUndef:
out = true;
break;
default: break;
}
break;
case kLayoutFunctionDeclarations:
case kLayoutFunctionDefinitions:
// NOTE: These instructions should NOT be in these layout sections
if (spvOpcodeGeneratesType(op) || spvOpcodeIsConstant(op)) {
out = false;
break;
}
switch (op) {
case SpvOpCapability:
case SpvOpExtension:
case SpvOpExtInstImport:
case SpvOpMemoryModel:
case SpvOpEntryPoint:
case SpvOpExecutionMode:
case SpvOpExecutionModeId:
case SpvOpSourceContinued:
case SpvOpSource:
case SpvOpSourceExtension:
case SpvOpString:
case SpvOpName:
case SpvOpMemberName:
case SpvOpModuleProcessed:
case SpvOpDecorate:
case SpvOpMemberDecorate:
case SpvOpGroupDecorate:
case SpvOpGroupMemberDecorate:
case SpvOpDecorationGroup:
case SpvOpTypeForwardPointer:
out = false;
break;
default:
out = true;
break;
}
}
// clang-format on
return out;
}
// Counts the number of instructions and functions in the file.
spv_result_t CountInstructions(void* user_data,
const spv_parsed_instruction_t* inst) {
ValidationState_t& _ = *(reinterpret_cast<ValidationState_t*>(user_data));
if (inst->opcode == SpvOpFunction) _.increment_total_functions();
_.increment_total_instructions();
return SPV_SUCCESS;
}
} // namespace
ValidationState_t::ValidationState_t(const spv_const_context ctx,
const spv_const_validator_options opt,
const uint32_t* words,
const size_t num_words,
const uint32_t max_warnings)
: context_(ctx),
options_(opt),
words_(words),
num_words_(num_words),
unresolved_forward_ids_{},
operand_names_{},
current_layout_section_(kLayoutCapabilities),
module_functions_(),
module_capabilities_(),
module_extensions_(),
ordered_instructions_(),
all_definitions_(),
global_vars_(),
local_vars_(),
struct_nesting_depth_(),
struct_has_nested_blockorbufferblock_struct_(),
grammar_(ctx),
addressing_model_(SpvAddressingModelMax),
memory_model_(SpvMemoryModelMax),
pointer_size_and_alignment_(0),
in_function_(false),
num_of_warnings_(0),
max_num_of_warnings_(max_warnings) {
assert(opt && "Validator options may not be Null.");
const auto env = context_->target_env;
if (spvIsVulkanEnv(env)) {
// Vulkan 1.1 includes VK_KHR_relaxed_block_layout in core.
if (env != SPV_ENV_VULKAN_1_0) {
features_.env_relaxed_block_layout = true;
}
}
switch (env) {
case SPV_ENV_WEBGPU_0:
features_.bans_op_undef = true;
break;
default:
break;
}
// Only attempt to count if we have words, otherwise let the other validation
// fail and generate an error.
if (num_words > 0) {
// Count the number of instructions in the binary.
// This parse should not produce any error messages. Hijack the context and
// replace the message consumer so that we do not pollute any state in input
// consumer.
spv_context_t hijacked_context = *ctx;
hijacked_context.consumer = [](spv_message_level_t, const char*,
const spv_position_t&, const char*) {};
spvBinaryParse(&hijacked_context, this, words, num_words,
/* parsed_header = */ nullptr, CountInstructions,
/* diagnostic = */ nullptr);
preallocateStorage();
}
friendly_mapper_ = spvtools::MakeUnique<spvtools::FriendlyNameMapper>(
context_, words_, num_words_);
name_mapper_ = friendly_mapper_->GetNameMapper();
}
void ValidationState_t::preallocateStorage() {
ordered_instructions_.reserve(total_instructions_);
module_functions_.reserve(total_functions_);
}
spv_result_t ValidationState_t::ForwardDeclareId(uint32_t id) {
unresolved_forward_ids_.insert(id);
return SPV_SUCCESS;
}
spv_result_t ValidationState_t::RemoveIfForwardDeclared(uint32_t id) {
unresolved_forward_ids_.erase(id);
return SPV_SUCCESS;
}
spv_result_t ValidationState_t::RegisterForwardPointer(uint32_t id) {
forward_pointer_ids_.insert(id);
return SPV_SUCCESS;
}
bool ValidationState_t::IsForwardPointer(uint32_t id) const {
return (forward_pointer_ids_.find(id) != forward_pointer_ids_.end());
}
void ValidationState_t::AssignNameToId(uint32_t id, std::string name) {
operand_names_[id] = name;
}
std::string ValidationState_t::getIdName(uint32_t id) const {
const std::string id_name = name_mapper_(id);
std::stringstream out;
out << id << "[%" << id_name << "]";
return out.str();
}
size_t ValidationState_t::unresolved_forward_id_count() const {
return unresolved_forward_ids_.size();
}
std::vector<uint32_t> ValidationState_t::UnresolvedForwardIds() const {
std::vector<uint32_t> out(std::begin(unresolved_forward_ids_),
std::end(unresolved_forward_ids_));
return out;
}
bool ValidationState_t::IsDefinedId(uint32_t id) const {
return all_definitions_.find(id) != std::end(all_definitions_);
}
const Instruction* ValidationState_t::FindDef(uint32_t id) const {
auto it = all_definitions_.find(id);
if (it == all_definitions_.end()) return nullptr;
return it->second;
}
Instruction* ValidationState_t::FindDef(uint32_t id) {
auto it = all_definitions_.find(id);
if (it == all_definitions_.end()) return nullptr;
return it->second;
}
ModuleLayoutSection ValidationState_t::current_layout_section() const {
return current_layout_section_;
}
void ValidationState_t::ProgressToNextLayoutSectionOrder() {
// Guard against going past the last element(kLayoutFunctionDefinitions)
if (current_layout_section_ <= kLayoutFunctionDefinitions) {
current_layout_section_ =
static_cast<ModuleLayoutSection>(current_layout_section_ + 1);
}
}
bool ValidationState_t::IsOpcodeInCurrentLayoutSection(SpvOp op) {
return IsInstructionInLayoutSection(current_layout_section_, op);
}
DiagnosticStream ValidationState_t::diag(spv_result_t error_code,
const Instruction* inst) {
if (error_code == SPV_WARNING) {
if (num_of_warnings_ == max_num_of_warnings_) {
DiagnosticStream({0, 0, 0}, context_->consumer, "", error_code)
<< "Other warnings have been suppressed.\n";
}
if (num_of_warnings_ >= max_num_of_warnings_) {
return DiagnosticStream({0, 0, 0}, nullptr, "", error_code);
}
++num_of_warnings_;
}
std::string disassembly;
if (inst) disassembly = Disassemble(*inst);
return DiagnosticStream({0, 0, inst ? inst->LineNum() : 0},
context_->consumer, disassembly, error_code);
}
std::vector<Function>& ValidationState_t::functions() {
return module_functions_;
}
Function& ValidationState_t::current_function() {
assert(in_function_body());
return module_functions_.back();
}
const Function& ValidationState_t::current_function() const {
assert(in_function_body());
return module_functions_.back();
}
const Function* ValidationState_t::function(uint32_t id) const {
const auto it = id_to_function_.find(id);
if (it == id_to_function_.end()) return nullptr;
return it->second;
}
Function* ValidationState_t::function(uint32_t id) {
auto it = id_to_function_.find(id);
if (it == id_to_function_.end()) return nullptr;
return it->second;
}
bool ValidationState_t::in_function_body() const { return in_function_; }
bool ValidationState_t::in_block() const {
return module_functions_.empty() == false &&
module_functions_.back().current_block() != nullptr;
}
void ValidationState_t::RegisterCapability(SpvCapability cap) {
// Avoid redundant work. Otherwise the recursion could induce work
// quadrdatic in the capability dependency depth. (Ok, not much, but
// it's something.)
if (module_capabilities_.Contains(cap)) return;
module_capabilities_.Add(cap);
spv_operand_desc desc;
if (SPV_SUCCESS ==
grammar_.lookupOperand(SPV_OPERAND_TYPE_CAPABILITY, cap, &desc)) {
CapabilitySet(desc->numCapabilities, desc->capabilities)
.ForEach([this](SpvCapability c) { RegisterCapability(c); });
}
switch (cap) {
case SpvCapabilityKernel:
features_.group_ops_reduce_and_scans = true;
break;
case SpvCapabilityInt8:
features_.use_int8_type = true;
features_.declare_int8_type = true;
break;
case SpvCapabilityStorageBuffer8BitAccess:
case SpvCapabilityUniformAndStorageBuffer8BitAccess:
case SpvCapabilityStoragePushConstant8:
features_.declare_int8_type = true;
break;
case SpvCapabilityInt16:
features_.declare_int16_type = true;
break;
case SpvCapabilityFloat16:
case SpvCapabilityFloat16Buffer:
features_.declare_float16_type = true;
break;
case SpvCapabilityStorageUniformBufferBlock16:
case SpvCapabilityStorageUniform16:
case SpvCapabilityStoragePushConstant16:
case SpvCapabilityStorageInputOutput16:
features_.declare_int16_type = true;
features_.declare_float16_type = true;
features_.free_fp_rounding_mode = true;
break;
case SpvCapabilityVariablePointers:
features_.variable_pointers = true;
features_.variable_pointers_storage_buffer = true;
break;
case SpvCapabilityVariablePointersStorageBuffer:
features_.variable_pointers_storage_buffer = true;
break;
default:
break;
}
}
void ValidationState_t::RegisterExtension(Extension ext) {
if (module_extensions_.Contains(ext)) return;
module_extensions_.Add(ext);
switch (ext) {
case kSPV_AMD_gpu_shader_half_float:
case kSPV_AMD_gpu_shader_half_float_fetch:
// SPV_AMD_gpu_shader_half_float enables float16 type.
// https://github.com/KhronosGroup/SPIRV-Tools/issues/1375
features_.declare_float16_type = true;
break;
case kSPV_AMD_gpu_shader_int16:
// This is not yet in the extension, but it's recommended for it.
// See https://github.com/KhronosGroup/glslang/issues/848
features_.uconvert_spec_constant_op = true;
break;
case kSPV_AMD_shader_ballot:
// The grammar doesn't encode the fact that SPV_AMD_shader_ballot
// enables the use of group operations Reduce, InclusiveScan,
// and ExclusiveScan. Enable it manually.
// https://github.com/KhronosGroup/SPIRV-Tools/issues/991
features_.group_ops_reduce_and_scans = true;
break;
default:
break;
}
}
bool ValidationState_t::HasAnyOfCapabilities(
const CapabilitySet& capabilities) const {
return module_capabilities_.HasAnyOf(capabilities);
}
bool ValidationState_t::HasAnyOfExtensions(
const ExtensionSet& extensions) const {
return module_extensions_.HasAnyOf(extensions);
}
void ValidationState_t::set_addressing_model(SpvAddressingModel am) {
addressing_model_ = am;
switch (am) {
case SpvAddressingModelPhysical32:
pointer_size_and_alignment_ = 4;
break;
default:
// fall through
case SpvAddressingModelPhysical64:
case SpvAddressingModelPhysicalStorageBuffer64EXT:
pointer_size_and_alignment_ = 8;
break;
}
}
SpvAddressingModel ValidationState_t::addressing_model() const {
return addressing_model_;
}
void ValidationState_t::set_memory_model(SpvMemoryModel mm) {
memory_model_ = mm;
}
SpvMemoryModel ValidationState_t::memory_model() const { return memory_model_; }
spv_result_t ValidationState_t::RegisterFunction(
uint32_t id, uint32_t ret_type_id, SpvFunctionControlMask function_control,
uint32_t function_type_id) {
assert(in_function_body() == false &&
"RegisterFunction can only be called when parsing the binary outside "
"of another function");
in_function_ = true;
module_functions_.emplace_back(id, ret_type_id, function_control,
function_type_id);
id_to_function_.emplace(id, &current_function());
// TODO(umar): validate function type and type_id
return SPV_SUCCESS;
}
spv_result_t ValidationState_t::RegisterFunctionEnd() {
assert(in_function_body() == true &&
"RegisterFunctionEnd can only be called when parsing the binary "
"inside of another function");
assert(in_block() == false &&
"RegisterFunctionParameter can only be called when parsing the binary "
"ouside of a block");
current_function().RegisterFunctionEnd();
in_function_ = false;
return SPV_SUCCESS;
}
Instruction* ValidationState_t::AddOrderedInstruction(
const spv_parsed_instruction_t* inst) {
ordered_instructions_.emplace_back(inst);
ordered_instructions_.back().SetLineNum(ordered_instructions_.size());
return &ordered_instructions_.back();
}
// Improves diagnostic messages by collecting names of IDs
void ValidationState_t::RegisterDebugInstruction(const Instruction* inst) {
switch (inst->opcode()) {
case SpvOpName: {
const auto target = inst->GetOperandAs<uint32_t>(0);
const auto* str = reinterpret_cast<const char*>(inst->words().data() +
inst->operand(1).offset);
AssignNameToId(target, str);
break;
}
case SpvOpMemberName: {
const auto target = inst->GetOperandAs<uint32_t>(0);
const auto* str = reinterpret_cast<const char*>(inst->words().data() +
inst->operand(2).offset);
AssignNameToId(target, str);
break;
}
case SpvOpSourceContinued:
case SpvOpSource:
case SpvOpSourceExtension:
case SpvOpString:
case SpvOpLine:
case SpvOpNoLine:
default:
break;
}
}
void ValidationState_t::RegisterInstruction(Instruction* inst) {
if (inst->id()) all_definitions_.insert(std::make_pair(inst->id(), inst));
// If the instruction is using an OpTypeSampledImage as an operand, it should
// be recorded. The validator will ensure that all usages of an
// OpTypeSampledImage and its definition are in the same basic block.
for (uint16_t i = 0; i < inst->operands().size(); ++i) {
const spv_parsed_operand_t& operand = inst->operand(i);
if (SPV_OPERAND_TYPE_ID == operand.type) {
const uint32_t operand_word = inst->word(operand.offset);
Instruction* operand_inst = FindDef(operand_word);
if (operand_inst && SpvOpSampledImage == operand_inst->opcode()) {
RegisterSampledImageConsumer(operand_word, inst->id());
}
}
}
}
std::vector<uint32_t> ValidationState_t::getSampledImageConsumers(
uint32_t sampled_image_id) const {
std::vector<uint32_t> result;
auto iter = sampled_image_consumers_.find(sampled_image_id);
if (iter != sampled_image_consumers_.end()) {
result = iter->second;
}
return result;
}
void ValidationState_t::RegisterSampledImageConsumer(uint32_t sampled_image_id,
uint32_t consumer_id) {
sampled_image_consumers_[sampled_image_id].push_back(consumer_id);
}
uint32_t ValidationState_t::getIdBound() const { return id_bound_; }
void ValidationState_t::setIdBound(const uint32_t bound) { id_bound_ = bound; }
bool ValidationState_t::RegisterUniqueTypeDeclaration(const Instruction* inst) {
std::vector<uint32_t> key;
key.push_back(static_cast<uint32_t>(inst->opcode()));
for (size_t index = 0; index < inst->operands().size(); ++index) {
const spv_parsed_operand_t& operand = inst->operand(index);
if (operand.type == SPV_OPERAND_TYPE_RESULT_ID) continue;
const int words_begin = operand.offset;
const int words_end = words_begin + operand.num_words;
assert(words_end <= static_cast<int>(inst->words().size()));
key.insert(key.end(), inst->words().begin() + words_begin,
inst->words().begin() + words_end);
}
return unique_type_declarations_.insert(std::move(key)).second;
}
uint32_t ValidationState_t::GetTypeId(uint32_t id) const {
const Instruction* inst = FindDef(id);
return inst ? inst->type_id() : 0;
}
SpvOp ValidationState_t::GetIdOpcode(uint32_t id) const {
const Instruction* inst = FindDef(id);
return inst ? inst->opcode() : SpvOpNop;
}
uint32_t ValidationState_t::GetComponentType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
switch (inst->opcode()) {
case SpvOpTypeFloat:
case SpvOpTypeInt:
case SpvOpTypeBool:
return id;
case SpvOpTypeVector:
return inst->word(2);
case SpvOpTypeMatrix:
return GetComponentType(inst->word(2));
case SpvOpTypeCooperativeMatrixNV:
return inst->word(2);
default:
break;
}
if (inst->type_id()) return GetComponentType(inst->type_id());
assert(0);
return 0;
}
uint32_t ValidationState_t::GetDimension(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
switch (inst->opcode()) {
case SpvOpTypeFloat:
case SpvOpTypeInt:
case SpvOpTypeBool:
return 1;
case SpvOpTypeVector:
case SpvOpTypeMatrix:
return inst->word(3);
case SpvOpTypeCooperativeMatrixNV:
// Actual dimension isn't known, return 0
return 0;
default:
break;
}
if (inst->type_id()) return GetDimension(inst->type_id());
assert(0);
return 0;
}
uint32_t ValidationState_t::GetBitWidth(uint32_t id) const {
const uint32_t component_type_id = GetComponentType(id);
const Instruction* inst = FindDef(component_type_id);
assert(inst);
if (inst->opcode() == SpvOpTypeFloat || inst->opcode() == SpvOpTypeInt)
return inst->word(2);
if (inst->opcode() == SpvOpTypeBool) return 1;
assert(0);
return 0;
}
bool ValidationState_t::IsFloatScalarType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
return inst->opcode() == SpvOpTypeFloat;
}
bool ValidationState_t::IsFloatVectorType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeVector) {
return IsFloatScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::IsFloatScalarOrVectorType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeFloat) {
return true;
}
if (inst->opcode() == SpvOpTypeVector) {
return IsFloatScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::IsIntScalarType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
return inst->opcode() == SpvOpTypeInt;
}
bool ValidationState_t::IsIntVectorType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeVector) {
return IsIntScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::IsIntScalarOrVectorType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeInt) {
return true;
}
if (inst->opcode() == SpvOpTypeVector) {
return IsIntScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::IsUnsignedIntScalarType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
return inst->opcode() == SpvOpTypeInt && inst->word(3) == 0;
}
bool ValidationState_t::IsUnsignedIntVectorType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeVector) {
return IsUnsignedIntScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::IsSignedIntScalarType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
return inst->opcode() == SpvOpTypeInt && inst->word(3) == 1;
}
bool ValidationState_t::IsSignedIntVectorType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeVector) {
return IsSignedIntScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::IsBoolScalarType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
return inst->opcode() == SpvOpTypeBool;
}
bool ValidationState_t::IsBoolVectorType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeVector) {
return IsBoolScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::IsBoolScalarOrVectorType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeBool) {
return true;
}
if (inst->opcode() == SpvOpTypeVector) {
return IsBoolScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::IsFloatMatrixType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() == SpvOpTypeMatrix) {
return IsFloatScalarType(GetComponentType(id));
}
return false;
}
bool ValidationState_t::GetMatrixTypeInfo(uint32_t id, uint32_t* num_rows,
uint32_t* num_cols,
uint32_t* column_type,
uint32_t* component_type) const {
if (!id) return false;
const Instruction* mat_inst = FindDef(id);
assert(mat_inst);
if (mat_inst->opcode() != SpvOpTypeMatrix) return false;
const uint32_t vec_type = mat_inst->word(2);
const Instruction* vec_inst = FindDef(vec_type);
assert(vec_inst);
if (vec_inst->opcode() != SpvOpTypeVector) {
assert(0);
return false;
}
*num_cols = mat_inst->word(3);
*num_rows = vec_inst->word(3);
*column_type = mat_inst->word(2);
*component_type = vec_inst->word(2);
return true;
}
bool ValidationState_t::GetStructMemberTypes(
uint32_t struct_type_id, std::vector<uint32_t>* member_types) const {
member_types->clear();
if (!struct_type_id) return false;
const Instruction* inst = FindDef(struct_type_id);
assert(inst);
if (inst->opcode() != SpvOpTypeStruct) return false;
*member_types =
std::vector<uint32_t>(inst->words().cbegin() + 2, inst->words().cend());
if (member_types->empty()) return false;
return true;
}
bool ValidationState_t::IsPointerType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
return inst->opcode() == SpvOpTypePointer;
}
bool ValidationState_t::GetPointerTypeInfo(uint32_t id, uint32_t* data_type,
uint32_t* storage_class) const {
if (!id) return false;
const Instruction* inst = FindDef(id);
assert(inst);
if (inst->opcode() != SpvOpTypePointer) return false;
*storage_class = inst->word(2);
*data_type = inst->word(3);
return true;
}
bool ValidationState_t::IsCooperativeMatrixType(uint32_t id) const {
const Instruction* inst = FindDef(id);
assert(inst);
return inst->opcode() == SpvOpTypeCooperativeMatrixNV;
}
bool ValidationState_t::IsFloatCooperativeMatrixType(uint32_t id) const {
if (!IsCooperativeMatrixType(id)) return false;
return IsFloatScalarType(FindDef(id)->word(2));
}
bool ValidationState_t::IsIntCooperativeMatrixType(uint32_t id) const {
if (!IsCooperativeMatrixType(id)) return false;
return IsIntScalarType(FindDef(id)->word(2));
}
bool ValidationState_t::IsUnsignedIntCooperativeMatrixType(uint32_t id) const {
if (!IsCooperativeMatrixType(id)) return false;
return IsUnsignedIntScalarType(FindDef(id)->word(2));
}
spv_result_t ValidationState_t::CooperativeMatrixShapesMatch(
const Instruction* inst, uint32_t m1, uint32_t m2) {
const auto m1_type = FindDef(m1);
const auto m2_type = FindDef(m2);
if (m1_type->opcode() != SpvOpTypeCooperativeMatrixNV ||
m2_type->opcode() != SpvOpTypeCooperativeMatrixNV) {
return diag(SPV_ERROR_INVALID_DATA, inst)
<< "Expected cooperative matrix types";
}
uint32_t m1_scope_id = m1_type->GetOperandAs<uint32_t>(2);
uint32_t m1_rows_id = m1_type->GetOperandAs<uint32_t>(3);
uint32_t m1_cols_id = m1_type->GetOperandAs<uint32_t>(4);
uint32_t m2_scope_id = m2_type->GetOperandAs<uint32_t>(2);
uint32_t m2_rows_id = m2_type->GetOperandAs<uint32_t>(3);
uint32_t m2_cols_id = m2_type->GetOperandAs<uint32_t>(4);
bool m1_is_int32 = false, m1_is_const_int32 = false, m2_is_int32 = false,
m2_is_const_int32 = false;
uint32_t m1_value = 0, m2_value = 0;
std::tie(m1_is_int32, m1_is_const_int32, m1_value) =
EvalInt32IfConst(m1_scope_id);
std::tie(m2_is_int32, m2_is_const_int32, m2_value) =
EvalInt32IfConst(m2_scope_id);
if (m1_is_const_int32 && m2_is_const_int32 && m1_value != m2_value) {
return diag(SPV_ERROR_INVALID_DATA, inst)
<< "Expected scopes of Matrix and Result Type to be "
<< "identical";
}
std::tie(m1_is_int32, m1_is_const_int32, m1_value) =
EvalInt32IfConst(m1_rows_id);
std::tie(m2_is_int32, m2_is_const_int32, m2_value) =
EvalInt32IfConst(m2_rows_id);
if (m1_is_const_int32 && m2_is_const_int32 && m1_value != m2_value) {
return diag(SPV_ERROR_INVALID_DATA, inst)
<< "Expected rows of Matrix type and Result Type to be "
<< "identical";
}
std::tie(m1_is_int32, m1_is_const_int32, m1_value) =
EvalInt32IfConst(m1_cols_id);
std::tie(m2_is_int32, m2_is_const_int32, m2_value) =
EvalInt32IfConst(m2_cols_id);
if (m1_is_const_int32 && m2_is_const_int32 && m1_value != m2_value) {
return diag(SPV_ERROR_INVALID_DATA, inst)
<< "Expected columns of Matrix type and Result Type to be "
<< "identical";
}
return SPV_SUCCESS;
}
uint32_t ValidationState_t::GetOperandTypeId(const Instruction* inst,
size_t operand_index) const {
return GetTypeId(inst->GetOperandAs<uint32_t>(operand_index));
}
bool ValidationState_t::GetConstantValUint64(uint32_t id, uint64_t* val) const {
const Instruction* inst = FindDef(id);
if (!inst) {
assert(0 && "Instruction not found");
return false;
}
if (inst->opcode() != SpvOpConstant && inst->opcode() != SpvOpSpecConstant)
return false;
if (!IsIntScalarType(inst->type_id())) return false;
if (inst->words().size() == 4) {
*val = inst->word(3);
} else {
assert(inst->words().size() == 5);
*val = inst->word(3);
*val |= uint64_t(inst->word(4)) << 32;
}
return true;
}
std::tuple<bool, bool, uint32_t> ValidationState_t::EvalInt32IfConst(
uint32_t id) const {
const Instruction* const inst = FindDef(id);
assert(inst);
const uint32_t type = inst->type_id();
if (type == 0 || !IsIntScalarType(type) || GetBitWidth(type) != 32) {
return std::make_tuple(false, false, 0);
}
// Spec constant values cannot be evaluated so don't consider constant for
// the purpose of this method.
if (!spvOpcodeIsConstant(inst->opcode()) ||
spvOpcodeIsSpecConstant(inst->opcode())) {
return std::make_tuple(true, false, 0);
}
if (inst->opcode() == SpvOpConstantNull) {
return std::make_tuple(true, true, 0);
}
assert(inst->words().size() == 4);
return std::make_tuple(true, true, inst->word(3));
}
void ValidationState_t::ComputeFunctionToEntryPointMapping() {
for (const uint32_t entry_point : entry_points()) {
std::stack<uint32_t> call_stack;
std::set<uint32_t> visited;
call_stack.push(entry_point);
while (!call_stack.empty()) {
const uint32_t called_func_id = call_stack.top();
call_stack.pop();
if (!visited.insert(called_func_id).second) continue;
function_to_entry_points_[called_func_id].push_back(entry_point);
const Function* called_func = function(called_func_id);
if (called_func) {
// Other checks should error out on this invalid SPIR-V.
for (const uint32_t new_call : called_func->function_call_targets()) {
call_stack.push(new_call);
}
}
}
}
}
void ValidationState_t::ComputeRecursiveEntryPoints() {
for (const Function func : functions()) {
std::stack<uint32_t> call_stack;
std::set<uint32_t> visited;
for (const uint32_t new_call : func.function_call_targets()) {
call_stack.push(new_call);
}
while (!call_stack.empty()) {
const uint32_t called_func_id = call_stack.top();
call_stack.pop();
if (!visited.insert(called_func_id).second) continue;
if (called_func_id == func.id()) {
for (const uint32_t entry_point :
function_to_entry_points_[called_func_id])
recursive_entry_points_.insert(entry_point);
break;
}
const Function* called_func = function(called_func_id);
if (called_func) {
// Other checks should error out on this invalid SPIR-V.
for (const uint32_t new_call : called_func->function_call_targets()) {
call_stack.push(new_call);
}
}
}
}
}
const std::vector<uint32_t>& ValidationState_t::FunctionEntryPoints(
uint32_t func) const {
auto iter = function_to_entry_points_.find(func);
if (iter == function_to_entry_points_.end()) {
return empty_ids_;
} else {
return iter->second;
}
}
std::set<uint32_t> ValidationState_t::EntryPointReferences(uint32_t id) const {
std::set<uint32_t> referenced_entry_points;
const auto inst = FindDef(id);
if (!inst) return referenced_entry_points;
std::vector<const Instruction*> stack;
stack.push_back(inst);
while (!stack.empty()) {
const auto current_inst = stack.back();
stack.pop_back();
if (const auto func = current_inst->function()) {
// Instruction lives in a function, we can stop searching.
const auto function_entry_points = FunctionEntryPoints(func->id());
referenced_entry_points.insert(function_entry_points.begin(),
function_entry_points.end());
} else {
// Instruction is in the global scope, keep searching its uses.
for (auto pair : current_inst->uses()) {
const auto next_inst = pair.first;
stack.push_back(next_inst);
}
}
}
return referenced_entry_points;
}
std::string ValidationState_t::Disassemble(const Instruction& inst) const {
const spv_parsed_instruction_t& c_inst(inst.c_inst());
return Disassemble(c_inst.words, c_inst.num_words);
}
std::string ValidationState_t::Disassemble(const uint32_t* words,
uint16_t num_words) const {
uint32_t disassembly_options = SPV_BINARY_TO_TEXT_OPTION_NO_HEADER |
SPV_BINARY_TO_TEXT_OPTION_FRIENDLY_NAMES;
return spvInstructionBinaryToText(context()->target_env, words, num_words,
words_, num_words_, disassembly_options);
}
} // namespace val
} // namespace spvtools