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// Copyright (c) 2019 Google LLC
//
// 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 <limits>
#include "source/fuzz/fact_manager.h"
#include "source/fuzz/uniform_buffer_element_descriptor.h"
#include "test/fuzz/fuzz_test_util.h"
namespace spvtools {
namespace fuzz {
namespace {
using opt::analysis::BoolConstant;
using opt::analysis::FloatConstant;
using opt::analysis::IntConstant;
using opt::analysis::ScalarConstant;
using opt::analysis::Bool;
using opt::analysis::Float;
using opt::analysis::Integer;
using opt::analysis::Type;
bool AddFactHelper(
FactManager* fact_manager, opt::IRContext* context,
std::vector<uint32_t>&& words,
const protobufs::UniformBufferElementDescriptor& descriptor) {
protobufs::FactConstantUniform constant_uniform_fact;
for (auto word : words) {
constant_uniform_fact.add_constant_word(word);
}
*constant_uniform_fact.mutable_uniform_buffer_element_descriptor() =
descriptor;
protobufs::Fact fact;
*fact.mutable_constant_uniform_fact() = constant_uniform_fact;
return fact_manager->AddFact(fact, context);
}
TEST(FactManagerTest, ConstantsAvailableViaUniforms) {
std::string shader = R"(
OpCapability Shader
OpCapability Int64
OpCapability Float64
%1 = OpExtInstImport "GLSL.std.450"
OpMemoryModel Logical GLSL450
OpEntryPoint Fragment %4 "main"
OpExecutionMode %4 OriginUpperLeft
OpSource GLSL 450
OpName %4 "main"
OpDecorate %100 DescriptorSet 0
OpDecorate %100 Binding 0
OpDecorate %200 DescriptorSet 0
OpDecorate %200 Binding 1
OpDecorate %300 DescriptorSet 0
OpDecorate %300 Binding 2
OpDecorate %400 DescriptorSet 0
OpDecorate %400 Binding 3
OpDecorate %500 DescriptorSet 0
OpDecorate %500 Binding 4
OpDecorate %600 DescriptorSet 0
OpDecorate %600 Binding 5
OpDecorate %700 DescriptorSet 0
OpDecorate %700 Binding 6
OpDecorate %800 DescriptorSet 1
OpDecorate %800 Binding 0
OpDecorate %900 DescriptorSet 1
OpDecorate %900 Binding 1
OpDecorate %1000 DescriptorSet 1
OpDecorate %1000 Binding 2
OpDecorate %1100 DescriptorSet 1
OpDecorate %1100 Binding 3
OpDecorate %1200 DescriptorSet 1
OpDecorate %1200 Binding 4
OpDecorate %1300 DescriptorSet 1
OpDecorate %1300 Binding 5
OpDecorate %1400 DescriptorSet 1
OpDecorate %1400 Binding 6
OpDecorate %1500 DescriptorSet 2
OpDecorate %1500 Binding 0
OpDecorate %1600 DescriptorSet 2
OpDecorate %1600 Binding 1
OpDecorate %1700 DescriptorSet 2
OpDecorate %1700 Binding 2
OpDecorate %1800 DescriptorSet 2
OpDecorate %1800 Binding 3
OpDecorate %1900 DescriptorSet 2
OpDecorate %1900 Binding 4
%2 = OpTypeVoid
%3 = OpTypeFunction %2
%10 = OpTypeInt 32 0
%11 = OpTypeInt 32 1
%12 = OpTypeInt 64 0
%13 = OpTypeInt 64 1
%15 = OpTypeFloat 32
%16 = OpTypeFloat 64
%17 = OpConstant %11 5
%18 = OpConstant %11 20
%19 = OpTypeVector %10 4
%20 = OpConstant %11 6
%21 = OpTypeVector %12 4
%22 = OpConstant %11 10
%23 = OpTypeVector %11 4
%102 = OpTypeStruct %10 %10 %23
%101 = OpTypePointer Uniform %102
%100 = OpVariable %101 Uniform
%203 = OpTypeArray %23 %17
%202 = OpTypeArray %203 %18
%201 = OpTypePointer Uniform %202
%200 = OpVariable %201 Uniform
%305 = OpTypeStruct %16 %16 %16 %11 %16
%304 = OpTypeStruct %16 %16 %305
%303 = OpTypeStruct %304
%302 = OpTypeStruct %10 %303
%301 = OpTypePointer Uniform %302
%300 = OpVariable %301 Uniform
%400 = OpVariable %101 Uniform
%500 = OpVariable %201 Uniform
%604 = OpTypeArray %13 %20
%603 = OpTypeArray %604 %20
%602 = OpTypeArray %603 %20
%601 = OpTypePointer Uniform %602
%600 = OpVariable %601 Uniform
%703 = OpTypeArray %13 %20
%702 = OpTypeArray %703 %20
%701 = OpTypePointer Uniform %702
%700 = OpVariable %701 Uniform
%802 = OpTypeStruct %702 %602 %19 %202 %302
%801 = OpTypePointer Uniform %802
%800 = OpVariable %801 Uniform
%902 = OpTypeStruct %702 %802 %19 %202 %302
%901 = OpTypePointer Uniform %902
%900 = OpVariable %901 Uniform
%1003 = OpTypeStruct %802
%1002 = OpTypeArray %1003 %20
%1001 = OpTypePointer Uniform %1002
%1000 = OpVariable %1001 Uniform
%1101 = OpTypePointer Uniform %21
%1100 = OpVariable %1101 Uniform
%1202 = OpTypeArray %21 %20
%1201 = OpTypePointer Uniform %1202
%1200 = OpVariable %1201 Uniform
%1302 = OpTypeArray %21 %20
%1301 = OpTypePointer Uniform %1302
%1300 = OpVariable %1301 Uniform
%1402 = OpTypeArray %15 %22
%1401 = OpTypePointer Uniform %1402
%1400 = OpVariable %1401 Uniform
%1501 = OpTypePointer Uniform %1402
%1500 = OpVariable %1501 Uniform
%1602 = OpTypeArray %1402 %22
%1601 = OpTypePointer Uniform %1602
%1600 = OpVariable %1601 Uniform
%1704 = OpTypeStruct %16 %16 %16
%1703 = OpTypeArray %1704 %22
%1702 = OpTypeArray %1703 %22
%1701 = OpTypePointer Uniform %1702
%1700 = OpVariable %1701 Uniform
%1800 = OpVariable %1701 Uniform
%1906 = OpTypeStruct %16
%1905 = OpTypeStruct %1906
%1904 = OpTypeStruct %1905
%1903 = OpTypeStruct %1904
%1902 = OpTypeStruct %1903
%1901 = OpTypePointer Uniform %1902
%1900 = OpVariable %1901 Uniform
%4 = OpFunction %2 None %3
%5 = OpLabel
OpReturn
OpFunctionEnd
)";
const auto env = SPV_ENV_UNIVERSAL_1_3;
const auto consumer = nullptr;
const auto context = BuildModule(env, consumer, shader, kFuzzAssembleOption);
ASSERT_TRUE(IsValid(env, context.get()));
uint32_t buffer_int32_min[1];
uint32_t buffer_int64_1[2];
uint32_t buffer_int64_max[2];
uint32_t buffer_uint64_1[2];
uint32_t buffer_uint64_max[2];
uint32_t buffer_float_10[1];
uint32_t buffer_double_10[2];
uint32_t buffer_double_20[2];
{
int32_t temp = std::numeric_limits<int32_t>::min();
std::memcpy(&buffer_int32_min, &temp, sizeof(temp));
}
{
int64_t temp = 1;
std::memcpy(&buffer_int64_1, &temp, sizeof(temp));
}
{
int64_t temp = std::numeric_limits<int64_t>::max();
std::memcpy(&buffer_int64_max, &temp, sizeof(temp));
}
{
uint64_t temp = 1;
std::memcpy(&buffer_uint64_1, &temp, sizeof(temp));
}
{
uint64_t temp = std::numeric_limits<uint64_t>::max();
std::memcpy(&buffer_uint64_max, &temp, sizeof(temp));
}
{
float temp = 10.0f;
std::memcpy(&buffer_float_10, &temp, sizeof(float));
}
{
double temp = 10.0;
std::memcpy(&buffer_double_10, &temp, sizeof(temp));
}
{
double temp = 20.0;
std::memcpy(&buffer_double_20, &temp, sizeof(temp));
}
FactManager fact_manager;
uint32_t type_int32_id = 11;
uint32_t type_int64_id = 13;
uint32_t type_uint32_id = 10;
uint32_t type_uint64_id = 12;
uint32_t type_float_id = 15;
uint32_t type_double_id = 16;
// Initially there should be no facts about uniforms.
ASSERT_TRUE(fact_manager
.GetConstantsAvailableFromUniformsForType(context.get(),
type_uint32_id)
.empty());
// In the comments that follow we write v[...][...] to refer to uniform
// variable v indexed with some given indices, when in practice v is
// identified via a (descriptor set, binding) pair.
// 100[2][3] == int(1)
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(), {1},
MakeUniformBufferElementDescriptor(0, 0, {2, 3})));
// 200[1][2][3] == int(1)
ASSERT_TRUE(
AddFactHelper(&fact_manager, context.get(), {1},
MakeUniformBufferElementDescriptor(0, 1, {1, 2, 3})));
// 300[1][0][2][3] == int(1)
ASSERT_TRUE(
AddFactHelper(&fact_manager, context.get(), {1},
MakeUniformBufferElementDescriptor(0, 2, {1, 0, 2, 3})));
// 400[2][3] = int32_min
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(), {buffer_int32_min[0]},
MakeUniformBufferElementDescriptor(0, 3, {2, 3})));
// 500[1][2][3] = int32_min
ASSERT_TRUE(
AddFactHelper(&fact_manager, context.get(), {buffer_int32_min[0]},
MakeUniformBufferElementDescriptor(0, 4, {1, 2, 3})));
// 600[1][2][3] = int64_max
ASSERT_TRUE(AddFactHelper(
&fact_manager, context.get(), {buffer_int64_max[0], buffer_int64_max[1]},
MakeUniformBufferElementDescriptor(0, 5, {1, 2, 3})));
// 700[1][1] = int64_max
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(),
{buffer_int64_max[0], buffer_int64_max[1]},
MakeUniformBufferElementDescriptor(0, 6, {1, 1})));
// 800[2][3] = uint(1)
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(), {1},
MakeUniformBufferElementDescriptor(1, 0, {2, 3})));
// 900[1][2][3] = uint(1)
ASSERT_TRUE(
AddFactHelper(&fact_manager, context.get(), {1},
MakeUniformBufferElementDescriptor(1, 1, {1, 2, 3})));
// 1000[1][0][2][3] = uint(1)
ASSERT_TRUE(
AddFactHelper(&fact_manager, context.get(), {1},
MakeUniformBufferElementDescriptor(1, 2, {1, 0, 2, 3})));
// 1100[0] = uint64(1)
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(),
{buffer_uint64_1[0], buffer_uint64_1[1]},
MakeUniformBufferElementDescriptor(1, 3, {0})));
// 1200[0][0] = uint64_max
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(),
{buffer_uint64_max[0], buffer_uint64_max[1]},
MakeUniformBufferElementDescriptor(1, 4, {0, 0})));
// 1300[1][0] = uint64_max
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(),
{buffer_uint64_max[0], buffer_uint64_max[1]},
MakeUniformBufferElementDescriptor(1, 5, {1, 0})));
// 1400[6] = float(10.0)
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(), {buffer_float_10[0]},
MakeUniformBufferElementDescriptor(1, 6, {6})));
// 1500[7] = float(10.0)
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(), {buffer_float_10[0]},
MakeUniformBufferElementDescriptor(2, 0, {7})));
// 1600[9][9] = float(10.0)
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(), {buffer_float_10[0]},
MakeUniformBufferElementDescriptor(2, 1, {9, 9})));
// 1700[9][9][1] = double(10.0)
ASSERT_TRUE(AddFactHelper(
&fact_manager, context.get(), {buffer_double_10[0], buffer_double_10[1]},
MakeUniformBufferElementDescriptor(2, 2, {9, 9, 1})));
// 1800[9][9][2] = double(10.0)
ASSERT_TRUE(AddFactHelper(
&fact_manager, context.get(), {buffer_double_10[0], buffer_double_10[1]},
MakeUniformBufferElementDescriptor(2, 3, {9, 9, 2})));
// 1900[0][0][0][0][0] = double(20.0)
ASSERT_TRUE(AddFactHelper(
&fact_manager, context.get(), {buffer_double_20[0], buffer_double_20[1]},
MakeUniformBufferElementDescriptor(2, 4, {0, 0, 0, 0, 0})));
opt::Instruction::OperandList operands = {
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {1}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_int32_id, 50, operands));
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_int32_min[0]}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_int32_id, 51, operands));
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_int64_max[0]}},
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_int64_max[1]}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_int64_id, 52, operands));
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {1}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_uint32_id, 53, operands));
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_uint64_1[0]}},
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_uint64_1[1]}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_uint64_id, 54, operands));
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_uint64_max[0]}},
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_uint64_max[1]}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_uint64_id, 55, operands));
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_float_10[0]}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_float_id, 56, operands));
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_double_10[0]}},
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_double_10[1]}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_double_id, 57, operands));
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_double_20[0]}},
{SPV_OPERAND_TYPE_LITERAL_INTEGER, {buffer_double_20[1]}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_double_id, 58, operands));
// A duplicate of the constant with id 59.
operands = {{SPV_OPERAND_TYPE_LITERAL_INTEGER, {1}}};
context->module()->AddGlobalValue(MakeUnique<opt::Instruction>(
context.get(), SpvOpConstant, type_int32_id, 59, operands));
context->InvalidateAnalysesExceptFor(opt::IRContext::Analysis::kAnalysisNone);
// Constants 1 and int32_min are available.
ASSERT_EQ(2, fact_manager
.GetConstantsAvailableFromUniformsForType(context.get(),
type_int32_id)
.size());
// Constant int64_max is available.
ASSERT_EQ(1, fact_manager
.GetConstantsAvailableFromUniformsForType(context.get(),
type_int64_id)
.size());
// Constant 1u is available.
ASSERT_EQ(1, fact_manager
.GetConstantsAvailableFromUniformsForType(context.get(),
type_uint32_id)
.size());
// Constants 1u and uint64_max are available.
ASSERT_EQ(2, fact_manager
.GetConstantsAvailableFromUniformsForType(context.get(),
type_uint64_id)
.size());
// Constant 10.0 is available.
ASSERT_EQ(1, fact_manager
.GetConstantsAvailableFromUniformsForType(context.get(),
type_float_id)
.size());
// Constants 10.0 and 20.0 are available.
ASSERT_EQ(2, fact_manager
.GetConstantsAvailableFromUniformsForType(context.get(),
type_double_id)
.size());
ASSERT_EQ(std::numeric_limits<int64_t>::max(),
context->get_constant_mgr()
->FindDeclaredConstant(
fact_manager.GetConstantsAvailableFromUniformsForType(
context.get(), type_int64_id)[0])
->AsIntConstant()
->GetS64());
ASSERT_EQ(1, context->get_constant_mgr()
->FindDeclaredConstant(
fact_manager.GetConstantsAvailableFromUniformsForType(
context.get(), type_uint32_id)[0])
->AsIntConstant()
->GetU32());
ASSERT_EQ(10.0f,
context->get_constant_mgr()
->FindDeclaredConstant(
fact_manager.GetConstantsAvailableFromUniformsForType(
context.get(), type_float_id)[0])
->AsFloatConstant()
->GetFloat());
const std::vector<uint32_t>& double_constant_ids =
fact_manager.GetConstantsAvailableFromUniformsForType(context.get(),
type_double_id);
ASSERT_EQ(10.0, context->get_constant_mgr()
->FindDeclaredConstant(double_constant_ids[0])
->AsFloatConstant()
->GetDouble());
ASSERT_EQ(20.0, context->get_constant_mgr()
->FindDeclaredConstant(double_constant_ids[1])
->AsFloatConstant()
->GetDouble());
const std::vector<protobufs::UniformBufferElementDescriptor>
descriptors_for_double_10 = fact_manager.GetUniformDescriptorsForConstant(
context.get(), double_constant_ids[0]);
ASSERT_EQ(2, descriptors_for_double_10.size());
{
auto temp = MakeUniformBufferElementDescriptor(2, 2, {9, 9, 1});
ASSERT_TRUE(UniformBufferElementDescriptorEquals()(
&temp, &descriptors_for_double_10[0]));
}
{
auto temp = MakeUniformBufferElementDescriptor(2, 3, {9, 9, 2});
ASSERT_TRUE(UniformBufferElementDescriptorEquals()(
&temp, &descriptors_for_double_10[1]));
}
const std::vector<protobufs::UniformBufferElementDescriptor>
descriptors_for_double_20 = fact_manager.GetUniformDescriptorsForConstant(
context.get(), double_constant_ids[1]);
ASSERT_EQ(1, descriptors_for_double_20.size());
{
auto temp = MakeUniformBufferElementDescriptor(2, 4, {0, 0, 0, 0, 0});
ASSERT_TRUE(UniformBufferElementDescriptorEquals()(
&temp, &descriptors_for_double_20[0]));
}
auto constant_1_id = fact_manager.GetConstantFromUniformDescriptor(
context.get(), MakeUniformBufferElementDescriptor(2, 3, {9, 9, 2}));
ASSERT_TRUE(constant_1_id);
auto constant_2_id = fact_manager.GetConstantFromUniformDescriptor(
context.get(), MakeUniformBufferElementDescriptor(2, 4, {0, 0, 0, 0, 0}));
ASSERT_TRUE(constant_2_id);
ASSERT_EQ(double_constant_ids[0], constant_1_id);
ASSERT_EQ(double_constant_ids[1], constant_2_id);
}
TEST(FactManagerTest, TwoConstantsWithSameValue) {
std::string shader = R"(
OpCapability Shader
%1 = OpExtInstImport "GLSL.std.450"
OpMemoryModel Logical GLSL450
OpEntryPoint Fragment %4 "main"
OpExecutionMode %4 OriginUpperLeft
OpSource ESSL 310
OpName %4 "main"
OpName %8 "x"
OpName %10 "buf"
OpMemberName %10 0 "a"
OpName %12 ""
OpDecorate %8 RelaxedPrecision
OpMemberDecorate %10 0 RelaxedPrecision
OpMemberDecorate %10 0 Offset 0
OpDecorate %10 Block
OpDecorate %12 DescriptorSet 0
OpDecorate %12 Binding 0
%2 = OpTypeVoid
%3 = OpTypeFunction %2
%6 = OpTypeInt 32 1
%7 = OpTypePointer Function %6
%9 = OpConstant %6 1
%20 = OpConstant %6 1
%10 = OpTypeStruct %6
%11 = OpTypePointer Uniform %10
%12 = OpVariable %11 Uniform
%4 = OpFunction %2 None %3
%5 = OpLabel
%8 = OpVariable %7 Function
OpStore %8 %9
OpReturn
OpFunctionEnd
)";
const auto env = SPV_ENV_UNIVERSAL_1_3;
const auto consumer = nullptr;
const auto context = BuildModule(env, consumer, shader, kFuzzAssembleOption);
ASSERT_TRUE(IsValid(env, context.get()));
FactManager fact_manager;
auto uniform_buffer_element_descriptor =
MakeUniformBufferElementDescriptor(0, 0, {0});
// (0, 0, [0]) = int(1)
ASSERT_TRUE(AddFactHelper(&fact_manager, context.get(), {1},
uniform_buffer_element_descriptor));
auto constants =
fact_manager.GetConstantsAvailableFromUniformsForType(context.get(), 6);
ASSERT_EQ(1, constants.size());
ASSERT_TRUE(constants[0] == 9 || constants[0] == 20);
auto constant = fact_manager.GetConstantFromUniformDescriptor(
context.get(), uniform_buffer_element_descriptor);
ASSERT_TRUE(constant == 9 || constant == 20);
// Because the constants with ids 9 and 20 are equal, we should get the same
// single uniform buffer element descriptor when we look up the descriptors
// for either one of them.
for (auto constant_id : {9u, 20u}) {
auto descriptors = fact_manager.GetUniformDescriptorsForConstant(
context.get(), constant_id);
ASSERT_EQ(1, descriptors.size());
ASSERT_TRUE(UniformBufferElementDescriptorEquals()(
&uniform_buffer_element_descriptor, &descriptors[0]));
}
}
TEST(FactManagerTest, NonFiniteFactsAreNotValid) {
std::string shader = R"(
OpCapability Shader
OpCapability Float64
%1 = OpExtInstImport "GLSL.std.450"
OpMemoryModel Logical GLSL450
OpEntryPoint Fragment %4 "main"
OpExecutionMode %4 OriginUpperLeft
OpSource ESSL 310
OpName %4 "main"
OpName %7 "buf"
OpMemberName %7 0 "f"
OpMemberName %7 1 "d"
OpName %9 ""
OpMemberDecorate %7 0 Offset 0
OpMemberDecorate %7 1 Offset 8
OpDecorate %7 Block
OpDecorate %9 DescriptorSet 0
OpDecorate %9 Binding 0
%2 = OpTypeVoid
%3 = OpTypeFunction %2
%6 = OpTypeFloat 32
%10 = OpTypeFloat 64
%7 = OpTypeStruct %6 %10
%8 = OpTypePointer Uniform %7
%9 = OpVariable %8 Uniform
%4 = OpFunction %2 None %3
%5 = OpLabel
OpReturn
OpFunctionEnd
)";
const auto env = SPV_ENV_UNIVERSAL_1_3;
const auto consumer = nullptr;
const auto context = BuildModule(env, consumer, shader, kFuzzAssembleOption);
ASSERT_TRUE(IsValid(env, context.get()));
FactManager fact_manager;
auto uniform_buffer_element_descriptor_f =
MakeUniformBufferElementDescriptor(0, 0, {0});
auto uniform_buffer_element_descriptor_d =
MakeUniformBufferElementDescriptor(0, 0, {1});
if (std::numeric_limits<float>::has_infinity) {
// f == +inf
float positive_infinity_float = std::numeric_limits<float>::infinity();
uint32_t words[1];
memcpy(words, &positive_infinity_float, sizeof(float));
ASSERT_FALSE(AddFactHelper(&fact_manager, context.get(), {words[0]},
uniform_buffer_element_descriptor_f));
// f == -inf
float negative_infinity_float = std::numeric_limits<float>::infinity();
memcpy(words, &negative_infinity_float, sizeof(float));
ASSERT_FALSE(AddFactHelper(&fact_manager, context.get(), {words[0]},
uniform_buffer_element_descriptor_f));
}
if (std::numeric_limits<float>::has_quiet_NaN) {
// f == NaN
float quiet_nan_float = std::numeric_limits<float>::quiet_NaN();
uint32_t words[1];
memcpy(words, &quiet_nan_float, sizeof(float));
ASSERT_FALSE(AddFactHelper(&fact_manager, context.get(), {words[0]},
uniform_buffer_element_descriptor_f));
}
if (std::numeric_limits<double>::has_infinity) {
// d == +inf
double positive_infinity_double = std::numeric_limits<double>::infinity();
uint32_t words[2];
memcpy(words, &positive_infinity_double, sizeof(double));
ASSERT_FALSE(AddFactHelper(&fact_manager, context.get(),
{words[0], words[1]},
uniform_buffer_element_descriptor_d));
// d == -inf
double negative_infinity_double = -std::numeric_limits<double>::infinity();
memcpy(words, &negative_infinity_double, sizeof(double));
ASSERT_FALSE(AddFactHelper(&fact_manager, context.get(),
{words[0], words[1]},
uniform_buffer_element_descriptor_d));
}
if (std::numeric_limits<double>::has_quiet_NaN) {
// d == NaN
double quiet_nan_double = std::numeric_limits<double>::quiet_NaN();
uint32_t words[2];
memcpy(words, &quiet_nan_double, sizeof(double));
ASSERT_FALSE(AddFactHelper(&fact_manager, context.get(),
{words[0], words[1]},
uniform_buffer_element_descriptor_d));
}
}
TEST(FactManagerTest, AmbiguousFact) {
// This test came from the following GLSL:
//
// #version 310 es
//
// precision highp float;
//
// layout(set = 0, binding = 0) uniform buf {
// float f;
// };
//
// layout(set = 0, binding = 0) uniform buf2 {
// float g;
// };
//
// void main() {
//
// }
std::string shader = R"(
OpCapability Shader
%1 = OpExtInstImport "GLSL.std.450"
OpMemoryModel Logical GLSL450
OpEntryPoint Fragment %4 "main"
OpExecutionMode %4 OriginUpperLeft
OpSource ESSL 310
OpName %4 "main"
OpName %7 "buf"
OpMemberName %7 0 "f"
OpName %9 ""
OpName %10 "buf2"
OpMemberName %10 0 "g"
OpName %12 ""
OpMemberDecorate %7 0 Offset 0
OpDecorate %7 Block
OpDecorate %9 DescriptorSet 0
OpDecorate %9 Binding 0
OpMemberDecorate %10 0 Offset 0
OpDecorate %10 Block
OpDecorate %12 DescriptorSet 0
OpDecorate %12 Binding 0
%2 = OpTypeVoid
%3 = OpTypeFunction %2
%6 = OpTypeFloat 32
%7 = OpTypeStruct %6
%8 = OpTypePointer Uniform %7
%9 = OpVariable %8 Uniform
%10 = OpTypeStruct %6
%11 = OpTypePointer Uniform %10
%12 = OpVariable %11 Uniform
%4 = OpFunction %2 None %3
%5 = OpLabel
OpReturn
OpFunctionEnd
)";
const auto env = SPV_ENV_UNIVERSAL_1_3;
const auto consumer = nullptr;
const auto context = BuildModule(env, consumer, shader, kFuzzAssembleOption);
ASSERT_TRUE(IsValid(env, context.get()));
FactManager fact_manager;
auto uniform_buffer_element_descriptor =
MakeUniformBufferElementDescriptor(0, 0, {0});
// The fact cannot be added because it is ambiguous: there are two uniforms
// with descriptor set 0 and binding 0.
ASSERT_FALSE(AddFactHelper(&fact_manager, context.get(), {1},
uniform_buffer_element_descriptor));
}
} // namespace
} // namespace fuzz
} // namespace spvtools