SPIRV-Tools/test/val/val_logicals_test.cpp
David Neto 63f57d95d6
Support SPIR-V 1.4 (#2550)
* SPIR-V 1.4 headers, add SPV_ENV_UNIVERSAL_1_4

* Support --target-env spv1.4 in help for command line tools

* Support asm/dis of UniformId decoration

* Validate UniformId decoration

* Fix version check on instructions and operands

Also register decorations used with OpDecorateId

* Extension lists can differ between enums that match

Example: SubgroupMaskEq vs SubgroupMaskEqKHR

* Validate scope value for Uniform decoration, for SPIR-V 1.4

* More unioning of exts

* Preserve grammar order within an enum value

* 1.4: Validate OpSelect over composites

* Tools default to 1.4

* Add asm/dis test for OpCopyLogical

* 1.4: asm/dis tests for PtrEqual, PtrNotEqual, PtrDiff

* Basic asm/Dis test for OpCopyMemory

* Test asm/dis OpCopyMemory with 2-memory access

Add asm/dis tests for OpCopyMemorySized

Requires grammar update to add second optional memory access operand
to OpCopyMemory and OpCopyMemorySized

* Validate one or two memory accesses on OpCopyMemory*

* Check av/vis on CopyMemory source and target memory access

This is a proposed rule. See
https://gitlab.khronos.org/spirv/SPIR-V/issues/413

* Validate operation for OpSpecConstantOp

* Validate NonWritable decoration

Also permit NonWritable on members of UBO and SSBO.

* SPIR-V 1.4: NonWrtiable can decorate Function and Private vars

* Update optimizer CLI tests for SPIR-V 1.4

* Testing tools: Give expected SPIR-V version in message

* SPIR-V 1.4 validation for entry point interfaces

* Allow only unique interfaces
* Allow all global variables
* Check that all statically used global variables are listed
* new tests

* Add validation fixture CompileFailure

* Add 1.4 validation for pointer comparisons

* New tests

* Validate with image operands SignExtend, ZeroExtend

Since we don't actually know the image texel format, we can't fully
validate.  We need more context.

But we can make sure we allow the new image operands in known-good
cases.

* Validate OpCopyLogical

* Recursively checks subtypes
* new tests

* Add SPIR-V 1.4 tests for NoSignedWrap, NoUnsignedWrap

* Allow scalar conditions in 1.4 with OpSelect

* Allows scalar conditions with vector operands
* new tests

* Validate uniform id scope as an execution scope

* Validate the values of memory and execution scopes are valid scope
values
* new test

* Remove SPIR-V 1.4 Vulkan 1.0 environment

* SPIR-V 1.4 requires Vulkan 1.1

* FIX: include string for spvLog

* FIX: validate nonwritable

* FIX: test case suite for member decorate string

* FIX: test case for hlsl functionality1

* Validation test fixture: ease debugging

* Use binary version for SPIR-V 1.4 specific features

* Switch checks based on the SPIR-V version from the target environment
to instead use the version from the binary
* Moved header parsing into the ValidationState_t constructor (where
version based features are set)
* Added new versions of tests that assemble a 1.3 binary and validate a
1.4 environment

* Fix test for update to SPIR-V 1.4 headers

* Fix formatting

* Ext inst lookup: Add Vulkan 1.1 env with SPIR-V 1.4

* Update spirv-val help

* Operand version checks should use module version

Use the module version instead of the target environment version.

* Fix comment about two-access form of OpCopyMemory
2019-05-07 12:27:18 -04:00

1165 lines
36 KiB
C++

// Copyright (c) 2017 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.
// Tests for unique type declaration rules validator.
#include <string>
#include "gmock/gmock.h"
#include "test/unit_spirv.h"
#include "test/val/val_fixtures.h"
namespace spvtools {
namespace val {
namespace {
using ::testing::Eq;
using ::testing::HasSubstr;
using ::testing::Not;
using ValidateLogicals = spvtest::ValidateBase<bool>;
std::string GenerateShaderCode(
const std::string& body,
const std::string& capabilities_and_extensions = "") {
const std::string capabilities =
R"(
OpCapability Shader
OpCapability Int64
OpCapability Float64)";
const std::string after_extension_before_body =
R"(
%ext_inst = OpExtInstImport "GLSL.std.450"
OpMemoryModel Logical GLSL450
OpEntryPoint Fragment %main "main"
OpExecutionMode %main OriginUpperLeft
%void = OpTypeVoid
%func = OpTypeFunction %void
%bool = OpTypeBool
%f32 = OpTypeFloat 32
%u32 = OpTypeInt 32 0
%s32 = OpTypeInt 32 1
%f64 = OpTypeFloat 64
%u64 = OpTypeInt 64 0
%s64 = OpTypeInt 64 1
%boolvec2 = OpTypeVector %bool 2
%s32vec2 = OpTypeVector %s32 2
%u32vec2 = OpTypeVector %u32 2
%u64vec2 = OpTypeVector %u64 2
%f32vec2 = OpTypeVector %f32 2
%f64vec2 = OpTypeVector %f64 2
%boolvec3 = OpTypeVector %bool 3
%u32vec3 = OpTypeVector %u32 3
%u64vec3 = OpTypeVector %u64 3
%s32vec3 = OpTypeVector %s32 3
%f32vec3 = OpTypeVector %f32 3
%f64vec3 = OpTypeVector %f64 3
%boolvec4 = OpTypeVector %bool 4
%u32vec4 = OpTypeVector %u32 4
%u64vec4 = OpTypeVector %u64 4
%s32vec4 = OpTypeVector %s32 4
%f32vec4 = OpTypeVector %f32 4
%f64vec4 = OpTypeVector %f64 4
%f32_0 = OpConstant %f32 0
%f32_1 = OpConstant %f32 1
%f32_2 = OpConstant %f32 2
%f32_3 = OpConstant %f32 3
%f32_4 = OpConstant %f32 4
%s32_0 = OpConstant %s32 0
%s32_1 = OpConstant %s32 1
%s32_2 = OpConstant %s32 2
%s32_3 = OpConstant %s32 3
%s32_4 = OpConstant %s32 4
%s32_m1 = OpConstant %s32 -1
%u32_0 = OpConstant %u32 0
%u32_1 = OpConstant %u32 1
%u32_2 = OpConstant %u32 2
%u32_3 = OpConstant %u32 3
%u32_4 = OpConstant %u32 4
%f64_0 = OpConstant %f64 0
%f64_1 = OpConstant %f64 1
%f64_2 = OpConstant %f64 2
%f64_3 = OpConstant %f64 3
%f64_4 = OpConstant %f64 4
%s64_0 = OpConstant %s64 0
%s64_1 = OpConstant %s64 1
%s64_2 = OpConstant %s64 2
%s64_3 = OpConstant %s64 3
%s64_4 = OpConstant %s64 4
%s64_m1 = OpConstant %s64 -1
%u64_0 = OpConstant %u64 0
%u64_1 = OpConstant %u64 1
%u64_2 = OpConstant %u64 2
%u64_3 = OpConstant %u64 3
%u64_4 = OpConstant %u64 4
%u32vec2_01 = OpConstantComposite %u32vec2 %u32_0 %u32_1
%u32vec2_12 = OpConstantComposite %u32vec2 %u32_1 %u32_2
%u32vec3_012 = OpConstantComposite %u32vec3 %u32_0 %u32_1 %u32_2
%u32vec3_123 = OpConstantComposite %u32vec3 %u32_1 %u32_2 %u32_3
%u32vec4_0123 = OpConstantComposite %u32vec4 %u32_0 %u32_1 %u32_2 %u32_3
%u32vec4_1234 = OpConstantComposite %u32vec4 %u32_1 %u32_2 %u32_3 %u32_4
%s32vec2_01 = OpConstantComposite %s32vec2 %s32_0 %s32_1
%s32vec2_12 = OpConstantComposite %s32vec2 %s32_1 %s32_2
%s32vec3_012 = OpConstantComposite %s32vec3 %s32_0 %s32_1 %s32_2
%s32vec3_123 = OpConstantComposite %s32vec3 %s32_1 %s32_2 %s32_3
%s32vec4_0123 = OpConstantComposite %s32vec4 %s32_0 %s32_1 %s32_2 %s32_3
%s32vec4_1234 = OpConstantComposite %s32vec4 %s32_1 %s32_2 %s32_3 %s32_4
%f32vec2_01 = OpConstantComposite %f32vec2 %f32_0 %f32_1
%f32vec2_12 = OpConstantComposite %f32vec2 %f32_1 %f32_2
%f32vec3_012 = OpConstantComposite %f32vec3 %f32_0 %f32_1 %f32_2
%f32vec3_123 = OpConstantComposite %f32vec3 %f32_1 %f32_2 %f32_3
%f32vec4_0123 = OpConstantComposite %f32vec4 %f32_0 %f32_1 %f32_2 %f32_3
%f32vec4_1234 = OpConstantComposite %f32vec4 %f32_1 %f32_2 %f32_3 %f32_4
%f64vec2_01 = OpConstantComposite %f64vec2 %f64_0 %f64_1
%f64vec2_12 = OpConstantComposite %f64vec2 %f64_1 %f64_2
%f64vec3_012 = OpConstantComposite %f64vec3 %f64_0 %f64_1 %f64_2
%f64vec3_123 = OpConstantComposite %f64vec3 %f64_1 %f64_2 %f64_3
%f64vec4_0123 = OpConstantComposite %f64vec4 %f64_0 %f64_1 %f64_2 %f64_3
%f64vec4_1234 = OpConstantComposite %f64vec4 %f64_1 %f64_2 %f64_3 %f64_4
%true = OpConstantTrue %bool
%false = OpConstantFalse %bool
%boolvec2_tf = OpConstantComposite %boolvec2 %true %false
%boolvec3_tft = OpConstantComposite %boolvec3 %true %false %true
%boolvec4_tftf = OpConstantComposite %boolvec4 %true %false %true %false
%arr_u32_2 = OpTypeArray %u32 %u32_2
%st_u32_u32 = OpTypeStruct %u32 %u32
%mat_f32_2_2 = OpTypeMatrix %f32vec2 2
%nul_arr_u32_2 = OpConstantNull %arr_u32_2
%nul_st_u32_u32 = OpConstantNull %st_u32_u32
%nul_mat_f32_2_2 = OpConstantNull %mat_f32_2_2
%arr_u32_2_1_2 = OpConstantComposite %arr_u32_2 %u32_1 %u32_2
%st_u32_u32_1_2 = OpConstantComposite %st_u32_u32 %u32_1 %u32_2
%mat_f32_2_2_01_12 = OpConstantComposite %mat_f32_2_2 %f32vec2_01 %f32vec2_12
%f32vec4ptr = OpTypePointer Function %f32vec4
%main = OpFunction %void None %func
%main_entry = OpLabel)";
const std::string after_body =
R"(
OpReturn
OpFunctionEnd)";
return capabilities + capabilities_and_extensions +
after_extension_before_body + body + after_body;
}
std::string GenerateKernelCode(
const std::string& body,
const std::string& capabilities_and_extensions = "") {
const std::string capabilities =
R"(
OpCapability Addresses
OpCapability Kernel
OpCapability Linkage
OpCapability Int64
OpCapability Float64)";
const std::string after_extension_before_body =
R"(
OpMemoryModel Physical32 OpenCL
%void = OpTypeVoid
%func = OpTypeFunction %void
%bool = OpTypeBool
%f32 = OpTypeFloat 32
%u32 = OpTypeInt 32 0
%f64 = OpTypeFloat 64
%u64 = OpTypeInt 64 0
%boolvec2 = OpTypeVector %bool 2
%u32vec2 = OpTypeVector %u32 2
%u64vec2 = OpTypeVector %u64 2
%f32vec2 = OpTypeVector %f32 2
%f64vec2 = OpTypeVector %f64 2
%boolvec3 = OpTypeVector %bool 3
%u32vec3 = OpTypeVector %u32 3
%u64vec3 = OpTypeVector %u64 3
%f32vec3 = OpTypeVector %f32 3
%f64vec3 = OpTypeVector %f64 3
%boolvec4 = OpTypeVector %bool 4
%u32vec4 = OpTypeVector %u32 4
%u64vec4 = OpTypeVector %u64 4
%f32vec4 = OpTypeVector %f32 4
%f64vec4 = OpTypeVector %f64 4
%f32_0 = OpConstant %f32 0
%f32_1 = OpConstant %f32 1
%f32_2 = OpConstant %f32 2
%f32_3 = OpConstant %f32 3
%f32_4 = OpConstant %f32 4
%u32_0 = OpConstant %u32 0
%u32_1 = OpConstant %u32 1
%u32_2 = OpConstant %u32 2
%u32_3 = OpConstant %u32 3
%u32_4 = OpConstant %u32 4
%f64_0 = OpConstant %f64 0
%f64_1 = OpConstant %f64 1
%f64_2 = OpConstant %f64 2
%f64_3 = OpConstant %f64 3
%f64_4 = OpConstant %f64 4
%u64_0 = OpConstant %u64 0
%u64_1 = OpConstant %u64 1
%u64_2 = OpConstant %u64 2
%u64_3 = OpConstant %u64 3
%u64_4 = OpConstant %u64 4
%u32vec2_01 = OpConstantComposite %u32vec2 %u32_0 %u32_1
%u32vec2_12 = OpConstantComposite %u32vec2 %u32_1 %u32_2
%u32vec3_012 = OpConstantComposite %u32vec3 %u32_0 %u32_1 %u32_2
%u32vec3_123 = OpConstantComposite %u32vec3 %u32_1 %u32_2 %u32_3
%u32vec4_0123 = OpConstantComposite %u32vec4 %u32_0 %u32_1 %u32_2 %u32_3
%u32vec4_1234 = OpConstantComposite %u32vec4 %u32_1 %u32_2 %u32_3 %u32_4
%f32vec2_01 = OpConstantComposite %f32vec2 %f32_0 %f32_1
%f32vec2_12 = OpConstantComposite %f32vec2 %f32_1 %f32_2
%f32vec3_012 = OpConstantComposite %f32vec3 %f32_0 %f32_1 %f32_2
%f32vec3_123 = OpConstantComposite %f32vec3 %f32_1 %f32_2 %f32_3
%f32vec4_0123 = OpConstantComposite %f32vec4 %f32_0 %f32_1 %f32_2 %f32_3
%f32vec4_1234 = OpConstantComposite %f32vec4 %f32_1 %f32_2 %f32_3 %f32_4
%f64vec2_01 = OpConstantComposite %f64vec2 %f64_0 %f64_1
%f64vec2_12 = OpConstantComposite %f64vec2 %f64_1 %f64_2
%f64vec3_012 = OpConstantComposite %f64vec3 %f64_0 %f64_1 %f64_2
%f64vec3_123 = OpConstantComposite %f64vec3 %f64_1 %f64_2 %f64_3
%f64vec4_0123 = OpConstantComposite %f64vec4 %f64_0 %f64_1 %f64_2 %f64_3
%f64vec4_1234 = OpConstantComposite %f64vec4 %f64_1 %f64_2 %f64_3 %f64_4
%true = OpConstantTrue %bool
%false = OpConstantFalse %bool
%boolvec2_tf = OpConstantComposite %boolvec2 %true %false
%boolvec3_tft = OpConstantComposite %boolvec3 %true %false %true
%boolvec4_tftf = OpConstantComposite %boolvec4 %true %false %true %false
%f32vec4ptr = OpTypePointer Function %f32vec4
%main = OpFunction %void None %func
%main_entry = OpLabel)";
const std::string after_body =
R"(
OpReturn
OpFunctionEnd)";
return capabilities + capabilities_and_extensions +
after_extension_before_body + body + after_body;
}
TEST_F(ValidateLogicals, OpAnySuccess) {
const std::string body = R"(
%val1 = OpAny %bool %boolvec2_tf
%val2 = OpAny %bool %boolvec3_tft
%val3 = OpAny %bool %boolvec4_tftf
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpAnyWrongTypeId) {
const std::string body = R"(
%val = OpAny %u32 %boolvec2_tf
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected bool scalar type as Result Type: Any"));
}
TEST_F(ValidateLogicals, OpAnyWrongOperand) {
const std::string body = R"(
%val = OpAny %bool %u32vec3_123
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected operand to be vector bool: Any"));
}
TEST_F(ValidateLogicals, OpIsNanSuccess) {
const std::string body = R"(
%val1 = OpIsNan %bool %f32_1
%val2 = OpIsNan %bool %f64_0
%val3 = OpIsNan %boolvec2 %f32vec2_12
%val4 = OpIsNan %boolvec3 %f32vec3_123
%val5 = OpIsNan %boolvec4 %f32vec4_1234
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpIsNanWrongTypeId) {
const std::string body = R"(
%val1 = OpIsNan %u32 %f32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected bool scalar or vector type as Result Type: IsNan"));
}
TEST_F(ValidateLogicals, OpIsNanOperandNotFloat) {
const std::string body = R"(
%val1 = OpIsNan %bool %u32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected operand to be scalar or vector float: IsNan"));
}
TEST_F(ValidateLogicals, OpIsNanOperandWrongSize) {
const std::string body = R"(
%val1 = OpIsNan %bool %f32vec2_12
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected vector sizes of Result Type and the operand to be equal: "
"IsNan"));
}
TEST_F(ValidateLogicals, OpLessOrGreaterSuccess) {
const std::string body = R"(
%val1 = OpLessOrGreater %bool %f32_0 %f32_1
%val2 = OpLessOrGreater %bool %f64_0 %f64_0
%val3 = OpLessOrGreater %boolvec2 %f32vec2_12 %f32vec2_12
%val4 = OpLessOrGreater %boolvec3 %f32vec3_123 %f32vec3_123
%val5 = OpLessOrGreater %boolvec4 %f32vec4_1234 %f32vec4_1234
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpLessOrGreaterWrongTypeId) {
const std::string body = R"(
%val1 = OpLessOrGreater %u32 %f32_1 %f32_1
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected bool scalar or vector type as Result Type: LessOrGreater"));
}
TEST_F(ValidateLogicals, OpLessOrGreaterLeftOperandNotFloat) {
const std::string body = R"(
%val1 = OpLessOrGreater %bool %u32_1 %f32_1
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected operands to be scalar or vector float: LessOrGreater"));
}
TEST_F(ValidateLogicals, OpLessOrGreaterLeftOperandWrongSize) {
const std::string body = R"(
%val1 = OpLessOrGreater %bool %f32vec2_12 %f32_1
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected vector sizes of Result Type and the operands to be equal: "
"LessOrGreater"));
}
TEST_F(ValidateLogicals, OpLessOrGreaterOperandsDifferentType) {
const std::string body = R"(
%val1 = OpLessOrGreater %bool %f32_1 %f64_1
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected left and right operands to have the same type: "
"LessOrGreater"));
}
TEST_F(ValidateLogicals, OpFOrdEqualSuccess) {
const std::string body = R"(
%val1 = OpFOrdEqual %bool %f32_0 %f32_1
%val2 = OpFOrdEqual %bool %f64_0 %f64_0
%val3 = OpFOrdEqual %boolvec2 %f32vec2_12 %f32vec2_12
%val4 = OpFOrdEqual %boolvec3 %f32vec3_123 %f32vec3_123
%val5 = OpFOrdEqual %boolvec4 %f32vec4_1234 %f32vec4_1234
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpFOrdEqualWrongTypeId) {
const std::string body = R"(
%val1 = OpFOrdEqual %u32 %f32_1 %f32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected bool scalar or vector type as Result Type: FOrdEqual"));
}
TEST_F(ValidateLogicals, OpFOrdEqualLeftOperandNotFloat) {
const std::string body = R"(
%val1 = OpFOrdEqual %bool %u32_1 %f32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected operands to be scalar or vector float: FOrdEqual"));
}
TEST_F(ValidateLogicals, OpFOrdEqualLeftOperandWrongSize) {
const std::string body = R"(
%val1 = OpFOrdEqual %bool %f32vec2_12 %f32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected vector sizes of Result Type and the operands to be equal: "
"FOrdEqual"));
}
TEST_F(ValidateLogicals, OpFOrdEqualOperandsDifferentType) {
const std::string body = R"(
%val1 = OpFOrdEqual %bool %f32_1 %f64_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected left and right operands to have the same type: "
"FOrdEqual"));
}
TEST_F(ValidateLogicals, OpLogicalEqualSuccess) {
const std::string body = R"(
%val1 = OpLogicalEqual %bool %true %false
%val2 = OpLogicalEqual %boolvec2 %boolvec2_tf %boolvec2_tf
%val3 = OpLogicalEqual %boolvec3 %boolvec3_tft %boolvec3_tft
%val4 = OpLogicalEqual %boolvec4 %boolvec4_tftf %boolvec4_tftf
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpLogicalEqualWrongTypeId) {
const std::string body = R"(
%val1 = OpLogicalEqual %u32 %true %false
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected bool scalar or vector type as Result Type: LogicalEqual"));
}
TEST_F(ValidateLogicals, OpLogicalEqualWrongLeftOperand) {
const std::string body = R"(
%val1 = OpLogicalEqual %bool %boolvec2_tf %false
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected both operands to be of Result Type: LogicalEqual"));
}
TEST_F(ValidateLogicals, OpLogicalEqualWrongRightOperand) {
const std::string body = R"(
%val1 = OpLogicalEqual %boolvec2 %boolvec2_tf %false
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected both operands to be of Result Type: LogicalEqual"));
}
TEST_F(ValidateLogicals, OpLogicalNotSuccess) {
const std::string body = R"(
%val1 = OpLogicalNot %bool %true
%val2 = OpLogicalNot %boolvec2 %boolvec2_tf
%val3 = OpLogicalNot %boolvec3 %boolvec3_tft
%val4 = OpLogicalNot %boolvec4 %boolvec4_tftf
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpLogicalNotWrongTypeId) {
const std::string body = R"(
%val1 = OpLogicalNot %u32 %true
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected bool scalar or vector type as Result Type: LogicalNot"));
}
TEST_F(ValidateLogicals, OpLogicalNotWrongOperand) {
const std::string body = R"(
%val1 = OpLogicalNot %bool %boolvec2_tf
)";
CompileSuccessfully(GenerateKernelCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected operand to be of Result Type: LogicalNot"));
}
TEST_F(ValidateLogicals, OpSelectSuccess) {
const std::string body = R"(
%val1 = OpSelect %u32 %true %u32_0 %u32_1
%val2 = OpSelect %f32 %true %f32_0 %f32_1
%val3 = OpSelect %f64 %true %f64_0 %f64_1
%val4 = OpSelect %f32vec2 %boolvec2_tf %f32vec2_01 %f32vec2_12
%val5 = OpSelect %f32vec4 %boolvec4_tftf %f32vec4_0123 %f32vec4_1234
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpSelectWrongTypeId) {
const std::string body = R"(
%val1 = OpSelect %void %true %u32_0 %u32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected scalar or vector type as Result Type: Select"));
}
TEST_F(ValidateLogicals, OpSelectWrongTypeIdV14) {
// In 1.4, the message changes to allow composites.
const std::string body = R"(
%val1 = OpSelect %void %true %u32_0 %u32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str(), SPV_ENV_UNIVERSAL_1_4);
ASSERT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected scalar or composite type as Result Type: Select"));
}
TEST_F(ValidateLogicals, OpSelectPointerNoCapability) {
const std::string body = R"(
%x = OpVariable %f32vec4ptr Function
%y = OpVariable %f32vec4ptr Function
OpStore %x %f32vec4_0123
OpStore %y %f32vec4_1234
%val1 = OpSelect %f32vec4ptr %true %x %y
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Using pointers with OpSelect requires capability VariablePointers "
"or VariablePointersStorageBuffer"));
}
TEST_F(ValidateLogicals, OpSelectPointerWithCapability1) {
const std::string body = R"(
%x = OpVariable %f32vec4ptr Function
%y = OpVariable %f32vec4ptr Function
OpStore %x %f32vec4_0123
OpStore %y %f32vec4_1234
%val1 = OpSelect %f32vec4ptr %true %x %y
)";
const std::string extra_cap_ext = R"(
OpCapability VariablePointers
OpExtension "SPV_KHR_variable_pointers"
)";
CompileSuccessfully(GenerateShaderCode(body, extra_cap_ext).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpSelectPointerWithCapability2) {
const std::string body = R"(
%x = OpVariable %f32vec4ptr Function
%y = OpVariable %f32vec4ptr Function
OpStore %x %f32vec4_0123
OpStore %y %f32vec4_1234
%val1 = OpSelect %f32vec4ptr %true %x %y
)";
const std::string extra_cap_ext = R"(
OpCapability VariablePointersStorageBuffer
OpExtension "SPV_KHR_variable_pointers"
)";
CompileSuccessfully(GenerateShaderCode(body, extra_cap_ext).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpSelectWrongCondition) {
const std::string body = R"(
%val1 = OpSelect %u32 %u32_1 %u32_0 %u32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected bool scalar or vector type as condition: Select"));
}
TEST_F(ValidateLogicals, OpSelectWrongConditionDimension) {
const std::string body = R"(
%val1 = OpSelect %u32vec2 %true %u32vec2_01 %u32vec2_12
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected vector sizes of Result Type and the condition to be equal: "
"Select"));
}
TEST_F(ValidateLogicals, OpSelectWrongLeftObject) {
const std::string body = R"(
%val1 = OpSelect %bool %true %u32vec2_01 %u32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected both objects to be of Result Type: Select"));
}
TEST_F(ValidateLogicals, OpSelectWrongRightObject) {
const std::string body = R"(
%val1 = OpSelect %bool %true %u32_1 %u32vec2_01
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected both objects to be of Result Type: Select"));
}
TEST_F(ValidateLogicals, OpSelectArrayV13Bad) {
const std::string body = R"(
%val1 = OpSelect %arr_u32_2 %true %nul_arr_u32_2 %arr_u32_2_1_2
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_3));
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected scalar or vector type as Result Type: Select"));
}
TEST_F(ValidateLogicals, OpSelectArrayV13TargetV14Bad) {
const std::string body = R"(
%val1 = OpSelect %arr_u32_2 %true %nul_arr_u32_2 %arr_u32_2_1_2
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected scalar or vector type as Result Type"));
}
TEST_F(ValidateLogicals, OpSelectArrayV14Good) {
const std::string body = R"(
%val1 = OpSelect %arr_u32_2 %true %nul_arr_u32_2 %arr_u32_2_1_2
)";
CompileSuccessfully(GenerateShaderCode(body).c_str(), SPV_ENV_UNIVERSAL_1_4);
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
EXPECT_THAT(getDiagnosticString(), Eq(""));
}
TEST_F(ValidateLogicals, OpSelectStructV13Bad) {
const std::string body = R"(
%val1 = OpSelect %st_u32_u32 %true %nul_st_u32_u32 %st_u32_u32_1_2
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_3));
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected scalar or vector type as Result Type: Select"));
}
TEST_F(ValidateLogicals, OpSelectStructV13TargetV14Bad) {
const std::string body = R"(
%val1 = OpSelect %st_u32_u32 %true %nul_st_u32_u32 %st_u32_u32_1_2
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected scalar or vector type as Result Type"));
}
TEST_F(ValidateLogicals, OpSelectStructV14Good) {
const std::string body = R"(
%val1 = OpSelect %st_u32_u32 %true %nul_st_u32_u32 %st_u32_u32_1_2
)";
CompileSuccessfully(GenerateShaderCode(body).c_str(), SPV_ENV_UNIVERSAL_1_4);
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
EXPECT_THAT(getDiagnosticString(), Eq(""));
}
TEST_F(ValidateLogicals, OpSelectMatrixV13Bad) {
const std::string body = R"(
%val1 = OpSelect %mat_f32_2_2 %true %nul_mat_f32_2_2 %mat_f32_2_2_01_12
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_3));
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected scalar or vector type as Result Type: Select"));
}
TEST_F(ValidateLogicals, OpSelectMatrixV13TargetV14Bad) {
const std::string body = R"(
%val1 = OpSelect %mat_f32_2_2 %true %nul_mat_f32_2_2 %mat_f32_2_2_01_12
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected scalar or vector type as Result Type"));
}
TEST_F(ValidateLogicals, OpSelectMatrixV14Good) {
const std::string body = R"(
%val1 = OpSelect %mat_f32_2_2 %true %nul_mat_f32_2_2 %mat_f32_2_2_01_12
)";
CompileSuccessfully(GenerateShaderCode(body).c_str(), SPV_ENV_UNIVERSAL_1_4);
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
EXPECT_THAT(getDiagnosticString(), Eq(""));
}
TEST_F(ValidateLogicals, OpIEqualSuccess) {
const std::string body = R"(
%val1 = OpIEqual %bool %u32_0 %s32_1
%val2 = OpIEqual %bool %s64_0 %u64_0
%val3 = OpIEqual %boolvec2 %s32vec2_12 %u32vec2_12
%val4 = OpIEqual %boolvec3 %s32vec3_123 %u32vec3_123
%val5 = OpIEqual %boolvec4 %s32vec4_1234 %u32vec4_1234
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpIEqualWrongTypeId) {
const std::string body = R"(
%val1 = OpIEqual %u32 %s32_1 %s32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected bool scalar or vector type as Result Type: IEqual"));
}
TEST_F(ValidateLogicals, OpIEqualLeftOperandNotInt) {
const std::string body = R"(
%val1 = OpIEqual %bool %f32_1 %s32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected operands to be scalar or vector int: IEqual"));
}
TEST_F(ValidateLogicals, OpIEqualLeftOperandWrongSize) {
const std::string body = R"(
%val1 = OpIEqual %bool %s32vec2_12 %s32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected vector sizes of Result Type and the operands to be equal: "
"IEqual"));
}
TEST_F(ValidateLogicals, OpIEqualRightOperandNotInt) {
const std::string body = R"(
%val1 = OpIEqual %bool %u32_1 %f32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected operands to be scalar or vector int: IEqual"));
}
TEST_F(ValidateLogicals, OpIEqualDifferentBitWidth) {
const std::string body = R"(
%val1 = OpIEqual %bool %u32_1 %u64_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected both operands to have the same component bit "
"width: IEqual"));
}
TEST_F(ValidateLogicals, OpUGreaterThanSuccess) {
const std::string body = R"(
%val1 = OpUGreaterThan %bool %u32_0 %u32_1
%val2 = OpUGreaterThan %bool %s32_0 %u32_1
%val3 = OpUGreaterThan %bool %u64_0 %u64_0
%val4 = OpUGreaterThan %bool %u64_0 %s64_0
%val5 = OpUGreaterThan %boolvec2 %u32vec2_12 %u32vec2_12
%val6 = OpUGreaterThan %boolvec3 %s32vec3_123 %u32vec3_123
%val7 = OpUGreaterThan %boolvec4 %u32vec4_1234 %u32vec4_1234
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpUGreaterThanWrongTypeId) {
const std::string body = R"(
%val1 = OpUGreaterThan %u32 %u32_1 %u32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected bool scalar or vector type as Result Type: UGreaterThan"));
}
TEST_F(ValidateLogicals, OpUGreaterThanLeftOperandNotInt) {
const std::string body = R"(
%val1 = OpUGreaterThan %bool %f32_1 %u32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected operands to be scalar or vector int: UGreaterThan"));
}
TEST_F(ValidateLogicals, OpUGreaterThanLeftOperandWrongSize) {
const std::string body = R"(
%val1 = OpUGreaterThan %bool %u32vec2_12 %u32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected vector sizes of Result Type and the operands to be equal: "
"UGreaterThan"));
}
TEST_F(ValidateLogicals, OpUGreaterThanRightOperandNotInt) {
const std::string body = R"(
%val1 = OpUGreaterThan %bool %u32_1 %f32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected operands to be scalar or vector int: UGreaterThan"));
}
TEST_F(ValidateLogicals, OpUGreaterThanDifferentBitWidth) {
const std::string body = R"(
%val1 = OpUGreaterThan %bool %u32_1 %u64_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected both operands to have the same component bit width: "
"UGreaterThan"));
}
TEST_F(ValidateLogicals, OpSGreaterThanSuccess) {
const std::string body = R"(
%val1 = OpSGreaterThan %bool %s32_0 %s32_1
%val2 = OpSGreaterThan %bool %u32_0 %s32_1
%val3 = OpSGreaterThan %bool %s64_0 %s64_0
%val4 = OpSGreaterThan %bool %s64_0 %u64_0
%val5 = OpSGreaterThan %boolvec2 %s32vec2_12 %s32vec2_12
%val6 = OpSGreaterThan %boolvec3 %s32vec3_123 %u32vec3_123
%val7 = OpSGreaterThan %boolvec4 %s32vec4_1234 %s32vec4_1234
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, OpSGreaterThanWrongTypeId) {
const std::string body = R"(
%val1 = OpSGreaterThan %s32 %s32_1 %s32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected bool scalar or vector type as Result Type: SGreaterThan"));
}
TEST_F(ValidateLogicals, OpSGreaterThanLeftOperandNotInt) {
const std::string body = R"(
%val1 = OpSGreaterThan %bool %f32_1 %s32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected operands to be scalar or vector int: SGreaterThan"));
}
TEST_F(ValidateLogicals, OpSGreaterThanLeftOperandWrongSize) {
const std::string body = R"(
%val1 = OpSGreaterThan %bool %s32vec2_12 %s32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr(
"Expected vector sizes of Result Type and the operands to be equal: "
"SGreaterThan"));
}
TEST_F(ValidateLogicals, OpSGreaterThanRightOperandNotInt) {
const std::string body = R"(
%val1 = OpSGreaterThan %bool %s32_1 %f32_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(
getDiagnosticString(),
HasSubstr("Expected operands to be scalar or vector int: SGreaterThan"));
}
TEST_F(ValidateLogicals, OpSGreaterThanDifferentBitWidth) {
const std::string body = R"(
%val1 = OpSGreaterThan %bool %s32_1 %s64_1
)";
CompileSuccessfully(GenerateShaderCode(body).c_str());
ASSERT_EQ(SPV_ERROR_INVALID_DATA, ValidateInstructions());
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected both operands to have the same component bit "
"width: SGreaterThan"));
}
TEST_F(ValidateLogicals, PSBSelectSuccess) {
const std::string body = R"(
OpCapability PhysicalStorageBufferAddressesEXT
OpCapability Int64
OpCapability Shader
OpExtension "SPV_EXT_physical_storage_buffer"
OpMemoryModel PhysicalStorageBuffer64EXT GLSL450
OpEntryPoint Fragment %main "main"
OpExecutionMode %main OriginUpperLeft
OpDecorate %val1 AliasedPointerEXT
%uint64 = OpTypeInt 64 0
%bool = OpTypeBool
%true = OpConstantTrue %bool
%ptr = OpTypePointer PhysicalStorageBufferEXT %uint64
%pptr_f = OpTypePointer Function %ptr
%void = OpTypeVoid
%voidfn = OpTypeFunction %void
%main = OpFunction %void None %voidfn
%entry = OpLabel
%val1 = OpVariable %pptr_f Function
%val2 = OpLoad %ptr %val1
%val3 = OpSelect %ptr %true %val2 %val2
OpReturn
OpFunctionEnd
)";
CompileSuccessfully(body.c_str());
ASSERT_EQ(SPV_SUCCESS, ValidateInstructions());
}
TEST_F(ValidateLogicals, SelectVectorsScalarCondition) {
const std::string spirv = R"(
OpCapability Shader
OpCapability Linkage
OpMemoryModel Logical GLSL450
%void = OpTypeVoid
%bool = OpTypeBool
%int = OpTypeInt 32 0
%int4 = OpTypeVector %int 4
%int4_0 = OpConstantNull %int4
%true = OpConstantTrue %bool
%void_fn = OpTypeFunction %void
%func = OpFunction %void None %void_fn
%1 = OpLabel
%select = OpSelect %int4 %true %int4_0 %int4_0
OpReturn
OpFunctionEnd
)";
CompileSuccessfully(spirv, SPV_ENV_UNIVERSAL_1_3);
EXPECT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_3));
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected vector sizes of Result Type and the "
"condition to be equal: Select"));
}
TEST_F(ValidateLogicals, SelectVectorsScalarCondition1p4) {
const std::string spirv = R"(
OpCapability Shader
OpCapability Linkage
OpMemoryModel Logical GLSL450
%void = OpTypeVoid
%bool = OpTypeBool
%int = OpTypeInt 32 0
%int4 = OpTypeVector %int 4
%int4_0 = OpConstantNull %int4
%true = OpConstantTrue %bool
%void_fn = OpTypeFunction %void
%func = OpFunction %void None %void_fn
%1 = OpLabel
%select = OpSelect %int4 %true %int4_0 %int4_0
OpReturn
OpFunctionEnd
)";
CompileSuccessfully(spirv, SPV_ENV_UNIVERSAL_1_4);
EXPECT_EQ(SPV_SUCCESS, ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
}
TEST_F(ValidateLogicals, SelectVectorsVectorConditionMismatchedDimensions1p4) {
const std::string spirv = R"(
OpCapability Shader
OpCapability Linkage
OpMemoryModel Logical GLSL450
%void = OpTypeVoid
%bool = OpTypeBool
%bool3 = OpTypeVector %bool 3
%int = OpTypeInt 32 0
%int4 = OpTypeVector %int 4
%int4_0 = OpConstantNull %int4
%bool3_null = OpConstantNull %bool3
%void_fn = OpTypeFunction %void
%func = OpFunction %void None %void_fn
%1 = OpLabel
%select = OpSelect %int4 %bool3_null %int4_0 %int4_0
OpReturn
OpFunctionEnd
)";
CompileSuccessfully(spirv, SPV_ENV_UNIVERSAL_1_4);
EXPECT_EQ(SPV_ERROR_INVALID_DATA,
ValidateInstructions(SPV_ENV_UNIVERSAL_1_4));
EXPECT_THAT(getDiagnosticString(),
HasSubstr("Expected vector sizes of Result Type and the "
"condition to be equal: Select"));
}
} // namespace
} // namespace val
} // namespace spvtools