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dawn/dawn/61d58df17d855df28d00a70da58f8e579ebf693e/./src/tint/lang/spirv/writer/binary_test.cc
blob: 489f9525756e0e13a27d3dc44f4356e62824d619 [file]
// Copyright 2023 The Dawn & Tint Authors
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// 1. Redistributions of source code must retain the above copyright notice, this
// list of conditions and the following disclaimer.
//
// 2. Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
//
// 3. Neither the name of the copyright holder nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
// DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
// FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
// DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
// SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
// OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "src/tint/lang/spirv/writer/common/helper_test.h"
#include "src/tint/lang/core/fluent_types.h"
#include "src/tint/lang/core/ir/binary.h"
using namespace tint::core::number_suffixes; // NOLINT
using namespace tint::core::fluent_types; // NOLINT
namespace tint::spirv::writer {
namespace {
/// A parameterized test case.
struct BinaryTestCase {
BinaryTestCase(TestElementType type_,
core::BinaryOp op_,
std::string spirv_inst_,
std::string spirv_type_name_)
: res_type(type_),
lhs_type(type_),
rhs_type(type_),
op(op_),
spirv_inst(spirv_inst_),
spirv_type_name(spirv_type_name_) {}
BinaryTestCase(TestElementType res_type_,
TestElementType lhs_type_,
TestElementType rhs_type_,
core::BinaryOp op_,
std::string spirv_inst_,
std::string spirv_type_name_)
: res_type(res_type_),
lhs_type(lhs_type_),
rhs_type(rhs_type_),
op(op_),
spirv_inst(spirv_inst_),
spirv_type_name(spirv_type_name_) {}
/// The result type of the binary op.
TestElementType res_type;
/// The LHS type of the binary op.
TestElementType lhs_type;
/// The RHS type of the binary op.
TestElementType rhs_type;
/// The binary operation.
core::BinaryOp op;
/// The expected SPIR-V instruction.
std::string spirv_inst;
/// The expected SPIR-V result type name.
std::string spirv_type_name;
};
using Arithmetic_Bitwise = SpirvWriterTestWithParam<BinaryTestCase>;
TEST_P(Arithmetic_Bitwise, Scalar) {
auto params = GetParam();
auto* func = b.Function("foo", ty.void_());
b.Append(func->Block(), [&] {
auto* lhs = MakeScalarValue(params.lhs_type);
auto* rhs = MakeScalarValue(params.rhs_type);
auto* result = b.Binary(params.op, MakeScalarType(params.res_type), lhs, rhs);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = " + params.spirv_inst + " %" + params.spirv_type_name);
}
TEST_P(Arithmetic_Bitwise, Vector) {
auto params = GetParam();
auto* func = b.Function("foo", ty.void_());
b.Append(func->Block(), [&] {
auto* lhs = MakeVectorValue(params.lhs_type);
auto* rhs = MakeVectorValue(params.rhs_type);
auto* result = b.Binary(params.op, MakeVectorType(params.res_type), lhs, rhs);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = " + params.spirv_inst + " %v2" + params.spirv_type_name);
}
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_I32,
Arithmetic_Bitwise,
testing::Values(BinaryTestCase{kI32, core::BinaryOp::kAnd, "OpBitwiseAnd", "int"},
BinaryTestCase{kI32, core::BinaryOp::kOr, "OpBitwiseOr", "int"},
BinaryTestCase{kI32, core::BinaryOp::kXor, "OpBitwiseXor", "int"},
BinaryTestCase{kI32, kI32, kU32, core::BinaryOp::kShiftRight,
"OpShiftRightArithmetic", "int"}));
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_U32,
Arithmetic_Bitwise,
testing::Values(BinaryTestCase{kU32, core::BinaryOp::kAdd, "OpIAdd", "uint"},
BinaryTestCase{kU32, core::BinaryOp::kSubtract, "OpISub", "uint"},
BinaryTestCase{kU32, core::BinaryOp::kMultiply, "OpIMul", "uint"},
BinaryTestCase{kU32, core::BinaryOp::kAnd, "OpBitwiseAnd", "uint"},
BinaryTestCase{kU32, core::BinaryOp::kOr, "OpBitwiseOr", "uint"},
BinaryTestCase{kU32, core::BinaryOp::kXor, "OpBitwiseXor", "uint"},
BinaryTestCase{kU32, core::BinaryOp::kShiftLeft, "OpShiftLeftLogical", "uint"},
BinaryTestCase{kU32, core::BinaryOp::kShiftRight, "OpShiftRightLogical",
"uint"}));
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_F32,
Arithmetic_Bitwise,
testing::Values(BinaryTestCase{kF32, core::BinaryOp::kAdd, "OpFAdd", "float"},
BinaryTestCase{kF32, core::BinaryOp::kSubtract, "OpFSub", "float"},
BinaryTestCase{kF32, core::BinaryOp::kMultiply, "OpFMul", "float"},
BinaryTestCase{kF32, core::BinaryOp::kDivide, "OpFDiv", "float"},
BinaryTestCase{kF32, core::BinaryOp::kModulo, "OpFRem", "float"}));
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_F16,
Arithmetic_Bitwise,
testing::Values(BinaryTestCase{kF16, core::BinaryOp::kAdd, "OpFAdd", "half"},
BinaryTestCase{kF16, core::BinaryOp::kSubtract, "OpFSub", "half"},
BinaryTestCase{kF16, core::BinaryOp::kMultiply, "OpFMul", "half"},
BinaryTestCase{kF16, core::BinaryOp::kDivide, "OpFDiv", "half"},
BinaryTestCase{kF16, core::BinaryOp::kModulo, "OpFRem", "half"}));
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_Bool,
Arithmetic_Bitwise,
testing::Values(BinaryTestCase{kBool, core::BinaryOp::kAnd, "OpLogicalAnd", "bool"},
BinaryTestCase{kBool, core::BinaryOp::kOr, "OpLogicalOr", "bool"}));
TEST_F(SpirvWriterTest, Binary_ScalarTimesVector_F32) {
auto* scalar = b.FunctionParam("scalar", ty.f32());
auto* vector = b.FunctionParam("vector", ty.vec4<f32>());
auto* func = b.Function("foo", ty.void_());
func->SetParams({scalar, vector});
b.Append(func->Block(), [&] {
auto* result = b.Multiply(ty.vec4<f32>(), scalar, vector);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = OpVectorTimesScalar %v4float %vector %scalar");
}
TEST_F(SpirvWriterTest, Binary_VectorTimesScalar_F32) {
auto* scalar = b.FunctionParam("scalar", ty.f32());
auto* vector = b.FunctionParam("vector", ty.vec4<f32>());
auto* func = b.Function("foo", ty.void_());
func->SetParams({scalar, vector});
b.Append(func->Block(), [&] {
auto* result = b.Multiply(ty.vec4<f32>(), vector, scalar);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = OpVectorTimesScalar %v4float %vector %scalar");
}
TEST_F(SpirvWriterTest, Binary_ScalarTimesMatrix_F32) {
auto* scalar = b.FunctionParam("scalar", ty.f32());
auto* matrix = b.FunctionParam("matrix", ty.mat3x4<f32>());
auto* func = b.Function("foo", ty.void_());
func->SetParams({scalar, matrix});
b.Append(func->Block(), [&] {
auto* result = b.Multiply(ty.mat3x4<f32>(), scalar, matrix);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = OpMatrixTimesScalar %mat3v4float %matrix %scalar");
}
TEST_F(SpirvWriterTest, Binary_MatrixTimesScalar_F32) {
auto* scalar = b.FunctionParam("scalar", ty.f32());
auto* matrix = b.FunctionParam("matrix", ty.mat3x4<f32>());
auto* func = b.Function("foo", ty.void_());
func->SetParams({scalar, matrix});
b.Append(func->Block(), [&] {
auto* result = b.Multiply(ty.mat3x4<f32>(), matrix, scalar);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = OpMatrixTimesScalar %mat3v4float %matrix %scalar");
}
TEST_F(SpirvWriterTest, Binary_VectorTimesMatrix_F32) {
auto* vector = b.FunctionParam("vector", ty.vec4<f32>());
auto* matrix = b.FunctionParam("matrix", ty.mat3x4<f32>());
auto* func = b.Function("foo", ty.void_());
func->SetParams({vector, matrix});
b.Append(func->Block(), [&] {
auto* result = b.Multiply(ty.vec3<f32>(), vector, matrix);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = OpVectorTimesMatrix %v3float %vector %matrix");
}
TEST_F(SpirvWriterTest, Binary_MatrixTimesVector_F32) {
auto* vector = b.FunctionParam("vector", ty.vec3<f32>());
auto* matrix = b.FunctionParam("matrix", ty.mat3x4<f32>());
auto* func = b.Function("foo", ty.void_());
func->SetParams({vector, matrix});
b.Append(func->Block(), [&] {
auto* result = b.Multiply(ty.vec4<f32>(), matrix, vector);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = OpMatrixTimesVector %v4float %matrix %vector");
}
TEST_F(SpirvWriterTest, Binary_MatrixTimesMatrix_F32) {
auto* mat1 = b.FunctionParam("mat1", ty.mat4x3<f32>());
auto* mat2 = b.FunctionParam("mat2", ty.mat3x4<f32>());
auto* func = b.Function("foo", ty.void_());
func->SetParams({mat1, mat2});
b.Append(func->Block(), [&] {
auto* result = b.Multiply(ty.mat3x3<f32>(), mat1, mat2);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = OpMatrixTimesMatrix %mat3v3float %mat1 %mat2");
}
using Comparison = SpirvWriterTestWithParam<BinaryTestCase>;
TEST_P(Comparison, Scalar) {
auto params = GetParam();
auto* func = b.Function("foo", ty.void_());
b.Append(func->Block(), [&] {
auto* lhs = MakeScalarValue(params.lhs_type);
auto* rhs = MakeScalarValue(params.rhs_type);
auto* result = b.Binary(params.op, ty.bool_(), lhs, rhs);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = " + params.spirv_inst + " %bool");
}
TEST_P(Comparison, Vector) {
auto params = GetParam();
auto* func = b.Function("foo", ty.void_());
b.Append(func->Block(), [&] {
auto* lhs = MakeVectorValue(params.lhs_type);
auto* rhs = MakeVectorValue(params.rhs_type);
auto* result = b.Binary(params.op, ty.vec2<bool>(), lhs, rhs);
b.Return(func);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%result = " + params.spirv_inst + " %v2bool");
}
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_I32,
Comparison,
testing::Values(
BinaryTestCase{kI32, core::BinaryOp::kEqual, "OpIEqual", "bool"},
BinaryTestCase{kI32, core::BinaryOp::kNotEqual, "OpINotEqual", "bool"},
BinaryTestCase{kI32, core::BinaryOp::kGreaterThan, "OpSGreaterThan", "bool"},
BinaryTestCase{kI32, core::BinaryOp::kGreaterThanEqual, "OpSGreaterThanEqual", "bool"},
BinaryTestCase{kI32, core::BinaryOp::kLessThan, "OpSLessThan", "bool"},
BinaryTestCase{kI32, core::BinaryOp::kLessThanEqual, "OpSLessThanEqual", "bool"}));
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_U32,
Comparison,
testing::Values(
BinaryTestCase{kU32, core::BinaryOp::kEqual, "OpIEqual", "bool"},
BinaryTestCase{kU32, core::BinaryOp::kNotEqual, "OpINotEqual", "bool"},
BinaryTestCase{kU32, core::BinaryOp::kGreaterThan, "OpUGreaterThan", "bool"},
BinaryTestCase{kU32, core::BinaryOp::kGreaterThanEqual, "OpUGreaterThanEqual", "bool"},
BinaryTestCase{kU32, core::BinaryOp::kLessThan, "OpULessThan", "bool"},
BinaryTestCase{kU32, core::BinaryOp::kLessThanEqual, "OpULessThanEqual", "bool"}));
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_F32,
Comparison,
testing::Values(
BinaryTestCase{kF32, core::BinaryOp::kEqual, "OpFOrdEqual", "bool"},
BinaryTestCase{kF32, core::BinaryOp::kNotEqual, "OpFOrdNotEqual", "bool"},
BinaryTestCase{kF32, core::BinaryOp::kGreaterThan, "OpFOrdGreaterThan", "bool"},
BinaryTestCase{kF32, core::BinaryOp::kGreaterThanEqual, "OpFOrdGreaterThanEqual", "bool"},
BinaryTestCase{kF32, core::BinaryOp::kLessThan, "OpFOrdLessThan", "bool"},
BinaryTestCase{kF32, core::BinaryOp::kLessThanEqual, "OpFOrdLessThanEqual", "bool"}));
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_F16,
Comparison,
testing::Values(
BinaryTestCase{kF16, core::BinaryOp::kEqual, "OpFOrdEqual", "bool"},
BinaryTestCase{kF16, core::BinaryOp::kNotEqual, "OpFOrdNotEqual", "bool"},
BinaryTestCase{kF16, core::BinaryOp::kGreaterThan, "OpFOrdGreaterThan", "bool"},
BinaryTestCase{kF16, core::BinaryOp::kGreaterThanEqual, "OpFOrdGreaterThanEqual", "bool"},
BinaryTestCase{kF16, core::BinaryOp::kLessThan, "OpFOrdLessThan", "bool"},
BinaryTestCase{kF16, core::BinaryOp::kLessThanEqual, "OpFOrdLessThanEqual", "bool"}));
INSTANTIATE_TEST_SUITE_P(
SpirvWriterTest_Binary_Bool,
Comparison,
testing::Values(BinaryTestCase{kBool, core::BinaryOp::kEqual, "OpLogicalEqual", "bool"},
BinaryTestCase{kBool, core::BinaryOp::kNotEqual, "OpLogicalNotEqual", "bool"}));
TEST_F(SpirvWriterTest, Binary_Chain) {
auto* func = b.Function("foo", ty.void_());
b.Append(func->Block(), [&] {
auto* sub = b.Subtract(ty.i32(), 1_i, 2_i);
auto* add = b.Add(ty.i32(), sub, sub);
b.Return(func);
mod.SetName(sub, "sub");
mod.SetName(add, "add");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("OpBitcast %uint %int_1");
EXPECT_INST("OpBitcast %uint %int_2");
EXPECT_INST("OpISub %uint %6 %9");
EXPECT_INST("OpIAdd %uint %13 %14");
}
TEST_F(SpirvWriterTest, Divide_u32_u32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.u32()));
args.Push(b.FunctionParam("rhs", ty.u32()));
auto* func = b.Function("foo", ty.u32());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kDivide, ty.u32(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST(R"(
; Function foo
%foo = OpFunction %uint None %5
%lhs = OpFunctionParameter %uint
%rhs = OpFunctionParameter %uint
%6 = OpLabel
%result = OpFunctionCall %uint %tint_div_u32 %lhs %rhs
OpReturnValue %result
OpFunctionEnd
; Function tint_div_u32
%tint_div_u32 = OpFunction %uint None %5
%lhs_0 = OpFunctionParameter %uint
%rhs_0 = OpFunctionParameter %uint
%11 = OpLabel
%12 = OpIEqual %bool %rhs_0 %uint_0
%15 = OpSelect %uint %12 %uint_1 %rhs_0
%17 = OpUDiv %uint %lhs_0 %15
OpReturnValue %17
OpFunctionEnd
)");
}
TEST_F(SpirvWriterTest, Divide_i32_i32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.i32()));
args.Push(b.FunctionParam("rhs", ty.i32()));
auto* func = b.Function("foo", ty.i32());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kDivide, ty.i32(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST(R"(
; Function foo
%foo = OpFunction %int None %5
%lhs = OpFunctionParameter %int
%rhs = OpFunctionParameter %int
%6 = OpLabel
%result = OpFunctionCall %int %tint_div_i32 %lhs %rhs
OpReturnValue %result
OpFunctionEnd
; Function tint_div_i32
%tint_div_i32 = OpFunction %int None %5
%lhs_0 = OpFunctionParameter %int
%rhs_0 = OpFunctionParameter %int
%11 = OpLabel
%12 = OpIEqual %bool %rhs_0 %int_0
%15 = OpIEqual %bool %lhs_0 %int_n2147483648
%17 = OpIEqual %bool %rhs_0 %int_n1
%19 = OpLogicalAnd %bool %15 %17
%20 = OpLogicalOr %bool %12 %19
%21 = OpSelect %int %20 %int_1 %rhs_0
%23 = OpSDiv %int %lhs_0 %21
OpReturnValue %23
OpFunctionEnd
)");
}
TEST_F(SpirvWriterTest, Divide_i32_vec4i) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.i32()));
args.Push(b.FunctionParam("rhs", ty.vec4<i32>()));
auto* func = b.Function("foo", ty.vec4<i32>());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kDivide, ty.vec4<i32>(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%16 = OpConstantNull %v4int");
EXPECT_INST(R"(
; Function foo
%foo = OpFunction %v4int None %6
%lhs = OpFunctionParameter %int
%rhs = OpFunctionParameter %v4int
%7 = OpLabel
%8 = OpCompositeConstruct %v4int %lhs %lhs %lhs %lhs
%result = OpFunctionCall %v4int %tint_div_v4i32 %8 %rhs
OpReturnValue %result
OpFunctionEnd
; Function tint_div_v4i32
%tint_div_v4i32 = OpFunction %v4int None %13
%lhs_0 = OpFunctionParameter %v4int
%rhs_0 = OpFunctionParameter %v4int
%14 = OpLabel
%15 = OpIEqual %v4bool %rhs_0 %16
%19 = OpIEqual %v4bool %lhs_0 %20
%22 = OpIEqual %v4bool %rhs_0 %23
%25 = OpLogicalAnd %v4bool %19 %22
%26 = OpLogicalOr %v4bool %15 %25
%27 = OpSelect %v4int %26 %28 %rhs_0
%30 = OpSDiv %v4int %lhs_0 %27
OpReturnValue %30
OpFunctionEnd
)");
}
TEST_F(SpirvWriterTest, Divide_vec4i_i32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.vec4<i32>()));
args.Push(b.FunctionParam("rhs", ty.i32()));
auto* func = b.Function("foo", ty.vec4<i32>());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kDivide, ty.vec4<i32>(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%16 = OpConstantNull %v4int");
EXPECT_INST(R"(
; Function foo
%foo = OpFunction %v4int None %6
%lhs = OpFunctionParameter %v4int
%rhs = OpFunctionParameter %int
%7 = OpLabel
%8 = OpCompositeConstruct %v4int %rhs %rhs %rhs %rhs
%result = OpFunctionCall %v4int %tint_div_v4i32 %lhs %8
OpReturnValue %result
OpFunctionEnd
; Function tint_div_v4i32
%tint_div_v4i32 = OpFunction %v4int None %13
%lhs_0 = OpFunctionParameter %v4int
%rhs_0 = OpFunctionParameter %v4int
%14 = OpLabel
%15 = OpIEqual %v4bool %rhs_0 %16
%19 = OpIEqual %v4bool %lhs_0 %20
%22 = OpIEqual %v4bool %rhs_0 %23
%25 = OpLogicalAnd %v4bool %19 %22
%26 = OpLogicalOr %v4bool %15 %25
%27 = OpSelect %v4int %26 %28 %rhs_0
%30 = OpSDiv %v4int %lhs_0 %27
OpReturnValue %30
OpFunctionEnd
)");
}
TEST_F(SpirvWriterTest, Modulo_u32_u32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.u32()));
args.Push(b.FunctionParam("rhs", ty.u32()));
auto* func = b.Function("foo", ty.u32());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kModulo, ty.u32(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST(R"(
; Function foo
%foo = OpFunction %uint None %5
%lhs = OpFunctionParameter %uint
%rhs = OpFunctionParameter %uint
%6 = OpLabel
%result = OpFunctionCall %uint %tint_mod_u32 %lhs %rhs
OpReturnValue %result
OpFunctionEnd
; Function tint_mod_u32
%tint_mod_u32 = OpFunction %uint None %5
%lhs_0 = OpFunctionParameter %uint
%rhs_0 = OpFunctionParameter %uint
%11 = OpLabel
%12 = OpIEqual %bool %rhs_0 %uint_0
%15 = OpSelect %uint %12 %uint_1 %rhs_0
%17 = OpUDiv %uint %lhs_0 %15
%18 = OpIMul %uint %17 %15
%19 = OpISub %uint %lhs_0 %18
OpReturnValue %19
OpFunctionEnd
)");
}
TEST_F(SpirvWriterTest, Modulo_i32_i32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.i32()));
args.Push(b.FunctionParam("rhs", ty.i32()));
auto* func = b.Function("foo", ty.i32());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kModulo, ty.i32(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST(R"(
; Function foo
%foo = OpFunction %int None %5
%lhs = OpFunctionParameter %int
%rhs = OpFunctionParameter %int
%6 = OpLabel
%result = OpFunctionCall %int %tint_mod_i32 %lhs %rhs
OpReturnValue %result
OpFunctionEnd
; Function tint_mod_i32
%tint_mod_i32 = OpFunction %int None %5
%lhs_0 = OpFunctionParameter %int
%rhs_0 = OpFunctionParameter %int
%11 = OpLabel
%12 = OpIEqual %bool %rhs_0 %int_0
%15 = OpIEqual %bool %lhs_0 %int_n2147483648
%17 = OpIEqual %bool %rhs_0 %int_n1
%19 = OpLogicalAnd %bool %15 %17
%20 = OpLogicalOr %bool %12 %19
%21 = OpSelect %int %20 %int_1 %rhs_0
%23 = OpSDiv %int %lhs_0 %21
%25 = OpBitcast %uint %23
%26 = OpBitcast %uint %21
%27 = OpIMul %uint %25 %26
%28 = OpBitcast %int %27
%29 = OpBitcast %uint %lhs_0
%30 = OpBitcast %uint %28
%31 = OpISub %uint %29 %30
%32 = OpBitcast %int %31
OpReturnValue %32
OpFunctionEnd
; Function unused_entry_point
%unused_entry_point = OpFunction %void None %35
%36 = OpLabel
OpReturn
OpFunctionEnd
)");
}
TEST_F(SpirvWriterTest, Add_i32_i32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.i32()));
args.Push(b.FunctionParam("rhs", ty.i32()));
auto* func = b.Function("foo", ty.i32());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kAdd, ty.i32(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST(R"(
OpMemoryModel Logical GLSL450
OpEntryPoint GLCompute %unused_entry_point "unused_entry_point"
OpExecutionMode %unused_entry_point LocalSize 1 1 1
; Debug Information
OpName %foo "foo" ; id %1
OpName %lhs "lhs" ; id %3
OpName %rhs "rhs" ; id %4
OpName %unused_entry_point "unused_entry_point" ; id %12
; Types, variables and constants
%int = OpTypeInt 32 1
%5 = OpTypeFunction %int %int %int
%uint = OpTypeInt 32 0
%void = OpTypeVoid
%14 = OpTypeFunction %void
; Function foo
%foo = OpFunction %int None %5
%lhs = OpFunctionParameter %int
%rhs = OpFunctionParameter %int
%6 = OpLabel
%8 = OpBitcast %uint %lhs
%9 = OpBitcast %uint %rhs
%10 = OpIAdd %uint %8 %9
%11 = OpBitcast %int %10
OpReturnValue %11
OpFunctionEnd
; Function unused_entry_point
%unused_entry_point = OpFunction %void None %14
%15 = OpLabel
)");
}
TEST_F(SpirvWriterTest, Sub_i32_i32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.i32()));
args.Push(b.FunctionParam("rhs", ty.i32()));
auto* func = b.Function("foo", ty.i32());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kSubtract, ty.i32(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST(R"(
OpMemoryModel Logical GLSL450
OpEntryPoint GLCompute %unused_entry_point "unused_entry_point"
OpExecutionMode %unused_entry_point LocalSize 1 1 1
; Debug Information
OpName %foo "foo" ; id %1
OpName %lhs "lhs" ; id %3
OpName %rhs "rhs" ; id %4
OpName %unused_entry_point "unused_entry_point" ; id %12
; Types, variables and constants
%int = OpTypeInt 32 1
%5 = OpTypeFunction %int %int %int
%uint = OpTypeInt 32 0
%void = OpTypeVoid
%14 = OpTypeFunction %void
; Function foo
%foo = OpFunction %int None %5
%lhs = OpFunctionParameter %int
%rhs = OpFunctionParameter %int
%6 = OpLabel
%8 = OpBitcast %uint %lhs
%9 = OpBitcast %uint %rhs
%10 = OpISub %uint %8 %9
%11 = OpBitcast %int %10
OpReturnValue %11
OpFunctionEnd
; Function unused_entry_point
%unused_entry_point = OpFunction %void None %14
%15 = OpLabel
)");
}
TEST_F(SpirvWriterTest, Mul_i32_i32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.i32()));
args.Push(b.FunctionParam("rhs", ty.i32()));
auto* func = b.Function("foo", ty.i32());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kMultiply, ty.i32(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST(R"(
OpMemoryModel Logical GLSL450
OpEntryPoint GLCompute %unused_entry_point "unused_entry_point"
OpExecutionMode %unused_entry_point LocalSize 1 1 1
; Debug Information
OpName %foo "foo" ; id %1
OpName %lhs "lhs" ; id %3
OpName %rhs "rhs" ; id %4
OpName %unused_entry_point "unused_entry_point" ; id %12
; Types, variables and constants
%int = OpTypeInt 32 1
%5 = OpTypeFunction %int %int %int
%uint = OpTypeInt 32 0
%void = OpTypeVoid
%14 = OpTypeFunction %void
; Function foo
%foo = OpFunction %int None %5
%lhs = OpFunctionParameter %int
%rhs = OpFunctionParameter %int
%6 = OpLabel
%8 = OpBitcast %uint %lhs
%9 = OpBitcast %uint %rhs
%10 = OpIMul %uint %8 %9
%11 = OpBitcast %int %10
OpReturnValue %11
OpFunctionEnd
; Function unused_entry_point
%unused_entry_point = OpFunction %void None %14
%15 = OpLabel
)");
}
TEST_F(SpirvWriterTest, ShiftLeft_i32_u32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.i32()));
args.Push(b.FunctionParam("rhs", ty.u32()));
auto* func = b.Function("foo", ty.i32());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kShiftLeft, ty.i32(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST(R"(
OpMemoryModel Logical GLSL450
OpEntryPoint GLCompute %unused_entry_point "unused_entry_point"
OpExecutionMode %unused_entry_point LocalSize 1 1 1
; Debug Information
OpName %foo "foo" ; id %1
OpName %lhs "lhs" ; id %3
OpName %rhs "rhs" ; id %5
OpName %unused_entry_point "unused_entry_point" ; id %13
; Types, variables and constants
%int = OpTypeInt 32 1
%uint = OpTypeInt 32 0
%6 = OpTypeFunction %int %int %uint
%uint_31 = OpConstant %uint 31
%void = OpTypeVoid
%15 = OpTypeFunction %void
; Function foo
%foo = OpFunction %int None %6
%lhs = OpFunctionParameter %int
%rhs = OpFunctionParameter %uint
%7 = OpLabel
%8 = OpBitwiseAnd %uint %rhs %uint_31
%10 = OpBitcast %uint %lhs
%11 = OpShiftLeftLogical %uint %10 %8
%12 = OpBitcast %int %11
OpReturnValue %12
OpFunctionEnd
; Function unused_entry_point
%unused_entry_point = OpFunction %void None %15
%16 = OpLabel
)");
}
TEST_F(SpirvWriterTest, Modulo_i32_vec4i) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.i32()));
args.Push(b.FunctionParam("rhs", ty.vec4<i32>()));
auto* func = b.Function("foo", ty.vec4<i32>());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kModulo, ty.vec4<i32>(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%16 = OpConstantNull %v4int");
EXPECT_INST(R"(
; Function foo
%foo = OpFunction %v4int None %6
%lhs = OpFunctionParameter %int
%rhs = OpFunctionParameter %v4int
%7 = OpLabel
%8 = OpCompositeConstruct %v4int %lhs %lhs %lhs %lhs
%result = OpFunctionCall %v4int %tint_mod_v4i32 %8 %rhs
OpReturnValue %result
OpFunctionEnd
; Function tint_mod_v4i32
%tint_mod_v4i32 = OpFunction %v4int None %13
%lhs_0 = OpFunctionParameter %v4int
%rhs_0 = OpFunctionParameter %v4int
%14 = OpLabel
%15 = OpIEqual %v4bool %rhs_0 %16
%19 = OpIEqual %v4bool %lhs_0 %20
%22 = OpIEqual %v4bool %rhs_0 %23
%25 = OpLogicalAnd %v4bool %19 %22
%26 = OpLogicalOr %v4bool %15 %25
%27 = OpSelect %v4int %26 %28 %rhs_0
%30 = OpSDiv %v4int %lhs_0 %27
%33 = OpBitcast %v4uint %30
%34 = OpBitcast %v4uint %27
%35 = OpIMul %v4uint %33 %34
%36 = OpBitcast %v4int %35
%37 = OpBitcast %v4uint %lhs_0
%38 = OpBitcast %v4uint %36
%39 = OpISub %v4uint %37 %38
%40 = OpBitcast %v4int %39
OpReturnValue %40
OpFunctionEnd
; Function unused_entry_point
%unused_entry_point = OpFunction %void None %43
%44 = OpLabel
OpReturn
OpFunctionEnd
)");
}
TEST_F(SpirvWriterTest, Modulo_vec4i_i32) {
Vector<core::ir::FunctionParam*, 4> args;
args.Push(b.FunctionParam("lhs", ty.vec4<i32>()));
args.Push(b.FunctionParam("rhs", ty.i32()));
auto* func = b.Function("foo", ty.vec4<i32>());
func->SetParams(args);
b.Append(func->Block(), [&] {
auto* result = b.Binary(core::BinaryOp::kModulo, ty.vec4<i32>(), args[0], args[1]);
b.Return(func, result);
mod.SetName(result, "result");
});
ASSERT_TRUE(Generate()) << Error() << output_;
EXPECT_INST("%16 = OpConstantNull %v4int");
EXPECT_INST(R"(
; Function foo
%foo = OpFunction %v4int None %6
%lhs = OpFunctionParameter %v4int
%rhs = OpFunctionParameter %int
%7 = OpLabel
%8 = OpCompositeConstruct %v4int %rhs %rhs %rhs %rhs
%result = OpFunctionCall %v4int %tint_mod_v4i32 %lhs %8
OpReturnValue %result
OpFunctionEnd
; Function tint_mod_v4i32
%tint_mod_v4i32 = OpFunction %v4int None %13
%lhs_0 = OpFunctionParameter %v4int
%rhs_0 = OpFunctionParameter %v4int
%14 = OpLabel
%15 = OpIEqual %v4bool %rhs_0 %16
%19 = OpIEqual %v4bool %lhs_0 %20
%22 = OpIEqual %v4bool %rhs_0 %23
%25 = OpLogicalAnd %v4bool %19 %22
%26 = OpLogicalOr %v4bool %15 %25
%27 = OpSelect %v4int %26 %28 %rhs_0
%30 = OpSDiv %v4int %lhs_0 %27
%33 = OpBitcast %v4uint %30
%34 = OpBitcast %v4uint %27
%35 = OpIMul %v4uint %33 %34
%36 = OpBitcast %v4int %35
%37 = OpBitcast %v4uint %lhs_0
%38 = OpBitcast %v4uint %36
%39 = OpISub %v4uint %37 %38
%40 = OpBitcast %v4int %39
OpReturnValue %40
OpFunctionEnd
; Function unused_entry_point
%unused_entry_point = OpFunction %void None %43
%44 = OpLabel
OpReturn
OpFunctionEnd
)");
}
} // namespace
} // namespace tint::spirv::writer