blob: c0528739cb53ba17b771317f878b7a1324d6867f [file] [log] [blame]
// Copyright 2020 The Tint Authors.
//
// 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 "gmock/gmock.h"
#include "src/ast/call_statement.h"
#include "src/ast/stage_decoration.h"
#include "src/sem/call.h"
#include "src/writer/hlsl/test_helper.h"
namespace tint {
namespace writer {
namespace hlsl {
namespace {
using IntrinsicType = sem::IntrinsicType;
using ::testing::HasSubstr;
using HlslGeneratorImplTest_Intrinsic = TestHelper;
enum class ParamType {
kF32,
kU32,
kBool,
};
struct IntrinsicData {
IntrinsicType intrinsic;
ParamType type;
const char* hlsl_name;
};
inline std::ostream& operator<<(std::ostream& out, IntrinsicData data) {
out << data.hlsl_name;
switch (data.type) {
case ParamType::kF32:
out << "f32";
break;
case ParamType::kU32:
out << "u32";
break;
case ParamType::kBool:
out << "bool";
break;
}
out << ">";
return out;
}
ast::CallExpression* GenerateCall(IntrinsicType intrinsic,
ParamType type,
ProgramBuilder* builder) {
std::string name;
std::ostringstream str(name);
str << intrinsic;
switch (intrinsic) {
case IntrinsicType::kAcos:
case IntrinsicType::kAsin:
case IntrinsicType::kAtan:
case IntrinsicType::kCeil:
case IntrinsicType::kCos:
case IntrinsicType::kCosh:
case IntrinsicType::kDpdx:
case IntrinsicType::kDpdxCoarse:
case IntrinsicType::kDpdxFine:
case IntrinsicType::kDpdy:
case IntrinsicType::kDpdyCoarse:
case IntrinsicType::kDpdyFine:
case IntrinsicType::kExp:
case IntrinsicType::kExp2:
case IntrinsicType::kFloor:
case IntrinsicType::kFract:
case IntrinsicType::kFwidth:
case IntrinsicType::kFwidthCoarse:
case IntrinsicType::kFwidthFine:
case IntrinsicType::kInverseSqrt:
case IntrinsicType::kIsFinite:
case IntrinsicType::kIsInf:
case IntrinsicType::kIsNan:
case IntrinsicType::kIsNormal:
case IntrinsicType::kLength:
case IntrinsicType::kLog:
case IntrinsicType::kLog2:
case IntrinsicType::kNormalize:
case IntrinsicType::kRound:
case IntrinsicType::kSin:
case IntrinsicType::kSinh:
case IntrinsicType::kSqrt:
case IntrinsicType::kTan:
case IntrinsicType::kTanh:
case IntrinsicType::kTrunc:
case IntrinsicType::kSign:
return builder->Call(str.str(), "f2");
case IntrinsicType::kLdexp:
return builder->Call(str.str(), "f2", "i2");
case IntrinsicType::kAtan2:
case IntrinsicType::kDot:
case IntrinsicType::kDistance:
case IntrinsicType::kPow:
case IntrinsicType::kReflect:
case IntrinsicType::kStep:
return builder->Call(str.str(), "f2", "f2");
case IntrinsicType::kCross:
return builder->Call(str.str(), "f3", "f3");
case IntrinsicType::kFma:
case IntrinsicType::kMix:
case IntrinsicType::kFaceForward:
case IntrinsicType::kSmoothStep:
return builder->Call(str.str(), "f2", "f2", "f2");
case IntrinsicType::kAll:
case IntrinsicType::kAny:
return builder->Call(str.str(), "b2");
case IntrinsicType::kAbs:
if (type == ParamType::kF32) {
return builder->Call(str.str(), "f2");
} else {
return builder->Call(str.str(), "u2");
}
case IntrinsicType::kCountOneBits:
case IntrinsicType::kReverseBits:
return builder->Call(str.str(), "u2");
case IntrinsicType::kMax:
case IntrinsicType::kMin:
if (type == ParamType::kF32) {
return builder->Call(str.str(), "f2", "f2");
} else {
return builder->Call(str.str(), "u2", "u2");
}
case IntrinsicType::kClamp:
if (type == ParamType::kF32) {
return builder->Call(str.str(), "f2", "f2", "f2");
} else {
return builder->Call(str.str(), "u2", "u2", "u2");
}
case IntrinsicType::kSelect:
return builder->Call(str.str(), "f2", "f2", "b2");
case IntrinsicType::kDeterminant:
return builder->Call(str.str(), "m2x2");
case IntrinsicType::kTranspose:
return builder->Call(str.str(), "m3x2");
default:
break;
}
return nullptr;
}
using HlslIntrinsicTest = TestParamHelper<IntrinsicData>;
TEST_P(HlslIntrinsicTest, Emit) {
auto param = GetParam();
Global("f2", ty.vec2<f32>(), ast::StorageClass::kPrivate);
Global("f3", ty.vec3<f32>(), ast::StorageClass::kPrivate);
Global("u2", ty.vec2<u32>(), ast::StorageClass::kPrivate);
Global("i2", ty.vec2<i32>(), ast::StorageClass::kPrivate);
Global("b2", ty.vec2<bool>(), ast::StorageClass::kPrivate);
Global("m2x2", ty.mat2x2<f32>(), ast::StorageClass::kPrivate);
Global("m3x2", ty.mat3x2<f32>(), ast::StorageClass::kPrivate);
auto* call = GenerateCall(param.intrinsic, param.type, this);
ASSERT_NE(nullptr, call) << "Unhandled intrinsic";
Func("func", {}, ty.void_(), {Ignore(call)},
{create<ast::StageDecoration>(ast::PipelineStage::kFragment)});
GeneratorImpl& gen = Build();
auto* sem = program->Sem().Get(call);
ASSERT_NE(sem, nullptr);
auto* target = sem->Target();
ASSERT_NE(target, nullptr);
auto* intrinsic = target->As<sem::Intrinsic>();
ASSERT_NE(intrinsic, nullptr);
EXPECT_EQ(gen.generate_builtin_name(intrinsic), param.hlsl_name);
}
INSTANTIATE_TEST_SUITE_P(
HlslGeneratorImplTest_Intrinsic,
HlslIntrinsicTest,
testing::Values(
IntrinsicData{IntrinsicType::kAbs, ParamType::kF32, "abs"},
IntrinsicData{IntrinsicType::kAbs, ParamType::kU32, "abs"},
IntrinsicData{IntrinsicType::kAcos, ParamType::kF32, "acos"},
IntrinsicData{IntrinsicType::kAll, ParamType::kBool, "all"},
IntrinsicData{IntrinsicType::kAny, ParamType::kBool, "any"},
IntrinsicData{IntrinsicType::kAsin, ParamType::kF32, "asin"},
IntrinsicData{IntrinsicType::kAtan, ParamType::kF32, "atan"},
IntrinsicData{IntrinsicType::kAtan2, ParamType::kF32, "atan2"},
IntrinsicData{IntrinsicType::kCeil, ParamType::kF32, "ceil"},
IntrinsicData{IntrinsicType::kClamp, ParamType::kF32, "clamp"},
IntrinsicData{IntrinsicType::kClamp, ParamType::kU32, "clamp"},
IntrinsicData{IntrinsicType::kCos, ParamType::kF32, "cos"},
IntrinsicData{IntrinsicType::kCosh, ParamType::kF32, "cosh"},
IntrinsicData{IntrinsicType::kCountOneBits, ParamType::kU32,
"countbits"},
IntrinsicData{IntrinsicType::kCross, ParamType::kF32, "cross"},
IntrinsicData{IntrinsicType::kDeterminant, ParamType::kF32,
"determinant"},
IntrinsicData{IntrinsicType::kDistance, ParamType::kF32, "distance"},
IntrinsicData{IntrinsicType::kDot, ParamType::kF32, "dot"},
IntrinsicData{IntrinsicType::kDpdx, ParamType::kF32, "ddx"},
IntrinsicData{IntrinsicType::kDpdxCoarse, ParamType::kF32,
"ddx_coarse"},
IntrinsicData{IntrinsicType::kDpdxFine, ParamType::kF32, "ddx_fine"},
IntrinsicData{IntrinsicType::kDpdy, ParamType::kF32, "ddy"},
IntrinsicData{IntrinsicType::kDpdyCoarse, ParamType::kF32,
"ddy_coarse"},
IntrinsicData{IntrinsicType::kDpdyFine, ParamType::kF32, "ddy_fine"},
IntrinsicData{IntrinsicType::kExp, ParamType::kF32, "exp"},
IntrinsicData{IntrinsicType::kExp2, ParamType::kF32, "exp2"},
IntrinsicData{IntrinsicType::kFaceForward, ParamType::kF32,
"faceforward"},
IntrinsicData{IntrinsicType::kFloor, ParamType::kF32, "floor"},
IntrinsicData{IntrinsicType::kFma, ParamType::kF32, "mad"},
IntrinsicData{IntrinsicType::kFract, ParamType::kF32, "frac"},
IntrinsicData{IntrinsicType::kFwidth, ParamType::kF32, "fwidth"},
IntrinsicData{IntrinsicType::kFwidthCoarse, ParamType::kF32, "fwidth"},
IntrinsicData{IntrinsicType::kFwidthFine, ParamType::kF32, "fwidth"},
IntrinsicData{IntrinsicType::kInverseSqrt, ParamType::kF32, "rsqrt"},
IntrinsicData{IntrinsicType::kIsFinite, ParamType::kF32, "isfinite"},
IntrinsicData{IntrinsicType::kIsInf, ParamType::kF32, "isinf"},
IntrinsicData{IntrinsicType::kIsNan, ParamType::kF32, "isnan"},
IntrinsicData{IntrinsicType::kLdexp, ParamType::kF32, "ldexp"},
IntrinsicData{IntrinsicType::kLength, ParamType::kF32, "length"},
IntrinsicData{IntrinsicType::kLog, ParamType::kF32, "log"},
IntrinsicData{IntrinsicType::kLog2, ParamType::kF32, "log2"},
IntrinsicData{IntrinsicType::kMax, ParamType::kF32, "max"},
IntrinsicData{IntrinsicType::kMax, ParamType::kU32, "max"},
IntrinsicData{IntrinsicType::kMin, ParamType::kF32, "min"},
IntrinsicData{IntrinsicType::kMin, ParamType::kU32, "min"},
IntrinsicData{IntrinsicType::kMix, ParamType::kF32, "lerp"},
IntrinsicData{IntrinsicType::kNormalize, ParamType::kF32, "normalize"},
IntrinsicData{IntrinsicType::kPow, ParamType::kF32, "pow"},
IntrinsicData{IntrinsicType::kReflect, ParamType::kF32, "reflect"},
IntrinsicData{IntrinsicType::kReverseBits, ParamType::kU32,
"reversebits"},
IntrinsicData{IntrinsicType::kRound, ParamType::kU32, "round"},
IntrinsicData{IntrinsicType::kSign, ParamType::kF32, "sign"},
IntrinsicData{IntrinsicType::kSin, ParamType::kF32, "sin"},
IntrinsicData{IntrinsicType::kSinh, ParamType::kF32, "sinh"},
IntrinsicData{IntrinsicType::kSmoothStep, ParamType::kF32,
"smoothstep"},
IntrinsicData{IntrinsicType::kSqrt, ParamType::kF32, "sqrt"},
IntrinsicData{IntrinsicType::kStep, ParamType::kF32, "step"},
IntrinsicData{IntrinsicType::kTan, ParamType::kF32, "tan"},
IntrinsicData{IntrinsicType::kTanh, ParamType::kF32, "tanh"},
IntrinsicData{IntrinsicType::kTranspose, ParamType::kF32, "transpose"},
IntrinsicData{IntrinsicType::kTrunc, ParamType::kF32, "trunc"}));
TEST_F(HlslGeneratorImplTest_Intrinsic, DISABLED_Intrinsic_IsNormal) {
FAIL();
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Intrinsic_Call) {
auto* call = Call("dot", "param1", "param2");
Global("param1", ty.vec3<f32>(), ast::StorageClass::kPrivate);
Global("param2", ty.vec3<f32>(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
gen.increment_indent();
std::stringstream out;
ASSERT_TRUE(gen.EmitExpression(out, call)) << gen.error();
EXPECT_EQ(out.str(), "dot(param1, param2)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Select_Scalar) {
auto* call = Call("select", 1.0f, 2.0f, true);
WrapInFunction(call);
GeneratorImpl& gen = Build();
gen.increment_indent();
std::stringstream out;
ASSERT_TRUE(gen.EmitExpression(out, call)) << gen.error();
EXPECT_EQ(out.str(), "(true ? 2.0f : 1.0f)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Select_Vector) {
auto* call =
Call("select", vec2<i32>(1, 2), vec2<i32>(3, 4), vec2<bool>(true, false));
WrapInFunction(call);
GeneratorImpl& gen = Build();
gen.increment_indent();
std::stringstream out;
ASSERT_TRUE(gen.EmitExpression(out, call)) << gen.error();
EXPECT_EQ(out.str(), "(bool2(true, false) ? int2(3, 4) : int2(1, 2))");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Modf_Scalar) {
auto* res = Var("res", ty.f32());
auto* call = Call("modf", 1.0f, AddressOf(res));
WrapInFunction(res, call);
GeneratorImpl& gen = SanitizeAndBuild();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_THAT(gen.result(), HasSubstr("modf(1.0f, res)"));
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Modf_Vector) {
auto* res = Var("res", ty.vec3<f32>());
auto* call = Call("modf", vec3<f32>(), AddressOf(res));
WrapInFunction(res, call);
GeneratorImpl& gen = SanitizeAndBuild();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_THAT(gen.result(), HasSubstr("modf(float3(0.0f, 0.0f, 0.0f), res)"));
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Frexp_Scalar_i32) {
auto* exp = Var("exp", ty.i32());
auto* call = Call("frexp", 1.0f, AddressOf(exp));
WrapInFunction(exp, call);
GeneratorImpl& gen = SanitizeAndBuild();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(),
R"(float tint_frexp(float param_0, inout int param_1) {
float float_exp;
float significand = frexp(param_0, float_exp);
param_1 = int(float_exp);
return significand;
}
[numthreads(1, 1, 1)]
void test_function() {
int exp = 0;
tint_frexp(1.0f, exp);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Frexp_Vector_i32) {
auto* res = Var("res", ty.vec3<i32>());
auto* call = Call("frexp", vec3<f32>(), AddressOf(res));
WrapInFunction(res, call);
GeneratorImpl& gen = SanitizeAndBuild();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(),
R"(float3 tint_frexp(float3 param_0, inout int3 param_1) {
float3 float_exp;
float3 significand = frexp(param_0, float_exp);
param_1 = int3(float_exp);
return significand;
}
[numthreads(1, 1, 1)]
void test_function() {
int3 res = int3(0, 0, 0);
tint_frexp(float3(0.0f, 0.0f, 0.0f), res);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, IsNormal_Scalar) {
auto* val = Var("val", ty.f32());
auto* call = Call("isNormal", val);
WrapInFunction(val, call);
GeneratorImpl& gen = SanitizeAndBuild();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(bool tint_isNormal(float param_0) {
uint exponent = asuint(param_0) & 0x7f80000;
uint clamped = clamp(exponent, 0x0080000, 0x7f00000);
return clamped == exponent;
}
[numthreads(1, 1, 1)]
void test_function() {
float val = 0.0f;
tint_isNormal(val);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, IsNormal_Vector) {
auto* val = Var("val", ty.vec3<f32>());
auto* call = Call("isNormal", val);
WrapInFunction(val, call);
GeneratorImpl& gen = SanitizeAndBuild();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(bool3 tint_isNormal(float3 param_0) {
uint3 exponent = asuint(param_0) & 0x7f80000;
uint3 clamped = clamp(exponent, 0x0080000, 0x7f00000);
return clamped == exponent;
}
[numthreads(1, 1, 1)]
void test_function() {
float3 val = float3(0.0f, 0.0f, 0.0f);
tint_isNormal(val);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Pack4x8Snorm) {
auto* call = Call("pack4x8snorm", "p1");
Global("p1", ty.vec4<f32>(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(uint tint_pack4x8snorm(float4 param_0) {
int4 i = int4(round(clamp(param_0, -1.0, 1.0) * 127.0)) & 0xff;
return asuint(i.x | i.y << 8 | i.z << 16 | i.w << 24);
}
static float4 p1 = float4(0.0f, 0.0f, 0.0f, 0.0f);
[numthreads(1, 1, 1)]
void test_function() {
tint_pack4x8snorm(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Pack4x8Unorm) {
auto* call = Call("pack4x8unorm", "p1");
Global("p1", ty.vec4<f32>(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(uint tint_pack4x8unorm(float4 param_0) {
uint4 i = uint4(round(clamp(param_0, 0.0, 1.0) * 255.0));
return (i.x | i.y << 8 | i.z << 16 | i.w << 24);
}
static float4 p1 = float4(0.0f, 0.0f, 0.0f, 0.0f);
[numthreads(1, 1, 1)]
void test_function() {
tint_pack4x8unorm(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Pack2x16Snorm) {
auto* call = Call("pack2x16snorm", "p1");
Global("p1", ty.vec2<f32>(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(uint tint_pack2x16snorm(float2 param_0) {
int2 i = int2(round(clamp(param_0, -1.0, 1.0) * 32767.0)) & 0xffff;
return asuint(i.x | i.y << 16);
}
static float2 p1 = float2(0.0f, 0.0f);
[numthreads(1, 1, 1)]
void test_function() {
tint_pack2x16snorm(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Pack2x16Unorm) {
auto* call = Call("pack2x16unorm", "p1");
Global("p1", ty.vec2<f32>(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(uint tint_pack2x16unorm(float2 param_0) {
uint2 i = uint2(round(clamp(param_0, 0.0, 1.0) * 65535.0));
return (i.x | i.y << 16);
}
static float2 p1 = float2(0.0f, 0.0f);
[numthreads(1, 1, 1)]
void test_function() {
tint_pack2x16unorm(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Pack2x16Float) {
auto* call = Call("pack2x16float", "p1");
Global("p1", ty.vec2<f32>(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(uint tint_pack2x16float(float2 param_0) {
uint2 i = f32tof16(param_0);
return i.x | (i.y << 16);
}
static float2 p1 = float2(0.0f, 0.0f);
[numthreads(1, 1, 1)]
void test_function() {
tint_pack2x16float(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Unpack4x8Snorm) {
auto* call = Call("unpack4x8snorm", "p1");
Global("p1", ty.u32(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(float4 tint_unpack4x8snorm(uint param_0) {
int j = int(param_0);
int4 i = int4(j << 24, j << 16, j << 8, j) >> 24;
return clamp(float4(i) / 127.0, -1.0, 1.0);
}
static uint p1 = 0u;
[numthreads(1, 1, 1)]
void test_function() {
tint_unpack4x8snorm(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Unpack4x8Unorm) {
auto* call = Call("unpack4x8unorm", "p1");
Global("p1", ty.u32(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(float4 tint_unpack4x8unorm(uint param_0) {
uint j = param_0;
uint4 i = uint4(j & 0xff, (j >> 8) & 0xff, (j >> 16) & 0xff, j >> 24);
return float4(i) / 255.0;
}
static uint p1 = 0u;
[numthreads(1, 1, 1)]
void test_function() {
tint_unpack4x8unorm(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Unpack2x16Snorm) {
auto* call = Call("unpack2x16snorm", "p1");
Global("p1", ty.u32(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(float2 tint_unpack2x16snorm(uint param_0) {
int j = int(param_0);
int2 i = int2(j << 16, j) >> 16;
return clamp(float2(i) / 32767.0, -1.0, 1.0);
}
static uint p1 = 0u;
[numthreads(1, 1, 1)]
void test_function() {
tint_unpack2x16snorm(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Unpack2x16Unorm) {
auto* call = Call("unpack2x16unorm", "p1");
Global("p1", ty.u32(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(float2 tint_unpack2x16unorm(uint param_0) {
uint j = param_0;
uint2 i = uint2(j & 0xffff, j >> 16);
return float2(i) / 65535.0;
}
static uint p1 = 0u;
[numthreads(1, 1, 1)]
void test_function() {
tint_unpack2x16unorm(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Unpack2x16Float) {
auto* call = Call("unpack2x16float", "p1");
Global("p1", ty.u32(), ast::StorageClass::kPrivate);
WrapInFunction(call);
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(float2 tint_unpack2x16float(uint param_0) {
uint i = param_0;
return f16tof32(uint2(i & 0xffff, i >> 16));
}
static uint p1 = 0u;
[numthreads(1, 1, 1)]
void test_function() {
tint_unpack2x16float(p1);
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, StorageBarrier) {
Func("main", {}, ty.void_(),
{create<ast::CallStatement>(Call("storageBarrier"))},
{
Stage(ast::PipelineStage::kCompute),
WorkgroupSize(1),
});
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"([numthreads(1, 1, 1)]
void main() {
DeviceMemoryBarrierWithGroupSync();
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, WorkgroupBarrier) {
Func("main", {}, ty.void_(),
{create<ast::CallStatement>(Call("workgroupBarrier"))},
{
Stage(ast::PipelineStage::kCompute),
WorkgroupSize(1),
});
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"([numthreads(1, 1, 1)]
void main() {
GroupMemoryBarrierWithGroupSync();
return;
}
)");
}
TEST_F(HlslGeneratorImplTest_Intrinsic, Ignore) {
Func("f", {Param("a", ty.i32()), Param("b", ty.i32()), Param("c", ty.i32())},
ty.i32(), {Return(Mul(Add("a", "b"), "c"))});
Func("main", {}, ty.void_(),
{create<ast::CallStatement>(Call("ignore", Call("f", 1, 2, 3)))},
{
Stage(ast::PipelineStage::kCompute),
WorkgroupSize(1),
});
GeneratorImpl& gen = Build();
ASSERT_TRUE(gen.Generate()) << gen.error();
EXPECT_EQ(gen.result(), R"(int f(int a, int b, int c) {
return ((a + b) * c);
}
[numthreads(1, 1, 1)]
void main() {
f(1, 2, 3);
return;
}
)");
}
} // namespace
} // namespace hlsl
} // namespace writer
} // namespace tint