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Add support for binary arithmetic expressions with mixed scalar and vector operands 

Bug: tint:376
Change-Id: I2994ff7394efa903050b470a850b41628d5b775c
Reviewed-on: https://dawn-review.googlesource.com/c/tint/+/52324
Commit-Queue: Antonio Maiorano <amaiorano@google.com>
Reviewed-by: Ben Clayton <bclayton@google.com>
This commit is contained in:
Antonio Maiorano 2021-05-27 21:07:56 +00:00 committed by Tint LUCI CQ
parent d5f4ea22f0
commit eaed2b6ce2
10 changed files with 909 additions and 18 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

40
src/resolver/resolver.cc
View File

@ -2097,23 +2097,35 @@ bool Resolver::Binary(ast::BinaryExpression* expr) {
SetType(expr, lhs_type);
return true;
}
// Binary arithmetic expressions with mixed scalar and vector operands
if (lhs_vec_elem_type && (lhs_vec_elem_type == rhs_type)) {
if (expr->IsModulo()) {
if (rhs_type->is_integer_scalar()) {
SetType(expr, lhs_type);
return true;
}
} else if (rhs_type->is_numeric_scalar()) {
SetType(expr, lhs_type);
return true;
}
}
if (rhs_vec_elem_type && (rhs_vec_elem_type == lhs_type)) {
if (expr->IsModulo()) {
if (lhs_type->is_integer_scalar()) {
SetType(expr, rhs_type);
return true;
}
} else if (lhs_type->is_numeric_scalar()) {
SetType(expr, rhs_type);
return true;
}
}
}
// Binary arithmetic expressions with mixed scalar, vector, and matrix
// operands
// Matrix arithmetic
// TODO(amaiorano): matrix-matrix addition and subtraction
if (expr->IsMultiply()) {
// Multiplication of a vector and a scalar
if (lhs_type->Is<F32>() && rhs_vec_elem_type &&
rhs_vec_elem_type->Is<F32>()) {
SetType(expr, rhs_type);
return true;
}
if (lhs_vec_elem_type && lhs_vec_elem_type->Is<F32>() &&
rhs_type->Is<F32>()) {
SetType(expr, lhs_type);
return true;
}
auto* lhs_mat = lhs_type->As<Matrix>();
auto* lhs_mat_elem_type = lhs_mat ? lhs_mat->type() : nullptr;
auto* rhs_mat = rhs_type->As<Matrix>();

44
src/resolver/resolver_test.cc
View File

@ -1298,16 +1298,52 @@ static constexpr Params all_valid_cases[] = {
Params{Op::kDivide, ast_vec3<f32>, ast_vec3<f32>, sem_vec3<sem_f32>},
Params{Op::kModulo, ast_vec3<f32>, ast_vec3<f32>, sem_vec3<sem_f32>},
// Binary arithmetic expressions with mixed scalar, vector, and matrix
// operands
Params{Op::kMultiply, ast_vec3<f32>, ast_f32, sem_vec3<sem_f32>},
Params{Op::kMultiply, ast_f32, ast_vec3<f32>, sem_vec3<sem_f32>},
// Binary arithmetic expressions with mixed scalar and vector operands
Params{Op::kAdd, ast_vec3<i32>, ast_i32, sem_vec3<sem_i32>},
Params{Op::kSubtract, ast_vec3<i32>, ast_i32, sem_vec3<sem_i32>},
Params{Op::kMultiply, ast_vec3<i32>, ast_i32, sem_vec3<sem_i32>},
Params{Op::kDivide, ast_vec3<i32>, ast_i32, sem_vec3<sem_i32>},
Params{Op::kModulo, ast_vec3<i32>, ast_i32, sem_vec3<sem_i32>},
Params{Op::kAdd, ast_i32, ast_vec3<i32>, sem_vec3<sem_i32>},
Params{Op::kSubtract, ast_i32, ast_vec3<i32>, sem_vec3<sem_i32>},
Params{Op::kMultiply, ast_i32, ast_vec3<i32>, sem_vec3<sem_i32>},
Params{Op::kDivide, ast_i32, ast_vec3<i32>, sem_vec3<sem_i32>},
Params{Op::kModulo, ast_i32, ast_vec3<i32>, sem_vec3<sem_i32>},
Params{Op::kAdd, ast_vec3<u32>, ast_u32, sem_vec3<sem_u32>},
Params{Op::kSubtract, ast_vec3<u32>, ast_u32, sem_vec3<sem_u32>},
Params{Op::kMultiply, ast_vec3<u32>, ast_u32, sem_vec3<sem_u32>},
Params{Op::kDivide, ast_vec3<u32>, ast_u32, sem_vec3<sem_u32>},
Params{Op::kModulo, ast_vec3<u32>, ast_u32, sem_vec3<sem_u32>},
Params{Op::kAdd, ast_u32, ast_vec3<u32>, sem_vec3<sem_u32>},
Params{Op::kSubtract, ast_u32, ast_vec3<u32>, sem_vec3<sem_u32>},
Params{Op::kMultiply, ast_u32, ast_vec3<u32>, sem_vec3<sem_u32>},
Params{Op::kDivide, ast_u32, ast_vec3<u32>, sem_vec3<sem_u32>},
Params{Op::kModulo, ast_u32, ast_vec3<u32>, sem_vec3<sem_u32>},
Params{Op::kAdd, ast_vec3<f32>, ast_f32, sem_vec3<sem_f32>},
Params{Op::kSubtract, ast_vec3<f32>, ast_f32, sem_vec3<sem_f32>},
Params{Op::kMultiply, ast_vec3<f32>, ast_f32, sem_vec3<sem_f32>},
Params{Op::kDivide, ast_vec3<f32>, ast_f32, sem_vec3<sem_f32>},
// NOTE: no kModulo for ast_vec3<f32>, ast_f32
// Params{Op::kModulo, ast_vec3<f32>, ast_f32, sem_vec3<sem_f32>},
Params{Op::kAdd, ast_f32, ast_vec3<f32>, sem_vec3<sem_f32>},
Params{Op::kSubtract, ast_f32, ast_vec3<f32>, sem_vec3<sem_f32>},
Params{Op::kMultiply, ast_f32, ast_vec3<f32>, sem_vec3<sem_f32>},
Params{Op::kDivide, ast_f32, ast_vec3<f32>, sem_vec3<sem_f32>},
// NOTE: no kModulo for ast_f32, ast_vec3<f32>
// Params{Op::kModulo, ast_f32, ast_vec3<f32>, sem_vec3<sem_f32>},
// Matrix arithmetic
Params{Op::kMultiply, ast_mat3x3<f32>, ast_f32, sem_mat3x3<sem_f32>},
Params{Op::kMultiply, ast_f32, ast_mat3x3<f32>, sem_mat3x3<sem_f32>},
Params{Op::kMultiply, ast_vec3<f32>, ast_mat3x3<f32>, sem_vec3<sem_f32>},
Params{Op::kMultiply, ast_mat3x3<f32>, ast_vec3<f32>, sem_vec3<sem_f32>},
// TODO(amaiorano): add mat+mat and mat-mat
Params{Op::kMultiply, ast_mat3x3<f32>, ast_mat3x3<f32>,
sem_mat3x3<sem_f32>},

52
src/writer/spirv/builder.cc
View File

@ -1719,6 +1719,31 @@ uint32_t Builder::GenerateShortCircuitBinaryExpression(
return result_id;
}
uint32_t Builder::GenerateSplat(uint32_t scalar_id, const sem::Type* vec_type) {
// Create a new vector to splat scalar into
auto splat_vector = result_op();
auto* splat_vector_type =
builder_.create<sem::Pointer>(vec_type, ast::StorageClass::kFunction);
push_function_var(
{Operand::Int(GenerateTypeIfNeeded(splat_vector_type)), splat_vector,
Operand::Int(ConvertStorageClass(ast::StorageClass::kFunction)),
Operand::Int(GenerateConstantNullIfNeeded(vec_type))});
// Splat scalar into vector
auto splat_result = result_op();
OperandList ops;
ops.push_back(Operand::Int(GenerateTypeIfNeeded(vec_type)));
ops.push_back(splat_result);
for (size_t i = 0; i < vec_type->As<sem::Vector>()->size(); ++i) {
ops.push_back(Operand::Int(scalar_id));
}
if (!push_function_inst(spv::Op::OpCompositeConstruct, ops)) {
return 0;
}
return splat_result.to_i();
}
uint32_t Builder::GenerateBinaryExpression(ast::BinaryExpression* expr) {
// There is special logic for short circuiting operators.
if (expr->IsLogicalAnd() || expr->IsLogicalOr()) {
@ -1749,6 +1774,33 @@ uint32_t Builder::GenerateBinaryExpression(ast::BinaryExpression* expr) {
// should have been rejected by validation.
auto* lhs_type = TypeOf(expr->lhs())->UnwrapRef();
auto* rhs_type = TypeOf(expr->rhs())->UnwrapRef();
// For vector-scalar arithmetic operations, splat scalar into a vector. We
// skip this for multiply as we can use OpVectorTimesScalar.
const bool is_float_scalar_vector_multiply =
expr->IsMultiply() &&
((lhs_type->is_float_scalar() && rhs_type->is_float_vector()) ||
(lhs_type->is_float_vector() && rhs_type->is_float_scalar()));
if (expr->IsArithmetic() && !is_float_scalar_vector_multiply) {
if (lhs_type->Is<sem::Vector>() && rhs_type->is_numeric_scalar()) {
uint32_t splat_vector_id = GenerateSplat(rhs_id, lhs_type);
if (splat_vector_id == 0) {
return 0;
}
rhs_id = splat_vector_id;
rhs_type = lhs_type;
} else if (lhs_type->is_numeric_scalar() && rhs_type->Is<sem::Vector>()) {
uint32_t splat_vector_id = GenerateSplat(lhs_id, rhs_type);
if (splat_vector_id == 0) {
return 0;
}
lhs_id = splat_vector_id;
lhs_type = rhs_type;
}
}
bool lhs_is_float_or_vec = lhs_type->is_float_scalar_or_vector();
bool lhs_is_unsigned = lhs_type->is_unsigned_scalar_or_vector();

7
src/writer/spirv/builder.h
View File

@ -473,6 +473,13 @@ class Builder {
/// @returns true if the vector was successfully generated
bool GenerateVectorType(const sem::Vector* vec, const Operand& result);
/// Generates instructions to splat `scalar_id` into a vector of type
/// `vec_type`
/// @param scalar_id scalar to splat
/// @param vec_type type of vector
/// @returns id of the new vector
uint32_t GenerateSplat(uint32_t scalar_id, const sem::Type* vec_type);
/// Converts AST image format to SPIR-V and pushes an appropriate capability.
/// @param format AST image format type
/// @returns SPIR-V image format type

216
src/writer/spirv/builder_binary_expression_test.cc
View File

@ -863,6 +863,222 @@ OpBranch %9
)");
}
enum class Type { f32, i32, u32 };
ast::Expression* MakeVectorExpr(ProgramBuilder* builder, Type type) {
switch (type) {
case Type::f32:
return builder->vec3<ProgramBuilder::f32>(1.f, 1.f, 1.f);
case Type::i32:
return builder->vec3<ProgramBuilder::i32>(1, 1, 1);
case Type::u32:
return builder->vec3<ProgramBuilder::u32>(1u, 1u, 1u);
}
return nullptr;
}
ast::Expression* MakeScalarExpr(ProgramBuilder* builder, Type type) {
switch (type) {
case Type::f32:
return builder->Expr(1.f);
case Type::i32:
return builder->Expr(1);
case Type::u32:
return builder->Expr(1u);
}
return nullptr;
}
std::string OpTypeDecl(Type type) {
switch (type) {
case Type::f32:
return "OpTypeFloat 32";
case Type::i32:
return "OpTypeInt 32 1";
case Type::u32:
return "OpTypeInt 32 0";
}
return {};
}
struct Param {
Type type;
ast::BinaryOp op;
std::string name;
};
using MixedBinaryArithTest = TestParamHelper<Param>;
TEST_P(MixedBinaryArithTest, VectorScalar) {
auto& param = GetParam();
ast::Expression* lhs = MakeVectorExpr(this, param.type);
ast::Expression* rhs = MakeScalarExpr(this, param.type);
std::string op_type_decl = OpTypeDecl(param.type);
auto* expr = create<ast::BinaryExpression>(param.op, lhs, rhs);
WrapInFunction(expr);
spirv::Builder& b = Build();
ASSERT_TRUE(b.Build()) << b.error();
EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
OpMemoryModel Logical GLSL450
OpEntryPoint GLCompute %3 "test_function"
OpExecutionMode %3 LocalSize 1 1 1
OpName %3 "test_function"
%2 = OpTypeVoid
%1 = OpTypeFunction %2
%6 = )" + op_type_decl + R"(
%5 = OpTypeVector %6 3
%7 = OpConstant %6 1
%8 = OpConstantComposite %5 %7 %7 %7
%11 = OpTypePointer Function %5
%12 = OpConstantNull %5
%3 = OpFunction %2 None %1
%4 = OpLabel
%10 = OpVariable %11 Function %12
%13 = OpCompositeConstruct %5 %7 %7 %7
%9 = )" + param.name + R"( %5 %8 %13
OpReturn
OpFunctionEnd
)");
Validate(b);
}
TEST_P(MixedBinaryArithTest, ScalarVector) {
auto& param = GetParam();
ast::Expression* lhs = MakeScalarExpr(this, param.type);
ast::Expression* rhs = MakeVectorExpr(this, param.type);
std::string op_type_decl = OpTypeDecl(param.type);
auto* expr = create<ast::BinaryExpression>(param.op, lhs, rhs);
WrapInFunction(expr);
spirv::Builder& b = Build();
ASSERT_TRUE(b.Build()) << b.error();
EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
OpMemoryModel Logical GLSL450
OpEntryPoint GLCompute %3 "test_function"
OpExecutionMode %3 LocalSize 1 1 1
OpName %3 "test_function"
%2 = OpTypeVoid
%1 = OpTypeFunction %2
%5 = )" + op_type_decl + R"(
%6 = OpConstant %5 1
%7 = OpTypeVector %5 3
%8 = OpConstantComposite %7 %6 %6 %6
%11 = OpTypePointer Function %7
%12 = OpConstantNull %7
%3 = OpFunction %2 None %1
%4 = OpLabel
%10 = OpVariable %11 Function %12
%13 = OpCompositeConstruct %7 %6 %6 %6
%9 = )" + param.name + R"( %7 %13 %8
OpReturn
OpFunctionEnd
)");
Validate(b);
}
INSTANTIATE_TEST_SUITE_P(
BuilderTest,
MixedBinaryArithTest,
testing::Values(Param{Type::f32, ast::BinaryOp::kAdd, "OpFAdd"},
Param{Type::f32, ast::BinaryOp::kDivide, "OpFDiv"},
// NOTE: Modulo not allowed on mixed float scalar-vector
// Param{Type::f32, ast::BinaryOp::kModulo, "OpFMod"},
// NOTE: We test f32 multiplies separately as we emit
// OpVectorTimesScalar for this case
// Param{Type::i32, ast::BinaryOp::kMultiply, "OpIMul"},
Param{Type::f32, ast::BinaryOp::kSubtract, "OpFSub"},
Param{Type::i32, ast::BinaryOp::kAdd, "OpIAdd"},
Param{Type::i32, ast::BinaryOp::kDivide, "OpSDiv"},
Param{Type::i32, ast::BinaryOp::kModulo, "OpSMod"},
Param{Type::i32, ast::BinaryOp::kMultiply, "OpIMul"},
Param{Type::i32, ast::BinaryOp::kSubtract, "OpISub"},
Param{Type::u32, ast::BinaryOp::kAdd, "OpIAdd"},
Param{Type::u32, ast::BinaryOp::kDivide, "OpUDiv"},
Param{Type::u32, ast::BinaryOp::kModulo, "OpUMod"},
Param{Type::u32, ast::BinaryOp::kMultiply, "OpIMul"},
Param{Type::u32, ast::BinaryOp::kSubtract, "OpISub"}));
using MixedBinaryArithMultiplyTest = TestParamHelper<Param>;
TEST_P(MixedBinaryArithMultiplyTest, VectorScalar) {
auto& param = GetParam();
ast::Expression* lhs = MakeVectorExpr(this, param.type);
ast::Expression* rhs = MakeScalarExpr(this, param.type);
std::string op_type_decl = OpTypeDecl(param.type);
auto* expr = create<ast::BinaryExpression>(param.op, lhs, rhs);
WrapInFunction(expr);
spirv::Builder& b = Build();
ASSERT_TRUE(b.Build()) << b.error();
EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
OpMemoryModel Logical GLSL450
OpEntryPoint GLCompute %3 "test_function"
OpExecutionMode %3 LocalSize 1 1 1
OpName %3 "test_function"
%2 = OpTypeVoid
%1 = OpTypeFunction %2
%6 = )" + op_type_decl + R"(
%5 = OpTypeVector %6 3
%7 = OpConstant %6 1
%8 = OpConstantComposite %5 %7 %7 %7
%3 = OpFunction %2 None %1
%4 = OpLabel
%9 = OpVectorTimesScalar %5 %8 %7
OpReturn
OpFunctionEnd
)");
Validate(b);
}
TEST_P(MixedBinaryArithMultiplyTest, ScalarVector) {
auto& param = GetParam();
ast::Expression* lhs = MakeScalarExpr(this, param.type);
ast::Expression* rhs = MakeVectorExpr(this, param.type);
std::string op_type_decl = OpTypeDecl(param.type);
auto* expr = create<ast::BinaryExpression>(param.op, lhs, rhs);
WrapInFunction(expr);
spirv::Builder& b = Build();
ASSERT_TRUE(b.Build()) << b.error();
EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
OpMemoryModel Logical GLSL450
OpEntryPoint GLCompute %3 "test_function"
OpExecutionMode %3 LocalSize 1 1 1
OpName %3 "test_function"
%2 = OpTypeVoid
%1 = OpTypeFunction %2
%5 = )" + op_type_decl + R"(
%6 = OpConstant %5 1
%7 = OpTypeVector %5 3
%8 = OpConstantComposite %7 %6 %6 %6
%3 = OpFunction %2 None %1
%4 = OpLabel
%9 = OpVectorTimesScalar %7 %8 %6
OpReturn
OpFunctionEnd
)");
Validate(b);
}
INSTANTIATE_TEST_SUITE_P(BuilderTest,
MixedBinaryArithMultiplyTest,
testing::Values(Param{
Type::f32, ast::BinaryOp::kMultiply, "OpFMul"}));
} // namespace
} // namespace spirv
} // namespace writer

70
test/expressions/binary_expressions.wgsl Normal file
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@ -0,0 +1,70 @@
fn vector_scalar_f32() {
var v : vec3<f32>;
var s : f32;
var r : vec3<f32>;
r = v + s;
r = v - s;
r = v * s;
r = v / s;
//r = v % s;
}
fn vector_scalar_i32() {
var v : vec3<i32>;
var s : i32;
var r : vec3<i32>;
r = v + s;
r = v - s;
r = v * s;
r = v / s;
r = v % s;
}
fn vector_scalar_u32() {
var v : vec3<u32>;
var s : u32;
var r : vec3<u32>;
r = v + s;
r = v - s;
r = v * s;
r = v / s;
r = v % s;
}
fn scalar_vector_f32() {
var v : vec3<f32>;
var s : f32;
var r : vec3<f32>;
r = s + v;
r = s - v;
r = s * v;
r = s / v;
//r = s % v;
}
fn scalar_vector_i32() {
var v : vec3<i32>;
var s : i32;
var r : vec3<i32>;
r = s + v;
r = s - v;
r = s * v;
r = s / v;
r = s % v;
}
fn scalar_vector_u32() {
var v : vec3<u32>;
var s : u32;
var r : vec3<u32>;
r = s + v;
r = s - v;
r = s * v;
r = s / v;
r = s % v;
}
[[stage(fragment)]]
fn main() -> [[location(0)]] vec4<f32> {
return vec4<f32>(0.0,0.0,0.0,0.0);
}

73
test/expressions/binary_expressions.wgsl.expected.hlsl Normal file
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@ -0,0 +1,73 @@
struct tint_symbol {
float4 value : SV_Target0;
};
void vector_scalar_f32() {
float3 v = float3(0.0f, 0.0f, 0.0f);
float s = 0.0f;
float3 r = float3(0.0f, 0.0f, 0.0f);
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
}
void vector_scalar_i32() {
int3 v = int3(0, 0, 0);
int s = 0;
int3 r = int3(0, 0, 0);
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
r = (v % s);
}
void vector_scalar_u32() {
uint3 v = uint3(0u, 0u, 0u);
uint s = 0u;
uint3 r = uint3(0u, 0u, 0u);
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
r = (v % s);
}
void scalar_vector_f32() {
float3 v = float3(0.0f, 0.0f, 0.0f);
float s = 0.0f;
float3 r = float3(0.0f, 0.0f, 0.0f);
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
}
void scalar_vector_i32() {
int3 v = int3(0, 0, 0);
int s = 0;
int3 r = int3(0, 0, 0);
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
r = (s % v);
}
void scalar_vector_u32() {
uint3 v = uint3(0u, 0u, 0u);
uint s = 0u;
uint3 r = uint3(0u, 0u, 0u);
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
r = (s % v);
}
tint_symbol main() {
const tint_symbol tint_symbol_1 = {float4(0.0f, 0.0f, 0.0f, 0.0f)};
return tint_symbol_1;
}

75
test/expressions/binary_expressions.wgsl.expected.msl Normal file
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@ -0,0 +1,75 @@
#include <metal_stdlib>
using namespace metal;
struct tint_symbol_1 {
float4 value [[color(0)]];
};
void vector_scalar_f32() {
float3 v = 0.0f;
float s = 0.0f;
float3 r = 0.0f;
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
}
void vector_scalar_i32() {
int3 v = 0;
int s = 0;
int3 r = 0;
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
r = (v % s);
}
void vector_scalar_u32() {
uint3 v = 0u;
uint s = 0u;
uint3 r = 0u;
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
r = (v % s);
}
void scalar_vector_f32() {
float3 v = 0.0f;
float s = 0.0f;
float3 r = 0.0f;
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
}
void scalar_vector_i32() {
int3 v = 0;
int s = 0;
int3 r = 0;
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
r = (s % v);
}
void scalar_vector_u32() {
uint3 v = 0u;
uint s = 0u;
uint3 r = 0u;
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
r = (s % v);
}
fragment tint_symbol_1 tint_symbol() {
return {float4(0.0f, 0.0f, 0.0f, 0.0f)};
}

282
test/expressions/binary_expressions.wgsl.expected.spvasm Normal file
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@ -0,0 +1,282 @@
; SPIR-V
; Version: 1.3
; Generator: Google Tint Compiler; 0
; Bound: 200
; Schema: 0
OpCapability Shader
OpMemoryModel Logical GLSL450
OpEntryPoint Fragment %main "main" %tint_symbol_1
OpExecutionMode %main OriginUpperLeft
OpName %tint_symbol_1 "tint_symbol_1"
OpName %vector_scalar_f32 "vector_scalar_f32"
OpName %v "v"
OpName %s "s"
OpName %r "r"
OpName %vector_scalar_i32 "vector_scalar_i32"
OpName %v_0 "v"
OpName %s_0 "s"
OpName %r_0 "r"
OpName %vector_scalar_u32 "vector_scalar_u32"
OpName %v_1 "v"
OpName %s_1 "s"
OpName %r_1 "r"
OpName %scalar_vector_f32 "scalar_vector_f32"
OpName %v_2 "v"
OpName %s_2 "s"
OpName %r_2 "r"
OpName %scalar_vector_i32 "scalar_vector_i32"
OpName %v_3 "v"
OpName %s_3 "s"
OpName %r_3 "r"
OpName %scalar_vector_u32 "scalar_vector_u32"
OpName %v_4 "v"
OpName %s_4 "s"
OpName %r_4 "r"
OpName %tint_symbol_2 "tint_symbol_2"
OpName %tint_symbol "tint_symbol"
OpName %main "main"
OpDecorate %tint_symbol_1 Location 0
%float = OpTypeFloat 32
%v4float = OpTypeVector %float 4
%_ptr_Output_v4float = OpTypePointer Output %v4float
%5 = OpConstantNull %v4float
%tint_symbol_1 = OpVariable %_ptr_Output_v4float Output %5
%void = OpTypeVoid
%6 = OpTypeFunction %void
%v3float = OpTypeVector %float 3
%_ptr_Function_v3float = OpTypePointer Function %v3float
%13 = OpConstantNull %v3float
%_ptr_Function_float = OpTypePointer Function %float
%16 = OpConstantNull %float
%int = OpTypeInt 32 1
%v3int = OpTypeVector %int 3
%_ptr_Function_v3int = OpTypePointer Function %v3int
%42 = OpConstantNull %v3int
%_ptr_Function_int = OpTypePointer Function %int
%45 = OpConstantNull %int
%uint = OpTypeInt 32 0
%v3uint = OpTypeVector %uint 3
%_ptr_Function_v3uint = OpTypePointer Function %v3uint
%78 = OpConstantNull %v3uint
%_ptr_Function_uint = OpTypePointer Function %uint
%81 = OpConstantNull %uint
%191 = OpTypeFunction %void %v4float
%float_0 = OpConstant %float 0
%199 = OpConstantComposite %v4float %float_0 %float_0 %float_0 %float_0
%vector_scalar_f32 = OpFunction %void None %6
%9 = OpLabel
%v = OpVariable %_ptr_Function_v3float Function %13
%s = OpVariable %_ptr_Function_float Function %16
%r = OpVariable %_ptr_Function_v3float Function %13
%21 = OpVariable %_ptr_Function_v3float Function %13
%26 = OpVariable %_ptr_Function_v3float Function %13
%34 = OpVariable %_ptr_Function_v3float Function %13
%18 = OpLoad %v3float %v
%19 = OpLoad %float %s
%22 = OpCompositeConstruct %v3float %19 %19 %19
%20 = OpFAdd %v3float %18 %22
OpStore %r %20
%23 = OpLoad %v3float %v
%24 = OpLoad %float %s
%27 = OpCompositeConstruct %v3float %24 %24 %24
%25 = OpFSub %v3float %23 %27
OpStore %r %25
%28 = OpLoad %v3float %v
%29 = OpLoad %float %s
%30 = OpVectorTimesScalar %v3float %28 %29
OpStore %r %30
%31 = OpLoad %v3float %v
%32 = OpLoad %float %s
%35 = OpCompositeConstruct %v3float %32 %32 %32
%33 = OpFDiv %v3float %31 %35
OpStore %r %33
OpReturn
OpFunctionEnd
%vector_scalar_i32 = OpFunction %void None %6
%37 = OpLabel
%v_0 = OpVariable %_ptr_Function_v3int Function %42
%s_0 = OpVariable %_ptr_Function_int Function %45
%r_0 = OpVariable %_ptr_Function_v3int Function %42
%50 = OpVariable %_ptr_Function_v3int Function %42
%55 = OpVariable %_ptr_Function_v3int Function %42
%60 = OpVariable %_ptr_Function_v3int Function %42
%65 = OpVariable %_ptr_Function_v3int Function %42
%70 = OpVariable %_ptr_Function_v3int Function %42
%47 = OpLoad %v3int %v_0
%48 = OpLoad %int %s_0
%51 = OpCompositeConstruct %v3int %48 %48 %48
%49 = OpIAdd %v3int %47 %51
OpStore %r_0 %49
%52 = OpLoad %v3int %v_0
%53 = OpLoad %int %s_0
%56 = OpCompositeConstruct %v3int %53 %53 %53
%54 = OpISub %v3int %52 %56
OpStore %r_0 %54
%57 = OpLoad %v3int %v_0
%58 = OpLoad %int %s_0
%61 = OpCompositeConstruct %v3int %58 %58 %58
%59 = OpIMul %v3int %57 %61
OpStore %r_0 %59
%62 = OpLoad %v3int %v_0
%63 = OpLoad %int %s_0
%66 = OpCompositeConstruct %v3int %63 %63 %63
%64 = OpSDiv %v3int %62 %66
OpStore %r_0 %64
%67 = OpLoad %v3int %v_0
%68 = OpLoad %int %s_0
%71 = OpCompositeConstruct %v3int %68 %68 %68
%69 = OpSMod %v3int %67 %71
OpStore %r_0 %69
OpReturn
OpFunctionEnd
%vector_scalar_u32 = OpFunction %void None %6
%73 = OpLabel
%v_1 = OpVariable %_ptr_Function_v3uint Function %78
%s_1 = OpVariable %_ptr_Function_uint Function %81
%r_1 = OpVariable %_ptr_Function_v3uint Function %78
%86 = OpVariable %_ptr_Function_v3uint Function %78
%91 = OpVariable %_ptr_Function_v3uint Function %78
%96 = OpVariable %_ptr_Function_v3uint Function %78
%101 = OpVariable %_ptr_Function_v3uint Function %78
%106 = OpVariable %_ptr_Function_v3uint Function %78
%83 = OpLoad %v3uint %v_1
%84 = OpLoad %uint %s_1
%87 = OpCompositeConstruct %v3uint %84 %84 %84
%85 = OpIAdd %v3uint %83 %87
OpStore %r_1 %85
%88 = OpLoad %v3uint %v_1
%89 = OpLoad %uint %s_1
%92 = OpCompositeConstruct %v3uint %89 %89 %89
%90 = OpISub %v3uint %88 %92
OpStore %r_1 %90
%93 = OpLoad %v3uint %v_1
%94 = OpLoad %uint %s_1
%97 = OpCompositeConstruct %v3uint %94 %94 %94
%95 = OpIMul %v3uint %93 %97
OpStore %r_1 %95
%98 = OpLoad %v3uint %v_1
%99 = OpLoad %uint %s_1
%102 = OpCompositeConstruct %v3uint %99 %99 %99
%100 = OpUDiv %v3uint %98 %102
OpStore %r_1 %100
%103 = OpLoad %v3uint %v_1
%104 = OpLoad %uint %s_1
%107 = OpCompositeConstruct %v3uint %104 %104 %104
%105 = OpUMod %v3uint %103 %107
OpStore %r_1 %105
OpReturn
OpFunctionEnd
%scalar_vector_f32 = OpFunction %void None %6
%109 = OpLabel
%v_2 = OpVariable %_ptr_Function_v3float Function %13
%s_2 = OpVariable %_ptr_Function_float Function %16
%r_2 = OpVariable %_ptr_Function_v3float Function %13
%116 = OpVariable %_ptr_Function_v3float Function %13
%121 = OpVariable %_ptr_Function_v3float Function %13
%129 = OpVariable %_ptr_Function_v3float Function %13
%113 = OpLoad %float %s_2
%114 = OpLoad %v3float %v_2
%117 = OpCompositeConstruct %v3float %113 %113 %113
%115 = OpFAdd %v3float %117 %114
OpStore %r_2 %115
%118 = OpLoad %float %s_2
%119 = OpLoad %v3float %v_2
%122 = OpCompositeConstruct %v3float %118 %118 %118
%120 = OpFSub %v3float %122 %119
OpStore %r_2 %120
%123 = OpLoad %float %s_2
%124 = OpLoad %v3float %v_2
%125 = OpVectorTimesScalar %v3float %124 %123
OpStore %r_2 %125
%126 = OpLoad %float %s_2
%127 = OpLoad %v3float %v_2
%130 = OpCompositeConstruct %v3float %126 %126 %126
%128 = OpFDiv %v3float %130 %127
OpStore %r_2 %128
OpReturn
OpFunctionEnd
%scalar_vector_i32 = OpFunction %void None %6
%132 = OpLabel
%v_3 = OpVariable %_ptr_Function_v3int Function %42
%s_3 = OpVariable %_ptr_Function_int Function %45
%r_3 = OpVariable %_ptr_Function_v3int Function %42
%139 = OpVariable %_ptr_Function_v3int Function %42
%144 = OpVariable %_ptr_Function_v3int Function %42
%149 = OpVariable %_ptr_Function_v3int Function %42
%154 = OpVariable %_ptr_Function_v3int Function %42
%159 = OpVariable %_ptr_Function_v3int Function %42
%136 = OpLoad %int %s_3
%137 = OpLoad %v3int %v_3
%140 = OpCompositeConstruct %v3int %136 %136 %136
%138 = OpIAdd %v3int %140 %137
OpStore %r_3 %138
%141 = OpLoad %int %s_3
%142 = OpLoad %v3int %v_3
%145 = OpCompositeConstruct %v3int %141 %141 %141
%143 = OpISub %v3int %145 %142
OpStore %r_3 %143
%146 = OpLoad %int %s_3
%147 = OpLoad %v3int %v_3
%150 = OpCompositeConstruct %v3int %146 %146 %146
%148 = OpIMul %v3int %150 %147
OpStore %r_3 %148
%151 = OpLoad %int %s_3
%152 = OpLoad %v3int %v_3
%155 = OpCompositeConstruct %v3int %151 %151 %151
%153 = OpSDiv %v3int %155 %152
OpStore %r_3 %153
%156 = OpLoad %int %s_3
%157 = OpLoad %v3int %v_3
%160 = OpCompositeConstruct %v3int %156 %156 %156
%158 = OpSMod %v3int %160 %157
OpStore %r_3 %158
OpReturn
OpFunctionEnd
%scalar_vector_u32 = OpFunction %void None %6
%162 = OpLabel
%v_4 = OpVariable %_ptr_Function_v3uint Function %78
%s_4 = OpVariable %_ptr_Function_uint Function %81
%r_4 = OpVariable %_ptr_Function_v3uint Function %78
%169 = OpVariable %_ptr_Function_v3uint Function %78
%174 = OpVariable %_ptr_Function_v3uint Function %78
%179 = OpVariable %_ptr_Function_v3uint Function %78
%184 = OpVariable %_ptr_Function_v3uint Function %78
%189 = OpVariable %_ptr_Function_v3uint Function %78
%166 = OpLoad %uint %s_4
%167 = OpLoad %v3uint %v_4
%170 = OpCompositeConstruct %v3uint %166 %166 %166
%168 = OpIAdd %v3uint %170 %167
OpStore %r_4 %168
%171 = OpLoad %uint %s_4
%172 = OpLoad %v3uint %v_4
%175 = OpCompositeConstruct %v3uint %171 %171 %171
%173 = OpISub %v3uint %175 %172
OpStore %r_4 %173
%176 = OpLoad %uint %s_4
%177 = OpLoad %v3uint %v_4
%180 = OpCompositeConstruct %v3uint %176 %176 %176
%178 = OpIMul %v3uint %180 %177
OpStore %r_4 %178
%181 = OpLoad %uint %s_4
%182 = OpLoad %v3uint %v_4
%185 = OpCompositeConstruct %v3uint %181 %181 %181
%183 = OpUDiv %v3uint %185 %182
OpStore %r_4 %183
%186 = OpLoad %uint %s_4
%187 = OpLoad %v3uint %v_4
%190 = OpCompositeConstruct %v3uint %186 %186 %186
%188 = OpUMod %v3uint %190 %187
OpStore %r_4 %188
OpReturn
OpFunctionEnd
%tint_symbol_2 = OpFunction %void None %191
%tint_symbol = OpFunctionParameter %v4float
%194 = OpLabel
OpStore %tint_symbol_1 %tint_symbol
OpReturn
OpFunctionEnd
%main = OpFunction %void None %6
%196 = OpLabel
%197 = OpFunctionCall %void %tint_symbol_2 %199
OpReturn
OpFunctionEnd

68
test/expressions/binary_expressions.wgsl.expected.wgsl Normal file
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fn vector_scalar_f32() {
var v : vec3<f32>;
var s : f32;
var r : vec3<f32>;
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
}
fn vector_scalar_i32() {
var v : vec3<i32>;
var s : i32;
var r : vec3<i32>;
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
r = (v % s);
}
fn vector_scalar_u32() {
var v : vec3<u32>;
var s : u32;
var r : vec3<u32>;
r = (v + s);
r = (v - s);
r = (v * s);
r = (v / s);
r = (v % s);
}
fn scalar_vector_f32() {
var v : vec3<f32>;
var s : f32;
var r : vec3<f32>;
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
}
fn scalar_vector_i32() {
var v : vec3<i32>;
var s : i32;
var r : vec3<i32>;
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
r = (s % v);
}
fn scalar_vector_u32() {
var v : vec3<u32>;
var s : u32;
var r : vec3<u32>;
r = (s + v);
r = (s - v);
r = (s * v);
r = (s / v);
r = (s % v);
}
[[stage(fragment)]]
fn main() -> [[location(0)]] vec4<f32> {
return vec4<f32>(0.0, 0.0, 0.0, 0.0);
}