src/transform/canonicalize_entry_point_io_test.cc

// Copyright 2021 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 "src/transform/canonicalize_entry_point_io.h"

#include "src/transform/test_helper.h"

namespace tint {
namespace transform {
namespace {

using CanonicalizeEntryPointIOTest = TransformTest;

TEST_F(CanonicalizeEntryPointIOTest, Error_MissingTransformData) {
  auto* src = "";

  auto* expect =
      "error: missing transform data for "
      "tint::transform::CanonicalizeEntryPointIO";

  auto got = Run<CanonicalizeEntryPointIO>(src);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, NoShaderIO) {
  // Test that we do not introduce wrapper functions when there is no shader IO
  // to process.
  auto* src = R"(
[[stage(fragment)]]
fn frag_main() {
}

[[stage(compute), workgroup_size(1)]]
fn comp_main() {
}
)";

  auto* expect = src;

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Parameters_Spirv) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main([[location(1)]] loc1 : f32,
             [[location(2)]] loc2 : vec4<u32>,
             [[builtin(position)]] coord : vec4<f32>) {
  var col : f32 = (coord.x * loc1);
}
)";

  auto* expect = R"(
[[location(1), internal(disable_validation__ignore_storage_class)]] var<in> loc1_1 : f32;

[[location(2), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<in> loc2_1 : vec4<u32>;

[[builtin(position), internal(disable_validation__ignore_storage_class)]] var<in> coord_1 : vec4<f32>;

fn frag_main_inner(loc1 : f32, loc2 : vec4<u32>, coord : vec4<f32>) {
  var col : f32 = (coord.x * loc1);
}

[[stage(fragment)]]
fn frag_main() {
  frag_main_inner(loc1_1, loc2_1, coord_1);
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Parameters_Msl) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main([[location(1)]] loc1 : f32,
             [[location(2)]] loc2 : vec4<u32>,
             [[builtin(position)]] coord : vec4<f32>) {
  var col : f32 = (coord.x * loc1);
}
)";

  auto* expect = R"(
struct tint_symbol_1 {
  [[location(1)]]
  loc1 : f32;
  [[location(2)]]
  loc2 : vec4<u32>;
};

fn frag_main_inner(loc1 : f32, loc2 : vec4<u32>, coord : vec4<f32>) {
  var col : f32 = (coord.x * loc1);
}

[[stage(fragment)]]
fn frag_main([[builtin(position)]] coord : vec4<f32>, tint_symbol : tint_symbol_1) {
  frag_main_inner(tint_symbol.loc1, tint_symbol.loc2, coord);
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Parameters_Hlsl) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main([[location(1)]] loc1 : f32,
             [[location(2)]] loc2 : vec4<u32>,
             [[builtin(position)]] coord : vec4<f32>) {
  var col : f32 = (coord.x * loc1);
}
)";

  auto* expect = R"(
struct tint_symbol_1 {
  [[location(1)]]
  loc1 : f32;
  [[location(2)]]
  loc2 : vec4<u32>;
  [[builtin(position)]]
  coord : vec4<f32>;
};

fn frag_main_inner(loc1 : f32, loc2 : vec4<u32>, coord : vec4<f32>) {
  var col : f32 = (coord.x * loc1);
}

[[stage(fragment)]]
fn frag_main(tint_symbol : tint_symbol_1) {
  frag_main_inner(tint_symbol.loc1, tint_symbol.loc2, tint_symbol.coord);
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Parameter_TypeAlias) {
  auto* src = R"(
type myf32 = f32;

[[stage(fragment)]]
fn frag_main([[location(1)]] loc1 : myf32) {
  var x : myf32 = loc1;
}
)";

  auto* expect = R"(
type myf32 = f32;

struct tint_symbol_1 {
  [[location(1)]]
  loc1 : myf32;
};

fn frag_main_inner(loc1 : myf32) {
  var x : myf32 = loc1;
}

[[stage(fragment)]]
fn frag_main(tint_symbol : tint_symbol_1) {
  frag_main_inner(tint_symbol.loc1);
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, StructParameters_Spirv) {
  auto* src = R"(
struct FragBuiltins {
  [[builtin(position)]] coord : vec4<f32>;
};
struct FragLocations {
  [[location(1)]] loc1 : f32;
  [[location(2)]] loc2 : vec4<u32>;
};

[[stage(fragment)]]
fn frag_main([[location(0)]] loc0 : f32,
             locations : FragLocations,
             builtins : FragBuiltins) {
  var col : f32 = ((builtins.coord.x * locations.loc1) + loc0);
}
)";

  auto* expect = R"(
[[location(0), internal(disable_validation__ignore_storage_class)]] var<in> loc0_1 : f32;

[[location(1), internal(disable_validation__ignore_storage_class)]] var<in> loc1_1 : f32;

[[location(2), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<in> loc2_1 : vec4<u32>;

[[builtin(position), internal(disable_validation__ignore_storage_class)]] var<in> coord_1 : vec4<f32>;

struct FragBuiltins {
  coord : vec4<f32>;
};

struct FragLocations {
  loc1 : f32;
  loc2 : vec4<u32>;
};

fn frag_main_inner(loc0 : f32, locations : FragLocations, builtins : FragBuiltins) {
  var col : f32 = ((builtins.coord.x * locations.loc1) + loc0);
}

[[stage(fragment)]]
fn frag_main() {
  frag_main_inner(loc0_1, FragLocations(loc1_1, loc2_1), FragBuiltins(coord_1));
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, StructParameters_kMsl) {
  auto* src = R"(
struct FragBuiltins {
  [[builtin(position)]] coord : vec4<f32>;
};
struct FragLocations {
  [[location(1)]] loc1 : f32;
  [[location(2)]] loc2 : vec4<u32>;
};

[[stage(fragment)]]
fn frag_main([[location(0)]] loc0 : f32,
             locations : FragLocations,
             builtins : FragBuiltins) {
  var col : f32 = ((builtins.coord.x * locations.loc1) + loc0);
}
)";

  auto* expect = R"(
struct FragBuiltins {
  coord : vec4<f32>;
};

struct FragLocations {
  loc1 : f32;
  loc2 : vec4<u32>;
};

struct tint_symbol_1 {
  [[location(0)]]
  loc0 : f32;
  [[location(1)]]
  loc1 : f32;
  [[location(2)]]
  loc2 : vec4<u32>;
};

fn frag_main_inner(loc0 : f32, locations : FragLocations, builtins : FragBuiltins) {
  var col : f32 = ((builtins.coord.x * locations.loc1) + loc0);
}

[[stage(fragment)]]
fn frag_main([[builtin(position)]] coord : vec4<f32>, tint_symbol : tint_symbol_1) {
  frag_main_inner(tint_symbol.loc0, FragLocations(tint_symbol.loc1, tint_symbol.loc2), FragBuiltins(coord));
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, StructParameters_Hlsl) {
  auto* src = R"(
struct FragBuiltins {
  [[builtin(position)]] coord : vec4<f32>;
};
struct FragLocations {
  [[location(1)]] loc1 : f32;
  [[location(2)]] loc2 : vec4<u32>;
};

[[stage(fragment)]]
fn frag_main([[location(0)]] loc0 : f32,
             locations : FragLocations,
             builtins : FragBuiltins) {
  var col : f32 = ((builtins.coord.x * locations.loc1) + loc0);
}
)";

  auto* expect = R"(
struct FragBuiltins {
  coord : vec4<f32>;
};

struct FragLocations {
  loc1 : f32;
  loc2 : vec4<u32>;
};

struct tint_symbol_1 {
  [[location(0)]]
  loc0 : f32;
  [[location(1)]]
  loc1 : f32;
  [[location(2)]]
  loc2 : vec4<u32>;
  [[builtin(position)]]
  coord : vec4<f32>;
};

fn frag_main_inner(loc0 : f32, locations : FragLocations, builtins : FragBuiltins) {
  var col : f32 = ((builtins.coord.x * locations.loc1) + loc0);
}

[[stage(fragment)]]
fn frag_main(tint_symbol : tint_symbol_1) {
  frag_main_inner(tint_symbol.loc0, FragLocations(tint_symbol.loc1, tint_symbol.loc2), FragBuiltins(tint_symbol.coord));
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Return_NonStruct_Spirv) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main() -> [[builtin(frag_depth)]] f32 {
  return 1.0;
}
)";

  auto* expect = R"(
[[builtin(frag_depth), internal(disable_validation__ignore_storage_class)]] var<out> value : f32;

fn frag_main_inner() -> f32 {
  return 1.0;
}

[[stage(fragment)]]
fn frag_main() {
  let inner_result = frag_main_inner();
  value = inner_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Return_NonStruct_Msl) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main() -> [[builtin(frag_depth)]] f32 {
  return 1.0;
}
)";

  auto* expect = R"(
struct tint_symbol {
  [[builtin(frag_depth)]]
  value : f32;
};

fn frag_main_inner() -> f32 {
  return 1.0;
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.value = inner_result;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Return_NonStruct_Hlsl) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main() -> [[builtin(frag_depth)]] f32 {
  return 1.0;
}
)";

  auto* expect = R"(
struct tint_symbol {
  [[builtin(frag_depth)]]
  value : f32;
};

fn frag_main_inner() -> f32 {
  return 1.0;
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.value = inner_result;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Return_Struct_Spirv) {
  auto* src = R"(
struct FragOutput {
  [[location(0)]] color : vec4<f32>;
  [[builtin(frag_depth)]] depth : f32;
  [[builtin(sample_mask)]] mask : u32;
};

[[stage(fragment)]]
fn frag_main() -> FragOutput {
  var output : FragOutput;
  output.depth = 1.0;
  output.mask = 7u;
  output.color = vec4<f32>(0.5, 0.5, 0.5, 1.0);
  return output;
}
)";

  auto* expect = R"(
[[location(0), internal(disable_validation__ignore_storage_class)]] var<out> color_1 : vec4<f32>;

[[builtin(frag_depth), internal(disable_validation__ignore_storage_class)]] var<out> depth_1 : f32;

[[builtin(sample_mask), internal(disable_validation__ignore_storage_class)]] var<out> mask_1 : u32;

struct FragOutput {
  color : vec4<f32>;
  depth : f32;
  mask : u32;
};

fn frag_main_inner() -> FragOutput {
  var output : FragOutput;
  output.depth = 1.0;
  output.mask = 7u;
  output.color = vec4<f32>(0.5, 0.5, 0.5, 1.0);
  return output;
}

[[stage(fragment)]]
fn frag_main() {
  let inner_result = frag_main_inner();
  color_1 = inner_result.color;
  depth_1 = inner_result.depth;
  mask_1 = inner_result.mask;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Return_Struct_Msl) {
  auto* src = R"(
struct FragOutput {
  [[location(0)]] color : vec4<f32>;
  [[builtin(frag_depth)]] depth : f32;
  [[builtin(sample_mask)]] mask : u32;
};

[[stage(fragment)]]
fn frag_main() -> FragOutput {
  var output : FragOutput;
  output.depth = 1.0;
  output.mask = 7u;
  output.color = vec4<f32>(0.5, 0.5, 0.5, 1.0);
  return output;
}
)";

  auto* expect = R"(
struct FragOutput {
  color : vec4<f32>;
  depth : f32;
  mask : u32;
};

struct tint_symbol {
  [[location(0)]]
  color : vec4<f32>;
  [[builtin(frag_depth)]]
  depth : f32;
  [[builtin(sample_mask)]]
  mask : u32;
};

fn frag_main_inner() -> FragOutput {
  var output : FragOutput;
  output.depth = 1.0;
  output.mask = 7u;
  output.color = vec4<f32>(0.5, 0.5, 0.5, 1.0);
  return output;
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.color = inner_result.color;
  wrapper_result.depth = inner_result.depth;
  wrapper_result.mask = inner_result.mask;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Return_Struct_Hlsl) {
  auto* src = R"(
struct FragOutput {
  [[location(0)]] color : vec4<f32>;
  [[builtin(frag_depth)]] depth : f32;
  [[builtin(sample_mask)]] mask : u32;
};

[[stage(fragment)]]
fn frag_main() -> FragOutput {
  var output : FragOutput;
  output.depth = 1.0;
  output.mask = 7u;
  output.color = vec4<f32>(0.5, 0.5, 0.5, 1.0);
  return output;
}
)";

  auto* expect = R"(
struct FragOutput {
  color : vec4<f32>;
  depth : f32;
  mask : u32;
};

struct tint_symbol {
  [[location(0)]]
  color : vec4<f32>;
  [[builtin(frag_depth)]]
  depth : f32;
  [[builtin(sample_mask)]]
  mask : u32;
};

fn frag_main_inner() -> FragOutput {
  var output : FragOutput;
  output.depth = 1.0;
  output.mask = 7u;
  output.color = vec4<f32>(0.5, 0.5, 0.5, 1.0);
  return output;
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.color = inner_result.color;
  wrapper_result.depth = inner_result.depth;
  wrapper_result.mask = inner_result.mask;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest,
       StructParameters_SharedDeviceFunction_Spirv) {
  auto* src = R"(
struct FragmentInput {
  [[location(0)]] value : f32;
  [[location(1)]] mul : f32;
};

fn foo(x : FragmentInput) -> f32 {
  return x.value * x.mul;
}

[[stage(fragment)]]
fn frag_main1(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main2(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}
)";

  auto* expect = R"(
[[location(0), internal(disable_validation__ignore_storage_class)]] var<in> value_1 : f32;

[[location(1), internal(disable_validation__ignore_storage_class)]] var<in> mul_1 : f32;

[[location(0), internal(disable_validation__ignore_storage_class)]] var<in> value_2 : f32;

[[location(1), internal(disable_validation__ignore_storage_class)]] var<in> mul_2 : f32;

struct FragmentInput {
  value : f32;
  mul : f32;
};

fn foo(x : FragmentInput) -> f32 {
  return (x.value * x.mul);
}

fn frag_main1_inner(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main1() {
  frag_main1_inner(FragmentInput(value_1, mul_1));
}

fn frag_main2_inner(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main2() {
  frag_main2_inner(FragmentInput(value_2, mul_2));
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest,
       StructParameters_SharedDeviceFunction_Msl) {
  auto* src = R"(
struct FragmentInput {
  [[location(0)]] value : f32;
  [[location(1)]] mul : f32;
};

fn foo(x : FragmentInput) -> f32 {
  return x.value * x.mul;
}

[[stage(fragment)]]
fn frag_main1(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main2(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}
)";

  auto* expect = R"(
struct FragmentInput {
  value : f32;
  mul : f32;
};

fn foo(x : FragmentInput) -> f32 {
  return (x.value * x.mul);
}

struct tint_symbol_1 {
  [[location(0)]]
  value : f32;
  [[location(1)]]
  mul : f32;
};

fn frag_main1_inner(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main1(tint_symbol : tint_symbol_1) {
  frag_main1_inner(FragmentInput(tint_symbol.value, tint_symbol.mul));
}

struct tint_symbol_3 {
  [[location(0)]]
  value : f32;
  [[location(1)]]
  mul : f32;
};

fn frag_main2_inner(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main2(tint_symbol_2 : tint_symbol_3) {
  frag_main2_inner(FragmentInput(tint_symbol_2.value, tint_symbol_2.mul));
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest,
       StructParameters_SharedDeviceFunction_Hlsl) {
  auto* src = R"(
struct FragmentInput {
  [[location(0)]] value : f32;
  [[location(1)]] mul : f32;
};

fn foo(x : FragmentInput) -> f32 {
  return x.value * x.mul;
}

[[stage(fragment)]]
fn frag_main1(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main2(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}
)";

  auto* expect = R"(
struct FragmentInput {
  value : f32;
  mul : f32;
};

fn foo(x : FragmentInput) -> f32 {
  return (x.value * x.mul);
}

struct tint_symbol_1 {
  [[location(0)]]
  value : f32;
  [[location(1)]]
  mul : f32;
};

fn frag_main1_inner(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main1(tint_symbol : tint_symbol_1) {
  frag_main1_inner(FragmentInput(tint_symbol.value, tint_symbol.mul));
}

struct tint_symbol_3 {
  [[location(0)]]
  value : f32;
  [[location(1)]]
  mul : f32;
};

fn frag_main2_inner(inputs : FragmentInput) {
  var x : f32 = foo(inputs);
}

[[stage(fragment)]]
fn frag_main2(tint_symbol_2 : tint_symbol_3) {
  frag_main2_inner(FragmentInput(tint_symbol_2.value, tint_symbol_2.mul));
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Struct_ModuleScopeVariable) {
  auto* src = R"(
struct FragmentInput {
  [[location(0)]] col1 : f32;
  [[location(1)]] col2 : f32;
};

var<private> global_inputs : FragmentInput;

fn foo() -> f32 {
  return global_inputs.col1 * 0.5;
}

fn bar() -> f32 {
  return global_inputs.col2 * 2.0;
}

[[stage(fragment)]]
fn frag_main1(inputs : FragmentInput) {
 global_inputs = inputs;
 var r : f32 = foo();
 var g : f32 = bar();
}
)";

  auto* expect = R"(
struct FragmentInput {
  col1 : f32;
  col2 : f32;
};

var<private> global_inputs : FragmentInput;

fn foo() -> f32 {
  return (global_inputs.col1 * 0.5);
}

fn bar() -> f32 {
  return (global_inputs.col2 * 2.0);
}

struct tint_symbol_1 {
  [[location(0)]]
  col1 : f32;
  [[location(1)]]
  col2 : f32;
};

fn frag_main1_inner(inputs : FragmentInput) {
  global_inputs = inputs;
  var r : f32 = foo();
  var g : f32 = bar();
}

[[stage(fragment)]]
fn frag_main1(tint_symbol : tint_symbol_1) {
  frag_main1_inner(FragmentInput(tint_symbol.col1, tint_symbol.col2));
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Struct_TypeAliases) {
  auto* src = R"(
type myf32 = f32;

struct FragmentInput {
  [[location(0)]] col1 : myf32;
  [[location(1)]] col2 : myf32;
};

struct FragmentOutput {
  [[location(0)]] col1 : myf32;
  [[location(1)]] col2 : myf32;
};

type MyFragmentInput = FragmentInput;

type MyFragmentOutput = FragmentOutput;

fn foo(x : MyFragmentInput) -> myf32 {
  return x.col1;
}

[[stage(fragment)]]
fn frag_main(inputs : MyFragmentInput) -> MyFragmentOutput {
  var x : myf32 = foo(inputs);
  return MyFragmentOutput(x, inputs.col2);
}
)";

  auto* expect = R"(
type myf32 = f32;

struct FragmentInput {
  col1 : myf32;
  col2 : myf32;
};

struct FragmentOutput {
  col1 : myf32;
  col2 : myf32;
};

type MyFragmentInput = FragmentInput;

type MyFragmentOutput = FragmentOutput;

fn foo(x : MyFragmentInput) -> myf32 {
  return x.col1;
}

struct tint_symbol_1 {
  [[location(0)]]
  col1 : myf32;
  [[location(1)]]
  col2 : myf32;
};

struct tint_symbol_2 {
  [[location(0)]]
  col1 : myf32;
  [[location(1)]]
  col2 : myf32;
};

fn frag_main_inner(inputs : MyFragmentInput) -> MyFragmentOutput {
  var x : myf32 = foo(inputs);
  return MyFragmentOutput(x, inputs.col2);
}

[[stage(fragment)]]
fn frag_main(tint_symbol : tint_symbol_1) -> tint_symbol_2 {
  let inner_result = frag_main_inner(MyFragmentInput(tint_symbol.col1, tint_symbol.col2));
  var wrapper_result : tint_symbol_2;
  wrapper_result.col1 = inner_result.col1;
  wrapper_result.col2 = inner_result.col2;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, InterpolateAttributes) {
  auto* src = R"(
struct VertexOut {
  [[builtin(position)]] pos : vec4<f32>;
  [[location(1), interpolate(flat)]] loc1: f32;
  [[location(2), interpolate(linear, sample)]] loc2 : f32;
  [[location(3), interpolate(perspective, centroid)]] loc3 : f32;
};

struct FragmentIn {
  [[location(1), interpolate(flat)]] loc1: f32;
  [[location(2), interpolate(linear, sample)]] loc2 : f32;
};

[[stage(vertex)]]
fn vert_main() -> VertexOut {
  return VertexOut();
}

[[stage(fragment)]]
fn frag_main(inputs : FragmentIn,
             [[location(3), interpolate(perspective, centroid)]] loc3 : f32) {
  let x = inputs.loc1 + inputs.loc2 + loc3;
}
)";

  auto* expect = R"(
struct VertexOut {
  pos : vec4<f32>;
  loc1 : f32;
  loc2 : f32;
  loc3 : f32;
};

struct FragmentIn {
  loc1 : f32;
  loc2 : f32;
};

struct tint_symbol {
  [[location(1), interpolate(flat)]]
  loc1 : f32;
  [[location(2), interpolate(linear, sample)]]
  loc2 : f32;
  [[location(3), interpolate(perspective, centroid)]]
  loc3 : f32;
  [[builtin(position)]]
  pos : vec4<f32>;
};

fn vert_main_inner() -> VertexOut {
  return VertexOut();
}

[[stage(vertex)]]
fn vert_main() -> tint_symbol {
  let inner_result = vert_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.pos = inner_result.pos;
  wrapper_result.loc1 = inner_result.loc1;
  wrapper_result.loc2 = inner_result.loc2;
  wrapper_result.loc3 = inner_result.loc3;
  return wrapper_result;
}

struct tint_symbol_2 {
  [[location(1), interpolate(flat)]]
  loc1 : f32;
  [[location(2), interpolate(linear, sample)]]
  loc2 : f32;
  [[location(3), interpolate(perspective, centroid)]]
  loc3 : f32;
};

fn frag_main_inner(inputs : FragmentIn, loc3 : f32) {
  let x = ((inputs.loc1 + inputs.loc2) + loc3);
}

[[stage(fragment)]]
fn frag_main(tint_symbol_1 : tint_symbol_2) {
  frag_main_inner(FragmentIn(tint_symbol_1.loc1, tint_symbol_1.loc2), tint_symbol_1.loc3);
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, InterpolateAttributes_Integers_Spirv) {
  // Test that we add a Flat attribute to integers that are vertex outputs and
  // fragment inputs, but not vertex inputs or fragment outputs.
  auto* src = R"(
struct VertexIn {
  [[location(0)]] i : i32;
  [[location(1)]] u : u32;
  [[location(2)]] vi : vec4<i32>;
  [[location(3)]] vu : vec4<u32>;
};

struct VertexOut {
  [[location(0)]] i : i32;
  [[location(1)]] u : u32;
  [[location(2)]] vi : vec4<i32>;
  [[location(3)]] vu : vec4<u32>;
  [[builtin(position)]] pos : vec4<f32>;
};

struct FragmentInterface {
  [[location(0)]] i : i32;
  [[location(1)]] u : u32;
  [[location(2)]] vi : vec4<i32>;
  [[location(3)]] vu : vec4<u32>;
};

[[stage(vertex)]]
fn vert_main(in : VertexIn) -> VertexOut {
  return VertexOut(in.i, in.u, in.vi, in.vu, vec4<f32>());
}

[[stage(fragment)]]
fn frag_main(inputs : FragmentInterface) -> FragmentInterface {
  return inputs;
}
)";

  auto* expect =
      R"(
[[location(0), internal(disable_validation__ignore_storage_class)]] var<in> i_1 : i32;

[[location(1), internal(disable_validation__ignore_storage_class)]] var<in> u_1 : u32;

[[location(2), internal(disable_validation__ignore_storage_class)]] var<in> vi_1 : vec4<i32>;

[[location(3), internal(disable_validation__ignore_storage_class)]] var<in> vu_1 : vec4<u32>;

[[location(0), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<out> i_2 : i32;

[[location(1), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<out> u_2 : u32;

[[location(2), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<out> vi_2 : vec4<i32>;

[[location(3), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<out> vu_2 : vec4<u32>;

[[builtin(position), internal(disable_validation__ignore_storage_class)]] var<out> pos_1 : vec4<f32>;

[[location(0), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<in> i_3 : i32;

[[location(1), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<in> u_3 : u32;

[[location(2), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<in> vi_3 : vec4<i32>;

[[location(3), interpolate(flat), internal(disable_validation__ignore_storage_class)]] var<in> vu_3 : vec4<u32>;

[[location(0), internal(disable_validation__ignore_storage_class)]] var<out> i_4 : i32;

[[location(1), internal(disable_validation__ignore_storage_class)]] var<out> u_4 : u32;

[[location(2), internal(disable_validation__ignore_storage_class)]] var<out> vi_4 : vec4<i32>;

[[location(3), internal(disable_validation__ignore_storage_class)]] var<out> vu_4 : vec4<u32>;

struct VertexIn {
  i : i32;
  u : u32;
  vi : vec4<i32>;
  vu : vec4<u32>;
};

struct VertexOut {
  i : i32;
  u : u32;
  vi : vec4<i32>;
  vu : vec4<u32>;
  pos : vec4<f32>;
};

struct FragmentInterface {
  i : i32;
  u : u32;
  vi : vec4<i32>;
  vu : vec4<u32>;
};

fn vert_main_inner(in : VertexIn) -> VertexOut {
  return VertexOut(in.i, in.u, in.vi, in.vu, vec4<f32>());
}

[[stage(vertex)]]
fn vert_main() {
  let inner_result = vert_main_inner(VertexIn(i_1, u_1, vi_1, vu_1));
  i_2 = inner_result.i;
  u_2 = inner_result.u;
  vi_2 = inner_result.vi;
  vu_2 = inner_result.vu;
  pos_1 = inner_result.pos;
}

fn frag_main_inner(inputs : FragmentInterface) -> FragmentInterface {
  return inputs;
}

[[stage(fragment)]]
fn frag_main() {
  let inner_result_1 = frag_main_inner(FragmentInterface(i_3, u_3, vi_3, vu_3));
  i_4 = inner_result_1.i;
  u_4 = inner_result_1.u;
  vi_4 = inner_result_1.vi;
  vu_4 = inner_result_1.vu;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, InvariantAttributes) {
  auto* src = R"(
struct VertexOut {
  [[builtin(position), invariant]] pos : vec4<f32>;
};

[[stage(vertex)]]
fn main1() -> VertexOut {
  return VertexOut();
}

[[stage(vertex)]]
fn main2() -> [[builtin(position), invariant]] vec4<f32> {
  return vec4<f32>();
}
)";

  auto* expect = R"(
struct VertexOut {
  pos : vec4<f32>;
};

struct tint_symbol {
  [[builtin(position), invariant]]
  pos : vec4<f32>;
};

fn main1_inner() -> VertexOut {
  return VertexOut();
}

[[stage(vertex)]]
fn main1() -> tint_symbol {
  let inner_result = main1_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.pos = inner_result.pos;
  return wrapper_result;
}

struct tint_symbol_1 {
  [[builtin(position), invariant]]
  value : vec4<f32>;
};

fn main2_inner() -> vec4<f32> {
  return vec4<f32>();
}

[[stage(vertex)]]
fn main2() -> tint_symbol_1 {
  let inner_result_1 = main2_inner();
  var wrapper_result_1 : tint_symbol_1;
  wrapper_result_1.value = inner_result_1;
  return wrapper_result_1;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, Struct_LayoutDecorations) {
  auto* src = R"(
[[block]]
struct FragmentInput {
  [[size(16), location(1)]] value : f32;
  [[builtin(position)]] [[align(32)]] coord : vec4<f32>;
  [[location(0), interpolate(linear, sample)]] [[align(128)]] loc0 : f32;
};

struct FragmentOutput {
  [[size(16), location(1), interpolate(flat)]] value : f32;
};

[[stage(fragment)]]
fn frag_main(inputs : FragmentInput) -> FragmentOutput {
  return FragmentOutput(inputs.coord.x * inputs.value + inputs.loc0);
}
)";

  auto* expect = R"(
[[block]]
struct FragmentInput {
  [[size(16)]]
  value : f32;
  [[align(32)]]
  coord : vec4<f32>;
  [[align(128)]]
  loc0 : f32;
};

struct FragmentOutput {
  [[size(16)]]
  value : f32;
};

struct tint_symbol_1 {
  [[location(0), interpolate(linear, sample)]]
  loc0 : f32;
  [[location(1)]]
  value : f32;
  [[builtin(position)]]
  coord : vec4<f32>;
};

struct tint_symbol_2 {
  [[location(1), interpolate(flat)]]
  value : f32;
};

fn frag_main_inner(inputs : FragmentInput) -> FragmentOutput {
  return FragmentOutput(((inputs.coord.x * inputs.value) + inputs.loc0));
}

[[stage(fragment)]]
fn frag_main(tint_symbol : tint_symbol_1) -> tint_symbol_2 {
  let inner_result = frag_main_inner(FragmentInput(tint_symbol.value, tint_symbol.coord, tint_symbol.loc0));
  var wrapper_result : tint_symbol_2;
  wrapper_result.value = inner_result.value;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, SortedMembers) {
  auto* src = R"(
struct VertexOutput {
  [[location(1)]] b : u32;
  [[builtin(position)]] pos : vec4<f32>;
  [[location(3)]] d : u32;
  [[location(0)]] a : f32;
  [[location(2)]] c : i32;
};

struct FragmentInputExtra {
  [[location(3)]] d : u32;
  [[builtin(position)]] pos : vec4<f32>;
  [[location(0)]] a : f32;
};

[[stage(vertex)]]
fn vert_main() -> VertexOutput {
  return VertexOutput();
}

[[stage(fragment)]]
fn frag_main([[builtin(front_facing)]] ff : bool,
             [[location(2)]] c : i32,
             inputs : FragmentInputExtra,
             [[location(1)]] b : u32) {
}
)";

  auto* expect = R"(
struct VertexOutput {
  b : u32;
  pos : vec4<f32>;
  d : u32;
  a : f32;
  c : i32;
};

struct FragmentInputExtra {
  d : u32;
  pos : vec4<f32>;
  a : f32;
};

struct tint_symbol {
  [[location(0)]]
  a : f32;
  [[location(1)]]
  b : u32;
  [[location(2)]]
  c : i32;
  [[location(3)]]
  d : u32;
  [[builtin(position)]]
  pos : vec4<f32>;
};

fn vert_main_inner() -> VertexOutput {
  return VertexOutput();
}

[[stage(vertex)]]
fn vert_main() -> tint_symbol {
  let inner_result = vert_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.b = inner_result.b;
  wrapper_result.pos = inner_result.pos;
  wrapper_result.d = inner_result.d;
  wrapper_result.a = inner_result.a;
  wrapper_result.c = inner_result.c;
  return wrapper_result;
}

struct tint_symbol_2 {
  [[location(0)]]
  a : f32;
  [[location(1)]]
  b : u32;
  [[location(2)]]
  c : i32;
  [[location(3)]]
  d : u32;
  [[builtin(position)]]
  pos : vec4<f32>;
  [[builtin(front_facing)]]
  ff : bool;
};

fn frag_main_inner(ff : bool, c : i32, inputs : FragmentInputExtra, b : u32) {
}

[[stage(fragment)]]
fn frag_main(tint_symbol_1 : tint_symbol_2) {
  frag_main_inner(tint_symbol_1.ff, tint_symbol_1.c, FragmentInputExtra(tint_symbol_1.d, tint_symbol_1.pos, tint_symbol_1.a), tint_symbol_1.b);
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kHlsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, DontRenameSymbols) {
  auto* src = R"(
[[stage(fragment)]]
fn tint_symbol_1([[location(0)]] col : f32) {
}
)";

  auto* expect = R"(
struct tint_symbol_2 {
  [[location(0)]]
  col : f32;
};

fn tint_symbol_1_inner(col : f32) {
}

[[stage(fragment)]]
fn tint_symbol_1(tint_symbol : tint_symbol_2) {
  tint_symbol_1_inner(tint_symbol.col);
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, FixedSampleMask_VoidNoReturn) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main() {
}
)";

  auto* expect = R"(
struct tint_symbol {
  [[builtin(sample_mask)]]
  fixed_sample_mask : u32;
};

fn frag_main_inner() {
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.fixed_sample_mask = 3u;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0x03u);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, FixedSampleMask_VoidWithReturn) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main() {
  return;
}
)";

  auto* expect = R"(
struct tint_symbol {
  [[builtin(sample_mask)]]
  fixed_sample_mask : u32;
};

fn frag_main_inner() {
  return;
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.fixed_sample_mask = 3u;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0x03u);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, FixedSampleMask_WithAuthoredMask) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main() -> [[builtin(sample_mask)]] u32 {
  return 7u;
}
)";

  auto* expect = R"(
struct tint_symbol {
  [[builtin(sample_mask)]]
  value : u32;
};

fn frag_main_inner() -> u32 {
  return 7u;
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.value = (inner_result & 3u);
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0x03u);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, FixedSampleMask_WithoutAuthoredMask) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main() -> [[location(0)]] f32 {
  return 1.0;
}
)";

  auto* expect = R"(
struct tint_symbol {
  [[location(0)]]
  value : f32;
  [[builtin(sample_mask)]]
  fixed_sample_mask : u32;
};

fn frag_main_inner() -> f32 {
  return 1.0;
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.value = inner_result;
  wrapper_result.fixed_sample_mask = 3u;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0x03u);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, FixedSampleMask_StructWithAuthoredMask) {
  auto* src = R"(
struct Output {
  [[builtin(frag_depth)]] depth : f32;
  [[builtin(sample_mask)]] mask : u32;
  [[location(0)]] value : f32;
};

[[stage(fragment)]]
fn frag_main() -> Output {
  return Output(0.5, 7u, 1.0);
}
)";

  auto* expect = R"(
struct Output {
  depth : f32;
  mask : u32;
  value : f32;
};

struct tint_symbol {
  [[location(0)]]
  value : f32;
  [[builtin(frag_depth)]]
  depth : f32;
  [[builtin(sample_mask)]]
  mask : u32;
};

fn frag_main_inner() -> Output {
  return Output(0.5, 7u, 1.0);
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.depth = inner_result.depth;
  wrapper_result.mask = (inner_result.mask & 3u);
  wrapper_result.value = inner_result.value;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0x03u);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest,
       FixedSampleMask_StructWithoutAuthoredMask) {
  auto* src = R"(
struct Output {
  [[builtin(frag_depth)]] depth : f32;
  [[location(0)]] value : f32;
};

[[stage(fragment)]]
fn frag_main() -> Output {
  return Output(0.5, 1.0);
}
)";

  auto* expect = R"(
struct Output {
  depth : f32;
  value : f32;
};

struct tint_symbol {
  [[location(0)]]
  value : f32;
  [[builtin(frag_depth)]]
  depth : f32;
  [[builtin(sample_mask)]]
  fixed_sample_mask : u32;
};

fn frag_main_inner() -> Output {
  return Output(0.5, 1.0);
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.depth = inner_result.depth;
  wrapper_result.value = inner_result.value;
  wrapper_result.fixed_sample_mask = 3u;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0x03u);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, FixedSampleMask_MultipleShaders) {
  auto* src = R"(
[[stage(fragment)]]
fn frag_main1() -> [[builtin(sample_mask)]] u32 {
  return 7u;
}

[[stage(fragment)]]
fn frag_main2() -> [[location(0)]] f32 {
  return 1.0;
}

[[stage(vertex)]]
fn vert_main1() -> [[builtin(position)]] vec4<f32> {
  return vec4<f32>();
}

[[stage(compute), workgroup_size(1)]]
fn comp_main1() {
}
)";

  auto* expect = R"(
struct tint_symbol {
  [[builtin(sample_mask)]]
  value : u32;
};

fn frag_main1_inner() -> u32 {
  return 7u;
}

[[stage(fragment)]]
fn frag_main1() -> tint_symbol {
  let inner_result = frag_main1_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.value = (inner_result & 3u);
  return wrapper_result;
}

struct tint_symbol_1 {
  [[location(0)]]
  value : f32;
  [[builtin(sample_mask)]]
  fixed_sample_mask : u32;
};

fn frag_main2_inner() -> f32 {
  return 1.0;
}

[[stage(fragment)]]
fn frag_main2() -> tint_symbol_1 {
  let inner_result_1 = frag_main2_inner();
  var wrapper_result_1 : tint_symbol_1;
  wrapper_result_1.value = inner_result_1;
  wrapper_result_1.fixed_sample_mask = 3u;
  return wrapper_result_1;
}

struct tint_symbol_2 {
  [[builtin(position)]]
  value : vec4<f32>;
};

fn vert_main1_inner() -> vec4<f32> {
  return vec4<f32>();
}

[[stage(vertex)]]
fn vert_main1() -> tint_symbol_2 {
  let inner_result_2 = vert_main1_inner();
  var wrapper_result_2 : tint_symbol_2;
  wrapper_result_2.value = inner_result_2;
  return wrapper_result_2;
}

[[stage(compute), workgroup_size(1)]]
fn comp_main1() {
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0x03u);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, FixedSampleMask_AvoidNameClash) {
  auto* src = R"(
struct FragOut {
  [[location(0)]] fixed_sample_mask : vec4<f32>;
  [[location(1)]] fixed_sample_mask_1 : vec4<f32>;
};

[[stage(fragment)]]
fn frag_main() -> FragOut {
  return FragOut();
}
)";

  auto* expect = R"(
struct FragOut {
  fixed_sample_mask : vec4<f32>;
  fixed_sample_mask_1 : vec4<f32>;
};

struct tint_symbol {
  [[location(0)]]
  fixed_sample_mask : vec4<f32>;
  [[location(1)]]
  fixed_sample_mask_1 : vec4<f32>;
  [[builtin(sample_mask)]]
  fixed_sample_mask_2 : u32;
};

fn frag_main_inner() -> FragOut {
  return FragOut();
}

[[stage(fragment)]]
fn frag_main() -> tint_symbol {
  let inner_result = frag_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.fixed_sample_mask = inner_result.fixed_sample_mask;
  wrapper_result.fixed_sample_mask_1 = inner_result.fixed_sample_mask_1;
  wrapper_result.fixed_sample_mask_2 = 3u;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0x03);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest,
       EmitVertexPointSize_ReturnNonStruct_Spirv) {
  auto* src = R"(
[[stage(vertex)]]
fn vert_main() -> [[builtin(position)]] vec4<f32> {
  return vec4<f32>();
}
)";

  auto* expect = R"(
[[builtin(position), internal(disable_validation__ignore_storage_class)]] var<out> value : vec4<f32>;

[[builtin(pointsize), internal(disable_validation__ignore_storage_class)]] var<out> vertex_point_size : f32;

fn vert_main_inner() -> vec4<f32> {
  return vec4<f32>();
}

[[stage(vertex)]]
fn vert_main() {
  let inner_result = vert_main_inner();
  value = inner_result;
  vertex_point_size = 1.0;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv, 0xFFFFFFFF, true);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, EmitVertexPointSize_ReturnNonStruct_Msl) {
  auto* src = R"(
[[stage(vertex)]]
fn vert_main() -> [[builtin(position)]] vec4<f32> {
  return vec4<f32>();
}
)";

  auto* expect = R"(
struct tint_symbol {
  [[builtin(position)]]
  value : vec4<f32>;
  [[builtin(pointsize)]]
  vertex_point_size : f32;
};

fn vert_main_inner() -> vec4<f32> {
  return vec4<f32>();
}

[[stage(vertex)]]
fn vert_main() -> tint_symbol {
  let inner_result = vert_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.value = inner_result;
  wrapper_result.vertex_point_size = 1.0;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0xFFFFFFFF, true);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, EmitVertexPointSize_ReturnStruct_Spirv) {
  auto* src = R"(
struct VertOut {
  [[builtin(position)]] pos : vec4<f32>;
};

[[stage(vertex)]]
fn vert_main() -> VertOut {
  return VertOut();
}
)";

  auto* expect = R"(
[[builtin(position), internal(disable_validation__ignore_storage_class)]] var<out> pos_1 : vec4<f32>;

[[builtin(pointsize), internal(disable_validation__ignore_storage_class)]] var<out> vertex_point_size : f32;

struct VertOut {
  pos : vec4<f32>;
};

fn vert_main_inner() -> VertOut {
  return VertOut();
}

[[stage(vertex)]]
fn vert_main() {
  let inner_result = vert_main_inner();
  pos_1 = inner_result.pos;
  vertex_point_size = 1.0;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv, 0xFFFFFFFF, true);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, EmitVertexPointSize_ReturnStruct_Msl) {
  auto* src = R"(
struct VertOut {
  [[builtin(position)]] pos : vec4<f32>;
};

[[stage(vertex)]]
fn vert_main() -> VertOut {
  return VertOut();
}
)";

  auto* expect = R"(
struct VertOut {
  pos : vec4<f32>;
};

struct tint_symbol {
  [[builtin(position)]]
  pos : vec4<f32>;
  [[builtin(pointsize)]]
  vertex_point_size : f32;
};

fn vert_main_inner() -> VertOut {
  return VertOut();
}

[[stage(vertex)]]
fn vert_main() -> tint_symbol {
  let inner_result = vert_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.pos = inner_result.pos;
  wrapper_result.vertex_point_size = 1.0;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0xFFFFFFFF, true);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, EmitVertexPointSize_AvoidNameClash_Spirv) {
  auto* src = R"(
var<private> vertex_point_size : f32;
var<private> vertex_point_size_1 : f32;
var<private> vertex_point_size_2 : f32;

struct VertOut {
  [[location(0)]] vertex_point_size : f32;
  [[builtin(position)]] vertex_point_size_1 : vec4<f32>;
};

[[stage(vertex)]]
fn vert_main() -> VertOut {
  return VertOut();
}
)";

  auto* expect = R"(
[[location(0), internal(disable_validation__ignore_storage_class)]] var<out> vertex_point_size_3 : f32;

[[builtin(position), internal(disable_validation__ignore_storage_class)]] var<out> vertex_point_size_1_1 : vec4<f32>;

[[builtin(pointsize), internal(disable_validation__ignore_storage_class)]] var<out> vertex_point_size_4 : f32;

var<private> vertex_point_size : f32;

var<private> vertex_point_size_1 : f32;

var<private> vertex_point_size_2 : f32;

struct VertOut {
  vertex_point_size : f32;
  vertex_point_size_1 : vec4<f32>;
};

fn vert_main_inner() -> VertOut {
  return VertOut();
}

[[stage(vertex)]]
fn vert_main() {
  let inner_result = vert_main_inner();
  vertex_point_size_3 = inner_result.vertex_point_size;
  vertex_point_size_1_1 = inner_result.vertex_point_size_1;
  vertex_point_size_4 = 1.0;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kSpirv, 0xFFFFFFFF, true);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

TEST_F(CanonicalizeEntryPointIOTest, EmitVertexPointSize_AvoidNameClash_Msl) {
  auto* src = R"(
struct VertOut {
  [[location(0)]] vertex_point_size : vec4<f32>;
  [[builtin(position)]] vertex_point_size_1 : vec4<f32>;
};

[[stage(vertex)]]
fn vert_main() -> VertOut {
  return VertOut();
}
)";

  auto* expect = R"(
struct VertOut {
  vertex_point_size : vec4<f32>;
  vertex_point_size_1 : vec4<f32>;
};

struct tint_symbol {
  [[location(0)]]
  vertex_point_size : vec4<f32>;
  [[builtin(position)]]
  vertex_point_size_1 : vec4<f32>;
  [[builtin(pointsize)]]
  vertex_point_size_2 : f32;
};

fn vert_main_inner() -> VertOut {
  return VertOut();
}

[[stage(vertex)]]
fn vert_main() -> tint_symbol {
  let inner_result = vert_main_inner();
  var wrapper_result : tint_symbol;
  wrapper_result.vertex_point_size = inner_result.vertex_point_size;
  wrapper_result.vertex_point_size_1 = inner_result.vertex_point_size_1;
  wrapper_result.vertex_point_size_2 = 1.0;
  return wrapper_result;
}
)";

  DataMap data;
  data.Add<CanonicalizeEntryPointIO::Config>(
      CanonicalizeEntryPointIO::ShaderStyle::kMsl, 0xFFFFFFFF, true);
  auto got = Run<CanonicalizeEntryPointIO>(src, data);

  EXPECT_EQ(expect, str(got));
}

}  // namespace
}  // namespace transform
}  // namespace tint