src/tint/ir/from_program_binary_test.cc - tint - Git at Google

 // Copyright 2023 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/tint/ir/test_helper.h"

 #include "gmock/gmock.h"
 #include "src/tint/ast/case_selector.h"
 #include "src/tint/ast/int_literal_expression.h"
 #include "src/tint/constant/scalar.h"

 namespace tint::ir {
 namespace {

 using namespace tint::number_suffixes;  // NOLINT

 using IR_BuilderImplTest = TestHelper;

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Add) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Add(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = add %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Increment) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = Increment("v1");
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = add %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundAdd) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = CompoundAssign("v1", 1_u, ast::BinaryOp::kAdd);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = add %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Subtract) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Sub(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = sub %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Decrement) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.i32());
     auto* expr = Decrement("v1");
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, i32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:i32 = load %v1
     %4:i32 = sub %3, 1i
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundSubtract) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = CompoundAssign("v1", 1_u, ast::BinaryOp::kSubtract);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = sub %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Multiply) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Mul(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = mul %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundMultiply) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = CompoundAssign("v1", 1_u, ast::BinaryOp::kMultiply);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = mul %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Div) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Div(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = div %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundDiv) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = CompoundAssign("v1", 1_u, ast::BinaryOp::kDivide);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = div %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Modulo) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Mod(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = mod %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundModulo) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = CompoundAssign("v1", 1_u, ast::BinaryOp::kModulo);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = mod %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_And) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = And(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = and %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundAnd) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.bool_());
     auto* expr = CompoundAssign("v1", false, ast::BinaryOp::kAnd);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, bool, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:bool = load %v1
     %4:bool = and %3, false
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Or) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Or(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = or %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundOr) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.bool_());
     auto* expr = CompoundAssign("v1", false, ast::BinaryOp::kOr);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, bool, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:bool = load %v1
     %4:bool = or %3, false
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Xor) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Xor(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = xor %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundXor) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = CompoundAssign("v1", 1_u, ast::BinaryOp::kXor);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = xor %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_LogicalAnd) {
     Func("my_func", utils::Empty, ty.bool_(), utils::Vector{Return(true)});
     auto* expr = If(LogicalAnd(Call("my_func"), false), Block());
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():bool -> %fn1 {
   %fn1 = block {
     br %fn2 true  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:bool = call my_func
     if %3 [t: %fn4, f: %fn5, m: %fn6]
       # True block
       %fn4 = block {
         br %fn6 false
       }

       # False block
       %fn5 = block {
         br %fn6 %3
       }

     # Merge block
     %fn6 = block (%4:bool) {
       if %4:bool [t: %fn7, f: %fn8, m: %fn9]
         # True block
         %fn7 = block {
           br %fn9
         }

         # False block
         %fn8 = block {
           br %fn9
         }

       # Merge block
       %fn9 = block {
         br %fn10  # return
       }

     }


   }

   %fn10 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_LogicalOr) {
     Func("my_func", utils::Empty, ty.bool_(), utils::Vector{Return(true)});
     auto* expr = If(LogicalOr(Call("my_func"), true), Block());
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():bool -> %fn1 {
   %fn1 = block {
     br %fn2 true  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:bool = call my_func
     if %3 [t: %fn4, f: %fn5, m: %fn6]
       # True block
       %fn4 = block {
         br %fn6 %3
       }

       # False block
       %fn5 = block {
         br %fn6 true
       }

     # Merge block
     %fn6 = block (%4:bool) {
       if %4:bool [t: %fn7, f: %fn8, m: %fn9]
         # True block
         %fn7 = block {
           br %fn9
         }

         # False block
         %fn8 = block {
           br %fn9
         }

       # Merge block
       %fn9 = block {
         br %fn10  # return
       }

     }


   }

   %fn10 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Equal) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Equal(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:bool = eq %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_NotEqual) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = NotEqual(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:bool = neq %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_LessThan) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = LessThan(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:bool = lt %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_GreaterThan) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = GreaterThan(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:bool = gt %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_LessThanEqual) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = LessThanEqual(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:bool = lte %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_GreaterThanEqual) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = GreaterThanEqual(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:bool = gte %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_ShiftLeft) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Shl(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = shiftl %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundShiftLeft) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = CompoundAssign("v1", 1_u, ast::BinaryOp::kShiftLeft);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = shiftl %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_ShiftRight) {
     Func("my_func", utils::Empty, ty.u32(), utils::Vector{Return(0_u)});
     auto* expr = Shr(Call("my_func"), 4_u);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():u32 -> %fn1 {
   %fn1 = block {
     br %fn2 0u  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = call my_func
     %tint_symbol:u32 = shiftr %3, 4u
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_CompoundShiftRight) {
     GlobalVar("v1", builtin::AddressSpace::kPrivate, ty.u32());
     auto* expr = CompoundAssign("v1", 1_u, ast::BinaryOp::kShiftRight);
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(# Root block
 %fn1 = block {
   %v1:ptr<private, u32, read_write> = var
   br %fn2  # root_end
 }

 %fn2 = root_terminator

 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:u32 = load %v1
     %4:u32 = shiftr %3, 1u
     store %v1, %4
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Compound) {
     Func("my_func", utils::Empty, ty.f32(), utils::Vector{Return(0_f)});

     auto* expr = LogicalAnd(LessThan(Call("my_func"), 2_f),
                             GreaterThan(2.5_f, Div(Call("my_func"), Mul(2.3_f, Call("my_func")))));
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func():f32 -> %fn1 {
   %fn1 = block {
     br %fn2 0.0f  # return
   }
   %fn2 = func_terminator
 }
 %2 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %3:f32 = call my_func
     %4:bool = lt %3, 2.0f
     if %4 [t: %fn4, f: %fn5, m: %fn6]
       # True block
       %fn4 = block {
         %5:f32 = call my_func
         %6:f32 = call my_func
         %7:f32 = mul 2.29999995231628417969f, %6
         %8:f32 = div %5, %7
         %9:bool = gt 2.5f, %8
         br %fn6 %9
       }

       # False block
       %fn5 = block {
         br %fn6 %4
       }

     # Merge block
     %fn6 = block (%tint_symbol:bool) {
       br %fn7  # return
     }

   }

   %fn7 = func_terminator
 }
 )");
 }

 TEST_F(IR_BuilderImplTest, EmitExpression_Binary_Compound_WithConstEval) {
     Func("my_func", utils::Vector{Param("p", ty.bool_())}, ty.bool_(), utils::Vector{Return(true)});
     auto* expr = Call("my_func", LogicalAnd(LessThan(2.4_f, 2_f),
                                             GreaterThan(2.5_f, Div(10_f, Mul(2.3_f, 9.4_f)))));
     WrapInFunction(expr);

     auto m = Build();
     ASSERT_TRUE(m) << (!m ? m.Failure() : "");

     EXPECT_EQ(Disassemble(m.Get()), R"(%1 = func my_func(%p:bool):bool -> %fn1 {
   %fn1 = block {
     br %fn2 true  # return
   }
   %fn2 = func_terminator
 }
 %3 = func test_function():void [@compute @workgroup_size(1, 1, 1)] -> %fn3 {
   %fn3 = block {
     %tint_symbol:bool = call my_func, false
     br %fn4  # return
   }
   %fn4 = func_terminator
 }
 )");
 }

 }  // namespace
 }  // namespace tint::ir