tests/codegen/const-vector.rs - toolchain/rustc - Git at Google

 //@ compile-flags: -C no-prepopulate-passes -Copt-level=0

 // This test checks that constants of SIMD type are passed as immediate vectors.
 // We ensure that both vector representations (struct with fields and struct wrapping array) work.
 #![crate_type = "lib"]
 #![feature(abi_unadjusted)]
 #![feature(const_trait_impl)]
 #![feature(repr_simd)]
 #![feature(rustc_attrs)]
 #![feature(simd_ffi)]
 #![allow(non_camel_case_types)]

 // Setting up structs that can be used as const vectors
 #[repr(simd)]
 #[derive(Clone)]
 pub struct i8x2([i8; 2]);

 #[repr(simd)]
 #[derive(Clone)]
 pub struct f32x2([f32; 2]);

 #[repr(simd, packed)]
 #[derive(Copy, Clone)]
 pub struct Simd<T, const N: usize>([T; N]);

 // The following functions are required for the tests to ensure
 // that they are called with a const vector

 extern "unadjusted" {
     fn test_i8x2(a: i8x2);
 }

 extern "unadjusted" {
     fn test_i8x2_two_args(a: i8x2, b: i8x2);
 }

 extern "unadjusted" {
     fn test_i8x2_mixed_args(a: i8x2, c: i32, b: i8x2);
 }

 extern "unadjusted" {
     fn test_i8x2_arr(a: i8x2);
 }

 extern "unadjusted" {
     fn test_f32x2(a: f32x2);
 }

 extern "unadjusted" {
     fn test_f32x2_arr(a: f32x2);
 }

 extern "unadjusted" {
     fn test_simd(a: Simd<i32, 4>);
 }

 extern "unadjusted" {
     fn test_simd_unaligned(a: Simd<i32, 3>);
 }

 // Ensure the packed variant of the simd struct does not become a const vector
 // if the size is not a power of 2
 // CHECK: %"Simd<i32, 3>" = type { [3 x i32] }

 pub fn do_call() {
     unsafe {
         // CHECK: call void @test_i8x2(<2 x i8> <i8 32, i8 64>
         test_i8x2(const { i8x2([32, 64]) });

         // CHECK: call void @test_i8x2_two_args(<2 x i8> <i8 32, i8 64>, <2 x i8> <i8 8, i8 16>
         test_i8x2_two_args(const { i8x2([32, 64]) }, const { i8x2([8, 16]) });

         // CHECK: call void @test_i8x2_mixed_args(<2 x i8> <i8 32, i8 64>, i32 43, <2 x i8> <i8 8, i8 16>
         test_i8x2_mixed_args(const { i8x2([32, 64]) }, 43, const { i8x2([8, 16]) });

         // CHECK: call void @test_i8x2_arr(<2 x i8> <i8 32, i8 64>
         test_i8x2_arr(const { i8x2([32, 64]) });

         // CHECK: call void @test_f32x2(<2 x float> <float 0x3FD47AE140000000, float 0x3FE47AE140000000>
         test_f32x2(const { f32x2([0.32, 0.64]) });

         // CHECK: void @test_f32x2_arr(<2 x float> <float 0x3FD47AE140000000, float 0x3FE47AE140000000>
         test_f32x2_arr(const { f32x2([0.32, 0.64]) });

         // CHECK: call void @test_simd(<4 x i32> <i32 2, i32 4, i32 6, i32 8>
         test_simd(const { Simd::<i32, 4>([2, 4, 6, 8]) });

         // CHECK: call void @test_simd_unaligned(%"Simd<i32, 3>" %1
         test_simd_unaligned(const { Simd::<i32, 3>([2, 4, 6]) });
     }
 }
	//@ compile-flags: -C no-prepopulate-passes -Copt-level=0

	// This test checks that constants of SIMD type are passed as immediate vectors.
	// We ensure that both vector representations (struct with fields and struct wrapping array) work.
	#![crate_type = "lib"]
	#![feature(abi_unadjusted)]
	#![feature(const_trait_impl)]
	#![feature(repr_simd)]
	#![feature(rustc_attrs)]
	#![feature(simd_ffi)]
	#![allow(non_camel_case_types)]

	// Setting up structs that can be used as const vectors
	#[repr(simd)]
	#[derive(Clone)]
	pub struct i8x2([i8; 2]);

	#[repr(simd)]
	#[derive(Clone)]
	pub struct f32x2([f32; 2]);

	#[repr(simd, packed)]
	#[derive(Copy, Clone)]
	pub struct Simd<T, const N: usize>([T; N]);

	// The following functions are required for the tests to ensure
	// that they are called with a const vector

	extern "unadjusted" {
	fn test_i8x2(a: i8x2);
	}

	extern "unadjusted" {
	fn test_i8x2_two_args(a: i8x2, b: i8x2);
	}

	extern "unadjusted" {
	fn test_i8x2_mixed_args(a: i8x2, c: i32, b: i8x2);
	}

	extern "unadjusted" {
	fn test_i8x2_arr(a: i8x2);
	}

	extern "unadjusted" {
	fn test_f32x2(a: f32x2);
	}

	extern "unadjusted" {
	fn test_f32x2_arr(a: f32x2);
	}

	extern "unadjusted" {
	fn test_simd(a: Simd<i32, 4>);
	}

	extern "unadjusted" {
	fn test_simd_unaligned(a: Simd<i32, 3>);
	}

	// Ensure the packed variant of the simd struct does not become a const vector
	// if the size is not a power of 2
	// CHECK: %"Simd<i32, 3>" = type { [3 x i32] }

	pub fn do_call() {
	unsafe {
	// CHECK: call void @test_i8x2(<2 x i8> <i8 32, i8 64>
	test_i8x2(const { i8x2([32, 64]) });

	// CHECK: call void @test_i8x2_two_args(<2 x i8> <i8 32, i8 64>, <2 x i8> <i8 8, i8 16>
	test_i8x2_two_args(const { i8x2([32, 64]) }, const { i8x2([8, 16]) });

	// CHECK: call void @test_i8x2_mixed_args(<2 x i8> <i8 32, i8 64>, i32 43, <2 x i8> <i8 8, i8 16>
	test_i8x2_mixed_args(const { i8x2([32, 64]) }, 43, const { i8x2([8, 16]) });

	// CHECK: call void @test_i8x2_arr(<2 x i8> <i8 32, i8 64>
	test_i8x2_arr(const { i8x2([32, 64]) });

	// CHECK: call void @test_f32x2(<2 x float> <float 0x3FD47AE140000000, float 0x3FE47AE140000000>
	test_f32x2(const { f32x2([0.32, 0.64]) });

	// CHECK: void @test_f32x2_arr(<2 x float> <float 0x3FD47AE140000000, float 0x3FE47AE140000000>
	test_f32x2_arr(const { f32x2([0.32, 0.64]) });

	// CHECK: call void @test_simd(<4 x i32> <i32 2, i32 4, i32 6, i32 8>
	test_simd(const { Simd::<i32, 4>([2, 4, 6, 8]) });

	// CHECK: call void @test_simd_unaligned(%"Simd<i32, 3>" %1
	test_simd_unaligned(const { Simd::<i32, 3>([2, 4, 6]) });
	}
	}