// RUN: %clang_cc1 -triple thumbv8.1m.main-none-none-eabi -target-feature +mve.fp -flax-vector-conversions=all -Werror -emit-llvm -o - %s | FileCheck %s // RUN: %clang_cc1 -triple thumbv8.1m.main-none-none-eabi -target-feature +mve.fp -flax-vector-conversions=all -verify -fsyntax-only -DERROR_CHECK %s typedef signed short int16_t; typedef signed int int32_t; typedef signed long long int64_t; typedef unsigned short uint16_t; typedef unsigned int uint32_t; typedef unsigned long long uint64_t; typedef __attribute__((neon_vector_type(8), __clang_arm_mve_strict_polymorphism)) int16_t int16x8_t; typedef __attribute__((neon_vector_type(4), __clang_arm_mve_strict_polymorphism)) int32_t int32x4_t; typedef __attribute__((neon_vector_type(2), __clang_arm_mve_strict_polymorphism)) int64_t int64x2_t; typedef __attribute__((neon_vector_type(8), __clang_arm_mve_strict_polymorphism)) uint16_t uint16x8_t; typedef __attribute__((neon_vector_type(4), __clang_arm_mve_strict_polymorphism)) uint32_t uint32x4_t; typedef __attribute__((neon_vector_type(2), __clang_arm_mve_strict_polymorphism)) uint64_t uint64x2_t; __attribute__((overloadable)) int overload(int16x8_t x, int16_t y); // expected-note {{candidate function}} __attribute__((overloadable)) int overload(int32x4_t x, int32_t y); // expected-note {{candidate function}} __attribute__((overloadable)) int overload(uint16x8_t x, uint16_t y); // expected-note {{candidate function}} __attribute__((overloadable)) int overload(uint32x4_t x, uint32_t y); // expected-note {{candidate function}} int16_t s16; int32_t s32; uint16_t u16; uint32_t u32; int16x8_t vs16; int32x4_t vs32; uint16x8_t vu16; uint32x4_t vu32; // ---------------------------------------------------------------------- // Simple cases where the types are correctly matched // CHECK-LABEL: @test_easy_s16( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_int16 int test_easy_s16(void) { return overload(vs16, s16); } // CHECK-LABEL: @test_easy_u16( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_uint16 int test_easy_u16(void) { return overload(vu16, u16); } // CHECK-LABEL: @test_easy_s32( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_int32 int test_easy_s32(void) { return overload(vs32, s32); } // CHECK-LABEL: @test_easy_u32( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_uint32 int test_easy_u32(void) { return overload(vu32, u32); } // ---------------------------------------------------------------------- // Do arithmetic on the scalar, and it may get promoted. We still expect the // same overloads to be selected if that happens. // CHECK-LABEL: @test_promote_s16( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_int16 int test_promote_s16(void) { return overload(vs16, s16 + 1); } // CHECK-LABEL: @test_promote_u16( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_uint16 int test_promote_u16(void) { return overload(vu16, u16 + 1); } // CHECK-LABEL: @test_promote_s32( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_int32 int test_promote_s32(void) { return overload(vs32, s32 + 1); } // CHECK-LABEL: @test_promote_u32( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_uint32 int test_promote_u32(void) { return overload(vu32, u32 + 1); } // ---------------------------------------------------------------------- // Write a simple integer literal without qualification, and expect // the vector type to make it unambiguous which integer type you meant // the literal to be. // CHECK-LABEL: @test_literal_s16( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_int16 int test_literal_s16(void) { return overload(vs16, 1); } // CHECK-LABEL: @test_literal_u16( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_uint16 int test_literal_u16(void) { return overload(vu16, 1); } // CHECK-LABEL: @test_literal_s32( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_int32 int test_literal_s32(void) { return overload(vs32, 1); } // CHECK-LABEL: @test_literal_u32( // CHECK: call i32 @_Z8overload{{[a-zA-Z0-9_]+}}_uint32 int test_literal_u32(void) { return overload(vu32, 1); } // ---------------------------------------------------------------------- // All of those overload resolutions are supposed to be unambiguous even when // lax vector conversion is enabled. Check here that a lax conversion in a // different context still works. int16x8_t lax_conversion(void) { return vu32; } // ---------------------------------------------------------------------- // Use a vector type that there really _isn't_ any overload for, and // make sure that we get a fatal compile error. #ifdef ERROR_CHECK int expect_error(uint64x2_t v) { return overload(v, 2); // expected-error {{no matching function for call to 'overload'}} } typedef __attribute__((__clang_arm_mve_strict_polymorphism)) int i; // expected-error {{'__clang_arm_mve_strict_polymorphism' attribute can only be applied to an MVE/NEON vector type}} typedef __attribute__((__clang_arm_mve_strict_polymorphism)) int f(); // expected-error {{'__clang_arm_mve_strict_polymorphism' attribute can only be applied to an MVE/NEON vector type}} typedef __attribute__((__clang_arm_mve_strict_polymorphism)) struct { uint16x8_t v; } s; // expected-error {{'__clang_arm_mve_strict_polymorphism' attribute can only be applied to an MVE/NEON vector type}} #endif