// RUN: %clang_cc1 -triple riscv64 -target-feature +f -target-abi lp64f -emit-llvm %s -o - \ // RUN: | FileCheck %s // RUN: %clang_cc1 -triple riscv64 -target-feature +d -target-abi lp64d -emit-llvm %s -o - \ // RUN: | FileCheck %s #include // Verify that the tracking of used GPRs and FPRs works correctly by checking // that small integers are sign/zero extended when passed in registers. // Floats are passed in FPRs, so argument 'i' will be passed zero-extended // because it will be passed in a GPR. // CHECK: define{{.*}} void @f_fpr_tracking(float %a, float %b, float %c, float %d, float %e, float %f, float %g, float %h, i8 zeroext %i) void f_fpr_tracking(float a, float b, float c, float d, float e, float f, float g, float h, uint8_t i) {} // Check that fp, fp+fp, and int+fp structs are lowered correctly. These will // be passed in FPR, FPR+FPR, or GPR+FPR regs if sufficient registers are // available the widths are <= XLEN and FLEN, and should be expanded to // separate arguments in IR. They are passed by the same rules for returns, // but will be lowered to simple two-element structs if necessary (as LLVM IR // functions cannot return multiple values). // A struct containing just one floating-point real is passed as though it // were a standalone floating-point real. struct float_s { float f; }; // CHECK: define{{.*}} void @f_float_s_arg(float %0) void f_float_s_arg(struct float_s a) {} // CHECK: define{{.*}} float @f_ret_float_s() struct float_s f_ret_float_s() { return (struct float_s){1.0}; } // A struct containing a float and any number of zero-width bitfields is // passed as though it were a standalone floating-point real. struct zbf_float_s { int : 0; float f; }; struct zbf_float_zbf_s { int : 0; float f; int : 0; }; // CHECK: define{{.*}} void @f_zbf_float_s_arg(float %0) void f_zbf_float_s_arg(struct zbf_float_s a) {} // CHECK: define{{.*}} float @f_ret_zbf_float_s() struct zbf_float_s f_ret_zbf_float_s() { return (struct zbf_float_s){1.0}; } // CHECK: define{{.*}} void @f_zbf_float_zbf_s_arg(float %0) void f_zbf_float_zbf_s_arg(struct zbf_float_zbf_s a) {} // CHECK: define{{.*}} float @f_ret_zbf_float_zbf_s() struct zbf_float_zbf_s f_ret_zbf_float_zbf_s() { return (struct zbf_float_zbf_s){1.0}; } // Check that structs containing two float values (FLEN <= width) are expanded // provided sufficient FPRs are available. struct float_float_s { float f; float g; }; // CHECK: define{{.*}} void @f_float_float_s_arg(float %0, float %1) void f_float_float_s_arg(struct float_float_s a) {} // CHECK: define{{.*}} { float, float } @f_ret_float_float_s() struct float_float_s f_ret_float_float_s() { return (struct float_float_s){1.0, 2.0}; } // CHECK: define{{.*}} void @f_float_float_s_arg_insufficient_fprs(float %a, float %b, float %c, float %d, float %e, float %f, float %g, i64 %h.coerce) void f_float_float_s_arg_insufficient_fprs(float a, float b, float c, float d, float e, float f, float g, struct float_float_s h) {} // Check that structs containing int+float values are expanded, provided // sufficient FPRs and GPRs are available. The integer components are neither // sign or zero-extended. struct float_int8_s { float f; int8_t i; }; struct float_uint8_s { float f; uint8_t i; }; struct float_int32_s { float f; int32_t i; }; struct float_int64_s { float f; int64_t i; }; struct float_int128bf_s { float f; __int128_t i : 64; }; struct float_int8_zbf_s { float f; int8_t i; int : 0; }; // CHECK: define{{.*}} void @f_float_int8_s_arg(float %0, i8 %1) void f_float_int8_s_arg(struct float_int8_s a) {} // CHECK: define{{.*}} { float, i8 } @f_ret_float_int8_s() struct float_int8_s f_ret_float_int8_s() { return (struct float_int8_s){1.0, 2}; } // CHECK: define{{.*}} void @f_float_uint8_s_arg(float %0, i8 %1) void f_float_uint8_s_arg(struct float_uint8_s a) {} // CHECK: define{{.*}} { float, i8 } @f_ret_float_uint8_s() struct float_uint8_s f_ret_float_uint8_s() { return (struct float_uint8_s){1.0, 2}; } // CHECK: define{{.*}} void @f_float_int32_s_arg(float %0, i32 %1) void f_float_int32_s_arg(struct float_int32_s a) {} // CHECK: define{{.*}} { float, i32 } @f_ret_float_int32_s() struct float_int32_s f_ret_float_int32_s() { return (struct float_int32_s){1.0, 2}; } // CHECK: define{{.*}} void @f_float_int64_s_arg(float %0, i64 %1) void f_float_int64_s_arg(struct float_int64_s a) {} // CHECK: define{{.*}} { float, i64 } @f_ret_float_int64_s() struct float_int64_s f_ret_float_int64_s() { return (struct float_int64_s){1.0, 2}; } // CHECK: define{{.*}} void @f_float_int128bf_s_arg(float %0, i64 %1) void f_float_int128bf_s_arg(struct float_int128bf_s a) {} // CHECK: define{{.*}} <{ float, i64 }> @f_ret_float_int128bf_s() struct float_int128bf_s f_ret_float_int128bf_s() { return (struct float_int128bf_s){1.0, 2}; } // The zero-width bitfield means the struct can't be passed according to the // floating point calling convention. // CHECK: define{{.*}} void @f_float_int8_zbf_s(float %0, i8 %1) void f_float_int8_zbf_s(struct float_int8_zbf_s a) {} // CHECK: define{{.*}} { float, i8 } @f_ret_float_int8_zbf_s() struct float_int8_zbf_s f_ret_float_int8_zbf_s() { return (struct float_int8_zbf_s){1.0, 2}; } // CHECK: define{{.*}} void @f_float_int8_s_arg_insufficient_gprs(i32 signext %a, i32 signext %b, i32 signext %c, i32 signext %d, i32 signext %e, i32 signext %f, i32 signext %g, i32 signext %h, i64 %i.coerce) void f_float_int8_s_arg_insufficient_gprs(int a, int b, int c, int d, int e, int f, int g, int h, struct float_int8_s i) {} // CHECK: define{{.*}} void @f_struct_float_int8_insufficient_fprs(float %a, float %b, float %c, float %d, float %e, float %f, float %g, float %h, i64 %i.coerce) void f_struct_float_int8_insufficient_fprs(float a, float b, float c, float d, float e, float f, float g, float h, struct float_int8_s i) {} // Complex floating-point values or structs containing a single complex // floating-point value should be passed as if it were an fp+fp struct. // CHECK: define{{.*}} void @f_floatcomplex(float %a.coerce0, float %a.coerce1) void f_floatcomplex(float __complex__ a) {} // CHECK: define{{.*}} { float, float } @f_ret_floatcomplex() float __complex__ f_ret_floatcomplex() { return 1.0; } struct floatcomplex_s { float __complex__ c; }; // CHECK: define{{.*}} void @f_floatcomplex_s_arg(float %0, float %1) void f_floatcomplex_s_arg(struct floatcomplex_s a) {} // CHECK: define{{.*}} { float, float } @f_ret_floatcomplex_s() struct floatcomplex_s f_ret_floatcomplex_s() { return (struct floatcomplex_s){1.0}; } // Complex floating-point values or structs containing a single complex // floating-point value should be passed in GPRs if no two FPRs is available. // CHECK: define{{.*}} void @f_floatcomplex_insufficient_fprs1(float %a.coerce0, float %a.coerce1, float %b.coerce0, float %b.coerce1, float %c.coerce0, float %c.coerce1, float %d.coerce0, float %d.coerce1, i64 %e.coerce) void f_floatcomplex_insufficient_fprs1(float __complex__ a, float __complex__ b, float __complex__ c, float __complex__ d, float __complex__ e) {} // CHECK: define{{.*}} void @f_floatcomplex_s_arg_insufficient_fprs1(float %0, float %1, float %2, float %3, float %4, float %5, float %6, float %7, i64 %e.coerce) void f_floatcomplex_s_arg_insufficient_fprs1(struct floatcomplex_s a, struct floatcomplex_s b, struct floatcomplex_s c, struct floatcomplex_s d, struct floatcomplex_s e) {} // CHECK: define{{.*}} void @f_floatcomplex_insufficient_fprs2(float %a, float %b.coerce0, float %b.coerce1, float %c.coerce0, float %c.coerce1, float %d.coerce0, float %d.coerce1, i64 %e.coerce) void f_floatcomplex_insufficient_fprs2(float a, float __complex__ b, float __complex__ c, float __complex__ d, float __complex__ e) {} // CHECK: define{{.*}} void @f_floatcomplex_s_arg_insufficient_fprs2(float %a, float %0, float %1, float %2, float %3, float %4, float %5, i64 %e.coerce) void f_floatcomplex_s_arg_insufficient_fprs2(float a, struct floatcomplex_s b, struct floatcomplex_s c, struct floatcomplex_s d, struct floatcomplex_s e) {} // Test single or two-element structs that need flattening. e.g. those // containing nested structs, floats in small arrays, zero-length structs etc. struct floatarr1_s { float a[1]; }; // CHECK: define{{.*}} void @f_floatarr1_s_arg(float %0) void f_floatarr1_s_arg(struct floatarr1_s a) {} // CHECK: define{{.*}} float @f_ret_floatarr1_s() struct floatarr1_s f_ret_floatarr1_s() { return (struct floatarr1_s){{1.0}}; } struct floatarr2_s { float a[2]; }; // CHECK: define{{.*}} void @f_floatarr2_s_arg(float %0, float %1) void f_floatarr2_s_arg(struct floatarr2_s a) {} // CHECK: define{{.*}} { float, float } @f_ret_floatarr2_s() struct floatarr2_s f_ret_floatarr2_s() { return (struct floatarr2_s){{1.0, 2.0}}; } struct floatarr2_tricky1_s { struct { float f[1]; } g[2]; }; // CHECK: define{{.*}} void @f_floatarr2_tricky1_s_arg(float %0, float %1) void f_floatarr2_tricky1_s_arg(struct floatarr2_tricky1_s a) {} // CHECK: define{{.*}} { float, float } @f_ret_floatarr2_tricky1_s() struct floatarr2_tricky1_s f_ret_floatarr2_tricky1_s() { return (struct floatarr2_tricky1_s){{{{1.0}}, {{2.0}}}}; } struct floatarr2_tricky2_s { struct {}; struct { float f[1]; } g[2]; }; // CHECK: define{{.*}} void @f_floatarr2_tricky2_s_arg(float %0, float %1) void f_floatarr2_tricky2_s_arg(struct floatarr2_tricky2_s a) {} // CHECK: define{{.*}} { float, float } @f_ret_floatarr2_tricky2_s() struct floatarr2_tricky2_s f_ret_floatarr2_tricky2_s() { return (struct floatarr2_tricky2_s){{}, {{{1.0}}, {{2.0}}}}; } struct floatarr2_tricky3_s { union {}; struct { float f[1]; } g[2]; }; // CHECK: define{{.*}} void @f_floatarr2_tricky3_s_arg(float %0, float %1) void f_floatarr2_tricky3_s_arg(struct floatarr2_tricky3_s a) {} // CHECK: define{{.*}} { float, float } @f_ret_floatarr2_tricky3_s() struct floatarr2_tricky3_s f_ret_floatarr2_tricky3_s() { return (struct floatarr2_tricky3_s){{}, {{{1.0}}, {{2.0}}}}; } struct floatarr2_tricky4_s { union {}; struct { struct {}; float f[1]; } g[2]; }; // CHECK: define{{.*}} void @f_floatarr2_tricky4_s_arg(float %0, float %1) void f_floatarr2_tricky4_s_arg(struct floatarr2_tricky4_s a) {} // CHECK: define{{.*}} { float, float } @f_ret_floatarr2_tricky4_s() struct floatarr2_tricky4_s f_ret_floatarr2_tricky4_s() { return (struct floatarr2_tricky4_s){{}, {{{}, {1.0}}, {{}, {2.0}}}}; } // Test structs that should be passed according to the normal integer calling // convention. struct int_float_int_s { int a; float b; int c; }; // CHECK: define{{.*}} void @f_int_float_int_s_arg([2 x i64] %a.coerce) void f_int_float_int_s_arg(struct int_float_int_s a) {} // CHECK: define{{.*}} [2 x i64] @f_ret_int_float_int_s() struct int_float_int_s f_ret_int_float_int_s() { return (struct int_float_int_s){1, 2.0, 3}; } struct char_char_float_s { char a; char b; float c; }; // CHECK-LABEL: define{{.*}} void @f_char_char_float_s_arg(i64 %a.coerce) void f_char_char_float_s_arg(struct char_char_float_s a) {} // CHECK: define{{.*}} i64 @f_ret_char_char_float_s() struct char_char_float_s f_ret_char_char_float_s() { return (struct char_char_float_s){1, 2, 3.0}; } // Unions are always passed according to the integer calling convention, even // if they can only contain a float. union float_u { float a; }; // CHECK: define{{.*}} void @f_float_u_arg(i64 %a.coerce) void f_float_u_arg(union float_u a) {} // CHECK: define{{.*}} i64 @f_ret_float_u() union float_u f_ret_float_u() { return (union float_u){1.0}; }