From cf62e6a15942978a0c0ec70fc460603227c6ff52 Mon Sep 17 00:00:00 2001 From: Alan Modra Date: Wed, 2 May 2018 13:55:29 +0930 Subject: [PATCH] PowerPC64 ELFv1 fp arg fixes The ELFv1 ABI says: "Single precision floating point values are mapped to the second word in a single doubleword" and also "Floating point registers f1 through f13 are used consecutively to pass up to 13 floating point values, one member aggregates passed by value containing a floating point value, and to pass complex floating point values". libffi wasn't expecting float args in the second word, and wasn't passing one member aggregates in fp registers. This patch fixes those problems, making use of the existing ELFv2 homogeneous aggregate support since a one element fp struct is a special case of an homogeneous aggregate. I've also set a flag when returning pointers that might be used one day. This is just a tidy since the ppc64 assembly support code currently doesn't test FLAG_RETURNS_64BITS for integer types.. * src/powerpc/ffi_linux64.c (discover_homogeneous_aggregate): Compile for ELFv1 too, handling single element aggregates. (ffi_prep_cif_linux64_core): Call discover_homogeneous_aggregate for ELFv1. Set FLAG_RETURNS_64BITS for FFI_TYPE_POINTER return. (ffi_prep_args64): Call discover_homogeneous_aggregate for ELFv1, and handle single element structs containing float or double as if the element wasn't wrapped in a struct. Store floats in second word of doubleword slot when big-endian. (ffi_closure_helper_LINUX64): Similarly. diff --git a/src/powerpc/ffi_linux64.c b/src/powerpc/ffi_linux64.c index b481c60..93a31f9 100644 --- a/src/powerpc/ffi_linux64.c +++ b/src/powerpc/ffi_linux64.c @@ -62,7 +62,6 @@ ffi_prep_types_linux64 (ffi_abi abi) #endif -#if _CALL_ELF == 2 static unsigned int discover_homogeneous_aggregate (const ffi_type *t, unsigned int *elnum) { @@ -86,8 +85,13 @@ discover_homogeneous_aggregate (const ffi_type *t, unsigned int *elnum) return 0; base_elt = el_elt; total_elnum += el_elnum; +#if _CALL_ELF == 2 if (total_elnum > 8) return 0; +#else + if (total_elnum > 1) + return 0; +#endif el++; } *elnum = total_elnum; @@ -98,7 +102,6 @@ discover_homogeneous_aggregate (const ffi_type *t, unsigned int *elnum) return 0; } } -#endif /* Perform machine dependent cif processing */ @@ -109,9 +112,7 @@ ffi_prep_cif_linux64_core (ffi_cif *cif) unsigned bytes; unsigned i, fparg_count = 0, intarg_count = 0; unsigned flags = cif->flags; -#if _CALL_ELF == 2 unsigned int elt, elnum; -#endif #if FFI_TYPE_LONGDOUBLE == FFI_TYPE_DOUBLE /* If compiled without long double support.. */ @@ -157,6 +158,7 @@ ffi_prep_cif_linux64_core (ffi_cif *cif) /* Fall through. */ case FFI_TYPE_UINT64: case FFI_TYPE_SINT64: + case FFI_TYPE_POINTER: flags |= FLAG_RETURNS_64BITS; break; @@ -222,7 +224,6 @@ ffi_prep_cif_linux64_core (ffi_cif *cif) intarg_count = FFI_ALIGN (intarg_count, align); } intarg_count += ((*ptr)->size + 7) / 8; -#if _CALL_ELF == 2 elt = discover_homogeneous_aggregate (*ptr, &elnum); if (elt) { @@ -231,7 +232,6 @@ ffi_prep_cif_linux64_core (ffi_cif *cif) flags |= FLAG_ARG_NEEDS_PSAVE; } else -#endif { if (intarg_count > NUM_GPR_ARG_REGISTERS64) flags |= FLAG_ARG_NEEDS_PSAVE; @@ -449,9 +449,7 @@ ffi_prep_args64 (extended_cif *ecif, unsigned long *const stack) i < nargs; i++, ptr++, p_argv.v++) { -#if _CALL_ELF == 2 unsigned int elt, elnum; -#endif switch ((*ptr)->type) { @@ -494,6 +492,7 @@ ffi_prep_args64 (extended_cif *ecif, unsigned long *const stack) /* Fall through. */ #endif case FFI_TYPE_DOUBLE: + do_double: double_tmp = **p_argv.d; if (fparg_count < NUM_FPR_ARG_REGISTERS64 && i < nfixedargs) { @@ -512,17 +511,30 @@ ffi_prep_args64 (extended_cif *ecif, unsigned long *const stack) break; case FFI_TYPE_FLOAT: + do_float: double_tmp = **p_argv.f; if (fparg_count < NUM_FPR_ARG_REGISTERS64 && i < nfixedargs) { *fpr_base.d++ = double_tmp; #if _CALL_ELF != 2 if ((flags & FLAG_COMPAT) != 0) - *next_arg.f = (float) double_tmp; + { +# ifndef __LITTLE_ENDIAN__ + next_arg.f[1] = (float) double_tmp; +# else + next_arg.f[0] = (float) double_tmp; +# endif + } #endif } else - *next_arg.f = (float) double_tmp; + { +# ifndef __LITTLE_ENDIAN__ + next_arg.f[1] = (float) double_tmp; +# else + next_arg.f[0] = (float) double_tmp; +# endif + } if (++next_arg.ul == gpr_end.ul) next_arg.ul = rest.ul; fparg_count++; @@ -538,10 +550,10 @@ ffi_prep_args64 (extended_cif *ecif, unsigned long *const stack) if (align > 1) next_arg.p = FFI_ALIGN (next_arg.p, align); } -#if _CALL_ELF == 2 elt = discover_homogeneous_aggregate (*ptr, &elnum); if (elt) { +#if _CALL_ELF == 2 union { void *v; float *f; @@ -583,9 +595,14 @@ ffi_prep_args64 (extended_cif *ecif, unsigned long *const stack) fparg_count++; } while (--elnum != 0); +#else + if (elt == FFI_TYPE_FLOAT) + goto do_float; + else + goto do_double; +#endif } else -#endif { words = ((*ptr)->size + 7) / 8; if (next_arg.ul >= gpr_base.ul && next_arg.ul + words > gpr_end.ul) @@ -796,12 +813,10 @@ ffi_closure_helper_LINUX64 (ffi_cif *cif, if (align > 1) pst = (unsigned long *) FFI_ALIGN ((size_t) pst, align); } - elt = 0; -#if _CALL_ELF == 2 elt = discover_homogeneous_aggregate (arg_types[i], &elnum); -#endif if (elt) { +#if _CALL_ELF == 2 union { void *v; unsigned long *ul; @@ -853,6 +868,12 @@ ffi_closure_helper_LINUX64 (ffi_cif *cif, } while (--elnum != 0); } +#else + if (elt == FFI_TYPE_FLOAT) + goto do_float; + else + goto do_double; +#endif } else { @@ -894,6 +915,7 @@ ffi_closure_helper_LINUX64 (ffi_cif *cif, /* Fall through. */ #endif case FFI_TYPE_DOUBLE: + do_double: /* On the outgoing stack all values are aligned to 8 */ /* there are 13 64bit floating point registers */ @@ -908,6 +930,7 @@ ffi_closure_helper_LINUX64 (ffi_cif *cif, break; case FFI_TYPE_FLOAT: + do_float: if (pfr < end_pfr && i < nfixedargs) { /* Float values are stored as doubles in the @@ -917,7 +940,13 @@ ffi_closure_helper_LINUX64 (ffi_cif *cif, pfr++; } else - avalue[i] = pst; + { +#ifndef __LITTLE_ENDIAN__ + avalue[i] = (char *) pst + 4; +#else + avalue[i] = pst; +#endif + } pst++; break;