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SUSE:SLE-12:Update
ltrace
ltrace-ppc64le_git17.patch
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File ltrace-ppc64le_git17.patch of Package ltrace
--- ltrace-elf.c.ori +++ ltrace-elf.c @@ -761,7 +761,7 @@ filter_symbol_chain(struct filter *filter, return 0; } -static void +void delete_symbol_chain(struct library_symbol *libsym) { while (libsym != NULL) { --- ltrace-elf.h.ori +++ ltrace-elf.h @@ -136,6 +136,7 @@ int elf_read_next_uleb128(Elf_Data *data, GElf_Xword *offset, uint64_t *retp); int elf_read_u32(Elf_Data *data, GElf_Xword offset, uint32_t *retp); int elf_read_u64(Elf_Data *data, GElf_Xword offset, uint64_t *retp); +void delete_symbol_chain(struct library_symbol *); #if __WORDSIZE == 32 #define PRI_ELF_ADDR PRIx32 #define GELF_ADDR_CAST(x) (void *)(uint32_t)(x) --- sysdeps/linux-gnu/ppc/arch.h.ori +++ sysdeps/linux-gnu/ppc/arch.h @@ -23,8 +23,8 @@ #define LTRACE_PPC_ARCH_H #include <gelf.h> +#include <stdbool.h> -#define BREAKPOINT_VALUE { 0x7f, 0xe0, 0x00, 0x08 } #define BREAKPOINT_LENGTH 4 #define DECR_PC_AFTER_BREAK 0 @@ -34,8 +34,33 @@ #ifdef __powerpc64__ // Says 'ltrace' is 64 bits, says nothing about target. #define LT_ELFCLASS2 ELFCLASS64 #define LT_ELF_MACHINE2 EM_PPC64 -#define ARCH_SUPPORTS_OPD -#endif + +# ifdef __LITTLE_ENDIAN__ +# define BREAKPOINT_VALUE { 0x08, 0x00, 0xe0, 0x7f } +# define ARCH_ENDIAN_LITTLE +# else +# define BREAKPOINT_VALUE { 0x7f, 0xe0, 0x00, 0x08 } +# define ARCH_SUPPORTS_OPD +# define ARCH_ENDIAN_BIG +# endif + +# if _CALL_ELF != 2 +# define ARCH_SUPPORTS_OPD +# define STACK_FRAME_OVERHEAD 112 +# ifndef EF_PPC64_ABI +# define EF_PPC64_ABI 3 +# endif +# else /* _CALL_ELF == 2 ABIv2 */ +# define STACK_FRAME_OVERHEAD 32 +# endif /* CALL_ELF */ + +#else +#define BREAKPOINT_VALUE { 0x7f, 0xe0, 0x00, 0x08 } +#define ARCH_ENDIAN_BIG +# ifndef EF_PPC64_ABI +# define EF_PPC64_ABI 3 +# endif +#endif /* __powerpc64__ */ #define ARCH_HAVE_ATOMIC_SINGLESTEP #define ARCH_HAVE_ADD_PLT_ENTRY @@ -43,7 +68,6 @@ #define ARCH_HAVE_TRANSLATE_ADDRESS #define ARCH_HAVE_DYNLINK_DONE #define ARCH_HAVE_FETCH_ARG -#define ARCH_ENDIAN_BIG #define ARCH_HAVE_SIZEOF #define ARCH_HAVE_ALIGNOF @@ -56,7 +80,8 @@ struct arch_ltelf_data { Elf_Data *opd_data; GElf_Addr opd_base; GElf_Xword opd_size; - int secure_plt; + bool secure_plt : 1; + bool elfv2_abi : 1; Elf_Data *reladyn; size_t reladyn_count; --- sysdeps/linux-gnu/ppc/fetch.c.ori +++ sysdeps/linux-gnu/ppc/fetch.c @@ -30,9 +30,11 @@ #include "ptrace.h" #include "proc.h" #include "value.h" +#include "ltrace-elf.h" static int allocate_gpr(struct fetch_context *ctx, struct Process *proc, - struct arg_type_info *info, struct value *valuep); + struct arg_type_info *info, struct value *valuep, + size_t off, bool is_hfa_type); /* Floating point registers have the same width on 32-bit as well as * 64-bit PPC, but <ucontext.h> presents a different API depending on @@ -62,7 +64,10 @@ struct fetch_context { gregs64_t r64; } regs; struct fpregs_t fpregs; - + int vgreg; + int struct_size; + int struct_hfa_size; + int struct_hfa_count; }; static int @@ -74,7 +79,8 @@ fetch_context_init(struct 0rocess *proc, struct fetch_context *context) if (proc->e_machine == EM_PPC) context->stack_pointer = proc->stack_pointer + 8; else - context->stack_pointer = proc->stack_pointer + 112; + context->stack_pointer = proc->stack_pointer + + STACK_FRAME_OVERHEAD; /* When ltrace is 64-bit, we might use PTRACE_GETREGS to * obtain 64-bit as well as 32-bit registers. But if we do it @@ -118,6 +124,11 @@ arch_fetch_arg_init(enum tof type, struct Process *proc, return NULL; } + context->vgreg = context->greg; + context->struct_size = 0; + context->struct_hfa_size = 0; + context->struct_hfa_count = 0; + /* Aggregates or unions of any length, and character strings * of length longer than 8 bytes, will be returned in a * storage buffer allocated by the caller. The caller will @@ -125,8 +136,20 @@ arch_fetch_arg_init(enum tof type, struct Process *proc, * in r3, causing the first explicit argument to be passed in * r4. */ context->ret_struct = ret_info->type == ARGTYPE_STRUCT; - if (context->ret_struct) + if (context->ret_struct) { +#if _CALL_ELF == 2 + /* if R3 points to stack, parameters will be in R4. */ + uint64_t pstack_end = ptrace(PTRACE_PEEKTEXT, proc->pid, + proc->stack_pointer, 0); + if (((arch_addr_t)context->regs.r64[3] > proc->stack_pointer) + && (context->regs.r64[3] < pstack_end)) { + context->greg++; + context->stack_pointer += 8; + } +#else context->greg++; +#endif + } return context; } @@ -144,7 +167,8 @@ arch_fetch_arg_clone(struct Process *proc, static int allocate_stack_slot(struct fetch_context *ctx, struct Process *proc, - struct arg_type_info *info, struct value *valuep) + struct arg_type_info *info, struct value *valuep, + bool is_hfa_type) { size_t sz = type_sizeof(proc, info); if (sz == (size_t)-1) @@ -154,7 +178,14 @@ allocate_stack_slot(struct fetch_context *ctx, struct Process *proc, size_t off = 0; if (proc->e_machine == EM_PPC && a < 4) a = 4; +#if _CALL_ELF == 2 + else if (proc->e_machine == EM_PPC64 && sz == 4 && is_hfa_type) + a = 4; + else + a = 8; +#else else if (proc->e_machine == EM_PPC64 && a < 8) +#endif a = 8; /* XXX Remove the two double casts when arch_addr_t @@ -164,7 +195,7 @@ allocate_stack_slot(struct fetch_context *ctx, struct Process *proc, if (valuep != NULL) value_in_inferior(valuep, ctx->stack_pointer + off); - ctx->stack_pointer += sz; + ctx->stack_pointer += a; return 0; } @@ -216,19 +247,34 @@ align_small_int(unsigned char *buf, size_t w, size_t sz) static int allocate_gpr(struct fetch_context *ctx, struct Process *proc, - struct arg_type_info *info, struct value *valuep) + struct arg_type_info *info, struct value *valuep, + size_t off, bool is_hfa_type) { if (ctx->greg > 10) - return allocate_stack_slot(ctx, proc, info, valuep); + return allocate_stack_slot(ctx, proc, info, valuep, is_hfa_type); - int reg_num = ctx->greg++; - if (valuep == NULL) - return 0; + int reg_num = ctx->greg; size_t sz = type_sizeof(proc, info); if (sz == (size_t)-1) return -1; assert(sz == 1 || sz == 2 || sz == 4 || sz == 8); +#if _CALL_ELF == 2 + /* Consume the stack slot corresponding to this arg. */ + if ((sz + off) >= 8) + ctx->greg++; + + if (is_hfa_type) + ctx->stack_pointer += sz; + else + ctx->stack_pointer += 8; +#else + ctx->greg++; +#endif + + if (valuep == NULL) + return 0; + if (value_reserve(valuep, sz) == NULL) return -1; @@ -240,13 +286,14 @@ allocate_gpr(struct fetch_context *ctx, struct Process *proc, u.i64 = read_gpr(ctx, proc, reg_num); if (proc->e_machine == EM_PPC) align_small_int(u.buf, 8, sz); - memcpy(value_get_raw_data(valuep), u.buf, sz); + memcpy(value_get_raw_data(valuep), u.buf + off, sz); return 0; } static int allocate_float(struct fetch_context *ctx, struct Process *proc, - struct arg_type_info *info, struct value *valuep) + struct arg_type_info *info, struct value *valuep, + size_t off, bool is_hfa_type) { int pool = proc->e_machine == EM_PPC64 ? 13 : 8; if (ctx->freg <= pool) { @@ -257,8 +304,12 @@ allocate_float(struct fetch_context *ctx, struct Process *proc, } u = { .d = ctx->fpregs.fpregs[ctx->freg] }; ctx->freg++; + + if (!is_hfa_type) + ctx->vgreg++; + if (proc->e_machine == EM_PPC64) - allocate_gpr(ctx, proc, info, NULL); + allocate_gpr(ctx, proc, info, NULL, off, is_hfa_type); size_t sz = sizeof(double); if (info->type == ARGTYPE_FLOAT) { @@ -272,8 +323,128 @@ allocate_float(struct fetch_context *ctx, struct Process *proc, memcpy(value_get_raw_data(valuep), u.buf, sz); return 0; } - return allocate_stack_slot(ctx, proc, info, valuep); + return allocate_stack_slot(ctx, proc, info, valuep, is_hfa_type); +} + +#if _CALL_ELF == 2 +static int +allocate_hfa(struct fetch_context *ctx, struct Process *proc, + struct arg_type_info *info, struct value *valuep, + enum arg_type hfa_type, size_t hfa_count) +{ + size_t sz = type_sizeof(proc, info); + if (sz == (size_t)-1) + return -1; + + ctx->struct_hfa_size += sz; + + /* There are two changes regarding structure return types: + * * heterogeneous float/vector structs are returned + * in (multiple) FP/vector registers, + * instead of via implicit reference. + * * small structs (up to 16 bytes) are return + * in one or two GPRs, instead of via implicit reference. + * + * Other structures (larger than 16 bytes, not heterogeneous) + * are still returned via implicit reference (i.e. a pointer + * to memory where to return the struct being passed in r3). + * Of course, whether or not an implicit reference pointer + * is present will shift the remaining arguments, + * so you need to get this right for ELFv2 in order + * to get the arguments correct. + * If an actual parameter is known to correspond to an HFA + * formal parameter, each element is passed in the next + * available floating-point argument register starting at fp1 + * until the fp13. The remaining elements of the aggregate are + * passed on the stack. */ + size_t slot_off = 0; + + unsigned char *buf = value_reserve(valuep, sz); + if (buf == NULL) + return -1; + + struct arg_type_info *hfa_info = type_get_simple(hfa_type); + size_t hfa_sz = type_sizeof(proc, hfa_info); + + if (hfa_count > 8) + ctx->struct_hfa_count += hfa_count; + + while (hfa_count > 0 && ctx->freg <= 13) { + int rc; + struct value tmp; + + value_init(&tmp, proc, NULL, hfa_info, 0); + + /* Hetereogeneous struct - get value on GPR or stack. */ + if (((hfa_type == ARGTYPE_FLOAT + || hfa_type == ARGTYPE_DOUBLE) + && hfa_count <= 8)) + rc = allocate_float(ctx, proc, hfa_info, &tmp, + slot_off, true); + else + rc = allocate_gpr(ctx, proc, hfa_info, &tmp, + slot_off, true); + + memcpy(buf, value_get_data(&tmp, NULL), hfa_sz); + + slot_off += hfa_sz; + buf += hfa_sz; + hfa_count--; + if (slot_off == 8) { + slot_off = 0; + ctx->vgreg++; + } + + value_destroy(&tmp); + if (rc < 0) + return -1; + } + if (hfa_count == 0) + return 0; + + /* if no remaining FP, GPR corresponding to slot is used + * Mostly it is in part of r10. */ + if (ctx->struct_hfa_size <= 64 && ctx->vgreg == 10) { + while (ctx->vgreg <= 10) { + struct value tmp; + value_init(&tmp, proc, NULL, hfa_info, 0); + union { + uint64_t i64; + unsigned char buf[0]; + } u; + + u.i64 = read_gpr(ctx, proc, ctx->vgreg); + + memcpy(buf, u.buf + slot_off, hfa_sz); + slot_off += hfa_sz; + buf += hfa_sz; + hfa_count--; + ctx->stack_pointer += hfa_sz; + if (slot_off >= 8 ) { + slot_off = 0; + ctx->vgreg++; + } + value_destroy(&tmp); + } + } + + if (hfa_count == 0) + return 0; + + /* Remaining values are on stack */ + while (hfa_count) { + struct value tmp; + value_init(&tmp, proc, NULL, hfa_info, 0); + + value_in_inferior(&tmp, ctx->stack_pointer); + memcpy(buf, value_get_data(&tmp, NULL), hfa_sz); + ctx->stack_pointer += hfa_sz; + buf += hfa_sz; + hfa_count--; + } + return 0; } +#endif static int allocate_argument(struct fetch_context *ctx, struct Process *proc, @@ -287,13 +458,25 @@ allocate_argument(struct fetch_context *ctx, struct Process *proc, case ARGTYPE_FLOAT: case ARGTYPE_DOUBLE: - return allocate_float(ctx, proc, info, valuep); + return allocate_float(ctx, proc, info, valuep, + 8 - type_sizeof(proc,info), false); case ARGTYPE_STRUCT: if (proc->e_machine == EM_PPC) { if (value_pass_by_reference(valuep) < 0) return -1; } else { +#if _CALL_ELF == 2 + struct arg_type_info *hfa_info; + size_t hfa_size; + hfa_info = type_get_hfa_type(info, &hfa_size); + if (hfa_info != NULL ) { + size_t sz = type_sizeof(proc, info); + ctx->struct_size += sz; + return allocate_hfa(ctx, proc, info, valuep, + hfa_info->type, hfa_size); + } +#endif /* PPC64: Fixed size aggregates and unions passed by * value are mapped to as many doublewords of the * parameter save area as the value uses in memory. @@ -326,6 +509,10 @@ allocate_argument(struct fetch_context *ctx, struct Process *proc, size_t sz = type_sizeof(proc, valuep->type); if (sz == (size_t)-1) return -1; + + if (ctx->ret_struct) + ctx->struct_size += sz; + size_t slots = (sz + width - 1) / width; /* Round up. */ unsigned char *buf = value_reserve(valuep, slots * width); if (buf == NULL) @@ -346,9 +533,11 @@ allocate_argument(struct fetch_context *ctx, struct Process *proc, struct arg_type_info *fp_info = type_get_fp_equivalent(valuep->type); if (fp_info != NULL) - rc = allocate_float(ctx, proc, fp_info, &val); + rc = allocate_float(ctx, proc, fp_info, &val, + 8-type_sizeof(proc,info), false); else - rc = allocate_gpr(ctx, proc, long_info, &val); + rc = allocate_gpr(ctx, proc, long_info, &val, + 0, false); if (rc >= 0) { memcpy(ptr, value_get_data(&val, NULL), width); @@ -363,6 +552,7 @@ allocate_argument(struct fetch_context *ctx, struct Process *proc, return rc; } +#ifndef __LITTLE_ENDIAN__ /* Small values need post-processing. */ if (sz < width) { switch (info->type) { @@ -394,6 +584,7 @@ allocate_argument(struct fetch_context *ctx, struct Process *proc, break; } } +#endif return 0; } @@ -411,7 +602,22 @@ arch_fetch_retval(struct fetch_context *ctx, enum tof type, struct Process *proc, struct arg_type_info *info, struct value *valuep) { + if (fetch_context_init(proc, ctx) < 0) + return -1; + +#if _CALL_ELF == 2 + void *ptr = (void *)(ctx->regs.r64[1]+32); + uint64_t val = ptrace(PTRACE_PEEKTEXT, proc->pid, ptr, 0); + + if (ctx->ret_struct + && ((ctx->struct_size > 64 + || ctx->struct_hfa_count > 8 + || (ctx->struct_hfa_size == 0 && ctx->struct_size > 56) + || (ctx->regs.r64[3] == ctx->regs.r64[1]+32) + || (ctx->regs.r64[3] == val )))) { +#else if (ctx->ret_struct) { +#endif assert(info->type == ARGTYPE_STRUCT); uint64_t addr = read_gpr(ctx, proc, 3); @@ -424,8 +630,6 @@ arch_fetch_retval(struct fetch_context *ctx, enum tof type, return 0; } - if (fetch_context_init(proc, ctx) < 0) - return -1; return allocate_argument(ctx, proc, info, valuep); } --- sysdeps/linux-gnu/ppc/plt.c.ori +++ sysdeps/linux-gnu/ppc/plt.c @@ -136,7 +136,11 @@ */ #define PPC_PLT_STUB_SIZE 16 -#define PPC64_PLT_STUB_SIZE 8 //xxx +#if _CALL_ELF != 2 +#define PPC64_PLT_STUB_SIZE 8 +#else +#define PPC64_PLT_STUB_SIZE 4 +#endif static inline int host_powerpc64() @@ -186,8 +190,13 @@ ppc32_delayed_symbol(struct library_symbol *libsym) if ((insn1 & BRANCH_MASK) == B_INSN || ((insn2 & BRANCH_MASK) == B_INSN /* XXX double cast */ +#ifdef __LITTLE_ENDIAN__ + && (ppc_branch_dest(libsym->enter_addr + 4, insn1) + == (arch_addr_t) (long) libsym->lib->arch.pltgot_addr))) +#else && (ppc_branch_dest(libsym->enter_addr + 4, insn2) == (arch_addr_t) (long) libsym->lib->arch.pltgot_addr))) +#endif { mark_as_resolved(libsym, libsym->arch.resolved_value); } @@ -206,7 +215,7 @@ arch_dynlink_done(struct Process *proc) "couldn't read PLT value for %s(%p): %s\n", libsym->name, libsym->enter_addr, strerror(errno)); - return; + return; } if (proc->e_machine == EM_PPC) @@ -228,8 +237,14 @@ reloc_is_irelative(int machine, GElf_Rela *rela) { bool irelative = false; if (machine == EM_PPC64) { -#ifdef R_PPC64_JMP_IREL +#ifdef __LITTLE_ENDIAN__ +# ifdef R_PPC64_IRELATIVE + irelative = GELF_R_TYPE(rela->r_info) == R_PPC64_IRELATIVE; +# endif +#else +# ifdef R_PPC64_JMP_IREL irelative = GELF_R_TYPE(rela->r_info) == R_PPC64_JMP_IREL; +# endif #endif } else { assert(machine == EM_PPC); @@ -286,6 +301,7 @@ arch_translate_address_dyn(struct Process *proc, arch_addr_t addr, arch_addr_t *ret) { if (proc->e_machine == EM_PPC64) { +#if _CALL_ELF != 2 uint64_t value; if (proc_read_64(proc, addr, &value) < 0) { fprintf(stderr, @@ -297,6 +313,7 @@ arch_translate_address_dyn(struct Process *proc, * arch_addr_t becomes integral type. */ *ret = (arch_addr_t)(uintptr_t)value; return 0; +#endif } *ret = addr; @@ -307,7 +324,8 @@ int arch_translate_address(struct ltelf *lte, arch_addr_t addr, arch_addr_t *ret) { - if (lte->ehdr.e_machine == EM_PPC64) { + if (lte->ehdr.e_machine == EM_PPC64 + && !lte->arch.elfv2_abi) { /* XXX The double cast should be removed when * arch_addr_t becomes integral type. */ GElf_Xword offset @@ -461,7 +479,16 @@ reloc_copy_if_irelative(GElf_Rela *rela, void *data) int arch_elf_init(struct ltelf *lte, struct library *lib) { + + /* Check for ABIv2 in ELF header processor specific flag. */ +#ifndef EF_PPC64_ABI + assert (! (lte->ehdr.e_flags & 3 ) == 2) +#else + lte->arch.elfv2_abi=((lte->ehdr.e_flags & EF_PPC64_ABI) == 2) ; +#endif + if (lte->ehdr.e_machine == EM_PPC64 + && !lte->arch.elfv2_abi && load_opd_data(lte, lib) < 0) return -1; @@ -631,7 +658,7 @@ read_plt_slot_value(struct Process *proc, GElf_Addr addr, GElf_Addr *valp) uint64_t l; /* XXX double cast. */ if (proc_read_64(proc, (arch_addr_t)(uintptr_t)addr, &l) < 0) { - fprintf(stderr, "ptrace .plt slot value @%#" PRIx64": %s\n", + debug(DEBUG_EVENT, "ptrace .plt slot value @%#" PRIx64": %s", addr, strerror(errno)); return -1; } @@ -648,7 +675,7 @@ unresolve_plt_slot(struct Process *proc, GElf_Addr addr, GElf_Addr value) * pointers intact. Hence the only adjustment that we need to * do is to IP. */ if (ptrace(PTRACE_POKETEXT, proc->pid, addr, value) < 0) { - fprintf(stderr, "failed to unresolve .plt slot: %s\n", + debug(DEBUG_EVENT, "failed to unresolve .plt slot: %s", strerror(errno)); return -1; } @@ -661,9 +688,48 @@ arch_elf_add_func_entry(struct Process *proc, struct ltelf *lte, arch_addr_t addr, const char *name, struct library_symbol **ret) { - if (lte->ehdr.e_machine != EM_PPC || lte->ehdr.e_type == ET_DYN) +#ifndef PPC64_LOCAL_ENTRY_OFFSET + assert(! lte->arch.elfv2_abi); +#else + /* With ABIv2 st_other field contains an offset. */ + if (lte->arch.elfv2_abi) + addr += PPC64_LOCAL_ENTRY_OFFSET(sym->st_other); +#endif + + int st_info = GELF_ST_TYPE(sym->st_info); + + if ((lte->ehdr.e_machine != EM_PPC && sym->st_other == 0) + || lte->ehdr.e_type == ET_DYN + || (st_info == STT_FUNC && ! sym->st_other)) return plt_default; + if (st_info == STT_FUNC) { + /* Put the default symbol to the chain. + * The addr has already been updated with + * symbol offset */ + char *full_name = strdup(name); + if (full_name == NULL) { + fprintf(stderr, "couldn't copy name of %s: %s\n", + name, strerror(errno)); + free(full_name); + return plt_fail; + } + struct library_symbol *libsym = malloc(sizeof *libsym); + if (libsym == NULL + || library_symbol_init(libsym, addr, full_name, 1, + LS_TOPLT_NONE) < 0) { + free(libsym); + delete_symbol_chain(libsym); + libsym = NULL; + fprintf(stderr, "Couldn't add symbol %s" + "for tracing.\n", name); + } + full_name = NULL; + libsym->next = *ret; + *ret = libsym; + return plt_ok; + } + bool ifunc = false; #ifdef STT_GNU_IFUNC ifunc = GELF_ST_TYPE(sym->st_info) == STT_GNU_IFUNC; @@ -782,9 +848,15 @@ arch_elf_add_plt_entry(struct Process *proc, struct ltelf *lte, assert(plt_slot_addr >= lte->plt_addr || plt_slot_addr < lte->plt_addr + lte->plt_size); + /* Should avoid to do read if dynamic linker hasn't run yet + * or allow -1 a valid return code. */ GElf_Addr plt_slot_value; - if (read_plt_slot_value(proc, plt_slot_addr, &plt_slot_value) < 0) + if (read_plt_slot_value(proc, plt_slot_addr, &plt_slot_value) < 0) { - goto fail; + if (!lte->arch.elfv2_abi) + return plt_fail; + else + return PPC_PLT_UNRESOLVED; + } struct library_symbol *libsym = malloc(sizeof(*libsym)); if (libsym == NULL) { @@ -1023,8 +1095,12 @@ ppc_plt_bp_continue(struct breakpoint *bp, struct Process *proc) return; } +#if _CALL_ELF == 2 + continue_after_breakpoint(proc, bp); +#else jump_to_entry_point(proc, bp); continue_process(proc->pid); +#endif return; case PPC64_PLT_STUB: @@ -1100,7 +1176,11 @@ arch_library_symbol_init(struct library_symbol *libsym) /* We set type explicitly in the code above, where we have the * necessary context. This is for calls from ltrace-elf.c and * such. */ +#if _CALL_ELF == 2 + libsym->arch.type = PPC_PLT_UNRESOLVED; +#else libsym->arch.type = PPC_DEFAULT; +#endif return 0; } --- sysdeps/linux-gnu/ppc/trace.c.ori +++ sysdeps/linux-gnu/ppc/trace.c @@ -63,9 +63,15 @@ syscall_p(struct Process *proc, int status, int *sysnum) if (WIFSTOPPED(status) && WSTOPSIG(status) == (SIGTRAP | proc->tracesysgood)) { long pc = (long)get_instruction_pointer(proc); +#ifndef __LITTLE_ENDIAN__ int insn = (int)ptrace(PTRACE_PEEKTEXT, proc->pid, pc - sizeof(long), 0); +#else + int insn = + (int)ptrace(PTRACE_PEEKTEXT, proc->pid, pc - sizeof(int), + 0); +#endif if (insn == SYSCALL_INSN) { *sysnum = @@ -125,7 +131,11 @@ arch_sw_singlestep(struct Process *proc, struct breakpoint *sbp, return -1; uint32_t insn; #ifdef __powerpc64__ +# ifdef __LITTLE_ENDIAN__ + insn = (uint32_t) l ; +# else insn = l >> 32; +# endif #else insn = l; #endif
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