Mercurial > hg > truffle
view src/share/tools/hsdis/hsdis.c @ 795:215f81b4d9b3
6841831: G1: assert(contains_reference(from),"We just added it!") fires
Summary: During parallel rset updating we have to make sure that the worker ids of the refinement threads do not intersect with the worker ids that can be claimed by the mutator threads.
Reviewed-by: tonyp
| author | iveresov |
|---|---|
| date | Mon, 18 May 2009 11:52:46 -0700 |
| parents | 67a2f5ba5582 |
| children | bd02caa94611 |
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/* * Copyright 2008 Sun Microsystems, Inc. All Rights Reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara, * CA 95054 USA or visit www.sun.com if you need additional information or * have any questions. * */ /* hsdis.c -- dump a range of addresses as native instructions This implements the plugin protocol required by the HotSpot PrintAssembly option. */ #include "hsdis.h" #include <sysdep.h> #include <libiberty.h> #include <bfd.h> #include <dis-asm.h> #include <inttypes.h> #ifndef bool #define bool int #define true 1 #define false 0 #endif /*bool*/ /* short names for stuff in hsdis.h */ typedef decode_instructions_event_callback_ftype event_callback_t; typedef decode_instructions_printf_callback_ftype printf_callback_t; /* disassemble_info.application_data object */ struct hsdis_app_data { /* the arguments to decode_instructions */ uintptr_t start; uintptr_t end; event_callback_t event_callback; void* event_stream; printf_callback_t printf_callback; void* printf_stream; bool losing; /* the architecture being disassembled */ const char* arch_name; const bfd_arch_info_type* arch_info; /* the disassembler we are going to use: */ disassembler_ftype dfn; struct disassemble_info dinfo; /* the actual struct! */ char mach_option[64]; char insn_options[256]; }; #define DECL_APP_DATA(dinfo) \ struct hsdis_app_data* app_data = (struct hsdis_app_data*) (dinfo)->application_data #define DECL_EVENT_CALLBACK(app_data) \ event_callback_t event_callback = (app_data)->event_callback; \ void* event_stream = (app_data)->event_stream #define DECL_PRINTF_CALLBACK(app_data) \ printf_callback_t printf_callback = (app_data)->printf_callback; \ void* printf_stream = (app_data)->printf_stream static void print_help(struct hsdis_app_data* app_data, const char* msg, const char* arg); static void setup_app_data(struct hsdis_app_data* app_data, const char* options); static const char* format_insn_close(const char* close, disassemble_info* dinfo, char* buf, size_t bufsize); void* #ifdef DLL_ENTRY DLL_ENTRY #endif decode_instructions(void* start_pv, void* end_pv, event_callback_t event_callback_arg, void* event_stream_arg, printf_callback_t printf_callback_arg, void* printf_stream_arg, const char* options) { struct hsdis_app_data app_data; memset(&app_data, 0, sizeof(app_data)); app_data.start = (uintptr_t) start_pv; app_data.end = (uintptr_t) end_pv; app_data.event_callback = event_callback_arg; app_data.event_stream = event_stream_arg; app_data.printf_callback = printf_callback_arg; app_data.printf_stream = printf_stream_arg; setup_app_data(&app_data, options); char buf[128]; { /* now reload everything from app_data: */ DECL_EVENT_CALLBACK(&app_data); DECL_PRINTF_CALLBACK(&app_data); uintptr_t start = app_data.start; uintptr_t end = app_data.end; uintptr_t p = start; (*event_callback)(event_stream, "insns", (void*)start); (*event_callback)(event_stream, "mach name='%s'", (void*) app_data.arch_info->printable_name); if (app_data.dinfo.bytes_per_line != 0) { (*event_callback)(event_stream, "format bytes-per-line='%p'/", (void*)(intptr_t) app_data.dinfo.bytes_per_line); } while (p < end && !app_data.losing) { (*event_callback)(event_stream, "insn", (void*) p); /* reset certain state, so we can read it with confidence */ app_data.dinfo.insn_info_valid = 0; app_data.dinfo.branch_delay_insns = 0; app_data.dinfo.data_size = 0; app_data.dinfo.insn_type = 0; int size = (*app_data.dfn)((bfd_vma) p, &app_data.dinfo); if (size > 0) p += size; else app_data.losing = true; const char* insn_close = format_insn_close("/insn", &app_data.dinfo, buf, sizeof(buf)); (*event_callback)(event_stream, insn_close, (void*) p); /* follow each complete insn by a nice newline */ (*printf_callback)(printf_stream, "\n"); } (*event_callback)(event_stream, "/insns", (void*) p); return (void*) p; } } /* take the address of the function, for luck, and also test the typedef: */ const decode_instructions_ftype decode_instructions_address = &decode_instructions; static const char* format_insn_close(const char* close, disassemble_info* dinfo, char* buf, size_t bufsize) { if (!dinfo->insn_info_valid) return close; enum dis_insn_type itype = dinfo->insn_type; int dsize = dinfo->data_size, delays = dinfo->branch_delay_insns; if ((itype == dis_nonbranch && (dsize | delays) == 0) || (strlen(close) + 3*20 > bufsize)) return close; const char* type = "unknown"; switch (itype) { case dis_nonbranch: type = NULL; break; case dis_branch: type = "branch"; break; case dis_condbranch: type = "condbranch"; break; case dis_jsr: type = "jsr"; break; case dis_condjsr: type = "condjsr"; break; case dis_dref: type = "dref"; break; case dis_dref2: type = "dref2"; break; } strcpy(buf, close); char* p = buf; if (type) sprintf(p += strlen(p), " type='%s'", type); if (dsize) sprintf(p += strlen(p), " dsize='%d'", dsize); if (delays) sprintf(p += strlen(p), " delay='%d'", delays); return buf; } /* handler functions */ static int hsdis_read_memory_func(bfd_vma memaddr, bfd_byte* myaddr, unsigned int length, struct disassemble_info* dinfo) { uintptr_t memaddr_p = (uintptr_t) memaddr; DECL_APP_DATA(dinfo); if (memaddr_p + length > app_data->end) { /* read is out of bounds */ return EIO; } else { memcpy(myaddr, (bfd_byte*) memaddr_p, length); return 0; } } static void hsdis_print_address_func(bfd_vma vma, struct disassemble_info* dinfo) { /* the actual value to print: */ void* addr_value = (void*) (uintptr_t) vma; DECL_APP_DATA(dinfo); DECL_EVENT_CALLBACK(app_data); /* issue the event: */ void* result = (*event_callback)(event_stream, "addr/", addr_value); if (result == NULL) { /* event declined */ generic_print_address(vma, dinfo); } } /* configuration */ static void set_optional_callbacks(struct hsdis_app_data* app_data); static void parse_caller_options(struct hsdis_app_data* app_data, const char* caller_options); static const char* native_arch_name(); static enum bfd_endian native_endian(); static const bfd_arch_info_type* find_arch_info(const char* arch_nane); static bfd* get_native_bfd(const bfd_arch_info_type* arch_info, /* to avoid malloc: */ bfd* empty_bfd, bfd_target* empty_xvec); static void init_disassemble_info_from_bfd(struct disassemble_info* dinfo, void *stream, fprintf_ftype fprintf_func, bfd* bfd, char* disassembler_options); static void parse_fake_insn(disassembler_ftype dfn, struct disassemble_info* dinfo); static void setup_app_data(struct hsdis_app_data* app_data, const char* caller_options) { /* Make reasonable defaults for null callbacks. A non-null stream for a null callback is assumed to be a FILE* for output. Events are rendered as XML. */ set_optional_callbacks(app_data); /* Look into caller_options for anything interesting. */ if (caller_options != NULL) parse_caller_options(app_data, caller_options); /* Discover which architecture we are going to disassemble. */ app_data->arch_name = &app_data->mach_option[0]; if (app_data->arch_name[0] == '\0') app_data->arch_name = native_arch_name(); app_data->arch_info = find_arch_info(app_data->arch_name); /* Make a fake bfd to hold the arch. and byteorder info. */ struct { bfd_target empty_xvec; bfd empty_bfd; } buf; bfd* native_bfd = get_native_bfd(app_data->arch_info, /* to avoid malloc: */ &buf.empty_bfd, &buf.empty_xvec); init_disassemble_info_from_bfd(&app_data->dinfo, app_data->printf_stream, app_data->printf_callback, native_bfd, app_data->insn_options); /* Finish linking together the various callback blocks. */ app_data->dinfo.application_data = (void*) app_data; app_data->dfn = disassembler(native_bfd); app_data->dinfo.print_address_func = hsdis_print_address_func; app_data->dinfo.read_memory_func = hsdis_read_memory_func; if (app_data->dfn == NULL) { const char* bad = app_data->arch_name; static bool complained; if (bad == &app_data->mach_option[0]) print_help(app_data, "bad mach=%s", bad); else if (!complained) print_help(app_data, "bad native mach=%s; please port hsdis to this platform", bad); complained = true; /* must bail out */ app_data->losing = true; return; } parse_fake_insn(app_data->dfn, &app_data->dinfo); } /* ignore all events, return a null */ static void* null_event_callback(void* ignore_stream, const char* ignore_event, void* arg) { return NULL; } /* print all events as XML markup */ static void* xml_event_callback(void* stream, const char* event, void* arg) { FILE* fp = (FILE*) stream; #define NS_PFX "dis:" if (event[0] != '/') { /* issue the tag, with or without a formatted argument */ fprintf(fp, "<"NS_PFX); fprintf(fp, event, arg); fprintf(fp, ">"); } else { ++event; /* skip slash */ const char* argp = strchr(event, ' '); if (argp == NULL) { /* no arguments; just issue the closing tag */ fprintf(fp, "</"NS_PFX"%s>", event); } else { /* split out the closing attributes as <dis:foo_done attr='val'/> */ int event_prefix = (argp - event); fprintf(fp, "<"NS_PFX"%.*s_done", event_prefix, event); fprintf(fp, argp, arg); fprintf(fp, "/></"NS_PFX"%.*s>", event_prefix, event); } } return NULL; } static void set_optional_callbacks(struct hsdis_app_data* app_data) { if (app_data->printf_callback == NULL) { int (*fprintf_callback)(FILE*, const char*, ...) = &fprintf; FILE* fprintf_stream = stdout; app_data->printf_callback = (printf_callback_t) fprintf_callback; if (app_data->printf_stream == NULL) app_data->printf_stream = (void*) fprintf_stream; } if (app_data->event_callback == NULL) { if (app_data->event_stream == NULL) app_data->event_callback = &null_event_callback; else app_data->event_callback = &xml_event_callback; } } static void parse_caller_options(struct hsdis_app_data* app_data, const char* caller_options) { char* iop_base = app_data->insn_options; char* iop_limit = iop_base + sizeof(app_data->insn_options) - 1; char* iop = iop_base; const char* p; for (p = caller_options; p != NULL; ) { const char* q = strchr(p, ','); size_t plen = (q == NULL) ? strlen(p) : ((q++) - p); if (plen == 4 && strncmp(p, "help", plen) == 0) { print_help(app_data, NULL, NULL); } else if (plen >= 5 && strncmp(p, "mach=", 5) == 0) { char* mach_option = app_data->mach_option; size_t mach_size = sizeof(app_data->mach_option); mach_size -= 1; /*leave room for the null*/ if (plen > mach_size) plen = mach_size; strncpy(mach_option, p, plen); mach_option[plen] = '\0'; } else if (plen > 6 && strncmp(p, "hsdis-", 6)) { // do not pass these to the next level } else { /* just copy it; {i386,sparc}-dis.c might like to see it */ if (iop > iop_base && iop < iop_limit) (*iop++) = ','; if (iop + plen > iop_limit) plen = iop_limit - iop; strncpy(iop, p, plen); iop += plen; } p = q; } } static void print_help(struct hsdis_app_data* app_data, const char* msg, const char* arg) { DECL_PRINTF_CALLBACK(app_data); if (msg != NULL) { (*printf_callback)(printf_stream, "hsdis: "); (*printf_callback)(printf_stream, msg, arg); (*printf_callback)(printf_stream, "\n"); } (*printf_callback)(printf_stream, "hsdis output options:\n"); if (printf_callback == (printf_callback_t) &fprintf) disassembler_usage((FILE*) printf_stream); else disassembler_usage(stderr); /* better than nothing */ (*printf_callback)(printf_stream, " mach=<arch> select disassembly mode\n"); #if defined(LIBARCH_i386) || defined(LIBARCH_amd64) (*printf_callback)(printf_stream, " mach=i386 select 32-bit mode\n"); (*printf_callback)(printf_stream, " mach=x86-64 select 64-bit mode\n"); (*printf_callback)(printf_stream, " suffix always print instruction suffix\n"); #endif (*printf_callback)(printf_stream, " help print this message\n"); } /* low-level bfd and arch stuff that binutils doesn't do for us */ static const bfd_arch_info_type* find_arch_info(const char* arch_name) { const bfd_arch_info_type* arch_info = bfd_scan_arch(arch_name); if (arch_info == NULL) { extern const bfd_arch_info_type bfd_default_arch_struct; arch_info = &bfd_default_arch_struct; } return arch_info; } static const char* native_arch_name() { const char* res = NULL; #ifdef LIBARCH_i386 res = "i386"; #endif #ifdef LIBARCH_amd64 res = "i386:x86-64"; #endif #ifdef LIBARCH_sparc res = "sparc:v8plusb"; #endif #ifdef LIBARCH_sparcv9 res = "sparc:v9b"; #endif if (res == NULL) res = "architecture not set in Makefile!"; return res; } static enum bfd_endian native_endian() { int32_t endian_test = 'x'; if (*(const char*) &endian_test == 'x') return BFD_ENDIAN_LITTLE; else return BFD_ENDIAN_BIG; } static bfd* get_native_bfd(const bfd_arch_info_type* arch_info, bfd* empty_bfd, bfd_target* empty_xvec) { memset(empty_bfd, 0, sizeof(*empty_bfd)); memset(empty_xvec, 0, sizeof(*empty_xvec)); empty_xvec->flavour = bfd_target_unknown_flavour; empty_xvec->byteorder = native_endian(); empty_bfd->xvec = empty_xvec; empty_bfd->arch_info = arch_info; return empty_bfd; } static int read_zero_data_only(bfd_vma ignore_p, bfd_byte* myaddr, unsigned int length, struct disassemble_info *ignore_info) { memset(myaddr, 0, length); return 0; } static int print_to_dev_null(void* ignore_stream, const char* ignore_format, ...) { return 0; } /* Prime the pump by running the selected disassembler on a null input. This forces the machine-specific disassembler to divulge invariant information like bytes_per_line. */ static void parse_fake_insn(disassembler_ftype dfn, struct disassemble_info* dinfo) { typedef int (*read_memory_ftype) (bfd_vma memaddr, bfd_byte *myaddr, unsigned int length, struct disassemble_info *info); read_memory_ftype read_memory_func = dinfo->read_memory_func; fprintf_ftype fprintf_func = dinfo->fprintf_func; dinfo->read_memory_func = &read_zero_data_only; dinfo->fprintf_func = &print_to_dev_null; (*dfn)(0, dinfo); // put it back: dinfo->read_memory_func = read_memory_func; dinfo->fprintf_func = fprintf_func; } static void init_disassemble_info_from_bfd(struct disassemble_info* dinfo, void *stream, fprintf_ftype fprintf_func, bfd* abfd, char* disassembler_options) { init_disassemble_info(dinfo, stream, fprintf_func); dinfo->flavour = bfd_get_flavour(abfd); dinfo->arch = bfd_get_arch(abfd); dinfo->mach = bfd_get_mach(abfd); dinfo->disassembler_options = disassembler_options; dinfo->octets_per_byte = bfd_octets_per_byte (abfd); dinfo->skip_zeroes = sizeof(void*) * 2; dinfo->skip_zeroes_at_end = sizeof(void*)-1; dinfo->disassembler_needs_relocs = FALSE; if (bfd_big_endian(abfd)) dinfo->display_endian = dinfo->endian = BFD_ENDIAN_BIG; else if (bfd_little_endian(abfd)) dinfo->display_endian = dinfo->endian = BFD_ENDIAN_LITTLE; else dinfo->endian = native_endian(); disassemble_init_for_target(dinfo); }