Mercurial > hg > graal-compiler
view agent/src/os/solaris/dbx/svc_agent_dbx.cpp @ 1552:c18cbe5936b8
6941466: Oracle rebranding changes for Hotspot repositories
Summary: Change all the Sun copyrights to Oracle copyright
Reviewed-by: ohair
| author | trims |
|---|---|
| date | Thu, 27 May 2010 19:08:38 -0700 |
| parents | a61af66fc99e |
| children |
line wrap: on
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/* * Copyright (c) 2000, 2002, Oracle and/or its affiliates. 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 Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ // This is the implementation of a very simple dbx import module which // handles requests from the VM which come in over a socket. The // higher-level Java wrapper for dbx starts the debugger, attaches to // the process, imports this command, and runs it. After that, the SA // writes commands to this agent via its own private communications // channel. The intent is to move away from the text-based front-end // completely in the near future (no more calling "debug" by printing // text to dbx's stdin). #include <stdio.h> #include <errno.h> #include <ctype.h> #include <sys/types.h> #include <sys/socket.h> #include <unistd.h> #include <string.h> #include <stropts.h> #include <netinet/in.h> #include <netinet/tcp.h> #include <proc_service.h> #include <sys/procfs_isa.h> #include <rtld_db.h> #include "proc_service_2.h" #include "svc_agent_dbx.hpp" static ServiceabilityAgentDbxModule* module = NULL; #define NEEDS_CLEANUP // Useful for debugging #define VERBOSE_DEBUGGING #ifdef VERBOSE_DEBUGGING # define debug_only(x) x #else # define debug_only(x) #endif // For profiling //#define PROFILING #ifdef PROFILING #define PROFILE_COUNT 200 static Timer scanTimer; static Timer workTimer; static Timer writeTimer; static int numRequests = 0; #endif /* PROFILING */ const char* ServiceabilityAgentDbxModule::CMD_ADDRESS_SIZE = "address_size"; const char* ServiceabilityAgentDbxModule::CMD_PEEK_FAIL_FAST = "peek_fail_fast"; const char* ServiceabilityAgentDbxModule::CMD_PEEK = "peek"; const char* ServiceabilityAgentDbxModule::CMD_POKE = "poke"; const char* ServiceabilityAgentDbxModule::CMD_MAPPED = "mapped"; const char* ServiceabilityAgentDbxModule::CMD_LOOKUP = "lookup"; const char* ServiceabilityAgentDbxModule::CMD_THR_GREGS = "thr_gregs"; const char* ServiceabilityAgentDbxModule::CMD_EXIT = "exit"; // The initialization routines must not have C++ name mangling extern "C" { /** This is the initialization routine called by dbx upon importing of this module. Returns 0 upon successful initialization, -1 upon failure. */ int shell_imp_init(int major, int minor, shell_imp_interp_t interp, int argc, char *argv[]) { // Ensure shell interpreter data structure is laid out the way we // expect if (major != SHELL_IMP_MAJOR) { debug_only(fprintf(stderr, "Serviceability agent: unexpected value for SHELL_IMP_MAJOR (got %d, expected %d)\n", major, SHELL_IMP_MAJOR);) return -1; } if (minor < SHELL_IMP_MINOR) { debug_only(fprintf(stderr, "Serviceability agent: unexpected value for SHELL_IMP_MINOR (got %d, expected >= %d)\n", minor, SHELL_IMP_MINOR);) return -1; } if (module != NULL) { debug_only(fprintf(stderr, "Serviceability agent: module appears to already be initialized (should not happen)\n");) // Already initialized. Should not happen. return -1; } module = new ServiceabilityAgentDbxModule(major, minor, interp, argc, argv); if (!module->install()) { debug_only(fprintf(stderr, "Serviceability agent: error installing import module\n");) delete module; module = NULL; return -1; } // Installation was successful. Next step will be for the user to // enter the appropriate command on the command line, which will // make the SA's dbx module wait for commands to come in over the // socket. return 0; } /** This is the routine called by dbx upon unloading of this module. Returns 0 upon success, -1 upon failure. */ int shell_imp_fini(shell_imp_interp_t) { if (module == NULL) { return -1; } bool res = module->uninstall(); delete module; module = NULL; if (!res) { return -1; } return 0; } } // extern "C" /** This is the routine which is called by the dbx shell when the user requests the serviceability agent module to run. This delegates to ServiceabilityAgentDbxModule::run. This routine's signature must match that of shell_imp_fun_t. */ extern "C" { static int svc_agent_run(shell_imp_interp_t, int, char **, void *) { if (module == NULL) { return -1; } module->run(); return 0; } } /* * Implementation of ServiceabilityAgentDbxModule class */ // NOTE: we need to forward declare the special "ps_get_prochandle2" // function which allows examination of core files as well. It isn't // currently in proc_service_2.h. Note also that it has name mangling // because it isn't declared extern "C". //const struct ps_prochandle *ps_get_prochandle2(int cores_too); ServiceabilityAgentDbxModule::ServiceabilityAgentDbxModule(int, int, shell_imp_interp_t interp, int argc, char *argv[]) :myComm(32768, 131072) { _interp = interp; _argc = argc; _argv = argv; _tdb_agent = NULL; peek_fail_fast = false; libThreadName = NULL; } ServiceabilityAgentDbxModule::~ServiceabilityAgentDbxModule() { if (_command != NULL) { uninstall(); } } char* readCStringFromProcess(psaddr_t addr) { char c; int num = 0; ps_prochandle* cur_proc = (ps_prochandle*) ps_get_prochandle2(1); // Search for null terminator do { if (ps_pread(cur_proc, addr + num, &c, 1) != PS_OK) { return NULL; } ++num; } while (c != 0); // Allocate string char* res = new char[num]; if (ps_pread(cur_proc, addr, res, num) != PS_OK) { delete[] res; return NULL; } return res; } int findLibThreadCB(const rd_loadobj_t* lo, void* data) { ServiceabilityAgentDbxModule* module = (ServiceabilityAgentDbxModule*) data; char* name = readCStringFromProcess(lo->rl_nameaddr); if (strstr(name, "libthread.so") != NULL) { module->libThreadName = name; return 0; } else { delete[] name; return 1; } } bool ServiceabilityAgentDbxModule::install() { // NOTE interdependency between here and Java side wrapper // FIXME: casts of string literal to char * to match prototype _command = shell_imp_define_command((char *) "svc_agent_run", &svc_agent_run, 0, NULL, (char *) "Run the serviceability agent's dbx module.\n" "This routine causes the module to listen on a socket for requests.\n" "It does not return until the Java-side code tells it to exit, at\n" "which point control is returned to the dbx shell."); if (_command == NULL) { debug_only(fprintf(stderr, "Serviceability agent: Failed to install svc_agent_run command\n")); return false; } // This is fairly painful. Since dbx doesn't currently load // libthread_db with RTLD_GLOBAL, we can't just use RTLD_DEFAULT for // the argument to dlsym. Instead, we have to use rtld_db to search // through the loaded objects in the target process for libthread.so and // Try rtld_db if (rd_init(RD_VERSION) != RD_OK) { debug_only(fprintf(stderr, "Serviceability agent: Unable to init rtld_db\n")); return false; } rd_agent_t* rda = rd_new((struct ps_prochandle*) ps_get_prochandle2(1)); if (rda == NULL) { debug_only(fprintf(stderr, "Serviceability agent: Unable to allocate rtld_db agent\n")); return false; } if (rd_loadobj_iter(rda, (rl_iter_f*) findLibThreadCB, this) != RD_OK) { debug_only(fprintf(stderr, "Serviceability agent: Loadobject iteration failed\n")); return false; } if (libThreadName == NULL) { debug_only(fprintf(stderr, "Serviceability agent: Failed to find pathname to libthread.so in target process\n")); return false; } // Find and open libthread_db.so char* slash = strrchr(libThreadName, '/'); if (slash == NULL) { debug_only(fprintf(stderr, "Serviceability agent: can't parse path to libthread.so \"%s\"\n")); return false; } int slashPos = slash - libThreadName; char* buf = new char[slashPos + strlen("libthread_db.so") + 20]; // slop if (buf == NULL) { debug_only(fprintf(stderr, "Serviceability agent: error allocating libthread_db.so pathname\n")); return false; } strncpy(buf, libThreadName, slashPos + 1); // Check dbx's data model; use sparcv9/ subdirectory if 64-bit and // if target process is 32-bit if ((sizeof(void*) == 8) && (strstr(libThreadName, "sparcv9") == NULL)) { strcpy(buf + slashPos + 1, "sparcv9/"); slashPos += strlen("sparcv9/"); } strcpy(buf + slashPos + 1, "libthread_db.so"); libThreadDB = dlopen(buf, RTLD_LAZY); void* tmpDB = libThreadDB; if (libThreadDB == NULL) { debug_only(fprintf(stderr, "Serviceability agent: Warning: unable to find libthread_db.so at \"%s\"\n", buf)); // Would like to handle this case as well. Maybe dbx has a better // idea of where libthread_db.so lies. If the problem with dbx // loading libthread_db without RTLD_GLOBAL specified ever gets // fixed, we could run this code all the time. tmpDB = RTLD_DEFAULT; } delete[] buf; // Initialize access to libthread_db td_init_fn = (td_init_fn_t*) dlsym(tmpDB, "td_init"); td_ta_new_fn = (td_ta_new_fn_t*) dlsym(tmpDB, "td_ta_new"); td_ta_delete_fn = (td_ta_delete_fn_t*) dlsym(tmpDB, "td_ta_delete"); td_ta_map_id2thr_fn = (td_ta_map_id2thr_fn_t*) dlsym(tmpDB, "td_ta_map_id2thr"); td_thr_getgregs_fn = (td_thr_getgregs_fn_t*) dlsym(tmpDB, "td_thr_getgregs"); if (td_init_fn == NULL || td_ta_new_fn == NULL || td_ta_delete_fn == NULL || td_ta_map_id2thr_fn == NULL || td_thr_getgregs_fn == NULL) { debug_only(fprintf(stderr, "Serviceability agent: Failed to find one or more libthread_db symbols:\n")); debug_only(if (td_init_fn == NULL) fprintf(stderr, " td_init\n")); debug_only(if (td_ta_new_fn == NULL) fprintf(stderr, " td_ta_new\n")); debug_only(if (td_ta_delete_fn == NULL) fprintf(stderr, " td_ta_delete\n")); debug_only(if (td_ta_map_id2thr_fn == NULL) fprintf(stderr, " td_ta_map_id2thr\n")); debug_only(if (td_thr_getgregs_fn == NULL) fprintf(stderr, " td_thr_getgregs\n")); return false; } if ((*td_init_fn)() != TD_OK) { debug_only(fprintf(stderr, "Serviceability agent: Failed to initialize libthread_db\n")); return false; } return true; } bool ServiceabilityAgentDbxModule::uninstall() { if (_command == NULL) { return false; } if (libThreadDB != NULL) { dlclose(libThreadDB); libThreadDB = NULL; } int res = shell_imp_undefine_command(_command); if (res != 0) { return false; } return true; } bool ServiceabilityAgentDbxModule::run() { // This is where most of the work gets done. // The command processor loop looks like the following: // - create listening socket // - accept a connection (only one for now) // - while that connection is open and the "exit" command has not // been received: // - read command // - if it's the exit command, cleanup and return // - otherwise, process command and write result int listening_socket = socket(AF_INET, SOCK_STREAM, 0); if (listening_socket < 0) { return false; } // Set the SO_REUSEADDR property on the listening socket. This // prevents problems with calls to bind() to the same port failing // after this process exits. This seems to work on all platforms. int reuse_address = 1; if (setsockopt(listening_socket, SOL_SOCKET, SO_REUSEADDR, (char *)&reuse_address, sizeof(reuse_address)) < 0) { close(listening_socket); return false; } sockaddr_in server_address; // Build the server address. We can bind the listening socket to the // INADDR_ANY internet address. memset((char*)&server_address, 0, sizeof(server_address)); server_address.sin_family = AF_INET; server_address.sin_addr.s_addr = (unsigned long)htonl(INADDR_ANY); server_address.sin_port = htons((short)PORT); // Bind socket to port if (bind(listening_socket, (sockaddr*) &server_address, sizeof(server_address)) < 0) { close(listening_socket); return false; } // Arbitrarily chosen backlog of 5 (shouldn't matter since we expect // at most one connection) if (listen(listening_socket, 5) < 0) { close(listening_socket); return false; } // OK, now ready to wait for a data connection. This call to // accept() will block. struct sockaddr_in client_address; int address_len = sizeof(client_address); int client_socket = accept(listening_socket, (sockaddr*) &client_address, &address_len); // Close listening socket regardless of whether accept() succeeded. // (FIXME: this may be annoying, especially during debugging, but I // really feel that robustness and multiple connections should be // handled higher up, e.g., at the Java level -- multiple clients // could conceivably connect to the SA via RMI, and that would be a // more robust solution than implementing multiple connections at // this level) NEEDS_CLEANUP; // NOTE: the call to shutdown() usually fails, so don't panic if this happens shutdown(listening_socket, 2); if (close(listening_socket) < 0) { debug_only(fprintf(stderr, "Serviceability agent: Error closing listening socket\n")); return false; } if (client_socket < 0) { debug_only(fprintf(stderr, "Serviceability agent: Failed to open client socket\n")); // No more cleanup necessary return false; } // Attempt to disable TCP buffering on this socket. We send small // amounts of data back and forth and don't want buffering. int buffer_val = 1; if (setsockopt(client_socket, IPPROTO_IP, TCP_NODELAY, (char *) &buffer_val, sizeof(buffer_val)) < 0) { debug_only(fprintf(stderr, "Serviceability agent: Failed to set TCP_NODELAY option on client socket\n")); cleanup(client_socket); return false; } // OK, we have the data socket through which we will communicate // with the Java side. Wait for commands or until reading or writing // caused an error. bool should_continue = true; myComm.setSocket(client_socket); #ifdef PROFILING scanTimer.reset(); workTimer.reset(); writeTimer.reset(); #endif // Allocate a new thread agent for libthread_db if ((*td_ta_new_fn)((ps_prochandle*) ps_get_prochandle2(1), &_tdb_agent) != TD_OK) { debug_only(fprintf(stderr, "Serviceability agent: Failed to allocate thread agent\n")); cleanup(client_socket); return false; } do { // Decided to use text to communicate between these processes. // Probably will make debugging easier -- could telnet in if // necessary. Will make scanning harder, but probably doesn't // matter. // Why not just do what workshop does and parse dbx's console? // Probably could do that, but at least this way we are in control // of the text format on both ends. // FIXME: should have some way of synchronizing these commands // between the C and Java sources. NEEDS_CLEANUP; // Do a blocking read of a line from the socket. char *input_buffer = myComm.readLine(); if (input_buffer == NULL) { debug_only(fprintf(stderr, "Serviceability agent: error during read: errno = %d\n", errno)); debug_only(perror("Serviceability agent")); // Error occurred during read. // FIXME: should guard against SIGPIPE cleanup(client_socket); return false; } // OK, now ready to scan. See README-commands.txt for syntax // descriptions. bool res = false; if (!strncmp(input_buffer, CMD_ADDRESS_SIZE, strlen(CMD_ADDRESS_SIZE))) { res = handleAddressSize(input_buffer + strlen(CMD_ADDRESS_SIZE)); } else if (!strncmp(input_buffer, CMD_PEEK_FAIL_FAST, strlen(CMD_PEEK_FAIL_FAST))) { res = handlePeekFailFast(input_buffer + strlen(CMD_PEEK_FAIL_FAST)); } else if (!strncmp(input_buffer, CMD_PEEK, strlen(CMD_PEEK))) { res = handlePeek(input_buffer + strlen(CMD_PEEK)); } else if (!strncmp(input_buffer, CMD_POKE, strlen(CMD_POKE))) { res = handlePoke(input_buffer + strlen(CMD_POKE)); } else if (!strncmp(input_buffer, CMD_MAPPED, strlen(CMD_MAPPED))) { res = handleMapped(input_buffer + strlen(CMD_MAPPED)); } else if (!strncmp(input_buffer, CMD_LOOKUP, strlen(CMD_LOOKUP))) { res = handleLookup(input_buffer + strlen(CMD_LOOKUP)); } else if (!strncmp(input_buffer, CMD_THR_GREGS, strlen(CMD_THR_GREGS))) { res = handleThrGRegs(input_buffer + strlen(CMD_THR_GREGS)); } else if (!strncmp(input_buffer, CMD_EXIT, strlen(CMD_EXIT))) { should_continue = false; } if (should_continue) { if (!res) { cleanup(client_socket); return false; } } #ifdef PROFILING if (++numRequests == PROFILE_COUNT) { fprintf(stderr, "%d requests: %d ms scanning, %d ms work, %d ms writing\n", PROFILE_COUNT, scanTimer.total(), workTimer.total(), writeTimer.total()); fflush(stderr); scanTimer.reset(); workTimer.reset(); writeTimer.reset(); numRequests = 0; } #endif } while (should_continue); // Successful exit cleanup(client_socket); return true; } void ServiceabilityAgentDbxModule::cleanup(int client_socket) { shutdown(client_socket, 2); close(client_socket); if (_tdb_agent != NULL) { (*td_ta_delete_fn)(_tdb_agent); } } bool ServiceabilityAgentDbxModule::handleAddressSize(char* data) { int data_model; ps_err_e result = ps_pdmodel((ps_prochandle*) ps_get_prochandle2(1), &data_model); if (result != PS_OK) { myComm.writeString("0"); myComm.flush(); return false; } int val; switch (data_model) { case PR_MODEL_ILP32: val = 32; break; case PR_MODEL_LP64: val = 64; break; default: val = 0; break; } if (!myComm.writeInt(val)) { return false; } if (!myComm.writeEOL()) { return false; } return myComm.flush(); } bool ServiceabilityAgentDbxModule::handlePeekFailFast(char* data) { unsigned int val; if (!scanUnsignedInt(&data, &val)) { return false; } peek_fail_fast = (val ? true : false); return true; } bool ServiceabilityAgentDbxModule::handlePeek(char* data) { // Scan hex address, return false if failed psaddr_t addr; #ifdef PROFILING scanTimer.start(); #endif /* PROFILING */ if (!scanAddress(&data, &addr)) { return false; } unsigned int num; if (!scanUnsignedInt(&data, &num)) { return false; } if (num == 0) { #ifdef PROFILING writeTimer.start(); #endif /* PROFILING */ myComm.writeBinChar('B'); myComm.writeBinChar(1); myComm.writeBinUnsignedInt(0); myComm.writeBinChar(0); #ifdef PROFILING writeTimer.stop(); #endif /* PROFILING */ return true; } #ifdef PROFILING scanTimer.stop(); workTimer.start(); #endif /* PROFILING */ char* buf = new char[num]; ps_prochandle* cur_proc = (ps_prochandle*) ps_get_prochandle2(1); ps_err_e result = ps_pread(cur_proc, addr, buf, num); if (result == PS_OK) { // Fast case; entire read succeeded. #ifdef PROFILING workTimer.stop(); writeTimer.start(); #endif /* PROFILING */ myComm.writeBinChar('B'); myComm.writeBinChar(1); myComm.writeBinUnsignedInt(num); myComm.writeBinChar(1); myComm.writeBinBuf(buf, num); #ifdef PROFILING writeTimer.stop(); #endif /* PROFILING */ } else { #ifdef PROFILING workTimer.stop(); #endif /* PROFILING */ if (peek_fail_fast) { #ifdef PROFILING writeTimer.start(); #endif /* PROFILING */ // Fail fast myComm.writeBinChar('B'); myComm.writeBinChar(1); myComm.writeBinUnsignedInt(num); myComm.writeBinChar(0); #ifdef PROFILING writeTimer.stop(); #endif /* PROFILING */ } else { // Slow case: try to read one byte at a time // FIXME: need better way of handling this, a la VirtualQuery unsigned int strideLen = 0; int bufIdx = 0; bool lastByteMapped = (ps_pread(cur_proc, addr, buf, 1) == PS_OK ? true : false); #ifdef PROFILING writeTimer.start(); #endif /* PROFILING */ myComm.writeBinChar('B'); myComm.writeBinChar(1); #ifdef PROFILING writeTimer.stop(); #endif /* PROFILING */ for (int i = 0; i < num; ++i, ++addr) { #ifdef PROFILING workTimer.start(); #endif /* PROFILING */ result = ps_pread(cur_proc, addr, &buf[bufIdx], 1); #ifdef PROFILING workTimer.stop(); #endif /* PROFILING */ bool tmpMapped = (result == PS_OK ? true : false); #ifdef PROFILING writeTimer.start(); #endif /* PROFILING */ if (tmpMapped != lastByteMapped) { // State change. Write the length of the last stride. myComm.writeBinUnsignedInt(strideLen); if (lastByteMapped) { // Stop gathering data. Write the data of the last stride. myComm.writeBinChar(1); myComm.writeBinBuf(buf, strideLen); bufIdx = 0; } else { // Start gathering data to write. myComm.writeBinChar(0); } strideLen = 0; lastByteMapped = tmpMapped; } #ifdef PROFILING writeTimer.stop(); #endif /* PROFILING */ if (lastByteMapped) { ++bufIdx; } ++strideLen; } // Write last stride (must be at least one byte long by definition) #ifdef PROFILING writeTimer.start(); #endif /* PROFILING */ myComm.writeBinUnsignedInt(strideLen); if (lastByteMapped) { myComm.writeBinChar(1); myComm.writeBinBuf(buf, strideLen); } else { myComm.writeBinChar(0); } #ifdef PROFILING writeTimer.stop(); #endif /* PROFILING */ } } delete[] buf; myComm.flush(); return true; } bool ServiceabilityAgentDbxModule::handlePoke(char* data) { // FIXME: not yet implemented NEEDS_CLEANUP; bool res = myComm.writeBoolAsInt(false); myComm.flush(); return res; } bool ServiceabilityAgentDbxModule::handleMapped(char* data) { // Scan address psaddr_t addr; if (!scanAddress(&data, &addr)) { return false; } unsigned int num; if (!scanUnsignedInt(&data, &num)) { return false; } unsigned char val; ps_prochandle* cur_proc = (ps_prochandle*) ps_get_prochandle2(1); char* buf = new char[num]; if (ps_pread(cur_proc, addr, buf, num) == PS_OK) { myComm.writeBoolAsInt(true); } else { myComm.writeBoolAsInt(false); } delete[] buf; myComm.writeEOL(); myComm.flush(); return true; } extern "C" int loadobj_iterator(const rd_loadobj_t* loadobj, void *) { if (loadobj != NULL) { fprintf(stderr, "loadobj_iterator: visited loadobj \"%p\"\n", (void*) loadobj->rl_nameaddr); return 1; } fprintf(stderr, "loadobj_iterator: NULL loadobj\n"); return 0; } bool ServiceabilityAgentDbxModule::handleLookup(char* data) { // Debugging: iterate over loadobjs /* rd_agent_t* rld_agent = rd_new((ps_prochandle*) ps_get_prochandle2(1)); rd_loadobj_iter(rld_agent, &loadobj_iterator, NULL); rd_delete(rld_agent); */ #ifdef PROFILING scanTimer.start(); #endif /* PROFILING */ char* object_name = scanSymbol(&data); if (object_name == NULL) { return false; } char* symbol_name = scanSymbol(&data); if (symbol_name == NULL) { delete[] object_name; return false; } #ifdef PROFILING scanTimer.stop(); workTimer.start(); #endif /* PROFILING */ ps_sym_t sym; // FIXME: check return values from write routines ps_prochandle* process = (ps_prochandle*) ps_get_prochandle2(1); ps_err_e lookup_res = ps_pglobal_sym(process, object_name, symbol_name, &sym); #ifdef PROFILING workTimer.stop(); writeTimer.start(); #endif /* PROFILING */ delete[] object_name; delete[] symbol_name; if (lookup_res != PS_OK) { // This is too noisy // debug_only(fprintf(stderr, "ServiceabilityAgentDbxModule::handleLookup: error %d\n", lookup_res)); myComm.writeString("0x0"); } else { myComm.writeAddress((void *)sym.st_value); } myComm.writeEOL(); myComm.flush(); #ifdef PROFILING writeTimer.stop(); #endif /* PROFILING */ return true; } bool ServiceabilityAgentDbxModule::handleThrGRegs(char* data) { #ifdef PROFILING scanTimer.start(); #endif /* PROFILING */ unsigned int num; // Get the thread ID if (!scanUnsignedInt(&data, &num)) { return false; } #ifdef PROFILING scanTimer.stop(); workTimer.start(); #endif /* PROFILING */ // Map tid to thread handle td_thrhandle_t thread_handle; if ((*td_ta_map_id2thr_fn)(_tdb_agent, num, &thread_handle) != TD_OK) { // fprintf(stderr, "Error mapping thread ID %d to thread handle\n", num); return false; } // Fetch register set prgregset_t reg_set; memset(reg_set, 0, sizeof(reg_set)); td_err_e result = (*td_thr_getgregs_fn)(&thread_handle, reg_set); if ((result != TD_OK) && (result != TD_PARTIALREG)) { // fprintf(stderr, "Error fetching registers for thread handle %d: error = %d\n", num, result); return false; } #ifdef PROFILING workTimer.stop(); writeTimer.start(); #endif /* PROFILING */ #if (defined(__sparc) || defined(__i386)) myComm.writeInt(NPRGREG); myComm.writeSpace(); for (int i = 0; i < NPRGREG; i++) { myComm.writeAddress((void *)reg_set[i]); if (i == NPRGREG - 1) { myComm.writeEOL(); } else { myComm.writeSpace(); } } #else #error Please port ServiceabilityAgentDbxModule::handleThrGRegs to your current platform #endif myComm.flush(); #ifdef PROFILING writeTimer.stop(); #endif /* PROFILING */ return true; } // // Input routines // bool ServiceabilityAgentDbxModule::scanAddress(char** data, psaddr_t* addr) { *addr = 0; // Skip whitespace while ((**data != 0) && (isspace(**data))) { ++*data; } if (**data == 0) { return false; } if (strncmp(*data, "0x", 2) != 0) { return false; } *data += 2; while ((**data != 0) && (!isspace(**data))) { int val; bool res = charToNibble(**data, &val); if (!res) { return false; } *addr <<= 4; *addr |= val; ++*data; } return true; } bool ServiceabilityAgentDbxModule::scanUnsignedInt(char** data, unsigned int* num) { *num = 0; // Skip whitespace while ((**data != 0) && (isspace(**data))) { ++*data; } if (**data == 0) { return false; } while ((**data != 0) && (!isspace(**data))) { char cur = **data; if ((cur < '0') || (cur > '9')) { return false; } *num *= 10; *num += cur - '0'; ++*data; } return true; } char* ServiceabilityAgentDbxModule::scanSymbol(char** data) { // Skip whitespace while ((**data != 0) && (isspace(**data))) { ++*data; } if (**data == 0) { return NULL; } // First count length int len = 1; // Null terminator char* tmpData = *data; while ((*tmpData != 0) && (!isspace(*tmpData))) { ++tmpData; ++len; } char* buf = new char[len]; strncpy(buf, *data, len - 1); buf[len - 1] = 0; *data += len - 1; return buf; } bool ServiceabilityAgentDbxModule::charToNibble(char ascii, int* value) { if (ascii >= '0' && ascii <= '9') { *value = ascii - '0'; return true; } else if (ascii >= 'A' && ascii <= 'F') { *value = 10 + ascii - 'A'; return true; } else if (ascii >= 'a' && ascii <= 'f') { *value = 10 + ascii - 'a'; return true; } return false; } char* ServiceabilityAgentDbxModule::readCStringFromProcess(psaddr_t addr) { char c; int num = 0; ps_prochandle* cur_proc = (ps_prochandle*) ps_get_prochandle2(1); // Search for null terminator do { if (ps_pread(cur_proc, addr + num, &c, 1) != PS_OK) { return NULL; } ++num; } while (c != 0); // Allocate string char* res = new char[num]; if (ps_pread(cur_proc, addr, res, num) != PS_OK) { delete[] res; return NULL; } return res; } //-------------------------------------------------------------------------------- // Class Timer // Timer::Timer() { reset(); } Timer::~Timer() { } void Timer::start() { gettimeofday(&startTime, NULL); } void Timer::stop() { struct timeval endTime; gettimeofday(&endTime, NULL); totalMicroseconds += timevalDiff(&startTime, &endTime); ++counter; } long Timer::total() { return (totalMicroseconds / 1000); } long Timer::average() { return (long) ((double) total() / (double) counter); } void Timer::reset() { totalMicroseconds = 0; counter = 0; } long long Timer::timevalDiff(struct timeval* start, struct timeval* end) { long long secs = end->tv_sec - start->tv_sec; secs *= 1000000; long long usecs = end->tv_usec - start->tv_usec; return (secs + usecs); }