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//{{{ Banner //============================================================================ // // trace.cxx // // Host side implementation of the infrastructure trace facilities. // //============================================================================ //####COPYRIGHTBEGIN#### // // ---------------------------------------------------------------------------- // Copyright (C) 2002 Bart Veer // Copyright (C) 1998, 1999, 2000, 2001 Red Hat, Inc. // // This file is part of the eCos host tools. // // This program is free software; you can redistribute it and/or modify it // under the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 of the License, or (at your option) // any later version. // // This program 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 for // more details. // // You should have received a copy of the GNU General Public License along with // this program; if not, write to the Free Software Foundation, Inc., // 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. // // ---------------------------------------------------------------------------- // //####COPYRIGHTEND#### //============================================================================ //#####DESCRIPTIONBEGIN#### // // Author(s): bartv // Contact(s): bartv // Date: 1998/12/07 // Version: 0.01 // Purpose: To provide a host-side implementation of the eCos tracing // facilities. // //####DESCRIPTIONEND#### //============================================================================ //}}} //{{{ #include's // Make sure that the host-side extensions get prototyped // as well. Note that the tracing code needs to interact // with the assertion facilities to set up an appropriate // callback. #define CYG_DECLARE_HOST_ASSERTION_SUPPORT #include "pkgconf/infra.h" #include "cyg/infra/cyg_type.h" #include "cyg/infra/cyg_ass.h" // Without this #define the tracing enums and prototypes are // not visible. #define CYGDBG_USE_TRACING #include "cyg/infra/cyg_trac.h" // The standard C++ string class is used extensively #include <string> // Add a few C headers #include <cctype> #include <cstring> #include <cstdio> //}}} //{{{ Description // ------------------------------------------------------------------------- // The tracing macros end up calling one of the following routines: // // void cyg_tracenomsg(cyg_uint32 what, const char* fn, const char* file, cyg_uint32 line) // void cyg_tracemsg( ..., const char* msg) // void cyg_tracemsg2( ..., CYG_ADDRWORD arg0, CYG_ADDRWORD arg1 ) // void cyg_tracemsg4( ..., CYG_ADDRWORD arg0, CYG_ADDRWORD arg1, ... ) // void cyg_tracemsg6( ..., CYG_ADDRWORD arg0, CYG_ADDRWORD arg1, ... ) // void cyg_tracemsg8( ..., CYG_ADDRWORD arg0, CYG_ADDRWORD arg1, ... ) // // For the 2/4/6/8 variants the msg argument is essentially a printf() // style format string. However the intention is that the implementation // of the trace code can delay doing the formatting until the trace // information is actually needed (with obvious consequences for // generated strings). Such an implementation would significantly // reduce the overheads associated with tracing, and is what is implemented // here. // // CYG_ADDRWORD is likely to be either "int" or the platform-specific // 64 bit data type: it should be big enough to hold either a pointer // or any normal integral type. This causes problems on machines which // have e.g. 32 bit int and 64 bit long: any 32 bit quantities will // have been converted to 64 bit quantities in the calling code, and // it is no longer possible to just pass the format string to sprintf(). // Instead what amounts to a re-implementation of sprintf() is needed // here. // // The basic implementation of this trace code is as follows: // // 1) a static array of data structures to hold the trace data. The // size can be configured. There is a current index into this // array. // // 2) the various trace functions simply update this array and the // counter. // // 3) all of the trace functions also check a static to see whether // or not it is necessary to install a trace handler. This cannot // be done by means of a static object due to constructor priority // ordering problems. // // 4) the callback function does all the hardware of the formatting // etc. //}}} //{{{ Types and statics // ---------------------------------------------------------------------------- // A data structure rather than a class is used to hold the trace data. // This guarantees that the array gets put in the bss section and is properly // zeroed. A "valid" field in the structure can be checked when dumping the // array. typedef struct trace_entry { bool valid; cyg_uint32 what; cyg_uint32 line; const char* fn; const char* file; const char* msg; CYG_ADDRWORD data[8]; } trace_entry; #ifndef CYGNUM_INFRA_TRACE_VECTOR_SIZE # define CYGNUM_INFRA_TRACE_VECTOR_SIZE 2048 #endif static trace_entry tracevec[CYGNUM_INFRA_TRACE_VECTOR_SIZE]; static volatile int trace_index = 0; // Forward declaration of the callback function, for convenience. static void trace_callback(void (*)(const char*)); // Has the callback been installed yet? static bool callback_installed = false; //}}} //{{{ The trace functions themselves // ---------------------------------------------------------------------------- // The functions that get called by the trace macros. Typically these work // as follows: // // 1) read and increment the trace index. This makes tracing marginally usable // in multi-threaded systems. // // 2) invalidate the entry that is about to be updated. Again this helps a bit // with multi-threaded systems. // // 3) fill in all the fields as per the command-line arguments, zeroing // unused fields. // // 4) set the valid flag to true, which means the contents can now be output. // // This is by no means sufficient to guarantee that a call to dump the trace // vector in some other thread can work safely, but it may help a little bit. extern "C" void cyg_tracenomsg(const char* fn, const char* file, cyg_uint32 line) { int i = trace_index; tracevec[i].valid = false; trace_index = (trace_index + 1) % CYGNUM_INFRA_TRACE_VECTOR_SIZE; tracevec[i].what = cyg_trace_trace; tracevec[i].fn = fn; tracevec[i].file = file; tracevec[i].line = line; tracevec[i].msg = 0; tracevec[i].data[0] = 0; tracevec[i].data[1] = 0; tracevec[i].data[2] = 0; tracevec[i].data[3] = 0; tracevec[i].data[4] = 0; tracevec[i].data[5] = 0; tracevec[i].data[6] = 0; tracevec[i].data[7] = 0; tracevec[i].valid = true; if (!callback_installed) { cyg_assert_install_failure_callback("Trace", &trace_callback); callback_installed = true; } } extern "C" void cyg_tracemsg(cyg_uint32 what, const char* fn, const char* file, cyg_uint32 line, const char* msg) { int i = trace_index; tracevec[i].valid = false; trace_index = (trace_index + 1) % CYGNUM_INFRA_TRACE_VECTOR_SIZE; tracevec[i].what = what; tracevec[i].fn = fn; tracevec[i].file = file; tracevec[i].line = line; tracevec[i].msg = msg; tracevec[i].data[0] = 0; tracevec[i].data[1] = 0; tracevec[i].data[2] = 0; tracevec[i].data[3] = 0; tracevec[i].data[4] = 0; tracevec[i].data[5] = 0; tracevec[i].data[6] = 0; tracevec[i].data[7] = 0; tracevec[i].valid = true; if (!callback_installed) { cyg_assert_install_failure_callback("Trace", &trace_callback); callback_installed = true; } } extern "C" void cyg_tracemsg2(cyg_uint32 what, const char* fn, const char* file, cyg_uint32 line, const char *msg, CYG_ADDRWORD arg0, CYG_ADDRWORD arg1) { int i = trace_index; tracevec[i].valid = false; trace_index = (trace_index + 1) % CYGNUM_INFRA_TRACE_VECTOR_SIZE; tracevec[i].what = what; tracevec[i].fn = fn; tracevec[i].file = file; tracevec[i].line = line; tracevec[i].msg = msg; tracevec[i].data[0] = arg0; tracevec[i].data[1] = arg1; tracevec[i].data[2] = 0; tracevec[i].data[3] = 0; tracevec[i].data[4] = 0; tracevec[i].data[5] = 0; tracevec[i].data[6] = 0; tracevec[i].data[7] = 0; tracevec[i].valid = true; if (!callback_installed) { cyg_assert_install_failure_callback("Trace", &trace_callback); callback_installed = true; } } extern "C" void cyg_tracemsg4(cyg_uint32 what, const char *fn, const char* file, cyg_uint32 line, const char *msg, CYG_ADDRWORD arg0, CYG_ADDRWORD arg1, CYG_ADDRWORD arg2, CYG_ADDRWORD arg3) { int i = trace_index; tracevec[i].valid = false; trace_index = (trace_index + 1) % CYGNUM_INFRA_TRACE_VECTOR_SIZE; tracevec[i].what = what; tracevec[i].fn = fn; tracevec[i].file = file; tracevec[i].line = line; tracevec[i].msg = msg; tracevec[i].data[0] = arg0; tracevec[i].data[1] = arg1; tracevec[i].data[2] = arg2; tracevec[i].data[3] = arg3; tracevec[i].data[4] = 0; tracevec[i].data[5] = 0; tracevec[i].data[6] = 0; tracevec[i].data[7] = 0; tracevec[i].valid = true; if (!callback_installed) { cyg_assert_install_failure_callback("Trace", &trace_callback); callback_installed = true; } } extern "C" void cyg_tracemsg6(cyg_uint32 what, const char *fn, const char* file, cyg_uint32 line, const char *msg, CYG_ADDRWORD arg0, CYG_ADDRWORD arg1, CYG_ADDRWORD arg2, CYG_ADDRWORD arg3, CYG_ADDRWORD arg4, CYG_ADDRWORD arg5) { int i = trace_index; tracevec[i].valid = false; trace_index = (trace_index + 1) % CYGNUM_INFRA_TRACE_VECTOR_SIZE; tracevec[i].what = what; tracevec[i].fn = fn; tracevec[i].file = file; tracevec[i].line = line; tracevec[i].msg = msg; tracevec[i].data[0] = arg0; tracevec[i].data[1] = arg1; tracevec[i].data[2] = arg2; tracevec[i].data[3] = arg3; tracevec[i].data[4] = arg4; tracevec[i].data[5] = arg5; tracevec[i].data[6] = 0; tracevec[i].data[7] = 0; tracevec[i].valid = true; if (!callback_installed) { cyg_assert_install_failure_callback("Trace", &trace_callback); callback_installed = true; } } extern "C" void cyg_tracemsg8(cyg_uint32 what, const char* fn, const char* file, cyg_uint32 line, const char *msg, CYG_ADDRWORD arg0, CYG_ADDRWORD arg1, CYG_ADDRWORD arg2, CYG_ADDRWORD arg3, CYG_ADDRWORD arg4, CYG_ADDRWORD arg5, CYG_ADDRWORD arg6, CYG_ADDRWORD arg7) { int i = trace_index; tracevec[i].valid = false; trace_index = (trace_index + 1) % CYGNUM_INFRA_TRACE_VECTOR_SIZE; tracevec[i].what = what; tracevec[i].fn = fn; tracevec[i].file = file; tracevec[i].line = line; tracevec[i].msg = msg; tracevec[i].data[0] = arg0; tracevec[i].data[1] = arg1; tracevec[i].data[2] = arg2; tracevec[i].data[3] = arg3; tracevec[i].data[4] = arg4; tracevec[i].data[5] = arg5; tracevec[i].data[6] = arg6; tracevec[i].data[7] = arg7; tracevec[i].valid = true; if (!callback_installed) { cyg_assert_install_failure_callback("Trace", &trace_callback); callback_installed = true; } } //}}} //{{{ Output callback // ---------------------------------------------------------------------------- // Dumping the output. The assertion code will invoke a single callback // function, cyg_trace_dummy::trace_callback(), with a function pointer // that can be used for the actual output. // // The trace_callback() function loops through the various entries in the // vector, ignoring invalid ones, and invoking output_entry() for the // valid ones. // // There are a number of utility routines: // // trim_file() is used to take a full pathname and return just the // final part of it as a C++ string. There is an upper bound on the // length of this string. // // trim_linenum() formats the linenumber sensibly. // // trim_function() is used to parse a __PRETTY_FUNCTION__ value // and produce something more manageable. // // parse_msg() is used to construct the full trace message. // Because of possible 32/64 bit confusion it is not possible // to just use sprintf() for this. static std::string trim_file(const char* file) { // If the output is to look reasonable then the result should be a // fixed length. 20 characters is reasonable for now. const int max_filename_len = 20; if (0 == file) { return std::string(max_filename_len, ' '); } // Move to the end of the string, and then back again until // a directory separator is found. Given the number of levels // in a typical eCos directory hierarchy it is probably not // worthwhile outputting any of that information. const char * pEnd = file + strlen(file); while ((pEnd > file) && ('/' != *pEnd) && ('\\' != *pEnd)) { pEnd--; } if (pEnd != file) pEnd++; std::string result = ""; int i = 0; for ( ;(*pEnd != '\0') && (i < max_filename_len); i++, pEnd++) { result += *pEnd; } for ( ; i < max_filename_len; i++) { result += ' '; } return result; } // The linenumber output should be up to four digits, right-padded // with spaces. sprintf() will do the trick nicely. static std::string trim_linenum(cyg_uint32 line) { char buf[32]; sprintf(buf, "%-4d", (int) line); return buf; } // Extract a function name. On the target side function names // are usually obtained via __PRETTY_FUNCTION__, and the resulting // output is a bit on the large side: return value, arguments, etc // are all included. On the host side the function name is normally // supplied explicitly and should not be trimmed at all. // // Padding is not appropriate since the function name is likely // to be followed immediately by the argument list. No maximum // length is imposed - arguably that is a bad idea. static std::string trim_function(const char* fn) { if (0 == fn) { return "<unknown>"; } #if 1 return fn; #else // This implements the target-side behaviour. // // First locate the opening bracket. The function name can // be identified by walking backwards from that. const char *s; for (s = fn; ('\0' != *s) && ('(' != *s); s++); for ( ; (s > fn) && (*s != ' '); s--); if ( s > fn) s++; std::string result = ""; while ( ('\0' != *s) && ('(' != *s) ) result += *s++; return result; #endif } // The trace format string contained a %s. It is necessary to check // whether the argument is still valid, and return a suitable // approximation to the actual data. static std::string trim_string(const char * arg) { const int max_string_len = 20; std::string result = ""; if (0 == arg) { return result; } int i; for ( i = 0; (i < max_string_len) && ('\0' != *arg) && isprint(*arg); i++, arg++) { result += *arg; } return result; } // ---------------------------------------------------------------------------- // Parse a printf() style format string and do the appropriate expansions. // Because of possible confusion between 32 and 64 bit integers it is not // possible to use sprintf() itself. // // It is assumed that the format string is valid, as are most of the // arguments. The possible exception is %s arguments where a little bit of // checking happens first. static std::string parse_msg(const char* msg, trace_entry& entry) { if (0 == msg) { return ""; } // Keep track of the number of arguments in the trace_entry // that have been processed. int args_index = 0; // A utility buffer for sprintf(), e.g. for integer-> string conversions. char util_buf[64]; std::string result = ""; for ( ; '\0' != *msg; msg++) { if ('%' != *msg) { result += *msg; continue; } // We have a format string. Extract all of it. std::string format = "%"; msg++; // The first part of the format string may be one or more flags. while ( ('-' == *msg) || ('+' == *msg) || (' ' == *msg) || ('#' == *msg) || ('0' == *msg) ) { format += *msg++; } // Next comes the width. If this is an asterix it is necessary to // substitute in an actual argument. if ('*' == *msg) { int width = (args_index < 8) ? (int) entry.data[args_index++] : 0; sprintf(util_buf, "%d", width); format += util_buf; msg++; } else { // Otherwise the width should be one or more digits while( isdigit(*msg) ) { format += *msg++; } } // Look for a precision, again coping with an asterix. if ('.' == *msg) { format += *msg++; if ('*' == *msg) { int precision = (args_index < 8) ? (int) entry.data[args_index++] : 0; sprintf(util_buf, "%d", precision); format += util_buf; msg++; } else { // The precision should be one or more digits, with an optional - if ('-' == *msg) { format += *msg++; } while (isdigit(*msg)) { format += *msg++; } } } // Now look for h,l and L. These have to be remembered. bool short_version = false; bool long_version = false; if ('h' == *msg) { format += *msg++; short_version = true; } else if (('l' == *msg) || ('L' == *msg)) { format += *msg++; long_version = true; } // The end of the format string has been reached. int format_ch = *msg; format += *msg; // If we have already formatted too many arguments, there is no point // in trying to do the actual formatting. if ( 8 <= args_index ) { continue; } CYG_ADDRWORD val = entry.data[args_index++]; switch( format_ch ) { case '%' : result += '%'; break; case 'd' : case 'i' : case 'o' : case 'u' : case 'x' : case 'X' : // "format" contains the appropriate format string. // Invoke sprintf() using util_buf, doing the // appropriate cast, and then append the output // of util_buf. // // This is not totally robust. If a ridiculous // precision has been specified then util_buf may // overflow. if (long_version) { sprintf(util_buf, format.c_str(), (long) val); } else { // The implicit cast rules mean that shorts do not // require any special attention. sprintf(util_buf, format.c_str(), (int) val); } result += util_buf; break; case 'c' : sprintf(util_buf, format.c_str(), (int) val); result += util_buf; break; case 'p' : sprintf(util_buf, format.c_str(), (void *) val); result += util_buf; break; case 's' : { std::string data = trim_string((char *) val); sprintf(util_buf, format.c_str(), data.c_str()); result += util_buf; break; } default : // Any attempt to do floating point conversions would be // rather tricky given the casts that have been applied. // There is no point in doing anything for unrecognised // sequences. break; } } return result; } // ---------------------------------------------------------------------------- static void output_entry(void (*pOutputFn)(const char*), trace_entry& entry) { std::string output = trim_file(entry.file) + " " + trim_linenum(entry.line) + " " + trim_function(entry.fn) + " "; if (0 != entry.msg) { switch( entry.what) { case cyg_trace_trace : output += " '"; break; case cyg_trace_enter : output += "{{"; break; case cyg_trace_args : output += "(("; break; case cyg_trace_return : output += "}}"; break; default : output += " ?"; } output += parse_msg(entry.msg, entry); switch( entry.what) { case cyg_trace_trace : output += "' "; break; case cyg_trace_enter : break; case cyg_trace_args : output += "))"; break; case cyg_trace_return : break; default : output += "? "; } } output += "\n"; (*pOutputFn)(output.c_str()); } static void trace_callback( void (*pOutputFn)(const char*)) { if ((trace_index < 0) || (trace_index >= CYGNUM_INFRA_TRACE_VECTOR_SIZE)) return; // Start at the last entry and work back down to zero, skipping // invalid ones. Then go to the top and work back to the current index. int i; for (i = trace_index - 1; i >= 0; i--) { if (tracevec[i].valid) { output_entry(pOutputFn, tracevec[i]); } } for (i = (CYGNUM_INFRA_TRACE_VECTOR_SIZE - 1); i >= trace_index; i--) { if (tracevec[i].valid) { output_entry(pOutputFn, tracevec[i]); } } } //}}}
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