/** \file common.c Various functions, mostly string utilities, that are used by most parts of fish. */ #include "config.h" #include #ifdef HAVE_STROPTS_H #include #endif #ifdef HAVE_SIGINFO_H #include #endif #include #include #include #include #include #include #include #ifdef HAVE_SYS_TERMIOS_H #include #endif #ifdef HAVE_SYS_IOCTL_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #ifdef HAVE_EXECINFO_H #include #endif #if HAVE_NCURSES_H #include #else #include #endif #if HAVE_TERMIO_H #include #endif #if HAVE_TERM_H #include #elif HAVE_NCURSES_TERM_H #include #endif #include "fallback.h" #include "util.h" #include "wutil.h" #include "common.h" #include "expand.h" #include "proc.h" #include "wildcard.h" #include "parser.h" #include "complete.h" #include "util.cpp" #include "fallback.cpp" struct termios shell_modes; // Note we foolishly assume that pthread_t is just a primitive. But it might be a struct. static pthread_t main_thread_id = 0; static bool thread_assertions_configured_for_testing = false; wchar_t ellipsis_char; char *profile=0; const wchar_t *program_name; int debug_level=1; /** This struct should be continually updated by signals as the term resizes, and as such always contain the correct current size. */ static struct winsize termsize; void show_stackframe() { void *trace[32]; char **messages = (char **)NULL; int i, trace_size = 0; trace_size = backtrace(trace, 32); messages = backtrace_symbols(trace, trace_size); if( messages ) { debug( 0, L"Backtrace:" ); for( i=0; i &list ) { wcstring_list_t strings; strings.reserve(list.size()); for (std::vector::const_iterator iter = list.begin(); iter != list.end(); ++iter) { strings.push_back(iter->completion); } return strings; } int fgetws2( wchar_t **b, int *len, FILE *f ) { int i=0; wint_t c; wchar_t *buff = *b; while( 1 ) { /* Reallocate the buffer if necessary */ if( i+1 >= *len ) { int new_len = maxi( 128, (*len)*2); buff = (wchar_t *)realloc( buff, sizeof(wchar_t)*new_len ); if( buff == 0 ) { DIE_MEM(); } else { *len = new_len; *b = buff; } } errno=0; c = getwc( f ); if( errno == EILSEQ ) { continue; } //fwprintf( stderr, L"b\n" ); switch( c ) { /* End of line */ case WEOF: case L'\n': case L'\0': buff[i]=L'\0'; return i; /* Ignore carriage returns */ case L'\r': break; default: buff[i++]=c; break; } } } static bool string_sort_predicate(const wcstring& d1, const wcstring& d2) { return wcsfilecmp(d1.c_str(), d2.c_str()) < 0; } void sort_strings( std::vector &strings) { std::sort(strings.begin(), strings.end(), string_sort_predicate); } void sort_completions( std::vector &completions) { std::sort(completions.begin(), completions.end()); } wchar_t *str2wcs( const char *in ) { wchar_t *out; size_t len = strlen(in); out = (wchar_t *)malloc( sizeof(wchar_t)*(len+1) ); if( !out ) { DIE_MEM(); } return str2wcs_internal( in, out ); } wcstring str2wcstring( const char *in ) { wchar_t *tmp = str2wcs(in); wcstring result = tmp; free(tmp); return result; } wcstring str2wcstring( const std::string &in ) { wchar_t *tmp = str2wcs(in.c_str()); wcstring result = tmp; free(tmp); return result; } wchar_t *str2wcs_internal( const char *in, wchar_t *out ) { size_t res=0; int in_pos=0; int out_pos = 0; mbstate_t state; size_t len; CHECK( in, 0 ); CHECK( out, 0 ); len = strlen(in); memset( &state, 0, sizeof(state) ); while( in[in_pos] ) { res = mbrtowc( &out[out_pos], &in[in_pos], len-in_pos, &state ); if( ( ( out[out_pos] >= ENCODE_DIRECT_BASE) && ( out[out_pos] < ENCODE_DIRECT_BASE+256)) || ( out[out_pos] == INTERNAL_SEPARATOR ) ) { out[out_pos] = ENCODE_DIRECT_BASE + (unsigned char)in[in_pos]; in_pos++; memset( &state, 0, sizeof(state) ); out_pos++; } else { switch( res ) { case (size_t)(-2): case (size_t)(-1): { out[out_pos] = ENCODE_DIRECT_BASE + (unsigned char)in[in_pos]; in_pos++; memset( &state, 0, sizeof(state) ); break; } case 0: { return out; } default: { in_pos += res; break; } } out_pos++; } } out[out_pos] = 0; return out; } char *wcs2str( const wchar_t *in ) { if (! in) return NULL; char *out; size_t desired_size = MAX_UTF8_BYTES*wcslen(in)+1; char local_buff[512]; if (desired_size <= sizeof local_buff / sizeof *local_buff) { // convert into local buff, then use strdup() so we don't waste malloc'd space char *result = wcs2str_internal(in, local_buff); if (result) { // It converted into the local buffer, so copy it result = strdup(result); if (! result) { DIE_MEM(); } } return result; } else { // here we fall into the bad case of allocating a buffer probably much larger than necessary out = (char *)malloc( MAX_UTF8_BYTES*wcslen(in)+1 ); if (!out) { DIE_MEM(); } return wcs2str_internal( in, out ); } return wcs2str_internal( in, out ); } std::string wcs2string(const wcstring &input) { char *tmp = wcs2str(input.c_str()); std::string result = tmp; free(tmp); return result; } char *wcs2str_internal( const wchar_t *in, char *out ) { size_t res=0; int in_pos=0; int out_pos = 0; mbstate_t state; CHECK( in, 0 ); CHECK( out, 0 ); memset( &state, 0, sizeof(state) ); while( in[in_pos] ) { if( in[in_pos] == INTERNAL_SEPARATOR ) { } else if( ( in[in_pos] >= ENCODE_DIRECT_BASE) && ( in[in_pos] < ENCODE_DIRECT_BASE+256) ) { out[out_pos++] = in[in_pos]- ENCODE_DIRECT_BASE; } else { res = wcrtomb( &out[out_pos], in[in_pos], &state ); if( res == (size_t)(-1) ) { debug( 1, L"Wide character %d has no narrow representation", in[in_pos] ); memset( &state, 0, sizeof(state) ); } else { out_pos += res; } } in_pos++; } out[out_pos] = 0; return out; } char **wcsv2strv( const wchar_t * const *in ) { int count =0; int i; while( in[count] != 0 ) count++; char **res = (char **)malloc( sizeof( char *)*(count+1)); if( res == 0 ) { DIE_MEM(); } for( i=0; i= max_size) { buff[0] = '\0'; break; } buff = (wchar_t *)realloc( (buff == static_buff ? NULL : buff), size); if (buff == NULL) { DIE_MEM(); } } /* Try printing */ va_list va; va_copy( va, va_orig ); status = vswprintf(buff, size / sizeof(wchar_t), format, va); va_end(va); } wcstring result = wcstring(buff); if (buff != static_buff) free(buff); errno = saved_err; return result; } void append_format(wcstring &str, const wchar_t *format, ...) { /* Preserve errno across this call since it likes to stomp on it */ int err = errno; va_list va; va_start( va, format ); str.append(vformat_string(format, va)); va_end( va ); errno = err; } wchar_t *wcsvarname( const wchar_t *str ) { while( *str ) { if( (!iswalnum(*str)) && (*str != L'_' ) ) { return (wchar_t *)str; } str++; } return 0; } const wchar_t *wcsfuncname( const wchar_t *str ) { return wcschr( str, L'/' ); } int wcsvarchr( wchar_t chr ) { return iswalnum(chr) || chr == L'_'; } /** The glibc version of wcswidth seems to hang on some strings. fish uses this replacement. */ int my_wcswidth( const wchar_t *c ) { int res=0; while( *c ) { int w = wcwidth( *c++ ); if( w < 0 ) w = 1; if( w > 2 ) w=1; res += w; } return res; } wchar_t *quote_end( const wchar_t *pos ) { wchar_t c = *pos; while( 1 ) { pos++; if( !*pos ) return 0; if( *pos == L'\\') { pos++; if( !*pos ) return 0; } else { if( *pos == c ) { return (wchar_t *)pos; } } } return 0; } wcstring wsetlocale(int category, const wchar_t *locale) { char *lang = NULL; if (locale){ lang = wcs2str( locale ); } char * res = setlocale(category,lang); free( lang ); /* Use ellipsis if on known unicode system, otherwise use $ */ char *ctype = setlocale( LC_CTYPE, NULL ); ellipsis_char = (strstr( ctype, ".UTF")||strstr( ctype, ".utf") )?L'\x2026':L'$'; if( !res ) return wcstring(); else return format_string(L"%s", res); } bool contains_internal( const wchar_t *a, ... ) { const wchar_t *arg; va_list va; int res = 0; CHECK( a, 0 ); va_start( va, a ); while( (arg=va_arg(va, const wchar_t *) )!= 0 ) { if( wcscmp( a,arg) == 0 ) { res=1; break; } } va_end( va ); return res; } /* wcstring variant of contains_internal. The first parameter is a wcstring, the rest are const wchar_t* */ __sentinel bool contains_internal( const wcstring &needle, ... ) { const wchar_t *arg; va_list va; int res = 0; va_start( va, needle ); while( (arg=va_arg(va, const wchar_t *) )!= 0 ) { if( needle == arg) { res=1; break; } } va_end( va ); return res; } int read_blocked(int fd, void *buf, size_t count) { int res; sigset_t chldset, oldset; sigemptyset( &chldset ); sigaddset( &chldset, SIGCHLD ); sigprocmask(SIG_BLOCK, &chldset, &oldset); res = read( fd, buf, count ); sigprocmask( SIG_SETMASK, &oldset, 0 ); return res; } ssize_t write_loop(int fd, const char *buff, size_t count) { ssize_t out=0; size_t out_cum=0; while( 1 ) { out = write( fd, &buff[out_cum], count - out_cum ); if (out < 0) { if(errno != EAGAIN && errno != EINTR) { return -1; } } else { out_cum += (size_t)out; } if( out_cum >= count ) { break; } } return out_cum; } ssize_t read_loop(int fd, void *buff, size_t count) { ssize_t result; do { result = read(fd, buff, count); } while (result < 0 && (errno == EAGAIN || errno == EINTR)); return result; } void debug( int level, const wchar_t *msg, ... ) { va_list va; wcstring sb; int errno_old = errno; if( level > debug_level ) return; CHECK( msg, ); sb = format_string(L"%ls: ", program_name); va_start(va, msg); sb.append(vformat_string(msg, va)); va_end(va); wcstring sb2; write_screen( sb, sb2 ); fwprintf( stderr, L"%ls", sb2.c_str() ); errno = errno_old; } void debug_safe(int level, const char *msg, const char *param1, const char *param2, const char *param3, const char *param4, const char *param5, const char *param6, const char *param7, const char *param8, const char *param9, const char *param10, const char *param11, const char *param12) { const char * const params[] = {param1, param2, param3, param4, param5, param6, param7, param8, param9, param10, param11, param12}; if (! msg) return; /* Can't call printf, that may allocate memory Just call write() over and over. */ if (level > debug_level) return; int errno_old = errno; size_t param_idx = 0; const char *cursor = msg; while (*cursor != '\0') { const char *end = strchr(cursor, '%'); if (end == NULL) end = cursor + strlen(cursor); write(STDERR_FILENO, cursor, end - cursor); if (end[0] == '%' && end[1] == 's') { /* Handle a format string */ assert(param_idx < sizeof params / sizeof *params); const char *format = params[param_idx++]; if (! format) format = "(null)"; write(STDERR_FILENO, format, strlen(format)); cursor = end + 2; } else if (end[0] == '\0') { /* Must be at the end of the string */ cursor = end; } else { /* Some other format specifier, just skip it */ cursor = end + 1; } } // We always append a newline write(STDERR_FILENO, "\n", 1); errno = errno_old; } void format_long_safe(char buff[128], long val) { if (val == 0) { strcpy(buff, "0"); } else { /* Generate the string in reverse */ size_t idx = 0; bool negative = (val < 0); /* Note that we can't just negate val if it's negative, because it may be the most negative value. We do rely on round-towards-zero division though. */ while (val != 0) { long rem = val % 10; buff[idx++] = '0' + (rem < 0 ? -rem : rem); val /= 10; } if (negative) buff[idx++] = '-'; buff[idx] = 0; size_t left = 0, right = idx - 1; while (left < right) { char tmp = buff[left]; buff[left++] = buff[right]; buff[right--] = tmp; } } } void format_long_safe(wchar_t buff[128], long val) { if (val == 0) { wcscpy(buff, L"0"); } else { /* Generate the string in reverse */ size_t idx = 0; bool negative = (val < 0); while (val > 0) { long rem = val % 10; /* Here we're assuming that wide character digits are contiguous - is that a correct assumption? */ buff[idx++] = L'0' + (rem < 0 ? -rem : rem); val /= 10; } if (negative) buff[idx++] = L'-'; buff[idx] = 0; size_t left = 0, right = idx - 1; while (left < right) { wchar_t tmp = buff[left]; buff[left++] = buff[right]; buff[right--] = tmp; } } } void write_screen( const wcstring &msg, wcstring &buff ) { const wchar_t *start, *pos; int line_width = 0; int tok_width = 0; int screen_width = common_get_width(); if( screen_width ) { start = pos = msg.c_str(); while( 1 ) { int overflow = 0; tok_width=0; /* Tokenize on whitespace, and also calculate the width of the token */ while( *pos && ( !wcschr( L" \n\r\t", *pos ) ) ) { /* Check is token is wider than one line. If so we mark it as an overflow and break the token. */ if((tok_width + wcwidth(*pos)) > (screen_width-1)) { overflow = 1; break; } tok_width += wcwidth( *pos ); pos++; } /* If token is zero character long, we don't do anything */ if( pos == start ) { start = pos = pos+1; } else if( overflow ) { /* In case of overflow, we print a newline, except if we already are at position 0 */ wchar_t *token = wcsndup( start, pos-start ); if( line_width != 0 ) buff.push_back(L'\n'); buff.append(format_string(L"%ls-\n", token)); free( token ); line_width=0; } else { /* Print the token */ wchar_t *token = wcsndup( start, pos-start ); if( (line_width + (line_width!=0?1:0) + tok_width) > screen_width ) { buff.push_back(L'\n'); line_width=0; } buff.append(format_string(L"%ls%ls", line_width?L" ":L"", token )); free( token ); line_width += (line_width!=0?1:0) + tok_width; } /* Break on end of string */ if( !*pos ) { break; } start=pos; } } else { buff.append(msg); } buff.push_back(L'\n'); } /** Perform string escaping of a strinng by only quoting it. Assumes the string has already been checked for characters that can not be escaped this way. */ static wchar_t *escape_simple( const wchar_t *in ) { wchar_t *out; size_t len = wcslen(in); out = (wchar_t *)malloc( sizeof(wchar_t)*(len+3)); if( !out ) DIE_MEM(); out[0] = L'\''; wcscpy(&out[1], in ); out[len+1]=L'\''; out[len+2]=0; return out; } wchar_t *escape( const wchar_t *in_orig, int flags ) { const wchar_t *in = in_orig; int escape_all = flags & ESCAPE_ALL; int no_quoted = flags & ESCAPE_NO_QUOTED; wchar_t *out; wchar_t *pos; int need_escape=0; int need_complex_escape=0; if( !in ) { debug( 0, L"%s called with null input", __func__ ); FATAL_EXIT(); } if( !no_quoted && (wcslen( in ) == 0) ) { out = wcsdup(L"''"); if( !out ) DIE_MEM(); return out; } out = (wchar_t *)malloc( sizeof(wchar_t)*(wcslen(in)*4 + 1)); pos = out; if( !out ) DIE_MEM(); while( *in != 0 ) { if( ( *in >= ENCODE_DIRECT_BASE) && ( *in < ENCODE_DIRECT_BASE+256) ) { int val = *in - ENCODE_DIRECT_BASE; int tmp; *(pos++) = L'\\'; *(pos++) = L'X'; tmp = val/16; *pos++ = tmp > 9? L'a'+(tmp-10):L'0'+tmp; tmp = val%16; *pos++ = tmp > 9? L'a'+(tmp-10):L'0'+tmp; need_escape=need_complex_escape=1; } else { switch( *in ) { case L'\t': *(pos++) = L'\\'; *(pos++) = L't'; need_escape=need_complex_escape=1; break; case L'\n': *(pos++) = L'\\'; *(pos++) = L'n'; need_escape=need_complex_escape=1; break; case L'\b': *(pos++) = L'\\'; *(pos++) = L'b'; need_escape=need_complex_escape=1; break; case L'\r': *(pos++) = L'\\'; *(pos++) = L'r'; need_escape=need_complex_escape=1; break; case L'\x1b': *(pos++) = L'\\'; *(pos++) = L'e'; need_escape=need_complex_escape=1; break; case L'\\': case L'\'': { need_escape=need_complex_escape=1; if( escape_all ) *pos++ = L'\\'; *pos++ = *in; break; } case L'&': case L'$': case L' ': case L'#': case L'^': case L'<': case L'>': case L'(': case L')': case L'[': case L']': case L'{': case L'}': case L'?': case L'*': case L'|': case L';': case L'"': case L'%': case L'~': { need_escape=1; if( escape_all ) *pos++ = L'\\'; *pos++ = *in; break; } default: { if( *in < 32 ) { if( *in <27 && *in > 0 ) { *(pos++) = L'\\'; *(pos++) = L'c'; *(pos++) = L'a' + *in -1; need_escape=need_complex_escape=1; break; } int tmp = (*in)%16; *pos++ = L'\\'; *pos++ = L'x'; *pos++ = ((*in>15)? L'1' : L'0'); *pos++ = tmp > 9? L'a'+(tmp-10):L'0'+tmp; need_escape=need_complex_escape=1; } else { *pos++ = *in; } break; } } } in++; } *pos = 0; /* Use quoted escaping if possible, since most people find it easier to read. */ if( !no_quoted && need_escape && !need_complex_escape && escape_all ) { free( out ); out = escape_simple( in_orig ); } return out; } wcstring escape_string( const wcstring &in, int escape_all ) { wchar_t *tmp = escape(in.c_str(), escape_all); wcstring result(tmp); free(tmp); return result; } wchar_t *unescape( const wchar_t * orig, int flags ) { int mode = 0; int in_pos, out_pos, len; int c; int bracket_count=0; wchar_t prev=0; wchar_t *in; int unescape_special = flags & UNESCAPE_SPECIAL; int allow_incomplete = flags & UNESCAPE_INCOMPLETE; CHECK( orig, 0 ); len = wcslen( orig ); in = wcsdup( orig ); if( !in ) DIE_MEM(); for( in_pos=0, out_pos=0; in_pos=0)?in[out_pos]:0), out_pos++, in_pos++ ) { c = in[in_pos]; switch( mode ) { /* Mode 0 means unquoted string */ case 0: { if( c == L'\\' ) { switch( in[++in_pos] ) { /* A null character after a backslash is an error, return null */ case L'\0': { if( !allow_incomplete ) { free(in); return 0; } } /* Numeric escape sequences. No prefix means octal escape, otherwise hexadecimal. */ case L'0': case L'1': case L'2': case L'3': case L'4': case L'5': case L'6': case L'7': case L'u': case L'U': case L'x': case L'X': { int i; long long res=0; int chars=2; int base=16; int byte = 0; wchar_t max_val = ASCII_MAX; switch( in[in_pos] ) { case L'u': { chars=4; max_val = UCS2_MAX; break; } case L'U': { chars=8; max_val = WCHAR_MAX; break; } case L'x': { break; } case L'X': { byte=1; max_val = BYTE_MAX; break; } default: { base=8; chars=3; in_pos--; break; } } for( i=0; i= L'a' && in[in_pos] <= (L'a'+32) ) { in[out_pos]=in[in_pos]-L'a'+1; } else if( in[in_pos] >= L'A' && in[in_pos] <= (L'A'+32) ) { in[out_pos]=in[in_pos]-L'A'+1; } else { free(in); return 0; } break; } /* \x1b means escape */ case L'e': { in[out_pos]=L'\x1b'; break; } /* \f means form feed */ case L'f': { in[out_pos]=L'\f'; break; } /* \n means newline */ case L'n': { in[out_pos]=L'\n'; break; } /* \r means carriage return */ case L'r': { in[out_pos]=L'\r'; break; } /* \t means tab */ case L't': { in[out_pos]=L'\t'; break; } /* \v means vertical tab */ case L'v': { in[out_pos]=L'\v'; break; } default: { if( unescape_special ) in[out_pos++] = INTERNAL_SEPARATOR; in[out_pos]=in[in_pos]; break; } } } else { switch( in[in_pos]) { case L'~': { if( unescape_special && (in_pos == 0) ) { in[out_pos]=HOME_DIRECTORY; } else { in[out_pos] = L'~'; } break; } case L'%': { if( unescape_special && (in_pos == 0) ) { in[out_pos]=PROCESS_EXPAND; } else { in[out_pos]=in[in_pos]; } break; } case L'*': { if( unescape_special ) { if( out_pos > 0 && in[out_pos-1]==ANY_STRING ) { out_pos--; in[out_pos] = ANY_STRING_RECURSIVE; } else in[out_pos]=ANY_STRING; } else { in[out_pos]=in[in_pos]; } break; } case L'?': { if( unescape_special ) { in[out_pos]=ANY_CHAR; } else { in[out_pos]=in[in_pos]; } break; } case L'$': { if( unescape_special ) { in[out_pos]=VARIABLE_EXPAND; } else { in[out_pos]=in[in_pos]; } break; } case L'{': { if( unescape_special ) { bracket_count++; in[out_pos]=BRACKET_BEGIN; } else { in[out_pos]=in[in_pos]; } break; } case L'}': { if( unescape_special ) { bracket_count--; in[out_pos]=BRACKET_END; } else { in[out_pos]=in[in_pos]; } break; } case L',': { if( unescape_special && bracket_count && prev!=BRACKET_SEP) { in[out_pos]=BRACKET_SEP; } else { in[out_pos]=in[in_pos]; } break; } case L'\'': { mode = 1; if( unescape_special ) in[out_pos] = INTERNAL_SEPARATOR; else out_pos--; break; } case L'\"': { mode = 2; if( unescape_special ) in[out_pos] = INTERNAL_SEPARATOR; else out_pos--; break; } default: { in[out_pos] = in[in_pos]; break; } } } break; } /* Mode 1 means single quoted string, i.e 'foo' */ case 1: { if( c == L'\\' ) { switch( in[++in_pos] ) { case '\\': case L'\'': case L'\n': { in[out_pos]=in[in_pos]; break; } case 0: { if( !allow_incomplete ) { free(in); return 0; } else { //We may ever escape a NULL character, but still appending a \ in case I am wrong. in[out_pos] = L'\\'; } } break; default: { in[out_pos++] = L'\\'; in[out_pos]= in[in_pos]; } } } if( c == L'\'' ) { if( unescape_special ) in[out_pos] = INTERNAL_SEPARATOR; else out_pos--; mode = 0; } else { in[out_pos] = in[in_pos]; } break; } /* Mode 2 means double quoted string, i.e. "foo" */ case 2: { switch( c ) { case '"': { mode = 0; if( unescape_special ) in[out_pos] = INTERNAL_SEPARATOR; else out_pos--; break; } case '\\': { switch( in[++in_pos] ) { case L'\0': { if( !allow_incomplete ) { free(in); return 0; } else { //We probably don't need it since NULL character is always appended before ending this function. in[out_pos]=in[in_pos]; } } break; case '\\': case L'$': case '"': case '\n': { in[out_pos]=in[in_pos]; break; } default: { in[out_pos++] = L'\\'; in[out_pos] = in[in_pos]; break; } } break; } case '$': { if( unescape_special ) { in[out_pos]=VARIABLE_EXPAND_SINGLE; } else { in[out_pos]=in[in_pos]; } break; } default: { in[out_pos] = in[in_pos]; break; } } break; } } } if( !allow_incomplete && mode ) { free( in ); return 0; } in[out_pos]=L'\0'; return in; } bool unescape_string(wcstring &str, int escape_special) { bool success = false; wchar_t *result = unescape(str.c_str(), escape_special); if (result) { str.replace(str.begin(), str.end(), result); free(result); success = true; } return success; } void common_handle_winch( int signal ) { #ifdef HAVE_WINSIZE if (ioctl(1,TIOCGWINSZ,&termsize)!=0) { return; } #else termsize.ws_col = 80; termsize.ws_row = 24; #endif } int common_get_width() { return termsize.ws_col; } int common_get_height() { return termsize.ws_row; } void tokenize_variable_array( const wcstring &val, std::vector &out) { size_t pos = 0, end = val.size(); while (pos < end) { size_t next_pos = val.find(ARRAY_SEP, pos); if (next_pos == wcstring::npos) break; out.push_back(val.substr(pos, next_pos - pos)); pos = next_pos + 1; //skip the separator } out.push_back(val.substr(pos, end - pos)); } bool string_prefixes_string(const wchar_t *proposed_prefix, const wcstring &value) { size_t prefix_size = wcslen(proposed_prefix); return prefix_size <= value.size() && value.compare(0, prefix_size, proposed_prefix) == 0; } bool string_prefixes_string(const wcstring &proposed_prefix, const wcstring &value) { size_t prefix_size = proposed_prefix.size(); return prefix_size <= value.size() && value.compare(0, prefix_size, proposed_prefix) == 0; } bool string_prefixes_string_case_insensitive(const wcstring &proposed_prefix, const wcstring &value) { size_t prefix_size = proposed_prefix.size(); return prefix_size <= value.size() && wcsncasecmp(proposed_prefix.c_str(), value.c_str(), prefix_size) == 0; } bool string_suffixes_string(const wcstring &proposed_suffix, const wcstring &value) { size_t suffix_size = proposed_suffix.size(); return suffix_size <= value.size() && value.compare(value.size() - suffix_size, suffix_size, proposed_suffix) == 0; } bool string_suffixes_string(const wchar_t *proposed_suffix, const wcstring &value) { size_t suffix_size = wcslen(proposed_suffix); return suffix_size <= value.size() && value.compare(value.size() - suffix_size, suffix_size, proposed_suffix) == 0; } bool list_contains_string(const wcstring_list_t &list, const wcstring &str) { return std::find(list.begin(), list.end(), str) != list.end(); } int create_directory( const wcstring &d ) { int ok = 0; struct stat buf; int stat_res = 0; while( (stat_res = wstat(d, &buf ) ) != 0 ) { if( errno != EAGAIN ) break; } if( stat_res == 0 ) { if( S_ISDIR( buf.st_mode ) ) { ok = 1; } } else { if( errno == ENOENT ) { wcstring dir = wdirname(d); if( !create_directory( dir ) ) { if( !wmkdir( d, 0700 ) ) { ok = 1; } } } } return ok?0:-1; } __attribute__((noinline)) void bugreport() { debug( 1, _( L"This is a bug. Break on bugreport to debug." L"If you can reproduce it, please send a bug report to %s." ), PACKAGE_BUGREPORT ); } wcstring format_size(long long sz) { wcstring result; const wchar_t *sz_name[]= { L"kB", L"MB", L"GB", L"TB", L"PB", L"EB", L"ZB", L"YB", 0 }; if( sz < 0 ) { result.append( L"unknown" ); } else if( sz < 1 ) { result.append( _( L"empty" ) ); } else if( sz < 1024 ) { result.append(format_string( L"%lldB", sz )); } else { int i; for( i=0; sz_name[i]; i++ ) { if( sz < (1024*1024) || !sz_name[i+1] ) { int isz = sz/1024; if( isz > 9 ) result.append( format_string( L"%d%ls", isz, sz_name[i] )); else result.append( format_string( L"%.1f%ls", (double)sz/1024, sz_name[i] )); break; } sz /= 1024; } } return result; } /* Crappy function to extract the most significant digit of an unsigned long long value */ static char extract_most_significant_digit(unsigned long long *xp) { unsigned long long place_value = 1; unsigned long long x = *xp; while (x >= 10) { x /= 10; place_value *= 10; } *xp -= (place_value * x); return x + '0'; } void append_ull(char *buff, unsigned long long val, size_t *inout_idx, size_t max_len) { size_t idx = *inout_idx; while (val > 0 && idx < max_len) buff[idx++] = extract_most_significant_digit(&val); *inout_idx = idx; } void append_str(char *buff, const char *str, size_t *inout_idx, size_t max_len) { size_t idx = *inout_idx; while (*str && idx < max_len) buff[idx++] = *str++; *inout_idx = idx; } void format_size_safe(char buff[128], unsigned long long sz) { const size_t buff_size = 128; const size_t max_len = buff_size - 1; //need to leave room for a null terminator bzero(buff, buff_size); size_t idx = 0; const char * const sz_name[]= { "kB", "MB", "GB", "TB", "PB", "EB", "ZB", "YB", NULL }; if (sz < 1) { strncpy(buff, "empty", buff_size); } else if (sz < 1024) { append_ull(buff, sz, &idx, max_len); append_str(buff, "B", &idx, max_len); } else { for( size_t i=0; sz_name[i]; i++ ) { if( sz < (1024*1024) || !sz_name[i+1] ) { unsigned long long isz = sz/1024; if( isz > 9 ) { append_ull(buff, isz, &idx, max_len); } else { if (isz == 0) { append_str(buff, "0", &idx, max_len); } else { append_ull(buff, isz, &idx, max_len); } // Maybe append a single fraction digit unsigned long long remainder = sz % 1024; if (remainder > 0) { char tmp[3] = {'.', extract_most_significant_digit(&remainder), 0}; append_str(buff, tmp, &idx, max_len); } } append_str(buff, sz_name[i], &idx, max_len); break; } sz /= 1024; } } } double timef() { int time_res; struct timeval tv; time_res = gettimeofday(&tv, 0); if( time_res ) { /* Fixme: What on earth is the correct parameter value for NaN? The man pages and the standard helpfully state that this parameter is implementation defined. Gcc gives a warning if a null pointer is used. But not even all mighty Google gives a hint to what value should actually be returned. */ return nan(""); } return (double)tv.tv_sec + 0.000001*tv.tv_usec; } void exit_without_destructors(int code) { _exit(code); } /* Helper function to convert from a null_terminated_array_t to a null_terminated_array_t */ null_terminated_array_t convert_wide_array_to_narrow(const null_terminated_array_t &wide_arr) { const wchar_t *const *arr = wide_arr.get(); if (! arr) return null_terminated_array_t(); std::vector list; for (size_t i=0; arr[i]; i++) { list.push_back(wcs2string(arr[i])); } return null_terminated_array_t(list); } void append_path_component(wcstring &path, const wcstring &component) { if (path.empty() || component.empty()) { path.append(component); } else { size_t path_len = path.size(); bool path_slash = path.at(path_len-1) == L'/'; bool comp_slash = component.at(0) == L'/'; if (! path_slash && ! comp_slash) { // Need a slash path.push_back(L'/'); } else if (path_slash && comp_slash) { // Too many slashes path.erase(path_len - 1, 1); } path.append(component); } } extern "C" { __attribute__((noinline)) void debug_thread_error(void) { while (1) sleep(9999999); } } void set_main_thread() { main_thread_id = pthread_self(); } void configure_thread_assertions_for_testing(void) { thread_assertions_configured_for_testing = true; } /* Notice when we've forked */ static pid_t initial_pid = 0; bool is_forked_child(void) { /* Just bail if nobody's called setup_fork_guards - e.g. fishd */ if (! initial_pid) return false; bool is_child_of_fork = (getpid() != initial_pid); if (is_child_of_fork) { printf("Uh-oh: %d\n", getpid()); while (1) sleep(10000); } return is_child_of_fork; } void setup_fork_guards(void) { /* Notice when we fork by stashing our pid. This seems simpler than pthread_atfork(). */ initial_pid = getpid(); } bool is_main_thread() { assert (main_thread_id != 0); return main_thread_id == pthread_self(); } void assert_is_main_thread(const char *who) { if (! is_main_thread() && ! thread_assertions_configured_for_testing) { fprintf(stderr, "Warning: %s called off of main thread. Break on debug_thread_error to debug.\n", who); debug_thread_error(); } } void assert_is_not_forked_child(const char *who) { if (is_forked_child()) { fprintf(stderr, "Warning: %s called in a forked child. Break on debug_thread_error to debug.\n", who); debug_thread_error(); } } void assert_is_background_thread(const char *who) { if (is_main_thread() && ! thread_assertions_configured_for_testing) { fprintf(stderr, "Warning: %s called on the main thread (may block!). Break on debug_thread_error to debug.\n", who); debug_thread_error(); } } void assert_is_locked(void *vmutex, const char *who, const char *caller) { pthread_mutex_t *mutex = static_cast(vmutex); if (0 == pthread_mutex_trylock(mutex)) { fprintf(stderr, "Warning: %s is not locked when it should be in '%s'. Break on debug_thread_error to debug.\n", who, caller); debug_thread_error(); pthread_mutex_unlock(mutex); } } void scoped_lock::lock(void) { assert(! locked); assert(! is_forked_child()); VOMIT_ON_FAILURE(pthread_mutex_lock(lock_obj)); locked = true; } void scoped_lock::unlock(void) { assert(locked); assert(! is_forked_child()); VOMIT_ON_FAILURE(pthread_mutex_unlock(lock_obj)); locked = false; } scoped_lock::scoped_lock(pthread_mutex_t &mutex) : lock_obj(&mutex), locked(false) { this->lock(); } scoped_lock::~scoped_lock() { if (locked) this->unlock(); }