//===-- sanitizer_printf.cc -----------------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file is shared between AddressSanitizer and ThreadSanitizer. // // Internal printf function, used inside run-time libraries. // We can't use libc printf because we intercept some of the functions used // inside it. //===----------------------------------------------------------------------===// #include "sanitizer_common.h" #include "sanitizer_flags.h" #include "sanitizer_libc.h" #include #include #if SANITIZER_WINDOWS && defined(_MSC_VER) && _MSC_VER < 1800 && \ !defined(va_copy) # define va_copy(dst, src) ((dst) = (src)) #endif namespace __sanitizer { static int AppendChar(char **buff, const char *buff_end, char c) { if (*buff < buff_end) { **buff = c; (*buff)++; } return 1; } // Appends number in a given base to buffer. If its length is less than // |minimal_num_length|, it is padded with leading zeroes or spaces, depending // on the value of |pad_with_zero|. static int AppendNumber(char **buff, const char *buff_end, u64 absolute_value, u8 base, u8 minimal_num_length, bool pad_with_zero, bool negative, bool uppercase) { uptr const kMaxLen = 30; RAW_CHECK(base == 10 || base == 16); RAW_CHECK(base == 10 || !negative); RAW_CHECK(absolute_value || !negative); RAW_CHECK(minimal_num_length < kMaxLen); int result = 0; if (negative && minimal_num_length) --minimal_num_length; if (negative && pad_with_zero) result += AppendChar(buff, buff_end, '-'); uptr num_buffer[kMaxLen]; int pos = 0; do { RAW_CHECK_MSG((uptr)pos < kMaxLen, "AppendNumber buffer overflow"); num_buffer[pos++] = absolute_value % base; absolute_value /= base; } while (absolute_value > 0); if (pos < minimal_num_length) { // Make sure compiler doesn't insert call to memset here. internal_memset(&num_buffer[pos], 0, sizeof(num_buffer[0]) * (minimal_num_length - pos)); pos = minimal_num_length; } RAW_CHECK(pos > 0); pos--; for (; pos >= 0 && num_buffer[pos] == 0; pos--) { char c = (pad_with_zero || pos == 0) ? '0' : ' '; result += AppendChar(buff, buff_end, c); } if (negative && !pad_with_zero) result += AppendChar(buff, buff_end, '-'); for (; pos >= 0; pos--) { char digit = static_cast(num_buffer[pos]); digit = (digit < 10) ? '0' + digit : (uppercase ? 'A' : 'a') + digit - 10; result += AppendChar(buff, buff_end, digit); } return result; } static int AppendUnsigned(char **buff, const char *buff_end, u64 num, u8 base, u8 minimal_num_length, bool pad_with_zero, bool uppercase) { return AppendNumber(buff, buff_end, num, base, minimal_num_length, pad_with_zero, false /* negative */, uppercase); } static int AppendSignedDecimal(char **buff, const char *buff_end, s64 num, u8 minimal_num_length, bool pad_with_zero) { bool negative = (num < 0); return AppendNumber(buff, buff_end, (u64)(negative ? -num : num), 10, minimal_num_length, pad_with_zero, negative, false /* uppercase */); } static int AppendString(char **buff, const char *buff_end, int precision, const char *s) { if (!s) s = ""; int result = 0; for (; *s; s++) { if (precision >= 0 && result >= precision) break; result += AppendChar(buff, buff_end, *s); } return result; } static int AppendPointer(char **buff, const char *buff_end, u64 ptr_value) { int result = 0; result += AppendString(buff, buff_end, -1, "0x"); result += AppendUnsigned(buff, buff_end, ptr_value, 16, SANITIZER_POINTER_FORMAT_LENGTH, true /* pad_with_zero */, false /* uppercase */); return result; } int VSNPrintf(char *buff, int buff_length, const char *format, va_list args) { static const char *kPrintfFormatsHelp = "Supported Printf formats: %([0-9]*)?(z|ll)?{d,u,x,X}; %p; %(\\.\\*)?s; " "%c\n"; RAW_CHECK(format); RAW_CHECK(buff_length > 0); const char *buff_end = &buff[buff_length - 1]; const char *cur = format; int result = 0; for (; *cur; cur++) { if (*cur != '%') { result += AppendChar(&buff, buff_end, *cur); continue; } cur++; bool have_width = (*cur >= '0' && *cur <= '9'); bool pad_with_zero = (*cur == '0'); int width = 0; if (have_width) { while (*cur >= '0' && *cur <= '9') { width = width * 10 + *cur++ - '0'; } } bool have_precision = (cur[0] == '.' && cur[1] == '*'); int precision = -1; if (have_precision) { cur += 2; precision = va_arg(args, int); } bool have_z = (*cur == 'z'); cur += have_z; bool have_ll = !have_z && (cur[0] == 'l' && cur[1] == 'l'); cur += have_ll * 2; s64 dval; u64 uval; bool have_flags = have_width | have_z | have_ll; // Only %s supports precision for now CHECK(!(precision >= 0 && *cur != 's')); switch (*cur) { case 'd': { dval = have_ll ? va_arg(args, s64) : have_z ? va_arg(args, sptr) : va_arg(args, int); result += AppendSignedDecimal(&buff, buff_end, dval, width, pad_with_zero); break; } case 'u': case 'x': case 'X': { uval = have_ll ? va_arg(args, u64) : have_z ? va_arg(args, uptr) : va_arg(args, unsigned); bool uppercase = (*cur == 'X'); result += AppendUnsigned(&buff, buff_end, uval, (*cur == 'u') ? 10 : 16, width, pad_with_zero, uppercase); break; } case 'p': { RAW_CHECK_MSG(!have_flags, kPrintfFormatsHelp); result += AppendPointer(&buff, buff_end, va_arg(args, uptr)); break; } case 's': { RAW_CHECK_MSG(!have_flags, kPrintfFormatsHelp); result += AppendString(&buff, buff_end, precision, va_arg(args, char*)); break; } case 'c': { RAW_CHECK_MSG(!have_flags, kPrintfFormatsHelp); result += AppendChar(&buff, buff_end, va_arg(args, int)); break; } case '%' : { RAW_CHECK_MSG(!have_flags, kPrintfFormatsHelp); result += AppendChar(&buff, buff_end, '%'); break; } default: { RAW_CHECK_MSG(false, kPrintfFormatsHelp); } } } RAW_CHECK(buff <= buff_end); AppendChar(&buff, buff_end + 1, '\0'); return result; } static void (*PrintfAndReportCallback)(const char *); void SetPrintfAndReportCallback(void (*callback)(const char *)) { PrintfAndReportCallback = callback; } // Can be overriden in frontend. #if SANITIZER_GO && defined(TSAN_EXTERNAL_HOOKS) // Implementation must be defined in frontend. extern "C" void OnPrint(const char *str); #else SANITIZER_INTERFACE_WEAK_DEF(void, OnPrint, const char *str) { (void)str; } #endif static void CallPrintfAndReportCallback(const char *str) { OnPrint(str); if (PrintfAndReportCallback) PrintfAndReportCallback(str); } static void NOINLINE SharedPrintfCodeNoBuffer(bool append_pid, char *local_buffer, int buffer_size, const char *format, va_list args) { va_list args2; va_copy(args2, args); const int kLen = 16 * 1024; int needed_length; char *buffer = local_buffer; // First try to print a message using a local buffer, and then fall back to // mmaped buffer. for (int use_mmap = 0; use_mmap < 2; use_mmap++) { if (use_mmap) { va_end(args); va_copy(args, args2); buffer = (char*)MmapOrDie(kLen, "Report"); buffer_size = kLen; } needed_length = 0; // Check that data fits into the current buffer. # define CHECK_NEEDED_LENGTH \ if (needed_length >= buffer_size) { \ if (!use_mmap) continue; \ RAW_CHECK_MSG(needed_length < kLen, \ "Buffer in Report is too short!\n"); \ } // Fuchsia's logging infrastructure always keeps track of the logging // process, thread, and timestamp, so never prepend such information. if (!SANITIZER_FUCHSIA && append_pid) { int pid = internal_getpid(); const char *exe_name = GetProcessName(); if (common_flags()->log_exe_name && exe_name) { needed_length += internal_snprintf(buffer, buffer_size, "==%s", exe_name); CHECK_NEEDED_LENGTH } needed_length += internal_snprintf( buffer + needed_length, buffer_size - needed_length, "==%d==", pid); CHECK_NEEDED_LENGTH } needed_length += VSNPrintf(buffer + needed_length, buffer_size - needed_length, format, args); CHECK_NEEDED_LENGTH // If the message fit into the buffer, print it and exit. break; # undef CHECK_NEEDED_LENGTH } RawWrite(buffer); // Remove color sequences from the message. RemoveANSIEscapeSequencesFromString(buffer); CallPrintfAndReportCallback(buffer); LogMessageOnPrintf(buffer); // If we had mapped any memory, clean up. if (buffer != local_buffer) UnmapOrDie((void *)buffer, buffer_size); va_end(args2); } static void NOINLINE SharedPrintfCode(bool append_pid, const char *format, va_list args) { // |local_buffer| is small enough not to overflow the stack and/or violate // the stack limit enforced by TSan (-Wframe-larger-than=512). On the other // hand, the bigger the buffer is, the more the chance the error report will // fit into it. char local_buffer[400]; SharedPrintfCodeNoBuffer(append_pid, local_buffer, ARRAY_SIZE(local_buffer), format, args); } FORMAT(1, 2) void Printf(const char *format, ...) { va_list args; va_start(args, format); SharedPrintfCode(false, format, args); va_end(args); } // Like Printf, but prints the current PID before the output string. FORMAT(1, 2) void Report(const char *format, ...) { va_list args; va_start(args, format); SharedPrintfCode(true, format, args); va_end(args); } // Writes at most "length" symbols to "buffer" (including trailing '\0'). // Returns the number of symbols that should have been written to buffer // (not including trailing '\0'). Thus, the string is truncated // iff return value is not less than "length". FORMAT(3, 4) int internal_snprintf(char *buffer, uptr length, const char *format, ...) { va_list args; va_start(args, format); int needed_length = VSNPrintf(buffer, length, format, args); va_end(args); return needed_length; } FORMAT(2, 3) void InternalScopedString::append(const char *format, ...) { CHECK_LT(length_, size()); va_list args; va_start(args, format); VSNPrintf(data() + length_, size() - length_, format, args); va_end(args); length_ += internal_strlen(data() + length_); CHECK_LT(length_, size()); } } // namespace __sanitizer