/* * Copyright (c) 2018-2021, Andreas Kling * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static void strtons(const char* str, char** endptr) { assert(endptr); char* ptr = const_cast(str); while (isspace(*ptr)) { ptr += 1; } *endptr = ptr; } enum Sign { Negative, Positive, }; static Sign strtosign(const char* str, char** endptr) { assert(endptr); if (*str == '+') { *endptr = const_cast(str + 1); return Sign::Positive; } else if (*str == '-') { *endptr = const_cast(str + 1); return Sign::Negative; } else { *endptr = const_cast(str); return Sign::Positive; } } enum DigitConsumeDecision { Consumed, PosOverflow, NegOverflow, Invalid, }; template class NumParser { AK_MAKE_NONMOVABLE(NumParser); public: NumParser(Sign sign, int base) : m_base(base) , m_num(0) , m_sign(sign) { m_cutoff = positive() ? (max_value / base) : (min_value / base); m_max_digit_after_cutoff = positive() ? (max_value % base) : (min_value % base); } int parse_digit(char ch) { int digit; if (isdigit(ch)) digit = ch - '0'; else if (islower(ch)) digit = ch - ('a' - 10); else if (isupper(ch)) digit = ch - ('A' - 10); else return -1; if (static_cast(digit) >= m_base) return -1; return digit; } DigitConsumeDecision consume(char ch) { int digit = parse_digit(ch); if (digit == -1) return DigitConsumeDecision::Invalid; if (!can_append_digit(digit)) { if (m_sign != Sign::Negative) { return DigitConsumeDecision::PosOverflow; } else { return DigitConsumeDecision::NegOverflow; } } m_num *= m_base; m_num += positive() ? digit : -digit; return DigitConsumeDecision::Consumed; } T number() const { return m_num; }; private: bool can_append_digit(int digit) { const bool is_below_cutoff = positive() ? (m_num < m_cutoff) : (m_num > m_cutoff); if (is_below_cutoff) { return true; } else { return m_num == m_cutoff && digit < m_max_digit_after_cutoff; } } bool positive() const { return m_sign != Sign::Negative; } const T m_base; T m_num; T m_cutoff; int m_max_digit_after_cutoff; Sign m_sign; }; typedef NumParser IntParser; typedef NumParser LongLongParser; typedef NumParser ULongLongParser; static bool is_either(char* str, int offset, char lower, char upper) { char ch = *(str + offset); return ch == lower || ch == upper; } template inline int generate_unique_filename(char* pattern, Callback callback) { size_t length = strlen(pattern); if (length < 6 || memcmp(pattern + length - 6, "XXXXXX", 6)) return EINVAL; size_t start = length - 6; constexpr char random_characters[] = "abcdefghijklmnopqrstuvwxyz0123456789"; for (int attempt = 0; attempt < 100; ++attempt) { for (int i = 0; i < 6; ++i) pattern[start + i] = random_characters[(arc4random() % (sizeof(random_characters) - 1))]; if (callback() == IterationDecision::Break) return 0; } return EEXIST; } extern "C" { long getauxval(long type) { errno = 0; auxv_t* auxvp = (auxv_t*)__auxiliary_vector; for (; auxvp->a_type != AT_NULL; ++auxvp) { if (auxvp->a_type == type) return auxvp->a_un.a_val; } errno = ENOENT; return 0; } void exit(int status) { __cxa_finalize(nullptr); if (secure_getenv("LIBC_DUMP_MALLOC_STATS")) serenity_dump_malloc_stats(); extern void _fini(); _fini(); fflush(stdout); fflush(stderr); #ifndef _DYNAMIC_LOADER __pthread_key_destroy_for_current_thread(); #endif _exit(status); } static void __atexit_to_cxa_atexit(void* handler) { reinterpret_cast(handler)(); } int atexit(void (*handler)()) { return __cxa_atexit(__atexit_to_cxa_atexit, (void*)handler, nullptr); } void abort() { // For starters, send ourselves a SIGABRT. raise(SIGABRT); // If that didn't kill us, try harder. sigset_t set; sigemptyset(&set); sigaddset(&set, SIGABRT); sigprocmask(SIG_UNBLOCK, &set, nullptr); raise(SIGABRT); _abort(); } static HashTable s_malloced_environment_variables; static void free_environment_variable_if_needed(const char* var) { if (!s_malloced_environment_variables.contains(var)) return; free(const_cast(var)); s_malloced_environment_variables.remove(var); } char* getenv(const char* name) { size_t vl = strlen(name); for (size_t i = 0; environ[i]; ++i) { const char* decl = environ[i]; char* eq = strchr(decl, '='); if (!eq) continue; size_t varLength = eq - decl; if (vl != varLength) continue; if (strncmp(decl, name, varLength) == 0) { return eq + 1; } } return nullptr; } char* secure_getenv(const char* name) { if (getauxval(AT_SECURE)) return nullptr; return getenv(name); } int unsetenv(const char* name) { auto new_var_len = strlen(name); size_t environ_size = 0; int skip = -1; for (; environ[environ_size]; ++environ_size) { char* old_var = environ[environ_size]; char* old_eq = strchr(old_var, '='); VERIFY(old_eq); size_t old_var_len = old_eq - old_var; if (new_var_len != old_var_len) continue; // can't match if (strncmp(name, old_var, new_var_len) == 0) skip = environ_size; } if (skip == -1) return 0; // not found: no failure. // Shuffle the existing array down by one. memmove(&environ[skip], &environ[skip + 1], ((environ_size - 1) - skip) * sizeof(environ[0])); environ[environ_size - 1] = nullptr; free_environment_variable_if_needed(name); return 0; } int clearenv() { size_t environ_size = 0; for (; environ[environ_size]; ++environ_size) { environ[environ_size] = NULL; } *environ = NULL; return 0; } int setenv(const char* name, const char* value, int overwrite) { if (!overwrite && getenv(name)) return 0; auto length = strlen(name) + strlen(value) + 2; auto* var = (char*)malloc(length); snprintf(var, length, "%s=%s", name, value); s_malloced_environment_variables.set(var); return putenv(var); } int putenv(char* new_var) { char* new_eq = strchr(new_var, '='); if (!new_eq) return unsetenv(new_var); auto new_var_len = new_eq - new_var; int environ_size = 0; for (; environ[environ_size]; ++environ_size) { char* old_var = environ[environ_size]; char* old_eq = strchr(old_var, '='); VERIFY(old_eq); auto old_var_len = old_eq - old_var; if (new_var_len != old_var_len) continue; // can't match if (strncmp(new_var, old_var, new_var_len) == 0) { free_environment_variable_if_needed(old_var); environ[environ_size] = new_var; return 0; } } // At this point, we need to append the new var. // 2 here: one for the new var, one for the sentinel value. auto** new_environ = static_cast(kmalloc_array(environ_size + 2, sizeof(char*))); if (new_environ == nullptr) { errno = ENOMEM; return -1; } for (int i = 0; environ[i]; ++i) { new_environ[i] = environ[i]; } new_environ[environ_size] = new_var; new_environ[environ_size + 1] = nullptr; // swap new and old // note that the initial environ is not heap allocated! extern bool __environ_is_malloced; if (__environ_is_malloced) free(environ); __environ_is_malloced = true; environ = new_environ; return 0; } static const char* __progname = NULL; const char* getprogname() { return __progname; } void setprogname(const char* progname) { for (int i = strlen(progname) - 1; i >= 0; i--) { if (progname[i] == '/') { __progname = progname + i + 1; return; } } __progname = progname; } double strtod(const char* str, char** endptr) { // Parse spaces, sign, and base char* parse_ptr = const_cast(str); strtons(parse_ptr, &parse_ptr); const Sign sign = strtosign(parse_ptr, &parse_ptr); // Parse inf/nan, if applicable. if (is_either(parse_ptr, 0, 'i', 'I')) { if (is_either(parse_ptr, 1, 'n', 'N')) { if (is_either(parse_ptr, 2, 'f', 'F')) { parse_ptr += 3; if (is_either(parse_ptr, 0, 'i', 'I')) { if (is_either(parse_ptr, 1, 'n', 'N')) { if (is_either(parse_ptr, 2, 'i', 'I')) { if (is_either(parse_ptr, 3, 't', 'T')) { if (is_either(parse_ptr, 4, 'y', 'Y')) { parse_ptr += 5; } } } } } if (endptr) *endptr = parse_ptr; // Don't set errno to ERANGE here: // The caller may want to distinguish between "input is // literal infinity" and "input is not literal infinity // but did not fit into double". if (sign != Sign::Negative) { return __builtin_huge_val(); } else { return -__builtin_huge_val(); } } } } if (is_either(parse_ptr, 0, 'n', 'N')) { if (is_either(parse_ptr, 1, 'a', 'A')) { if (is_either(parse_ptr, 2, 'n', 'N')) { if (endptr) *endptr = parse_ptr + 3; errno = ERANGE; if (sign != Sign::Negative) { return __builtin_nan(""); } else { return -__builtin_nan(""); } } } } // Parse base char exponent_lower; char exponent_upper; int base = 10; if (*parse_ptr == '0') { const char base_ch = *(parse_ptr + 1); if (base_ch == 'x' || base_ch == 'X') { base = 16; parse_ptr += 2; } } if (base == 10) { exponent_lower = 'e'; exponent_upper = 'E'; } else { exponent_lower = 'p'; exponent_upper = 'P'; } // Parse "digits", possibly keeping track of the exponent offset. // We parse the most significant digits and the position in the // base-`base` representation separately. This allows us to handle // numbers like `0.0000000000000000000000000000000000001234` or // `1234567890123456789012345678901234567890` with ease. LongLongParser digits { sign, base }; bool digits_usable = false; bool should_continue = true; bool digits_overflow = false; bool after_decimal = false; int exponent = 0; do { if (!after_decimal && *parse_ptr == '.') { after_decimal = true; parse_ptr += 1; continue; } bool is_a_digit; if (digits_overflow) { is_a_digit = digits.parse_digit(*parse_ptr) != -1; } else { DigitConsumeDecision decision = digits.consume(*parse_ptr); switch (decision) { case DigitConsumeDecision::Consumed: is_a_digit = true; // The very first actual digit must pass here: digits_usable = true; break; case DigitConsumeDecision::PosOverflow: case DigitConsumeDecision::NegOverflow: is_a_digit = true; digits_overflow = true; break; case DigitConsumeDecision::Invalid: is_a_digit = false; break; default: VERIFY_NOT_REACHED(); } } if (is_a_digit) { exponent -= after_decimal ? 1 : 0; exponent += digits_overflow ? 1 : 0; } should_continue = is_a_digit; parse_ptr += should_continue; } while (should_continue); if (!digits_usable) { // No actual number value available. if (endptr) *endptr = const_cast(str); return 0.0; } // Parse exponent. // We already know the next character is not a digit in the current base, // nor a valid decimal point. Check whether it's an exponent sign. if (*parse_ptr == exponent_lower || *parse_ptr == exponent_upper) { // Need to keep the old parse_ptr around, in case of rollback. char* old_parse_ptr = parse_ptr; parse_ptr += 1; // Can't use atol or strtol here: Must accept excessive exponents, // even exponents >64 bits. Sign exponent_sign = strtosign(parse_ptr, &parse_ptr); IntParser exponent_parser { exponent_sign, base }; bool exponent_usable = false; bool exponent_overflow = false; should_continue = true; do { bool is_a_digit; if (exponent_overflow) { is_a_digit = exponent_parser.parse_digit(*parse_ptr) != -1; } else { DigitConsumeDecision decision = exponent_parser.consume(*parse_ptr); switch (decision) { case DigitConsumeDecision::Consumed: is_a_digit = true; // The very first actual digit must pass here: exponent_usable = true; break; case DigitConsumeDecision::PosOverflow: case DigitConsumeDecision::NegOverflow: is_a_digit = true; exponent_overflow = true; break; case DigitConsumeDecision::Invalid: is_a_digit = false; break; default: VERIFY_NOT_REACHED(); } } should_continue = is_a_digit; parse_ptr += should_continue; } while (should_continue); if (!exponent_usable) { parse_ptr = old_parse_ptr; } else if (exponent_overflow) { // Technically this is wrong. If someone gives us 5GB of digits, // and then an exponent of -5_000_000_000, the resulting exponent // should be around 0. // However, I think it's safe to assume that we never have to deal // with that many digits anyway. if (sign != Sign::Negative) { exponent = INT_MIN; } else { exponent = INT_MAX; } } else { // Literal exponent is usable and fits in an int. // However, `exponent + exponent_parser.number()` might overflow an int. // This would result in the wrong sign of the exponent! long long new_exponent = static_cast(exponent) + static_cast(exponent_parser.number()); if (new_exponent < INT_MIN) { exponent = INT_MIN; } else if (new_exponent > INT_MAX) { exponent = INT_MAX; } else { exponent = static_cast(new_exponent); } } } // Parsing finished. now we only have to compute the result. if (endptr) *endptr = const_cast(parse_ptr); // If `digits` is zero, we don't even have to look at `exponent`. if (digits.number() == 0) { if (sign != Sign::Negative) { return 0.0; } else { return -0.0; } } // Deal with extreme exponents. // The smallest normal is 2^-1022. // The smallest denormal is 2^-1074. // The largest number in `digits` is 2^63 - 1. // Therefore, if "base^exponent" is smaller than 2^-(1074+63), the result is 0.0 anyway. // This threshold is roughly 5.3566 * 10^-343. // So if the resulting exponent is -344 or lower (closer to -inf), // the result is 0.0 anyway. // We only need to avoid false positives, so we can ignore base 16. if (exponent <= -344) { errno = ERANGE; // Definitely can't be represented more precisely. // I lied, sometimes the result is +0.0, and sometimes -0.0. if (sign != Sign::Negative) { return 0.0; } else { return -0.0; } } // The largest normal is 2^+1024-eps. // The smallest number in `digits` is 1. // Therefore, if "base^exponent" is 2^+1024, the result is INF anyway. // This threshold is roughly 1.7977 * 10^-308. // So if the resulting exponent is +309 or higher, // the result is INF anyway. // We only need to avoid false positives, so we can ignore base 16. if (exponent >= 309) { errno = ERANGE; // Definitely can't be represented more precisely. // I lied, sometimes the result is +INF, and sometimes -INF. if (sign != Sign::Negative) { return __builtin_huge_val(); } else { return -__builtin_huge_val(); } } // TODO: If `exponent` is large, this could be made faster. double value = digits.number(); double scale = 1; if (exponent < 0) { exponent = -exponent; for (int i = 0; i < min(exponent, 300); ++i) { scale *= base; } value /= scale; for (int i = 300; i < exponent; i++) { value /= base; } if (value == -0.0 || value == +0.0) { errno = ERANGE; } } else if (exponent > 0) { for (int i = 0; i < exponent; ++i) { scale *= base; } value *= scale; if (value == -__builtin_huge_val() || value == +__builtin_huge_val()) { errno = ERANGE; } } return value; } long double strtold(const char* str, char** endptr) { assert(sizeof(double) == sizeof(long double)); return strtod(str, endptr); } float strtof(const char* str, char** endptr) { return strtod(str, endptr); } double atof(const char* str) { return strtod(str, nullptr); } int atoi(const char* str) { long value = strtol(str, nullptr, 10); if (value > INT_MAX) { return INT_MAX; } return value; } long atol(const char* str) { return strtol(str, nullptr, 10); } long long atoll(const char* str) { return strtoll(str, nullptr, 10); } static char ptsname_buf[32]; char* ptsname(int fd) { if (ptsname_r(fd, ptsname_buf, sizeof(ptsname_buf)) < 0) return nullptr; return ptsname_buf; } int ptsname_r(int fd, char* buffer, size_t size) { int rc = syscall(SC_ptsname, fd, buffer, size); __RETURN_WITH_ERRNO(rc, rc, -1); } static unsigned long s_next_rand = 1; int rand() { s_next_rand = s_next_rand * 1103515245 + 12345; return ((unsigned)(s_next_rand / ((RAND_MAX + 1) * 2)) % (RAND_MAX + 1)); } void srand(unsigned seed) { s_next_rand = seed; } int abs(int i) { return i < 0 ? -i : i; } long long int llabs(long long int i) { return i < 0 ? -i : i; } long int random() { return rand(); } void srandom(unsigned seed) { srand(seed); } int system(const char* command) { if (!command) return 1; pid_t child; const char* argv[] = { "sh", "-c", command, nullptr }; if ((errno = posix_spawn(&child, "/bin/sh", nullptr, nullptr, const_cast(argv), environ))) return -1; int wstatus; waitpid(child, &wstatus, 0); return WEXITSTATUS(wstatus); } char* mktemp(char* pattern) { auto error = generate_unique_filename(pattern, [&] { struct stat st; int rc = lstat(pattern, &st); if (rc < 0 && errno == ENOENT) return IterationDecision::Break; return IterationDecision::Continue; }); if (error) { pattern[0] = '\0'; errno = error; } return pattern; } int mkstemp(char* pattern) { int fd = -1; auto error = generate_unique_filename(pattern, [&] { fd = open(pattern, O_RDWR | O_CREAT | O_EXCL, S_IRUSR | S_IWUSR); // I'm using the flags I saw glibc using. if (fd >= 0) return IterationDecision::Break; return IterationDecision::Continue; }); if (error) { errno = error; return -1; } return fd; } char* mkdtemp(char* pattern) { auto error = generate_unique_filename(pattern, [&] { if (mkdir(pattern, 0700) == 0) return IterationDecision::Break; return IterationDecision::Continue; }); if (error) { errno = error; return nullptr; } return pattern; } void* bsearch(const void* key, const void* base, size_t nmemb, size_t size, int (*compar)(const void*, const void*)) { char* start = static_cast(const_cast(base)); while (nmemb > 0) { char* middle_memb = start + (nmemb / 2) * size; int comparison = compar(key, middle_memb); if (comparison == 0) return middle_memb; else if (comparison > 0) { start = middle_memb + size; --nmemb; } nmemb /= 2; } return nullptr; } div_t div(int numerator, int denominator) { div_t result; result.quot = numerator / denominator; result.rem = numerator % denominator; if (numerator >= 0 && result.rem < 0) { result.quot++; result.rem -= denominator; } return result; } ldiv_t ldiv(long numerator, long denominator) { ldiv_t result; result.quot = numerator / denominator; result.rem = numerator % denominator; if (numerator >= 0 && result.rem < 0) { result.quot++; result.rem -= denominator; } return result; } lldiv_t lldiv(long long numerator, long long denominator) { lldiv_t result; result.quot = numerator / denominator; result.rem = numerator % denominator; if (numerator >= 0 && result.rem < 0) { result.quot++; result.rem -= denominator; } return result; } int mblen(char const* s, size_t n) { // FIXME: Implement locale support if (!s) return 0; return (MB_CUR_MAX > n) ? n : MB_CUR_MAX; } size_t mbstowcs(wchar_t*, const char*, size_t) { dbgln("FIXME: Implement mbstowcs()"); TODO(); } int mbtowc(wchar_t* wch, const char* data, [[maybe_unused]] size_t data_size) { // FIXME: This needs a real implementation. if (wch && data) { *wch = *data; return 1; } if (!wch && data) { return 1; } return 0; } int wctomb(char*, wchar_t) { dbgln("FIXME: Implement wctomb()"); TODO(); } size_t wcstombs(char* dest, const wchar_t* src, size_t max) { char* original_dest = dest; while ((size_t)(dest - original_dest) < max) { StringView v { (const char*)src, sizeof(wchar_t) }; // FIXME: dependent on locale, for now utf-8 is supported. Utf8View utf8 { v }; if (*utf8.begin() == '\0') { *dest = '\0'; return (size_t)(dest - original_dest); // Exclude null character in returned size } for (auto byte : utf8) { if (byte != '\0') *dest++ = byte; } ++src; } return max; } long strtol(const char* str, char** endptr, int base) { long long value = strtoll(str, endptr, base); if (value < LONG_MIN) { errno = ERANGE; return LONG_MIN; } else if (value > LONG_MAX) { errno = ERANGE; return LONG_MAX; } return value; } unsigned long strtoul(const char* str, char** endptr, int base) { unsigned long long value = strtoull(str, endptr, base); if (value > ULONG_MAX) { errno = ERANGE; return ULONG_MAX; } return value; } long long strtoll(const char* str, char** endptr, int base) { // Parse spaces and sign char* parse_ptr = const_cast(str); strtons(parse_ptr, &parse_ptr); const Sign sign = strtosign(parse_ptr, &parse_ptr); // Parse base if (base == 0) { if (*parse_ptr == '0') { if (tolower(*(parse_ptr + 1)) == 'x') { base = 16; parse_ptr += 2; } else { base = 8; } } else { base = 10; } } // Parse actual digits. LongLongParser digits { sign, base }; bool digits_usable = false; bool should_continue = true; bool overflow = false; do { bool is_a_digit; if (overflow) { is_a_digit = digits.parse_digit(*parse_ptr) >= 0; } else { DigitConsumeDecision decision = digits.consume(*parse_ptr); switch (decision) { case DigitConsumeDecision::Consumed: is_a_digit = true; // The very first actual digit must pass here: digits_usable = true; break; case DigitConsumeDecision::PosOverflow: case DigitConsumeDecision::NegOverflow: is_a_digit = true; overflow = true; break; case DigitConsumeDecision::Invalid: is_a_digit = false; break; default: VERIFY_NOT_REACHED(); } } should_continue = is_a_digit; parse_ptr += should_continue; } while (should_continue); if (!digits_usable) { // No actual number value available. if (endptr) *endptr = const_cast(str); return 0; } if (endptr) *endptr = parse_ptr; if (overflow) { errno = ERANGE; if (sign != Sign::Negative) { return LONG_LONG_MAX; } else { return LONG_LONG_MIN; } } return digits.number(); } unsigned long long strtoull(const char* str, char** endptr, int base) { // Parse spaces and sign char* parse_ptr = const_cast(str); strtons(parse_ptr, &parse_ptr); if (base == 16) { // Dr. POSIX: "If the value of base is 16, the characters 0x or 0X may optionally precede // the sequence of letters and digits, following the sign if present." if (*parse_ptr == '0') { if (tolower(*(parse_ptr + 1)) == 'x') parse_ptr += 2; } } // Parse base if (base == 0) { if (*parse_ptr == '0') { if (tolower(*(parse_ptr + 1)) == 'x') { base = 16; parse_ptr += 2; } else { base = 8; } } else { base = 10; } } // Parse actual digits. ULongLongParser digits { Sign::Positive, base }; bool digits_usable = false; bool should_continue = true; bool overflow = false; do { bool is_a_digit; if (overflow) { is_a_digit = digits.parse_digit(*parse_ptr) >= 0; } else { DigitConsumeDecision decision = digits.consume(*parse_ptr); switch (decision) { case DigitConsumeDecision::Consumed: is_a_digit = true; // The very first actual digit must pass here: digits_usable = true; break; case DigitConsumeDecision::PosOverflow: case DigitConsumeDecision::NegOverflow: is_a_digit = true; overflow = true; break; case DigitConsumeDecision::Invalid: is_a_digit = false; break; default: VERIFY_NOT_REACHED(); } } should_continue = is_a_digit; parse_ptr += should_continue; } while (should_continue); if (!digits_usable) { // No actual number value available. if (endptr) *endptr = const_cast(str); return 0; } if (endptr) *endptr = parse_ptr; if (overflow) { errno = ERANGE; return LONG_LONG_MAX; } return digits.number(); } // Serenity's PRNG is not cryptographically secure. Do not rely on this for // any real crypto! These functions (for now) are for compatibility. // TODO: In the future, rand can be made deterministic and this not. uint32_t arc4random(void) { uint32_t buf; syscall(SC_getrandom, &buf, sizeof(buf), 0); return buf; } void arc4random_buf(void* buffer, size_t buffer_size) { // arc4random_buf should never fail, but user supplied buffers could fail. // However, if the user passes a garbage buffer, that's on them. syscall(SC_getrandom, buffer, buffer_size, 0); } uint32_t arc4random_uniform(uint32_t max_bounds) { return AK::get_random_uniform(max_bounds); } char* realpath(const char* pathname, char* buffer) { if (!pathname) { errno = EFAULT; return nullptr; } size_t size = PATH_MAX; bool self_allocated = false; if (buffer == nullptr) { // Since we self-allocate, try to sneakily use a smaller buffer instead, in an attempt to use less memory. size = 64; buffer = (char*)malloc(size); self_allocated = true; } Syscall::SC_realpath_params params { { pathname, strlen(pathname) }, { buffer, size } }; int rc = syscall(SC_realpath, ¶ms); if (rc < 0) { if (self_allocated) free(buffer); errno = -rc; return nullptr; } if (self_allocated && static_cast(rc) > size) { // There was silent truncation, *and* we can simply retry without the caller noticing. free(buffer); size = static_cast(rc); buffer = (char*)malloc(size); params.buffer = { buffer, size }; rc = syscall(SC_realpath, ¶ms); if (rc < 0) { // Can only happen if we lose a race. Let's pretend we lost the race in the first place. free(buffer); errno = -rc; return nullptr; } size_t new_size = static_cast(rc); if (new_size < size) { // If we're here, the symlink has become longer while we were looking at it. // There's not much we can do, unless we want to loop endlessly // in this case. Let's leave it up to the caller whether to loop. free(buffer); errno = EAGAIN; return nullptr; } } errno = 0; return buffer; } int posix_openpt(int flags) { if (flags & ~(O_RDWR | O_NOCTTY | O_CLOEXEC)) { errno = EINVAL; return -1; } return open("/dev/ptmx", flags); } int grantpt([[maybe_unused]] int fd) { return 0; } int unlockpt([[maybe_unused]] int fd) { return 0; } } void _Exit(int status) { _exit(status); }