// Prototypes for various functions, mostly string utilities, that are used by most parts of fish. #ifndef FISH_COMMON_H #define FISH_COMMON_H #include "config.h" #include #include #include // IWYU pragma: keep #include #include #include #include #include #include #include #include #include #include #include #include "fallback.h" // IWYU pragma: keep #include "signal.h" // IWYU pragma: keep // Define a symbol we can use elsewhere in our code to determine if we're being built on MS Windows // under Cygwin. #if defined(_WIN32) || defined(_WIN64) || defined(WIN32) || defined(__CYGWIN__) || \ defined(__WIN32__) #define OS_IS_CYGWIN #endif // Common string type. typedef std::wstring wcstring; typedef std::vector wcstring_list_t; // Maximum number of bytes used by a single utf-8 character. #define MAX_UTF8_BYTES 6 // Highest legal ASCII value. #define ASCII_MAX 127u // Highest legal 16-bit Unicode value. #define UCS2_MAX 0xFFFFu // Highest legal byte value. #define BYTE_MAX 0xFFu // Unicode BOM value. #define UTF8_BOM_WCHAR 0xFEFFu // Unicode replacement character. #define REPLACEMENT_WCHAR 0xFFFDu // Use Unicode "noncharacters" for internal characters as much as we can. This // gives us 32 "characters" for internal use that we can guarantee should not // appear in our input stream. See http://www.unicode.org/faq/private_use.html. #define RESERVED_CHAR_BASE (wchar_t)0xFDD0 #define RESERVED_CHAR_END (wchar_t)0xFDF0 // Split the available noncharacter values into two ranges to ensure there are // no conflicts among the places we use these special characters. #define EXPAND_RESERVED_BASE RESERVED_CHAR_BASE #define EXPAND_RESERVED_END (EXPAND_RESERVED_BASE + 16) #define WILDCARD_RESERVED_BASE EXPAND_RESERVED_END #define WILDCARD_RESERVED_END (WILDCARD_RESERVED_BASE + 16) // Make sure the ranges defined above don't exceed the range for noncharacters. // This is to make sure we didn't do something stupid in subdividing the // Unicode range for our needs. //#if WILDCARD_RESERVED_END > RESERVED_CHAR_END //#error //#endif // These are in the Unicode private-use range. We really shouldn't use this // range but have little choice in the matter given how our lexer/parser works. // We can't use non-characters for these two ranges because there are only 66 of // them and we need at least 256 + 64. // // If sizeof(wchar_t))==4 we could avoid using private-use chars; however, that // would result in fish having different behavior on machines with 16 versus 32 // bit wchar_t. It's better that fish behave the same on both types of systems. // // Note: We don't use the highest 8 bit range (0xF800 - 0xF8FF) because we know // of at least one use of a codepoint in that range: the Apple symbol (0xF8FF) // on Mac OS X. See http://www.unicode.org/faq/private_use.html. #define ENCODE_DIRECT_BASE (wchar_t)0xF600 #define ENCODE_DIRECT_END (ENCODE_DIRECT_BASE + 256) #define INPUT_COMMON_BASE (wchar_t)0xF700 #define INPUT_COMMON_END (INPUT_COMMON_BASE + 64) // Flags for unescape_string functions. enum { UNESCAPE_DEFAULT = 0, // default behavior UNESCAPE_SPECIAL = 1 << 0, // escape special fish syntax characters like the semicolon UNESCAPE_INCOMPLETE = 1 << 1 // allow incomplete escape sequences }; typedef unsigned int unescape_flags_t; // Flags for the escape_string() and escape_string() functions. enum { /// Escape all characters, including magic characters like the semicolon. ESCAPE_ALL = 1 << 0, /// Do not try to use 'simplified' quoted escapes, and do not use empty quotes as the empty /// string. ESCAPE_NO_QUOTED = 1 << 1, /// Do not escape tildes. ESCAPE_NO_TILDE = 1 << 2 }; typedef unsigned int escape_flags_t; // Directions. enum selection_direction_t { // Visual directions. direction_north, direction_east, direction_south, direction_west, direction_page_north, direction_page_south, // Logical directions. direction_next, direction_prev, // Special value that means deselect. direction_deselect }; /// Issue a debug message with printf-style string formating and automatic line breaking. The string /// will begin with the string \c program_name, followed by a colon and a whitespace. /// /// Because debug is often called to tell the user about an error, before using wperror to give a /// specific error message, debug will never ever modify the value of errno. /// /// \param level the priority of the message. Lower number means higher priority. Messages with a /// priority_number higher than \c debug_level will be ignored.. /// \param msg the message format string. /// /// Example: /// /// debug( 1, L"Pi = %.3f", M_PI ); /// /// will print the string 'fish: Pi = 3.141', given that debug_level is 1 or higher, and that /// program_name is 'fish'. void __attribute__((noinline)) debug(int level, const char *msg, ...) __attribute__((format(printf, 2, 3))); void __attribute__((noinline)) debug(int level, const wchar_t *msg, ...); /// Exits without invoking destructors (via _exit), useful for code after fork. [[noreturn]] void exit_without_destructors(int code); /// Save the shell mode on startup so we can restore them on exit. extern struct termios shell_modes; /// The character to use where the text has been truncated. Is an ellipsis on unicode system and a $ /// on other systems. extern wchar_t ellipsis_char; /// Character representing an omitted newline at the end of text. extern wchar_t omitted_newline_char; /// The verbosity level of fish. If a call to debug has a severity level higher than \c debug_level, /// it will not be printed. extern int debug_level; /// How many stack frames to show when a debug() call is made. extern int debug_stack_frames; /// Profiling flag. True if commands should be profiled. extern bool g_profiling_active; /// Name of the current program. Should be set at startup. Used by the debug function. extern const wchar_t *program_name; // Variants of read() and write() that ignores return values, defeating a warning. void read_ignore(int fd, void *buff, size_t count); void write_ignore(int fd, const void *buff, size_t count); /// Set to false at run-time if it's been determined we can't trust the last modified timestamp on /// the tty. extern bool has_working_tty_timestamps; /// This macro is used to check that an argument is true. It is a bit like a non-fatal form of /// assert. Instead of exiting on failure, the current function is ended at once. The second /// parameter is the return value of the current function on failure. #define CHECK(arg, retval) \ if (!(arg)) { \ debug(0, "function %s called with false value for argument %s", __func__, #arg); \ bugreport(); \ show_stackframe(L'E'); \ return retval; \ } // Pause for input, then exit the program. If supported, print a backtrace first. // The `return` will never be run but silences oclint warnings. Especially when this is called // from within a `switch` block. As of the time I'm writing this oclint doesn't recognize the // `__attribute__((noreturn))` on the exit_without_destructors() function. // TODO: we use C++11 [[noreturn]] now, does that change things? #define FATAL_EXIT() \ { \ char exit_read_buff; \ show_stackframe(L'E'); \ read_ignore(0, &exit_read_buff, 1); \ exit_without_destructors(1); \ } /// Exit the program at once after emitting an error message and stack trace if possible. /// We use our own private implementation of `assert()` for two reasons. First, some implementations /// are subtly broken. For example, using `printf()` which can cause problems when mixed with wide /// stdio functions and should be writing the message to stderr rather than stdout. Second, if /// possible it is useful to provide additional context such as a stack backtrace. #undef assert #undef __assert //#define assert(e) do {(void)((e) ? ((void)0) : __assert(#e, __FILE__, __LINE__)); } while(false) #define assert(e) (e) ? ((void)0) : __assert(#e, __FILE__, __LINE__, 0) #define assert_with_errno(e) (e) ? ((void)0) : __assert(#e, __FILE__, __LINE__, errno) #define DIE(msg) __assert(msg, __FILE__, __LINE__, 0) #define DIE_WITH_ERRNO(msg) __assert(msg, __FILE__, __LINE__, errno) /// This macro is meant to be used with functions that return zero on success otherwise return an /// errno value. Most notably the pthread family of functions which we never expect to fail. #define DIE_ON_FAILURE(e) \ do { \ int status = e; \ if (status != 0) { \ __assert(#e, __FILE__, __LINE__, status); \ } \ } while (0) [[noreturn]] void __assert(const char *msg, const char *file, size_t line, int error); /// Check if signals are blocked. If so, print an error message and return from the function /// performing this check. #define CHECK_BLOCK(retval) #if 0 #define CHECK_BLOCK(retval) \ if (signal_is_blocked()) { \ debug(0, "function %s called while blocking signals. ", __func__); \ bugreport(); \ show_stackframe(L'E'); \ return retval; \ } #endif /// Shorthand for wgettext call in situations where a C-style string is needed (e.g., fwprintf()). #define _(wstr) wgettext(wstr).c_str() /// Noop, used to tell xgettext that a string should be translated. Use this when a string cannot be /// passed through wgettext() at the point where it is used. For example, when initializing a /// static array or structure. You must pass the string through wgettext() when it is used. /// See https://developer.gnome.org/glib/stable/glib-I18N.html#N-:CAPS #define N_(wstr) wstr /// Check if the specified string element is a part of the specified string list. #define contains(str, ...) contains_internal(str, 0, __VA_ARGS__, NULL) /// Print a stack trace to stderr. void show_stackframe(const wchar_t msg_level, int frame_count = 100, int skip_levels = 0); /// Read a line from the stream f into the string. Returns the number of bytes read or -1 on /// failure. /// /// If the carriage return character is encountered, it is ignored. fgetws() considers the line to /// end if reading the file results in either a newline (L'\n') character, the null (L'\\0') /// character or the end of file (WEOF) character. int fgetws2(wcstring *s, FILE *f); /// Returns a wide character string equivalent of the specified multibyte character string. /// /// This function encodes illegal character sequences in a reversible way using the private use /// area. wcstring str2wcstring(const char *in); wcstring str2wcstring(const char *in, size_t len); wcstring str2wcstring(const std::string &in); /// Returns a newly allocated multibyte character string equivalent of the specified wide character /// string. /// /// This function decodes illegal character sequences in a reversible way using the private use /// area. char *wcs2str(const wchar_t *in); char *wcs2str(const wcstring &in); std::string wcs2string(const wcstring &input); /// Test if a string prefixes another. Returns true if a is a prefix of b. bool string_prefixes_string(const wcstring &proposed_prefix, const wcstring &value); bool string_prefixes_string(const wchar_t *proposed_prefix, const wcstring &value); /// Test if a string is a suffix of another. bool string_suffixes_string(const wcstring &proposed_suffix, const wcstring &value); bool string_suffixes_string(const wchar_t *proposed_suffix, const wcstring &value); /// Test if a string prefixes another without regard to case. Returns true if a is a prefix of b. bool string_prefixes_string_case_insensitive(const wcstring &proposed_prefix, const wcstring &value); enum fuzzy_match_type_t { // We match the string exactly: FOOBAR matches FOOBAR. fuzzy_match_exact = 0, // We match a prefix of the string: FO matches FOOBAR. fuzzy_match_prefix, // We match the string exactly, but in a case insensitive way: foobar matches FOOBAR. fuzzy_match_case_insensitive, // We match a prefix of the string, in a case insensitive way: foo matches FOOBAR. fuzzy_match_prefix_case_insensitive, // We match a substring of the string: OOBA matches FOOBAR. fuzzy_match_substring, // A subsequence match with insertions only: FBR matches FOOBAR. fuzzy_match_subsequence_insertions_only, // We don't match the string. fuzzy_match_none }; /// Indicates where a match type requires replacing the entire token. static inline bool match_type_requires_full_replacement(fuzzy_match_type_t t) { switch (t) { case fuzzy_match_exact: case fuzzy_match_prefix: { return false; } default: { return true; } } } /// Indicates where a match shares a prefix with the string it matches. static inline bool match_type_shares_prefix(fuzzy_match_type_t t) { switch (t) { case fuzzy_match_exact: case fuzzy_match_prefix: case fuzzy_match_case_insensitive: case fuzzy_match_prefix_case_insensitive: { return true; } default: { return false; } } } /// Test if string is a fuzzy match to another. struct string_fuzzy_match_t { enum fuzzy_match_type_t type; // Strength of the match. The value depends on the type. Lower is stronger. size_t match_distance_first; size_t match_distance_second; // Constructor. explicit string_fuzzy_match_t(enum fuzzy_match_type_t t, size_t distance_first = 0, size_t distance_second = 0); // Return -1, 0, 1 if this match is (respectively) better than, equal to, or worse than rhs. int compare(const string_fuzzy_match_t &rhs) const; }; /// Compute a fuzzy match for a string. If maximum_match is not fuzzy_match_none, limit the type to /// matches at or below that type. string_fuzzy_match_t string_fuzzy_match_string(const wcstring &string, const wcstring &match_against, fuzzy_match_type_t limit_type = fuzzy_match_none); /// Test if a list contains a string using a linear search. bool list_contains_string(const wcstring_list_t &list, const wcstring &str); // Check if we are running in the test mode, where we should suppress error output #define TESTS_PROGRAM_NAME L"(ignore)" bool should_suppress_stderr_for_tests(); void assert_is_main_thread(const char *who); #define ASSERT_IS_MAIN_THREAD_TRAMPOLINE(x) assert_is_main_thread(x) #define ASSERT_IS_MAIN_THREAD() ASSERT_IS_MAIN_THREAD_TRAMPOLINE(__FUNCTION__) void assert_is_background_thread(const char *who); #define ASSERT_IS_BACKGROUND_THREAD_TRAMPOLINE(x) assert_is_background_thread(x) #define ASSERT_IS_BACKGROUND_THREAD() ASSERT_IS_BACKGROUND_THREAD_TRAMPOLINE(__FUNCTION__) /// Useful macro for asserting that a lock is locked. This doesn't check whether this thread locked /// it, which it would be nice if it did, but here it is anyways. void assert_is_locked(void *mutex, const char *who, const char *caller); #define ASSERT_IS_LOCKED(x) assert_is_locked((void *)(&x), #x, __FUNCTION__) /// Format the specified size (in bytes, kilobytes, etc.) into the specified stringbuffer. wcstring format_size(long long sz); /// Version of format_size that does not allocate memory. void format_size_safe(char buff[128], unsigned long long sz); /// Our crappier versions of debug which is guaranteed to not allocate any memory, or do anything /// other than call write(). This is useful after a call to fork() with threads. void debug_safe(int level, const char *msg, const char *param1 = NULL, const char *param2 = NULL, const char *param3 = NULL, const char *param4 = NULL, const char *param5 = NULL, const char *param6 = NULL, const char *param7 = NULL, const char *param8 = NULL, const char *param9 = NULL, const char *param10 = NULL, const char *param11 = NULL, const char *param12 = NULL); /// Writes out a long safely. void format_long_safe(char buff[64], long val); void format_long_safe(wchar_t buff[64], long val); /// "Narrows" a wide character string. This just grabs any ASCII characters and trunactes. void narrow_string_safe(char buff[64], const wchar_t *s); template T from_string(const wcstring &x) { T result; std::wstringstream stream(x); stream >> result; return result; } template T from_string(const std::string &x) { T result = T(); std::stringstream stream(x); stream >> result; return result; } template wcstring to_string(const T &x) { std::wstringstream stream; stream << x; return stream.str(); } // wstringstream is a huge memory pig. Let's provide some specializations where we can. template <> inline wcstring to_string(const long &x) { wchar_t buff[128]; format_long_safe(buff, x); return wcstring(buff); } template <> inline bool from_string(const std::string &x) { return !x.empty() && strchr("YTyt1", x.at(0)); } template <> inline bool from_string(const wcstring &x) { return !x.empty() && wcschr(L"YTyt1", x.at(0)); } template <> inline wcstring to_string(const int &x) { return to_string(static_cast(x)); } wchar_t **make_null_terminated_array(const wcstring_list_t &lst); char **make_null_terminated_array(const std::vector &lst); // Helper class for managing a null-terminated array of null-terminated strings (of some char type). template class null_terminated_array_t { CharType_t **array; // No assignment or copying. void operator=(null_terminated_array_t rhs); null_terminated_array_t(const null_terminated_array_t &); typedef std::vector > string_list_t; size_t size() const { size_t len = 0; if (array != NULL) { while (array[len] != NULL) { len++; } } return len; } void free(void) { ::free((void *)array); array = NULL; } public: null_terminated_array_t() : array(NULL) {} explicit null_terminated_array_t(const string_list_t &argv) : array(make_null_terminated_array(argv)) {} ~null_terminated_array_t() { this->free(); } void set(const string_list_t &argv) { this->free(); this->array = make_null_terminated_array(argv); } const CharType_t *const *get() const { return array; } void clear() { this->free(); } }; // Helper function to convert from a null_terminated_array_t to a // null_terminated_array_t. void convert_wide_array_to_narrow(const null_terminated_array_t &arr, null_terminated_array_t *output); class mutex_lock_t { public: pthread_mutex_t mutex; mutex_lock_t() { DIE_ON_FAILURE(pthread_mutex_init(&mutex, NULL)); } ~mutex_lock_t() { DIE_ON_FAILURE(pthread_mutex_destroy(&mutex)); } }; // Basic scoped lock class. class scoped_lock { pthread_mutex_t *lock_obj; bool locked; // No copying. scoped_lock &operator=(const scoped_lock &) = delete; scoped_lock(const scoped_lock &) = delete; public: scoped_lock(scoped_lock &&rhs) : lock_obj(rhs.lock_obj), locked(rhs.locked) { // we acquire any locked state // ensure the rhs doesn't try to unlock rhs.locked = false; } void lock(void); void unlock(void); explicit scoped_lock(pthread_mutex_t &mutex); explicit scoped_lock(mutex_lock_t &lock); ~scoped_lock(); }; class rwlock_t { public: pthread_rwlock_t rwlock; rwlock_t() { DIE_ON_FAILURE(pthread_rwlock_init(&rwlock, NULL)); } ~rwlock_t() { DIE_ON_FAILURE(pthread_rwlock_destroy(&rwlock)); } rwlock_t &operator=(const rwlock_t &) = delete; rwlock_t(const rwlock_t &) = delete; }; // Scoped lock class for rwlocks. class scoped_rwlock { pthread_rwlock_t *rwlock_obj; bool locked; bool locked_shared; // No copying. scoped_rwlock &operator=(const scoped_lock &) = delete; explicit scoped_rwlock(const scoped_lock &) = delete; public: void lock(void); void unlock(void); void lock_shared(void); void unlock_shared(void); // Upgrade shared lock to exclusive. Equivalent to `lock.unlock_shared(); lock.lock();`. void upgrade(void); explicit scoped_rwlock(pthread_rwlock_t &rwlock, bool shared = false); explicit scoped_rwlock(rwlock_t &rwlock, bool shared = false); ~scoped_rwlock(); }; // An object wrapping a scoped lock and a value // This is returned from owning_lock.acquire() // Sample usage: // owning_lock locked_name; // acquired_lock name = name.acquire(); // name.value = "derp" // // Or for simple cases: // name.acquire().value = "derp" // template class acquired_lock { scoped_lock lock; acquired_lock(mutex_lock_t &lk, DATA *v) : lock(lk), value(*v) {} template friend class owning_lock; public: // No copying, move only acquired_lock &operator=(const acquired_lock &) = delete; acquired_lock(const acquired_lock &) = delete; acquired_lock(acquired_lock &&) = default; acquired_lock &operator=(acquired_lock &&) = default; DATA &value; }; // A lock that owns a piece of data // Access to the data is only provided by taking the lock template class owning_lock { // No copying owning_lock &operator=(const scoped_lock &) = delete; owning_lock(const scoped_lock &) = delete; owning_lock(owning_lock &&) = default; owning_lock &operator=(owning_lock &&) = default; mutex_lock_t lock; DATA data; public: owning_lock(DATA &&d) : data(std::move(d)) {} owning_lock() : data() {} acquired_lock acquire() { return {lock, &data}; } }; /// A scoped manager to save the current value of some variable, and optionally set it to a new /// value. On destruction it restores the variable to its old value. /// /// This can be handy when there are multiple code paths to exit a block. template class scoped_push { T *const ref; T saved_value; bool restored; public: explicit scoped_push(T *r) : ref(r), saved_value(*r), restored(false) {} scoped_push(T *r, T new_value) : ref(r), restored(false) { saved_value = std::move(*ref); *ref = std::move(new_value); } ~scoped_push() { restore(); } void restore() { if (!restored) { *ref = std::move(saved_value); restored = true; } } }; /// Wrapper around wcstok. class wcstokenizer { wchar_t *buffer, *str, *state; const wcstring sep; // No copying. wcstokenizer &operator=(const wcstokenizer &); wcstokenizer(const wcstokenizer &); public: wcstokenizer(const wcstring &s, const wcstring &separator); bool next(wcstring &result); ~wcstokenizer(); }; /// Appends a path component, with a / if necessary. void append_path_component(wcstring &path, const wcstring &component); wcstring format_string(const wchar_t *format, ...); wcstring vformat_string(const wchar_t *format, va_list va_orig); void append_format(wcstring &str, const wchar_t *format, ...); void append_formatv(wcstring &str, const wchar_t *format, va_list ap); #ifdef __cpp_lib_make_unique using std::make_unique; #else /// make_unique implementation template std::unique_ptr make_unique(Args &&... args) { return std::unique_ptr(new T(std::forward(args)...)); } #endif /// This functions returns the end of the quoted substring beginning at \c in. The type of quoting /// character is detemrined by examining \c in. Returns 0 on error. /// /// \param in the position of the opening quote. wchar_t *quote_end(const wchar_t *in); /// A call to this function will reset the error counter. Some functions print out non-critical /// error messages. These should check the error_count before, and skip printing the message if /// MAX_ERROR_COUNT messages have been printed. The error_reset() should be called after each /// interactive command executes, to allow new messages to be printed. void error_reset(); /// This function should be called after calling `setlocale()` to perform fish specific locale /// initialization. void fish_setlocale(); /// Checks if \c needle is included in the list of strings specified. A warning is printed if needle /// is zero. /// /// \param needle the string to search for in the list. /// /// \return zero if needle is not found, of if needle is null, non-zero otherwise. __sentinel bool contains_internal(const wchar_t *needle, int vararg_handle, ...); __sentinel bool contains_internal(const wcstring &needle, int vararg_handle, ...); /// Call read while blocking the SIGCHLD signal. Should only be called if you _know_ there is data /// available for reading, or the program will hang until there is data. long read_blocked(int fd, void *buf, size_t count); /// Loop a write request while failure is non-critical. Return -1 and set errno in case of critical /// error. ssize_t write_loop(int fd, const char *buff, size_t count); /// Loop a read request while failure is non-critical. Return -1 and set errno in case of critical /// error. ssize_t read_loop(int fd, void *buff, size_t count); /// Replace special characters with backslash escape sequences. Newline is replaced with \n, etc. /// /// \param in The string to be escaped /// \param flags Flags to control the escaping /// \return The escaped string wcstring escape_string(const wchar_t *in, escape_flags_t flags); wcstring escape_string(const wcstring &in, escape_flags_t flags); /// Expand backslashed escapes and substitute them with their unescaped counterparts. Also /// optionally change the wildcards, the tilde character and a few more into constants which are /// defined in a private use area of Unicode. This assumes wchar_t is a unicode character set. /// Given a null terminated string starting with a backslash, read the escape as if it is unquoted, /// appending to result. Return the number of characters consumed, or 0 on error. size_t read_unquoted_escape(const wchar_t *input, wcstring *result, bool allow_incomplete, bool unescape_special); /// Unescapes a string in-place. A true result indicates the string was unescaped, a false result /// indicates the string was unmodified. bool unescape_string_in_place(wcstring *str, unescape_flags_t escape_special); /// Unescapes a string, returning the unescaped value by reference. On failure, the output is set to /// an empty string. bool unescape_string(const wchar_t *input, wcstring *output, unescape_flags_t escape_special); bool unescape_string(const wcstring &input, wcstring *output, unescape_flags_t escape_special); /// Returns the width of the terminal window, so that not all functions that use these values /// continually have to keep track of it separately. /// /// Only works if common_handle_winch is registered to handle winch signals. int common_get_width(); /// Returns the height of the terminal window, so that not all functions that use these values /// continually have to keep track of it separatly. /// /// Only works if common_handle_winch is registered to handle winch signals. int common_get_height(); /// Handle a window change event by looking up the new window size and saving it in an internal /// variable used by common_get_wisth and common_get_height(). void common_handle_winch(int signal); /// Write the given paragraph of output, redoing linebreaks to fit the current screen. wcstring reformat_for_screen(const wcstring &msg); /// Tokenize the specified string into the specified wcstring_list_t. /// /// \param val the input string. The contents of this string is not changed. /// \param out the list in which to place the elements. void tokenize_variable_array(const wcstring &val, wcstring_list_t &out); /// Make sure the specified direcotry exists. If needed, try to create it and any currently not /// existing parent directories. /// /// \return 0 if, at the time of function return the directory exists, -1 otherwise. int create_directory(const wcstring &d); /// Print a short message about how to file a bug report to stderr. void bugreport(); /// Return the number of seconds from the UNIX epoch, with subsecond precision. This function uses /// the gettimeofday function and will have the same precision as that function. double timef(); /// Call the following function early in main to set the main thread. This is our replacement for /// pthread_main_np(). void set_main_thread(); bool is_main_thread(); /// Configures thread assertions for testing. void configure_thread_assertions_for_testing(); /// Set up a guard to complain if we try to do certain things (like take a lock) after calling fork. void setup_fork_guards(void); /// Save the value of tcgetpgrp so we can restore it on exit. void save_term_foreground_process_group(void); void restore_term_foreground_process_group(void); /// Return whether we are the child of a fork. bool is_forked_child(void); void assert_is_not_forked_child(const char *who); #define ASSERT_IS_NOT_FORKED_CHILD_TRAMPOLINE(x) assert_is_not_forked_child(x) #define ASSERT_IS_NOT_FORKED_CHILD() ASSERT_IS_NOT_FORKED_CHILD_TRAMPOLINE(__FUNCTION__) extern "C" { __attribute__((noinline)) void debug_thread_error(void); } /// Converts from wide char to digit in the specified base. If d is not a valid digit in the /// specified base, return -1. long convert_digit(wchar_t d, int base); /// This is a macro that can be used to silence "unused parameter" warnings from the compiler for /// functions which need to accept parameters they do not use because they need to be compatible /// with an interface. It's similar to the Python idiom of doing `_ = expr` at the top of a /// function in the same situation. #define UNUSED(expr) \ do { \ (void)(expr); \ } while (0) // Return true if the character is in a range reserved for fish's private use. bool fish_reserved_codepoint(wchar_t c); /// Used for constructing mappings between enums and strings. The resulting array must be sorted /// according to the `str` member since str_to_enum() does a binary search. Also the last entry must /// have NULL for the `str` member and the default value for `val` to be returned if the string /// isn't found. template struct enum_map { T val; const wchar_t *const str; }; /// Given a string return the matching enum. Return the sentinal enum if no match is made. The map /// must be sorted by the `str` member. A binary search is twice as fast as a linear search with 16 /// elements in the map. template static T str_to_enum(const wchar_t *name, const enum_map map[], int len) { // Ignore the sentinel value when searching as it is the "not found" value. size_t left = 0, right = len - 1; while (left < right) { size_t mid = left + (right - left) / 2; int cmp = wcscmp(name, map[mid].str); if (cmp < 0) { right = mid; // name was smaller than mid } else if (cmp > 0) { left = mid + 1; // name was larger than mid } else { return map[mid].val; // found it } } return map[len - 1].val; // return the sentinel value } /// Given an enum return the matching string. template static const wchar_t *enum_to_str(T enum_val, const enum_map map[]) { for (const enum_map *entry = map; entry->str; entry++) { if (enum_val == entry->val) { return entry->str; } } return NULL; }; void redirect_tty_output(); // Minimum allowed terminal size and default size if the detected size is not reasonable. #define MIN_TERM_COL 20 #define MIN_TERM_ROW 2 #define DFLT_TERM_COL 80 #define DFLT_TERM_ROW 24 #define DFLT_TERM_COL_STR L"80" #define DFLT_TERM_ROW_STR L"24" void invalidate_termsize(bool invalidate_vars = false); struct winsize get_current_winsize(); #endif