strbuf.hon commit Merge branch 'js/t0001-case-insensitive' into maint (dc55e3e)
   1#ifndef STRBUF_H
   2#define STRBUF_H
   3
   4struct string_list;
   5
   6/**
   7 * strbuf's are meant to be used with all the usual C string and memory
   8 * APIs. Given that the length of the buffer is known, it's often better to
   9 * use the mem* functions than a str* one (memchr vs. strchr e.g.).
  10 * Though, one has to be careful about the fact that str* functions often
  11 * stop on NULs and that strbufs may have embedded NULs.
  12 *
  13 * A strbuf is NUL terminated for convenience, but no function in the
  14 * strbuf API actually relies on the string being free of NULs.
  15 *
  16 * strbufs have some invariants that are very important to keep in mind:
  17 *
  18 *  - The `buf` member is never NULL, so it can be used in any usual C
  19 *    string operations safely. strbuf's _have_ to be initialized either by
  20 *    `strbuf_init()` or by `= STRBUF_INIT` before the invariants, though.
  21 *
  22 *    Do *not* assume anything on what `buf` really is (e.g. if it is
  23 *    allocated memory or not), use `strbuf_detach()` to unwrap a memory
  24 *    buffer from its strbuf shell in a safe way. That is the sole supported
  25 *    way. This will give you a malloced buffer that you can later `free()`.
  26 *
  27 *    However, it is totally safe to modify anything in the string pointed by
  28 *    the `buf` member, between the indices `0` and `len-1` (inclusive).
  29 *
  30 *  - The `buf` member is a byte array that has at least `len + 1` bytes
  31 *    allocated. The extra byte is used to store a `'\0'`, allowing the
  32 *    `buf` member to be a valid C-string. Every strbuf function ensure this
  33 *    invariant is preserved.
  34 *
  35 *    NOTE: It is OK to "play" with the buffer directly if you work it this
  36 *    way:
  37 *
  38 *        strbuf_grow(sb, SOME_SIZE); <1>
  39 *        strbuf_setlen(sb, sb->len + SOME_OTHER_SIZE);
  40 *
  41 *    <1> Here, the memory array starting at `sb->buf`, and of length
  42 *    `strbuf_avail(sb)` is all yours, and you can be sure that
  43 *    `strbuf_avail(sb)` is at least `SOME_SIZE`.
  44 *
  45 *    NOTE: `SOME_OTHER_SIZE` must be smaller or equal to `strbuf_avail(sb)`.
  46 *
  47 *    Doing so is safe, though if it has to be done in many places, adding the
  48 *    missing API to the strbuf module is the way to go.
  49 *
  50 *    WARNING: Do _not_ assume that the area that is yours is of size `alloc
  51 *    - 1` even if it's true in the current implementation. Alloc is somehow a
  52 *    "private" member that should not be messed with. Use `strbuf_avail()`
  53 *    instead.
  54*/
  55
  56/**
  57 * Data Structures
  58 * ---------------
  59 */
  60
  61/**
  62 * This is the string buffer structure. The `len` member can be used to
  63 * determine the current length of the string, and `buf` member provides
  64 * access to the string itself.
  65 */
  66struct strbuf {
  67        size_t alloc;
  68        size_t len;
  69        char *buf;
  70};
  71
  72extern char strbuf_slopbuf[];
  73#define STRBUF_INIT  { .alloc = 0, .len = 0, .buf = strbuf_slopbuf }
  74
  75/*
  76 * Predeclare this here, since cache.h includes this file before it defines the
  77 * struct.
  78 */
  79struct object_id;
  80
  81/**
  82 * Life Cycle Functions
  83 * --------------------
  84 */
  85
  86/**
  87 * Initialize the structure. The second parameter can be zero or a bigger
  88 * number to allocate memory, in case you want to prevent further reallocs.
  89 */
  90void strbuf_init(struct strbuf *sb, size_t alloc);
  91
  92/**
  93 * Release a string buffer and the memory it used. After this call, the
  94 * strbuf points to an empty string that does not need to be free()ed, as
  95 * if it had been set to `STRBUF_INIT` and never modified.
  96 *
  97 * To clear a strbuf in preparation for further use without the overhead
  98 * of free()ing and malloc()ing again, use strbuf_reset() instead.
  99 */
 100void strbuf_release(struct strbuf *sb);
 101
 102/**
 103 * Detach the string from the strbuf and returns it; you now own the
 104 * storage the string occupies and it is your responsibility from then on
 105 * to release it with `free(3)` when you are done with it.
 106 *
 107 * The strbuf that previously held the string is reset to `STRBUF_INIT` so
 108 * it can be reused after calling this function.
 109 */
 110char *strbuf_detach(struct strbuf *sb, size_t *sz);
 111
 112/**
 113 * Attach a string to a buffer. You should specify the string to attach,
 114 * the current length of the string and the amount of allocated memory.
 115 * The amount must be larger than the string length, because the string you
 116 * pass is supposed to be a NUL-terminated string.  This string _must_ be
 117 * malloc()ed, and after attaching, the pointer cannot be relied upon
 118 * anymore, and neither be free()d directly.
 119 */
 120void strbuf_attach(struct strbuf *sb, void *str, size_t len, size_t mem);
 121
 122/**
 123 * Swap the contents of two string buffers.
 124 */
 125static inline void strbuf_swap(struct strbuf *a, struct strbuf *b)
 126{
 127        SWAP(*a, *b);
 128}
 129
 130
 131/**
 132 * Functions related to the size of the buffer
 133 * -------------------------------------------
 134 */
 135
 136/**
 137 * Determine the amount of allocated but unused memory.
 138 */
 139static inline size_t strbuf_avail(const struct strbuf *sb)
 140{
 141        return sb->alloc ? sb->alloc - sb->len - 1 : 0;
 142}
 143
 144/**
 145 * Ensure that at least this amount of unused memory is available after
 146 * `len`. This is used when you know a typical size for what you will add
 147 * and want to avoid repetitive automatic resizing of the underlying buffer.
 148 * This is never a needed operation, but can be critical for performance in
 149 * some cases.
 150 */
 151void strbuf_grow(struct strbuf *sb, size_t amount);
 152
 153/**
 154 * Set the length of the buffer to a given value. This function does *not*
 155 * allocate new memory, so you should not perform a `strbuf_setlen()` to a
 156 * length that is larger than `len + strbuf_avail()`. `strbuf_setlen()` is
 157 * just meant as a 'please fix invariants from this strbuf I just messed
 158 * with'.
 159 */
 160static inline void strbuf_setlen(struct strbuf *sb, size_t len)
 161{
 162        if (len > (sb->alloc ? sb->alloc - 1 : 0))
 163                die("BUG: strbuf_setlen() beyond buffer");
 164        sb->len = len;
 165        if (sb->buf != strbuf_slopbuf)
 166                sb->buf[len] = '\0';
 167        else
 168                assert(!strbuf_slopbuf[0]);
 169}
 170
 171/**
 172 * Empty the buffer by setting the size of it to zero.
 173 */
 174#define strbuf_reset(sb)  strbuf_setlen(sb, 0)
 175
 176
 177/**
 178 * Functions related to the contents of the buffer
 179 * -----------------------------------------------
 180 */
 181
 182/**
 183 * Strip whitespace from the beginning (`ltrim`), end (`rtrim`), or both side
 184 * (`trim`) of a string.
 185 */
 186void strbuf_trim(struct strbuf *sb);
 187void strbuf_rtrim(struct strbuf *sb);
 188void strbuf_ltrim(struct strbuf *sb);
 189
 190/* Strip trailing directory separators */
 191void strbuf_trim_trailing_dir_sep(struct strbuf *sb);
 192
 193/* Strip trailing LF or CR/LF */
 194void strbuf_trim_trailing_newline(struct strbuf *sb);
 195
 196/**
 197 * Replace the contents of the strbuf with a reencoded form.  Returns -1
 198 * on error, 0 on success.
 199 */
 200int strbuf_reencode(struct strbuf *sb, const char *from, const char *to);
 201
 202/**
 203 * Lowercase each character in the buffer using `tolower`.
 204 */
 205void strbuf_tolower(struct strbuf *sb);
 206
 207/**
 208 * Compare two buffers. Returns an integer less than, equal to, or greater
 209 * than zero if the first buffer is found, respectively, to be less than,
 210 * to match, or be greater than the second buffer.
 211 */
 212int strbuf_cmp(const struct strbuf *first, const struct strbuf *second);
 213
 214
 215/**
 216 * Adding data to the buffer
 217 * -------------------------
 218 *
 219 * NOTE: All of the functions in this section will grow the buffer as
 220 * necessary.  If they fail for some reason other than memory shortage and the
 221 * buffer hadn't been allocated before (i.e. the `struct strbuf` was set to
 222 * `STRBUF_INIT`), then they will free() it.
 223 */
 224
 225/**
 226 * Add a single character to the buffer.
 227 */
 228static inline void strbuf_addch(struct strbuf *sb, int c)
 229{
 230        if (!strbuf_avail(sb))
 231                strbuf_grow(sb, 1);
 232        sb->buf[sb->len++] = c;
 233        sb->buf[sb->len] = '\0';
 234}
 235
 236/**
 237 * Add a character the specified number of times to the buffer.
 238 */
 239void strbuf_addchars(struct strbuf *sb, int c, size_t n);
 240
 241/**
 242 * Insert data to the given position of the buffer. The remaining contents
 243 * will be shifted, not overwritten.
 244 */
 245void strbuf_insert(struct strbuf *sb, size_t pos, const void *, size_t);
 246
 247/**
 248 * Insert data to the given position of the buffer giving a printf format
 249 * string. The contents will be shifted, not overwritten.
 250 */
 251void strbuf_vinsertf(struct strbuf *sb, size_t pos, const char *fmt,
 252                     va_list ap);
 253
 254void strbuf_insertf(struct strbuf *sb, size_t pos, const char *fmt, ...);
 255
 256/**
 257 * Remove given amount of data from a given position of the buffer.
 258 */
 259void strbuf_remove(struct strbuf *sb, size_t pos, size_t len);
 260
 261/**
 262 * Remove the bytes between `pos..pos+len` and replace it with the given
 263 * data.
 264 */
 265void strbuf_splice(struct strbuf *sb, size_t pos, size_t len,
 266                   const void *data, size_t data_len);
 267
 268/**
 269 * Add a NUL-terminated string to the buffer. Each line will be prepended
 270 * by a comment character and a blank.
 271 */
 272void strbuf_add_commented_lines(struct strbuf *out,
 273                                const char *buf, size_t size);
 274
 275
 276/**
 277 * Add data of given length to the buffer.
 278 */
 279void strbuf_add(struct strbuf *sb, const void *data, size_t len);
 280
 281/**
 282 * Add a NUL-terminated string to the buffer.
 283 *
 284 * NOTE: This function will *always* be implemented as an inline or a macro
 285 * using strlen, meaning that this is efficient to write things like:
 286 *
 287 *     strbuf_addstr(sb, "immediate string");
 288 *
 289 */
 290static inline void strbuf_addstr(struct strbuf *sb, const char *s)
 291{
 292        strbuf_add(sb, s, strlen(s));
 293}
 294
 295/**
 296 * Copy the contents of another buffer at the end of the current one.
 297 */
 298void strbuf_addbuf(struct strbuf *sb, const struct strbuf *sb2);
 299
 300/**
 301 * Join the arguments into a buffer. `delim` is put between every
 302 * two arguments.
 303 */
 304const char *strbuf_join_argv(struct strbuf *buf, int argc,
 305                             const char **argv, char delim);
 306
 307/**
 308 * This function can be used to expand a format string containing
 309 * placeholders. To that end, it parses the string and calls the specified
 310 * function for every percent sign found.
 311 *
 312 * The callback function is given a pointer to the character after the `%`
 313 * and a pointer to the struct strbuf.  It is expected to add the expanded
 314 * version of the placeholder to the strbuf, e.g. to add a newline
 315 * character if the letter `n` appears after a `%`.  The function returns
 316 * the length of the placeholder recognized and `strbuf_expand()` skips
 317 * over it.
 318 *
 319 * The format `%%` is automatically expanded to a single `%` as a quoting
 320 * mechanism; callers do not need to handle the `%` placeholder themselves,
 321 * and the callback function will not be invoked for this placeholder.
 322 *
 323 * All other characters (non-percent and not skipped ones) are copied
 324 * verbatim to the strbuf.  If the callback returned zero, meaning that the
 325 * placeholder is unknown, then the percent sign is copied, too.
 326 *
 327 * In order to facilitate caching and to make it possible to give
 328 * parameters to the callback, `strbuf_expand()` passes a context pointer,
 329 * which can be used by the programmer of the callback as she sees fit.
 330 */
 331typedef size_t (*expand_fn_t) (struct strbuf *sb,
 332                               const char *placeholder,
 333                               void *context);
 334void strbuf_expand(struct strbuf *sb,
 335                   const char *format,
 336                   expand_fn_t fn,
 337                   void *context);
 338
 339/**
 340 * Used as callback for `strbuf_expand` to only expand literals
 341 * (i.e. %n and %xNN). The context argument is ignored.
 342 */
 343size_t strbuf_expand_literal_cb(struct strbuf *sb,
 344                                const char *placeholder,
 345                                void *context);
 346
 347/**
 348 * Used as callback for `strbuf_expand()`, expects an array of
 349 * struct strbuf_expand_dict_entry as context, i.e. pairs of
 350 * placeholder and replacement string.  The array needs to be
 351 * terminated by an entry with placeholder set to NULL.
 352 */
 353struct strbuf_expand_dict_entry {
 354        const char *placeholder;
 355        const char *value;
 356};
 357size_t strbuf_expand_dict_cb(struct strbuf *sb,
 358                             const char *placeholder,
 359                             void *context);
 360
 361/**
 362 * Append the contents of one strbuf to another, quoting any
 363 * percent signs ("%") into double-percents ("%%") in the
 364 * destination. This is useful for literal data to be fed to either
 365 * strbuf_expand or to the *printf family of functions.
 366 */
 367void strbuf_addbuf_percentquote(struct strbuf *dst, const struct strbuf *src);
 368
 369/**
 370 * Append the given byte size as a human-readable string (i.e. 12.23 KiB,
 371 * 3.50 MiB).
 372 */
 373void strbuf_humanise_bytes(struct strbuf *buf, off_t bytes);
 374
 375/**
 376 * Add a formatted string to the buffer.
 377 */
 378__attribute__((format (printf,2,3)))
 379void strbuf_addf(struct strbuf *sb, const char *fmt, ...);
 380
 381/**
 382 * Add a formatted string prepended by a comment character and a
 383 * blank to the buffer.
 384 */
 385__attribute__((format (printf, 2, 3)))
 386void strbuf_commented_addf(struct strbuf *sb, const char *fmt, ...);
 387
 388__attribute__((format (printf,2,0)))
 389void strbuf_vaddf(struct strbuf *sb, const char *fmt, va_list ap);
 390
 391/**
 392 * Add the time specified by `tm`, as formatted by `strftime`.
 393 * `tz_offset` is in decimal hhmm format, e.g. -600 means six hours west
 394 * of Greenwich, and it's used to expand %z internally.  However, tokens
 395 * with modifiers (e.g. %Ez) are passed to `strftime`.
 396 * `suppress_tz_name`, when set, expands %Z internally to the empty
 397 * string rather than passing it to `strftime`.
 398 */
 399void strbuf_addftime(struct strbuf *sb, const char *fmt,
 400                    const struct tm *tm, int tz_offset,
 401                    int suppress_tz_name);
 402
 403/**
 404 * Read a given size of data from a FILE* pointer to the buffer.
 405 *
 406 * NOTE: The buffer is rewound if the read fails. If -1 is returned,
 407 * `errno` must be consulted, like you would do for `read(3)`.
 408 * `strbuf_read()`, `strbuf_read_file()` and `strbuf_getline_*()`
 409 * family of functions have the same behaviour as well.
 410 */
 411size_t strbuf_fread(struct strbuf *sb, size_t size, FILE *file);
 412
 413/**
 414 * Read the contents of a given file descriptor. The third argument can be
 415 * used to give a hint about the file size, to avoid reallocs.  If read fails,
 416 * any partial read is undone.
 417 */
 418ssize_t strbuf_read(struct strbuf *sb, int fd, size_t hint);
 419
 420/**
 421 * Read the contents of a given file descriptor partially by using only one
 422 * attempt of xread. The third argument can be used to give a hint about the
 423 * file size, to avoid reallocs. Returns the number of new bytes appended to
 424 * the sb.
 425 */
 426ssize_t strbuf_read_once(struct strbuf *sb, int fd, size_t hint);
 427
 428/**
 429 * Read the contents of a file, specified by its path. The third argument
 430 * can be used to give a hint about the file size, to avoid reallocs.
 431 * Return the number of bytes read or a negative value if some error
 432 * occurred while opening or reading the file.
 433 */
 434ssize_t strbuf_read_file(struct strbuf *sb, const char *path, size_t hint);
 435
 436/**
 437 * Read the target of a symbolic link, specified by its path.  The third
 438 * argument can be used to give a hint about the size, to avoid reallocs.
 439 */
 440int strbuf_readlink(struct strbuf *sb, const char *path, size_t hint);
 441
 442/**
 443 * Write the whole content of the strbuf to the stream not stopping at
 444 * NUL bytes.
 445 */
 446ssize_t strbuf_write(struct strbuf *sb, FILE *stream);
 447
 448/**
 449 * Read a line from a FILE *, overwriting the existing contents of
 450 * the strbuf.  The strbuf_getline*() family of functions share
 451 * this signature, but have different line termination conventions.
 452 *
 453 * Reading stops after the terminator or at EOF.  The terminator
 454 * is removed from the buffer before returning.  Returns 0 unless
 455 * there was nothing left before EOF, in which case it returns `EOF`.
 456 */
 457typedef int (*strbuf_getline_fn)(struct strbuf *, FILE *);
 458
 459/* Uses LF as the line terminator */
 460int strbuf_getline_lf(struct strbuf *sb, FILE *fp);
 461
 462/* Uses NUL as the line terminator */
 463int strbuf_getline_nul(struct strbuf *sb, FILE *fp);
 464
 465/*
 466 * Similar to strbuf_getline_lf(), but additionally treats a CR that
 467 * comes immediately before the LF as part of the terminator.
 468 * This is the most friendly version to be used to read "text" files
 469 * that can come from platforms whose native text format is CRLF
 470 * terminated.
 471 */
 472int strbuf_getline(struct strbuf *sb, FILE *file);
 473
 474
 475/**
 476 * Like `strbuf_getline`, but keeps the trailing terminator (if
 477 * any) in the buffer.
 478 */
 479int strbuf_getwholeline(struct strbuf *sb, FILE *file, int term);
 480
 481/**
 482 * Like `strbuf_getwholeline`, but operates on a file descriptor.
 483 * It reads one character at a time, so it is very slow.  Do not
 484 * use it unless you need the correct position in the file
 485 * descriptor.
 486 */
 487int strbuf_getwholeline_fd(struct strbuf *sb, int fd, int term);
 488
 489/**
 490 * Set the buffer to the path of the current working directory.
 491 */
 492int strbuf_getcwd(struct strbuf *sb);
 493
 494/**
 495 * Add a path to a buffer, converting a relative path to an
 496 * absolute one in the process.  Symbolic links are not
 497 * resolved.
 498 */
 499void strbuf_add_absolute_path(struct strbuf *sb, const char *path);
 500
 501/**
 502 * Canonize `path` (make it absolute, resolve symlinks, remove extra
 503 * slashes) and append it to `sb`.  Die with an informative error
 504 * message if there is a problem.
 505 *
 506 * The directory part of `path` (i.e., everything up to the last
 507 * dir_sep) must denote a valid, existing directory, but the last
 508 * component need not exist.
 509 *
 510 * Callers that don't mind links should use the more lightweight
 511 * strbuf_add_absolute_path() instead.
 512 */
 513void strbuf_add_real_path(struct strbuf *sb, const char *path);
 514
 515
 516/**
 517 * Normalize in-place the path contained in the strbuf. See
 518 * normalize_path_copy() for details. If an error occurs, the contents of "sb"
 519 * are left untouched, and -1 is returned.
 520 */
 521int strbuf_normalize_path(struct strbuf *sb);
 522
 523/**
 524 * Strip whitespace from a buffer. The second parameter controls if
 525 * comments are considered contents to be removed or not.
 526 */
 527void strbuf_stripspace(struct strbuf *buf, int skip_comments);
 528
 529static inline int strbuf_strip_suffix(struct strbuf *sb, const char *suffix)
 530{
 531        if (strip_suffix_mem(sb->buf, &sb->len, suffix)) {
 532                strbuf_setlen(sb, sb->len);
 533                return 1;
 534        } else
 535                return 0;
 536}
 537
 538/**
 539 * Split str (of length slen) at the specified terminator character.
 540 * Return a null-terminated array of pointers to strbuf objects
 541 * holding the substrings.  The substrings include the terminator,
 542 * except for the last substring, which might be unterminated if the
 543 * original string did not end with a terminator.  If max is positive,
 544 * then split the string into at most max substrings (with the last
 545 * substring containing everything following the (max-1)th terminator
 546 * character).
 547 *
 548 * The most generic form is `strbuf_split_buf`, which takes an arbitrary
 549 * pointer/len buffer. The `_str` variant takes a NUL-terminated string,
 550 * the `_max` variant takes a strbuf, and just `strbuf_split` is a convenience
 551 * wrapper to drop the `max` parameter.
 552 *
 553 * For lighter-weight alternatives, see string_list_split() and
 554 * string_list_split_in_place().
 555 */
 556struct strbuf **strbuf_split_buf(const char *str, size_t len,
 557                                 int terminator, int max);
 558
 559static inline struct strbuf **strbuf_split_str(const char *str,
 560                                               int terminator, int max)
 561{
 562        return strbuf_split_buf(str, strlen(str), terminator, max);
 563}
 564
 565static inline struct strbuf **strbuf_split_max(const struct strbuf *sb,
 566                                               int terminator, int max)
 567{
 568        return strbuf_split_buf(sb->buf, sb->len, terminator, max);
 569}
 570
 571static inline struct strbuf **strbuf_split(const struct strbuf *sb,
 572                                           int terminator)
 573{
 574        return strbuf_split_max(sb, terminator, 0);
 575}
 576
 577/*
 578 * Adds all strings of a string list to the strbuf, separated by the given
 579 * separator.  For example, if sep is
 580 *   ', '
 581 * and slist contains
 582 *   ['element1', 'element2', ..., 'elementN'],
 583 * then write:
 584 *   'element1, element2, ..., elementN'
 585 * to str.  If only one element, just write "element1" to str.
 586 */
 587void strbuf_add_separated_string_list(struct strbuf *str,
 588                                      const char *sep,
 589                                      struct string_list *slist);
 590
 591/**
 592 * Free a NULL-terminated list of strbufs (for example, the return
 593 * values of the strbuf_split*() functions).
 594 */
 595void strbuf_list_free(struct strbuf **list);
 596
 597/**
 598 * Add the abbreviation, as generated by find_unique_abbrev, of `sha1` to
 599 * the strbuf `sb`.
 600 */
 601void strbuf_add_unique_abbrev(struct strbuf *sb,
 602                              const struct object_id *oid,
 603                              int abbrev_len);
 604
 605/**
 606 * Launch the user preferred editor to edit a file and fill the buffer
 607 * with the file's contents upon the user completing their editing. The
 608 * third argument can be used to set the environment which the editor is
 609 * run in. If the buffer is NULL the editor is launched as usual but the
 610 * file's contents are not read into the buffer upon completion.
 611 */
 612int launch_editor(const char *path, struct strbuf *buffer,
 613                  const char *const *env);
 614
 615int launch_sequence_editor(const char *path, struct strbuf *buffer,
 616                           const char *const *env);
 617
 618void strbuf_add_lines(struct strbuf *sb,
 619                      const char *prefix,
 620                      const char *buf,
 621                      size_t size);
 622
 623/**
 624 * Append s to sb, with the characters '<', '>', '&' and '"' converted
 625 * into XML entities.
 626 */
 627void strbuf_addstr_xml_quoted(struct strbuf *sb,
 628                              const char *s);
 629
 630/**
 631 * "Complete" the contents of `sb` by ensuring that either it ends with the
 632 * character `term`, or it is empty.  This can be used, for example,
 633 * to ensure that text ends with a newline, but without creating an empty
 634 * blank line if there is no content in the first place.
 635 */
 636static inline void strbuf_complete(struct strbuf *sb, char term)
 637{
 638        if (sb->len && sb->buf[sb->len - 1] != term)
 639                strbuf_addch(sb, term);
 640}
 641
 642static inline void strbuf_complete_line(struct strbuf *sb)
 643{
 644        strbuf_complete(sb, '\n');
 645}
 646
 647/*
 648 * Copy "name" to "sb", expanding any special @-marks as handled by
 649 * interpret_branch_name(). The result is a non-qualified branch name
 650 * (so "foo" or "origin/master" instead of "refs/heads/foo" or
 651 * "refs/remotes/origin/master").
 652 *
 653 * Note that the resulting name may not be a syntactically valid refname.
 654 *
 655 * If "allowed" is non-zero, restrict the set of allowed expansions. See
 656 * interpret_branch_name() for details.
 657 */
 658void strbuf_branchname(struct strbuf *sb, const char *name,
 659                       unsigned allowed);
 660
 661/*
 662 * Like strbuf_branchname() above, but confirm that the result is
 663 * syntactically valid to be used as a local branch name in refs/heads/.
 664 *
 665 * The return value is "0" if the result is valid, and "-1" otherwise.
 666 */
 667int strbuf_check_branch_ref(struct strbuf *sb, const char *name);
 668
 669void strbuf_addstr_urlencode(struct strbuf *sb, const char *name,
 670                             int reserved);
 671
 672__attribute__((format (printf,1,2)))
 673int printf_ln(const char *fmt, ...);
 674__attribute__((format (printf,2,3)))
 675int fprintf_ln(FILE *fp, const char *fmt, ...);
 676
 677char *xstrdup_tolower(const char *);
 678char *xstrdup_toupper(const char *);
 679
 680/**
 681 * Create a newly allocated string using printf format. You can do this easily
 682 * with a strbuf, but this provides a shortcut to save a few lines.
 683 */
 684__attribute__((format (printf, 1, 0)))
 685char *xstrvfmt(const char *fmt, va_list ap);
 686__attribute__((format (printf, 1, 2)))
 687char *xstrfmt(const char *fmt, ...);
 688
 689#endif /* STRBUF_H */