1 // Protocol Buffers - Google's data interchange format
2 // Copyright 2008 Google Inc. All rights reserved.
3 // https://developers.google.com/protocol-buffers/
4 //
5 // Redistribution and use in source and binary forms, with or without
6 // modification, are permitted provided that the following conditions are
7 // met:
8 //
9 // * Redistributions of source code must retain the above copyright
10 // notice, this list of conditions and the following disclaimer.
11 // * Redistributions in binary form must reproduce the above
12 // copyright notice, this list of conditions and the following disclaimer
13 // in the documentation and/or other materials provided with the
14 // distribution.
15 // * Neither the name of Google Inc. nor the names of its
16 // contributors may be used to endorse or promote products derived from
17 // this software without specific prior written permission.
18 //
19 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
20 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
21 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
22 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
23 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
24 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
25 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
26 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
27 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
28 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
29 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
30
31 // from google3/strings/strutil.h
32
33 #ifndef GOOGLE_PROTOBUF_STUBS_STRUTIL_H__
34 #define GOOGLE_PROTOBUF_STUBS_STRUTIL_H__
35
36 #include <stdlib.h>
37 #include <vector>
38 #include <google/protobuf/stubs/common.h>
39
40 namespace google {
41 namespace protobuf {
42
43 #ifdef _MSC_VER
44 #define strtoll _strtoi64
45 #define strtoull _strtoui64
46 #elif defined(__DECCXX) && defined(__osf__)
47 // HP C++ on Tru64 does not have strtoll, but strtol is already 64-bit.
48 #define strtoll strtol
49 #define strtoull strtoul
50 #endif
51
52 // ----------------------------------------------------------------------
53 // ascii_isalnum()
54 // Check if an ASCII character is alphanumeric. We can't use ctype's
55 // isalnum() because it is affected by locale. This function is applied
56 // to identifiers in the protocol buffer language, not to natural-language
57 // strings, so locale should not be taken into account.
58 // ascii_isdigit()
59 // Like above, but only accepts digits.
60 // ----------------------------------------------------------------------
61
ascii_isalnum(char c)62 inline bool ascii_isalnum(char c) {
63 return ('a' <= c && c <= 'z') ||
64 ('A' <= c && c <= 'Z') ||
65 ('0' <= c && c <= '9');
66 }
67
ascii_isdigit(char c)68 inline bool ascii_isdigit(char c) {
69 return ('0' <= c && c <= '9');
70 }
71
72 // ----------------------------------------------------------------------
73 // HasPrefixString()
74 // Check if a string begins with a given prefix.
75 // StripPrefixString()
76 // Given a string and a putative prefix, returns the string minus the
77 // prefix string if the prefix matches, otherwise the original
78 // string.
79 // ----------------------------------------------------------------------
HasPrefixString(const string & str,const string & prefix)80 inline bool HasPrefixString(const string& str,
81 const string& prefix) {
82 return str.size() >= prefix.size() &&
83 str.compare(0, prefix.size(), prefix) == 0;
84 }
85
StripPrefixString(const string & str,const string & prefix)86 inline string StripPrefixString(const string& str, const string& prefix) {
87 if (HasPrefixString(str, prefix)) {
88 return str.substr(prefix.size());
89 } else {
90 return str;
91 }
92 }
93
94 // ----------------------------------------------------------------------
95 // HasSuffixString()
96 // Return true if str ends in suffix.
97 // StripSuffixString()
98 // Given a string and a putative suffix, returns the string minus the
99 // suffix string if the suffix matches, otherwise the original
100 // string.
101 // ----------------------------------------------------------------------
HasSuffixString(const string & str,const string & suffix)102 inline bool HasSuffixString(const string& str,
103 const string& suffix) {
104 return str.size() >= suffix.size() &&
105 str.compare(str.size() - suffix.size(), suffix.size(), suffix) == 0;
106 }
107
StripSuffixString(const string & str,const string & suffix)108 inline string StripSuffixString(const string& str, const string& suffix) {
109 if (HasSuffixString(str, suffix)) {
110 return str.substr(0, str.size() - suffix.size());
111 } else {
112 return str;
113 }
114 }
115
116 // ----------------------------------------------------------------------
117 // StripString
118 // Replaces any occurrence of the character 'remove' (or the characters
119 // in 'remove') with the character 'replacewith'.
120 // Good for keeping html characters or protocol characters (\t) out
121 // of places where they might cause a problem.
122 // ----------------------------------------------------------------------
123 LIBPROTOBUF_EXPORT void StripString(string* s, const char* remove,
124 char replacewith);
125
126 // ----------------------------------------------------------------------
127 // LowerString()
128 // UpperString()
129 // ToUpper()
130 // Convert the characters in "s" to lowercase or uppercase. ASCII-only:
131 // these functions intentionally ignore locale because they are applied to
132 // identifiers used in the Protocol Buffer language, not to natural-language
133 // strings.
134 // ----------------------------------------------------------------------
135
LowerString(string * s)136 inline void LowerString(string * s) {
137 string::iterator end = s->end();
138 for (string::iterator i = s->begin(); i != end; ++i) {
139 // tolower() changes based on locale. We don't want this!
140 if ('A' <= *i && *i <= 'Z') *i += 'a' - 'A';
141 }
142 }
143
UpperString(string * s)144 inline void UpperString(string * s) {
145 string::iterator end = s->end();
146 for (string::iterator i = s->begin(); i != end; ++i) {
147 // toupper() changes based on locale. We don't want this!
148 if ('a' <= *i && *i <= 'z') *i += 'A' - 'a';
149 }
150 }
151
ToUpper(const string & s)152 inline string ToUpper(const string& s) {
153 string out = s;
154 UpperString(&out);
155 return out;
156 }
157
158 // ----------------------------------------------------------------------
159 // StringReplace()
160 // Give me a string and two patterns "old" and "new", and I replace
161 // the first instance of "old" in the string with "new", if it
162 // exists. RETURN a new string, regardless of whether the replacement
163 // happened or not.
164 // ----------------------------------------------------------------------
165
166 LIBPROTOBUF_EXPORT string StringReplace(const string& s, const string& oldsub,
167 const string& newsub, bool replace_all);
168
169 // ----------------------------------------------------------------------
170 // SplitStringUsing()
171 // Split a string using a character delimiter. Append the components
172 // to 'result'. If there are consecutive delimiters, this function skips
173 // over all of them.
174 // ----------------------------------------------------------------------
175 LIBPROTOBUF_EXPORT void SplitStringUsing(const string& full, const char* delim,
176 vector<string>* res);
177
178 // Split a string using one or more byte delimiters, presented
179 // as a nul-terminated c string. Append the components to 'result'.
180 // If there are consecutive delimiters, this function will return
181 // corresponding empty strings. If you want to drop the empty
182 // strings, try SplitStringUsing().
183 //
184 // If "full" is the empty string, yields an empty string as the only value.
185 // ----------------------------------------------------------------------
186 LIBPROTOBUF_EXPORT void SplitStringAllowEmpty(const string& full,
187 const char* delim,
188 vector<string>* result);
189
190 // ----------------------------------------------------------------------
191 // Split()
192 // Split a string using a character delimiter.
193 // ----------------------------------------------------------------------
194 inline vector<string> Split(
195 const string& full, const char* delim, bool skip_empty = true) {
196 vector<string> result;
197 if (skip_empty) {
198 SplitStringUsing(full, delim, &result);
199 } else {
200 SplitStringAllowEmpty(full, delim, &result);
201 }
202 return result;
203 }
204
205 // ----------------------------------------------------------------------
206 // JoinStrings()
207 // These methods concatenate a vector of strings into a C++ string, using
208 // the C-string "delim" as a separator between components. There are two
209 // flavors of the function, one flavor returns the concatenated string,
210 // another takes a pointer to the target string. In the latter case the
211 // target string is cleared and overwritten.
212 // ----------------------------------------------------------------------
213 LIBPROTOBUF_EXPORT void JoinStrings(const vector<string>& components,
214 const char* delim, string* result);
215
JoinStrings(const vector<string> & components,const char * delim)216 inline string JoinStrings(const vector<string>& components,
217 const char* delim) {
218 string result;
219 JoinStrings(components, delim, &result);
220 return result;
221 }
222
223 // ----------------------------------------------------------------------
224 // UnescapeCEscapeSequences()
225 // Copies "source" to "dest", rewriting C-style escape sequences
226 // -- '\n', '\r', '\\', '\ooo', etc -- to their ASCII
227 // equivalents. "dest" must be sufficiently large to hold all
228 // the characters in the rewritten string (i.e. at least as large
229 // as strlen(source) + 1 should be safe, since the replacements
230 // are always shorter than the original escaped sequences). It's
231 // safe for source and dest to be the same. RETURNS the length
232 // of dest.
233 //
234 // It allows hex sequences \xhh, or generally \xhhhhh with an
235 // arbitrary number of hex digits, but all of them together must
236 // specify a value of a single byte (e.g. \x0045 is equivalent
237 // to \x45, and \x1234 is erroneous).
238 //
239 // It also allows escape sequences of the form \uhhhh (exactly four
240 // hex digits, upper or lower case) or \Uhhhhhhhh (exactly eight
241 // hex digits, upper or lower case) to specify a Unicode code
242 // point. The dest array will contain the UTF8-encoded version of
243 // that code-point (e.g., if source contains \u2019, then dest will
244 // contain the three bytes 0xE2, 0x80, and 0x99).
245 //
246 // Errors: In the first form of the call, errors are reported with
247 // LOG(ERROR). The same is true for the second form of the call if
248 // the pointer to the string vector is NULL; otherwise, error
249 // messages are stored in the vector. In either case, the effect on
250 // the dest array is not defined, but rest of the source will be
251 // processed.
252 // ----------------------------------------------------------------------
253
254 LIBPROTOBUF_EXPORT int UnescapeCEscapeSequences(const char* source, char* dest);
255 LIBPROTOBUF_EXPORT int UnescapeCEscapeSequences(const char* source, char* dest,
256 vector<string> *errors);
257
258 // ----------------------------------------------------------------------
259 // UnescapeCEscapeString()
260 // This does the same thing as UnescapeCEscapeSequences, but creates
261 // a new string. The caller does not need to worry about allocating
262 // a dest buffer. This should be used for non performance critical
263 // tasks such as printing debug messages. It is safe for src and dest
264 // to be the same.
265 //
266 // The second call stores its errors in a supplied string vector.
267 // If the string vector pointer is NULL, it reports the errors with LOG().
268 //
269 // In the first and second calls, the length of dest is returned. In the
270 // the third call, the new string is returned.
271 // ----------------------------------------------------------------------
272
273 LIBPROTOBUF_EXPORT int UnescapeCEscapeString(const string& src, string* dest);
274 LIBPROTOBUF_EXPORT int UnescapeCEscapeString(const string& src, string* dest,
275 vector<string> *errors);
276 LIBPROTOBUF_EXPORT string UnescapeCEscapeString(const string& src);
277
278 // ----------------------------------------------------------------------
279 // CEscapeString()
280 // Copies 'src' to 'dest', escaping dangerous characters using
281 // C-style escape sequences. This is very useful for preparing query
282 // flags. 'src' and 'dest' should not overlap.
283 // Returns the number of bytes written to 'dest' (not including the \0)
284 // or -1 if there was insufficient space.
285 //
286 // Currently only \n, \r, \t, ", ', \ and !isprint() chars are escaped.
287 // ----------------------------------------------------------------------
288 LIBPROTOBUF_EXPORT int CEscapeString(const char* src, int src_len,
289 char* dest, int dest_len);
290
291 // ----------------------------------------------------------------------
292 // CEscape()
293 // More convenient form of CEscapeString: returns result as a "string".
294 // This version is slower than CEscapeString() because it does more
295 // allocation. However, it is much more convenient to use in
296 // non-speed-critical code like logging messages etc.
297 // ----------------------------------------------------------------------
298 LIBPROTOBUF_EXPORT string CEscape(const string& src);
299
300 namespace strings {
301 // Like CEscape() but does not escape bytes with the upper bit set.
302 LIBPROTOBUF_EXPORT string Utf8SafeCEscape(const string& src);
303
304 // Like CEscape() but uses hex (\x) escapes instead of octals.
305 LIBPROTOBUF_EXPORT string CHexEscape(const string& src);
306 } // namespace strings
307
308 // ----------------------------------------------------------------------
309 // strto32()
310 // strtou32()
311 // strto64()
312 // strtou64()
313 // Architecture-neutral plug compatible replacements for strtol() and
314 // strtoul(). Long's have different lengths on ILP-32 and LP-64
315 // platforms, so using these is safer, from the point of view of
316 // overflow behavior, than using the standard libc functions.
317 // ----------------------------------------------------------------------
318 LIBPROTOBUF_EXPORT int32 strto32_adaptor(const char *nptr, char **endptr,
319 int base);
320 LIBPROTOBUF_EXPORT uint32 strtou32_adaptor(const char *nptr, char **endptr,
321 int base);
322
strto32(const char * nptr,char ** endptr,int base)323 inline int32 strto32(const char *nptr, char **endptr, int base) {
324 if (sizeof(int32) == sizeof(long))
325 return strtol(nptr, endptr, base);
326 else
327 return strto32_adaptor(nptr, endptr, base);
328 }
329
strtou32(const char * nptr,char ** endptr,int base)330 inline uint32 strtou32(const char *nptr, char **endptr, int base) {
331 if (sizeof(uint32) == sizeof(unsigned long))
332 return strtoul(nptr, endptr, base);
333 else
334 return strtou32_adaptor(nptr, endptr, base);
335 }
336
337 // For now, long long is 64-bit on all the platforms we care about, so these
338 // functions can simply pass the call to strto[u]ll.
strto64(const char * nptr,char ** endptr,int base)339 inline int64 strto64(const char *nptr, char **endptr, int base) {
340 GOOGLE_COMPILE_ASSERT(sizeof(int64) == sizeof(long long),
341 sizeof_int64_is_not_sizeof_long_long);
342 return strtoll(nptr, endptr, base);
343 }
344
strtou64(const char * nptr,char ** endptr,int base)345 inline uint64 strtou64(const char *nptr, char **endptr, int base) {
346 GOOGLE_COMPILE_ASSERT(sizeof(uint64) == sizeof(unsigned long long),
347 sizeof_uint64_is_not_sizeof_long_long);
348 return strtoull(nptr, endptr, base);
349 }
350
351 // ----------------------------------------------------------------------
352 // safe_strto32()
353 // ----------------------------------------------------------------------
354 LIBPROTOBUF_EXPORT bool safe_int(string text, int32* value_p);
355
safe_strto32(string text,int32 * value)356 inline bool safe_strto32(string text, int32* value) {
357 return safe_int(text, value);
358 }
359
360 // ----------------------------------------------------------------------
361 // FastIntToBuffer()
362 // FastHexToBuffer()
363 // FastHex64ToBuffer()
364 // FastHex32ToBuffer()
365 // FastTimeToBuffer()
366 // These are intended for speed. FastIntToBuffer() assumes the
367 // integer is non-negative. FastHexToBuffer() puts output in
368 // hex rather than decimal. FastTimeToBuffer() puts the output
369 // into RFC822 format.
370 //
371 // FastHex64ToBuffer() puts a 64-bit unsigned value in hex-format,
372 // padded to exactly 16 bytes (plus one byte for '\0')
373 //
374 // FastHex32ToBuffer() puts a 32-bit unsigned value in hex-format,
375 // padded to exactly 8 bytes (plus one byte for '\0')
376 //
377 // All functions take the output buffer as an arg.
378 // They all return a pointer to the beginning of the output,
379 // which may not be the beginning of the input buffer.
380 // ----------------------------------------------------------------------
381
382 // Suggested buffer size for FastToBuffer functions. Also works with
383 // DoubleToBuffer() and FloatToBuffer().
384 static const int kFastToBufferSize = 32;
385
386 LIBPROTOBUF_EXPORT char* FastInt32ToBuffer(int32 i, char* buffer);
387 LIBPROTOBUF_EXPORT char* FastInt64ToBuffer(int64 i, char* buffer);
388 char* FastUInt32ToBuffer(uint32 i, char* buffer); // inline below
389 char* FastUInt64ToBuffer(uint64 i, char* buffer); // inline below
390 LIBPROTOBUF_EXPORT char* FastHexToBuffer(int i, char* buffer);
391 LIBPROTOBUF_EXPORT char* FastHex64ToBuffer(uint64 i, char* buffer);
392 LIBPROTOBUF_EXPORT char* FastHex32ToBuffer(uint32 i, char* buffer);
393
394 // at least 22 bytes long
FastIntToBuffer(int i,char * buffer)395 inline char* FastIntToBuffer(int i, char* buffer) {
396 return (sizeof(i) == 4 ?
397 FastInt32ToBuffer(i, buffer) : FastInt64ToBuffer(i, buffer));
398 }
FastUIntToBuffer(unsigned int i,char * buffer)399 inline char* FastUIntToBuffer(unsigned int i, char* buffer) {
400 return (sizeof(i) == 4 ?
401 FastUInt32ToBuffer(i, buffer) : FastUInt64ToBuffer(i, buffer));
402 }
FastLongToBuffer(long i,char * buffer)403 inline char* FastLongToBuffer(long i, char* buffer) {
404 return (sizeof(i) == 4 ?
405 FastInt32ToBuffer(i, buffer) : FastInt64ToBuffer(i, buffer));
406 }
FastULongToBuffer(unsigned long i,char * buffer)407 inline char* FastULongToBuffer(unsigned long i, char* buffer) {
408 return (sizeof(i) == 4 ?
409 FastUInt32ToBuffer(i, buffer) : FastUInt64ToBuffer(i, buffer));
410 }
411
412 // ----------------------------------------------------------------------
413 // FastInt32ToBufferLeft()
414 // FastUInt32ToBufferLeft()
415 // FastInt64ToBufferLeft()
416 // FastUInt64ToBufferLeft()
417 //
418 // Like the Fast*ToBuffer() functions above, these are intended for speed.
419 // Unlike the Fast*ToBuffer() functions, however, these functions write
420 // their output to the beginning of the buffer (hence the name, as the
421 // output is left-aligned). The caller is responsible for ensuring that
422 // the buffer has enough space to hold the output.
423 //
424 // Returns a pointer to the end of the string (i.e. the null character
425 // terminating the string).
426 // ----------------------------------------------------------------------
427
428 LIBPROTOBUF_EXPORT char* FastInt32ToBufferLeft(int32 i, char* buffer);
429 LIBPROTOBUF_EXPORT char* FastUInt32ToBufferLeft(uint32 i, char* buffer);
430 LIBPROTOBUF_EXPORT char* FastInt64ToBufferLeft(int64 i, char* buffer);
431 LIBPROTOBUF_EXPORT char* FastUInt64ToBufferLeft(uint64 i, char* buffer);
432
433 // Just define these in terms of the above.
FastUInt32ToBuffer(uint32 i,char * buffer)434 inline char* FastUInt32ToBuffer(uint32 i, char* buffer) {
435 FastUInt32ToBufferLeft(i, buffer);
436 return buffer;
437 }
FastUInt64ToBuffer(uint64 i,char * buffer)438 inline char* FastUInt64ToBuffer(uint64 i, char* buffer) {
439 FastUInt64ToBufferLeft(i, buffer);
440 return buffer;
441 }
442
443 // ----------------------------------------------------------------------
444 // SimpleItoa()
445 // Description: converts an integer to a string.
446 //
447 // Return value: string
448 // ----------------------------------------------------------------------
449 LIBPROTOBUF_EXPORT string SimpleItoa(int i);
450 LIBPROTOBUF_EXPORT string SimpleItoa(unsigned int i);
451 LIBPROTOBUF_EXPORT string SimpleItoa(long i);
452 LIBPROTOBUF_EXPORT string SimpleItoa(unsigned long i);
453 LIBPROTOBUF_EXPORT string SimpleItoa(long long i);
454 LIBPROTOBUF_EXPORT string SimpleItoa(unsigned long long i);
455
456 // ----------------------------------------------------------------------
457 // SimpleDtoa()
458 // SimpleFtoa()
459 // DoubleToBuffer()
460 // FloatToBuffer()
461 // Description: converts a double or float to a string which, if
462 // passed to NoLocaleStrtod(), will produce the exact same original double
463 // (except in case of NaN; all NaNs are considered the same value).
464 // We try to keep the string short but it's not guaranteed to be as
465 // short as possible.
466 //
467 // DoubleToBuffer() and FloatToBuffer() write the text to the given
468 // buffer and return it. The buffer must be at least
469 // kDoubleToBufferSize bytes for doubles and kFloatToBufferSize
470 // bytes for floats. kFastToBufferSize is also guaranteed to be large
471 // enough to hold either.
472 //
473 // Return value: string
474 // ----------------------------------------------------------------------
475 LIBPROTOBUF_EXPORT string SimpleDtoa(double value);
476 LIBPROTOBUF_EXPORT string SimpleFtoa(float value);
477
478 LIBPROTOBUF_EXPORT char* DoubleToBuffer(double i, char* buffer);
479 LIBPROTOBUF_EXPORT char* FloatToBuffer(float i, char* buffer);
480
481 // In practice, doubles should never need more than 24 bytes and floats
482 // should never need more than 14 (including null terminators), but we
483 // overestimate to be safe.
484 static const int kDoubleToBufferSize = 32;
485 static const int kFloatToBufferSize = 24;
486
487 // ----------------------------------------------------------------------
488 // ToString() are internal help methods used in StrCat() and Join()
489 // ----------------------------------------------------------------------
490 namespace internal {
ToString(int i)491 inline string ToString(int i) {
492 return SimpleItoa(i);
493 }
494
ToString(string a)495 inline string ToString(string a) {
496 return a;
497 }
498 } // namespace internal
499
500 // ----------------------------------------------------------------------
501 // StrCat()
502 // These methods join some strings together.
503 // ----------------------------------------------------------------------
504 template <typename T1, typename T2, typename T3, typename T4, typename T5>
StrCat(const T1 & a,const T2 & b,const T3 & c,const T4 & d,const T5 & e)505 string StrCat(
506 const T1& a, const T2& b, const T3& c, const T4& d, const T5& e) {
507 return internal::ToString(a) + internal::ToString(b) +
508 internal::ToString(c) + internal::ToString(d) + internal::ToString(e);
509 }
510
511 template <typename T1, typename T2, typename T3, typename T4>
StrCat(const T1 & a,const T2 & b,const T3 & c,const T4 & d)512 string StrCat(
513 const T1& a, const T2& b, const T3& c, const T4& d) {
514 return internal::ToString(a) + internal::ToString(b) +
515 internal::ToString(c) + internal::ToString(d);
516 }
517
518 template <typename T1, typename T2, typename T3>
StrCat(const T1 & a,const T2 & b,const T3 & c)519 string StrCat(const T1& a, const T2& b, const T3& c) {
520 return internal::ToString(a) + internal::ToString(b) +
521 internal::ToString(c);
522 }
523
524 template <typename T1, typename T2>
StrCat(const T1 & a,const T2 & b)525 string StrCat(const T1& a, const T2& b) {
526 return internal::ToString(a) + internal::ToString(b);
527 }
528
529 // ----------------------------------------------------------------------
530 // Join()
531 // These methods concatenate a range of components into a C++ string, using
532 // the C-string "delim" as a separator between components.
533 // ----------------------------------------------------------------------
534 template <typename Iterator>
Join(Iterator start,Iterator end,const char * delim,string * result)535 void Join(Iterator start, Iterator end,
536 const char* delim, string* result) {
537 for (Iterator it = start; it != end; ++it) {
538 if (it != start) {
539 result->append(delim);
540 }
541 result->append(internal::ToString(*it));
542 }
543 }
544
545 template <typename Range>
Join(const Range & components,const char * delim)546 string Join(const Range& components,
547 const char* delim) {
548 string result;
549 Join(components.begin(), components.end(), delim, &result);
550 return result;
551 }
552
553 // ----------------------------------------------------------------------
554 // ToHex()
555 // Return a lower-case hex string representation of the given integer.
556 // ----------------------------------------------------------------------
557 LIBPROTOBUF_EXPORT string ToHex(uint64 num);
558
559 } // namespace protobuf
560 } // namespace google
561
562 #endif // GOOGLE_PROTOBUF_STUBS_STRUTIL_H__
563