1 // Copyright (c) 1999, Google Inc.
2 // All rights reserved.
3 //
4 // Redistribution and use in source and binary forms, with or without
5 // modification, are permitted provided that the following conditions are
6 // met:
7 //
8 // * Redistributions of source code must retain the above copyright
9 // notice, this list of conditions and the following disclaimer.
10 // * Redistributions in binary form must reproduce the above
11 // copyright notice, this list of conditions and the following disclaimer
12 // in the documentation and/or other materials provided with the
13 // distribution.
14 // * Neither the name of Google Inc. nor the names of its
15 // contributors may be used to endorse or promote products derived from
16 // this software without specific prior written permission.
17 //
18 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
19 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
20 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
21 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
22 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
23 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
24 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
25 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
26 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
27 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
28 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
29
30 // ---
31 // Revamped and reorganized by Craig Silverstein
32 //
33 // This file contains the implementation of all our command line flags
34 // stuff. Here's how everything fits together
35 //
36 // * FlagRegistry owns CommandLineFlags owns FlagValue.
37 // * FlagSaver holds a FlagRegistry (saves it at construct time,
38 // restores it at destroy time).
39 // * CommandLineFlagParser lives outside that hierarchy, but works on
40 // CommandLineFlags (modifying the FlagValues).
41 // * Free functions like SetCommandLineOption() work via one of the
42 // above (such as CommandLineFlagParser).
43 //
44 // In more detail:
45 //
46 // -- The main classes that hold flag data:
47 //
48 // FlagValue holds the current value of a flag. It's
49 // pseudo-templatized: every operation on a FlagValue is typed. It
50 // also deals with storage-lifetime issues (so flag values don't go
51 // away in a destructor), which is why we need a whole class to hold a
52 // variable's value.
53 //
54 // CommandLineFlag is all the information about a single command-line
55 // flag. It has a FlagValue for the flag's current value, but also
56 // the flag's name, type, etc.
57 //
58 // FlagRegistry is a collection of CommandLineFlags. There's the
59 // global registry, which is where flags defined via DEFINE_foo()
60 // live. But it's possible to define your own flag, manually, in a
61 // different registry you create. (In practice, multiple registries
62 // are used only by FlagSaver).
63 //
64 // A given FlagValue is owned by exactly one CommandLineFlag. A given
65 // CommandLineFlag is owned by exactly one FlagRegistry. FlagRegistry
66 // has a lock; any operation that writes to a FlagValue or
67 // CommandLineFlag owned by that registry must acquire the
68 // FlagRegistry lock before doing so.
69 //
70 // --- Some other classes and free functions:
71 //
72 // CommandLineFlagInfo is a client-exposed version of CommandLineFlag.
73 // Once it's instantiated, it has no dependencies or relationships
74 // with any other part of this file.
75 //
76 // FlagRegisterer is the helper class used by the DEFINE_* macros to
77 // allow work to be done at global initialization time.
78 //
79 // CommandLineFlagParser is the class that reads from the commandline
80 // and instantiates flag values based on that. It needs to poke into
81 // the innards of the FlagValue->CommandLineFlag->FlagRegistry class
82 // hierarchy to do that. It's careful to acquire the FlagRegistry
83 // lock before doing any writing or other non-const actions.
84 //
85 // GetCommandLineOption is just a hook into registry routines to
86 // retrieve a flag based on its name. SetCommandLineOption, on the
87 // other hand, hooks into CommandLineFlagParser. Other API functions
88 // are, similarly, mostly hooks into the functionality described above.
89
90 #include "config.h"
91 #include "gflags/gflags.h"
92
93 #include <assert.h>
94 #include <ctype.h>
95 #include <errno.h>
96 #if defined(HAVE_FNMATCH_H)
97 # include <fnmatch.h>
98 #elif defined(HAVE_SHLWAPI_H)
99 # define NO_SHLWAPI_ISOS
100 # include <shlwapi.h>
101 #endif
102 #include <stdarg.h> // For va_list and related operations
103 #include <stdio.h>
104 #include <string.h>
105
106 #include <algorithm>
107 #include <map>
108 #include <string>
109 #include <utility> // for pair<>
110 #include <vector>
111
112 #include "mutex.h"
113 #include "util.h"
114
115 using namespace MUTEX_NAMESPACE;
116
117
118 // Special flags, type 1: the 'recursive' flags. They set another flag's val.
119 DEFINE_string(flagfile, "", "load flags from file");
120 DEFINE_string(fromenv, "", "set flags from the environment"
121 " [use 'export FLAGS_flag1=value']");
122 DEFINE_string(tryfromenv, "", "set flags from the environment if present");
123
124 // Special flags, type 2: the 'parsing' flags. They modify how we parse.
125 DEFINE_string(undefok, "", "comma-separated list of flag names that it is okay to specify "
126 "on the command line even if the program does not define a flag "
127 "with that name. IMPORTANT: flags in this list that have "
128 "arguments MUST use the flag=value format");
129
130 namespace GFLAGS_NAMESPACE {
131
132 using std::map;
133 using std::pair;
134 using std::sort;
135 using std::string;
136 using std::vector;
137
138 // This is used by the unittest to test error-exit code
139 void GFLAGS_DLL_DECL (*gflags_exitfunc)(int) = &exit; // from stdlib.h
140
141
142 // The help message indicating that the commandline flag has been
143 // 'stripped'. It will not show up when doing "-help" and its
144 // variants. The flag is stripped if STRIP_FLAG_HELP is set to 1
145 // before including base/gflags.h
146
147 // This is used by this file, and also in gflags_reporting.cc
148 const char kStrippedFlagHelp[] = "\001\002\003\004 (unknown) \004\003\002\001";
149
150 namespace {
151
152 // There are also 'reporting' flags, in gflags_reporting.cc.
153
154 static const char kError[] = "ERROR: ";
155
156 // Indicates that undefined options are to be ignored.
157 // Enables deferred processing of flags in dynamically loaded libraries.
158 static bool allow_command_line_reparsing = false;
159
160 static bool logging_is_probably_set_up = false;
161
162 // This is a 'prototype' validate-function. 'Real' validate
163 // functions, take a flag-value as an argument: ValidateFn(bool) or
164 // ValidateFn(uint64). However, for easier storage, we strip off this
165 // argument and then restore it when actually calling the function on
166 // a flag value.
167 typedef bool (*ValidateFnProto)();
168
169 // Whether we should die when reporting an error.
170 enum DieWhenReporting { DIE, DO_NOT_DIE };
171
172 // Report Error and exit if requested.
ReportError(DieWhenReporting should_die,const char * format,...)173 static void ReportError(DieWhenReporting should_die, const char* format, ...) {
174 va_list ap;
175 va_start(ap, format);
176 vfprintf(stderr, format, ap);
177 va_end(ap);
178 fflush(stderr); // should be unnecessary, but cygwin's rxvt buffers stderr
179 if (should_die == DIE) gflags_exitfunc(1);
180 }
181
182
183 // --------------------------------------------------------------------
184 // FlagValue
185 // This represent the value a single flag might have. The major
186 // functionality is to convert from a string to an object of a
187 // given type, and back. Thread-compatible.
188 // --------------------------------------------------------------------
189
190 class CommandLineFlag;
191 class FlagValue {
192 public:
193 enum ValueType {
194 FV_BOOL = 0,
195 FV_INT32 = 1,
196 FV_UINT32 = 2,
197 FV_INT64 = 3,
198 FV_UINT64 = 4,
199 FV_DOUBLE = 5,
200 FV_STRING = 6,
201 FV_MAX_INDEX = 6,
202 };
203
204 template <typename FlagType>
205 FlagValue(FlagType* valbuf, bool transfer_ownership_of_value);
206 ~FlagValue();
207
208 bool ParseFrom(const char* spec);
209 string ToString() const;
210
Type() const211 ValueType Type() const { return static_cast<ValueType>(type_); }
212
213 private:
214 friend class CommandLineFlag; // for many things, including Validate()
215 friend class GFLAGS_NAMESPACE::FlagSaverImpl; // calls New()
216 friend class FlagRegistry; // checks value_buffer_ for flags_by_ptr_ map
217 template <typename T> friend T GetFromEnv(const char*, T);
218 friend bool TryParseLocked(const CommandLineFlag*, FlagValue*,
219 const char*, string*); // for New(), CopyFrom()
220
221 template <typename FlagType>
222 struct FlagValueTraits;
223
224 const char* TypeName() const;
225 bool Equal(const FlagValue& x) const;
226 FlagValue* New() const; // creates a new one with default value
227 void CopyFrom(const FlagValue& x);
228
229 // Calls the given validate-fn on value_buffer_, and returns
230 // whatever it returns. But first casts validate_fn_proto to a
231 // function that takes our value as an argument (eg void
232 // (*validate_fn)(bool) for a bool flag).
233 bool Validate(const char* flagname, ValidateFnProto validate_fn_proto) const;
234
235 void* const value_buffer_; // points to the buffer holding our data
236 const int8 type_; // how to interpret value_
237 const bool owns_value_; // whether to free value on destruct
238
239 FlagValue(const FlagValue&); // no copying!
240 void operator=(const FlagValue&);
241 };
242
243 // Map the given C++ type to a value of the ValueType enum at compile time.
244 #define DEFINE_FLAG_TRAITS(type, value) \
245 template <> \
246 struct FlagValue::FlagValueTraits<type> { \
247 static const ValueType kValueType = value; \
248 }
249
250 // Define full template specializations of the FlagValueTraits template
251 // for all supported flag types.
252 DEFINE_FLAG_TRAITS(bool, FV_BOOL);
253 DEFINE_FLAG_TRAITS(int32, FV_INT32);
254 DEFINE_FLAG_TRAITS(uint32, FV_UINT32);
255 DEFINE_FLAG_TRAITS(int64, FV_INT64);
256 DEFINE_FLAG_TRAITS(uint64, FV_UINT64);
257 DEFINE_FLAG_TRAITS(double, FV_DOUBLE);
258 DEFINE_FLAG_TRAITS(std::string, FV_STRING);
259
260 #undef DEFINE_FLAG_TRAITS
261
262
263 // This could be a templated method of FlagValue, but doing so adds to the
264 // size of the .o. Since there's no type-safety here anyway, macro is ok.
265 #define VALUE_AS(type) *reinterpret_cast<type*>(value_buffer_)
266 #define OTHER_VALUE_AS(fv, type) *reinterpret_cast<type*>(fv.value_buffer_)
267 #define SET_VALUE_AS(type, value) VALUE_AS(type) = (value)
268
269 template <typename FlagType>
FlagValue(FlagType * valbuf,bool transfer_ownership_of_value)270 FlagValue::FlagValue(FlagType* valbuf,
271 bool transfer_ownership_of_value)
272 : value_buffer_(valbuf),
273 type_(FlagValueTraits<FlagType>::kValueType),
274 owns_value_(transfer_ownership_of_value) {
275 }
276
~FlagValue()277 FlagValue::~FlagValue() {
278 if (!owns_value_) {
279 return;
280 }
281 switch (type_) {
282 case FV_BOOL: delete reinterpret_cast<bool*>(value_buffer_); break;
283 case FV_INT32: delete reinterpret_cast<int32*>(value_buffer_); break;
284 case FV_UINT32: delete reinterpret_cast<uint32*>(value_buffer_); break;
285 case FV_INT64: delete reinterpret_cast<int64*>(value_buffer_); break;
286 case FV_UINT64: delete reinterpret_cast<uint64*>(value_buffer_); break;
287 case FV_DOUBLE: delete reinterpret_cast<double*>(value_buffer_); break;
288 case FV_STRING: delete reinterpret_cast<string*>(value_buffer_); break;
289 }
290 }
291
ParseFrom(const char * value)292 bool FlagValue::ParseFrom(const char* value) {
293 if (type_ == FV_BOOL) {
294 const char* kTrue[] = { "1", "t", "true", "y", "yes" };
295 const char* kFalse[] = { "0", "f", "false", "n", "no" };
296 COMPILE_ASSERT(sizeof(kTrue) == sizeof(kFalse), true_false_equal);
297 for (size_t i = 0; i < sizeof(kTrue)/sizeof(*kTrue); ++i) {
298 if (strcasecmp(value, kTrue[i]) == 0) {
299 SET_VALUE_AS(bool, true);
300 return true;
301 } else if (strcasecmp(value, kFalse[i]) == 0) {
302 SET_VALUE_AS(bool, false);
303 return true;
304 }
305 }
306 return false; // didn't match a legal input
307
308 } else if (type_ == FV_STRING) {
309 SET_VALUE_AS(string, value);
310 return true;
311 }
312
313 // OK, it's likely to be numeric, and we'll be using a strtoXXX method.
314 if (value[0] == '\0') // empty-string is only allowed for string type.
315 return false;
316 char* end;
317 // Leading 0x puts us in base 16. But leading 0 does not put us in base 8!
318 // It caused too many bugs when we had that behavior.
319 int base = 10; // by default
320 if (value[0] == '0' && (value[1] == 'x' || value[1] == 'X'))
321 base = 16;
322 errno = 0;
323
324 switch (type_) {
325 case FV_INT32: {
326 const int64 r = strto64(value, &end, base);
327 if (errno || end != value + strlen(value)) return false; // bad parse
328 if (static_cast<int32>(r) != r) // worked, but number out of range
329 return false;
330 SET_VALUE_AS(int32, static_cast<int32>(r));
331 return true;
332 }
333 case FV_UINT32: {
334 while (*value == ' ') value++;
335 if (*value == '-') return false; // negative number
336 const uint64 r = strtou64(value, &end, base);
337 if (errno || end != value + strlen(value)) return false; // bad parse
338 if (static_cast<uint32>(r) != r) // worked, but number out of range
339 return false;
340 SET_VALUE_AS(uint32, static_cast<uint32>(r));
341 return true;
342 }
343 case FV_INT64: {
344 const int64 r = strto64(value, &end, base);
345 if (errno || end != value + strlen(value)) return false; // bad parse
346 SET_VALUE_AS(int64, r);
347 return true;
348 }
349 case FV_UINT64: {
350 while (*value == ' ') value++;
351 if (*value == '-') return false; // negative number
352 const uint64 r = strtou64(value, &end, base);
353 if (errno || end != value + strlen(value)) return false; // bad parse
354 SET_VALUE_AS(uint64, r);
355 return true;
356 }
357 case FV_DOUBLE: {
358 const double r = strtod(value, &end);
359 if (errno || end != value + strlen(value)) return false; // bad parse
360 SET_VALUE_AS(double, r);
361 return true;
362 }
363 default: {
364 assert(false); // unknown type
365 return false;
366 }
367 }
368 }
369
ToString() const370 string FlagValue::ToString() const {
371 char intbuf[64]; // enough to hold even the biggest number
372 switch (type_) {
373 case FV_BOOL:
374 return VALUE_AS(bool) ? "true" : "false";
375 case FV_INT32:
376 snprintf(intbuf, sizeof(intbuf), "%" PRId32, VALUE_AS(int32));
377 return intbuf;
378 case FV_UINT32:
379 snprintf(intbuf, sizeof(intbuf), "%" PRIu32, VALUE_AS(uint32));
380 return intbuf;
381 case FV_INT64:
382 snprintf(intbuf, sizeof(intbuf), "%" PRId64, VALUE_AS(int64));
383 return intbuf;
384 case FV_UINT64:
385 snprintf(intbuf, sizeof(intbuf), "%" PRIu64, VALUE_AS(uint64));
386 return intbuf;
387 case FV_DOUBLE:
388 snprintf(intbuf, sizeof(intbuf), "%.17g", VALUE_AS(double));
389 return intbuf;
390 case FV_STRING:
391 return VALUE_AS(string);
392 default:
393 assert(false);
394 return ""; // unknown type
395 }
396 }
397
Validate(const char * flagname,ValidateFnProto validate_fn_proto) const398 bool FlagValue::Validate(const char* flagname,
399 ValidateFnProto validate_fn_proto) const {
400 switch (type_) {
401 case FV_BOOL:
402 return reinterpret_cast<bool (*)(const char*, bool)>(
403 validate_fn_proto)(flagname, VALUE_AS(bool));
404 case FV_INT32:
405 return reinterpret_cast<bool (*)(const char*, int32)>(
406 validate_fn_proto)(flagname, VALUE_AS(int32));
407 case FV_UINT32:
408 return reinterpret_cast<bool (*)(const char*, uint32)>(
409 validate_fn_proto)(flagname, VALUE_AS(uint32));
410 case FV_INT64:
411 return reinterpret_cast<bool (*)(const char*, int64)>(
412 validate_fn_proto)(flagname, VALUE_AS(int64));
413 case FV_UINT64:
414 return reinterpret_cast<bool (*)(const char*, uint64)>(
415 validate_fn_proto)(flagname, VALUE_AS(uint64));
416 case FV_DOUBLE:
417 return reinterpret_cast<bool (*)(const char*, double)>(
418 validate_fn_proto)(flagname, VALUE_AS(double));
419 case FV_STRING:
420 return reinterpret_cast<bool (*)(const char*, const string&)>(
421 validate_fn_proto)(flagname, VALUE_AS(string));
422 default:
423 assert(false); // unknown type
424 return false;
425 }
426 }
427
TypeName() const428 const char* FlagValue::TypeName() const {
429 static const char types[] =
430 "bool\0xx"
431 "int32\0x"
432 "uint32\0"
433 "int64\0x"
434 "uint64\0"
435 "double\0"
436 "string";
437 if (type_ > FV_MAX_INDEX) {
438 assert(false);
439 return "";
440 }
441 // Directly indexing the strings in the 'types' string, each of them is 7 bytes long.
442 return &types[type_ * 7];
443 }
444
Equal(const FlagValue & x) const445 bool FlagValue::Equal(const FlagValue& x) const {
446 if (type_ != x.type_)
447 return false;
448 switch (type_) {
449 case FV_BOOL: return VALUE_AS(bool) == OTHER_VALUE_AS(x, bool);
450 case FV_INT32: return VALUE_AS(int32) == OTHER_VALUE_AS(x, int32);
451 case FV_UINT32: return VALUE_AS(uint32) == OTHER_VALUE_AS(x, uint32);
452 case FV_INT64: return VALUE_AS(int64) == OTHER_VALUE_AS(x, int64);
453 case FV_UINT64: return VALUE_AS(uint64) == OTHER_VALUE_AS(x, uint64);
454 case FV_DOUBLE: return VALUE_AS(double) == OTHER_VALUE_AS(x, double);
455 case FV_STRING: return VALUE_AS(string) == OTHER_VALUE_AS(x, string);
456 default: assert(false); return false; // unknown type
457 }
458 }
459
New() const460 FlagValue* FlagValue::New() const {
461 switch (type_) {
462 case FV_BOOL: return new FlagValue(new bool(false), true);
463 case FV_INT32: return new FlagValue(new int32(0), true);
464 case FV_UINT32: return new FlagValue(new uint32(0), true);
465 case FV_INT64: return new FlagValue(new int64(0), true);
466 case FV_UINT64: return new FlagValue(new uint64(0), true);
467 case FV_DOUBLE: return new FlagValue(new double(0.0), true);
468 case FV_STRING: return new FlagValue(new string, true);
469 default: assert(false); return NULL; // unknown type
470 }
471 }
472
CopyFrom(const FlagValue & x)473 void FlagValue::CopyFrom(const FlagValue& x) {
474 assert(type_ == x.type_);
475 switch (type_) {
476 case FV_BOOL: SET_VALUE_AS(bool, OTHER_VALUE_AS(x, bool)); break;
477 case FV_INT32: SET_VALUE_AS(int32, OTHER_VALUE_AS(x, int32)); break;
478 case FV_UINT32: SET_VALUE_AS(uint32, OTHER_VALUE_AS(x, uint32)); break;
479 case FV_INT64: SET_VALUE_AS(int64, OTHER_VALUE_AS(x, int64)); break;
480 case FV_UINT64: SET_VALUE_AS(uint64, OTHER_VALUE_AS(x, uint64)); break;
481 case FV_DOUBLE: SET_VALUE_AS(double, OTHER_VALUE_AS(x, double)); break;
482 case FV_STRING: SET_VALUE_AS(string, OTHER_VALUE_AS(x, string)); break;
483 default: assert(false); // unknown type
484 }
485 }
486
487 // --------------------------------------------------------------------
488 // CommandLineFlag
489 // This represents a single flag, including its name, description,
490 // default value, and current value. Mostly this serves as a
491 // struct, though it also knows how to register itself.
492 // All CommandLineFlags are owned by a (exactly one)
493 // FlagRegistry. If you wish to modify fields in this class, you
494 // should acquire the FlagRegistry lock for the registry that owns
495 // this flag.
496 // --------------------------------------------------------------------
497
498 class CommandLineFlag {
499 public:
500 // Note: we take over memory-ownership of current_val and default_val.
501 CommandLineFlag(const char* name, const char* help, const char* filename,
502 FlagValue* current_val, FlagValue* default_val);
503 ~CommandLineFlag();
504
name() const505 const char* name() const { return name_; }
help() const506 const char* help() const { return help_; }
filename() const507 const char* filename() const { return file_; }
508 const char* CleanFileName() const; // nixes irrelevant prefix such as homedir
current_value() const509 string current_value() const { return current_->ToString(); }
default_value() const510 string default_value() const { return defvalue_->ToString(); }
type_name() const511 const char* type_name() const { return defvalue_->TypeName(); }
validate_function() const512 ValidateFnProto validate_function() const { return validate_fn_proto_; }
flag_ptr() const513 const void* flag_ptr() const { return current_->value_buffer_; }
514
Type() const515 FlagValue::ValueType Type() const { return defvalue_->Type(); }
516
517 void FillCommandLineFlagInfo(struct CommandLineFlagInfo* result);
518
519 // If validate_fn_proto_ is non-NULL, calls it on value, returns result.
520 bool Validate(const FlagValue& value) const;
ValidateCurrent() const521 bool ValidateCurrent() const { return Validate(*current_); }
Modified() const522 bool Modified() const { return modified_; }
523
524 private:
525 // for SetFlagLocked() and setting flags_by_ptr_
526 friend class FlagRegistry;
527 friend class GFLAGS_NAMESPACE::FlagSaverImpl; // for cloning the values
528 // set validate_fn
529 friend bool AddFlagValidator(const void*, ValidateFnProto);
530
531 // This copies all the non-const members: modified, processed, defvalue, etc.
532 void CopyFrom(const CommandLineFlag& src);
533
534 void UpdateModifiedBit();
535
536 const char* const name_; // Flag name
537 const char* const help_; // Help message
538 const char* const file_; // Which file did this come from?
539 bool modified_; // Set after default assignment?
540 FlagValue* defvalue_; // Default value for flag
541 FlagValue* current_; // Current value for flag
542 // This is a casted, 'generic' version of validate_fn, which actually
543 // takes a flag-value as an arg (void (*validate_fn)(bool), say).
544 // When we pass this to current_->Validate(), it will cast it back to
545 // the proper type. This may be NULL to mean we have no validate_fn.
546 ValidateFnProto validate_fn_proto_;
547
548 CommandLineFlag(const CommandLineFlag&); // no copying!
549 void operator=(const CommandLineFlag&);
550 };
551
CommandLineFlag(const char * name,const char * help,const char * filename,FlagValue * current_val,FlagValue * default_val)552 CommandLineFlag::CommandLineFlag(const char* name, const char* help,
553 const char* filename,
554 FlagValue* current_val, FlagValue* default_val)
555 : name_(name), help_(help), file_(filename), modified_(false),
556 defvalue_(default_val), current_(current_val), validate_fn_proto_(NULL) {
557 }
558
~CommandLineFlag()559 CommandLineFlag::~CommandLineFlag() {
560 delete current_;
561 delete defvalue_;
562 }
563
CleanFileName() const564 const char* CommandLineFlag::CleanFileName() const {
565 // This function has been used to strip off a common prefix from
566 // flag source file names. Because flags can be defined in different
567 // shared libraries, there may not be a single common prefix.
568 // Further, this functionality hasn't been active for many years.
569 // Need a better way to produce more user friendly help output or
570 // "anonymize" file paths in help output, respectively.
571 // Follow issue at: https://github.com/gflags/gflags/issues/86
572 return filename();
573 }
574
FillCommandLineFlagInfo(CommandLineFlagInfo * result)575 void CommandLineFlag::FillCommandLineFlagInfo(
576 CommandLineFlagInfo* result) {
577 result->name = name();
578 result->type = type_name();
579 result->description = help();
580 result->current_value = current_value();
581 result->default_value = default_value();
582 result->filename = CleanFileName();
583 UpdateModifiedBit();
584 result->is_default = !modified_;
585 result->has_validator_fn = validate_function() != NULL;
586 result->flag_ptr = flag_ptr();
587 }
588
UpdateModifiedBit()589 void CommandLineFlag::UpdateModifiedBit() {
590 // Update the "modified" bit in case somebody bypassed the
591 // Flags API and wrote directly through the FLAGS_name variable.
592 if (!modified_ && !current_->Equal(*defvalue_)) {
593 modified_ = true;
594 }
595 }
596
CopyFrom(const CommandLineFlag & src)597 void CommandLineFlag::CopyFrom(const CommandLineFlag& src) {
598 // Note we only copy the non-const members; others are fixed at construct time
599 if (modified_ != src.modified_) modified_ = src.modified_;
600 if (!current_->Equal(*src.current_)) current_->CopyFrom(*src.current_);
601 if (!defvalue_->Equal(*src.defvalue_)) defvalue_->CopyFrom(*src.defvalue_);
602 if (validate_fn_proto_ != src.validate_fn_proto_)
603 validate_fn_proto_ = src.validate_fn_proto_;
604 }
605
Validate(const FlagValue & value) const606 bool CommandLineFlag::Validate(const FlagValue& value) const {
607
608 if (validate_function() == NULL)
609 return true;
610 else
611 return value.Validate(name(), validate_function());
612 }
613
614
615 // --------------------------------------------------------------------
616 // FlagRegistry
617 // A FlagRegistry singleton object holds all flag objects indexed
618 // by their names so that if you know a flag's name (as a C
619 // string), you can access or set it. If the function is named
620 // FooLocked(), you must own the registry lock before calling
621 // the function; otherwise, you should *not* hold the lock, and
622 // the function will acquire it itself if needed.
623 // --------------------------------------------------------------------
624
625 struct StringCmp { // Used by the FlagRegistry map class to compare char*'s
operator ()GFLAGS_NAMESPACE::__anon2c14dfba0111::StringCmp626 bool operator() (const char* s1, const char* s2) const {
627 return (strcmp(s1, s2) < 0);
628 }
629 };
630
631
632 class FlagRegistry {
633 public:
FlagRegistry()634 FlagRegistry() {
635 }
~FlagRegistry()636 ~FlagRegistry() {
637 // Not using STLDeleteElements as that resides in util and this
638 // class is base.
639 for (FlagMap::iterator p = flags_.begin(), e = flags_.end(); p != e; ++p) {
640 CommandLineFlag* flag = p->second;
641 delete flag;
642 }
643 }
644
DeleteGlobalRegistry()645 static void DeleteGlobalRegistry() {
646 delete global_registry_;
647 global_registry_ = NULL;
648 }
649
650 // Store a flag in this registry. Takes ownership of the given pointer.
651 void RegisterFlag(CommandLineFlag* flag);
652
Lock()653 void Lock() { lock_.Lock(); }
Unlock()654 void Unlock() { lock_.Unlock(); }
655
656 // Returns the flag object for the specified name, or NULL if not found.
657 CommandLineFlag* FindFlagLocked(const char* name);
658
659 // Returns the flag object whose current-value is stored at flag_ptr.
660 // That is, for whom current_->value_buffer_ == flag_ptr
661 CommandLineFlag* FindFlagViaPtrLocked(const void* flag_ptr);
662
663 // A fancier form of FindFlag that works correctly if name is of the
664 // form flag=value. In that case, we set key to point to flag, and
665 // modify v to point to the value (if present), and return the flag
666 // with the given name. If the flag does not exist, returns NULL
667 // and sets error_message.
668 CommandLineFlag* SplitArgumentLocked(const char* argument,
669 string* key, const char** v,
670 string* error_message);
671
672 // Set the value of a flag. If the flag was successfully set to
673 // value, set msg to indicate the new flag-value, and return true.
674 // Otherwise, set msg to indicate the error, leave flag unchanged,
675 // and return false. msg can be NULL.
676 bool SetFlagLocked(CommandLineFlag* flag, const char* value,
677 FlagSettingMode set_mode, string* msg);
678
679 static FlagRegistry* GlobalRegistry(); // returns a singleton registry
680
681 private:
682 friend class GFLAGS_NAMESPACE::FlagSaverImpl; // reads all the flags in order to copy them
683 friend class CommandLineFlagParser; // for ValidateUnmodifiedFlags
684 friend void GFLAGS_NAMESPACE::GetAllFlags(vector<CommandLineFlagInfo>*);
685
686 // The map from name to flag, for FindFlagLocked().
687 typedef map<const char*, CommandLineFlag*, StringCmp> FlagMap;
688 typedef FlagMap::iterator FlagIterator;
689 typedef FlagMap::const_iterator FlagConstIterator;
690 FlagMap flags_;
691
692 // The map from current-value pointer to flag, fo FindFlagViaPtrLocked().
693 typedef map<const void*, CommandLineFlag*> FlagPtrMap;
694 FlagPtrMap flags_by_ptr_;
695
696 static FlagRegistry* global_registry_; // a singleton registry
697
698 Mutex lock_;
699
700 static void InitGlobalRegistry();
701
702 // Disallow
703 FlagRegistry(const FlagRegistry&);
704 FlagRegistry& operator=(const FlagRegistry&);
705 };
706
707 class FlagRegistryLock {
708 public:
FlagRegistryLock(FlagRegistry * fr)709 explicit FlagRegistryLock(FlagRegistry* fr) : fr_(fr) { fr_->Lock(); }
~FlagRegistryLock()710 ~FlagRegistryLock() { fr_->Unlock(); }
711 private:
712 FlagRegistry *const fr_;
713 };
714
715
RegisterFlag(CommandLineFlag * flag)716 void FlagRegistry::RegisterFlag(CommandLineFlag* flag) {
717 Lock();
718 pair<FlagIterator, bool> ins =
719 flags_.insert(pair<const char*, CommandLineFlag*>(flag->name(), flag));
720 if (ins.second == false) { // means the name was already in the map
721 if (strcmp(ins.first->second->filename(), flag->filename()) != 0) {
722 ReportError(DIE, "ERROR: flag '%s' was defined more than once "
723 "(in files '%s' and '%s').\n",
724 flag->name(),
725 ins.first->second->filename(),
726 flag->filename());
727 } else {
728 ReportError(DIE, "ERROR: something wrong with flag '%s' in file '%s'. "
729 "One possibility: file '%s' is being linked both statically "
730 "and dynamically into this executable.\n",
731 flag->name(),
732 flag->filename(), flag->filename());
733 }
734 }
735 // Also add to the flags_by_ptr_ map.
736 flags_by_ptr_[flag->current_->value_buffer_] = flag;
737 Unlock();
738 }
739
FindFlagLocked(const char * name)740 CommandLineFlag* FlagRegistry::FindFlagLocked(const char* name) {
741 FlagConstIterator i = flags_.find(name);
742 if (i == flags_.end()) {
743 // If the name has dashes in it, try again after replacing with
744 // underscores.
745 if (strchr(name, '-') == NULL) return NULL;
746 string name_rep = name;
747 std::replace(name_rep.begin(), name_rep.end(), '-', '_');
748 return FindFlagLocked(name_rep.c_str());
749 } else {
750 return i->second;
751 }
752 }
753
FindFlagViaPtrLocked(const void * flag_ptr)754 CommandLineFlag* FlagRegistry::FindFlagViaPtrLocked(const void* flag_ptr) {
755 FlagPtrMap::const_iterator i = flags_by_ptr_.find(flag_ptr);
756 if (i == flags_by_ptr_.end()) {
757 return NULL;
758 } else {
759 return i->second;
760 }
761 }
762
SplitArgumentLocked(const char * arg,string * key,const char ** v,string * error_message)763 CommandLineFlag* FlagRegistry::SplitArgumentLocked(const char* arg,
764 string* key,
765 const char** v,
766 string* error_message) {
767 // Find the flag object for this option
768 const char* flag_name;
769 const char* value = strchr(arg, '=');
770 if (value == NULL) {
771 key->assign(arg);
772 *v = NULL;
773 } else {
774 // Strip out the "=value" portion from arg
775 key->assign(arg, value-arg);
776 *v = ++value; // advance past the '='
777 }
778 flag_name = key->c_str();
779
780 CommandLineFlag* flag = FindFlagLocked(flag_name);
781
782 if (flag == NULL) {
783 // If we can't find the flag-name, then we should return an error.
784 // The one exception is if 1) the flag-name is 'nox', 2) there
785 // exists a flag named 'x', and 3) 'x' is a boolean flag.
786 // In that case, we want to return flag 'x'.
787 if (!(flag_name[0] == 'n' && flag_name[1] == 'o')) {
788 // flag-name is not 'nox', so we're not in the exception case.
789 *error_message = StringPrintf("%sunknown command line flag '%s'\n",
790 kError, key->c_str());
791 return NULL;
792 }
793 flag = FindFlagLocked(flag_name+2);
794 if (flag == NULL) {
795 // No flag named 'x' exists, so we're not in the exception case.
796 *error_message = StringPrintf("%sunknown command line flag '%s'\n",
797 kError, key->c_str());
798 return NULL;
799 }
800 if (flag->Type() != FlagValue::FV_BOOL) {
801 // 'x' exists but is not boolean, so we're not in the exception case.
802 *error_message = StringPrintf(
803 "%sboolean value (%s) specified for %s command line flag\n",
804 kError, key->c_str(), flag->type_name());
805 return NULL;
806 }
807 // We're in the exception case!
808 // Make up a fake value to replace the "no" we stripped out
809 key->assign(flag_name+2); // the name without the "no"
810 *v = "0";
811 }
812
813 // Assign a value if this is a boolean flag
814 if (*v == NULL && flag->Type() == FlagValue::FV_BOOL) {
815 *v = "1"; // the --nox case was already handled, so this is the --x case
816 }
817
818 return flag;
819 }
820
TryParseLocked(const CommandLineFlag * flag,FlagValue * flag_value,const char * value,string * msg)821 bool TryParseLocked(const CommandLineFlag* flag, FlagValue* flag_value,
822 const char* value, string* msg) {
823 // Use tenative_value, not flag_value, until we know value is valid.
824 FlagValue* tentative_value = flag_value->New();
825 if (!tentative_value->ParseFrom(value)) {
826 if (msg) {
827 StringAppendF(msg,
828 "%sillegal value '%s' specified for %s flag '%s'\n",
829 kError, value,
830 flag->type_name(), flag->name());
831 }
832 delete tentative_value;
833 return false;
834 } else if (!flag->Validate(*tentative_value)) {
835 if (msg) {
836 StringAppendF(msg,
837 "%sfailed validation of new value '%s' for flag '%s'\n",
838 kError, tentative_value->ToString().c_str(),
839 flag->name());
840 }
841 delete tentative_value;
842 return false;
843 } else {
844 flag_value->CopyFrom(*tentative_value);
845 if (msg) {
846 StringAppendF(msg, "%s set to %s\n",
847 flag->name(), flag_value->ToString().c_str());
848 }
849 delete tentative_value;
850 return true;
851 }
852 }
853
SetFlagLocked(CommandLineFlag * flag,const char * value,FlagSettingMode set_mode,string * msg)854 bool FlagRegistry::SetFlagLocked(CommandLineFlag* flag,
855 const char* value,
856 FlagSettingMode set_mode,
857 string* msg) {
858 flag->UpdateModifiedBit();
859 switch (set_mode) {
860 case SET_FLAGS_VALUE: {
861 // set or modify the flag's value
862 if (!TryParseLocked(flag, flag->current_, value, msg))
863 return false;
864 flag->modified_ = true;
865 break;
866 }
867 case SET_FLAG_IF_DEFAULT: {
868 // set the flag's value, but only if it hasn't been set by someone else
869 if (!flag->modified_) {
870 if (!TryParseLocked(flag, flag->current_, value, msg))
871 return false;
872 flag->modified_ = true;
873 } else {
874 *msg = StringPrintf("%s set to %s",
875 flag->name(), flag->current_value().c_str());
876 }
877 break;
878 }
879 case SET_FLAGS_DEFAULT: {
880 // modify the flag's default-value
881 if (!TryParseLocked(flag, flag->defvalue_, value, msg))
882 return false;
883 if (!flag->modified_) {
884 // Need to set both defvalue *and* current, in this case
885 TryParseLocked(flag, flag->current_, value, NULL);
886 }
887 break;
888 }
889 default: {
890 // unknown set_mode
891 assert(false);
892 return false;
893 }
894 }
895
896 return true;
897 }
898
899 // Get the singleton FlagRegistry object
900 FlagRegistry* FlagRegistry::global_registry_ = NULL;
901
GlobalRegistry()902 FlagRegistry* FlagRegistry::GlobalRegistry() {
903 static Mutex lock(Mutex::LINKER_INITIALIZED);
904 MutexLock acquire_lock(&lock);
905 if (!global_registry_) {
906 global_registry_ = new FlagRegistry;
907 }
908 return global_registry_;
909 }
910
911 // --------------------------------------------------------------------
912 // CommandLineFlagParser
913 // Parsing is done in two stages. In the first, we go through
914 // argv. For every flag-like arg we can make sense of, we parse
915 // it and set the appropriate FLAGS_* variable. For every flag-
916 // like arg we can't make sense of, we store it in a vector,
917 // along with an explanation of the trouble. In stage 2, we
918 // handle the 'reporting' flags like --help and --mpm_version.
919 // (This is via a call to HandleCommandLineHelpFlags(), in
920 // gflags_reporting.cc.)
921 // An optional stage 3 prints out the error messages.
922 // This is a bit of a simplification. For instance, --flagfile
923 // is handled as soon as it's seen in stage 1, not in stage 2.
924 // --------------------------------------------------------------------
925
926 class CommandLineFlagParser {
927 public:
928 // The argument is the flag-registry to register the parsed flags in
CommandLineFlagParser(FlagRegistry * reg)929 explicit CommandLineFlagParser(FlagRegistry* reg) : registry_(reg) {}
~CommandLineFlagParser()930 ~CommandLineFlagParser() {}
931
932 // Stage 1: Every time this is called, it reads all flags in argv.
933 // However, it ignores all flags that have been successfully set
934 // before. Typically this is only called once, so this 'reparsing'
935 // behavior isn't important. It can be useful when trying to
936 // reparse after loading a dll, though.
937 uint32 ParseNewCommandLineFlags(int* argc, char*** argv, bool remove_flags);
938
939 // Stage 2: print reporting info and exit, if requested.
940 // In gflags_reporting.cc:HandleCommandLineHelpFlags().
941
942 // Stage 3: validate all the commandline flags that have validators
943 // registered and were not set/modified by ParseNewCommandLineFlags.
944 void ValidateFlags(bool all);
945 void ValidateUnmodifiedFlags();
946
947 // Stage 4: report any errors and return true if any were found.
948 bool ReportErrors();
949
950 // Set a particular command line option. "newval" is a string
951 // describing the new value that the option has been set to. If
952 // option_name does not specify a valid option name, or value is not
953 // a valid value for option_name, newval is empty. Does recursive
954 // processing for --flagfile and --fromenv. Returns the new value
955 // if everything went ok, or empty-string if not. (Actually, the
956 // return-string could hold many flag/value pairs due to --flagfile.)
957 // NB: Must have called registry_->Lock() before calling this function.
958 string ProcessSingleOptionLocked(CommandLineFlag* flag,
959 const char* value,
960 FlagSettingMode set_mode);
961
962 // Set a whole batch of command line options as specified by contentdata,
963 // which is in flagfile format (and probably has been read from a flagfile).
964 // Returns the new value if everything went ok, or empty-string if
965 // not. (Actually, the return-string could hold many flag/value
966 // pairs due to --flagfile.)
967 // NB: Must have called registry_->Lock() before calling this function.
968 string ProcessOptionsFromStringLocked(const string& contentdata,
969 FlagSettingMode set_mode);
970
971 // These are the 'recursive' flags, defined at the top of this file.
972 // Whenever we see these flags on the commandline, we must take action.
973 // These are called by ProcessSingleOptionLocked and, similarly, return
974 // new values if everything went ok, or the empty-string if not.
975 string ProcessFlagfileLocked(const string& flagval, FlagSettingMode set_mode);
976 // diff fromenv/tryfromenv
977 string ProcessFromenvLocked(const string& flagval, FlagSettingMode set_mode,
978 bool errors_are_fatal);
979
980 private:
981 FlagRegistry* const registry_;
982 map<string, string> error_flags_; // map from name to error message
983 // This could be a set<string>, but we reuse the map to minimize the .o size
984 map<string, string> undefined_names_; // --[flag] name was not registered
985 };
986
987
988 // Parse a list of (comma-separated) flags.
ParseFlagList(const char * value,vector<string> * flags)989 static void ParseFlagList(const char* value, vector<string>* flags) {
990 for (const char *p = value; p && *p; value = p) {
991 p = strchr(value, ',');
992 size_t len;
993 if (p) {
994 len = p - value;
995 p++;
996 } else {
997 len = strlen(value);
998 }
999
1000 if (len == 0)
1001 ReportError(DIE, "ERROR: empty flaglist entry\n");
1002 if (value[0] == '-')
1003 ReportError(DIE, "ERROR: flag \"%*s\" begins with '-'\n", len, value);
1004
1005 flags->push_back(string(value, len));
1006 }
1007 }
1008
1009 // Snarf an entire file into a C++ string. This is just so that we
1010 // can do all the I/O in one place and not worry about it everywhere.
1011 // Plus, it's convenient to have the whole file contents at hand.
1012 // Adds a newline at the end of the file.
1013 #define PFATAL(s) do { perror(s); gflags_exitfunc(1); } while (0)
1014
ReadFileIntoString(const char * filename)1015 static string ReadFileIntoString(const char* filename) {
1016 const int kBufSize = 8092;
1017 char buffer[kBufSize];
1018 string s;
1019 FILE* fp;
1020 if ((errno = SafeFOpen(&fp, filename, "r")) != 0) PFATAL(filename);
1021 size_t n;
1022 while ( (n=fread(buffer, 1, kBufSize, fp)) > 0 ) {
1023 if (ferror(fp)) PFATAL(filename);
1024 s.append(buffer, n);
1025 }
1026 fclose(fp);
1027 return s;
1028 }
1029
ParseNewCommandLineFlags(int * argc,char *** argv,bool remove_flags)1030 uint32 CommandLineFlagParser::ParseNewCommandLineFlags(int* argc, char*** argv,
1031 bool remove_flags) {
1032 int first_nonopt = *argc; // for non-options moved to the end
1033
1034 registry_->Lock();
1035 for (int i = 1; i < first_nonopt; i++) {
1036 char* arg = (*argv)[i];
1037
1038 // Like getopt(), we permute non-option flags to be at the end.
1039 if (arg[0] != '-' || arg[1] == '\0') { // must be a program argument: "-" is an argument, not a flag
1040 memmove((*argv) + i, (*argv) + i+1, (*argc - (i+1)) * sizeof((*argv)[i]));
1041 (*argv)[*argc-1] = arg; // we go last
1042 first_nonopt--; // we've been pushed onto the stack
1043 i--; // to undo the i++ in the loop
1044 continue;
1045 }
1046 arg++; // skip leading '-'
1047 if (arg[0] == '-') arg++; // or leading '--'
1048
1049 // -- alone means what it does for GNU: stop options parsing
1050 if (*arg == '\0') {
1051 first_nonopt = i+1;
1052 break;
1053 }
1054
1055 // Find the flag object for this option
1056 string key;
1057 const char* value;
1058 string error_message;
1059 CommandLineFlag* flag = registry_->SplitArgumentLocked(arg, &key, &value,
1060 &error_message);
1061 if (flag == NULL) {
1062 undefined_names_[key] = ""; // value isn't actually used
1063 error_flags_[key] = error_message;
1064 continue;
1065 }
1066
1067 if (value == NULL) {
1068 // Boolean options are always assigned a value by SplitArgumentLocked()
1069 assert(flag->Type() != FlagValue::FV_BOOL);
1070 if (i+1 >= first_nonopt) {
1071 // This flag needs a value, but there is nothing available
1072 error_flags_[key] = (string(kError) + "flag '" + (*argv)[i] + "'"
1073 + " is missing its argument");
1074 if (flag->help() && flag->help()[0] > '\001') {
1075 // Be useful in case we have a non-stripped description.
1076 error_flags_[key] += string("; flag description: ") + flag->help();
1077 }
1078 error_flags_[key] += "\n";
1079 break; // we treat this as an unrecoverable error
1080 } else {
1081 value = (*argv)[++i]; // read next arg for value
1082
1083 // Heuristic to detect the case where someone treats a string arg
1084 // like a bool:
1085 // --my_string_var --foo=bar
1086 // We look for a flag of string type, whose value begins with a
1087 // dash, and where the flag-name and value are separated by a
1088 // space rather than an '='.
1089 // To avoid false positives, we also require the word "true"
1090 // or "false" in the help string. Without this, a valid usage
1091 // "-lat -30.5" would trigger the warning. The common cases we
1092 // want to solve talk about true and false as values.
1093 if (value[0] == '-'
1094 && flag->Type() == FlagValue::FV_STRING
1095 && (strstr(flag->help(), "true")
1096 || strstr(flag->help(), "false"))) {
1097 LOG(WARNING) << "Did you really mean to set flag '"
1098 << flag->name() << "' to the value '"
1099 << value << "'?";
1100 }
1101 }
1102 }
1103
1104 // TODO(csilvers): only set a flag if we hadn't set it before here
1105 ProcessSingleOptionLocked(flag, value, SET_FLAGS_VALUE);
1106 }
1107 registry_->Unlock();
1108
1109 if (remove_flags) { // Fix up argc and argv by removing command line flags
1110 (*argv)[first_nonopt-1] = (*argv)[0];
1111 (*argv) += (first_nonopt-1);
1112 (*argc) -= (first_nonopt-1);
1113 first_nonopt = 1; // because we still don't count argv[0]
1114 }
1115
1116 logging_is_probably_set_up = true; // because we've parsed --logdir, etc.
1117
1118 return first_nonopt;
1119 }
1120
ProcessFlagfileLocked(const string & flagval,FlagSettingMode set_mode)1121 string CommandLineFlagParser::ProcessFlagfileLocked(const string& flagval,
1122 FlagSettingMode set_mode) {
1123 if (flagval.empty())
1124 return "";
1125
1126 string msg;
1127 vector<string> filename_list;
1128 ParseFlagList(flagval.c_str(), &filename_list); // take a list of filenames
1129 for (size_t i = 0; i < filename_list.size(); ++i) {
1130 const char* file = filename_list[i].c_str();
1131 msg += ProcessOptionsFromStringLocked(ReadFileIntoString(file), set_mode);
1132 }
1133 return msg;
1134 }
1135
ProcessFromenvLocked(const string & flagval,FlagSettingMode set_mode,bool errors_are_fatal)1136 string CommandLineFlagParser::ProcessFromenvLocked(const string& flagval,
1137 FlagSettingMode set_mode,
1138 bool errors_are_fatal) {
1139 if (flagval.empty())
1140 return "";
1141
1142 string msg;
1143 vector<string> flaglist;
1144 ParseFlagList(flagval.c_str(), &flaglist);
1145
1146 for (size_t i = 0; i < flaglist.size(); ++i) {
1147 const char* flagname = flaglist[i].c_str();
1148 CommandLineFlag* flag = registry_->FindFlagLocked(flagname);
1149 if (flag == NULL) {
1150 error_flags_[flagname] =
1151 StringPrintf("%sunknown command line flag '%s' "
1152 "(via --fromenv or --tryfromenv)\n",
1153 kError, flagname);
1154 undefined_names_[flagname] = "";
1155 continue;
1156 }
1157
1158 const string envname = string("FLAGS_") + string(flagname);
1159 string envval;
1160 if (!SafeGetEnv(envname.c_str(), envval)) {
1161 if (errors_are_fatal) {
1162 error_flags_[flagname] = (string(kError) + envname +
1163 " not found in environment\n");
1164 }
1165 continue;
1166 }
1167
1168 // Avoid infinite recursion.
1169 if (envval == "fromenv" || envval == "tryfromenv") {
1170 error_flags_[flagname] =
1171 StringPrintf("%sinfinite recursion on environment flag '%s'\n",
1172 kError, envval.c_str());
1173 continue;
1174 }
1175
1176 msg += ProcessSingleOptionLocked(flag, envval.c_str(), set_mode);
1177 }
1178 return msg;
1179 }
1180
ProcessSingleOptionLocked(CommandLineFlag * flag,const char * value,FlagSettingMode set_mode)1181 string CommandLineFlagParser::ProcessSingleOptionLocked(
1182 CommandLineFlag* flag, const char* value, FlagSettingMode set_mode) {
1183 string msg;
1184 if (value && !registry_->SetFlagLocked(flag, value, set_mode, &msg)) {
1185 error_flags_[flag->name()] = msg;
1186 return "";
1187 }
1188
1189 // The recursive flags, --flagfile and --fromenv and --tryfromenv,
1190 // must be dealt with as soon as they're seen. They will emit
1191 // messages of their own.
1192 if (strcmp(flag->name(), "flagfile") == 0) {
1193 msg += ProcessFlagfileLocked(FLAGS_flagfile, set_mode);
1194
1195 } else if (strcmp(flag->name(), "fromenv") == 0) {
1196 // last arg indicates envval-not-found is fatal (unlike in --tryfromenv)
1197 msg += ProcessFromenvLocked(FLAGS_fromenv, set_mode, true);
1198
1199 } else if (strcmp(flag->name(), "tryfromenv") == 0) {
1200 msg += ProcessFromenvLocked(FLAGS_tryfromenv, set_mode, false);
1201 }
1202
1203 return msg;
1204 }
1205
ValidateFlags(bool all)1206 void CommandLineFlagParser::ValidateFlags(bool all) {
1207 FlagRegistryLock frl(registry_);
1208 for (FlagRegistry::FlagConstIterator i = registry_->flags_.begin();
1209 i != registry_->flags_.end(); ++i) {
1210 if ((all || !i->second->Modified()) && !i->second->ValidateCurrent()) {
1211 // only set a message if one isn't already there. (If there's
1212 // an error message, our job is done, even if it's not exactly
1213 // the same error.)
1214 if (error_flags_[i->second->name()].empty()) {
1215 error_flags_[i->second->name()] =
1216 string(kError) + "--" + i->second->name() +
1217 " must be set on the commandline";
1218 if (!i->second->Modified()) {
1219 error_flags_[i->second->name()] += " (default value fails validation)";
1220 }
1221 error_flags_[i->second->name()] += "\n";
1222 }
1223 }
1224 }
1225 }
1226
ValidateUnmodifiedFlags()1227 void CommandLineFlagParser::ValidateUnmodifiedFlags() {
1228 ValidateFlags(false);
1229 }
1230
ReportErrors()1231 bool CommandLineFlagParser::ReportErrors() {
1232 // error_flags_ indicates errors we saw while parsing.
1233 // But we ignore undefined-names if ok'ed by --undef_ok
1234 if (!FLAGS_undefok.empty()) {
1235 vector<string> flaglist;
1236 ParseFlagList(FLAGS_undefok.c_str(), &flaglist);
1237 for (size_t i = 0; i < flaglist.size(); ++i) {
1238 // We also deal with --no<flag>, in case the flagname was boolean
1239 const string no_version = string("no") + flaglist[i];
1240 if (undefined_names_.find(flaglist[i]) != undefined_names_.end()) {
1241 error_flags_[flaglist[i]] = ""; // clear the error message
1242 } else if (undefined_names_.find(no_version) != undefined_names_.end()) {
1243 error_flags_[no_version] = "";
1244 }
1245 }
1246 }
1247 // Likewise, if they decided to allow reparsing, all undefined-names
1248 // are ok; we just silently ignore them now, and hope that a future
1249 // parse will pick them up somehow.
1250 if (allow_command_line_reparsing) {
1251 for (map<string, string>::const_iterator it = undefined_names_.begin();
1252 it != undefined_names_.end(); ++it)
1253 error_flags_[it->first] = ""; // clear the error message
1254 }
1255
1256 bool found_error = false;
1257 string error_message;
1258 for (map<string, string>::const_iterator it = error_flags_.begin();
1259 it != error_flags_.end(); ++it) {
1260 if (!it->second.empty()) {
1261 error_message.append(it->second.data(), it->second.size());
1262 found_error = true;
1263 }
1264 }
1265 if (found_error)
1266 ReportError(DO_NOT_DIE, "%s", error_message.c_str());
1267 return found_error;
1268 }
1269
ProcessOptionsFromStringLocked(const string & contentdata,FlagSettingMode set_mode)1270 string CommandLineFlagParser::ProcessOptionsFromStringLocked(
1271 const string& contentdata, FlagSettingMode set_mode) {
1272 string retval;
1273 const char* flagfile_contents = contentdata.c_str();
1274 bool flags_are_relevant = true; // set to false when filenames don't match
1275 bool in_filename_section = false;
1276
1277 const char* line_end = flagfile_contents;
1278 // We read this file a line at a time.
1279 for (; line_end; flagfile_contents = line_end + 1) {
1280 while (*flagfile_contents && isspace(*flagfile_contents))
1281 ++flagfile_contents;
1282 // Windows uses "\r\n"
1283 line_end = strchr(flagfile_contents, '\r');
1284 if (line_end == NULL)
1285 line_end = strchr(flagfile_contents, '\n');
1286
1287 size_t len = line_end ? line_end - flagfile_contents
1288 : strlen(flagfile_contents);
1289 string line(flagfile_contents, len);
1290
1291 // Each line can be one of four things:
1292 // 1) A comment line -- we skip it
1293 // 2) An empty line -- we skip it
1294 // 3) A list of filenames -- starts a new filenames+flags section
1295 // 4) A --flag=value line -- apply if previous filenames match
1296 if (line.empty() || line[0] == '#') {
1297 // comment or empty line; just ignore
1298
1299 } else if (line[0] == '-') { // flag
1300 in_filename_section = false; // instead, it was a flag-line
1301 if (!flags_are_relevant) // skip this flag; applies to someone else
1302 continue;
1303
1304 const char* name_and_val = line.c_str() + 1; // skip the leading -
1305 if (*name_and_val == '-')
1306 name_and_val++; // skip second - too
1307 string key;
1308 const char* value;
1309 string error_message;
1310 CommandLineFlag* flag = registry_->SplitArgumentLocked(name_and_val,
1311 &key, &value,
1312 &error_message);
1313 // By API, errors parsing flagfile lines are silently ignored.
1314 if (flag == NULL) {
1315 // "WARNING: flagname '" + key + "' not found\n"
1316 } else if (value == NULL) {
1317 // "WARNING: flagname '" + key + "' missing a value\n"
1318 } else {
1319 retval += ProcessSingleOptionLocked(flag, value, set_mode);
1320 }
1321
1322 } else { // a filename!
1323 if (!in_filename_section) { // start over: assume filenames don't match
1324 in_filename_section = true;
1325 flags_are_relevant = false;
1326 }
1327
1328 // Split the line up at spaces into glob-patterns
1329 const char* space = line.c_str(); // just has to be non-NULL
1330 for (const char* word = line.c_str(); *space; word = space+1) {
1331 if (flags_are_relevant) // we can stop as soon as we match
1332 break;
1333 space = strchr(word, ' ');
1334 if (space == NULL)
1335 space = word + strlen(word);
1336 const string glob(word, space - word);
1337 // We try matching both against the full argv0 and basename(argv0)
1338 if (glob == ProgramInvocationName() // small optimization
1339 || glob == ProgramInvocationShortName()
1340 #if defined(HAVE_FNMATCH_H)
1341 || fnmatch(glob.c_str(), ProgramInvocationName(), FNM_PATHNAME) == 0
1342 || fnmatch(glob.c_str(), ProgramInvocationShortName(), FNM_PATHNAME) == 0
1343 #elif defined(HAVE_SHLWAPI_H)
1344 || PathMatchSpecA(glob.c_str(), ProgramInvocationName())
1345 || PathMatchSpecA(glob.c_str(), ProgramInvocationShortName())
1346 #endif
1347 ) {
1348 flags_are_relevant = true;
1349 }
1350 }
1351 }
1352 }
1353 return retval;
1354 }
1355
1356 // --------------------------------------------------------------------
1357 // GetFromEnv()
1358 // AddFlagValidator()
1359 // These are helper functions for routines like BoolFromEnv() and
1360 // RegisterFlagValidator, defined below. They're defined here so
1361 // they can live in the unnamed namespace (which makes friendship
1362 // declarations for these classes possible).
1363 // --------------------------------------------------------------------
1364
1365 template<typename T>
GetFromEnv(const char * varname,T dflt)1366 T GetFromEnv(const char *varname, T dflt) {
1367 std::string valstr;
1368 if (SafeGetEnv(varname, valstr)) {
1369 FlagValue ifv(new T, true);
1370 if (!ifv.ParseFrom(valstr.c_str())) {
1371 ReportError(DIE, "ERROR: error parsing env variable '%s' with value '%s'\n",
1372 varname, valstr.c_str());
1373 }
1374 return OTHER_VALUE_AS(ifv, T);
1375 } else return dflt;
1376 }
1377
AddFlagValidator(const void * flag_ptr,ValidateFnProto validate_fn_proto)1378 bool AddFlagValidator(const void* flag_ptr, ValidateFnProto validate_fn_proto) {
1379 // We want a lock around this routine, in case two threads try to
1380 // add a validator (hopefully the same one!) at once. We could use
1381 // our own thread, but we need to loook at the registry anyway, so
1382 // we just steal that one.
1383 FlagRegistry* const registry = FlagRegistry::GlobalRegistry();
1384 FlagRegistryLock frl(registry);
1385 // First, find the flag whose current-flag storage is 'flag'.
1386 // This is the CommandLineFlag whose current_->value_buffer_ == flag
1387 CommandLineFlag* flag = registry->FindFlagViaPtrLocked(flag_ptr);
1388 if (!flag) {
1389 LOG(WARNING) << "Ignoring RegisterValidateFunction() for flag pointer "
1390 << flag_ptr << ": no flag found at that address";
1391 return false;
1392 } else if (validate_fn_proto == flag->validate_function()) {
1393 return true; // ok to register the same function over and over again
1394 } else if (validate_fn_proto != NULL && flag->validate_function() != NULL) {
1395 LOG(WARNING) << "Ignoring RegisterValidateFunction() for flag '"
1396 << flag->name() << "': validate-fn already registered";
1397 return false;
1398 } else {
1399 flag->validate_fn_proto_ = validate_fn_proto;
1400 return true;
1401 }
1402 }
1403
1404 } // end unnamed namespaces
1405
1406
1407 // Now define the functions that are exported via the .h file
1408
1409 // --------------------------------------------------------------------
1410 // FlagRegisterer
1411 // This class exists merely to have a global constructor (the
1412 // kind that runs before main(), that goes an initializes each
1413 // flag that's been declared. Note that it's very important we
1414 // don't have a destructor that deletes flag_, because that would
1415 // cause us to delete current_storage/defvalue_storage as well,
1416 // which can cause a crash if anything tries to access the flag
1417 // values in a global destructor.
1418 // --------------------------------------------------------------------
1419
1420 namespace {
RegisterCommandLineFlag(const char * name,const char * help,const char * filename,FlagValue * current,FlagValue * defvalue)1421 void RegisterCommandLineFlag(const char* name,
1422 const char* help,
1423 const char* filename,
1424 FlagValue* current,
1425 FlagValue* defvalue) {
1426 if (help == NULL)
1427 help = "";
1428 // Importantly, flag_ will never be deleted, so storage is always good.
1429 CommandLineFlag* flag =
1430 new CommandLineFlag(name, help, filename, current, defvalue);
1431 FlagRegistry::GlobalRegistry()->RegisterFlag(flag); // default registry
1432 }
1433 }
1434
1435 template <typename FlagType>
FlagRegisterer(const char * name,const char * help,const char * filename,FlagType * current_storage,FlagType * defvalue_storage)1436 FlagRegisterer::FlagRegisterer(const char* name,
1437 const char* help,
1438 const char* filename,
1439 FlagType* current_storage,
1440 FlagType* defvalue_storage) {
1441 FlagValue* const current = new FlagValue(current_storage, false);
1442 FlagValue* const defvalue = new FlagValue(defvalue_storage, false);
1443 RegisterCommandLineFlag(name, help, filename, current, defvalue);
1444 }
1445
1446 // Force compiler to generate code for the given template specialization.
1447 #define INSTANTIATE_FLAG_REGISTERER_CTOR(type) \
1448 template GFLAGS_DLL_DECL FlagRegisterer::FlagRegisterer( \
1449 const char* name, const char* help, const char* filename, \
1450 type* current_storage, type* defvalue_storage)
1451
1452 // Do this for all supported flag types.
1453 INSTANTIATE_FLAG_REGISTERER_CTOR(bool);
1454 INSTANTIATE_FLAG_REGISTERER_CTOR(int32);
1455 INSTANTIATE_FLAG_REGISTERER_CTOR(uint32);
1456 INSTANTIATE_FLAG_REGISTERER_CTOR(int64);
1457 INSTANTIATE_FLAG_REGISTERER_CTOR(uint64);
1458 INSTANTIATE_FLAG_REGISTERER_CTOR(double);
1459 INSTANTIATE_FLAG_REGISTERER_CTOR(std::string);
1460
1461 #undef INSTANTIATE_FLAG_REGISTERER_CTOR
1462
1463 // --------------------------------------------------------------------
1464 // GetAllFlags()
1465 // The main way the FlagRegistry class exposes its data. This
1466 // returns, as strings, all the info about all the flags in
1467 // the main registry, sorted first by filename they are defined
1468 // in, and then by flagname.
1469 // --------------------------------------------------------------------
1470
1471 struct FilenameFlagnameCmp {
operator ()GFLAGS_NAMESPACE::FilenameFlagnameCmp1472 bool operator()(const CommandLineFlagInfo& a,
1473 const CommandLineFlagInfo& b) const {
1474 int cmp = strcmp(a.filename.c_str(), b.filename.c_str());
1475 if (cmp == 0)
1476 cmp = strcmp(a.name.c_str(), b.name.c_str()); // secondary sort key
1477 return cmp < 0;
1478 }
1479 };
1480
GetAllFlags(vector<CommandLineFlagInfo> * OUTPUT)1481 void GetAllFlags(vector<CommandLineFlagInfo>* OUTPUT) {
1482 FlagRegistry* const registry = FlagRegistry::GlobalRegistry();
1483 registry->Lock();
1484 for (FlagRegistry::FlagConstIterator i = registry->flags_.begin();
1485 i != registry->flags_.end(); ++i) {
1486 CommandLineFlagInfo fi;
1487 i->second->FillCommandLineFlagInfo(&fi);
1488 OUTPUT->push_back(fi);
1489 }
1490 registry->Unlock();
1491 // Now sort the flags, first by filename they occur in, then alphabetically
1492 sort(OUTPUT->begin(), OUTPUT->end(), FilenameFlagnameCmp());
1493 }
1494
1495 // --------------------------------------------------------------------
1496 // SetArgv()
1497 // GetArgvs()
1498 // GetArgv()
1499 // GetArgv0()
1500 // ProgramInvocationName()
1501 // ProgramInvocationShortName()
1502 // SetUsageMessage()
1503 // ProgramUsage()
1504 // Functions to set and get argv. Typically the setter is called
1505 // by ParseCommandLineFlags. Also can get the ProgramUsage string,
1506 // set by SetUsageMessage.
1507 // --------------------------------------------------------------------
1508
1509 // These values are not protected by a Mutex because they are normally
1510 // set only once during program startup.
1511 static string argv0("UNKNOWN"); // just the program name
1512 static string cmdline; // the entire command-line
1513 static string program_usage;
1514 static vector<string> argvs;
1515 static uint32 argv_sum = 0;
1516
SetArgv(int argc,const char ** argv)1517 void SetArgv(int argc, const char** argv) {
1518 static bool called_set_argv = false;
1519 if (called_set_argv) return;
1520 called_set_argv = true;
1521
1522 assert(argc > 0); // every program has at least a name
1523 argv0 = argv[0];
1524
1525 cmdline.clear();
1526 for (int i = 0; i < argc; i++) {
1527 if (i != 0) cmdline += " ";
1528 cmdline += argv[i];
1529 argvs.push_back(argv[i]);
1530 }
1531
1532 // Compute a simple sum of all the chars in argv
1533 argv_sum = 0;
1534 for (string::const_iterator c = cmdline.begin(); c != cmdline.end(); ++c) {
1535 argv_sum += *c;
1536 }
1537 }
1538
GetArgvs()1539 const vector<string>& GetArgvs() { return argvs; }
GetArgv()1540 const char* GetArgv() { return cmdline.c_str(); }
GetArgv0()1541 const char* GetArgv0() { return argv0.c_str(); }
GetArgvSum()1542 uint32 GetArgvSum() { return argv_sum; }
ProgramInvocationName()1543 const char* ProgramInvocationName() { // like the GNU libc fn
1544 return GetArgv0();
1545 }
ProgramInvocationShortName()1546 const char* ProgramInvocationShortName() { // like the GNU libc fn
1547 size_t pos = argv0.rfind('/');
1548 #ifdef OS_WINDOWS
1549 if (pos == string::npos) pos = argv0.rfind('\\');
1550 #endif
1551 return (pos == string::npos ? argv0.c_str() : (argv0.c_str() + pos + 1));
1552 }
1553
SetUsageMessage(const string & usage)1554 void SetUsageMessage(const string& usage) {
1555 program_usage = usage;
1556 }
1557
ProgramUsage()1558 const char* ProgramUsage() {
1559 if (program_usage.empty()) {
1560 return "Warning: SetUsageMessage() never called";
1561 }
1562 return program_usage.c_str();
1563 }
1564
1565 // --------------------------------------------------------------------
1566 // SetVersionString()
1567 // VersionString()
1568 // --------------------------------------------------------------------
1569
1570 static string version_string;
1571
SetVersionString(const string & version)1572 void SetVersionString(const string& version) {
1573 version_string = version;
1574 }
1575
VersionString()1576 const char* VersionString() {
1577 return version_string.c_str();
1578 }
1579
1580
1581 // --------------------------------------------------------------------
1582 // GetCommandLineOption()
1583 // GetCommandLineFlagInfo()
1584 // GetCommandLineFlagInfoOrDie()
1585 // SetCommandLineOption()
1586 // SetCommandLineOptionWithMode()
1587 // The programmatic way to set a flag's value, using a string
1588 // for its name rather than the variable itself (that is,
1589 // SetCommandLineOption("foo", x) rather than FLAGS_foo = x).
1590 // There's also a bit more flexibility here due to the various
1591 // set-modes, but typically these are used when you only have
1592 // that flag's name as a string, perhaps at runtime.
1593 // All of these work on the default, global registry.
1594 // For GetCommandLineOption, return false if no such flag
1595 // is known, true otherwise. We clear "value" if a suitable
1596 // flag is found.
1597 // --------------------------------------------------------------------
1598
1599
GetCommandLineOption(const char * name,string * value)1600 bool GetCommandLineOption(const char* name, string* value) {
1601 if (NULL == name)
1602 return false;
1603 assert(value);
1604
1605 FlagRegistry* const registry = FlagRegistry::GlobalRegistry();
1606 FlagRegistryLock frl(registry);
1607 CommandLineFlag* flag = registry->FindFlagLocked(name);
1608 if (flag == NULL) {
1609 return false;
1610 } else {
1611 *value = flag->current_value();
1612 return true;
1613 }
1614 }
1615
GetCommandLineFlagInfo(const char * name,CommandLineFlagInfo * OUTPUT)1616 bool GetCommandLineFlagInfo(const char* name, CommandLineFlagInfo* OUTPUT) {
1617 if (NULL == name) return false;
1618 FlagRegistry* const registry = FlagRegistry::GlobalRegistry();
1619 FlagRegistryLock frl(registry);
1620 CommandLineFlag* flag = registry->FindFlagLocked(name);
1621 if (flag == NULL) {
1622 return false;
1623 } else {
1624 assert(OUTPUT);
1625 flag->FillCommandLineFlagInfo(OUTPUT);
1626 return true;
1627 }
1628 }
1629
GetCommandLineFlagInfoOrDie(const char * name)1630 CommandLineFlagInfo GetCommandLineFlagInfoOrDie(const char* name) {
1631 CommandLineFlagInfo info;
1632 if (!GetCommandLineFlagInfo(name, &info)) {
1633 fprintf(stderr, "FATAL ERROR: flag name '%s' doesn't exist\n", name);
1634 gflags_exitfunc(1); // almost certainly gflags_exitfunc()
1635 }
1636 return info;
1637 }
1638
SetCommandLineOptionWithMode(const char * name,const char * value,FlagSettingMode set_mode)1639 string SetCommandLineOptionWithMode(const char* name, const char* value,
1640 FlagSettingMode set_mode) {
1641 string result;
1642 FlagRegistry* const registry = FlagRegistry::GlobalRegistry();
1643 FlagRegistryLock frl(registry);
1644 CommandLineFlag* flag = registry->FindFlagLocked(name);
1645 if (flag) {
1646 CommandLineFlagParser parser(registry);
1647 result = parser.ProcessSingleOptionLocked(flag, value, set_mode);
1648 if (!result.empty()) { // in the error case, we've already logged
1649 // Could consider logging this change
1650 }
1651 }
1652 // The API of this function is that we return empty string on error
1653 return result;
1654 }
1655
SetCommandLineOption(const char * name,const char * value)1656 string SetCommandLineOption(const char* name, const char* value) {
1657 return SetCommandLineOptionWithMode(name, value, SET_FLAGS_VALUE);
1658 }
1659
1660 // --------------------------------------------------------------------
1661 // FlagSaver
1662 // FlagSaverImpl
1663 // This class stores the states of all flags at construct time,
1664 // and restores all flags to that state at destruct time.
1665 // Its major implementation challenge is that it never modifies
1666 // pointers in the 'main' registry, so global FLAG_* vars always
1667 // point to the right place.
1668 // --------------------------------------------------------------------
1669
1670 class FlagSaverImpl {
1671 public:
1672 // Constructs an empty FlagSaverImpl object.
FlagSaverImpl(FlagRegistry * main_registry)1673 explicit FlagSaverImpl(FlagRegistry* main_registry)
1674 : main_registry_(main_registry) { }
~FlagSaverImpl()1675 ~FlagSaverImpl() {
1676 // reclaim memory from each of our CommandLineFlags
1677 vector<CommandLineFlag*>::const_iterator it;
1678 for (it = backup_registry_.begin(); it != backup_registry_.end(); ++it)
1679 delete *it;
1680 }
1681
1682 // Saves the flag states from the flag registry into this object.
1683 // It's an error to call this more than once.
1684 // Must be called when the registry mutex is not held.
SaveFromRegistry()1685 void SaveFromRegistry() {
1686 FlagRegistryLock frl(main_registry_);
1687 assert(backup_registry_.empty()); // call only once!
1688 for (FlagRegistry::FlagConstIterator it = main_registry_->flags_.begin();
1689 it != main_registry_->flags_.end();
1690 ++it) {
1691 const CommandLineFlag* main = it->second;
1692 // Sets up all the const variables in backup correctly
1693 CommandLineFlag* backup = new CommandLineFlag(
1694 main->name(), main->help(), main->filename(),
1695 main->current_->New(), main->defvalue_->New());
1696 // Sets up all the non-const variables in backup correctly
1697 backup->CopyFrom(*main);
1698 backup_registry_.push_back(backup); // add it to a convenient list
1699 }
1700 }
1701
1702 // Restores the saved flag states into the flag registry. We
1703 // assume no flags were added or deleted from the registry since
1704 // the SaveFromRegistry; if they were, that's trouble! Must be
1705 // called when the registry mutex is not held.
RestoreToRegistry()1706 void RestoreToRegistry() {
1707 FlagRegistryLock frl(main_registry_);
1708 vector<CommandLineFlag*>::const_iterator it;
1709 for (it = backup_registry_.begin(); it != backup_registry_.end(); ++it) {
1710 CommandLineFlag* main = main_registry_->FindFlagLocked((*it)->name());
1711 if (main != NULL) { // if NULL, flag got deleted from registry(!)
1712 main->CopyFrom(**it);
1713 }
1714 }
1715 }
1716
1717 private:
1718 FlagRegistry* const main_registry_;
1719 vector<CommandLineFlag*> backup_registry_;
1720
1721 FlagSaverImpl(const FlagSaverImpl&); // no copying!
1722 void operator=(const FlagSaverImpl&);
1723 };
1724
FlagSaver()1725 FlagSaver::FlagSaver()
1726 : impl_(new FlagSaverImpl(FlagRegistry::GlobalRegistry())) {
1727 impl_->SaveFromRegistry();
1728 }
1729
~FlagSaver()1730 FlagSaver::~FlagSaver() {
1731 impl_->RestoreToRegistry();
1732 delete impl_;
1733 }
1734
1735
1736 // --------------------------------------------------------------------
1737 // CommandlineFlagsIntoString()
1738 // ReadFlagsFromString()
1739 // AppendFlagsIntoFile()
1740 // ReadFromFlagsFile()
1741 // These are mostly-deprecated routines that stick the
1742 // commandline flags into a file/string and read them back
1743 // out again. I can see a use for CommandlineFlagsIntoString,
1744 // for creating a flagfile, but the rest don't seem that useful
1745 // -- some, I think, are a poor-man's attempt at FlagSaver --
1746 // and are included only until we can delete them from callers.
1747 // Note they don't save --flagfile flags (though they do save
1748 // the result of having called the flagfile, of course).
1749 // --------------------------------------------------------------------
1750
TheseCommandlineFlagsIntoString(const vector<CommandLineFlagInfo> & flags)1751 static string TheseCommandlineFlagsIntoString(
1752 const vector<CommandLineFlagInfo>& flags) {
1753 vector<CommandLineFlagInfo>::const_iterator i;
1754
1755 size_t retval_space = 0;
1756 for (i = flags.begin(); i != flags.end(); ++i) {
1757 // An (over)estimate of how much space it will take to print this flag
1758 retval_space += i->name.length() + i->current_value.length() + 5;
1759 }
1760
1761 string retval;
1762 retval.reserve(retval_space);
1763 for (i = flags.begin(); i != flags.end(); ++i) {
1764 retval += "--";
1765 retval += i->name;
1766 retval += "=";
1767 retval += i->current_value;
1768 retval += "\n";
1769 }
1770 return retval;
1771 }
1772
CommandlineFlagsIntoString()1773 string CommandlineFlagsIntoString() {
1774 vector<CommandLineFlagInfo> sorted_flags;
1775 GetAllFlags(&sorted_flags);
1776 return TheseCommandlineFlagsIntoString(sorted_flags);
1777 }
1778
ReadFlagsFromString(const string & flagfilecontents,const char *,bool errors_are_fatal)1779 bool ReadFlagsFromString(const string& flagfilecontents,
1780 const char* /*prog_name*/, // TODO(csilvers): nix this
1781 bool errors_are_fatal) {
1782 FlagRegistry* const registry = FlagRegistry::GlobalRegistry();
1783 FlagSaverImpl saved_states(registry);
1784 saved_states.SaveFromRegistry();
1785
1786 CommandLineFlagParser parser(registry);
1787 registry->Lock();
1788 parser.ProcessOptionsFromStringLocked(flagfilecontents, SET_FLAGS_VALUE);
1789 registry->Unlock();
1790 // Should we handle --help and such when reading flags from a string? Sure.
1791 HandleCommandLineHelpFlags();
1792 if (parser.ReportErrors()) {
1793 // Error. Restore all global flags to their previous values.
1794 if (errors_are_fatal)
1795 gflags_exitfunc(1);
1796 saved_states.RestoreToRegistry();
1797 return false;
1798 }
1799 return true;
1800 }
1801
1802 // TODO(csilvers): nix prog_name in favor of ProgramInvocationShortName()
AppendFlagsIntoFile(const string & filename,const char * prog_name)1803 bool AppendFlagsIntoFile(const string& filename, const char *prog_name) {
1804 FILE *fp;
1805 if (SafeFOpen(&fp, filename.c_str(), "a") != 0) {
1806 return false;
1807 }
1808
1809 if (prog_name)
1810 fprintf(fp, "%s\n", prog_name);
1811
1812 vector<CommandLineFlagInfo> flags;
1813 GetAllFlags(&flags);
1814 // But we don't want --flagfile, which leads to weird recursion issues
1815 vector<CommandLineFlagInfo>::iterator i;
1816 for (i = flags.begin(); i != flags.end(); ++i) {
1817 if (strcmp(i->name.c_str(), "flagfile") == 0) {
1818 flags.erase(i);
1819 break;
1820 }
1821 }
1822 fprintf(fp, "%s", TheseCommandlineFlagsIntoString(flags).c_str());
1823
1824 fclose(fp);
1825 return true;
1826 }
1827
ReadFromFlagsFile(const string & filename,const char * prog_name,bool errors_are_fatal)1828 bool ReadFromFlagsFile(const string& filename, const char* prog_name,
1829 bool errors_are_fatal) {
1830 return ReadFlagsFromString(ReadFileIntoString(filename.c_str()),
1831 prog_name, errors_are_fatal);
1832 }
1833
1834
1835 // --------------------------------------------------------------------
1836 // BoolFromEnv()
1837 // Int32FromEnv()
1838 // Uint32FromEnv()
1839 // Int64FromEnv()
1840 // Uint64FromEnv()
1841 // DoubleFromEnv()
1842 // StringFromEnv()
1843 // Reads the value from the environment and returns it.
1844 // We use an FlagValue to make the parsing easy.
1845 // Example usage:
1846 // DEFINE_bool(myflag, BoolFromEnv("MYFLAG_DEFAULT", false), "whatever");
1847 // --------------------------------------------------------------------
1848
BoolFromEnv(const char * v,bool dflt)1849 bool BoolFromEnv(const char *v, bool dflt) {
1850 return GetFromEnv(v, dflt);
1851 }
Int32FromEnv(const char * v,int32 dflt)1852 int32 Int32FromEnv(const char *v, int32 dflt) {
1853 return GetFromEnv(v, dflt);
1854 }
Uint32FromEnv(const char * v,uint32 dflt)1855 uint32 Uint32FromEnv(const char *v, uint32 dflt) {
1856 return GetFromEnv(v, dflt);
1857 }
Int64FromEnv(const char * v,int64 dflt)1858 int64 Int64FromEnv(const char *v, int64 dflt) {
1859 return GetFromEnv(v, dflt);
1860 }
Uint64FromEnv(const char * v,uint64 dflt)1861 uint64 Uint64FromEnv(const char *v, uint64 dflt) {
1862 return GetFromEnv(v, dflt);
1863 }
DoubleFromEnv(const char * v,double dflt)1864 double DoubleFromEnv(const char *v, double dflt) {
1865 return GetFromEnv(v, dflt);
1866 }
1867
1868 #ifdef _MSC_VER
1869 # pragma warning(push)
1870 # pragma warning(disable: 4996) // ignore getenv security warning
1871 #endif
StringFromEnv(const char * varname,const char * dflt)1872 const char *StringFromEnv(const char *varname, const char *dflt) {
1873 const char* const val = getenv(varname);
1874 return val ? val : dflt;
1875 }
1876 #ifdef _MSC_VER
1877 # pragma warning(pop)
1878 #endif
1879
1880
1881 // --------------------------------------------------------------------
1882 // RegisterFlagValidator()
1883 // RegisterFlagValidator() is the function that clients use to
1884 // 'decorate' a flag with a validation function. Once this is
1885 // done, every time the flag is set (including when the flag
1886 // is parsed from argv), the validator-function is called.
1887 // These functions return true if the validator was added
1888 // successfully, or false if not: the flag already has a validator,
1889 // (only one allowed per flag), the 1st arg isn't a flag, etc.
1890 // This function is not thread-safe.
1891 // --------------------------------------------------------------------
1892
RegisterFlagValidator(const bool * flag,bool (* validate_fn)(const char *,bool))1893 bool RegisterFlagValidator(const bool* flag,
1894 bool (*validate_fn)(const char*, bool)) {
1895 return AddFlagValidator(flag, reinterpret_cast<ValidateFnProto>(validate_fn));
1896 }
RegisterFlagValidator(const int32 * flag,bool (* validate_fn)(const char *,int32))1897 bool RegisterFlagValidator(const int32* flag,
1898 bool (*validate_fn)(const char*, int32)) {
1899 return AddFlagValidator(flag, reinterpret_cast<ValidateFnProto>(validate_fn));
1900 }
RegisterFlagValidator(const uint32 * flag,bool (* validate_fn)(const char *,uint32))1901 bool RegisterFlagValidator(const uint32* flag,
1902 bool (*validate_fn)(const char*, uint32)) {
1903 return AddFlagValidator(flag, reinterpret_cast<ValidateFnProto>(validate_fn));
1904 }
RegisterFlagValidator(const int64 * flag,bool (* validate_fn)(const char *,int64))1905 bool RegisterFlagValidator(const int64* flag,
1906 bool (*validate_fn)(const char*, int64)) {
1907 return AddFlagValidator(flag, reinterpret_cast<ValidateFnProto>(validate_fn));
1908 }
RegisterFlagValidator(const uint64 * flag,bool (* validate_fn)(const char *,uint64))1909 bool RegisterFlagValidator(const uint64* flag,
1910 bool (*validate_fn)(const char*, uint64)) {
1911 return AddFlagValidator(flag, reinterpret_cast<ValidateFnProto>(validate_fn));
1912 }
RegisterFlagValidator(const double * flag,bool (* validate_fn)(const char *,double))1913 bool RegisterFlagValidator(const double* flag,
1914 bool (*validate_fn)(const char*, double)) {
1915 return AddFlagValidator(flag, reinterpret_cast<ValidateFnProto>(validate_fn));
1916 }
RegisterFlagValidator(const string * flag,bool (* validate_fn)(const char *,const string &))1917 bool RegisterFlagValidator(const string* flag,
1918 bool (*validate_fn)(const char*, const string&)) {
1919 return AddFlagValidator(flag, reinterpret_cast<ValidateFnProto>(validate_fn));
1920 }
1921
1922
1923 // --------------------------------------------------------------------
1924 // ParseCommandLineFlags()
1925 // ParseCommandLineNonHelpFlags()
1926 // HandleCommandLineHelpFlags()
1927 // This is the main function called from main(), to actually
1928 // parse the commandline. It modifies argc and argv as described
1929 // at the top of gflags.h. You can also divide this
1930 // function into two parts, if you want to do work between
1931 // the parsing of the flags and the printing of any help output.
1932 // --------------------------------------------------------------------
1933
ParseCommandLineFlagsInternal(int * argc,char *** argv,bool remove_flags,bool do_report)1934 static uint32 ParseCommandLineFlagsInternal(int* argc, char*** argv,
1935 bool remove_flags, bool do_report) {
1936 SetArgv(*argc, const_cast<const char**>(*argv)); // save it for later
1937
1938 FlagRegistry* const registry = FlagRegistry::GlobalRegistry();
1939 CommandLineFlagParser parser(registry);
1940
1941 // When we parse the commandline flags, we'll handle --flagfile,
1942 // --tryfromenv, etc. as we see them (since flag-evaluation order
1943 // may be important). But sometimes apps set FLAGS_tryfromenv/etc.
1944 // manually before calling ParseCommandLineFlags. We want to evaluate
1945 // those too, as if they were the first flags on the commandline.
1946 registry->Lock();
1947 parser.ProcessFlagfileLocked(FLAGS_flagfile, SET_FLAGS_VALUE);
1948 // Last arg here indicates whether flag-not-found is a fatal error or not
1949 parser.ProcessFromenvLocked(FLAGS_fromenv, SET_FLAGS_VALUE, true);
1950 parser.ProcessFromenvLocked(FLAGS_tryfromenv, SET_FLAGS_VALUE, false);
1951 registry->Unlock();
1952
1953 // Now get the flags specified on the commandline
1954 const int r = parser.ParseNewCommandLineFlags(argc, argv, remove_flags);
1955
1956 if (do_report)
1957 HandleCommandLineHelpFlags(); // may cause us to exit on --help, etc.
1958
1959 // See if any of the unset flags fail their validation checks
1960 parser.ValidateUnmodifiedFlags();
1961
1962 if (parser.ReportErrors()) // may cause us to exit on illegal flags
1963 gflags_exitfunc(1);
1964 return r;
1965 }
1966
ParseCommandLineFlags(int * argc,char *** argv,bool remove_flags)1967 uint32 ParseCommandLineFlags(int* argc, char*** argv, bool remove_flags) {
1968 return ParseCommandLineFlagsInternal(argc, argv, remove_flags, true);
1969 }
1970
ParseCommandLineNonHelpFlags(int * argc,char *** argv,bool remove_flags)1971 uint32 ParseCommandLineNonHelpFlags(int* argc, char*** argv,
1972 bool remove_flags) {
1973 return ParseCommandLineFlagsInternal(argc, argv, remove_flags, false);
1974 }
1975
1976 // --------------------------------------------------------------------
1977 // AllowCommandLineReparsing()
1978 // ReparseCommandLineNonHelpFlags()
1979 // This is most useful for shared libraries. The idea is if
1980 // a flag is defined in a shared library that is dlopen'ed
1981 // sometime after main(), you can ParseCommandLineFlags before
1982 // the dlopen, then ReparseCommandLineNonHelpFlags() after the
1983 // dlopen, to get the new flags. But you have to explicitly
1984 // Allow() it; otherwise, you get the normal default behavior
1985 // of unrecognized flags calling a fatal error.
1986 // TODO(csilvers): this isn't used. Just delete it?
1987 // --------------------------------------------------------------------
1988
AllowCommandLineReparsing()1989 void AllowCommandLineReparsing() {
1990 allow_command_line_reparsing = true;
1991 }
1992
ReparseCommandLineNonHelpFlags()1993 void ReparseCommandLineNonHelpFlags() {
1994 // We make a copy of argc and argv to pass in
1995 const vector<string>& argvs = GetArgvs();
1996 int tmp_argc = static_cast<int>(argvs.size());
1997 char** tmp_argv = new char* [tmp_argc + 1];
1998 for (int i = 0; i < tmp_argc; ++i)
1999 tmp_argv[i] = strdup(argvs[i].c_str()); // TODO(csilvers): don't dup
2000
2001 ParseCommandLineNonHelpFlags(&tmp_argc, &tmp_argv, false);
2002
2003 for (int i = 0; i < tmp_argc; ++i)
2004 free(tmp_argv[i]);
2005 delete[] tmp_argv;
2006 }
2007
ShutDownCommandLineFlags()2008 void ShutDownCommandLineFlags() {
2009 FlagRegistry::DeleteGlobalRegistry();
2010 }
2011
2012
2013 } // namespace GFLAGS_NAMESPACE
2014