Adds resource_provider::ResourceProvider
[chromium-blink-merge.git] / base / i18n / build_utf8_validator_tables.cc
blobae5b1a71e9df2ad961d4f56dcf12f4ef49f73af9
1 // Copyright 2014 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 // Create a state machine for validating UTF-8. The algorithm in brief:
6 // 1. Convert the complete unicode range of code points, except for the
7 // surrogate code points, to an ordered array of sequences of bytes in
8 // UTF-8.
9 // 2. Convert individual bytes to ranges, starting from the right of each byte
10 // sequence. For each range, ensure the bytes on the left and the ranges
11 // on the right are the identical.
12 // 3. Convert the resulting list of ranges into a state machine, collapsing
13 // identical states.
14 // 4. Convert the state machine to an array of bytes.
15 // 5. Output as a C++ file.
17 // To use:
18 // $ ninja -C out/Release build_utf8_validator_tables
19 // $ out/Release/build_utf8_validator_tables
20 // --output=base/i18n/utf8_validator_tables.cc
21 // $ git add base/i18n/utf8_validator_tables.cc
23 // Because the table is not expected to ever change, it is checked into the
24 // repository rather than being regenerated at build time.
26 // This code uses type uint8 throughout to represent bytes, to avoid
27 // signed/unsigned char confusion.
29 #include <stdio.h>
30 #include <stdlib.h>
31 #include <string.h>
33 #include <algorithm>
34 #include <map>
35 #include <string>
36 #include <vector>
38 #include "base/basictypes.h"
39 #include "base/command_line.h"
40 #include "base/files/file_path.h"
41 #include "base/files/file_util.h"
42 #include "base/logging.h"
43 #include "base/numerics/safe_conversions.h"
44 #include "base/strings/stringprintf.h"
45 #include "third_party/icu/source/common/unicode/utf8.h"
47 namespace {
49 const char kHelpText[] =
50 "Usage: build_utf8_validator_tables [ --help ] [ --output=<file> ]\n";
52 const char kProlog[] =
53 "// Copyright 2013 The Chromium Authors. All rights reserved.\n"
54 "// Use of this source code is governed by a BSD-style license that can "
55 "be\n"
56 "// found in the LICENSE file.\n"
57 "\n"
58 "// This file is auto-generated by build_utf8_validator_tables.\n"
59 "// DO NOT EDIT.\n"
60 "\n"
61 "#include \"base/i18n/utf8_validator_tables.h\"\n"
62 "\n"
63 "namespace base {\n"
64 "namespace internal {\n"
65 "\n"
66 "const uint8 kUtf8ValidatorTables[] = {\n";
68 const char kEpilog[] =
69 "};\n"
70 "\n"
71 "const size_t kUtf8ValidatorTablesSize = arraysize(kUtf8ValidatorTables);\n"
72 "\n"
73 "} // namespace internal\n"
74 "} // namespace base\n";
76 // Ranges are inclusive at both ends--they represent [from, to]
77 class Range {
78 public:
79 // Ranges always start with just one byte.
80 explicit Range(uint8 value) : from_(value), to_(value) {}
82 // Range objects are copyable and assignable to be used in STL
83 // containers. Since they only contain non-pointer POD types, the default copy
84 // constructor, assignment operator and destructor will work.
86 // Add a byte to the range. We intentionally only support adding a byte at the
87 // end, since that is the only operation the code needs.
88 void AddByte(uint8 to) {
89 CHECK(to == to_ + 1);
90 to_ = to;
93 uint8 from() const { return from_; }
94 uint8 to() const { return to_; }
96 bool operator<(const Range& rhs) const {
97 return (from() < rhs.from() || (from() == rhs.from() && to() < rhs.to()));
100 bool operator==(const Range& rhs) const {
101 return from() == rhs.from() && to() == rhs.to();
104 private:
105 uint8 from_;
106 uint8 to_;
109 // A vector of Ranges is like a simple regular expression--it corresponds to
110 // a set of strings of the same length that have bytes in each position in
111 // the appropriate range.
112 typedef std::vector<Range> StringSet;
114 // A UTF-8 "character" is represented by a sequence of bytes.
115 typedef std::vector<uint8> Character;
117 // In the second stage of the algorithm, we want to convert a large list of
118 // Characters into a small list of StringSets.
119 struct Pair {
120 Character character;
121 StringSet set;
124 typedef std::vector<Pair> PairVector;
126 // A class to print a table of numbers in the same style as clang-format.
127 class TablePrinter {
128 public:
129 explicit TablePrinter(FILE* stream)
130 : stream_(stream), values_on_this_line_(0), current_offset_(0) {}
132 void PrintValue(uint8 value) {
133 if (values_on_this_line_ == 0) {
134 fputs(" ", stream_);
135 } else if (values_on_this_line_ == kMaxValuesPerLine) {
136 fprintf(stream_, " // 0x%02x\n ", current_offset_);
137 values_on_this_line_ = 0;
139 fprintf(stream_, " 0x%02x,", static_cast<int>(value));
140 ++values_on_this_line_;
141 ++current_offset_;
144 void NewLine() {
145 while (values_on_this_line_ < kMaxValuesPerLine) {
146 fputs(" ", stream_);
147 ++values_on_this_line_;
149 fprintf(stream_, " // 0x%02x\n", current_offset_);
150 values_on_this_line_ = 0;
153 private:
154 // stdio stream. Not owned.
155 FILE* stream_;
157 // Number of values so far printed on this line.
158 int values_on_this_line_;
160 // Total values printed so far.
161 int current_offset_;
163 static const int kMaxValuesPerLine = 8;
165 DISALLOW_COPY_AND_ASSIGN(TablePrinter);
168 // Start by filling a PairVector with characters. The resulting vector goes from
169 // "\x00" to "\xf4\x8f\xbf\xbf".
170 PairVector InitializeCharacters() {
171 PairVector vector;
172 for (int i = 0; i <= 0x10FFFF; ++i) {
173 if (i >= 0xD800 && i < 0xE000) {
174 // Surrogate codepoints are not permitted. Non-character code points are
175 // explicitly permitted.
176 continue;
178 uint8 bytes[4];
179 unsigned int offset = 0;
180 UBool is_error = false;
181 U8_APPEND(bytes, offset, arraysize(bytes), i, is_error);
182 DCHECK(!is_error);
183 DCHECK_GT(offset, 0u);
184 DCHECK_LE(offset, arraysize(bytes));
185 Pair pair = {Character(bytes, bytes + offset), StringSet()};
186 vector.push_back(pair);
188 return vector;
191 // Construct a new Pair from |character| and the concatenation of |new_range|
192 // and |existing_set|, and append it to |pairs|.
193 void ConstructPairAndAppend(const Character& character,
194 const Range& new_range,
195 const StringSet& existing_set,
196 PairVector* pairs) {
197 Pair new_pair = {character, StringSet(1, new_range)};
198 new_pair.set.insert(
199 new_pair.set.end(), existing_set.begin(), existing_set.end());
200 pairs->push_back(new_pair);
203 // Each pass over the PairVector strips one byte off the right-hand-side of the
204 // characters and adds a range to the set on the right. For example, the first
205 // pass converts the range from "\xe0\xa0\x80" to "\xe0\xa0\xbf" to ("\xe0\xa0",
206 // [\x80-\xbf]), then the second pass converts the range from ("\xe0\xa0",
207 // [\x80-\xbf]) to ("\xe0\xbf", [\x80-\xbf]) to ("\xe0",
208 // [\xa0-\xbf][\x80-\xbf]).
209 void MoveRightMostCharToSet(PairVector* pairs) {
210 PairVector new_pairs;
211 PairVector::const_iterator it = pairs->begin();
212 while (it != pairs->end() && it->character.empty()) {
213 new_pairs.push_back(*it);
214 ++it;
216 CHECK(it != pairs->end());
217 Character unconverted_bytes(it->character.begin(), it->character.end() - 1);
218 Range new_range(it->character.back());
219 StringSet converted = it->set;
220 ++it;
221 while (it != pairs->end()) {
222 const Pair& current_pair = *it++;
223 if (current_pair.character.size() == unconverted_bytes.size() + 1 &&
224 std::equal(unconverted_bytes.begin(),
225 unconverted_bytes.end(),
226 current_pair.character.begin()) &&
227 converted == current_pair.set) {
228 // The particular set of UTF-8 codepoints we are validating guarantees
229 // that each byte range will be contiguous. This would not necessarily be
230 // true for an arbitrary set of UTF-8 codepoints.
231 DCHECK_EQ(new_range.to() + 1, current_pair.character.back());
232 new_range.AddByte(current_pair.character.back());
233 continue;
235 ConstructPairAndAppend(unconverted_bytes, new_range, converted, &new_pairs);
236 unconverted_bytes = Character(current_pair.character.begin(),
237 current_pair.character.end() - 1);
238 new_range = Range(current_pair.character.back());
239 converted = current_pair.set;
241 ConstructPairAndAppend(unconverted_bytes, new_range, converted, &new_pairs);
242 new_pairs.swap(*pairs);
245 void MoveAllCharsToSets(PairVector* pairs) {
246 // Since each pass of the function moves one character, and UTF-8 sequences
247 // are at most 4 characters long, this simply runs the algorithm four times.
248 for (int i = 0; i < 4; ++i) {
249 MoveRightMostCharToSet(pairs);
251 #if DCHECK_IS_ON()
252 for (PairVector::const_iterator it = pairs->begin(); it != pairs->end();
253 ++it) {
254 DCHECK(it->character.empty());
256 #endif
259 // Logs the generated string sets in regular-expression style, ie. [\x00-\x7f],
260 // [\xc2-\xdf][\x80-\xbf], etc. This can be a useful sanity-check that the
261 // algorithm is working. Use the command-line option
262 // --vmodule=build_utf8_validator_tables=1 to see this output.
263 void LogStringSets(const PairVector& pairs) {
264 for (PairVector::const_iterator pair_it = pairs.begin();
265 pair_it != pairs.end();
266 ++pair_it) {
267 std::string set_as_string;
268 for (StringSet::const_iterator set_it = pair_it->set.begin();
269 set_it != pair_it->set.end();
270 ++set_it) {
271 set_as_string += base::StringPrintf("[\\x%02x-\\x%02x]",
272 static_cast<int>(set_it->from()),
273 static_cast<int>(set_it->to()));
275 VLOG(1) << set_as_string;
279 // A single state in the state machine is represented by a sorted vector of
280 // start bytes and target states. All input bytes in the range between the start
281 // byte and the next entry in the vector (or 0xFF) result in a transition to the
282 // target state.
283 struct StateRange {
284 uint8 from;
285 uint8 target_state;
288 typedef std::vector<StateRange> State;
290 // Generates a state where all bytes go to state 1 (invalid). This is also used
291 // as an initialiser for other states (since bytes from outside the desired
292 // range are invalid).
293 State GenerateInvalidState() {
294 const StateRange range = {0, 1};
295 return State(1, range);
298 // A map from a state (ie. a set of strings which will match from this state) to
299 // a number (which is an index into the array of states).
300 typedef std::map<StringSet, uint8> StateMap;
302 // Create a new state corresponding to |set|, add it |states| and |state_map|
303 // and return the index it was given in |states|.
304 uint8 MakeState(const StringSet& set,
305 std::vector<State>* states,
306 StateMap* state_map) {
307 DCHECK(!set.empty());
308 const Range& range = set.front();
309 const StringSet rest(set.begin() + 1, set.end());
310 const StateMap::const_iterator where = state_map->find(rest);
311 const uint8 target_state = where == state_map->end()
312 ? MakeState(rest, states, state_map)
313 : where->second;
314 DCHECK_LT(0, range.from());
315 DCHECK_LT(range.to(), 0xFF);
316 const StateRange new_state_initializer[] = {
317 {0, 1}, {range.from(), target_state},
318 {static_cast<uint8>(range.to() + 1), 1}};
319 states->push_back(
320 State(new_state_initializer,
321 new_state_initializer + arraysize(new_state_initializer)));
322 const uint8 new_state_number =
323 base::checked_cast<uint8>(states->size() - 1);
324 CHECK(state_map->insert(std::make_pair(set, new_state_number)).second);
325 return new_state_number;
328 std::vector<State> GenerateStates(const PairVector& pairs) {
329 // States 0 and 1 are the initial/valid state and invalid state, respectively.
330 std::vector<State> states(2, GenerateInvalidState());
331 StateMap state_map;
332 state_map.insert(std::make_pair(StringSet(), 0));
333 for (PairVector::const_iterator it = pairs.begin(); it != pairs.end(); ++it) {
334 DCHECK(it->character.empty());
335 DCHECK(!it->set.empty());
336 const Range& range = it->set.front();
337 const StringSet rest(it->set.begin() + 1, it->set.end());
338 const StateMap::const_iterator where = state_map.find(rest);
339 const uint8 target_state = where == state_map.end()
340 ? MakeState(rest, &states, &state_map)
341 : where->second;
342 if (states[0].back().from == range.from()) {
343 DCHECK_EQ(1, states[0].back().target_state);
344 states[0].back().target_state = target_state;
345 DCHECK_LT(range.to(), 0xFF);
346 const StateRange new_range = {static_cast<uint8>(range.to() + 1), 1};
347 states[0].push_back(new_range);
348 } else {
349 DCHECK_LT(range.to(), 0xFF);
350 const StateRange new_range_initializer[] = {{range.from(), target_state},
351 {static_cast<uint8>(range.to() + 1), 1}};
352 states[0]
353 .insert(states[0].end(),
354 new_range_initializer,
355 new_range_initializer + arraysize(new_range_initializer));
358 return states;
361 // Output the generated states as a C++ table. Two tricks are used to compact
362 // the table: each state in the table starts with a shift value which indicates
363 // how many bits we can discard from the right-hand-side of the byte before
364 // doing the table lookup. Secondly, only the state-transitions for bytes
365 // with the top-bit set are included in the table; bytes without the top-bit set
366 // are just ASCII and are handled directly by the code.
367 void PrintStates(const std::vector<State>& states, FILE* stream) {
368 // First calculate the start-offset of each state. This allows the state
369 // machine to jump directly to the correct offset, avoiding an extra
370 // indirection. State 0 starts at offset 0.
371 std::vector<uint8> state_offset(1, 0);
372 std::vector<uint8> shifts;
373 uint8 pos = 0;
375 for (std::vector<State>::const_iterator state_it = states.begin();
376 state_it != states.end();
377 ++state_it) {
378 // We want to set |shift| to the (0-based) index of the least-significant
379 // set bit in any of the ranges for this state, since this tells us how many
380 // bits we can discard and still determine what range a byte lies in. Sadly
381 // it appears that ffs() is not portable, so we do it clumsily.
382 uint8 shift = 7;
383 for (State::const_iterator range_it = state_it->begin();
384 range_it != state_it->end();
385 ++range_it) {
386 while (shift > 0 && range_it->from % (1 << shift) != 0) {
387 --shift;
390 shifts.push_back(shift);
391 pos += 1 + (1 << (7 - shift));
392 state_offset.push_back(pos);
395 DCHECK_EQ(129, state_offset[1]);
397 fputs(kProlog, stream);
398 TablePrinter table_printer(stream);
400 for (uint8 state_index = 0; state_index < states.size(); ++state_index) {
401 const uint8 shift = shifts[state_index];
402 uint8 next_range = 0;
403 uint8 target_state = 1;
404 fprintf(stream,
405 " // State %d, offset 0x%02x\n",
406 static_cast<int>(state_index),
407 static_cast<int>(state_offset[state_index]));
408 table_printer.PrintValue(shift);
409 for (int i = 0; i < 0x100; i += (1 << shift)) {
410 if (next_range < states[state_index].size() &&
411 states[state_index][next_range].from == i) {
412 target_state = states[state_index][next_range].target_state;
413 ++next_range;
415 if (i >= 0x80) {
416 table_printer.PrintValue(state_offset[target_state]);
419 table_printer.NewLine();
422 fputs(kEpilog, stream);
425 } // namespace
427 int main(int argc, char* argv[]) {
428 base::CommandLine::Init(argc, argv);
429 logging::LoggingSettings settings;
430 settings.logging_dest = logging::LOG_TO_SYSTEM_DEBUG_LOG;
431 logging::InitLogging(settings);
432 if (base::CommandLine::ForCurrentProcess()->HasSwitch("help")) {
433 fwrite(kHelpText, 1, arraysize(kHelpText), stdout);
434 exit(EXIT_SUCCESS);
436 base::FilePath filename =
437 base::CommandLine::ForCurrentProcess()->GetSwitchValuePath("output");
439 FILE* output = stdout;
440 if (!filename.empty()) {
441 output = base::OpenFile(filename, "wb");
442 if (!output)
443 PLOG(FATAL) << "Couldn't open '" << filename.AsUTF8Unsafe()
444 << "' for writing";
447 // Step 1: Enumerate the characters
448 PairVector pairs = InitializeCharacters();
449 // Step 2: Convert to sets.
450 MoveAllCharsToSets(&pairs);
451 if (VLOG_IS_ON(1)) {
452 LogStringSets(pairs);
454 // Step 3: Generate states.
455 std::vector<State> states = GenerateStates(pairs);
456 // Step 4/5: Print output
457 PrintStates(states, output);
459 if (!filename.empty()) {
460 if (!base::CloseFile(output))
461 PLOG(FATAL) << "Couldn't finish writing '" << filename.AsUTF8Unsafe()
462 << "'";
465 return EXIT_SUCCESS;