/* * Copyright (C) 2010, The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef LATINIME_DEFINES_H #define LATINIME_DEFINES_H #include #if defined(FLAG_DO_PROFILE) || defined(FLAG_DBG) #include #ifndef LOG_TAG #define LOG_TAG "LatinIME: " #endif #define AKLOGE(fmt, ...) __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, fmt, ##__VA_ARGS__) #define AKLOGI(fmt, ...) __android_log_print(ANDROID_LOG_INFO, LOG_TAG, fmt, ##__VA_ARGS__) #define DUMP_RESULT(words, frequencies, maxWordCount, maxWordLength) do { \ dumpResult(words, frequencies, maxWordCount, maxWordLength); } while (0) #define DUMP_WORD(word, length) do { dumpWord(word, length); } while (0) #define DUMP_WORD_INT(word, length) do { dumpWordInt(word, length); } while (0) // TODO: INTS_TO_CHARS #define SHORTS_TO_CHARS(input, length, output) do { \ shortArrayToCharArray(input, length, output); } while (0) static inline void dumpWordInfo(const unsigned short *word, const int length, const int rank, const int frequency) { static char charBuf[50]; int i = 0; for (; i < length; ++i) { const unsigned short c = word[i]; if (c == 0) { break; } // static_cast only for debugging charBuf[i] = static_cast(c); } charBuf[i] = 0; if (i > 1) { AKLOGI("%2d [ %s ] (%d)", rank, charBuf, frequency); } } static inline void dumpResult( const unsigned short *outWords, const int *frequencies, const int maxWordCounts, const int maxWordLength) { AKLOGI("--- DUMP RESULT ---------"); for (int i = 0; i < maxWordCounts; ++i) { dumpWordInfo(&outWords[i * maxWordLength], maxWordLength, i, frequencies[i]); } AKLOGI("-------------------------"); } static inline void dumpWord(const unsigned short *word, const int length) { static char charBuf[50]; int i = 0; for (; i < length; ++i) { const unsigned short c = word[i]; if (c == 0) { break; } // static_cast only for debugging charBuf[i] = static_cast(c); } charBuf[i] = 0; if (i > 1) { AKLOGI("[ %s ]", charBuf); } } static inline void dumpWordInt(const int *word, const int length) { static char charBuf[50]; for (int i = 0; i < length; ++i) { charBuf[i] = word[i]; } charBuf[length] = 0; AKLOGI("i[ %s ]", charBuf); } // TODO: Change this to intArrayToCharArray static inline void shortArrayToCharArray( const unsigned short *input, const int length, char *output) { int i = 0; for (;i < length; ++i) { const unsigned short c = input[i]; if (c == 0) { break; } // static_cast only for debugging output[i] = static_cast(c); } output[i] = 0; } #ifndef __ANDROID__ #include #include #include #define ASSERT(success) do { if (!(success)) { showStackTrace(); assert(success);} } while (0) #define SHOW_STACK_TRACE do { showStackTrace(); } while (0) static inline void showStackTrace() { void *callstack[128]; int i, frames = backtrace(callstack, 128); char **strs = backtrace_symbols(callstack, frames); for (i = 0; i < frames; ++i) { if (i == 0) { AKLOGI("=== Trace ==="); continue; } AKLOGI("%s", strs[i]); } free(strs); } #else #include #define ASSERT(success) assert(success) #define SHOW_STACK_TRACE #endif #else #define AKLOGE(fmt, ...) #define AKLOGI(fmt, ...) #define DUMP_RESULT(words, frequencies, maxWordCount, maxWordLength) #define DUMP_WORD(word, length) #define DUMP_WORD_INT(word, length) #define ASSERT(success) #define SHOW_STACK_TRACE // TODO: INTS_TO_CHARS #define SHORTS_TO_CHARS(input, length, output) #endif #ifdef FLAG_DO_PROFILE // Profiler #include #define PROF_BUF_SIZE 100 static float profile_buf[PROF_BUF_SIZE]; static float profile_old[PROF_BUF_SIZE]; static unsigned int profile_counter[PROF_BUF_SIZE]; #define PROF_RESET prof_reset() #define PROF_COUNT(prof_buf_id) ++profile_counter[prof_buf_id] #define PROF_OPEN do { PROF_RESET; PROF_START(PROF_BUF_SIZE - 1); } while (0) #define PROF_START(prof_buf_id) do { \ PROF_COUNT(prof_buf_id); profile_old[prof_buf_id] = (clock()); } while (0) #define PROF_CLOSE do { PROF_END(PROF_BUF_SIZE - 1); PROF_OUTALL; } while (0) #define PROF_END(prof_buf_id) profile_buf[prof_buf_id] += ((clock()) - profile_old[prof_buf_id]) #define PROF_CLOCKOUT(prof_buf_id) \ AKLOGI("%s : clock is %f", __FUNCTION__, (clock() - profile_old[prof_buf_id])) #define PROF_OUTALL do { AKLOGI("--- %s ---", __FUNCTION__); prof_out(); } while (0) static inline void prof_reset(void) { for (int i = 0; i < PROF_BUF_SIZE; ++i) { profile_buf[i] = 0; profile_old[i] = 0; profile_counter[i] = 0; } } static inline void prof_out(void) { if (profile_counter[PROF_BUF_SIZE - 1] != 1) { AKLOGI("Error: You must call PROF_OPEN before PROF_CLOSE."); } AKLOGI("Total time is %6.3f ms.", profile_buf[PROF_BUF_SIZE - 1] * 1000.0f / static_cast(CLOCKS_PER_SEC)); float all = 0; for (int i = 0; i < PROF_BUF_SIZE - 1; ++i) { all += profile_buf[i]; } if (all == 0) all = 1; for (int i = 0; i < PROF_BUF_SIZE - 1; ++i) { if (profile_buf[i]) { AKLOGI("(%d): Used %4.2f%%, %8.4f ms. Called %d times.", i, (profile_buf[i] * 100 / all), profile_buf[i] * 1000.0f / static_cast(CLOCKS_PER_SEC), profile_counter[i]); } } } #else // FLAG_DO_PROFILE #define PROF_BUF_SIZE 0 #define PROF_RESET #define PROF_COUNT(prof_buf_id) #define PROF_OPEN #define PROF_START(prof_buf_id) #define PROF_CLOSE #define PROF_END(prof_buf_id) #define PROF_CLOCK_OUT(prof_buf_id) #define PROF_CLOCKOUT(prof_buf_id) #define PROF_OUTALL #endif // FLAG_DO_PROFILE #ifdef FLAG_DBG #define DEBUG_DICT true #define DEBUG_DICT_FULL false #define DEBUG_EDIT_DISTANCE false #define DEBUG_SHOW_FOUND_WORD false #define DEBUG_NODE DEBUG_DICT_FULL #define DEBUG_TRACE DEBUG_DICT_FULL #define DEBUG_PROXIMITY_INFO false #define DEBUG_PROXIMITY_CHARS false #define DEBUG_CORRECTION false #define DEBUG_CORRECTION_FREQ false #define DEBUG_WORDS_PRIORITY_QUEUE false #ifdef FLAG_FULL_DBG #define DEBUG_GEO_FULL true #else #define DEBUG_GEO_FULL false #endif #else // FLAG_DBG #define DEBUG_DICT false #define DEBUG_DICT_FULL false #define DEBUG_EDIT_DISTANCE false #define DEBUG_SHOW_FOUND_WORD false #define DEBUG_NODE false #define DEBUG_TRACE false #define DEBUG_PROXIMITY_INFO false #define DEBUG_PROXIMITY_CHARS false #define DEBUG_CORRECTION false #define DEBUG_CORRECTION_FREQ false #define DEBUG_WORDS_PRIORITY_QUEUE false #define DEBUG_GEO_FULL false #endif // FLAG_DBG #ifndef U_SHORT_MAX #define U_SHORT_MAX 65535 // ((1 << 16) - 1) #endif #ifndef S_INT_MAX #define S_INT_MAX 2147483647 // ((1 << 31) - 1) #endif #ifndef S_INT_MIN // The literal constant -2147483648 does not work in C prior C90, because // the compiler tries to fit the positive number into an int and then negate it. // GCC warns about this. #define S_INT_MIN (-2147483647 - 1) // -(1 << 31) #endif // Define this to use mmap() for dictionary loading. Undefine to use malloc() instead of mmap(). // We measured and compared performance of both, and found mmap() is fairly good in terms of // loading time, and acceptable even for several initial lookups which involve page faults. #define USE_MMAP_FOR_DICTIONARY // 22-bit address = ~4MB dictionary size limit, which on average would be about 200k-300k words #define ADDRESS_MASK 0x3FFFFF // The bit that decides if an address follows in the next 22 bits #define FLAG_ADDRESS_MASK 0x40 // The bit that decides if this is a terminal node for a word. The node could still have children, // if the word has other endings. #define FLAG_TERMINAL_MASK 0x80 #define FLAG_BIGRAM_READ 0x80 #define FLAG_BIGRAM_CHILDEXIST 0x40 #define FLAG_BIGRAM_CONTINUED 0x80 #define FLAG_BIGRAM_FREQ 0x7F #define DICTIONARY_VERSION_MIN 200 #define NOT_VALID_WORD (-99) #define NOT_A_CODE_POINT (-1) #define NOT_A_DISTANCE (-1) #define NOT_A_COORDINATE (-1) #define EQUIVALENT_CHAR_WITHOUT_DISTANCE_INFO (-2) #define PROXIMITY_CHAR_WITHOUT_DISTANCE_INFO (-3) #define ADDITIONAL_PROXIMITY_CHAR_DISTANCE_INFO (-4) #define NOT_AN_INDEX (-1) #define NOT_A_PROBABILITY (-1) #define KEYCODE_SPACE ' ' #define CALIBRATE_SCORE_BY_TOUCH_COORDINATES true #define SUGGEST_WORDS_WITH_MISSING_CHARACTER true #define SUGGEST_WORDS_WITH_EXCESSIVE_CHARACTER true #define SUGGEST_WORDS_WITH_TRANSPOSED_CHARACTERS true #define SUGGEST_MULTIPLE_WORDS true // The following "rate"s are used as a multiplier before dividing by 100, so they are in percent. #define WORDS_WITH_MISSING_CHARACTER_DEMOTION_RATE 80 #define WORDS_WITH_MISSING_CHARACTER_DEMOTION_START_POS_10X 12 #define WORDS_WITH_MISSING_SPACE_CHARACTER_DEMOTION_RATE 58 #define WORDS_WITH_MISTYPED_SPACE_DEMOTION_RATE 50 #define WORDS_WITH_EXCESSIVE_CHARACTER_DEMOTION_RATE 75 #define WORDS_WITH_EXCESSIVE_CHARACTER_OUT_OF_PROXIMITY_DEMOTION_RATE 75 #define WORDS_WITH_TRANSPOSED_CHARACTERS_DEMOTION_RATE 70 #define FULL_MATCHED_WORDS_PROMOTION_RATE 120 #define WORDS_WITH_PROXIMITY_CHARACTER_DEMOTION_RATE 90 #define WORDS_WITH_ADDITIONAL_PROXIMITY_CHARACTER_DEMOTION_RATE 70 #define WORDS_WITH_MATCH_SKIP_PROMOTION_RATE 105 #define WORDS_WITH_JUST_ONE_CORRECTION_PROMOTION_RATE 148 #define WORDS_WITH_JUST_ONE_CORRECTION_PROMOTION_MULTIPLIER 3 #define CORRECTION_COUNT_RATE_DEMOTION_RATE_BASE 45 #define INPUT_EXCEEDS_OUTPUT_DEMOTION_RATE 70 #define FIRST_CHAR_DIFFERENT_DEMOTION_RATE 96 #define TWO_WORDS_CAPITALIZED_DEMOTION_RATE 50 #define TWO_WORDS_CORRECTION_DEMOTION_BASE 80 #define TWO_WORDS_PLUS_OTHER_ERROR_CORRECTION_DEMOTION_DIVIDER 1 #define ZERO_DISTANCE_PROMOTION_RATE 110 #define NEUTRAL_SCORE_SQUARED_RADIUS 8.0f #define HALF_SCORE_SQUARED_RADIUS 32.0f #define MAX_FREQ 255 #define MAX_BIGRAM_FREQ 15 // This must be greater than or equal to MAX_WORD_LENGTH defined in BinaryDictionary.java // This is only used for the size of array. Not to be used in c functions. #define MAX_WORD_LENGTH_INTERNAL 48 // This must be the same as ProximityInfo#MAX_PROXIMITY_CHARS_SIZE, currently it's 16. #define MAX_PROXIMITY_CHARS_SIZE_INTERNAL 16 // This must be equal to ADDITIONAL_PROXIMITY_CHAR_DELIMITER_CODE in KeyDetector.java #define ADDITIONAL_PROXIMITY_CHAR_DELIMITER_CODE 2 // Assuming locale strings such as en_US, sr-Latn etc. #define MAX_LOCALE_STRING_LENGTH 10 // Word limit for sub queues used in WordsPriorityQueuePool. Sub queues are temporary queues used // for better performance. // Holds up to 1 candidate for each word #define SUB_QUEUE_MAX_WORDS 1 #define SUB_QUEUE_MAX_COUNT 10 #define SUB_QUEUE_MIN_WORD_LENGTH 4 // TODO: Extend this limitation #define MULTIPLE_WORDS_SUGGESTION_MAX_WORDS 5 // TODO: Remove this limitation #define MULTIPLE_WORDS_SUGGESTION_MAX_WORD_LENGTH 12 // TODO: Remove this limitation #define MULTIPLE_WORDS_SUGGESTION_MAX_TOTAL_TRAVERSE_COUNT 45 #define MULTIPLE_WORDS_DEMOTION_RATE 80 #define MIN_INPUT_LENGTH_FOR_THREE_OR_MORE_WORDS_CORRECTION 6 #define TWO_WORDS_CORRECTION_WITH_OTHER_ERROR_THRESHOLD 0.35 #define START_TWO_WORDS_CORRECTION_THRESHOLD 0.185 /* heuristic... This should be changed if we change the unit of the frequency. */ #define SUPPRESS_SHORT_MULTIPLE_WORDS_THRESHOLD_FREQ (MAX_FREQ * 58 / 100) #define MAX_DEPTH_MULTIPLIER 3 #define FIRST_WORD_INDEX 0 #define MAX_SPACES_INTERNAL 16 // Max Distance between point to key #define MAX_POINT_TO_KEY_LENGTH 10000000 // The max number of the keys in one keyboard layout #define MAX_KEY_COUNT_IN_A_KEYBOARD 64 // TODO: Reduce this constant if possible; check the maximum number of digraphs in the same // word in the dictionary for languages with digraphs, like German and French #define DEFAULT_MAX_DIGRAPH_SEARCH_DEPTH 5 #define MIN_USER_TYPED_LENGTH_FOR_MULTIPLE_WORD_SUGGESTION 3 #define MIN_USER_TYPED_LENGTH_FOR_EXCESSIVE_CHARACTER_SUGGESTION 3 // TODO: Remove #define MAX_POINTER_COUNT_FOR_G 2 // Size, in bytes, of the bloom filter index for bigrams // 128 gives us 1024 buckets. The probability of false positive is (1 - e ** (-kn/m))**k, // where k is the number of hash functions, n the number of bigrams, and m the number of // bits we can test. // At the moment 100 is the maximum number of bigrams for a word with the current // dictionaries, so n = 100. 1024 buckets give us m = 1024. // With 1 hash function, our false positive rate is about 9.3%, which should be enough for // our uses since we are only using this to increase average performance. For the record, // k = 2 gives 3.1% and k = 3 gives 1.6%. With k = 1, making m = 2048 gives 4.8%, // and m = 4096 gives 2.4%. #define BIGRAM_FILTER_BYTE_SIZE 128 // Must be smaller than BIGRAM_FILTER_BYTE_SIZE * 8, and preferably prime. 1021 is the largest // prime under 128 * 8. #define BIGRAM_FILTER_MODULO 1021 #if BIGRAM_FILTER_BYTE_SIZE * 8 < BIGRAM_FILTER_MODULO #error "BIGRAM_FILTER_MODULO is larger than BIGRAM_FILTER_BYTE_SIZE" #endif template inline T min(T a, T b) { return a < b ? a : b; } template inline T max(T a, T b) { return a > b ? a : b; } // The ratio of neutral area radius to sweet spot radius. #define NEUTRAL_AREA_RADIUS_RATIO 1.3f // DEBUG #define INPUTLENGTH_FOR_DEBUG (-1) #define MIN_OUTPUT_INDEX_FOR_DEBUG (-1) #define DISALLOW_COPY_AND_ASSIGN(TypeName) \ TypeName(const TypeName&); \ void operator=(const TypeName&) #define DISALLOW_IMPLICIT_CONSTRUCTORS(TypeName) \ TypeName(); \ DISALLOW_COPY_AND_ASSIGN(TypeName) // Used as a return value for character comparison typedef enum { // Same char, possibly with different case or accent EQUIVALENT_CHAR, // It is a char located nearby on the keyboard NEAR_PROXIMITY_CHAR, // It is an unrelated char UNRELATED_CHAR, // Additional proximity char which can differ by language. ADDITIONAL_PROXIMITY_CHAR } ProximityType; #endif // LATINIME_DEFINES_H