/* -*-C-*- ******************************************************************************** * * File: protos.c (Formerly protos.c) * Description: * Author: Mark Seaman, OCR Technology * Created: Fri Oct 16 14:37:00 1987 * Modified: Mon Mar 4 14:51:24 1991 (Dan Johnson) danj@hpgrlj * Language: C * Package: N/A * Status: Reusable Software Component * * (c) Copyright 1987, Hewlett-Packard Company. ** 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. * *********************************************************************************/ /*---------------------------------------------------------------------- I n c l u d e s ----------------------------------------------------------------------*/ #include "protos.h" #include "debug.h" #include "const.h" #include "emalloc.h" #include "freelist.h" #include "callcpp.h" #include "tprintf.h" #include "adaptmatch.h" #include "scanutils.h" #include "globals.h" #include #include #define PROTO_INCREMENT 32 #define CONFIG_INCREMENT 16 /*---------------------------------------------------------------------- V a r i a b l e s ----------------------------------------------------------------------*/ CLASS_STRUCT TrainingData[NUMBER_OF_CLASSES]; char *TrainingFile; //extern int LearningDebugLevel; /*---------------------------------------------------------------------- F u n c t i o n s ----------------------------------------------------------------------*/ /********************************************************************** * AddConfigToClass * * Add a new config to this class. Malloc new space and copy the * old configs if necessary. Return the config id for the new config. **********************************************************************/ int AddConfigToClass(CLASS_TYPE Class) { int NewNumConfigs; int NewConfig; int MaxNumProtos; BIT_VECTOR Config; MaxNumProtos = Class->MaxNumProtos; if (NumConfigsIn (Class) >= Class->MaxNumConfigs) { /* add configs in CONFIG_INCREMENT chunks at a time */ NewNumConfigs = (((Class->MaxNumConfigs + CONFIG_INCREMENT) / CONFIG_INCREMENT) * CONFIG_INCREMENT); Class->Configurations = (CONFIGS) Erealloc (Class->Configurations, sizeof (BIT_VECTOR) * NewNumConfigs); Class->MaxNumConfigs = NewNumConfigs; } NewConfig = NumConfigsIn (Class); NumConfigsIn (Class)++; Config = NewBitVector (MaxNumProtos); ConfigIn (Class, NewConfig) = Config; zero_all_bits (Config, WordsInVectorOfSize (MaxNumProtos)); return (NewConfig); } /********************************************************************** * AddProtoToClass * * Add a new proto to this class. Malloc new space and copy the * old protos if necessary. Return the proto id for the new proto. **********************************************************************/ int AddProtoToClass(CLASS_TYPE Class) { int i; int Bit; int NewNumProtos; int NewProto; BIT_VECTOR Config; if (NumProtosIn (Class) >= Class->MaxNumProtos) { /* add protos in PROTO_INCREMENT chunks at a time */ NewNumProtos = (((Class->MaxNumProtos + PROTO_INCREMENT) / PROTO_INCREMENT) * PROTO_INCREMENT); Class->Prototypes = (PROTO) Erealloc (Class->Prototypes, sizeof (PROTO_STRUCT) * NewNumProtos); Class->MaxNumProtos = NewNumProtos; for (i = 0; i < NumConfigsIn (Class); i++) { Config = ConfigIn (Class, i); ConfigIn (Class, i) = ExpandBitVector (Config, NewNumProtos); for (Bit = NumProtosIn (Class); Bit < NewNumProtos; Bit++) reset_bit(Config, Bit); } } NewProto = NumProtosIn (Class); NumProtosIn (Class)++; if (NumProtosIn(Class) > MAX_NUM_PROTOS) { tprintf("Ouch! number of protos = %d, vs max of %d!", NumProtosIn(Class), MAX_NUM_PROTOS); } return (NewProto); } /********************************************************************** * ClassConfigLength * * Return the length of all the protos in this class. **********************************************************************/ FLOAT32 ClassConfigLength(CLASS_TYPE Class, BIT_VECTOR Config) { inT16 Pid; FLOAT32 TotalLength = 0; for (Pid = 0; Pid < NumProtosIn (Class); Pid++) { if (test_bit (Config, Pid)) { TotalLength += ProtoLength (ProtoIn (Class, Pid)); } } return (TotalLength); } /********************************************************************** * ClassProtoLength * * Return the length of all the protos in this class. **********************************************************************/ FLOAT32 ClassProtoLength(CLASS_TYPE Class) { inT16 Pid; FLOAT32 TotalLength = 0; for (Pid = 0; Pid < NumProtosIn (Class); Pid++) { TotalLength += ProtoLength (ProtoIn (Class, Pid)); } return (TotalLength); } /********************************************************************** * CopyProto * * Copy the first proto into the second. **********************************************************************/ void CopyProto(PROTO Src, PROTO Dest) { ProtoX (Dest) = ProtoX (Src); ProtoY (Dest) = ProtoY (Src); ProtoLength (Dest) = ProtoLength (Src); ProtoAngle (Dest) = ProtoAngle (Src); CoefficientA (Dest) = CoefficientA (Src); CoefficientB (Dest) = CoefficientB (Src); CoefficientC (Dest) = CoefficientC (Src); } /********************************************************************** * FillABC * * Fill in Protos A, B, C fields based on the X, Y, Angle fields. **********************************************************************/ void FillABC(PROTO Proto) { FLOAT32 Slope, Intercept, Normalizer; Slope = tan (Proto->Angle * 2.0 * PI); Intercept = Proto->Y - Slope * Proto->X; Normalizer = 1.0 / sqrt (Slope * Slope + 1.0); Proto->A = Slope * Normalizer; Proto->B = -Normalizer; Proto->C = Intercept * Normalizer; } /********************************************************************** * FreeClass * * Deallocate the memory consumed by the specified class. **********************************************************************/ void FreeClass(CLASS_TYPE Class) { if (Class) { FreeClassFields(Class); memfree(Class); } } /********************************************************************** * FreeClassFields * * Deallocate the memory consumed by subfields of the specified class. **********************************************************************/ void FreeClassFields(CLASS_TYPE Class) { int i; if (Class) { if (Class->MaxNumProtos > 0) memfree (Class->Prototypes); if (Class->MaxNumConfigs > 0) { for (i = 0; i < NumConfigsIn (Class); i++) FreeBitVector (ConfigIn (Class, i)); memfree (Class->Configurations); } } } /********************************************************************** * InitPrototypes * * Initialize anything that needs to be initialized to work with the * functions in this file. **********************************************************************/ void InitPrototypes() { string_variable (TrainingFile, "TrainingFile", "MicroFeatures"); } /********************************************************************** * NewClass * * Allocate a new class with enough memory to hold the specified number * of prototypes and configurations. **********************************************************************/ CLASS_TYPE NewClass(int NumProtos, int NumConfigs) { CLASS_TYPE Class; Class = (CLASS_TYPE) Emalloc (sizeof (CLASS_STRUCT)); if (NumProtos > 0) Class->Prototypes = (PROTO) Emalloc (NumProtos * sizeof (PROTO_STRUCT)); if (NumConfigs > 0) Class->Configurations = (CONFIGS) Emalloc (NumConfigs * sizeof (BIT_VECTOR)); Class->MaxNumProtos = NumProtos; Class->MaxNumConfigs = NumConfigs; Class->NumProtos = 0; Class->NumConfigs = 0; return (Class); } /********************************************************************** * PrintProtos * * Print the list of prototypes in this class type. **********************************************************************/ void PrintProtos(CLASS_TYPE Class) { inT16 Pid; for (Pid = 0; Pid < NumProtosIn (Class); Pid++) { cprintf ("Proto %d:\t", Pid); PrintProto (ProtoIn (Class, Pid)); cprintf ("\t"); PrintProtoLine (ProtoIn (Class, Pid)); new_line(); } } /********************************************************************** * ReadClassFile * * Read in the training data from a file. All of the classes are read * in. The results are stored in the global variable, 'TrainingData'. **********************************************************************/ void ReadClassFile() { FILE *File; char TextLine[CHARS_PER_LINE]; char unichar[CHARS_PER_LINE]; cprintf ("Reading training data from '%s' ...", TrainingFile); fflush(stdout); File = open_file (TrainingFile, "r"); while (fgets (TextLine, CHARS_PER_LINE, File) != NULL) { sscanf(TextLine, "%s", unichar); ReadClassFromFile (File, unicharset.unichar_to_id(unichar)); fgets(TextLine, CHARS_PER_LINE, File); fgets(TextLine, CHARS_PER_LINE, File); } fclose(File); new_line(); } /********************************************************************** * ReadClassFromFile * * Read in a class description (protos and configs) from a file. Update * the class structure record. **********************************************************************/ void ReadClassFromFile(FILE *File, UNICHAR_ID unichar_id) { CLASS_TYPE Class; Class = &TrainingData[unichar_id]; ReadProtos(File, Class); ReadConfigs(File, Class); } /********************************************************************** * ReadConfigs * * Read the prototype configurations for this class from a file. Read * the requested number of lines. **********************************************************************/ void ReadConfigs(register FILE *File, CLASS_TYPE Class) { inT16 Cid; register inT16 Wid; register BIT_VECTOR ThisConfig; int NumWords; int NumConfigs; fscanf (File, "%d %d\n", &NumConfigs, &NumWords); NumConfigsIn (Class) = NumConfigs; Class->MaxNumConfigs = NumConfigs; Class->Configurations = (CONFIGS) Emalloc (sizeof (BIT_VECTOR) * NumConfigs); NumWords = WordsInVectorOfSize (NumProtosIn (Class)); for (Cid = 0; Cid < NumConfigs; Cid++) { ThisConfig = NewBitVector (NumProtosIn (Class)); for (Wid = 0; Wid < NumWords; Wid++) fscanf (File, "%x", &ThisConfig[Wid]); ConfigIn (Class, Cid) = ThisConfig; } } /********************************************************************** * ReadProtos * * Read in all the prototype information from a file. Read the number * of lines requested. **********************************************************************/ void ReadProtos(register FILE *File, CLASS_TYPE Class) { register inT16 Pid; register PROTO Proto; int NumProtos; fscanf (File, "%d\n", &NumProtos); NumProtosIn (Class) = NumProtos; Class->MaxNumProtos = NumProtos; Class->Prototypes = (PROTO) Emalloc (sizeof (PROTO_STRUCT) * NumProtos); for (Pid = 0; Pid < NumProtos; Pid++) { Proto = ProtoIn (Class, Pid); fscanf (File, "%f %f %f %f %f %f %f\n", &ProtoX (Proto), &ProtoY (Proto), &ProtoLength (Proto), &ProtoAngle (Proto), &CoefficientA (Proto), &CoefficientB (Proto), &CoefficientC (Proto)); } } /********************************************************************** * SplitProto * * Add a new proto to this class. Malloc new space and copy the * old protos if necessary. Return the proto id for the new proto. * Update all configurations so that each config which contained the * specified old proto will also contain the new proto. The caller * is responsible for actually filling in the appropriate proto params. **********************************************************************/ int SplitProto(CLASS_TYPE Class, int OldPid) { int i; int NewPid; BIT_VECTOR Config; NewPid = AddProtoToClass (Class); for (i = 0; i < NumConfigsIn (Class); i++) { Config = ConfigIn (Class, i); if (test_bit (Config, OldPid)) SET_BIT(Config, NewPid); } return (NewPid); } /********************************************************************** * WriteOldConfigFile * * Write the configs in the given class to the specified file in the * old config format. **********************************************************************/ void WriteOldConfigFile(FILE *File, CLASS_TYPE Class) { int Cid, Pid; BIT_VECTOR Config; fprintf (File, "%d %d\n", NumConfigsIn (Class), NumProtosIn (Class)); for (Cid = 0; Cid < NumConfigsIn (Class); Cid++) { fprintf (File, "1 "); Config = ConfigIn (Class, Cid); for (Pid = 0; Pid < NumProtosIn (Class); Pid++) { if (test_bit (Config, Pid)) fprintf (File, "1"); else fprintf (File, "0"); } fprintf (File, "\n"); } } /********************************************************************** * WriteOldProtoFile * * Write the protos in the given class to the specified file in the * old proto format. **********************************************************************/ void WriteOldProtoFile(FILE *File, CLASS_TYPE Class) { int Pid; PROTO Proto; /* print old header */ fprintf (File, "6\n"); fprintf (File, "linear essential -0.500000 0.500000\n"); fprintf (File, "linear essential -0.250000 0.750000\n"); fprintf (File, "linear essential 0.000000 1.000000\n"); fprintf (File, "circular essential 0.000000 1.000000\n"); fprintf (File, "linear non-essential -0.500000 0.500000\n"); fprintf (File, "linear non-essential -0.500000 0.500000\n"); for (Pid = 0; Pid < NumProtosIn (Class); Pid++) { Proto = ProtoIn (Class, Pid); fprintf (File, "significant elliptical 1\n"); fprintf (File, " %9.6f %9.6f %9.6f %9.6f %9.6f %9.6f\n", ProtoX (Proto), ProtoY (Proto), ProtoLength (Proto), ProtoAngle (Proto), 0.0, 0.0); fprintf (File, " %9.6f %9.6f %9.6f %9.6f %9.6f %9.6f\n", 0.0001, 0.0001, 0.0001, 0.0001, 0.0001, 0.0001); } }