/****************************************************************************** ** Filename: intfx.c ** Purpose: Integer character normalization & feature extraction ** Author: Robert Moss ** History: Tue May 21 15:51:57 MDT 1991, RWM, Created. ** ** (c) Copyright Hewlett-Packard Company, 1988. ** 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. ******************************************************************************/ /**---------------------------------------------------------------------------- Include Files and Type Defines ----------------------------------------------------------------------------**/ #include "intfx.h" #include "intmatcher.h" #include "const.h" #ifdef __UNIX__ #endif /**---------------------------------------------------------------------------- Private Function Prototypes ----------------------------------------------------------------------------**/ int SaveFeature(); uinT8 TableLookup(); uinT8 MySqrt2(); void ClipRadius(); INT_VAR(classify_radius_gyr_min_man, 255, "Minimum Radius of Gyration Mantissa 0-255: "); INT_VAR(classify_radius_gyr_min_exp, 0, "Minimum Radius of Gyration Exponent 0-255: "); INT_VAR(classify_radius_gyr_max_man, 158, "Maximum Radius of Gyration Mantissa 0-255: "); INT_VAR(classify_radius_gyr_max_exp, 8, "Maximum Radius of Gyration Exponent 0-255: "); /**---------------------------------------------------------------------------- Global Data Definitions and Declarations ----------------------------------------------------------------------------**/ #define ATAN_TABLE_SIZE 64 static uinT8 AtanTable[ATAN_TABLE_SIZE]; /**---------------------------------------------------------------------------- Public Code ----------------------------------------------------------------------------**/ /*---------------------------------------------------------------------------*/ void InitIntegerFX() { int i; for (i = 0; i < ATAN_TABLE_SIZE; i++) AtanTable[i] = (uinT8) (atan ((i / (float) ATAN_TABLE_SIZE)) * 128.0 / PI + 0.5); } /*--------------------------------------------------------------------------*/ int ExtractIntFeat(TBLOB *Blob, INT_FEATURE_ARRAY BLFeat, INT_FEATURE_ARRAY CNFeat, INT_FX_RESULT Results) { TESSLINE *OutLine; EDGEPT *Loop, *LoopStart, *Segment; inT16 LastX, LastY, Xmean, Ymean; inT32 NormX, NormY, DeltaX, DeltaY; inT32 Xsum, Ysum; uinT32 Ix, Iy, LengthSum; uinT16 n; uinT8 Theta; uinT16 NumBLFeatures, NumCNFeatures; uinT8 RxInv, RyInv; /* x.xxxxxxx * 2^Exp */ uinT8 RxExp, RyExp; /* sxxxxxxxxxxxxxxxxxxxxxxx.xxxxxxxx */ register inT32 pfX, pfY, dX, dY; uinT16 Length; register int i; Results->Length = 0; Results->Xmean = 0; Results->Ymean = 0; Results->Rx = 0; Results->Ry = 0; Results->NumBL = 0; Results->NumCN = 0; /* find Xmean, Ymean */ NumBLFeatures = 0; NumCNFeatures = 0; OutLine = Blob->outlines; Xsum = 0; Ysum = 0; LengthSum = 0; while (OutLine != NULL) { LoopStart = OutLine->loop; Loop = LoopStart; LastX = Loop->pos.x; LastY = Loop->pos.y; /* Check for bad loops */ if ((Loop == NULL) || (Loop->next == NULL) || (Loop->next == LoopStart)) return FALSE; do { Segment = Loop; Loop = Loop->next; NormX = Loop->pos.x; NormY = Loop->pos.y; n = 1; if (!is_hidden_edge (Segment)) { DeltaX = NormX - LastX; DeltaY = NormY - LastY; Length = MySqrt (DeltaX, DeltaY); n = ((Length << 2) + Length + 32) >> 6; if (n != 0) { Xsum += ((LastX << 1) + DeltaX) * (int) Length; Ysum += ((LastY << 1) + DeltaY) * (int) Length; LengthSum += Length; } } if (n != 0) { /* Throw away a point that is too close */ LastX = NormX; LastY = NormY; } } while (Loop != LoopStart); OutLine = OutLine->next; } if (LengthSum == 0) return FALSE; Xmean = (Xsum / (inT32) LengthSum) >> 1; Ymean = (Ysum / (inT32) LengthSum) >> 1; Results->Length = LengthSum; Results->Xmean = Xmean; Results->Ymean = Ymean; /* extract Baseline normalized features, */ /* and find 2nd moments & radius of gyration */ Ix = 0; Iy = 0; NumBLFeatures = 0; OutLine = Blob->outlines; while (OutLine != NULL) { LoopStart = OutLine->loop; Loop = LoopStart; LastX = Loop->pos.x - Xmean; LastY = Loop->pos.y; /* Check for bad loops */ if ((Loop == NULL) || (Loop->next == NULL) || (Loop->next == LoopStart)) return FALSE; do { Segment = Loop; Loop = Loop->next; NormX = Loop->pos.x - Xmean; NormY = Loop->pos.y; n = 1; if (!is_hidden_edge (Segment)) { DeltaX = NormX - LastX; DeltaY = NormY - LastY; Length = MySqrt (DeltaX, DeltaY); n = ((Length << 2) + Length + 32) >> 6; if (n != 0) { Theta = TableLookup (DeltaY, DeltaX); dX = (DeltaX << 8) / n; dY = (DeltaY << 8) / n; pfX = (LastX << 8) + (dX >> 1); pfY = (LastY << 8) + (dY >> 1); Ix += ((pfY >> 8) - Ymean) * ((pfY >> 8) - Ymean); Iy += (pfX >> 8) * (pfX >> 8); if (SaveFeature (BLFeat, NumBLFeatures, (inT16) (pfX >> 8), (inT16) ((pfY >> 8) - 128), Theta) == FALSE) return FALSE; NumBLFeatures++; for (i = 1; i < n; i++) { pfX += dX; pfY += dY; Ix += ((pfY >> 8) - Ymean) * ((pfY >> 8) - Ymean); Iy += (pfX >> 8) * (pfX >> 8); if (SaveFeature (BLFeat, NumBLFeatures, (inT16) (pfX >> 8), (inT16) ((pfY >> 8) - 128), Theta) == FALSE) return FALSE; NumBLFeatures++; } } } if (n != 0) { /* Throw away a point that is too close */ LastX = NormX; LastY = NormY; } } while (Loop != LoopStart); OutLine = OutLine->next; } if (Ix == 0) Ix = 1; if (Iy == 0) Iy = 1; RxInv = MySqrt2 (NumBLFeatures, Ix, &RxExp); RyInv = MySqrt2 (NumBLFeatures, Iy, &RyExp); ClipRadius(&RxInv, &RxExp, &RyInv, &RyExp); Results->Rx = (inT16) (51.2 / (double) RxInv * pow (2.0, (double) RxExp)); Results->Ry = (inT16) (51.2 / (double) RyInv * pow (2.0, (double) RyExp)); if (Results->Ry == 0) { /* This would result in features having 'nan' values. Since the expression is always > 0, assign a value of 1. */ Results->Ry = 1; } Results->NumBL = NumBLFeatures; /* extract character normalized features */ NumCNFeatures = 0; OutLine = Blob->outlines; while (OutLine != NULL) { LoopStart = OutLine->loop; Loop = LoopStart; LastX = (Loop->pos.x - Xmean) * RyInv; LastY = (Loop->pos.y - Ymean) * RxInv; LastX >>= (inT8) RyExp; LastY >>= (inT8) RxExp; /* Check for bad loops */ if ((Loop == NULL) || (Loop->next == NULL) || (Loop->next == LoopStart)) return FALSE; do { Segment = Loop; Loop = Loop->next; NormX = (Loop->pos.x - Xmean) * RyInv; NormY = (Loop->pos.y - Ymean) * RxInv; NormX >>= (inT8) RyExp; NormY >>= (inT8) RxExp; n = 1; if (!is_hidden_edge (Segment)) { DeltaX = NormX - LastX; DeltaY = NormY - LastY; Length = MySqrt (DeltaX, DeltaY); n = ((Length << 2) + Length + 32) >> 6; if (n != 0) { Theta = TableLookup (DeltaY, DeltaX); dX = (DeltaX << 8) / n; dY = (DeltaY << 8) / n; pfX = (LastX << 8) + (dX >> 1); pfY = (LastY << 8) + (dY >> 1); if (SaveFeature (CNFeat, NumCNFeatures, (inT16) (pfX >> 8), (inT16) ((pfY >> 8)), Theta) == FALSE) return FALSE; NumCNFeatures++; for (i = 1; i < n; i++) { pfX += dX; pfY += dY; if (SaveFeature (CNFeat, NumCNFeatures, (inT16) (pfX >> 8), (inT16) ((pfY >> 8)), Theta) == FALSE) return FALSE; NumCNFeatures++; } } } if (n != 0) { /* Throw away a point that is too close */ LastX = NormX; LastY = NormY; } } while (Loop != LoopStart); OutLine = OutLine->next; } Results->NumCN = NumCNFeatures; return TRUE; } /*--------------------------------------------------------------------------*/ uinT8 TableLookup(inT32 Y, inT32 X) { inT16 Angle; uinT16 Ratio; uinT32 AbsX, AbsY; assert ((X != 0) || (Y != 0)); if (X < 0) AbsX = -X; else AbsX = X; if (Y < 0) AbsY = -Y; else AbsY = Y; if (AbsX > AbsY) Ratio = AbsY * ATAN_TABLE_SIZE / AbsX; else Ratio = AbsX * ATAN_TABLE_SIZE / AbsY; if (Ratio >= ATAN_TABLE_SIZE) Ratio = ATAN_TABLE_SIZE - 1; Angle = AtanTable[Ratio]; if (X >= 0) if (Y >= 0) if (AbsX > AbsY) Angle = Angle; else Angle = 64 - Angle; else if (AbsX > AbsY) Angle = 256 - Angle; else Angle = 192 + Angle; else if (Y >= 0) if (AbsX > AbsY) Angle = 128 - Angle; else Angle = 64 + Angle; else if (AbsX > AbsY) Angle = 128 + Angle; else Angle = 192 - Angle; /* reverse angles to match old feature extractor: Angle += PI */ Angle += 128; Angle &= 255; return (uinT8) Angle; } /*--------------------------------------------------------------------------*/ int SaveFeature(INT_FEATURE_ARRAY FeatureArray, uinT16 FeatureNum, inT16 X, inT16 Y, uinT8 Theta) { INT_FEATURE Feature; if (FeatureNum >= MAX_NUM_INT_FEATURES) return FALSE; Feature = &(FeatureArray[FeatureNum]); X = X + 128; Y = Y + 128; if (X > 255) Feature->X = 255; else if (X < 0) Feature->X = 0; else Feature->X = X; if (Y > 255) Feature->Y = 255; else if (Y < 0) Feature->Y = 0; else Feature->Y = Y; Feature->Theta = Theta; return TRUE; } /*---------------------------------------------------------------------------*/ uinT16 MySqrt(inT32 X, inT32 Y) { register uinT16 SqRoot; register uinT32 Square; register uinT16 BitLocation; register uinT32 Sum; if (X < 0) X = -X; if (Y < 0) Y = -Y; if (X > EvidenceMultMask) X = EvidenceMultMask; if (Y > EvidenceMultMask) Y = EvidenceMultMask; Sum = X * X + Y * Y; BitLocation = 1024; SqRoot = 0; do { Square = (SqRoot | BitLocation) * (SqRoot | BitLocation); if (Square <= Sum) SqRoot |= BitLocation; BitLocation >>= 1; } while (BitLocation); return SqRoot; } /*--------------------------------------------------------------------------*/ uinT8 MySqrt2(uinT16 N, uinT32 I, uinT8 *Exp) { register inT8 k; register uinT32 N2; register uinT8 SqRoot; register uinT16 Square; register uinT8 BitLocation; register uinT16 Ratio; N2 = N * 41943; k = 9; while ((N2 & 0xc0000000) == 0) { N2 <<= 2; k += 1; } while ((I & 0xc0000000) == 0) { I <<= 2; k -= 1; } if (((N2 & 0x80000000) == 0) && ((I & 0x80000000) == 0)) { N2 <<= 1; I <<= 1; } N2 &= 0xffff0000; I >>= 14; Ratio = N2 / I; BitLocation = 128; SqRoot = 0; do { Square = (SqRoot | BitLocation) * (SqRoot | BitLocation); if (Square <= Ratio) SqRoot |= BitLocation; BitLocation >>= 1; } while (BitLocation); if (k < 0) { *Exp = 0; return 255; } else { *Exp = k; return SqRoot; } } /*-------------------------------------------------------------------------*/ void ClipRadius(uinT8 *RxInv, uinT8 *RxExp, uinT8 *RyInv, uinT8 *RyExp) { register uinT8 AM, BM, AE, BE; register uinT8 BitN, LastCarry; int RxInvLarge, RyInvSmall; AM = classify_radius_gyr_min_man; AE = classify_radius_gyr_min_exp; BM = *RxInv; BE = *RxExp; LastCarry = 1; while ((AM != 0) || (BM != 0)) { if (AE > BE) { BitN = LastCarry + (AM & 1) + 1; AM >>= 1; AE--; } else if (AE < BE) { BitN = LastCarry + (!(BM & 1)); BM >>= 1; BE--; } else { /* AE == BE */ BitN = LastCarry + (AM & 1) + (!(BM & 1)); AM >>= 1; BM >>= 1; AE--; BE--; } LastCarry = (BitN & 2) > 1; BitN = BitN & 1; } BitN = LastCarry + 1; LastCarry = (BitN & 2) > 1; BitN = BitN & 1; if (BitN == 1) { *RxInv = classify_radius_gyr_min_man; *RxExp = classify_radius_gyr_min_exp; } AM = classify_radius_gyr_min_man; AE = classify_radius_gyr_min_exp; BM = *RyInv; BE = *RyExp; LastCarry = 1; while ((AM != 0) || (BM != 0)) { if (AE > BE) { BitN = LastCarry + (AM & 1) + 1; AM >>= 1; AE--; } else if (AE < BE) { BitN = LastCarry + (!(BM & 1)); BM >>= 1; BE--; } else { /* AE == BE */ BitN = LastCarry + (AM & 1) + (!(BM & 1)); AM >>= 1; BM >>= 1; AE--; BE--; } LastCarry = (BitN & 2) > 1; BitN = BitN & 1; } BitN = LastCarry + 1; LastCarry = (BitN & 2) > 1; BitN = BitN & 1; if (BitN == 1) { *RyInv = classify_radius_gyr_min_man; *RyExp = classify_radius_gyr_min_exp; } AM = classify_radius_gyr_max_man; AE = classify_radius_gyr_max_exp; BM = *RxInv; BE = *RxExp; LastCarry = 1; while ((AM != 0) || (BM != 0)) { if (AE > BE) { BitN = LastCarry + (AM & 1) + 1; AM >>= 1; AE--; } else if (AE < BE) { BitN = LastCarry + (!(BM & 1)); BM >>= 1; BE--; } else { /* AE == BE */ BitN = LastCarry + (AM & 1) + (!(BM & 1)); AM >>= 1; BM >>= 1; AE--; BE--; } LastCarry = (BitN & 2) > 1; BitN = BitN & 1; } BitN = LastCarry + 1; LastCarry = (BitN & 2) > 1; BitN = BitN & 1; if (BitN == 1) RxInvLarge = 1; else RxInvLarge = 0; AM = *RyInv; AE = *RyExp; BM = classify_radius_gyr_max_man; BE = classify_radius_gyr_max_exp; LastCarry = 1; while ((AM != 0) || (BM != 0)) { if (AE > BE) { BitN = LastCarry + (AM & 1) + 1; AM >>= 1; AE--; } else if (AE < BE) { BitN = LastCarry + (!(BM & 1)); BM >>= 1; BE--; } else { /* AE == BE */ BitN = LastCarry + (AM & 1) + (!(BM & 1)); AM >>= 1; BM >>= 1; AE--; BE--; } LastCarry = (BitN & 2) > 1; BitN = BitN & 1; } BitN = LastCarry + 1; LastCarry = (BitN & 2) > 1; BitN = BitN & 1; if (BitN == 1) RyInvSmall = 1; else RyInvSmall = 0; if (RxInvLarge && RyInvSmall) { *RyInv = classify_radius_gyr_max_man; *RyExp = classify_radius_gyr_max_exp; } }