/* -*-C-*- ******************************************************************************** * * File: states.c (Formerly states.c) * Description: Representations of search states * Author: Mark Seaman, OCR Technology * Created: Wed May 16 15:49:34 1990 * Modified: Mon Jun 17 17:54:41 1991 (Mark Seaman) marks@hpgrlt * Language: C * Package: N/A * Status: Experimental (Do Not Distribute) * * (c) Copyright 1990, 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 "states.h" #include "structures.h" #include "tordvars.h" #include "callcpp.h" /*------------------------------------------------------------------------- Variables --------------------------------------------------------------------------*/ #define STATEBLOCK 100 /* Cells per block */ makestructure (newstate, free_state, printstate, STATE, freestate, STATEBLOCK, "STATE", statecount); /*---------------------------------------------------------------------- F u n c t i o n s ----------------------------------------------------------------------*/ /********************************************************************** * bin_to_chunks * * Convert a representation of the search state in "STATE" form to one * in "SEARCH_STATE" form. Create the memory required to hold the * resultant state value. **********************************************************************/ SEARCH_STATE bin_to_chunks(STATE *state, int num_joints) { int x; unsigned int mask; int depth; int pieces = 0; SEARCH_STATE s; s = memalloc (sizeof (int) * (ones_in_state (state, num_joints) + 1)); depth = 1; mask = 1 << (num_joints - 1 - 32); for (x = num_joints; x > 32; x--) { if (state->part1 & mask) { s[depth++] = pieces; pieces = 0; } else { pieces++; } mask >>= 1; } if (num_joints > 32) mask = 1 << 31; else mask = 1 << (num_joints - 1); while (x--) { if (state->part2 & mask) { s[depth++] = pieces; pieces = 0; } else { pieces++; } mask >>= 1; } s[0] = depth - 1; return (s); } /********************************************************************** * bin_to_pieces * * Convert the binary (bit vector) format of a search state to an array * of piece counts. This array has a zero element after the last valid * character. **********************************************************************/ void bin_to_pieces(STATE *state, int num_joints, PIECES_STATE pieces) { int x; unsigned int mask; /* Bit mask */ INT16 num_pieces = 0; /* Preset mask */ if (debug_8) print_state ("bin_to_pieces = ", state, num_joints); mask = ((num_joints > 32) ? (1 << (num_joints - 1 - 32)) : (1 << (num_joints - 1))); pieces[num_pieces] = 0; for (x = num_joints - 1; x >= 0; x--) { /* Iterate all bits */ pieces[num_pieces]++; if ((x < 32) ? /* Test for 1 bit */ ((state->part2 & mask) ? TRUE : FALSE) : ((state->part1 & mask) ? TRUE : FALSE)) { pieces[++num_pieces] = 0; if (debug_8) cprintf ("[%d]=%d ", num_pieces - 1, pieces[num_pieces - 1]); } /* Next mask value */ mask = ((mask == 1) ? (1 << 31) : (mask >> 1)); } pieces[num_pieces]++; pieces[++num_pieces] = 0; ASSERT_HOST (num_pieces < MAX_NUM_CHUNKS + 2); if (debug_8) new_line(); } /********************************************************************** * insert_new_chunk * * Add a new chunk division into this state vector at the location * requested. **********************************************************************/ void insert_new_chunk(register STATE *state, register int index, register int num_joints) { register unsigned int mask; register unsigned int result; index = (num_joints - index); if (index < 32) { mask = ~0; mask <<= index; result = (mask & state->part2) << 1; result |= (~mask & state->part2); state->part1 <<= 1; if (state->part2 & 0x80000000) state->part1 |= 1; state->part2 = result; } else { mask = ~0; mask <<= index - 32; result = (mask & state->part1) << 1; result |= (~mask & state->part1); state->part1 = result; } } /********************************************************************** * new_state * * Create a memory space for a new state variable. Set its initial * value according to the parameters. **********************************************************************/ STATE *new_state(STATE *oldstate) { STATE *this_state; this_state = newstate (); this_state->part1 = oldstate->part1; this_state->part2 = oldstate->part2; return (this_state); } /********************************************************************* * ones_in_state * * Return the number of ones that are in this state. **********************************************************************/ int ones_in_state(STATE *state, int num_joints) { INT8 num_ones = 0; INT8 x; unsigned int mask; if (num_joints > 32) /* Preset mask */ mask = 1 << (num_joints - 1 - 32); else mask = 1 << (num_joints - 1); for (x = num_joints - 1; x >= 0; x--) { /* Iterate all bits */ if (x < 32) num_ones += ((state->part2 & mask) ? 1 : 0); else num_ones += ((state->part1 & mask) ? 1 : 0); if (mask == 1) /* Next mask value */ mask = 1 << 31; else mask >>= 1; } return (num_ones); } /********************************************************************** * print_state * * Print out the current state variable on a line with a label. **********************************************************************/ void print_state(const char *label, STATE *state, int num_joints) { int x; unsigned int mask; /* Bit mask */ if (num_joints > 32) /* Preset mask */ mask = 1 << (num_joints - 1 - 32); else mask = 1 << (num_joints - 1); cprintf ("%s ", label); for (x = num_joints - 1; x >= 0; x--) { /* Iterate all bits */ if (x < 32) cprintf ("%d", ((state->part2 & mask) ? 1 : 0)); else cprintf ("%d", ((state->part1 & mask) ? 1 : 0)); if (x % 4 == 0) cprintf (" "); if (mask == 1) /* Next mask value */ mask = 1 << 31; else mask >>= 1; } new_line(); } /********************************************************************** * set_n_ones * * Set the first n bits in a state. **********************************************************************/ void set_n_ones(STATE *state, int n) { if (n < 32) { state->part2 = ~0; state->part2 >>= 32 - n; state->part1 = 0; } else { state->part2 = ~0; state->part1 = ~0; state->part1 >>= 64 - n; } } /********************************************************************** * compare_states * * Compare the 2 states at the given blob index. Return 1 if the given * blob is a fragment compared to reality, 2 if correct, 4 if a join, * and 5 if both a join and a fragment. * On return the blob index is set to the corresponding index in the * correct string. **********************************************************************/ int compare_states(STATE *true_state, STATE *this_state, int *blob_index) { int blob_count; //number found int true_index; //index of true blob int index; //current int result = 0; //return value UINT32 mask; if (true_state->part1 == this_state->part1 && true_state->part2 == this_state->part2) return 2; if (*blob_index == 0) { if (bits_in_states > 32) { for (mask = 1 << bits_in_states - 33; mask != 0; mask >>= 1) { if (this_state->part1 & mask) { if (true_state->part1 & mask) return 2; else return 1; } else if (true_state->part1 & mask) return 4; } index = 31; } else index = bits_in_states - 1; for (mask = 1 << index; mask != 0; mask >>= 1) { if (this_state->part2 & mask) { if (true_state->part2 & mask) return 2; else return 1; } else if (true_state->part2 & mask) return 4; } return 2; } else { blob_count = 0; true_index = 0; if (bits_in_states > 32) { for (mask = 1 << bits_in_states - 33; mask != 0; mask >>= 1) { if (true_state->part1 & mask) true_index++; if (this_state->part1 & mask) { blob_count++; if (blob_count == *blob_index) { if ((true_state->part1 & mask) == 0) result = 1; break; } } } if (blob_count == *blob_index) { for (mask >>= 1; mask != 0; mask >>= 1) { if (this_state->part1 & mask) { if ((true_state->part1 & mask) && result == 0) return 2; else return result | 1; } else if (true_state->part1 & mask) result |= 4; } } index = 31; } else index = bits_in_states - 1; mask = 1 << index; if (blob_count < *blob_index) { for (; mask != 0; mask >>= 1) { if (true_state->part2 & mask) true_index++; if (this_state->part2 & mask) { blob_count++; if (blob_count == *blob_index) { if ((true_state->part2 & mask) == 0) result = 1; break; } } } if (blob_count != *blob_index) return 2; mask >>= 1; } *blob_index = true_index; for (; mask != 0; mask >>= 1) { if (this_state->part2 & mask) { if ((true_state->part2 & mask) && result == 0) return 2; else return result | 1; } else if (true_state->part2 & mask) result |= 4; } return result == 0 ? 2 : result; } }