zoneminder/src/zm_zone.cpp

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//
// ZoneMinder Zone Class Implementation, $Date$, $Revision$
// Copyright (C) 2003, 2004, 2005 Philip Coombes
//
// This program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License
// as published by the Free Software Foundation; either version 2
// of the License, or (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
//
#include "zm.h"
#include "zm_db.h"
#include "zm_zone.h"
#include "zm_image.h"
#include "zm_monitor.h"
void Zone::Setup( Monitor *p_monitor, int p_id, const char *p_label, ZoneType p_type, const Polygon &p_polygon, const Rgb p_alarm_rgb, CheckMethod p_check_method, int p_min_pixel_threshold, int p_max_pixel_threshold, int p_min_alarm_pixels, int p_max_alarm_pixels, const Coord &p_filter_box, int p_min_filter_pixels, int p_max_filter_pixels, int p_min_blob_pixels, int p_max_blob_pixels, int p_min_blobs, int p_max_blobs )
{
monitor = p_monitor;
id = p_id;
label = new char[strlen(p_label)+1];
strcpy( label, p_label );
type = p_type;
polygon = p_polygon;
alarm_rgb = p_alarm_rgb;
check_method = p_check_method;
min_pixel_threshold = p_min_pixel_threshold;
max_pixel_threshold = p_max_pixel_threshold;
min_alarm_pixels = p_min_alarm_pixels;
max_alarm_pixels = p_max_alarm_pixels;
filter_box = p_filter_box;
min_filter_pixels = p_min_filter_pixels;
max_filter_pixels = p_max_filter_pixels;
min_blob_pixels = p_min_blob_pixels;
max_blob_pixels = p_max_blob_pixels;
min_blobs = p_min_blobs;
max_blobs = p_max_blobs;
Debug( 1, ( "Initialised zone %d/%s - %d - %dx%d - Rgb:%06x, CM:%d, MnAT:%d, MxAT:%d, MnAP:%d, MxAP:%d, FB:%dx%d, MnFP:%d, MxFP:%d, MnBS:%d, MxBS:%d, MnB:%d, MxB:%d", id, label, type, polygon.Width(), polygon.Height(), alarm_rgb, check_method, min_pixel_threshold, max_pixel_threshold, min_alarm_pixels, max_alarm_pixels, filter_box.X(), filter_box.Y(), min_filter_pixels, max_filter_pixels, min_blob_pixels, max_blob_pixels, min_blobs, max_blobs ));
alarmed = false;
alarm_pixels = 0;
alarm_filter_pixels = 0;
alarm_blob_pixels = 0;
alarm_blobs = 0;
min_blob_size = 0;
max_blob_size = 0;
image = 0;
score = 0;
pg_image = new Image( monitor->Width(), monitor->Height(), 1 );
pg_image->Fill( 0xff, polygon );
pg_image->Outline( 0xff, polygon );
pg_image->Crop( polygon.LoX(), polygon.LoY(), polygon.HiX(), polygon.HiY() );
ranges = new Range[polygon.Height()];
int y = polygon.LoY();
for ( int py = 0; py < polygon.Height(); py++, y++ )
{
int x = polygon.LoX();
ranges[py].lo_x = -1;
ranges[py].hi_x = -1;
ranges[py].off_x = 0;
unsigned char *ppoly = pg_image->Buffer( 0, py );
for ( int px = 0; px < polygon.Width(); px++, x++, ppoly++ )
{
if ( *ppoly )
{
if ( ranges[py].lo_x == -1 )
{
ranges[py].lo_x = x;
ranges[py].off_x = px;
}
else if ( ranges[py].hi_x < x )
{
ranges[py].hi_x = x;
}
}
}
}
}
Zone::~Zone()
{
delete[] label;
delete image;
delete pg_image;
delete[] ranges;
}
void Zone::RecordStats( const Event *event )
{
static char sql[BUFSIZ];
snprintf( sql, sizeof(sql), "insert into Stats set MonitorId=%d, ZoneId=%d, EventId=%d, FrameId=%d, AlarmPixels=%d, FilterPixels=%d, BlobPixels=%d, Blobs=%d, MinBlobSize=%d, MaxBlobSize=%d, MinX=%d, MinY=%d, MaxX=%d, MaxY=%d, Score=%d", monitor->Id(), id, event->Id(), event->Frames()+1, alarm_pixels, alarm_filter_pixels, alarm_blob_pixels, alarm_blobs, min_blob_size, max_blob_size, alarm_box.LoX(), alarm_box.LoY(), alarm_box.HiX(), alarm_box.HiY(), score );
if ( mysql_query( &dbconn, sql ) )
{
Error(( "Can't insert event stats: %s", mysql_error( &dbconn ) ));
exit( mysql_errno( &dbconn ) );
}
}
bool Zone::CheckAlarms( const Image *delta_image )
{
bool alarm = false;
ResetStats();
delete image;
// Get the difference image
Image *diff_image = image = new Image( *delta_image );
int diff_width = diff_image->Width();
int diff_height = diff_image->Height();
int diff_stride = diff_width * diff_image->Colours();
int alarm_lo_x = 0;
int alarm_hi_x = 0;
int alarm_lo_y = 0;
int alarm_hi_y = 0;
int alarm_mid_x = -1;
int alarm_mid_y = -1;
int lo_y = polygon.LoY();
int hi_y = polygon.HiY();
int lo_x;
int hi_x;
Debug( 4, ( "Checking alarms for zone %d/%s in lines %d -> %d", id, label, lo_y, hi_y ));
Debug( 5, ( "Checking for alarmed pixels" ));
unsigned char *pdiff, *ppoly;
// Create an upper margin
if ( lo_y > 0 )
{
lo_x = ranges[0].lo_x;
if ( lo_x > 0 )
lo_x--;
hi_x = ranges[0].hi_x;
if ( hi_x < (diff_width-1) )
hi_x++;
pdiff = diff_image->Buffer( lo_x, lo_y-1 );
memset( pdiff, BLACK, (hi_x-lo_x)+1 );
}
for ( int y = lo_y, py = 0; y <= hi_y; y++, py++ )
{
lo_x = ranges[py].lo_x;
hi_x = ranges[py].hi_x;
Debug( 7, ( "Checking line %d from %d -> %d", y, lo_x, hi_x ));
pdiff = diff_image->Buffer( lo_x, y );
ppoly = pg_image->Buffer( ranges[py].off_x, py );
// Left margin
if ( y < hi_y )
{
int next_lo_x = ranges[py+1].lo_x;
if ( next_lo_x < lo_x )
{
int lo_x_diff = lo_x-next_lo_x;
memset( pdiff-lo_x_diff, BLACK, lo_x_diff );
}
else if ( lo_x > 0 )
*(pdiff-1) = BLACK;
}
else if ( lo_x > 0 )
*(pdiff-1) = BLACK;
for ( int x = lo_x; x <= hi_x; x++, pdiff++, ppoly++ )
{
if ( *ppoly && (*pdiff > min_pixel_threshold) && (!max_pixel_threshold || (*pdiff < max_pixel_threshold)) )
{
*pdiff = WHITE;
alarm_pixels++;
}
else
{
*pdiff = BLACK;
}
}
// Right margin
if ( y < hi_y )
{
int next_hi_x = ranges[py+1].hi_x;
if ( next_hi_x > hi_x )
{
//printf( "%d: Setting %d-%d = %d\n", y, hi_x, next_hi_x, next_hi_x-hi_x );
memset( pdiff, BLACK, next_hi_x-hi_x );
}
}
}
Debug( 5, ( "Got %d alarmed pixels, need %d -> %d", alarm_pixels, min_alarm_pixels, max_alarm_pixels ));
if ( config.record_diag_images )
{
static char diag_path[PATH_MAX] = "";
if ( !diag_path[0] )
{
snprintf( diag_path, sizeof(diag_path), "%s/%s/diag-%d-%d.jpg", config.dir_events, monitor->Name(), id, 1 );
}
diff_image->WriteJpeg( diag_path );
}
if ( !alarm_pixels ) return( false );
if ( min_alarm_pixels && alarm_pixels < min_alarm_pixels ) return( false );
if ( max_alarm_pixels && alarm_pixels > max_alarm_pixels ) return( false );
score = (100*alarm_pixels)/polygon.Area();
Debug( 5, ( "Current score is %d", score ));
if ( check_method >= FILTERED_PIXELS )
{
int bx = filter_box.X();
int by = filter_box.Y();
int bx1 = bx-1;
int by1 = by-1;
Debug( 5, ( "Checking for filtered pixels" ));
if ( bx > 1 || by > 1 )
{
// Now remove any pixels smaller than our filter size
unsigned char *pdiff;
unsigned char *cpdiff;
int ldx, hdx, ldy, hdy;
bool block;
for ( int y = lo_y, py = 0; y <= hi_y; y++, py++ )
{
int lo_x = ranges[py].lo_x;
int hi_x = ranges[py].hi_x;
pdiff = diff_image->Buffer( lo_x, y );
for ( int x = lo_x; x <= hi_x; x++, pdiff++ )
{
if ( *pdiff == WHITE )
{
// Check participation in an X block
ldx = (x>=(lo_x+bx1))?-bx1:lo_x-x;
hdx = (x<=(hi_x-bx1))?0:((hi_x-x)-bx1);
ldy = (y>=(lo_y+by1))?-by1:lo_y-y;
hdy = (y<=(hi_y-by1))?0:((hi_y-y)-by1);
block = false;
for ( int dy = ldy; !block && dy <= hdy; dy++ )
{
for ( int dx = ldx; !block && dx <= hdx; dx++ )
{
block = true;
for ( int dy2 = 0; block && dy2 < by; dy2++ )
{
for ( int dx2 = 0; block && dx2 < bx; dx2++ )
{
cpdiff = diff_image->Buffer( x+dx+dx2, y+dy+dy2 );
if ( !*cpdiff )
{
block = false;
}
}
}
}
}
if ( !block )
{
*pdiff = BLACK;
continue;
}
alarm_filter_pixels++;
}
}
}
}
else
{
alarm_filter_pixels = alarm_pixels;
}
if ( config.record_diag_images )
{
static char diag_path[PATH_MAX] = "";
if ( !diag_path[0] )
{
snprintf( diag_path, sizeof(diag_path), "%s/%d/diag-%d-%d.jpg", config.dir_events, monitor->Id(), id, 2 );
}
diff_image->WriteJpeg( diag_path );
}
Debug( 5, ( "Got %d filtered pixels, need %d -> %d", alarm_filter_pixels, min_filter_pixels, max_filter_pixels ));
if ( !alarm_filter_pixels ) return( false );
if ( min_filter_pixels && alarm_filter_pixels < min_filter_pixels ) return( false );
if ( max_filter_pixels && alarm_filter_pixels > max_filter_pixels ) return( false );
score = (100*alarm_filter_pixels)/(polygon.Area());
Debug( 5, ( "Current score is %d", score ));
if ( check_method >= BLOBS )
{
Debug( 5, ( "Checking for blob pixels" ));
typedef struct { unsigned char tag; int count; int lo_x; int hi_x; int lo_y; int hi_y; } BlobStats;
BlobStats blob_stats[256];
memset( blob_stats, 0, sizeof(BlobStats)*256 );
unsigned char *pdiff, *spdiff;
int last_x, last_y;
BlobStats *bsx, *bsy;
BlobStats *bsm, *bss;
for ( int y = lo_y, py = 0; y <= hi_y; y++, py++ )
{
int lo_x = ranges[py].lo_x;
int hi_x = ranges[py].hi_x;
int last_lo_x = py>=0?ranges[py-1].lo_x:0;
int last_hi_x = py>=0?ranges[py-1].hi_x:0;
pdiff = diff_image->Buffer( lo_x, y );
for ( int x = lo_x; x <= hi_x; x++, pdiff++ )
{
if ( *pdiff == WHITE )
{
Debug( 9, ( "Got white pixel at %d,%d (%x)", x, y, pdiff ));
//last_x = (x>lo_x)?*(pdiff-1):0;
//last_y = (y>lo_y&&x>=last_lo_x&&x<=last_hi_x)?*(pdiff-diff_width):0;
last_x = x>0?*(pdiff-1):0;
last_y = y>0?*(pdiff-diff_width):0;
if ( last_x )
{
Debug( 9, ( "Left neighbour is %d", last_x ));
bsx = &blob_stats[last_x];
if ( last_y )
{
Debug( 9, ( "Top neighbour is %d", last_y ));
bsy = &blob_stats[last_y];
if ( last_x == last_y )
{
Debug( 9, ( "Matching neighbours, setting to %d", last_x ));
// Add to the blob from the x side (either side really)
*pdiff = last_x;
bsx->count++;
if ( x > bsx->hi_x ) bsx->hi_x = x;
if ( y > bsx->hi_y ) bsx->hi_y = y;
}
else
{
// Aggregate blobs
bsm = bsx->count>=bsy->count?bsx:bsy;
bss = bsm==bsx?bsy:bsx;
Debug( 9, ( "Different neighbours, setting pixels of %d to %d", bss->tag, bsm->tag ));
Debug( 9, ( "Master blob t:%d, c:%d, lx:%d, hx:%d, ly:%d, hy:%d", bsm->tag, bsm->count, bsm->lo_x, bsm->hi_x, bsm->lo_y, bsm->hi_y ));
Debug( 9, ( "Slave blob t:%d, c:%d, lx:%d, hx:%d, ly:%d, hy:%d", bss->tag, bss->count, bss->lo_x, bss->hi_x, bss->lo_y, bss->hi_y ));
// Now change all those pixels to the other setting
int changed = 0;
for ( int sy = bss->lo_y, psy = bss->lo_y-lo_y; sy <= bss->hi_y; sy++, psy++ )
{
int lo_sx = bss->lo_x>=ranges[psy].lo_x?bss->lo_x:ranges[psy].lo_x;
int hi_sx = bss->hi_x<=ranges[psy].hi_x?bss->hi_x:ranges[psy].hi_x;
Debug( 9, ( "Changing %d(%d), %d->%d", sy, psy, lo_sx, hi_sx ));
Debug( 9, ( "Range %d(%d), %d->%d", sy, psy, ranges[psy].lo_x, ranges[psy].hi_x ));
spdiff = diff_image->Buffer( lo_sx, sy );
for ( int sx = lo_sx; sx <= hi_sx; sx++, spdiff++ )
{
Debug( 9, ( "Pixel at %d,%d (%x) is %d", sx, sy, spdiff, *spdiff ));
if ( *spdiff == bss->tag )
{
Debug( 9, ( "Setting pixel" ));
*spdiff = bsm->tag;
changed++;
}
}
}
*pdiff = bsm->tag;
if ( !changed )
{
Info(( "Master blob t:%d, c:%d, lx:%d, hx:%d, ly:%d, hy:%d", bsm->tag, bsm->count, bsm->lo_x, bsm->hi_x, bsm->lo_y, bsm->hi_y ));
Info(( "Slave blob t:%d, c:%d, lx:%d, hx:%d, ly:%d, hy:%d", bss->tag, bss->count, bss->lo_x, bss->hi_x, bss->lo_y, bss->hi_y ));
Error(( "No pixels changed, exiting" ));
exit( -1 );
}
// Merge the slave blob into the master
bsm->count += bss->count+1;
if ( x > bsm->hi_x ) bsm->hi_x = x;
if ( y > bsm->hi_y ) bsm->hi_y = y;
if ( bss->lo_x < bsm->lo_x ) bsm->lo_x = bss->lo_x;
if ( bss->lo_y < bsm->lo_y ) bsm->lo_y = bss->lo_y;
if ( bss->hi_x > bsm->hi_x ) bsm->hi_x = bss->hi_x;
if ( bss->hi_y > bsm->hi_y ) bsm->hi_y = bss->hi_y;
alarm_blobs--;
Debug( 6, ( "Merging blob %d with %d at %d,%d, %d current blobs", bss->tag, bsm->tag, x, y, alarm_blobs ));
// Clear out the old blob
bss->tag = 0;
bss->count = 0;
bss->lo_x = 0;
bss->lo_y = 0;
bss->hi_x = 0;
bss->hi_y = 0;
}
}
else
{
Debug( 9, ( "Setting to left neighbour %d", last_x ));
// Add to the blob from the x side
*pdiff = last_x;
bsx->count++;
if ( x > bsx->hi_x ) bsx->hi_x = x;
if ( y > bsx->hi_y ) bsx->hi_y = y;
}
}
else
{
if ( last_y )
{
Debug( 9, ( "Setting to top neighbour %d", last_y ));
// Add to the blob from the y side
BlobStats *bsy = &blob_stats[last_y];
*pdiff = last_y;
bsy->count++;
if ( x > bsy->hi_x ) bsy->hi_x = x;
if ( y > bsy->hi_y ) bsy->hi_y = y;
}
else
{
// Create a new blob
int i;
for ( i = (WHITE-1); i > 0; i-- )
{
BlobStats *bs = &blob_stats[i];
// See if we can recycle one first, only if it's at least two rows up
if ( bs->count && bs->hi_y < (y-1) )
{
if ( (min_blob_pixels && bs->count < min_blob_pixels) || (max_blob_pixels && bs->count > max_blob_pixels) )
{
if ( config.create_analysis_images || config.record_diag_images )
{
for ( int sy = bs->lo_y; sy <= bs->hi_y; sy++ )
{
unsigned char *spdiff = diff_image->Buffer( bs->lo_x, sy );
for ( int sx = bs->lo_x; sx <= bs->hi_x; sx++, spdiff++ )
{
if ( *spdiff == bs->tag )
{
*spdiff = BLACK;
}
}
}
}
alarm_blobs--;
alarm_blob_pixels -= bs->count;
Debug( 6, ( "Eliminated blob %d, %d pixels (%d,%d - %d,%d), %d current blobs", i, bs->count, bs->lo_x, bs->lo_y, bs->hi_x, bs->hi_y, alarm_blobs ));
bs->tag = 0;
bs->count = 0;
bs->lo_x = 0;
bs->lo_y = 0;
bs->hi_x = 0;
bs->hi_y = 0;
}
}
if ( !bs->count )
{
Debug( 9, ( "Creating new blob %d", i ));
*pdiff = i;
bs->tag = i;
bs->count++;
bs->lo_x = bs->hi_x = x;
bs->lo_y = bs->hi_y = y;
alarm_blobs++;
Debug( 6, ( "Created blob %d at %d,%d, %d current blobs", bs->tag, x, y, alarm_blobs ));
break;
}
}
if ( i == 0 )
{
Warning(( "Max blob count reached. Unable to allocate new blobs so terminating. Zone settings may be too sensitive." ));
x = hi_x+1;
y = hi_y+1;
}
}
}
}
}
}
if ( config.record_diag_images )
{
static char diag_path[PATH_MAX] = "";
if ( !diag_path[0] )
{
snprintf( diag_path, sizeof(diag_path), "%s/%d/diag-%d-%d.jpg", config.dir_events, monitor->Id(), id, 3 );
}
diff_image->WriteJpeg( diag_path );
}
if ( !alarm_blobs ) return( false );
alarm_blob_pixels = alarm_filter_pixels;
Debug( 5, ( "Got %d raw blob pixels, %d raw blobs, need %d -> %d, %d -> %d", alarm_blob_pixels, alarm_blobs, min_blob_pixels, max_blob_pixels, min_blobs, max_blobs ));
// Now eliminate blobs under the threshold
for ( int i = 1; i < WHITE; i++ )
{
BlobStats *bs = &blob_stats[i];
if ( bs->count )
{
if ( (min_blob_pixels && bs->count < min_blob_pixels) || (max_blob_pixels && bs->count > max_blob_pixels) )
{
if ( config.create_analysis_images || config.record_diag_images )
{
for ( int sy = bs->lo_y; sy <= bs->hi_y; sy++ )
{
unsigned char *spdiff = diff_image->Buffer( bs->lo_x, sy );
for ( int sx = bs->lo_x; sx <= bs->hi_x; sx++, spdiff++ )
{
if ( *spdiff == bs->tag )
{
*spdiff = BLACK;
}
}
}
}
alarm_blobs--;
alarm_blob_pixels -= bs->count;
Debug( 6, ( "Eliminated blob %d, %d pixels (%d,%d - %d,%d), %d current blobs", i, bs->count, bs->lo_x, bs->lo_y, bs->hi_x, bs->hi_y, alarm_blobs ));
bs->tag = 0;
bs->count = 0;
bs->lo_x = 0;
bs->lo_y = 0;
bs->hi_x = 0;
bs->hi_y = 0;
}
else
{
Debug( 6, ( "Preserved blob %d, %d pixels (%d,%d - %d,%d), %d current blobs", i, bs->count, bs->lo_x, bs->lo_y, bs->hi_x, bs->hi_y, alarm_blobs ));
if ( !min_blob_size || bs->count < min_blob_size ) min_blob_size = bs->count;
if ( !max_blob_size || bs->count > max_blob_size ) max_blob_size = bs->count;
}
}
}
if ( config.record_diag_images )
{
static char diag_path[PATH_MAX] = "";
if ( !diag_path[0] )
{
snprintf( diag_path, sizeof(diag_path), "%s/%d/diag-%d-%d.jpg", config.dir_events, monitor->Id(), id, 4 );
}
diff_image->WriteJpeg( diag_path );
}
Debug( 5, ( "Got %d blob pixels, %d blobs, need %d -> %d, %d -> %d", alarm_blob_pixels, alarm_blobs, min_blob_pixels, max_blob_pixels, min_blobs, max_blobs ));
if ( !alarm_blobs ) return( false );
if ( min_blobs && alarm_blobs < min_blobs ) return( false );
if ( max_blobs && alarm_blobs > max_blobs ) return( false );
alarm_lo_x = polygon.HiX()+1;
alarm_hi_x = polygon.LoX()-1;
alarm_lo_y = polygon.HiY()+1;
alarm_hi_y = polygon.LoY()-1;
for ( int i = 1; i < WHITE; i++ )
{
BlobStats *bs = &blob_stats[i];
if ( bs->count )
{
if ( bs->count == max_blob_size )
{
if ( config.weighted_alarm_centres )
{
unsigned long x_total = 0;
unsigned long y_total = 0;
for ( int sy = bs->lo_y; sy <= bs->hi_y; sy++ )
{
unsigned char *spdiff = diff_image->Buffer( bs->lo_x, sy );
for ( int sx = bs->lo_x; sx <= bs->hi_x; sx++, spdiff++ )
{
if ( *spdiff == bs->tag )
{
x_total += sx;
y_total += sy;
}
}
}
alarm_mid_x = int(round(x_total/bs->count));
alarm_mid_y = int(round(y_total/bs->count));
}
else
{
alarm_mid_x = int((bs->hi_x+bs->lo_x+1)/2);
alarm_mid_y = int((bs->hi_y+bs->lo_y+1)/2);
}
}
if ( alarm_lo_x > bs->lo_x ) alarm_lo_x = bs->lo_x;
if ( alarm_lo_y > bs->lo_y ) alarm_lo_y = bs->lo_y;
if ( alarm_hi_x < bs->hi_x ) alarm_hi_x = bs->hi_x;
if ( alarm_hi_y < bs->hi_y ) alarm_hi_y = bs->hi_y;
}
}
score = ((100*alarm_blob_pixels)/int(sqrt((double)alarm_blobs)))/(polygon.Area());
Debug( 5, ( "Current score is %d", score ));
}
else
{
alarm_mid_x = int((alarm_hi_x+alarm_lo_x+1)/2);
alarm_mid_y = int((alarm_hi_y+alarm_lo_y+1)/2);
}
}
if ( type == INCLUSIVE )
{
score /= 2;
}
else if ( type == EXCLUSIVE )
{
score *= 2;
}
Debug( 5, ( "Adjusted score is %d", score ));
// Now outline the changed region
if ( score )
{
alarm = true;
alarm_box = Box( Coord( alarm_lo_x, alarm_lo_y ), Coord( alarm_hi_x, alarm_hi_y ) );
//if ( monitor->followMotion() )
if ( true )
{
alarm_centre = Coord( alarm_mid_x, alarm_mid_y );
}
else
{
alarm_centre = alarm_box.Centre();
}
if ( (type < PRECLUSIVE) && check_method >= BLOBS && config.create_analysis_images )
{
int lo_x = polygon.LoX();
int hi_x = polygon.HiX();
int lo_y = polygon.LoY();
int hi_y = polygon.HiY();
// First mask out anything we don't want
for ( int y = lo_y, py = 0; y <= hi_y; y++, py++ )
{
pdiff = diff_image->Buffer( lo_x, y );
int lo_x2 = ranges[py].lo_x;
int hi_x2 = ranges[py].hi_x;
int lo_gap = lo_x2-lo_x;
if ( lo_gap > 0 )
{
if ( lo_gap == 1 )
{
*pdiff++ = BLACK;
}
else
{
memset( pdiff, BLACK, lo_gap );
pdiff += lo_gap;
}
}
ppoly = pg_image->Buffer( lo_gap, py );
for ( int x = lo_x2; x <= hi_x2; x++, pdiff++, ppoly++ )
{
if ( !*ppoly )
{
*pdiff = BLACK;
}
}
int hi_gap = hi_x-hi_x2;
if ( hi_gap > 0 )
{
if ( hi_gap == 1 )
{
*pdiff = BLACK;
}
else
{
memset( pdiff, BLACK, hi_gap );
}
}
}
image = diff_image->HighlightEdges( alarm_rgb, &polygon.Extent() );
// Only need to delete this when 'image' becomes detached and points somewhere else
delete diff_image;
}
else
{
delete image;
image = 0;
}
Debug( 1, ( "%s: Alarm Pixels: %d, Filter Pixels: %d, Blob Pixels: %d, Blobs: %d, Score: %d", Label(), alarm_pixels, alarm_filter_pixels, alarm_blob_pixels, alarm_blobs, score ));
}
return( true );
}
bool Zone::ParsePolygonString( const char *poly_string, Polygon &polygon )
{
Debug( 3, ( "Parsing polygon string '%s'", poly_string ));
char *str_ptr = new char[strlen(poly_string)+1];
char *str = str_ptr;
strcpy( str, poly_string );
char *ws;
int n_coords = 0;
int max_n_coords = strlen(str)/4;
Coord *coords = new Coord[max_n_coords];
while( true )
{
if ( *str == '\0' )
{
break;
}
ws = strchr( str, ' ' );
if ( ws )
{
*ws = '\0';
}
char *cp = strchr( str, ',' );
if ( !cp )
{
Error(( "Bogus coordinate %s found in polygon string", str ));
delete[] coords;
delete[] str_ptr;
return( false );
}
else
{
*cp = '\0';
char *xp = str;
char *yp = cp+1;
int x = atoi(xp);
int y = atoi(yp);
Debug( 3, ( "Got coordinate %d,%d from polygon string", x, y ));
#if 0
if ( x < 0 )
x = 0;
else if ( x >= width )
x = width-1;
if ( y < 0 )
y = 0;
else if ( y >= height )
y = height-1;
#endif
coords[n_coords++] = Coord( x, y );
}
if ( ws )
str = ws+1;
else
break;
}
polygon = Polygon( n_coords, coords );
Debug( 3, ( "Successfully parsed polygon string" ));
//printf( "Area: %d\n", pg.Area() );
//printf( "Centre: %d,%d\n", pg.Centre().X(), pg.Centre().Y() );
delete[] coords;
delete[] str_ptr;
return( true );
}
bool Zone::ParseZoneString( const char *zone_string, int &zone_id, int &colour, Polygon &polygon )
{
Debug( 3, ( "Parsing zone string '%s'", zone_string ));
char *str_ptr = new char[strlen(zone_string)+1];
char *str = str_ptr;
strcpy( str, zone_string );
char *ws = strchr( str, ' ' );
if ( !ws )
{
Debug( 3, ( "No whitespace found in zone string, finishing", zone_string ));
}
zone_id = strtol( str, 0, 10 );
Debug( 3, ( "Got zone %d from zone string", zone_id ));
if ( !ws )
{
delete str_ptr;
return( true );
}
*ws = '\0';
str = ws+1;
ws = strchr( str, ' ' );
if ( !ws )
{
Error(( "No whitespace found in zone string '%s'", zone_string ));
delete[] str_ptr;
return( false );
}
*ws = '\0';
colour = strtol( str, 0, 16 );
Debug( 3, ( "Got colour %06x from zone string", colour ));
str = ws+1;
bool result = ParsePolygonString( str, polygon );
//printf( "Area: %d\n", pg.Area() );
//printf( "Centre: %d,%d\n", pg.Centre().X(), pg.Centre().Y() );
delete[] str_ptr;
return( result );
}
int Zone::Load( Monitor *monitor, Zone **&zones )
{
static char sql[BUFSIZ];
snprintf( sql, sizeof(sql), "select Id,Name,Type+0,Units,NumCoords,Coords,AlarmRGB,CheckMethod+0,MinPixelThreshold,MaxPixelThreshold,MinAlarmPixels,MaxAlarmPixels,FilterX,FilterY,MinFilterPixels,MaxFilterPixels,MinBlobPixels,MaxBlobPixels,MinBlobs,MaxBlobs from Zones where MonitorId = %d order by Type, Id", monitor->Id() );
if ( mysql_query( &dbconn, sql ) )
{
Error(( "Can't run query: %s", mysql_error( &dbconn ) ));
exit( mysql_errno( &dbconn ) );
}
MYSQL_RES *result = mysql_store_result( &dbconn );
if ( !result )
{
Error(( "Can't use query result: %s", mysql_error( &dbconn ) ));
exit( mysql_errno( &dbconn ) );
}
int n_zones = mysql_num_rows( result );
Debug( 1, ( "Got %d zones for monitor %s", n_zones, monitor->Name() ));
delete[] zones;
zones = new Zone *[n_zones];
for( int i = 0; MYSQL_ROW dbrow = mysql_fetch_row( result ); i++ )
{
int col = 0;
int Id = atoi(dbrow[col++]);
const char *Name = dbrow[col++];
int Type = atoi(dbrow[col++]);
const char *Units = dbrow[col++];
int NumCoords = atoi(dbrow[col++]);
const char *Coords = dbrow[col++];
int AlarmRGB = dbrow[col]?atoi(dbrow[col]):0; col++;
int CheckMethod = atoi(dbrow[col++]);
int MinPixelThreshold = dbrow[col]?atoi(dbrow[col]):0; col++;
int MaxPixelThreshold = dbrow[col]?atoi(dbrow[col]):0; col++;
int MinAlarmPixels = dbrow[col]?atoi(dbrow[col]):0; col++;
int MaxAlarmPixels = dbrow[col]?atoi(dbrow[col]):0; col++;
int FilterX = dbrow[col]?atoi(dbrow[col]):0; col++;
int FilterY = dbrow[col]?atoi(dbrow[col]):0; col++;
int MinFilterPixels = dbrow[col]?atoi(dbrow[col]):0; col++;
int MaxFilterPixels = dbrow[col]?atoi(dbrow[col]):0; col++;
int MinBlobPixels = dbrow[col]?atoi(dbrow[col]):0; col++;
int MaxBlobPixels = dbrow[col]?atoi(dbrow[col]):0; col++;
int MinBlobs = dbrow[col]?atoi(dbrow[col]):0; col++;
int MaxBlobs = dbrow[col]?atoi(dbrow[col]):0; col++;
Debug( 5, ( "Parsing polygon %s", Coords ));
Polygon polygon;
if ( !ParsePolygonString( Coords, polygon ) )
continue;
if ( false && !strcmp( Units, "Percent" ) )
{
MinAlarmPixels = (MinAlarmPixels*polygon.Area())/100;
MaxAlarmPixels = (MaxAlarmPixels*polygon.Area())/100;
MinFilterPixels = (MinFilterPixels*polygon.Area())/100;
MaxFilterPixels = (MaxFilterPixels*polygon.Area())/100;
MinBlobPixels = (MinBlobPixels*polygon.Area())/100;
MaxBlobPixels = (MaxBlobPixels*polygon.Area())/100;
}
if ( atoi(dbrow[2]) == Zone::INACTIVE )
{
zones[i] = new Zone( monitor, Id, Name, polygon );
}
else
{
zones[i] = new Zone( monitor, Id, Name, (Zone::ZoneType)Type, polygon, AlarmRGB, (Zone::CheckMethod)CheckMethod, MinPixelThreshold, MaxPixelThreshold, MinAlarmPixels, MaxAlarmPixels, Coord( FilterX, FilterY ), MinFilterPixels, MaxFilterPixels, MinBlobPixels, MaxBlobPixels, MinBlobs, MaxBlobs );
}
}
if ( mysql_errno( &dbconn ) )
{
Error(( "Can't fetch row: %s", mysql_error( &dbconn ) ));
exit( mysql_errno( &dbconn ) );
}
// Yadda yadda
mysql_free_result( result );
return( n_zones );
}
bool Zone::DumpSettings( char *output, bool /*verbose*/ )
{
output[0] = 0;
sprintf( output+strlen(output), " Id : %d\n", id );
sprintf( output+strlen(output), " Label : %s\n", label );
sprintf( output+strlen(output), " Type: %d - %s\n", type,
type==ACTIVE?"Active":(
type==INCLUSIVE?"Inclusive":(
type==EXCLUSIVE?"Exclusive":(
type==PRECLUSIVE?"Preclusive":(
type==INACTIVE?"Inactive":"Unknown"
)))));
//sprintf( output+strlen(output), " Limits : %d,%d - %d,%d\n", limits.LoX(), limits.LoY(), limits.HiX(), limits.HiY() );
sprintf( output+strlen(output), " Alarm RGB : %06x\n", alarm_rgb );
sprintf( output+strlen(output), " Check Method: %d - %s\n", check_method,
check_method==ALARMED_PIXELS?"Alarmed Pixels":(
check_method==FILTERED_PIXELS?"FilteredPixels":(
check_method==BLOBS?"Blobs":"Unknown"
)));
sprintf( output+strlen(output), " Min Pixel Threshold : %d\n", min_pixel_threshold );
sprintf( output+strlen(output), " Max Pixel Threshold : %d\n", max_pixel_threshold );
sprintf( output+strlen(output), " Min Alarm Pixels : %d\n", min_alarm_pixels );
sprintf( output+strlen(output), " Max Alarm Pixels : %d\n", max_alarm_pixels );
sprintf( output+strlen(output), " Filter Box : %d,%d\n", filter_box.X(), filter_box.Y() );
sprintf( output+strlen(output), " Min Filter Pixels : %d\n", min_filter_pixels );
sprintf( output+strlen(output), " Max Filter Pixels : %d\n", max_filter_pixels );
sprintf( output+strlen(output), " Min Blob Pixels : %d\n", min_blob_pixels );
sprintf( output+strlen(output), " Max Blob Pixels : %d\n", max_blob_pixels );
sprintf( output+strlen(output), " Min Blobs : %d\n", min_blobs );
sprintf( output+strlen(output), " Max Blobs : %d\n", max_blobs );
return( true );
}