zoneminder/src/zm_monitorstream.cpp

808 lines
26 KiB
C++
Raw Normal View History

2017-04-11 09:57:31 +08:00
//
// ZoneMinder Monitor Class Implementation, $Date$, $Revision$
// Copyright (C) 2001-2008 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
//
#include "zm.h"
#include "zm_db.h"
#include "zm_time.h"
#include "zm_mpeg.h"
#include "zm_signal.h"
#include "zm_monitor.h"
#include "zm_monitorstream.h"
#include <arpa/inet.h>
#include <glob.h>
bool MonitorStream::checkSwapPath( const char *path, bool create_path ) {
struct stat stat_buf;
if ( stat( path, &stat_buf ) < 0 ) {
if ( create_path && errno == ENOENT ) {
Debug( 3, "Swap path '%s' missing, creating", path );
if ( mkdir( path, 0755 ) ) {
Error( "Can't mkdir %s: %s", path, strerror(errno));
return( false );
}
if ( stat( path, &stat_buf ) < 0 ) {
Error( "Can't stat '%s': %s", path, strerror(errno) );
return( false );
}
} else {
Error( "Can't stat '%s': %s", path, strerror(errno) );
return( false );
}
}
if ( !S_ISDIR(stat_buf.st_mode) ) {
Error( "Swap image path '%s' is not a directory", path );
return( false );
}
uid_t uid = getuid();
gid_t gid = getgid();
mode_t mask = 0;
if ( uid == stat_buf.st_uid ) {
// If we are the owner
mask = 00700;
} else if ( gid == stat_buf.st_gid ) {
// If we are in the owner group
mask = 00070;
} else {
// We are neither the owner nor in the group
mask = 00007;
}
if ( (stat_buf.st_mode & mask) != mask ) {
Error( "Insufficient permissions on swap image path '%s'", path );
return( false );
}
return( true );
} // end bool MonitorStream::checkSwapPath( const char *path, bool create_path )
void MonitorStream::processCommand( const CmdMsg *msg ) {
Debug( 2, "Got message, type %d, msg %d", msg->msg_type, msg->msg_data[0] );
// Check for incoming command
switch( (MsgCommand)msg->msg_data[0] ) {
case CMD_PAUSE :
{
Debug( 1, "Got PAUSE command" );
// Set paused flag
paused = true;
// Set delayed flag
delayed = true;
last_frame_sent = TV_2_FLOAT( now );
break;
}
case CMD_PLAY :
{
Debug( 1, "Got PLAY command" );
if ( paused ) {
// Clear paused flag
paused = false;
// Set delayed_play flag
delayed = true;
}
replay_rate = ZM_RATE_BASE;
break;
}
case CMD_VARPLAY :
{
Debug( 1, "Got VARPLAY command" );
if ( paused ) {
// Clear paused flag
paused = false;
// Set delayed_play flag
delayed = true;
}
replay_rate = ntohs(((unsigned char)msg->msg_data[2]<<8)|(unsigned char)msg->msg_data[1])-32768;
break;
}
case CMD_STOP :
{
Debug( 1, "Got STOP command" );
// Clear paused flag
paused = false;
// Clear delayed_play flag
delayed = false;
break;
}
case CMD_FASTFWD :
{
Debug( 1, "Got FAST FWD command" );
if ( paused ) {
// Clear paused flag
paused = false;
// Set delayed_play flag
delayed = true;
}
// Set play rate
switch ( replay_rate )
{
case 2 * ZM_RATE_BASE :
replay_rate = 5 * ZM_RATE_BASE;
break;
case 5 * ZM_RATE_BASE :
replay_rate = 10 * ZM_RATE_BASE;
break;
case 10 * ZM_RATE_BASE :
replay_rate = 25 * ZM_RATE_BASE;
break;
case 25 * ZM_RATE_BASE :
case 50 * ZM_RATE_BASE :
replay_rate = 50 * ZM_RATE_BASE;
break;
default :
replay_rate = 2 * ZM_RATE_BASE;
break;
}
break;
}
case CMD_SLOWFWD :
{
Debug( 1, "Got SLOW FWD command" );
// Set paused flag
paused = true;
// Set delayed flag
delayed = true;
// Set play rate
replay_rate = ZM_RATE_BASE;
// Set step
step = 1;
break;
}
case CMD_SLOWREV :
{
Debug( 1, "Got SLOW REV command" );
// Set paused flag
paused = true;
// Set delayed flag
delayed = true;
// Set play rate
replay_rate = ZM_RATE_BASE;
// Set step
step = -1;
break;
}
case CMD_FASTREV :
{
Debug( 1, "Got FAST REV command" );
if ( paused ) {
// Clear paused flag
paused = false;
// Set delayed_play flag
delayed = true;
}
// Set play rate
switch ( replay_rate ) {
case -2 * ZM_RATE_BASE :
replay_rate = -5 * ZM_RATE_BASE;
break;
case -5 * ZM_RATE_BASE :
replay_rate = -10 * ZM_RATE_BASE;
break;
case -10 * ZM_RATE_BASE :
replay_rate = -25 * ZM_RATE_BASE;
break;
case -25 * ZM_RATE_BASE :
case -50 * ZM_RATE_BASE :
replay_rate = -50 * ZM_RATE_BASE;
break;
default :
replay_rate = -2 * ZM_RATE_BASE;
break;
}
break;
}
case CMD_ZOOMIN :
{
x = ((unsigned char)msg->msg_data[1]<<8)|(unsigned char)msg->msg_data[2];
y = ((unsigned char)msg->msg_data[3]<<8)|(unsigned char)msg->msg_data[4];
Debug( 1, "Got ZOOM IN command, to %d,%d", x, y );
switch ( zoom ) {
case 100:
zoom = 150;
break;
case 150:
zoom = 200;
break;
case 200:
zoom = 300;
break;
case 300:
zoom = 400;
break;
case 400:
default :
zoom = 500;
break;
}
break;
}
case CMD_ZOOMOUT :
{
Debug( 1, "Got ZOOM OUT command" );
switch ( zoom ) {
case 500:
zoom = 400;
break;
case 400:
zoom = 300;
break;
case 300:
zoom = 200;
break;
case 200:
zoom = 150;
break;
case 150:
default :
zoom = 100;
break;
}
break;
}
case CMD_PAN :
{
x = ((unsigned char)msg->msg_data[1]<<8)|(unsigned char)msg->msg_data[2];
y = ((unsigned char)msg->msg_data[3]<<8)|(unsigned char)msg->msg_data[4];
Debug( 1, "Got PAN command, to %d,%d", x, y );
break;
}
case CMD_SCALE :
{
scale = ((unsigned char)msg->msg_data[1]<<8)|(unsigned char)msg->msg_data[2];
Debug( 1, "Got SCALE command, to %d", scale );
break;
}
case CMD_QUIT :
{
Info ("User initiated exit - CMD_QUIT");
break;
}
case CMD_QUERY :
{
Debug( 1, "Got QUERY command, sending STATUS" );
break;
}
default :
{
Error( "Got unexpected command %d", msg->msg_data[0] );
break;
}
}
struct {
int id;
int state;
double fps;
int buffer_level;
int rate;
double delay;
int zoom;
bool delayed;
bool paused;
bool enabled;
bool forced;
} status_data;
status_data.id = monitor->Id();
status_data.fps = monitor->GetFPS();
status_data.state = monitor->shared_data->state;
if ( playback_buffer > 0 )
status_data.buffer_level = (MOD_ADD( (temp_write_index-temp_read_index), 0, temp_image_buffer_count )*100)/temp_image_buffer_count;
else
status_data.buffer_level = 0;
status_data.delayed = delayed;
status_data.paused = paused;
status_data.rate = replay_rate;
status_data.delay = TV_2_FLOAT( now ) - TV_2_FLOAT( last_frame_timestamp );
status_data.zoom = zoom;
//status_data.enabled = monitor->shared_data->active;
status_data.enabled = monitor->trigger_data->trigger_state!=Monitor::TRIGGER_OFF;
status_data.forced = monitor->trigger_data->trigger_state==Monitor::TRIGGER_ON;
Debug( 2, "L:%d, D:%d, P:%d, R:%d, d:%.3f, Z:%d, E:%d F:%d",
status_data.buffer_level,
status_data.delayed,
status_data.paused,
status_data.rate,
status_data.delay,
status_data.zoom,
status_data.enabled,
status_data.forced
);
DataMsg status_msg;
status_msg.msg_type = MSG_DATA_WATCH;
memcpy( &status_msg.msg_data, &status_data, sizeof(status_data) );
int nbytes = 0;
if ( (nbytes = sendto( sd, &status_msg, sizeof(status_msg), MSG_DONTWAIT, (sockaddr *)&rem_addr, sizeof(rem_addr) )) < 0 ) {
//if ( errno != EAGAIN )
{
Error( "Can't sendto on sd %d: %s", sd, strerror(errno) );
//exit( -1 );
}
}
// quit after sending a status, if this was a quit request
if ((MsgCommand)msg->msg_data[0]==CMD_QUIT)
exit(0);
updateFrameRate( monitor->GetFPS() );
} // end void MonitorStream::processCommand( const CmdMsg *msg )
bool MonitorStream::sendFrame( const char *filepath, struct timeval *timestamp ) {
bool send_raw = ((scale>=ZM_SCALE_BASE)&&(zoom==ZM_SCALE_BASE));
if ( type != STREAM_JPEG )
send_raw = false;
if ( !config.timestamp_on_capture && timestamp )
send_raw = false;
if ( !send_raw ) {
Image temp_image( filepath );
return( sendFrame( &temp_image, timestamp ) );
} else {
int img_buffer_size = 0;
static unsigned char img_buffer[ZM_MAX_IMAGE_SIZE];
FILE *fdj = NULL;
if ( (fdj = fopen( filepath, "r" )) ) {
img_buffer_size = fread( img_buffer, 1, sizeof(img_buffer), fdj );
fclose( fdj );
} else {
Error( "Can't open %s: %s", filepath, strerror(errno) );
return( false );
}
// Calculate how long it takes to actually send the frame
struct timeval frameStartTime;
gettimeofday( &frameStartTime, NULL );
fprintf( stdout, "--ZoneMinderFrame\r\n" );
fprintf( stdout, "Content-Length: %d\r\n", img_buffer_size );
fprintf( stdout, "Content-Type: image/jpeg\r\n\r\n" );
if ( fwrite( img_buffer, img_buffer_size, 1, stdout ) != 1 ) {
if ( ! zm_terminate )
Error( "Unable to send stream frame: %s", strerror(errno) );
return( false );
}
fprintf( stdout, "\r\n\r\n" );
fflush( stdout );
struct timeval frameEndTime;
gettimeofday( &frameEndTime, NULL );
int frameSendTime = tvDiffMsec( frameStartTime, frameEndTime );
if ( frameSendTime > 1000/maxfps ) {
maxfps /= 2;
Error( "Frame send time %d msec too slow, throttling maxfps to %.2f", frameSendTime, maxfps );
}
last_frame_sent = TV_2_FLOAT( now );
return( true );
}
return( false );
}
bool MonitorStream::sendFrame( Image *image, struct timeval *timestamp ) {
Image *send_image = prepareImage( image );
if ( !config.timestamp_on_capture && timestamp )
monitor->TimestampImage( send_image, timestamp );
#if HAVE_LIBAVCODEC
if ( type == STREAM_MPEG ) {
if ( !vid_stream ) {
vid_stream = new VideoStream( "pipe:", format, bitrate, effective_fps, send_image->Colours(), send_image->SubpixelOrder(), send_image->Width(), send_image->Height() );
fprintf( stdout, "Content-type: %s\r\n\r\n", vid_stream->MimeType() );
vid_stream->OpenStream();
}
static struct timeval base_time;
struct DeltaTimeval delta_time;
if ( !frame_count )
base_time = *timestamp;
DELTA_TIMEVAL( delta_time, *timestamp, base_time, DT_PREC_3 );
/* double pts = */ vid_stream->EncodeFrame( send_image->Buffer(), send_image->Size(), config.mpeg_timed_frames, delta_time.delta );
} else
#endif // HAVE_LIBAVCODEC
{
static unsigned char temp_img_buffer[ZM_MAX_IMAGE_SIZE];
int img_buffer_size = 0;
unsigned char *img_buffer = temp_img_buffer;
// Calculate how long it takes to actually send the frame
struct timeval frameStartTime;
gettimeofday( &frameStartTime, NULL );
fprintf( stdout, "--ZoneMinderFrame\r\n" );
switch( type ) {
case STREAM_JPEG :
send_image->EncodeJpeg( img_buffer, &img_buffer_size );
fprintf( stdout, "Content-Type: image/jpeg\r\n" );
break;
case STREAM_RAW :
fprintf( stdout, "Content-Type: image/x-rgb\r\n" );
img_buffer = (uint8_t*)send_image->Buffer();
img_buffer_size = send_image->Size();
break;
case STREAM_ZIP :
fprintf( stdout, "Content-Type: image/x-rgbz\r\n" );
unsigned long zip_buffer_size;
send_image->Zip( img_buffer, &zip_buffer_size );
img_buffer_size = zip_buffer_size;
break;
default :
Fatal( "Unexpected frame type %d", type );
break;
}
fprintf( stdout, "Content-Length: %d\r\n\r\n", img_buffer_size );
if ( fwrite( img_buffer, img_buffer_size, 1, stdout ) != 1 ) {
if ( !zm_terminate )
Error( "Unable to send stream frame: %s", strerror(errno) );
return( false );
}
fprintf( stdout, "\r\n\r\n" );
fflush( stdout );
struct timeval frameEndTime;
gettimeofday( &frameEndTime, NULL );
int frameSendTime = tvDiffMsec( frameStartTime, frameEndTime );
if ( frameSendTime > 1000/maxfps ) {
maxfps /= 1.5;
Error( "Frame send time %d msec too slow, throttling maxfps to %.2f", frameSendTime, maxfps );
}
}
last_frame_sent = TV_2_FLOAT( now );
return( true );
} // end bool MonitorStream::sendFrame( Image *image, struct timeval *timestamp )
void MonitorStream::runStream() {
if ( type == STREAM_SINGLE ) {
// Not yet migrated over to stream class
SingleImage( scale );
return;
}
openComms();
2017-08-12 00:20:46 +08:00
if ( ! checkInitialised() ) {
Error("Not initialized");
return;
}
2017-04-11 09:57:31 +08:00
updateFrameRate( monitor->GetFPS() );
if ( type == STREAM_JPEG )
fprintf( stdout, "Content-Type: multipart/x-mixed-replace;boundary=ZoneMinderFrame\r\n\r\n" );
int last_read_index = monitor->image_buffer_count;
time_t stream_start_time;
time( &stream_start_time );
frame_count = 0;
temp_image_buffer = 0;
temp_image_buffer_count = playback_buffer;
temp_read_index = temp_image_buffer_count;
temp_write_index = temp_image_buffer_count;
char *swap_path = 0;
bool buffered_playback = false;
// 15 is the max length for the swap path suffix, /zmswap-whatever, assuming max 6 digits for monitor id
const int max_swap_len_suffix = 15;
2017-06-14 09:15:58 +08:00
int swap_path_length = staticConfig.PATH_SWAP.length() + 1; // +1 for NULL terminator
2017-04-11 09:57:31 +08:00
int subfolder1_length = snprintf(NULL, 0, "/zmswap-m%d", monitor->Id() ) + 1;
int subfolder2_length = snprintf(NULL, 0, "/zmswap-q%06d", connkey ) + 1;
int total_swap_path_length = swap_path_length + subfolder1_length + subfolder2_length;
if ( connkey && playback_buffer > 0 ) {
if ( total_swap_path_length + max_swap_len_suffix > PATH_MAX ) {
Error( "Swap Path is too long. %d > %d ", total_swap_path_length+max_swap_len_suffix, PATH_MAX );
} else {
swap_path = (char *)malloc( total_swap_path_length+max_swap_len_suffix );
2017-06-14 09:15:58 +08:00
strncpy( swap_path, staticConfig.PATH_SWAP.c_str(), swap_path_length );
2017-04-11 09:57:31 +08:00
Debug( 3, "Checking swap path folder: %s", swap_path );
if ( checkSwapPath( swap_path, false ) ) {
// Append the subfolder name /zmswap-m{monitor-id} to the end of swap_path
int ndx = swap_path_length - 1; // Array index of the NULL terminator
snprintf( &(swap_path[ndx]), subfolder1_length, "/zmswap-m%d", monitor->Id() );
Debug( 4, "Checking swap path subfolder: %s", swap_path );
if ( checkSwapPath( swap_path, true ) ) {
// Append the subfolder name /zmswap-q{connection key} to the end of swap_path
ndx = swap_path_length+subfolder1_length - 2; // Array index of the NULL terminator
snprintf( &(swap_path[ndx]), subfolder2_length, "/zmswap-q%06d", connkey );
Debug( 4, "Checking swap path subfolder: %s", swap_path );
if ( checkSwapPath( swap_path, true ) ) {
buffered_playback = true;
}
}
}
if ( !buffered_playback ) {
Error( "Unable to validate swap image path, disabling buffered playback" );
} else {
Debug( 2, "Assigning temporary buffer" );
temp_image_buffer = new SwapImage[temp_image_buffer_count];
memset( temp_image_buffer, 0, sizeof(*temp_image_buffer)*temp_image_buffer_count );
Debug( 2, "Assigned temporary buffer" );
}
}
}
float max_secs_since_last_sent_frame = 10.0; //should be > keep alive amount (5 secs)
while ( !zm_terminate ) {
bool got_command = false;
if ( feof( stdout ) || ferror( stdout ) || !monitor->ShmValid() ) {
break;
}
gettimeofday( &now, NULL );
if ( connkey ) {
while(checkCommandQueue()) {
got_command = true;
}
}
//bool frame_sent = false;
if ( buffered_playback && delayed ) {
if ( temp_read_index == temp_write_index ) {
// Go back to live viewing
Debug( 1, "Exceeded temporary streaming buffer" );
// Clear paused flag
paused = false;
// Clear delayed_play flag
delayed = false;
replay_rate = ZM_RATE_BASE;
} else {
if ( !paused ) {
int temp_index = MOD_ADD( temp_read_index, 0, temp_image_buffer_count );
//Debug( 3, "tri: %d, ti: %d", temp_read_index, temp_index );
SwapImage *swap_image = &temp_image_buffer[temp_index];
if ( !swap_image->valid ) {
paused = true;
delayed = true;
temp_read_index = MOD_ADD( temp_read_index, (replay_rate>=0?-1:1), temp_image_buffer_count );
} else {
//Debug( 3, "siT: %f, lfT: %f", TV_2_FLOAT( swap_image->timestamp ), TV_2_FLOAT( last_frame_timestamp ) );
double expected_delta_time = ((TV_2_FLOAT( swap_image->timestamp ) - TV_2_FLOAT( last_frame_timestamp )) * ZM_RATE_BASE)/replay_rate;
double actual_delta_time = TV_2_FLOAT( now ) - last_frame_sent;
//Debug( 3, "eDT: %.3lf, aDT: %.3f, lFS:%.3f, NOW:%.3f", expected_delta_time, actual_delta_time, last_frame_sent, TV_2_FLOAT( now ) );
// If the next frame is due
if ( actual_delta_time > expected_delta_time ) {
//Debug( 2, "eDT: %.3lf, aDT: %.3f", expected_delta_time, actual_delta_time );
if ( temp_index%frame_mod == 0 ) {
Debug( 2, "Sending delayed frame %d", temp_index );
// Send the next frame
if ( ! sendFrame( temp_image_buffer[temp_index].file_name, &temp_image_buffer[temp_index].timestamp ) )
zm_terminate = true;
memcpy( &last_frame_timestamp, &(swap_image->timestamp), sizeof(last_frame_timestamp) );
//frame_sent = true;
}
temp_read_index = MOD_ADD( temp_read_index, (replay_rate>0?1:-1), temp_image_buffer_count );
}
}
} else if ( step != 0 ) {
temp_read_index = MOD_ADD( temp_read_index, (step>0?1:-1), temp_image_buffer_count );
SwapImage *swap_image = &temp_image_buffer[temp_read_index];
// Send the next frame
if ( !sendFrame( temp_image_buffer[temp_read_index].file_name, &temp_image_buffer[temp_read_index].timestamp ) )
zm_terminate = true;
memcpy( &last_frame_timestamp, &(swap_image->timestamp), sizeof(last_frame_timestamp) );
//frame_sent = true;
step = 0;
} else {
int temp_index = MOD_ADD( temp_read_index, 0, temp_image_buffer_count );
double actual_delta_time = TV_2_FLOAT( now ) - last_frame_sent;
if ( got_command || actual_delta_time > 5 ) {
// Send keepalive
Debug( 2, "Sending keepalive frame %d", temp_index );
// Send the next frame
if ( !sendFrame( temp_image_buffer[temp_index].file_name, &temp_image_buffer[temp_index].timestamp ) )
zm_terminate = true;
//frame_sent = true;
}
}
}
if ( temp_read_index == temp_write_index ) {
// Go back to live viewing
Warning( "Rewound over write index, resuming live play" );
// Clear paused flag
paused = false;
// Clear delayed_play flag
delayed = false;
replay_rate = ZM_RATE_BASE;
}
}
if ( (unsigned int)last_read_index != monitor->shared_data->last_write_index ) {
int index = monitor->shared_data->last_write_index%monitor->image_buffer_count;
last_read_index = monitor->shared_data->last_write_index;
//Debug( 1, "%d: %x - %x", index, image_buffer[index].image, image_buffer[index].image->buffer );
if ( (frame_mod == 1) || ((frame_count%frame_mod) == 0) ) {
if ( !paused && !delayed ) {
// Send the next frame
Monitor::Snapshot *snap = &monitor->image_buffer[index];
if ( !sendFrame( snap->image, snap->timestamp ) )
zm_terminate = true;
memcpy( &last_frame_timestamp, snap->timestamp, sizeof(last_frame_timestamp) );
//frame_sent = true;
temp_read_index = temp_write_index;
}
}
if ( buffered_playback ) {
if ( monitor->shared_data->valid ) {
if ( monitor->image_buffer[index].timestamp->tv_sec ) {
int temp_index = temp_write_index%temp_image_buffer_count;
Debug( 2, "Storing frame %d", temp_index );
if ( !temp_image_buffer[temp_index].valid ) {
snprintf( temp_image_buffer[temp_index].file_name, sizeof(temp_image_buffer[0].file_name), "%s/zmswap-i%05d.jpg", swap_path, temp_index );
temp_image_buffer[temp_index].valid = true;
}
memcpy( &(temp_image_buffer[temp_index].timestamp), monitor->image_buffer[index].timestamp, sizeof(temp_image_buffer[0].timestamp) );
monitor->image_buffer[index].image->WriteJpeg( temp_image_buffer[temp_index].file_name, config.jpeg_file_quality );
temp_write_index = MOD_ADD( temp_write_index, 1, temp_image_buffer_count );
if ( temp_write_index == temp_read_index ) {
// Go back to live viewing
Warning( "Exceeded temporary buffer, resuming live play" );
// Clear paused flag
paused = false;
// Clear delayed_play flag
delayed = false;
replay_rate = ZM_RATE_BASE;
}
} else {
Warning( "Unable to store frame as timestamp invalid" );
}
} else {
Warning( "Unable to store frame as shared memory invalid" );
}
}
frame_count++;
}
usleep( (unsigned long)((1000000 * ZM_RATE_BASE)/((base_fps?base_fps:1)*abs(replay_rate*2))) );
if ( ttl ) {
if ( (now.tv_sec - stream_start_time) > ttl ) {
break;
}
}
if ( (TV_2_FLOAT( now ) - last_frame_sent) > max_secs_since_last_sent_frame ) {
Error( "Terminating, last frame sent time %f secs more than maximum of %f", TV_2_FLOAT( now ) - last_frame_sent, max_secs_since_last_sent_frame );
break;
}
}
if ( buffered_playback ) {
Debug( 1, "Cleaning swap files from %s", swap_path );
struct stat stat_buf;
if ( stat( swap_path, &stat_buf ) < 0 ) {
if ( errno != ENOENT ) {
Error( "Can't stat '%s': %s", swap_path, strerror(errno) );
}
} else if ( !S_ISDIR(stat_buf.st_mode) ) {
Error( "Swap image path '%s' is not a directory", swap_path );
} else {
char glob_pattern[PATH_MAX] = "";
snprintf( glob_pattern, sizeof(glob_pattern), "%s/*.*", swap_path );
glob_t pglob;
int glob_status = glob( glob_pattern, 0, 0, &pglob );
if ( glob_status != 0 ) {
if ( glob_status < 0 ) {
Error( "Can't glob '%s': %s", glob_pattern, strerror(errno) );
} else {
Debug( 1, "Can't glob '%s': %d", glob_pattern, glob_status );
}
} else {
for ( unsigned int i = 0; i < pglob.gl_pathc; i++ ) {
if ( unlink( pglob.gl_pathv[i] ) < 0 ) {
Error( "Can't unlink '%s': %s", pglob.gl_pathv[i], strerror(errno) );
}
}
}
globfree( &pglob );
if ( rmdir( swap_path ) < 0 ) {
Error( "Can't rmdir '%s': %s", swap_path, strerror(errno) );
}
} // end if checking for swap_path
} // end if buffered_playback
2017-04-11 09:57:31 +08:00
if ( swap_path ) free( swap_path );
closeComms();
}
void MonitorStream::SingleImage( int scale ) {
int img_buffer_size = 0;
static JOCTET img_buffer[ZM_MAX_IMAGE_SIZE];
Image scaled_image;
Monitor::Snapshot *snap = monitor->getSnapshot();
Image *snap_image = snap->image;
if ( scale != ZM_SCALE_BASE ) {
scaled_image.Assign( *snap_image );
scaled_image.Scale( scale );
snap_image = &scaled_image;
}
if ( !config.timestamp_on_capture ) {
monitor->TimestampImage( snap_image, snap->timestamp );
}
snap_image->EncodeJpeg( img_buffer, &img_buffer_size );
fprintf( stdout, "Content-Length: %d\r\n", img_buffer_size );
fprintf( stdout, "Content-Type: image/jpeg\r\n\r\n" );
fwrite( img_buffer, img_buffer_size, 1, stdout );
}
void MonitorStream::SingleImageRaw( int scale ) {
Image scaled_image;
Monitor::Snapshot *snap = monitor->getSnapshot();
Image *snap_image = snap->image;
if ( scale != ZM_SCALE_BASE ) {
scaled_image.Assign( *snap_image );
scaled_image.Scale( scale );
snap_image = &scaled_image;
}
if ( !config.timestamp_on_capture ) {
monitor->TimestampImage( snap_image, snap->timestamp );
}
fprintf( stdout, "Content-Length: %d\r\n", snap_image->Size() );
fprintf( stdout, "Content-Type: image/x-rgb\r\n\r\n" );
fwrite( snap_image->Buffer(), snap_image->Size(), 1, stdout );
}
void MonitorStream::SingleImageZip( int scale ) {
unsigned long img_buffer_size = 0;
static Bytef img_buffer[ZM_MAX_IMAGE_SIZE];
Image scaled_image;
Monitor::Snapshot *snap = monitor->getSnapshot();
Image *snap_image = snap->image;
if ( scale != ZM_SCALE_BASE ) {
scaled_image.Assign( *snap_image );
scaled_image.Scale( scale );
snap_image = &scaled_image;
}
if ( !config.timestamp_on_capture ) {
monitor->TimestampImage( snap_image, snap->timestamp );
}
snap_image->Zip( img_buffer, &img_buffer_size );
fprintf( stdout, "Content-Length: %ld\r\n", img_buffer_size );
fprintf( stdout, "Content-Type: image/x-rgbz\r\n\r\n" );
fwrite( img_buffer, img_buffer_size, 1, stdout );
}