voltando a versao de n aberturas e fechamentos de sockets data 19/09
Dependencies: EthernetInterface NTPClient mbed-rtos mbed EALib
Fork of header_main_publish by
vz_protocol.cpp
- Committer:
- klauss
- Date:
- 2014-09-20
- Revision:
- 19:ab2088e0dec6
- Parent:
- 18:01a93677e40c
File content as of revision 19:ab2088e0dec6:
#include "vz_protocol.h" extern DigitalOut led2; extern DigitalOut led3; uint8_t * __parse_cb_buffer__( int * ext, int * port, volatile uint8_t * type, uint8_t * cb_buffer ){ /** * parse and split vz package, * | E | E | P | P | C | C | T | [ Seq_num | Audio ] | 14[ Clock | Audio ] | [ TS | Audio ] | ... | * E = Ext = Ramal * P = Port = Porta * C = Checksum * T = Type = Tipo * Seq_num = Sequence Number = Numero de sequencia * Clock = 14 bytes to sync * ... = demais __CB_BUFFER_SIZE__ - __VZ_HEADER_OFFSET__ bytes */ uint8_t p_lsb, p_msb; uint8_t e_lsb, e_msb; if( cb_buffer == NULL ) return( NULL ); uint16_t cc = ( uint16_t )cb_buffer[ 4 ] << 8 | cb_buffer[ 5 ]; /* UDPSocket debug; Endpoint debug_server; char debug_msg[ 1024 ]; debug_server.set_address( "192.168.120.180", 9897 ); debug.bind( 8182 ); debug.init(); //if( cc != __checksum__( cb_buffer + __CHECKSUM_OFFSET__, // __CB_BUFFER_SIZE__ - __CHECKSUM_OFFSET__ ) ){ sprintf( debug_msg, " -- cc :: %x :: __checksum %x -- bit[4] %x :: bit[5] %x", cc, __checksum__( cb_buffer, __CB_BUFFER_SIZE__ ), cb_buffer[ 4 ], cb_buffer[ 5 ] ); debug.sendTo( debug_server, debug_msg, strlen( debug_msg ) ); debug.sendTo( debug_server, debug_msg, strlen( debug_msg ) ); */ if( cc != __checksum__( cb_buffer, __CB_BUFFER_SIZE__ ) ){ return( NULL ); }else{ e_msb = cb_buffer[ 0 ]; e_lsb = cb_buffer[ 1 ]; *ext = e_msb << 8 | e_lsb; p_msb = cb_buffer[ 2 ]; p_lsb = cb_buffer[ 3 ]; *port = p_msb << 8 | p_lsb; *type = cb_buffer[ 6 ]; return( cb_buffer + __VZ_HEADER_OFFSET__ ); } } uint8_t * __build_cb_package__( int ext, int port, uint8_t type, char * cb_buffer, uint8_t seq_num, int length, uint8_t * pkg ){ debug_msg(""); pkg[ 0 ] = ( uint8_t )( ( ext & 0xFF00 ) >> 8 ); pkg[ 1 ] = ( uint8_t )( ext & 0x00FF ); pkg[ 2 ] = ( uint8_t )( ( port & 0xFF00 ) >> 8 ); pkg[ 3 ] = ( uint8_t )( port & 0x00FF ); pkg[ 6 ] = type; size_t fill = 0x00; if( type == __AUDIO__ ){ for( register int i = __VZ_HEADER_OFFSET__; i < length + __VZ_HEADER_OFFSET__; i++ ) pkg[ i ] = ( uint8_t )cb_buffer[ i - __VZ_HEADER_OFFSET__ ]; fill = length + __VZ_HEADER_OFFSET__; }else if( type == __INVITE__ ){ pkg[ 7 ] = seq_num; //__print_clock__( pkg + 8 ); pkg[ __TIMESLICE_PLACE__ ] = cb_buffer[ __TIMESLICE_PLACE__ ]; fill = __TIMESLICE_PLACE__ + 1; }else if( type == __REGISTRY__ || type == __BOOT__ ){ pkg[ 7 ] = seq_num; //__print_clock__( pkg + 8 ); fill = __VZ_HEADER_OFFSET__ + __CLOCK_SYNC_SIZE__ + __SEQ_NUM_SIZE__; }if( type == __CB_BYE__ ){ pkg[ 7 ] = seq_num; //__print_clock__( pkg + 8 ); pkg[ __TIMESLICE_PLACE__ ] = cb_buffer[ __TIMESLICE_PLACE__ ]; fill = __TIMESLICE_PLACE__ + 1; }else if( type == __TELEMETRY__ ){ pkg[ 7 ] = seq_num; //__print_clock__( pkg + 8 ); pkg[ __TIMESLICE_PLACE__ ] = cb_buffer[ __TIMESLICE_PLACE__ ]; fill = __TIMESLICE_PLACE__ + 1; } for( register int i = fill; i < __CB_BUFFER_SIZE__; i++ ) pkg[ i ] = 0x00; led2 = !led2; uint16_t cc = __checksum__( pkg, 300 ); pkg[ 4 ] =( uint8_t )( ( cc & 0xFF00 ) >> 8) ; pkg[ 5 ] =( uint8_t )( cc & 0x00FF ); debug_msg(""); return pkg; } char * __build_eth__package__( void ){ return( NULL ); } uint8_t * __read_cb_buffer__( uint8_t * dest, uint8_t * src ){ for( register int i = 0; i < __CB_BUFFER_SIZE__; i++ ) *dest++ = *src++; return( dest ); } uint8_t * __read_eth_buffer__( uint8_t * dest, uint8_t * src ){ for( register int i = 0; i < __ETH_BUFFER_SIZE__; i++ ) *dest++ = *src++; return( dest ); } uint8_t * __write_cb_buffer__( uint8_t * dest, uint8_t * src ){ for( register int i = 0; i < __CB_BUFFER_SIZE__; i++ ) *dest++ = *src++; return( dest ); } uint8_t * __write_eth_buffer__( uint8_t * dest, uint8_t * src ){ for( register int i = 0; i < __ETH_BUFFER_SIZE__; i++ ) *dest++ = *src++; return( dest ); } uint16_t __checksum__( uint8_t * buffer, size_t length ){ uint16_t cc = 0x00; buffer[ 4 ] = buffer[ 5 ] = 0x5a; for( register int i = 0; i < length; i++ ){ cc += buffer[ i ]; if( cc & BIT15 ){ cc <<= 1; cc |= BIT0; }else{ cc <<= BIT0; } } cc ^= 0xffff; return cc; } void __print_clock__( uint8_t * buffer ){ debug_msg(""); NTPClient ntp; debug_msg(""); //int ntp_result = ntp.setTime( "200.192.232.8", 123, 3 ); struct tm ts; int ntp_result = ntp.setTime( "200.192.232.8" ); if( ntp_result == 0 ){ debug_msg(""); time_t seconds; debug_msg(""); // seconds = time(NULL); time( &seconds ); debug_msg(""); ts = *localtime( &seconds ); } debug_msg(""); int ano = ts.tm_year + 1900; int mes = ts.tm_mon + 1; int dia = ts.tm_mday; int hora = ts.tm_hour - 3; int min = ts.tm_min; int sec = ts.tm_sec; buffer[ 0 ] = ano / 1000; ano -= buffer[ 0 ] * 1000; buffer[ 1 ] = ano / 100; ano -= buffer[ 1 ]* 100; buffer[ 2 ] = ano / 10; ano -= buffer[ 2 ] * 10; buffer[ 3 ] = ano; buffer[ 4 ] = mes / 10; buffer[ 5 ] = mes % 10; buffer[ 6 ] = dia / 10; buffer[ 7 ] = dia % 10; buffer[ 8 ] = hora / 10; buffer[ 9 ] = hora % 10; buffer[ 10 ] = min / 10; buffer[ 11 ] = min % 10; buffer[ 12 ] = sec / 10; buffer[ 13 ] = sec % 10; /* convertendo pro ascii do nro */ for( register int i = 0; i < 14; i++ ) buffer[ i ] += 0x30; debug_msg(""); }