hyperion.ng/libsrc/leddevice/LedDeviceUdp.cpp
redPanther 197af35de0 Clone single led color from other led (#157)
* start ledclone

* led cloning: clone scan areas from original led
main: show exceptions, better exit

* tune json schema for new option. somwe cleanup

* fix warnings and bug for framebuffer selection. thx to clang brought by new osx buikld on travis

* make ledclone feature work flawlessly for effects too. Effect sees the ledstring without cloned leds.
cloned leds will be inserted just before sending to leddevice

additional: remove warnings and fix code style

* fix warning
2016-08-08 00:17:00 +02:00

200 lines
4.9 KiB
C++

// Local-Hyperion includes
#include "LedDeviceUdp.h"
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <errno.h>
#include <string.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <netdb.h>
#include <assert.h>
struct addrinfo hints, *servinfo, *p;
//char udpbuffer[1024];
int sockfd;
int ledprotocol;
unsigned leds_per_pkt;
int update_number;
int fragment_number;
LedDeviceUdp::LedDeviceUdp(const std::string& output, const unsigned protocol, const unsigned maxPacket)
{
std::string hostname;
std::string port;
ledprotocol = protocol;
leds_per_pkt = ((maxPacket-4)/3);
if (leds_per_pkt <= 0) {
leds_per_pkt = 200;
}
int got_colon=0;
for (unsigned int i=0; i<output.length(); i++) {
if (output[i] == ':') {
got_colon++;
} else if (got_colon == 0) {
hostname+=output[i];
} else {
port+=output[i];
}
}
assert(got_colon==1);
int rv;
memset(&hints, 0, sizeof hints);
hints.ai_family = AF_UNSPEC;
hints.ai_socktype = SOCK_DGRAM;
if ((rv = getaddrinfo(hostname.c_str() , port.c_str(), &hints, &servinfo)) != 0) {
Debug(_log, "getaddrinfo: %s", gai_strerror(rv));
assert(rv==0);
}
// loop through all the results and make a socket
for(p = servinfo; p != NULL; p = p->ai_next) {
if ((sockfd = socket(p->ai_family, p->ai_socktype,
p->ai_protocol)) == -1) {
Error(_log,"talker: socket %s", strerror(errno));
// perror("talker: socket");
continue;
}
break;
}
if (p == NULL) {
Error(_log,"talker: failed to create socket");
assert(p!=NULL);
}
}
LedDeviceUdp::~LedDeviceUdp()
{
// empty
}
int LedDeviceUdp::write(const std::vector<ColorRgb> & ledValues)
{
char udpbuffer[4096];
int udpPtr=0;
update_number++;
update_number &= 0xf;
if (ledprotocol == 0) {
int i=0;
for (const ColorRgb& color : ledValues)
{
if (i<4090) {
udpbuffer[i++] = color.red;
udpbuffer[i++] = color.green;
udpbuffer[i++] = color.blue;
}
}
sendto(sockfd, udpbuffer, i, 0, p->ai_addr, p->ai_addrlen);
}
if (ledprotocol == 1) {
#define MAXLEDperFRAG 450
int mLedCount = ledValues.size();
for (int frag=0; frag<4; frag++) {
udpPtr=0;
udpbuffer[udpPtr++] = 0;
udpbuffer[udpPtr++] = 0;
udpbuffer[udpPtr++] = (frag*MAXLEDperFRAG)/256; // high byte
udpbuffer[udpPtr++] = (frag*MAXLEDperFRAG)%256; // low byte
int ct=0;
for (int this_led = frag*300; ((this_led<mLedCount) && (ct++<MAXLEDperFRAG)); this_led++) {
const ColorRgb& color = ledValues[this_led];
if (udpPtr<4090) {
udpbuffer[udpPtr++] = color.red;
udpbuffer[udpPtr++] = color.green;
udpbuffer[udpPtr++] = color.blue;
}
}
if (udpPtr > 7)
sendto(sockfd, udpbuffer, udpPtr, 0, p->ai_addr, p->ai_addrlen);
}
}
if (ledprotocol == 2) {
udpPtr = 0;
unsigned int ledCtr = 0;
fragment_number = 0;
udpbuffer[udpPtr++] = update_number & 0xf;
udpbuffer[udpPtr++] = fragment_number++;
udpbuffer[udpPtr++] = ledCtr/256; // high byte
udpbuffer[udpPtr++] = ledCtr%256; // low byte
for (const ColorRgb& color : ledValues)
{
if (udpPtr<4090) {
udpbuffer[udpPtr++] = color.red;
udpbuffer[udpPtr++] = color.green;
udpbuffer[udpPtr++] = color.blue;
}
ledCtr++;
if ( (ledCtr % leds_per_pkt == 0) || (ledCtr == ledValues.size()) ) {
sendto(sockfd, udpbuffer, udpPtr, 0, p->ai_addr, p->ai_addrlen);
memset(udpbuffer, 0, sizeof udpbuffer);
udpPtr = 0;
udpbuffer[udpPtr++] = update_number & 0xf;
udpbuffer[udpPtr++] = fragment_number++;
udpbuffer[udpPtr++] = ledCtr/256; // high byte
udpbuffer[udpPtr++] = ledCtr%256; // low byte
}
}
}
if (ledprotocol == 3) {
udpPtr = 0;
unsigned int ledCtr = 0;
unsigned int fragments = 1;
unsigned int datasize = ledValues.size() * 3;
if (ledValues.size() > leds_per_pkt) {
fragments = (ledValues.size() / leds_per_pkt) + 1;
}
fragment_number = 1;
udpbuffer[udpPtr++] = 0x9C;
udpbuffer[udpPtr++] = 0xDA;
udpbuffer[udpPtr++] = datasize/256; // high byte
udpbuffer[udpPtr++] = datasize%256; // low byte
udpbuffer[udpPtr++] = fragment_number++;
udpbuffer[udpPtr++] = fragments;
for (const ColorRgb& color : ledValues)
{
if (udpPtr<4090) {
udpbuffer[udpPtr++] = color.red;
udpbuffer[udpPtr++] = color.green;
udpbuffer[udpPtr++] = color.blue;
}
ledCtr++;
if ( (ledCtr % leds_per_pkt == 0) || (ledCtr == ledValues.size()) ) {
udpbuffer[udpPtr++] = 0x36;
sendto(sockfd, udpbuffer, udpPtr, 0, p->ai_addr, p->ai_addrlen);
memset(udpbuffer, 0, sizeof udpbuffer);
udpPtr = 0;
udpbuffer[udpPtr++] = 0x9C;
udpbuffer[udpPtr++] = 0xDA;
udpbuffer[udpPtr++] = datasize/256; // high byte
udpbuffer[udpPtr++] = datasize%256; // low byte
udpbuffer[udpPtr++] = fragment_number++;
udpbuffer[udpPtr++] = fragments;
}
}
}
return 0;
}
int LedDeviceUdp::switchOff()
{
// return write(std::vector<ColorRgb>(mLedCount, ColorRgb{0,0,0}));
return 0;
}