/**************************************************************************
* Lock and initialize the serial port.
* This function is called by the LIRC daemon when the first client
* registers itself.
* Return 1 on success, 0 on error.
**************************************************************************/
int mplay_init(void)
{
int result = 1;
LOGPRINTF(1, "Entering mplay_init()");
/* Creation of a lock file for the port */
if (!tty_create_lock(hw.device)) {
logprintf(LOG_ERR, "Could not create the lock file");
LOGPRINTF(1, "Could not create the lock file");
result = 0;
}
/* Try to open serial port */
else if ((hw.fd = open(hw.device, O_RDWR | O_NONBLOCK | O_NOCTTY)) < 0) {
logprintf(LOG_ERR, "Could not open the serial port");
LOGPRINTF(1, "Could not open the serial port");
mplay_deinit();
result = 0;
}
/* Serial port configuration */
else if (!tty_reset(hw.fd) || !tty_setbaud(hw.fd, MPLAY_BAUD_RATE)) {
logprintf(LOG_ERR, "could not configure the serial port for '%s'", hw.device);
LOGPRINTF(1, "could not configure the serial port for '%s'", hw.device);
mplay_deinit();
}
return result;
}
static char *uirt2_raw_rec(struct ir_remote *remotes)
{
LOGPRINTF(1, "uirt2_raw_rec");
LOGPRINTF(1, "uirt2_raw_rec: %p", remotes);
if (!clear_rec_buffer())
return (NULL);
if (remotes) {
char *res;
res = decode_all(remotes);
return res;
} else {
lirc_t data;
queue_clear();
data = uirt2_read_raw(dev, 1);
if (data) {
queue_put(data);
}
return NULL;
}
}
//TODO failure? return 0 on success
int
remove_interval(struct pmm_interval_list *l, struct pmm_interval *i)
{
LOGPRINTF("removing interval with type: %d\n", i->type);
//if interval is at top or bottom, rewire top/bottom pointers
if(l->top == i) {
l->top = i->previous;
}
if(l->bottom == i) {
l->bottom = i->next;
}
//rewire intervals that were previous/next intervals of the remove-ee
if(i->next != NULL) {
i->next->previous = i->previous;
}
if(i->previous != NULL) {
i->previous->next = i->next;
}
//free interval
free_interval(&i);
l->size -= 1;
LOGPRINTF("size: %d\n", l->size);
return 1;
}
int tty_read(int fd,char *byte)
{
fd_set fds;
int ret;
struct timeval tv;
FD_ZERO(&fds);
FD_SET(fd,&fds);
tv.tv_sec=1; /* timeout after 1 sec */
tv.tv_usec=0;
ret=select(fd+1,&fds,NULL,NULL,&tv);
if(ret==0)
{
logprintf(LOG_ERR,"tty_read(): timeout");
return(-1); /* received nothing, bad */
}
else if(ret!=1)
{
LOGPRINTF(1,"tty_read(): select() failed");
LOGPERROR(1,"tty_read()");
return(-1);
}
if(read(fd,byte,1)!=1)
{
LOGPRINTF(1,"tty_read(): read() failed");
LOGPERROR(1,"tty_read()");
return(-1);
}
return(1);
}
int tty_setrtscts(int fd,int enable)
{
struct termios options;
if(tcgetattr(fd,&options)==-1)
{
LOGPRINTF(1,"%s: tcgetattr() failed", __FUNCTION__);
LOGPERROR(1, __FUNCTION__);
return(0);
}
if(enable)
{
options.c_cflag|=CRTSCTS;
}
else
{
options.c_cflag&=~CRTSCTS;
}
if(tcsetattr(fd,TCSAFLUSH,&options)==-1)
{
LOGPRINTF(1,"%s: tcsetattr() failed", __FUNCTION__);
LOGPERROR(1, __FUNCTION__);
return(0);
}
return(1);
}
/* @brief Called after network connection state was requested, or the state has changed
*
*/
static void on_connection_status ( eripc_context_t *context,
const eripc_event_info_t *info,
void *user_data )
{
LOGPRINTF("entry");
const eripc_arg_t *arg_array = info->args;
if ((arg_array[0].type == ERIPC_TYPE_BOOL) &&
(arg_array[1].type == ERIPC_TYPE_STRING) &&
(arg_array[2].type == ERIPC_TYPE_STRING) &&
(arg_array[3].type == ERIPC_TYPE_STRING))
{
gboolean is_connected = arg_array[0].value.b;
//const gchar *medium = arg_array[1].value.s;
//const gchar *profile = arg_array[2].value.s;
//const gchar *reason = arg_array[3].value.s;
if (is_connected)
{
LOGPRINTF("Network connection established");
g_connect_cb();
}
else
{
LOGPRINTF("Network connection terminated - reason [%s]", arg_array[3].value.s);
g_disconnect_cb();
}
}
}
char *bte_readline()
{
static char msg[PACKET_SIZE + 1];
char c;
static int n = 0;
int ok = 1;
LOGPRINTF(6, "bte_readline called");
if (io_failed && !bte_connect()) // try to reestablish connection
return (NULL);
if ((ok = read(hw.fd, &c, 1)) <= 0) {
io_failed = 1;
logprintf(LOG_ERR, "bte_readline: read failed - %d: %s", errno, strerror(errno));
return (NULL);
}
if (ok == 0 || c == '\r')
return NULL;
if (c == '\n') {
if (n == 0)
return NULL;
msg[n] = 0;
n = 0;
LOGPRINTF(1, "bte_readline: %s", msg);
return (msg);
}
msg[n++] = c;
if (n >= PACKET_SIZE - 1)
msg[--n] = '!';
return NULL;
}
static int calc_data_bit(struct ir_remote *remote,
int table[], int table_len, int signal, int tUnit)
{
int i;
for (i = 0; i < table_len; i++)
{
if (table[i] == 0)
{
table[i] = signal / tUnit;
LOGPRINTF(2, "table[%d] = %d\n", i, table[i]);
return i;
}
if (expect(remote, signal, table[i] * tUnit))
{
LOGPRINTF(2, "expect %d, table[%d] = %d\n",
signal / tUnit, i, table[i]);
return i;
}
}
LOGPRINTF(2, "Couldn't find %d\n", signal/tUnit);
return -1;
}
int livedrive_decode(struct ir_remote *remote, ir_code * prep, ir_code * codep, ir_code * postp, int *repeat_flagp,
lirc_t * min_remaining_gapp, lirc_t * max_remaining_gapp)
{
lirc_t gap;
if (!map_code(remote, prep, codep, postp, 16, pre, 16, code, 0, 0))
return (0);
gap = 0;
if (start.tv_sec - last.tv_sec >= 2)
*repeat_flagp = 0;
else {
gap = time_elapsed(&last, &start);
if (gap < 300000)
*repeat_flagp = 1;
else
*repeat_flagp = 0;
}
LOGPRINTF(1, "repeat_flag: %d", *repeat_flagp);
LOGPRINTF(1, "gap: %lu", (__u32) gap);
return (1);
}
void FreeBuff(char *buff1, char *buff2)
{
VAPI_ret_t ret;
if(s_mr_hndl != VAPI_INVAL_HNDL) {
LOGPRINTF("Deregistering send buffer\n");
ret = VAPI_deregister_mr(hca_hndl, s_mr_hndl);
if(ret != VAPI_OK) {
fprintf(stderr, "Error deregistering send mr: %s\n", VAPI_strerror(ret));
} else {
s_mr_hndl = VAPI_INVAL_HNDL;
}
}
if(r_mr_hndl != VAPI_INVAL_HNDL) {
LOGPRINTF("Deregistering recv buffer\n");
ret = VAPI_deregister_mr(hca_hndl, r_mr_hndl);
if(ret != VAPI_OK) {
fprintf(stderr, "Error deregistering recv mr: %s\n", VAPI_strerror(ret));
} else {
r_mr_hndl = VAPI_INVAL_HNDL;
}
}
if(buff1 != NULL)
free(buff1);
if(buff2 != NULL)
free(buff2);
}
int init_device()
{
char c;
int fd;
/* user overriding autoprobing */
if ( hw.device ) {
fd = open(hw.device,O_RDWR);
if ( fd < 0 ) {
LOGPRINTF(1, "Init: open of %s failed", hw.device);
return 0;
}
/* open ok, test device */
if ( is_my_device(fd,hw.device) ) {
return fd;
}
return 0;
}
for(c = 'a';c < 'z';c++) {
sprintf(dev_name,"/dev/sg%c",c);
fd = open(dev_name,O_RDWR);
if ( fd < 0 ) {
LOGPRINTF(1, "Probing: open of %s failed", dev_name);
continue;
}
/* open ok, test device */
if ( is_my_device(fd,dev_name) ) {
hw.device = dev_name;
return fd;
}
}
return 0;
}
struct ir_code_node *defineNode(struct ir_ncode *code, const char *val)
{
struct ir_code_node *node;
node=s_malloc(sizeof(*node));
if(node==NULL) return NULL;
node->code=s_strtocode(val);
node->next=NULL;
# ifdef LONG_IR_CODE
LOGPRINTF(3," 0x%016llX", node->code);
# else
LOGPRINTF(3," 0x%016lX", node->code);
# endif
if(code->current==NULL)
{
code->next=node;
code->current=node;
}
else
{
code->current->next=node;
code->current=node;
}
return node;
}
/* De_register the allocated memory regions before exiting */
void FreeBuff(char *buff1, char *buff2)
{
int ret;
if(s_mr_hndl) {
LOGPRINTF(("Deregistering send buffer"));
ret = ibv_dereg_mr(s_mr_hndl);
if(ret) {
fprintf(stderr, "Error deregistering send mr\n");
} else {
s_mr_hndl = NULL;
}
}
if(r_mr_hndl) {
LOGPRINTF(("Deregistering recv buffer"));
ret = ibv_dereg_mr(r_mr_hndl);
if(ret) {
fprintf(stderr, "Error deregistering recv mr\n");
} else {
r_mr_hndl = NULL;
}
}
if(buff1 != NULL)
free(buff1);
if(buff2 != NULL)
free(buff2);
}
int hiddev_decode(struct ir_remote *remote, ir_code * prep, ir_code * codep, ir_code * postp, int *repeat_flagp,
lirc_t * min_remaining_gapp, lirc_t * max_remaining_gapp)
{
LOGPRINTF(1, "hiddev_decode");
if (!map_code(remote, prep, codep, postp, pre_code_length, pre_code, main_code_length, main_code, 0, 0)) {
return (0);
}
LOGPRINTF(1, "lirc code: 0x%X", *codep);
map_gap(remote, &start, &last, 0, repeat_flagp, min_remaining_gapp, max_remaining_gapp);
/* override repeat */
switch (repeat_state) {
case RPT_NO:
*repeat_flagp = 0;
break;
case RPT_YES:
*repeat_flagp = 1;
break;
default:
break;
}
return 1;
}
int CCodecBase::EncodeBegin(utvf_t infmt, unsigned int width, unsigned int height, size_t cbGrossWidth)
{
LOGPRINTF("%p CCodecBase::EncodeBegin(infmt=%08X, width=%u, height=%u, cbGrossWidth=%" PRIdSZT ")", this, infmt, width, height, cbGrossWidth);
int ret = InternalEncodeBegin(infmt, width, height, cbGrossWidth);
LOGPRINTF("%p CCodecBase::EncodeBegin return %d", this, ret);
return ret;
}
int CCodecBase::EncodeQuery(utvf_t infmt, unsigned int width, unsigned int height)
{
LOGPRINTF("%p CCodecBase::EncodeQuery(infmt=%08X, width=%u, height=%u)", this, infmt, width, height);
int ret = InternalEncodeQuery(infmt, width, height);
LOGPRINTF("%p CCodecBase::EncodeQuery return %d", this, ret);
return ret;
}
void AfterAlignmentInit(ArgStruct *p)
{
int bytesRead;
/* Exchange buffer pointers and remote infiniband keys if doing rdma. Do
* the exchange in this function because this will happen after any
* memory alignment is done, which is important for getting the
* correct remote address.
*/
if( p->prot.commtype == NP_COMM_RDMAWRITE ||
p->prot.commtype == NP_COMM_RDMAWRITE_WITH_IMM ) {
/* Send my receive buffer address
*/
if(write(p->commfd, (void *)&p->r_buff, sizeof(void*)) < 0) {
perror("NetPIPE: write of buffer address failed in AfterAlignmentInit");
exit(-1);
}
LOGPRINTF("Sent buffer address: %p\n", p->r_buff);
/* Send my remote key for accessing
* my remote buffer via IB RDMA
*/
if(write(p->commfd, (void *)&r_mr_out.r_key, sizeof(VAPI_rkey_t)) < 0) {
perror("NetPIPE: write of remote key failed in AfterAlignmentInit");
exit(-1);
}
LOGPRINTF("Sent remote key: %d\n", r_mr_out.r_key);
/* Read the sent data
*/
bytesRead = readFully(p->commfd, (void *)&remote_address, sizeof(void*));
if (bytesRead < 0) {
perror("NetPIPE: read of buffer address failed in AfterAlignmentInit");
exit(-1);
} else if (bytesRead != sizeof(void*)) {
perror("NetPIPE: partial read of buffer address in AfterAlignmentInit");
exit(-1);
}
LOGPRINTF("Received remote address from other node: %p\n", remote_address);
bytesRead = readFully(p->commfd, (void *)&remote_key, sizeof(VAPI_rkey_t));
if (bytesRead < 0) {
perror("NetPIPE: read of remote key failed in AfterAlignmentInit");
exit(-1);
} else if (bytesRead != sizeof(VAPI_rkey_t)) {
perror("NetPIPE: partial read of remote key in AfterAlignmentInit");
exit(-1);
}
LOGPRINTF("Received remote key from other node: %d\n", remote_key);
}
}
int tira_init(void)
{
if (child_pid != -1) tira_deinit();
LOGPRINTF (1, "Tira init");
if(!tty_create_lock(hw.device))
{
logprintf(LOG_ERR,"could not create lock files");
return 0;
}
if ( (hw.fd = open (hw.device, O_RDWR | O_NONBLOCK | O_NOCTTY)) < 0)
{
tty_delete_lock ();
logprintf (LOG_ERR, "Could not open the '%s' device",
hw.device);
return 0;
}
LOGPRINTF(1, "device '%s' opened", hw.device);
/* We want 9600 8N1 with CTS/RTS handshaking, lets set that
* up. The specs state a baud rate of 100000, looking at the
* ftdi_sio driver it forces the issue so we can set to what
* we would like. And seeing as this is mapped to 9600 under
* windows should be a safe bet.
*/
/* Determine device type */
device_type=0;
if (check_tira()) device_type='t';else
if (check_ira()) device_type='i';
#ifdef DEBUG
const char *device_string;
switch(device_type)
{
case 't':
device_string = "Tira";
break;
case 'i':
device_string = "Ira";
break;
default:
device_string = "unknown";
}
LOGPRINTF(1, "device type %s", device_string);
#endif
if (device_type == 0)
{
tira_deinit();
return 0;
}
return 1;
}
int is_my_device(int fd,char *name)
{
sg_io_hdr_t io_hdr;
int k;
unsigned char inqCmdBlk [SCSI_INQ_CMD_LEN] =
{INQUIRY, 0, 0, 0, MAX_SCSI_REPLY_LEN, 0};
unsigned char Buff[MAX_SCSI_REPLY_LEN];
unsigned char sense_buffer[32];
/* Just to be safe, check we have a sg device wigh version > 3 */
if ((ioctl(fd, SG_GET_VERSION_NUM, &k) < 0) || (k < 30000)) {
LOGPRINTF(LOG_ERR, "%s isn't sg device version > 3",name);
return 0;
} else {
usleep(10);
LOGPRINTF(1,"%s is valid sg device - checking what it is",
name);
}
/* Prepare INQUIRY command */
memset(&io_hdr, 0, sizeof(sg_io_hdr_t));
io_hdr.interface_id = 'S';
io_hdr.cmd_len = sizeof(inqCmdBlk);
io_hdr.mx_sb_len = sizeof(sense_buffer);
io_hdr.dxfer_direction = SG_DXFER_FROM_DEV;
io_hdr.dxfer_len = MAX_SCSI_REPLY_LEN;
io_hdr.dxferp = Buff;
io_hdr.cmdp = inqCmdBlk;
io_hdr.sbp = sense_buffer;
io_hdr.timeout = 2000;
if (ioctl(fd, SG_IO, &io_hdr) < 0) {
LOGPRINTF(LOG_ERR, "INQUIRY SG_IO ioctl error");
return 0;
} else {
usleep(10);
}
if ( (io_hdr.info & SG_INFO_OK_MASK) != SG_INFO_OK) {
LOGPRINTF(LOG_ERR,
"INQUIRY: SCSI status=0x%x host_status=0x%x "
"driver_status=0x%x",io_hdr.status,
io_hdr.host_status,io_hdr.driver_status);
return 0;
}
/* check INQUIRY returned string */
if ( strncmp(Buff+8,"CREATIVE",8) > 0 ) {
LOGPRINTF(LOG_ERR, "%s is %s (vendor isn't Creative)",
name,Buff+8);
}
/* now run sense_mode_10 for page 0 to see if this is really it */
if ( test_device_command(fd) < 0 ) {
return 0;
}
return 1;
}
int parseFlags(char *val)
{
struct flaglist *flaglptr;
int flags=0;
char *flag,*help;
flag=help=val;
while(flag!=NULL)
{
while(*help!='|' && *help!=0) help++;
if(*help=='|')
{
*help=0;help++;
}
else
{
help=NULL;
}
flaglptr=all_flags;
while(flaglptr->name!=NULL){
if(strcasecmp(flaglptr->name,flag)==0){
if(flaglptr->flag&IR_PROTOCOL_MASK &&
flags&IR_PROTOCOL_MASK)
{
logprintf(LOG_ERR, "error in "
"configfile line %d:",
line);
logprintf(LOG_ERR, "multiple "
"protocols given in flags: "
"\"%s\"",flag);
parse_error=1;
return(0);
}
flags=flags|flaglptr->flag;
LOGPRINTF(3,"flag %s recognized",
flaglptr->name);
break;
}
flaglptr++;
}
if(flaglptr->name==NULL)
{
logprintf(LOG_ERR,"error in configfile line %d:",
line);
logprintf(LOG_ERR,"unknown flag: \"%s\"",flag);
parse_error=1;
return(0);
}
flag=help;
}
LOGPRINTF(2,"flags value: %d",flags);
return(flags);
}
struct ir_ncode *defineCode(char *key, char *val, struct ir_ncode *code)
{
code->name=s_strdup(key);
code->code=s_strtocode(val);
# ifdef LONG_IR_CODE
LOGPRINTF(3," %-20s 0x%016llX",code->name, code->code);
# else
LOGPRINTF(3," %-20s 0x%016lX",code->name, code->code);
# endif
return(code);
}
int bte_decode(struct ir_remote *remote, ir_code * prep, ir_code * codep, ir_code * postp, int *repeat_flagp,
lirc_t * min_remaining_gapp, lirc_t * max_remaining_gapp)
{
LOGPRINTF(3, "bte_decode called");
*prep = pre;
*codep = code;
*postp = 0;
LOGPRINTF(1, "bte_decode: %llx", (__u64) * codep);
return (1);
}
/* SendData == Post a 'send' request to the (send)command queue */
void SendData(ArgStruct *p)
{
int ret; /* Return code */
struct ibv_send_wr sr; /* Send request */
struct ibv_send_wr *bad_wr; /* Handle to any incomplete wr returned by ibv*/
struct ibv_sge sg_entry; /* Scatter/Gather list - holds buff addr */
/* Fill in send request struct */
/* Set the send request's opcode based on run-time options */
if(p->prot.commtype == NP_COMM_SENDRECV) {
sr.opcode = IBV_WR_SEND;
LOGPRINTF(("Doing regular send"));
} else if(p->prot.commtype == NP_COMM_SENDRECV_WITH_IMM) {
sr.opcode = IBV_WR_SEND_WITH_IMM;
LOGPRINTF(("Doing regular send with imm"));
} else if(p->prot.commtype == NP_COMM_RDMAWRITE) {
sr.opcode = IBV_WR_RDMA_WRITE; /* if RDMA, need to give more info */
sr.wr.rdma.remote_addr = (uintptr_t)(((char *)remote_address) + (p->s_ptr - p->s_buff));
sr.wr.rdma.rkey = remote_key;
LOGPRINTF(("Doing RDMA write (raddr=%p)", sr.wr.rdma.remote_addr));
} else if(p->prot.commtype == NP_COMM_RDMAWRITE_WITH_IMM) {
sr.opcode = IBV_WR_RDMA_WRITE_WITH_IMM; /* more info if RDMA */
sr.wr.rdma.remote_addr = (uintptr_t)(((char *)remote_address) + (p->s_ptr - p->s_buff));
sr.wr.rdma.rkey = remote_key;
LOGPRINTF(("Doing RDMA write with imm (raddr=%p)", sr.wr.rdma.remote_addr));
} else {
fprintf(stderr, "Error, invalid communication type in SendData\n");
exit(-1);
}
sr.send_flags = 0; /* This needed due to a bug in Mellanox HW rel a-0 */
sr.num_sge = 1; /* # entries in this request */
sr.sg_list = &sg_entry; /* the list of other requests */
sr.next = NULL; /* the next request in the list */
sg_entry.lkey = s_mr_hndl->lkey; /* Local memory region key */
sg_entry.length = p->bufflen; /* buffer's size */
sg_entry.addr = (uintptr_t)p->s_ptr; /* buffer's location */
/* Post the send request to the (send)command queue */
/* ibv_post_send(...) is handled in same fashion ibv_post_recv(..) */
ret = ibv_post_send(qp_hndl, &sr, &bad_wr);
if(ret) {
fprintf(stderr, "Error posting send request\n");
} else {
LOGPRINTF(("Posted send request"));
}
}
char *mp3anywhere_rec(struct ir_remote *remotes)
{
char *m;
int i=0;
b[0]=0x00;
b[1]=0xd5;
b[2]=0xaa;
b[3]=0xee;
b[5]=0xad;
last=end;
gettimeofday(&start,NULL);
while(b[i] != 0xAD)
{
i++;
if(i>=NUMBYTES)
{
LOGPRINTF(0,"buffer overflow at byte %d",i);
break;
}
if(i>0)
{
if(!waitfordata(TIMEOUT))
{
LOGPRINTF(0,"timeout reading byte %d",i);
return(NULL);
}
}
if(read(hw.fd,&b[i],1)!=1)
{
logprintf(LOG_ERR,"reading of byte %d failed",i);
logperror(LOG_ERR,NULL);
return(NULL);
}
if(b[1]!= 0xd5 ||
b[2]!= 0xaa ||
b[3]!= 0xee ||
b[5]!= 0xad )
{
logprintf(LOG_ERR,"bad envelope");
return(NULL);
}
LOGPRINTF(1,"byte %d: %02x",i,b[i]);
}
gettimeofday(&end,NULL);
pre=0xD5AAEE;
code=(ir_code) b[4];
m=decode_all(remotes);
return(m);
}
char *logitech_rec(struct ir_remote *remotes)
{
char *m;
int i=0;
int repeat, mouse_event;
b[i]=0x00;
last=end;
gettimeofday(&start,NULL);
while(b[i] != 0xAA)
{
i++;
if(i>=NUMBYTES)
{
LOGPRINTF(0,"buffer overflow at byte %d",i);
break;
}
if(i>0)
{
if(!waitfordata(TIMEOUT))
{
LOGPRINTF(0,"timeout reading byte %d",i);
return(NULL);
}
}
if(read(hw.fd,&b[i],1)!=1)
{
logprintf(LOG_ERR,"reading of byte %d failed",i);
logperror(LOG_ERR,NULL);
return(NULL);
}
LOGPRINTF(1,"byte %d: %02x",i,b[i]);
if(b[i] >= 0x40 && b[i] <= 0x6F)
{
mouse_event=b[i];
b[1]=0xA0;
b[2]=mouse_event;
LOGPRINTF(1,"mouse event: %02x",mouse_event);
break;
}
}
gettimeofday(&end,NULL);
if(b[1] == 0xA0) repeat=0;
else repeat=1;
if(!repeat) pre=(ir_code) b[1];
else pre=0xA0;
code=(ir_code) b[2];
m=decode_all(remotes);
return(m);
}
/* initialize driver -- returns 1 on success, 0 on error */
static int dfc_init()
{
struct usb_device *usb_dev;
int pipe_fd[2] = { -1, -1 };
LOGPRINTF(1, "initializing USB receiver");
init_rec_buffer();
usb_dev = find_usb_device();
if (usb_dev == NULL) {
logprintf(LOG_ERR, "couldn't find a compatible USB device");
return 0;
}
/* A separate process will be forked to read data from the USB
* receiver and write it to a pipe. hw.fd is set to the readable
* end of this pipe. */
if (pipe(pipe_fd) != 0) {
logperror(LOG_ERR, "couldn't open pipe");
return 0;
}
hw.fd = pipe_fd[0];
dev_handle = usb_open(usb_dev);
if (dev_handle == NULL) {
logperror(LOG_ERR, "couldn't open USB receiver");
goto fail;
}
child = fork();
if (child == -1) {
logperror(LOG_ERR, "couldn't fork child process");
goto fail;
} else if (child == 0) {
usb_read_loop(pipe_fd[1]);
}
LOGPRINTF(1, "USB receiver initialized");
return 1;
fail:
if (dev_handle) {
usb_close(dev_handle);
dev_handle = NULL;
}
if (pipe_fd[0] >= 0)
close(pipe_fd[0]);
if (pipe_fd[1] >= 0)
close(pipe_fd[1]);
return 0;
}
BOOL APIENTRY DllMain(HMODULE hModule, DWORD dwReason, LPVOID lpReserved)
{
if (dwReason == DLL_PROCESS_ATTACH)
{
LOGPRINTF("DllMain(hModule=%p, dwReason=DLL_PROCESS_ATTACH, lpReserved=%p)", hModule, lpReserved);
}
else if (dwReason == DLL_PROCESS_DETACH)
{
LOGPRINTF("DllMain(hModule=%p, dwReason=DLL_PROCESS_DETACH, lpReserved=%p)", hModule, lpReserved);
}
return TRUE;
}
static int uirt2_raw_decode(struct ir_remote *remote, ir_code * prep, ir_code * codep, ir_code * postp,
int *repeat_flagp, lirc_t * min_remaining_gapp, lirc_t * max_remaining_gapp)
{
int res;
LOGPRINTF(1, "uirt2_raw_decode: enter");
res = receive_decode(remote, prep, codep, postp, repeat_flagp, min_remaining_gapp, max_remaining_gapp);
LOGPRINTF(1, "uirt2_raw_decode: %d", res);
return res;
}
int CCodecBase::InternalSetStateWrapper(const void *pState, size_t cb)
{
if (IsLogWriterInitializedOrDebugBuild())
{
char buf[256];
FormatBinary(buf, pState, cb, GetStateSize());
LOGPRINTF("%p CCodecBase::InternalSetStateWrapper(pState=%s, cb=%" PRIuSZT ")", this, buf, cb);
}
int ret = InternalSetState(pState, cb);
LOGPRINTF("%p CCodecBase::InternalSetStateWrapper return %d", this, ret);
return ret;
}
int CCodecBase::DecodeQuery(utvf_t outfmt, unsigned int width, unsigned int height, const void *pExtraData, size_t cbExtraData)
{
if (IsLogWriterInitializedOrDebugBuild())
{
char buf[256];
FormatBinary(buf, pExtraData, cbExtraData, EncodeGetExtraDataSize());
LOGPRINTF("%p CCodecBase::DecodeQuery(outfmt=%08X, width=%u, height=%u, pExtraData=%s, cbExtraData=%" PRIuSZT ")", this, outfmt, width, height, buf, cbExtraData);
}
int ret = InternalDecodeQuery(outfmt, width, height, pExtraData, cbExtraData);
LOGPRINTF("%p CCodecBase::DecodeQuery return %d", this, ret);
return ret;
}
