libisofs-legacy/cdrskin/cdrfifo.c

1037 lines
30 KiB
C

/*
cdrfifo.c , Copyright 2006 Thomas Schmitt <scdbackup@gmx.net>
A fd-to-fd or fd-to-memory fifo to be used within cdrskin or independently.
By chaining of fifo objects, several fifos can be run simultaneously
in fd-to-fd mode. Modes are controlled by parameter flag of
Cdrfifo_try_to_work().
Provided under GPL license within cdrskin and under BSD license elsewise.
*/
/*
Compile as standalone tool :
cc -g -o cdrfifo -DCdrfifo_standalonE cdrfifo.c
*/
#include <stdio.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <string.h>
#include <stdlib.h>
#include <errno.h>
#include <sys/time.h>
#include <sys/select.h>
#include "cdrfifo.h"
/* Macro for creation of arrays of objects (or single objects) */
#define TSOB_FELD(typ,anz) (typ *) malloc((anz)*sizeof(typ));
#define Cdrfifo_buffer_chunK 2048
/** Number of follow-up fd pairs */
#define Cdrfifo_ffd_maX 100
/* 1= enable , 0= disable status messages to stderr */
static int Cdrfifo_debuG= 0;
struct CdrfifO {
int chunk_size;
int source_fd;
double in_counter;
char *buffer;
int buffer_size;
int buffer_is_full;
int write_idx;
int read_idx;
int dest_fd;
double out_counter;
struct timeval start_time;
double speed_limit;
/* statistics */
double interval_counter;
struct timeval interval_start_time;
double interval_start_counter;
int total_min_fill;
int interval_min_fill;
double put_counter;
double get_counter;
double empty_counter;
double full_counter;
/* (sequential) fd chaining */
int follow_up_fds[Cdrfifo_ffd_maX][2];
/* index of first byte in buffer which does not belong to predecessor fd */
int follow_up_eop[Cdrfifo_ffd_maX];
/* index of first byte in buffer which belongs to [this] fd pair */
int follow_up_sod[Cdrfifo_ffd_maX];
/* number of defined follow-ups */
int follow_up_fd_counter;
/* index of currently active (i.e. reading) follow-up */
int follow_up_fd_idx;
/* (simultaneous) peer chaining */
struct CdrfifO *next;
struct CdrfifO *prev;
};
/** Create a fifo object.
@param ff Returns the address of the new object.
@param source_fd Filedescriptor opened to a readable data stream.
@param dest_fd Filedescriptor opened to a writable data stream.
To work with libburn, it needs to be attached to a
struct burn_source object.
@param chunk_size Size of buffer block for a single transaction (0=default)
@param buffer_size Size of fifo buffer
@param flag Unused yet
@return 1 on success, <=0 on failure
*/
int Cdrfifo_new(struct CdrfifO **ff, int source_fd, int dest_fd,
int chunk_size, int buffer_size, int flag)
{
struct CdrfifO *o;
struct timezone tz;
int i;
(*ff)= o= TSOB_FELD(struct CdrfifO,1);
if(o==NULL)
return(-1);
if(chunk_size<=0)
chunk_size= Cdrfifo_buffer_chunK;
o->chunk_size= chunk_size;
if(buffer_size%chunk_size)
buffer_size+= chunk_size-(buffer_size%chunk_size);
o->source_fd= source_fd;
o->in_counter= 0.0;
o->buffer= NULL;
o->buffer_is_full= 0;
o->buffer_size= buffer_size;
o->write_idx= 0;
o->read_idx= 0;
o->dest_fd= dest_fd;
o->out_counter= 0.0;
memset(&(o->start_time),0,sizeof(o->start_time));
gettimeofday(&(o->start_time),&tz);
o->speed_limit= 0.0;
o->interval_counter= 0.0;
memset(&(o->interval_start_time),0,sizeof(o->interval_start_time));
gettimeofday(&(o->interval_start_time),&tz);
o->interval_start_counter= 0.0;
o->total_min_fill= buffer_size;
o->interval_min_fill= buffer_size;
o->put_counter= 0.0;
o->get_counter= 0.0;
o->empty_counter= 0.0;
o->full_counter= 0.0;
for(i= 0; i<Cdrfifo_ffd_maX; i++) {
o->follow_up_fds[i][0]= o->follow_up_fds[i][1]= -1;
o->follow_up_eop[i]= o->follow_up_sod[i]= -1;
}
o->follow_up_fd_counter= 0;
o->follow_up_fd_idx= -1;
o->next= o->prev= NULL;
o->buffer= TSOB_FELD(char,buffer_size);
if(o->buffer==NULL)
goto failed;
return(1);
failed:;
Cdrfifo_destroy(ff,0);
return(-1);
}
/** Close any output fds */
int Cdrfifo_close(struct CdrfifO *o, int flag)
{
int i;
if(o->dest_fd!=-1)
close(o->dest_fd);
o->dest_fd= -1;
for(i=0; i<o->follow_up_fd_counter; i++)
if(o->follow_up_fds[i][1]!=-1)
close(o->follow_up_fds[i][1]);
o->follow_up_fds[i][1]= -1;
return(1);
}
/** Release from memory a fifo object previously created by Cdrfifo_new().
@param ff The victim (gets returned as NULL, call can stand *ff==NULL))
@param flag Bitfield for control purposes:
bit0= do not close destination fd
*/
int Cdrfifo_destroy(struct CdrfifO **ff, int flag)
/* flag
bit0= do not close destination fd
*/
{
struct CdrfifO *o;
o= *ff;
if(o==NULL)
return(0);
if(o->next!=NULL)
o->next->prev= o->prev;
if(o->prev!=NULL)
o->prev->next= o->next;
if(!(flag&1))
Cdrfifo_close(o,0);
/* eventual closing of source fds is the job of the calling application */
if(o->buffer!=NULL)
free((char *) o->buffer);
free((char *) o);
(*ff)= NULL;
return(1);
}
int Cdrfifo_get_sizes(struct CdrfifO *o, int *chunk_size, int *buffer_size,
int flag)
{
*chunk_size= o->chunk_size;
*buffer_size= o->buffer_size;
return(1);
}
/** Set a speed limit for buffer output.
@param o The fifo object
@param bytes_per_second >0 catch up slowdowns over the whole run time
<0 catch up slowdowns only over one interval
=0 disable speed limit
*/
int Cdrfifo_set_speed_limit(struct CdrfifO *o, double bytes_per_second,
int flag)
{
o->speed_limit= bytes_per_second;
return(1);
}
int Cdrfifo_set_fds(struct CdrfifO *o, int source_fd, int dest_fd, int flag)
{
o->source_fd= source_fd;
o->dest_fd= dest_fd;
return(1);
}
int Cdrfifo_get_fds(struct CdrfifO *o, int *source_fd, int *dest_fd, int flag)
{
*source_fd= o->source_fd;
*dest_fd= o->dest_fd;
return(1);
}
/** Attach a further pair of input and output fd which will use the same
fifo buffer when its predecessors are exhausted. Reading will start as
soon as reading of the predecessor encounters EOF. Writing will start
as soon as all pending predecessor data are written.
*/
int Cdrfifo_attach_follow_up_fds(struct CdrfifO *o, int source_fd, int dest_fd,
int flag)
{
if(o->follow_up_fd_counter>=Cdrfifo_ffd_maX)
return(0);
o->follow_up_fds[o->follow_up_fd_counter][0]= source_fd;
o->follow_up_fds[o->follow_up_fd_counter][1]= dest_fd;
o->follow_up_fd_counter++;
return(1);
}
/** Attach a further fifo which shall be processed simultaneously with this
one by Cdrfifo_try_to_work() in fd-to-fd mode.
*/
int Cdrfifo_attach_peer(struct CdrfifO *o, struct CdrfifO *next, int flag)
{
for(;o->next!=NULL;o= o->next); /* determine end of o-chain */
for(;next->prev!=NULL;next= next->prev); /* determine start of next-chain */
next->prev= o;
o->next= next;
return(1);
}
static int Cdrfifo_tell_buffer_space(struct CdrfifO *o, int flag)
{
if(o->buffer_is_full)
return(0);
if(o->write_idx>=o->read_idx)
return((o->buffer_size - o->write_idx) + o->read_idx);
return(o->read_idx - o->write_idx);
}
/** Obtain buffer state.
@param o The buffer object
@param fill Returns the number of pending payload bytes in the buffer
@param space Returns the number of unused buffer bytes
@param flag Unused yet
@return -1=error , 0=inactive , 1=reading and writing ,
2=reading ended (but still writing)
*/
int Cdrfifo_get_buffer_state(struct CdrfifO *o,int *fill,int *space,int flag)
/* return :
-1=error
0=inactive
1=reading and writing
2=reading ended, still writing
*/
{
*space= Cdrfifo_tell_buffer_space(o,0);
*fill= o->buffer_size-(*space);
if(o->dest_fd==-1)
return(0);
if(o->source_fd<0)
return(2);
return(1);
}
int Cdrfifo_get_counters(struct CdrfifO *o,
double *in_counter, double *out_counter, int flag)
{
*in_counter= o->in_counter;
*out_counter= o->out_counter;
return(1);
}
/** reads min_fill and begins measurement interval for next min_fill */
int Cdrfifo_next_interval(struct CdrfifO *o, int *min_fill, int flag)
{
struct timezone tz;
o->interval_counter++;
gettimeofday(&(o->interval_start_time),&tz);
o->interval_start_counter= o->out_counter;
*min_fill= o->interval_min_fill;
o->interval_min_fill= o->buffer_size - Cdrfifo_tell_buffer_space(o,0);
return(1);
}
int Cdrfifo_get_min_fill(struct CdrfifO *o, int *total_min_fill,
int *interval_min_fill, int flag)
{
*total_min_fill= o->total_min_fill;
*interval_min_fill= o->interval_min_fill;
return(1);
}
/** Get counters which are mentioned by cdrecord at the end of burning.
It still has to be examined wether they mean what i believe they do.
*/
int Cdrfifo_get_cdr_counters(struct CdrfifO *o,
double *put_counter, double *get_counter,
double *empty_counter, double *full_counter,
int flag)
{
*put_counter= o->put_counter;;
*get_counter= o->get_counter;
*empty_counter= o->empty_counter;
*full_counter= o->full_counter;
return(1);
}
/** Adjust a given buffer fill value so it will not cross an eop boundary.
@param o The fifo to exploit.
@param buffer_fill The byte count to adjust.
@param eop_idx If eop boundary exactly hit: index of follow-up fd pair
@param flag Unused yet.
@return 0= nothing changed , 1= buffer_fill adjusted
*/
int Cdrfifo_eop_adjust(struct CdrfifO *o,int *buffer_fill, int *eop_idx,
int flag)
{
int i,eop_is_near= 0,valid_fill;
*eop_idx= -1;
valid_fill= *buffer_fill;
for(i=0; i<=o->follow_up_fd_idx; i++) {
if(o->follow_up_eop[i]>=0 && o->follow_up_eop[i]>=o->read_idx) {
eop_is_near= 1;
valid_fill= o->follow_up_eop[i]-o->read_idx;
if(valid_fill==0)
*eop_idx= i;
else if(valid_fill<=o->chunk_size)
eop_is_near= 2; /* for debugging. to carry a break point */
break;
}
}
if(*buffer_fill>valid_fill)
*buffer_fill= valid_fill;
return(!!eop_is_near);
}
/* Perform pre-select activities of Cdrfifo_try_to_work() */
static int Cdrfifo_setup_try(struct CdrfifO *o, struct timeval start_tv,
double start_out_counter, int *still_to_wait,
int *speed_limiter, int *ready_to_write,
fd_set *rds, fd_set *wts, int *max_fd, int flag)
/* flag:
bit0= enable debug pacifier (same with Cdrfifo_debuG)
bit1= do not write, just fill buffer
bit2= fd-to-memory mode (else fd-to-fd mode):
rather than writing a chunk return it and its size in reply_*
bit3= with bit2: do not check destination fd for readiness
*/
{
int buffer_space,buffer_fill,eop_reached= -1,eop_is_near= 0,was_closed;
int fd_buffer_fill;
struct timeval current_tv;
struct timezone tz;
double diff_time,diff_counter,limit,min_wait_time;
setup_try:;
buffer_space= Cdrfifo_tell_buffer_space(o,0);
fd_buffer_fill= buffer_fill= o->buffer_size - buffer_space;
#ifdef NIX
fprintf(stderr,"cdrfifo_debug: o->write_idx=%d o->read_idx=%d o->source_fd=%d\n",o->write_idx,o->read_idx,o->source_fd);
if(buffer_fill>10)
sleep(1);
#endif
if(o->follow_up_fd_idx>=0)
eop_is_near= Cdrfifo_eop_adjust(o,&fd_buffer_fill,&eop_reached,0);
if(fd_buffer_fill<=0 && (o->source_fd==-1 || eop_reached>=0) ) {
was_closed= 0;
if(o->dest_fd!=-1 && !(flag&4))
close(o->dest_fd);
if(o->dest_fd<0)
was_closed= 1;
else
o->dest_fd= -1;
if(eop_reached>=0) { /* switch to next output fd */
o->dest_fd= o->follow_up_fds[eop_reached][1];
o->read_idx= o->follow_up_sod[eop_reached];
o->follow_up_eop[eop_reached]= -1;
eop_is_near= 0;
eop_reached= -1;
goto setup_try;
} else {
/* work is really done */
if((!was_closed) && ((flag&1)||Cdrfifo_debuG))
fprintf(stderr,
"\ncdrfifo_debug: w=%d r=%d | b=%d s=%d | i=%.f o=%.f (done)\n",
o->write_idx,o->read_idx,buffer_fill,buffer_space,
o->in_counter,o->out_counter);
return(2);
}
}
if(o->interval_counter>0) {
if(o->total_min_fill>buffer_fill && o->source_fd>=0)
o->total_min_fill= buffer_fill;
if(o->interval_min_fill>buffer_fill)
o->interval_min_fill= buffer_fill;
}
*speed_limiter= 0;
if(o->speed_limit!=0) {
gettimeofday(&current_tv,&tz);
if(o->speed_limit>0) {
diff_time= ((double) current_tv.tv_sec)-((double) o->start_time.tv_sec)+
(((double) current_tv.tv_usec)-((double) o->start_time.tv_usec))*1e-6;
diff_counter= o->out_counter;
limit= o->speed_limit;
} else if(flag&4) {
if(o->interval_start_time.tv_sec==0)
o->interval_start_time= start_tv;
diff_time= ((double) current_tv.tv_sec)
- ((double) o->interval_start_time.tv_sec)
+ (((double) current_tv.tv_usec)
-((double) o->interval_start_time.tv_usec))*1e-6;
diff_counter= o->out_counter - o->interval_start_counter;
limit= -o->speed_limit;
} else {
diff_time= ((double) current_tv.tv_sec) - ((double) start_tv.tv_sec)
+ (((double) current_tv.tv_usec)
-((double)start_tv.tv_usec))*1e-6;
diff_counter= o->out_counter - start_out_counter;
limit= -o->speed_limit;
}
if(diff_time>0.0)
if(diff_counter/diff_time>limit) {
min_wait_time= (diff_counter/limit - diff_time)*1.0e6;
if(min_wait_time<*still_to_wait)
*still_to_wait= min_wait_time;
if(*still_to_wait>0)
*speed_limiter= 1;
}
}
if(o->source_fd>=0) {
if(buffer_space>0) {
FD_SET((o->source_fd),rds);
if(*max_fd<o->source_fd)
*max_fd= o->source_fd;
} else if(o->interval_counter>0)
o->full_counter++;
}
*ready_to_write= 0;
if(o->dest_fd>=0 && (!(flag&2)) && !*speed_limiter) {
if(fd_buffer_fill>=o->chunk_size || o->source_fd<0 || eop_is_near) {
if((flag&(4|8))==(4|8)) {
*still_to_wait= 0;
*ready_to_write= 1;
} else {
FD_SET((o->dest_fd),wts);
if(*max_fd<o->dest_fd)
*max_fd= o->dest_fd;
}
} else if(o->interval_counter>0)
o->empty_counter++;
}
return(1);
}
/* Perform post-select activities of Cdrfifo_try_to_work() */
static int Cdrfifo_transact(struct CdrfifO *o, fd_set *rds, fd_set *wts,
char *reply_buffer, int *reply_count, int flag)
/* flag:
bit0= enable debug pacifier (same with Cdrfifo_debuG)
bit1= do not write, just fill buffer
bit2= fd-to-memory mode (else fd-to-fd mode):
rather than writing a chunk return it and its size in reply_*
bit3= with bit2: do not check destination fd for readiness
return: <0 = error , 0 = idle , 1 = did some work
*/
{
double buffer_space;
int can_read,can_write,ret,did_work= 0,idx,sod,eop_is_near,eop_idx;
buffer_space= Cdrfifo_tell_buffer_space(o,0);
if(o->dest_fd>=0) if(FD_ISSET((o->dest_fd),wts)) {
can_write= o->buffer_size - buffer_space;
if(can_write>o->chunk_size)
can_write= o->chunk_size;
if(o->read_idx+can_write > o->buffer_size)
can_write= o->buffer_size - o->read_idx;
if(o->follow_up_fd_idx>=0) {
eop_is_near= Cdrfifo_eop_adjust(o,&can_write,&eop_idx,0);
if(can_write<=0)
goto after_write;
}
if(flag&4) {
memcpy(reply_buffer,o->buffer+o->read_idx,can_write);
*reply_count= ret= can_write;
} else {
ret= write(o->dest_fd,o->buffer+o->read_idx,can_write);
}
if(ret==-1) {
/* >>> handle broken pipe */;
fprintf(stderr,"\ncdrfifo: on write: errno=%d , \"%s\"\n",errno,
errno==0?"-no error code available-":strerror(errno));
if(!(flag&4))
close(o->dest_fd);
o->dest_fd= -1;
{ret= -1; goto ex;}
}
did_work= 1;
o->get_counter++;
o->out_counter+= can_write;
o->read_idx+= can_write;
if(o->read_idx>=o->buffer_size)
o->read_idx= 0;
o->buffer_is_full= 0;
}
after_write:;
if(o->source_fd>=0) if(FD_ISSET((o->source_fd),rds)) {
can_read= o->buffer_size - o->write_idx;
if(can_read>o->chunk_size)
can_read= o->chunk_size;
if(o->write_idx<o->read_idx && o->write_idx+can_read > o->read_idx)
can_read= o->read_idx - o->write_idx;
ret= read(o->source_fd,o->buffer+o->write_idx,can_read);
if(ret==-1) {
/* >>> handle input error */;
fprintf(stderr,"\ncdrfifo: on read: errno=%d , \"%s\"\n",errno,
errno==0?"-no error code available-":strerror(errno));
o->source_fd= -1;
} else if(ret==0) { /* eof */
/* activate eventual follow-up source fd */
if(Cdrfifo_debuG || (flag&1))
fprintf(stderr,"\ncdrfifo: on read(%d,buffer,%d): eof\n",
o->source_fd,can_read);
if(o->follow_up_fd_idx+1 < o->follow_up_fd_counter) {
idx= ++(o->follow_up_fd_idx);
o->source_fd= o->follow_up_fds[idx][0];
/* End-Of-Previous */
if(o->write_idx==0)
o->follow_up_eop[idx]= o->buffer_size;
else
o->follow_up_eop[idx]= o->write_idx;
/* Start-Of-Data . Try to start at next full chunk */
sod= o->write_idx;
if(o->write_idx%o->chunk_size)
sod+= o->chunk_size - (o->write_idx%o->chunk_size);
/* but do not catch up to the read pointer */
if((o->write_idx<=o->read_idx && o->read_idx<=sod) || sod==o->read_idx)
sod= o->write_idx;
if(sod>=o->buffer_size)
sod= 0;
o->follow_up_sod[idx]= sod;
o->write_idx= sod;
if(Cdrfifo_debuG || (flag&1))
fprintf(stderr,"\ncdrfio: new fifo source fd : %d\n",o->source_fd);
} else {
o->source_fd= -1;
}
} else {
did_work= 1;
o->put_counter++;
o->in_counter+= ret;
o->write_idx+= ret;
if(o->write_idx>=o->buffer_size)
o->write_idx= 0;
if(o->write_idx==o->read_idx)
o->buffer_is_full= 1;
}
}
ret= !!did_work;
ex:;
return(ret);
}
/** Check for pending data at the fifo's source file descriptor and wether the
fifo is ready to take them. Simultaneously check the buffer for existing
data and the destination fd for readiness to accept some. If so, a small
chunk of data is transfered to and/or from the fifo.
This is done for the given fifo object and all members of its next-chain.
The check and transactions are repeated until a given timespan has elapsed.
libburn applications call this function in the burn loop instead of sleep().
It may also be used instead of read(). Then it returns as soon as an output
transaction would be performed. See flag:bit2.
@param o The fifo object
@param wait_usec The time in microseconds after which the function shall
return.
@param reply_buffer with bit2: Returns write-ready buffer chunk and must
be able to take at least chunk_size bytes
@param reply_count with bit2: Returns number of writeable bytes in reply
@param flag Bitfield for control purposes:
bit0= Enable debug pacifier (same with Cdrfifo_debuG)
bit1= Do not write, just fill buffer
bit2= fd-to-memory mode (else fd-to-fd mode):
Rather than writing a chunk return it and its size.
No simultaneous processing of chained fifos.
bit3= With bit2: do not check destination fd for readiness
@return <0 = error , 0 = idle , 1 = did some work , 2 = all work is done
*/
int Cdrfifo_try_to_work(struct CdrfifO *o, int wait_usec,
char *reply_buffer, int *reply_count, int flag)
{
struct timeval wt,start_tv,current_tv;
struct timezone tz;
fd_set rds,wts,exs;
int ready,ret,max_fd= -1,buffer_space,dummy,still_active= 0;
int did_work= 0,elapsed,still_to_wait,speed_limiter= 0,ready_to_write= 0;
double start_out_counter;
struct CdrfifO *ff;
start_out_counter= o->out_counter;
gettimeofday(&start_tv,&tz);
still_to_wait= wait_usec;
if(flag&4)
*reply_count= 0;
try_again:;
/* is there still a destination open ? */
for(ff= o; ff!=NULL; ff= ff->next)
if(ff->dest_fd!=-1)
break;
if(ff==NULL)
return(2);
FD_ZERO(&rds);
FD_ZERO(&wts);
FD_ZERO(&exs);
for(ff= o; ff!=NULL; ff= ff->next) {
ret= Cdrfifo_setup_try(ff,start_tv,start_out_counter,
&still_to_wait,&speed_limiter,&ready_to_write,
&rds,&wts,&max_fd,flag&15);
if(ret<=0)
return(ret);
else if(ret==2) {
/* This fifo is done */;
} else
still_active= 1;
if(flag&2)
break;
}
if(!still_active)
return(2);
if(still_to_wait>0 || max_fd>=0) {
wt.tv_sec= still_to_wait/1000000;
wt.tv_usec= still_to_wait%1000000;
ready= select(max_fd+1,&rds,&wts,&exs,&wt);
} else
ready= 0;
if(ready<=0) {
if(!ready_to_write)
goto check_wether_done;
FD_ZERO(&rds);
}
if(ready_to_write)
FD_SET((o->dest_fd),&wts);
for(ff= o; ff!=NULL; ff= ff->next) {
ret= Cdrfifo_transact(ff,&rds,&wts,reply_buffer,reply_count,flag&15);
if(ret<0)
goto ex;
if(ret>0)
did_work= 1;
if(flag&2)
break;
}
check_wether_done:;
if((flag&4) && *reply_count>0)
{ret= 1; goto ex;}
gettimeofday(&current_tv,&tz);
elapsed= (current_tv.tv_sec-start_tv.tv_sec)*1000000 +
(((int) current_tv.tv_usec) - ((int) start_tv.tv_usec));
still_to_wait= wait_usec-elapsed;
if(still_to_wait>0)
goto try_again;
ret= !!did_work;
ex:;
if(flag&4) {
gettimeofday(&current_tv,&tz);
elapsed= (current_tv.tv_sec - o->interval_start_time.tv_sec)*1000000
+ (((int) current_tv.tv_usec)
- ((int) o->interval_start_time.tv_usec));
} else
elapsed= wait_usec;
if(elapsed>=wait_usec) {
if((flag&1)||Cdrfifo_debuG) {
fprintf(stderr,"\n");
for(ff= o; ff!=NULL; ff= ff->next) {
buffer_space= Cdrfifo_tell_buffer_space(ff,0);
fprintf(stderr,
"cdrfifo_debug: w=%d r=%d | b=%d s=%d | i=%.f o=%.f\n",
ff->write_idx,ff->read_idx,
ff->buffer_size-buffer_space,buffer_space,
ff->in_counter,ff->out_counter);
}
}
if(flag&4)
Cdrfifo_next_interval(o,&dummy,0);
}
return(ret);
}
/** Fill the fifo as far as possible without writing to destination fd */
int Cdrfifo_fill(struct CdrfifO *o, int flag)
{
int ret,fill= 0,space,state;
while(1) {
state= Cdrfifo_get_buffer_state(o,&fill,&space,0);
if(state==-1) {
/* >>> handle error */;
return(0);
} else if(state!=1)
break;
if(space<=0)
break;
ret= Cdrfifo_try_to_work(o,100000,NULL,NULL,2);
if(ret<0) {
/* >>> handle error */;
return(0);
}
if(ret==2)
break;
}
o->total_min_fill= fill;
o->interval_min_fill= fill;
return(1);
}
int Cdrfifo_close_all(struct CdrfifO *o, int flag)
{
struct CdrfifO *ff;
if(o==NULL)
return(0);
for(ff= o; ff->prev!=NULL; ff= ff->prev);
for(; ff!=NULL; ff= ff->next)
Cdrfifo_close(ff,0);
return(1);
}
#ifdef Cdrfifo_standalonE
/* ---------------------------------------------------------------------- */
/** Application example. See also cdrskin.c */
double Scanf_io_size(char *text, int flag)
/*
bit0= default value -1 rather than 0
*/
{
int c;
double ret= 0.0;
if(flag&1)
ret= -1.0;
if(text[0]==0)
return(ret);
sscanf(text,"%lf",&ret);
c= text[strlen(text)-1];
if(c=='k' || c=='K') ret*= 1024.0;
if(c=='m' || c=='M') ret*= 1024.0*1024.0;
if(c=='g' || c=='G') ret*= 1024.0*1024.0*1024.0;
if(c=='t' || c=='T') ret*= 1024.0*1024.0*1024.0*1024.0;
if(c=='p' || c=='P') ret*= 1024.0*1024.0*1024.0*1024.0*1024.0;
if(c=='e' || c=='E') ret*= 1024.0*1024.0*1024.0*1024.0*1024.0*1024.0;
if(c=='s' || c=='S') ret*= 2048.0;
return(ret);
}
/* This is a hardcoded test mock-up for two simultaneous fifos of which the
first one simulates the cdrskin fifo feeding libburn and the second one
simulates libburn and the burner at given speed. Both have two fd pairs
(i.e. tracks). The tracks are read from /u/test/cdrskin/in_[12] and
written to /u/test/cdrskin/out_[12].
*/
int Test_multi(int fs_size, double speed_limit, double interval, int flag)
/*
bit0= debugging verbousity
*/
{
int fd_in[4],fd_out[4],ret,pipe_fds[4][2],real_out[4],pipe_idx;
int i,iv;
char buf[10240];
struct CdrfifO *ff1= NULL,*ff2= NULL;
/* open four pairs of fds */
fd_in[0]= open("/u/test/cdrskin/in_1",O_RDONLY);
fd_in[1]= open("/u/test/cdrskin/in_2",O_RDONLY);
fd_out[2]= open("/u/test/cdrskin/out_1",
O_WRONLY|O_CREAT|O_TRUNC, S_IRUSR|S_IWUSR);
fd_out[3]= open("/u/test/cdrskin/out_2",
O_WRONLY|O_CREAT|O_TRUNC, S_IRUSR|S_IWUSR);
if(pipe(pipe_fds[0])==-1)
return(-3);
if(pipe(pipe_fds[1])==-1)
return(-3);
fd_out[0]= pipe_fds[0][1];
fd_out[1]= pipe_fds[1][1];
fd_in[2]= pipe_fds[0][0];
fd_in[3]= pipe_fds[1][0];
for(i=0;i<4;i++) {
if(fd_in[i]==-1)
return(-1);
if(fd_out[i]==-1)
return(-2);
}
/* Create two fifos with two sequential fd pairs each and chain them for
simultaneous usage. */
Cdrfifo_new(&ff1,fd_in[0],fd_out[0],2048,fs_size,0);
Cdrfifo_new(&ff2,fd_in[2],fd_out[2],2048,2*1024*1024,0); /*burner cache 2 MB*/
if(ff1==NULL || ff2==NULL)
return(-3);
Cdrfifo_set_speed_limit(ff2,speed_limit,0);
ret= Cdrfifo_attach_follow_up_fds(ff1,fd_in[1],fd_out[1],0);
if(ret<=0)
return(-4);
ret= Cdrfifo_attach_follow_up_fds(ff2,fd_in[3],fd_out[3],0);
if(ret<=0)
return(-4);
Cdrfifo_attach_peer(ff1,ff2,0);
/* Let the fifos work */
iv= interval*1e6;
while(1) {
ret= Cdrfifo_try_to_work(ff1,iv,NULL,NULL,flag&1);
if(ret<0 || ret==2) { /* <0 = error , 2 = work is done */
fprintf(stderr,"\ncdrfifo: fifo ended work with ret=%d\n",ret);
if(ret<0)
return(-7);
break;
}
}
return(1);
}
int main(int argc, char **argv)
{
int i,ret,exit_value= 0,verbous= 1,fill_buffer= 0,min_fill,fifo_percent,fd;
double fs_value= 4.0*1024.0*1024.0,bs_value= 2048,in_counter,out_counter;
double interval= 1.0,speed_limit= 0.0;
char output_file[4096];
struct CdrfifO *ff= NULL;
strcpy(output_file,"-");
fd= 1;
for(i= 1; i<argc; i++) {
if(strncmp(argv[i],"bs=",3)==0) {
bs_value= Scanf_io_size(argv[i]+3,0);
if(bs_value<=0 || bs_value>1024.0*1024.0*1024.0) {
fprintf(stderr,
"cdrfifo: FATAL : bs=N expects a size between 1 and 1g\n");
{exit_value= 2; goto ex;}
}
} else if(strncmp(argv[i],"fl=",3)==0) {
sscanf(argv[i]+3,"%d",&fill_buffer);
fill_buffer= !!fill_buffer;
} else if(strncmp(argv[i],"fs=",3)==0) {
fs_value= Scanf_io_size(argv[i]+3,0);
if(fs_value<=0 || fs_value>1024.0*1024.0*1024.0) {
fprintf(stderr,
"cdrfifo: FATAL : fs=N expects a size between 1 and 1g\n");
{exit_value= 2; goto ex;}
}
} else if(strncmp(argv[i],"iv=",3)==0) {
sscanf(argv[i]+3,"%lf",&interval);
if(interval<0.001 || interval>1000.0)
interval= 1;
} else if(strncmp(argv[i],"of=",3)==0) {
if(strcmp(argv[i]+3,"-")==0 || argv[i][3]==0)
continue;
fd= open(argv[i]+3,O_WRONLY|O_CREAT);
if(fd<0) {
fprintf(stderr,"cdrfifo: FATAL : cannot open output file '%s'\n",
argv[i]+3);
fprintf(stderr,"cdrfifo: errno=%d , \"%s\"\n",
errno,errno==0?"-no error code available-":strerror(errno));
{exit_value= 4; goto ex;}
}
} else if(strncmp(argv[i],"sl=",3)==0) {
speed_limit= Scanf_io_size(argv[i]+3,0);
} else if(strncmp(argv[i],"vb=",3)==0) {
sscanf(argv[i]+3,"%d",&verbous);
} else if(strcmp(argv[i],"-multi_test")==0) {
if(speed_limit==0.0)
speed_limit= 10*150*1024;
ret= Test_multi((int) fs_value,speed_limit,interval,(verbous>=2));
fprintf(stderr,"Test_multi(): ret= %d\n",ret);
exit(ret<0);
} else {
fprintf(stderr,"cdrfifo 0.3 : stdin-to-stdout fifo buffer.\n");
fprintf(stderr,"usage : %s [bs=block_size] [fl=fillfirst]\n",argv[0]);
fprintf(stderr," [fs=fifo_size] [iv=interval] [of=output_file]\n");
fprintf(stderr," [sl=bytes_per_second_limit] [vb=verbosity]\n");
fprintf(stderr,"fl=1 reads full buffer before writing starts.\n");
fprintf(stderr,"sl>0 allows catch up for whole run time.\n");
fprintf(stderr,"sl<0 allows catch up for single interval.\n");
fprintf(stderr,"vb=0 is silent, vb=2 is debug.\n");
fprintf(stderr,"example: cdrfifo bs=8k fl=1 fs=32m iv=0.1 sl=-5400k\n");
if(strcmp(argv[i],"-help")!=0 && strcmp(argv[i],"--help")!=0) {
fprintf(stderr,"\ncdrfifo: FATAL : option not recognized: '%s'\n",
argv[i]);
exit_value= 1;
}
goto ex;
}
}
if(verbous>=1) {
fprintf(stderr,
"cdrfifo: bs=%.lf fl=%d fs=%.lf iv=%lf of='%s' sl=%.lf vb=%d\n",
bs_value,fill_buffer,fs_value,interval,output_file,speed_limit,
verbous);
}
ret= Cdrfifo_new(&ff,0,fd,(int) bs_value,(int) fs_value,0);
if(ret<=0) {
fprintf(stderr,
"cdrfifo: FATAL : creation of fifo object with %.lf bytes failed\n",
fs_value);
{exit_value= 3; goto ex;}
}
if(speed_limit!=0.0)
Cdrfifo_set_speed_limit(ff,speed_limit,0);
if(fill_buffer) {
ret= Cdrfifo_fill(ff,0);
if(ret<=0) {
fprintf(stderr,
"cdrfifo: FATAL : initial filling of fifo buffer failed\n");
{exit_value= 4; goto ex;}
}
}
while(1) {
ret= Cdrfifo_try_to_work(ff,(int) (interval*1000000.0),
NULL,NULL,(verbous>=2));
if(ret<0) {
fprintf(stderr,"\ncdrfifo: FATAL : fifo aborted. errno=%d , \"%s\"\n",
errno,errno==0?"-no error code available-":strerror(errno));
{exit_value= 4; goto ex;}
} else if(ret==2) {
if(verbous>=1) {
double put_counter,get_counter,empty_counter,full_counter;
int total_min_fill;
Cdrfifo_get_counters(ff,&in_counter,&out_counter,0);
fprintf(stderr,"\ncdrfifo: done : %.lf bytes in , %.lf bytes out\n",
in_counter,out_counter);
Cdrfifo_get_min_fill(ff,&total_min_fill,&min_fill,0);
fifo_percent= 100.0*((double) total_min_fill)/fs_value;
if(fifo_percent==0 && total_min_fill>0)
fifo_percent= 1;
Cdrfifo_get_cdr_counters(ff,&put_counter,&get_counter,
&empty_counter,&full_counter,0);
fprintf(stderr,"cdrfifo: fifo had %.lf puts and %.lf gets.\n",
put_counter,get_counter);
fprintf(stderr,
"cdrfifo: fifo was %.lf times empty and %.lf times full, min fill was %d%%.\n",
empty_counter,full_counter,fifo_percent);
}
break;
}
Cdrfifo_next_interval(ff,&min_fill,0);
}
ex:;
Cdrfifo_destroy(&ff,0);
exit(exit_value);
}
#endif /* Cdrfifo_standalonE */