1 // vim: ts=4 sw=4 noet:
3 --------------------------------------------------------------------------------
4 Copyright (c) 2018-2019 AT&T Intellectual Property.
6 Licensed under the Apache License, Version 2.0 (the "License");
7 you may not use this file except in compliance with the License.
8 You may obtain a copy of the License at
10 http://www.apache.org/licenses/LICENSE-2.0
12 Unless required by applicable law or agreed to in writing, software
13 distributed under the License is distributed on an "AS IS" BASIS,
14 WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
15 See the License for the specific language governing permissions and
16 limitations under the License.
17 --------------------------------------------------------------------------------
22 Abstract: The mc listener library content. All external functions
23 should start with mcl_ and all stderr messages should have
24 (mcl) as the first token following the severity indicator.
27 Author: E. Scott Daniels
39 #include <sys/types.h>
43 #include <rmr/rmr_symtab.h>
44 #include <rmr/RIC_message_types.h>
59 Information about one file descriptor. This is pointed to by the hash
60 such that the message type can be used as a key to look up the fifo's
65 int key; // symtab key
66 long long wcount; // number of writes
67 long long drops; // number dropped
69 long long wcount_rp; // number of writes during last reporting period
70 long long drops_rp; // number dropped during last reporting period
74 Our conext. Pointers to the read and write hash tables (both keyed on the message
75 type), the message router (RMR) context, and other goodies.
78 void* mrc; // the message router's context
79 void* wr_hash; // symtable to look up pipe info based on mt for writing
80 void* rd_hash; // we support reading from pipes, but need a different FD for that
81 char* fifo_dir; // directory where we open fifos
85 // -------- private -------------------------------------------------------
89 Set up for raw data capture. We look for directory overriedes from
90 environment variables, and then invoke the rdc_init() to actually
93 static void* setup_rdc() {
95 int value; // value computed for something
96 char* ep; // pointer to environment var
97 char* sdir = "/tmp/rdc/stage"; // default directory names
98 char* fdir = "/tmp/rdc/final";
99 char* suffix = ".rdc";
102 if( (ep = getenv( "MCL_RDC_ENABLE" )) != NULL && atoi( ep ) == 0 ) { // exists and is 0
103 logit( LOG_INFO, "(mcl) raw data capture disabled by environment var setting (MCL_RDCENABLE=0)\n" );
107 if( (ep = getenv( "MCL_RDC_STAGE" )) != NULL ) {
110 mkdir( "/tmp/rdc", 0755 ); // we ignore failures here as it could likely exist
114 if( (ep = getenv( "MCL_RDC_FINAL" )) != NULL ) {
117 mkdir( "/tmp/rdc", 0755 ); // we ignore failures again -- very likely it's there
121 if( (ep = getenv( "MCL_RDC_SUFFIX" )) != NULL ) {
125 if( (ep = getenv( "MCL_RDC_DONE" )) != NULL ) {
129 ctx = rdc_init( sdir, fdir, suffix, done );
131 logit( LOG_ERR, "rdc_init did not generate a context" );
133 logit( LOG_INFO, "raw data capture files will be staged in: %s", sdir );
134 logit( LOG_INFO, "raw data capture files will be moved for copy to: %s", fdir );
137 if( (ep = getenv( "MCL_RDC_FREQ" )) != NULL ) {
139 logit( LOG_INFO, "setting frequency: %d", value );
140 rdc_set_freq( ctx, value );
146 Builds an extended header in the buffer provided, or allocates a new buffer if
147 dest is nil. The header is of the form:
148 <delim><len><timestamp>
150 Field lengths (bytes) are:
153 timestamp 16 (15 digits + 0)
156 Timestamp is a single unsigned long long in ASCII; ms since epoch.
157 If the current time is 2019/10/03 10:39:51.103 which is 1570113591.103
158 the timestamp generated will be 1570113591103.
160 The lenght and timestamp fields in the header are zero terminated so
161 they can be parsed as a string (atoi etc).
163 static char* build_hdr( int len, char* dest, int dest_len ) {
164 struct timespec ts; // time just before call executed
167 dest_len = MCL_EXHDR_SIZE + 2; // more than enough room
168 dest = (char *) malloc( sizeof( char ) * dest_len );
170 if( dest_len < MCL_EXHDR_SIZE ) { // shouldn't happen, but take no chances
171 memset( dest, 0, dest_len );
176 memset( dest, 0, dest_len );
178 clock_gettime( CLOCK_REALTIME, &ts );
179 snprintf( dest, dest_len, "%s%07d", MCL_DELIM, len );
180 snprintf( dest+12, dest_len-13, "%ld%03ld", ts.tv_sec, ts.tv_nsec/1000000 );
186 Build a file name and open. The io_direction is either READER or
187 WRITER. For a writer we must 'trick' the system into allowing us
188 to open a pipe for writing in non-blocking mode so that we can
189 report on drops (messages we couldn't write because there was no
190 reader). The trick is to open a reader on the pipe so that when
191 we open the writer there's a reader and the open won't fail. As
192 soon as we have the writer open, we can close the junk reader.
194 If the desired fifo does not exist, it is created.
196 static int open_fifo( mcl_ctx_t* ctx, int mtype, int io_dir ) {
198 int fd; // real file des
199 int jfd = -1; // junk file des
202 if( ctx == NULL || mtype < 0 ) {
206 snprintf( wbuf, sizeof( wbuf ), "%s/MT_%09d", ctx->fifo_dir, mtype );
208 state = mkfifo( wbuf, 0660 ); // make the fifo; this will fail if it exists and that's ok
209 if( state != 0 && errno != EEXIST ) {
210 logit( LOG_ERR, "(mcl) unable to create fifo: %s: %s", wbuf, strerror( errno ) );
214 if( io_dir == READER ) {
215 fd = open( wbuf, O_RDONLY ); // just open the reader
217 logit( LOG_ERR, "(mcl) fifo open failed (ro): %s: %s", wbuf, strerror( errno ) );
220 jfd = open( wbuf, O_RDWR | O_NONBLOCK ); // must have a reader before we can open a non-blocking writer
222 logit( LOG_ERR, "(mcl) fifo open failed (rw): %s: %s", wbuf, strerror( errno ) );
226 fd = open( wbuf, O_WRONLY | O_NONBLOCK ); // this will be our actual writer, in non-blocking mode
228 logit( LOG_ERR, "(mcl) fifo open failed (wo): %s: %s", wbuf, strerror( errno ) );
231 close( jfd ); // should be safe to close this
239 Given a message type, return the file des of the fifo that
240 the payload should be written to. Returns the file des, or -1
241 on error. When sussing out a read file descriptor this will
242 block until there is a fifo for the message type which is
245 If fref is not nil, then a pointer to the fifo info block is returned
246 allowing for direct update of counts after the write.
248 static int suss_fifo( mcl_ctx_t* ctx, int mtype, int io_dir, fifo_t** fref ) {
259 if( io_dir == READER ) { // with an integer key, we need two hash tables
265 if( (fifo = (fifo_t *) rmr_sym_pull( hash, mtype )) == NULL ) {
266 fifo = (fifo_t *) malloc( sizeof( *fifo ) );
268 memset( fifo, 0, sizeof( *fifo ) );
270 fifo->fd = open_fifo( ctx, mtype, io_dir );
271 if( fifo->fd >= 0 ) { // save only on good open
272 rmr_sym_map( hash, mtype, fifo );
284 return fifo == NULL ? -1 : fifo->fd;
288 Make marking counts easier in code
290 static inline void chalk_error( fifo_t* fifo ) {
297 static inline void chalk_ok( fifo_t* fifo ) {
305 Callback function driven to traverse the symtab and generate the
306 counts for each fifo. Sonar will complain about unused parameters which
307 are normal for callbacks. Further, sonar will grumble about st, and entry
308 not being const; we can't unless RMR proto for the callback changes.
310 static void wr_stats( void* st, void* entry, char const* name, void* thing, void* data ) {
312 int report_period = 60;
315 report_period = *((int *) data);
318 if( (fifo = (fifo_t *) thing) != NULL ) {
319 logit( LOG_STAT, "(mcl) mtype=%d total writes=%lld total drops=%lld; during last %ds writes=%lld drops=%lld",
320 fifo->key, fifo->wcount, fifo->drops, report_period, fifo->wcount_rp, fifo->drops_rp );
322 fifo->wcount_rp = 0; // reset the report counts
327 // ---------- public ------------------------------------------------------
329 Sets a signal handler for sigpipe so we don't crash if a reader closes the
330 last reading fd on a pipe. We could do this automatically, but if the user
331 programme needs to trap sigpipe too, this gives them the option not to have
334 extern int mcl_set_sigh( ) {
335 signal( SIGPIPE, SIG_IGN );
339 "Opens" the interface to RMR such that messages sent to the application will
340 be available via the rmr receive funcitons. This is NOT automatically called
341 by the mk_context function as some applications will be using the mc library
342 for non-RMR, fifo, chores.
344 extern int mcl_start_listening( void* vctx, char* port, int wait4ready ) {
348 if( (ctx = (mcl_ctx_t*) vctx) == NULL ) {
352 ctx->mrc = rmr_init( port, RMR_MAX_RCV_BYTES, RMRFL_NONE ); // start your engines!
353 if( ctx->mrc == NULL ) {
354 logit( LOG_CRIT, "start listening: unable to initialise RMr" );
358 while( wait4ready && ! rmr_ready( ctx->mrc ) ) { // only senders need to wait
359 if( announce <= 0 ) {
360 logit( LOG_INFO, "waiting for RMR to show ready" );
373 Blocks until a message arives with a good return code or we timeout. Returns the
374 rmr message buffer. Timeout value epxected in seconds.
376 extern rmr_mbuf_t* mcl_get_msg( void* vctx, rmr_mbuf_t* msg, int timeout ) {
379 if( (ctx = (mcl_ctx_t *) vctx) == NULL ) {
383 if( ctx->mrc == NULL ) {
384 logit( LOG_CRIT, "get msg: abort: bad rmr context reference (nil)" );
389 msg = rmr_torcv_msg( ctx->mrc, msg, timeout * 1000 ); // wait for next
390 } while( msg == NULL || (msg->state != RMR_OK && msg->state != RMR_ERR_TIMEOUT) );
398 extern void* mcl_mk_context( const char* dir ) {
401 if( (ctx = (mcl_ctx_t *) malloc( sizeof( *ctx ) )) != NULL ) {
402 memset( ctx, 0, sizeof( *ctx ) );
403 ctx->fifo_dir = strdup( dir );
404 ctx->wr_hash = rmr_sym_alloc( 1001 );
405 ctx->rd_hash = rmr_sym_alloc( 1001 );
407 if( ctx->wr_hash == NULL || ctx->rd_hash == NULL ) {
408 logit( LOG_ERR, "(mcl) unable to allocate hash table for fifo keys" );
418 Read the header. Best case we read the expected number of bytes, get all
419 of them and find that they start with the delemiter. Worst case
420 We have to wait for all of the header, or need to synch at the next
421 delimeter. We assume best case most likely and handle it as such.
423 static void read_header( int fd, char* buf ) {
425 int need = MCL_EXHDR_SIZE; // total needed
426 int dneed; // delimieter needed
427 char* rp; // read position in buf
429 len = read( fd, buf, need );
430 if( len == need && strncmp( buf, MCL_DELIM, strlen( MCL_DELIM )) == 0 ) { // best case, most likely
435 if( len < strlen( MCL_DELIM ) ) { // must get at least enough bytes to check delim
437 dneed = strlen( MCL_DELIM ) - len;
440 len = read( fd, rp, dneed );
446 if( strncmp( buf, MCL_DELIM, strlen( MCL_DELIM )) == 0 ) { // have a good delimiter, just need to wait for bytes
447 need = MCL_EXHDR_SIZE - strlen( MCL_DELIM );
448 rp = buf + (MCL_EXHDR_SIZE - need);
451 len = read( fd, rp, need );
459 while( buf[0] != MCL_DELIM[0] ) { // wait for a recognised start byte to be read (may cause an additional message drop
460 len = read( fd, buf, 1 ); // because we ignore start byte that might be in the buffer)
467 Read one record from the fifo that the message type maps to.
468 Writes at max ublen bytes into the ubuf.
470 If long_hdrs is true (!0), then we expect that the stream in the fifo
471 has extended headers (<delim><len><time>), and will write the timestamp
472 from the header into the buffer pointed to by timestamp. The buffer is
473 assumed to be at least MCL_TSTAMP_SIZE bytes in length.
475 Further, when extended headers are being used, this function will
476 automatically resynchronise if it detects an issue.
478 The function could look for the delimiter and automatically detect whether
479 or not extended headers are in use, but if the stream is out of synch on the
480 first read, this cannot be done, so the funciton requires that the caller
481 know that the FIFO contains extended headers.
483 static int fifo_read1( void *vctx, int mtype, char* ubuf, int ublen, int long_hdrs, char* timestamp ) {
487 int got = 0; // number of bytes we actually got
490 mcl_ctx_t* ctx; // our context; mostly for the rmr context reference and symtable
492 if( (ctx = (mcl_ctx_t*) vctx) == NULL ) {
497 if( (fd = suss_fifo( ctx, mtype, READER, NULL )) >= 0 ) {
499 read_header( fd, wbuf );
500 msg_len = need = atoi( wbuf + MCL_LEN_OFF ); // read the length
502 strncpy( timestamp, wbuf + MCL_TSTAMP_OFF+1, MCL_TSTAMP_SIZE );
505 if( timestamp != NULL ) { // won't be there, but ensure it's not garbage
509 read( fd, wbuf, MCL_LEN_SIZE ); // we assume we will get all 8 bytes as there isn't a way to sync the old stream
510 msg_len = need = atoi( wbuf );
515 need = ublen; // cannot give them more than they can take
518 len = read( fd, wbuf, need > sizeof( wbuf ) ? sizeof( wbuf ) : need );
519 memcpy( ubuf+got, wbuf, len );
524 if( msg_len > got ) { // we must ditch rest of this message
525 need = msg_len - got;
527 len = read( fd, wbuf, need > sizeof( wbuf ) ? sizeof( wbuf ) : need );
540 Read one record from the fifo that the message type maps to.
541 Writes at max ublen bytes into the ubuf. If extended headers are in use
542 this function will ignore the timestamp.
544 If long_hdrs is true (!0), then we expect that the stream in the fifo
545 has extended headers (<delim><len><time>).
547 extern int mcl_fifo_read1( void *vctx, int mtype, char* ubuf, int ublen, int long_hdrs ) {
548 return fifo_read1( vctx, mtype, ubuf, ublen, long_hdrs, NULL );
552 Read a single message from the FIFO returning it in the caller's buffer. If extended
553 headers are being used, and the caller supplied a timestamp buffer, the timestamp
554 which was in the header will be returned in that buffer. The return value is the number
555 of bytes in the buffer; 0 indicates an error and errno should be set.
557 extern int mcl_fifo_tsread1( void *vctx, int mtype, char* ubuf, int ublen, int long_hdrs, char *timestamp ) {
558 return fifo_read1( vctx, mtype, ubuf, ublen, long_hdrs, timestamp );
563 Will read messages and fan them out based on the message type. This should not
564 return and if it does the caller should assume an error.
566 The output to each fifo is MCL_LEN_SIZE bytes with an ASCII, zero terminated, length
567 string , followed by that number of 'raw' bytes. The raw bytes are the payload
570 The report parameter is the frequency, in seconds, for writing a short
571 status report to stdout. If 0 then it's off.
573 If long_hdr is true, then we geneate an extended header with a delimiter and
576 The one message which is NOT pushed into a FIFO is the RIC_HEALTH_CHECK_REQ
577 message. When the health check message is received it is responded to
578 with the current state of processing (ok or err).
580 extern void mcl_fifo_fanout( void* vctx, int report, int long_hdr ) {
581 mcl_ctx_t* ctx; // our context; mostly for the rmr context reference and symtable
582 fifo_t* fifo; // fifo to chalk counts on
583 rmr_mbuf_t* mbuf = NULL; // received message buffer; recycled on each call
584 char header[128]; // header we'll pop in front of the payload
585 int fd; // file des to write to
586 long long total = 0; // total messages received and written
587 long long total_drops = 0; // total messages received and written
588 long count = 0; // messages received and written during last reporting period
589 long errors = 0; // unsuccessful payload writes
590 long drops = 0; // number of drops
591 time_t next_report = 0; // we'll report every 2 seconds if report is true
593 size_t hwlen; // write len for header
594 void* rdc_ctx = NULL; // raw data capture context
595 void* rdc_buf = NULL; // capture buffer
597 if( (ctx = (mcl_ctx_t*) vctx) == NULL ) {
598 logit( LOG_ERR, "(mcl) invalid context given to fanout" );
607 rdc_ctx = setup_rdc( ); // pull rdc directories from enviornment and initialise
610 mbuf = mcl_get_msg( ctx, mbuf, report ); // wait up to report sec for msg (0 == block until message)
612 if( mbuf != NULL && mbuf->state == RMR_OK ) {
613 if( mbuf->mtype == RIC_HEALTH_CHECK_REQ ) {
614 mbuf->mtype = RIC_HEALTH_CHECK_RESP; // if we're here we are running and all is ok
616 mbuf = rmr_realloc_payload( mbuf, 128, FALSE, FALSE ); // ensure payload is large enough
617 if( mbuf->payload != NULL ) {
618 strncpy( mbuf->payload, "OK\n", rmr_payload_size( mbuf) );
619 rmr_rts_msg( ctx->mrc, mbuf );
624 if( mbuf->len > 0 ) {
626 build_hdr( mbuf->len, header, sizeof( header ) );
627 hwlen = MCL_EXHDR_SIZE;
629 snprintf( header, sizeof( header ), "%07d", mbuf->len ); // size of payload CAUTION: 7d is MCL_LEN_SIZE-1
630 hwlen = MCL_LEN_SIZE;
633 fd = suss_fifo( ctx, mbuf->mtype, WRITER, &fifo ); // map the message type to an open fd
635 if( write( fd, header, hwlen ) != hwlen ) { // write exactly MCL_LEN_SIZE bytes from the buffer
640 if( write( fd, mbuf->payload, mbuf->len ) < mbuf->len ) { // followed by the payload
651 if( rdc_ctx != NULL ) {
652 rdc_buf = rdc_init_buf( mbuf->mtype, header, hwlen, rdc_buf ); // set up for write
653 rdc_write( rdc_ctx, rdc_buf, mbuf->payload, mbuf->len ); // write the raw data
659 if( (now = time( NULL ) ) > next_report ) {
660 rmr_sym_foreach_class( ctx->wr_hash, 0, wr_stats, &report ); // run endpoints in the active table
663 logit( LOG_STAT, "(mcl) total writes=%lld total drops=%lld; during last %ds writes=%ld drops=%ld errs=%ld errors",
664 total, total_drops, report, count, drops, errors );
665 next_report = now + report;
674 if( ! FOREVER ) { // allow escape during unit tests; compiled out othewise, but sonar won't see that
676 break; // sonar grumbles if we put FOREVER into the while; maddening
683 Given a buffer and length, along with the message type, look up the fifo and write
684 the buffer. Returns 0 on error; 1 on success.
686 extern int mcl_fifo_one( void* vctx, const char* payload, int plen, int mtype ) {
687 mcl_ctx_t* ctx; // our context; mostly for the rmr context reference and symtable
688 fifo_t* fifo; // fifo to chalk counts on
690 int fd; // file des to write to
692 if( plen <= 0 || payload == NULL ) {
696 if( (ctx = (mcl_ctx_t*) vctx) == NULL ) {
697 logit( LOG_ERR, "(mcl) invalid context given to fifo_one\n" );
701 fd = suss_fifo( ctx, mtype, WRITER, &fifo ); // map the message type to an open fd
703 state = write( fd, payload, plen );
706 return state == (size_t) plen;