/** Node type: File
*
* This file implements the file type for nodes.
*
* @author Steffen Vogel <stvogel@eonerc.rwth-aachen.de>
* @copyright 2014-2015, Institute for Automation of Complex Power Systems, EONERC
* This file is part of S2SS. All Rights Reserved. Proprietary and confidential.
* Unauthorized copying of this file, via any medium is strictly prohibited.
*********************************************************************************/
#include <unistd.h>
#include <string.h>
#include "msg.h"
#include "file.h"
#include "utils.h"
#include "timing.h"
#include "pool.h"
int file_reverse(struct node *n)
{
struct file *f = n->_vd;
SWAP(f->read, f->write);
return 0;
}
static char * file_format_name(const char *format, struct timespec *ts)
{
struct tm tm;
char *buf = alloc(FILE_MAX_PATHLEN);
/* Convert time */
gmtime_r(&ts->tv_sec, &tm);
strftime(buf, FILE_MAX_PATHLEN, format, &tm);
return buf;
}
static FILE * file_reopen(struct file_direction *dir)
{
char buf[FILE_MAX_PATHLEN];
const char *path = buf;
/* Append chunk number to filename */
if (dir->chunk >= 0)
snprintf(buf, FILE_MAX_PATHLEN, "%s_%03u", dir->path, dir->chunk);
else
path = dir->path;
if (dir->handle)
fclose(dir->handle);
return fopen(path, dir->mode);
}
static int file_parse_direction(config_setting_t *cfg, struct file *f, int d)
{
struct file_direction *dir = (d == FILE_READ) ? &f->read : &f->write;
if (!config_setting_lookup_string(cfg, "path", &dir->fmt))
return -1;
if (!config_setting_lookup_string(cfg, "mode", &dir->mode))
dir->mode = (d == FILE_READ) ? "r" : "w+";
return 0;
}
int file_parse(struct node *n, config_setting_t *cfg)
{
struct file *f = n->_vd;
config_setting_t *cfg_in, *cfg_out;
cfg_out = config_setting_get_member(cfg, "out");
if (cfg_out) {
if (file_parse_direction(cfg_out, f, FILE_WRITE))
cerror(cfg_out, "Failed to parse output file for node %s", node_name(n));
/* More write specific settings */
if (!config_setting_lookup_int(cfg_out, "split", &f->write.split))
f->write.split = 0; /* Save all samples in a single file */
}
cfg_in = config_setting_get_member(cfg, "in");
if (cfg_in) {
if (file_parse_direction(cfg_in, f, FILE_READ))
cerror(cfg_in, "Failed to parse input file for node %s", node_name(n));
/* More read specific settings */
if (!config_setting_lookup_bool(cfg_in, "splitted", &f->read.split))
f->read.split = 0; /* Save all samples in a single file */
if (!config_setting_lookup_float(cfg_in, "rate", &f->read_rate))
f->read_rate = 0; /* Disable fixed rate sending. Using timestamps of file instead */
double epoch_flt;
if (!config_setting_lookup_float(cfg_in, "epoch", &epoch_flt))
epoch_flt = 0;
f->read_epoch = time_from_double(epoch_flt);
const char *epoch_mode;
if (!config_setting_lookup_string(cfg_in, "epoch_mode", &epoch_mode))
epoch_mode = "direct";
if (!strcmp(epoch_mode, "direct"))
f->read_epoch_mode = EPOCH_DIRECT;
else if (!strcmp(epoch_mode, "wait"))
f->read_epoch_mode = EPOCH_WAIT;
else if (!strcmp(epoch_mode, "relative"))
f->read_epoch_mode = EPOCH_RELATIVE;
else if (!strcmp(epoch_mode, "absolute"))
f->read_epoch_mode = EPOCH_ABSOLUTE;
else
cerror(cfg_in, "Invalid value '%s' for setting 'epoch_mode'", epoch_mode);
}
n->_vd = f;
return 0;
}
char * file_print(struct node *n)
{
struct file *f = n->_vd;
char *buf = NULL;
if (f->read.fmt) {
const char *epoch_str = NULL;
switch (f->read_epoch_mode) {
case EPOCH_DIRECT: epoch_str = "direct"; break;
case EPOCH_WAIT: epoch_str = "wait"; break;
case EPOCH_RELATIVE: epoch_str = "relative"; break;
case EPOCH_ABSOLUTE: epoch_str = "absolute"; break;
}
strcatf(&buf, "in=%s, epoch_mode=%s, epoch=%.2f, ",
f->read.path ? f->read.path : f->read.fmt,
epoch_str,
time_to_double(&f->read_epoch)
);
if (f->read_rate)
strcatf(&buf, "rate=%.1f, ", f->read_rate);
}
if (f->write.fmt) {
strcatf(&buf, "out=%s, mode=%s, ",
f->write.path ? f->write.path : f->write.fmt,
f->write.mode
);
}
if (f->read_first.tv_sec || f->read_first.tv_nsec)
strcatf(&buf, "first=%.2f, ", time_to_double(&f->read_first));
if (f->read_offset.tv_sec || f->read_offset.tv_nsec)
strcatf(&buf, "offset=%.2f, ", time_to_double(&f->read_offset));
if ((f->read_first.tv_sec || f->read_first.tv_nsec) &&
(f->read_offset.tv_sec || f->read_offset.tv_nsec)) {
struct timespec eta, now = time_now();
eta = time_add(&f->read_first, &f->read_offset);
eta = time_diff(&now, &eta);
if (eta.tv_sec || eta.tv_nsec)
strcatf(&buf, "eta=%.2f sec, ", time_to_double(&eta));
}
if (strlen(buf) > 2)
buf[strlen(buf) - 2] = 0;
return buf;
}
int file_open(struct node *n)
{
struct file *f = n->_vd;
struct timespec now = time_now();
if (f->read.fmt) {
/* Prepare file name */
f->read.chunk = f->read.split ? 0 : -1;
f->read.path = file_format_name(f->read.fmt, &now);
/* Open file */
f->read.handle = file_reopen(&f->read);
if (!f->read.handle)
serror("Failed to open file for reading: '%s'", f->read.path);
/* Create timer */
f->read_timer = timerfd_create(CLOCK_REALTIME, 0);
if (f->read_timer < 0)
serror("Failed to create timer");
/* Arm the timer with a fixed rate */
if (f->read_rate) {
struct itimerspec its = {
.it_interval = time_from_double(1 / f->read_rate),
.it_value = { 0, 1 },
};
int ret = timerfd_settime(f->read_timer, 0, &its, NULL);
if (ret)
serror("Failed to start timer");
}
/* Get current time */
struct timespec now = time_now();
/* Get timestamp of first line */
struct msg m;
int ret = msg_fscan(f->read.handle, &m, NULL, NULL); rewind(f->read.handle);
if (ret < 0)
error("Failed to read first timestamp of node %s", node_name(n));
f->read_first = MSG_TS(&m);
/* Set read_offset depending on epoch_mode */
switch (f->read_epoch_mode) {
case EPOCH_DIRECT: /* read first value at now + epoch */
f->read_offset = time_diff(&f->read_first, &now);
f->read_offset = time_add(&f->read_offset, &f->read_epoch);
break;
case EPOCH_WAIT: /* read first value at now + first + epoch */
f->read_offset = now;
f->read_offset = time_add(&f->read_offset, &f->read_epoch);
break;
case EPOCH_RELATIVE: /* read first value at first + epoch */
f->read_offset = f->read_epoch;
break;
case EPOCH_ABSOLUTE: /* read first value at f->read_epoch */
f->read_offset = time_diff(&f->read_first, &f->read_epoch);
break;
}
}
if (f->write.fmt) {
/* Prepare file name */
f->write.chunk = f->write.split ? 0 : -1;
f->write.path = file_format_name(f->write.fmt, &now);
/* Open file */
f->write.handle = file_reopen(&f->write);
if (!f->write.handle)
serror("Failed to open file for writing: '%s'", f->write.path);
}
return 0;
}
int file_close(struct node *n)
{
struct file *f = n->_vd;
free(f->read.path);
free(f->write.path);
if (f->read_timer)
close(f->read_timer);
if (f->read.handle)
fclose(f->read.handle);
if (f->write.handle)
fclose(f->write.handle);
return 0;
}
int file_read(struct node *n, struct pool *pool, int cnt)
{
struct file *f = n->_vd;
int values, flags, i = 0;
if (f->read.handle) {
for (i = 0; i < cnt; i++) {
struct msg *cur = pool_getrel(pool, i);
/* Get message and timestamp */
retry: values = msg_fscan(f->read.handle, cur, &flags, NULL);
if (values < 0) {
if (feof(f->read.handle)) {
if (f->read.split) {
f->read.chunk++;
f->read.handle = file_reopen(&f->read);
if (!f->read.handle)
return 0;
info("Open new input chunk of node %s: %d", node_name(n), f->read.chunk);
}
else {
info("Rewind input file of node %s", node_name(n));
rewind(f->read.handle);
goto retry;
}
}
else
warn("Failed to read messages from node %s: reason=%d", node_name(n), values);
return 0;
}
/* Fix missing sequence no */
cur->sequence = f->read_sequence = (flags & MSG_PRINT_SEQUENCE) ? cur->sequence : f->read_sequence + 1;
if (!f->read_rate || ftell(f->read.handle) == 0) {
struct timespec until = time_add(&MSG_TS(cur), &f->read_offset);
if (timerfd_wait_until(f->read_timer, &until) < 0)
serror("Failed to wait for timer");
/* Update timestamp */
cur->ts.sec = until.tv_sec;
cur->ts.nsec = until.tv_nsec;
}
else { /* Wait with fixed rate delay */
if (timerfd_wait(f->read_timer) < 0)
serror("Failed to wait for timer");
/* Update timestamp */
struct timespec now = time_now();
cur->ts.sec = now.tv_sec;
cur->ts.nsec = now.tv_nsec;
}
}
}
else
error("Can not read from node %s", node_name(n));
return i;
}
int file_write(struct node *n, struct pool *pool, int cnt)
{
int i = 0;
struct file *f = n->_vd;
if (f->write.handle) {
for (i = 0; i < cnt; i++) {
struct msg *m = pool_getrel(pool, i);
/* Split file if requested */
if ((f->write.split > 0) && ftell(f->write.handle) > f->write.split * (1 << 20)) {
f->write.chunk++;
f->write.handle = file_reopen(&f->write);
info("Splitted output node %s: chunk=%u", node_name(n), f->write.chunk);
}
msg_fprint(f->write.handle, m, MSG_PRINT_ALL & ~MSG_PRINT_OFFSET, 0);
}
fflush(f->write.handle);
}
else
error("Can not write to node %s", node_name(n));
return i;
}
static struct node_type vt = {
.name = "file",
.description = "support for file log / replay node type",
.size = sizeof(struct file),
.reverse = file_reverse,
.parse = file_parse,
.print = file_print,
.open = file_open,
.close = file_close,
.read = file_read,
.write = file_write
};
REGISTER_NODE_TYPE(&vt)