1 /****************************************************************************
2 * RRDtool 1.3.1 Copyright by Tobi Oetiker, 1997-2008
3 ****************************************************************************
4 * rrd__graph.c produce graphs from data in rrdfiles
5 ****************************************************************************/
15 #if defined(WIN32) && !defined(__CYGWIN__) && !defined(__CYGWIN32__)
28 #include "rrd_graph.h"
30 /* some constant definitions */
34 #ifndef RRD_DEFAULT_FONT
35 /* there is special code later to pick Cour.ttf when running on windows */
36 #define RRD_DEFAULT_FONT "DejaVu Sans Mono,Bitstream Vera Sans Mono,monospace,Courier"
39 text_prop_t text_prop[] = {
40 {8.0, RRD_DEFAULT_FONT}
42 {9.0, RRD_DEFAULT_FONT}
44 {7.0, RRD_DEFAULT_FONT}
46 {8.0, RRD_DEFAULT_FONT}
48 {8.0, RRD_DEFAULT_FONT} /* legend */
52 {0, 0, TMT_SECOND, 30, TMT_MINUTE, 5, TMT_MINUTE, 5, 0, "%H:%M"}
54 {2, 0, TMT_MINUTE, 1, TMT_MINUTE, 5, TMT_MINUTE, 5, 0, "%H:%M"}
56 {5, 0, TMT_MINUTE, 2, TMT_MINUTE, 10, TMT_MINUTE, 10, 0, "%H:%M"}
58 {10, 0, TMT_MINUTE, 5, TMT_MINUTE, 20, TMT_MINUTE, 20, 0, "%H:%M"}
60 {30, 0, TMT_MINUTE, 10, TMT_HOUR, 1, TMT_HOUR, 1, 0, "%H:%M"}
62 {60, 0, TMT_MINUTE, 30, TMT_HOUR, 2, TMT_HOUR, 2, 0, "%H:%M"}
64 {60, 24 * 3600, TMT_MINUTE, 30, TMT_HOUR, 2, TMT_HOUR, 6, 0, "%a %H:%M"}
66 {180, 0, TMT_HOUR, 1, TMT_HOUR, 6, TMT_HOUR, 6, 0, "%H:%M"}
68 {180, 24 * 3600, TMT_HOUR, 1, TMT_HOUR, 6, TMT_HOUR, 12, 0, "%a %H:%M"}
70 /*{300, 0, TMT_HOUR,3, TMT_HOUR,12, TMT_HOUR,12, 12*3600,"%a %p"}, this looks silly */
71 {600, 0, TMT_HOUR, 6, TMT_DAY, 1, TMT_DAY, 1, 24 * 3600, "%a"}
73 {1200, 0, TMT_HOUR, 6, TMT_DAY, 1, TMT_DAY, 1, 24 * 3600, "%d"}
75 {1800, 0, TMT_HOUR, 12, TMT_DAY, 1, TMT_DAY, 2, 24 * 3600, "%a %d"}
77 {2400, 0, TMT_HOUR, 12, TMT_DAY, 1, TMT_DAY, 2, 24 * 3600, "%a"}
79 {3600, 0, TMT_DAY, 1, TMT_WEEK, 1, TMT_WEEK, 1, 7 * 24 * 3600, "Week %V"}
81 {3 * 3600, 0, TMT_WEEK, 1, TMT_MONTH, 1, TMT_WEEK, 2, 7 * 24 * 3600,
84 {6 * 3600, 0, TMT_MONTH, 1, TMT_MONTH, 1, TMT_MONTH, 1, 30 * 24 * 3600,
87 {48 * 3600, 0, TMT_MONTH, 1, TMT_MONTH, 3, TMT_MONTH, 3, 30 * 24 * 3600,
90 {315360, 0, TMT_MONTH, 3, TMT_YEAR, 1, TMT_YEAR, 1, 365 * 24 * 3600, "%Y"}
92 {10 * 24 * 3600, 0, TMT_YEAR, 1, TMT_YEAR, 1, TMT_YEAR, 1,
93 365 * 24 * 3600, "%y"}
95 {-1, 0, TMT_MONTH, 0, TMT_MONTH, 0, TMT_MONTH, 0, 0, ""}
98 /* sensible y label intervals ...*/
122 {20.0, {1, 5, 10, 20}
128 {100.0, {1, 2, 5, 10}
131 {200.0, {1, 5, 10, 20}
134 {500.0, {1, 2, 4, 10}
142 gfx_color_t graph_col[] = /* default colors */
144 {1.00, 1.00, 1.00, 1.00}, /* canvas */
145 {0.95, 0.95, 0.95, 1.00}, /* background */
146 {0.81, 0.81, 0.81, 1.00}, /* shade A */
147 {0.62, 0.62, 0.62, 1.00}, /* shade B */
148 {0.56, 0.56, 0.56, 0.75}, /* grid */
149 {0.87, 0.31, 0.31, 0.60}, /* major grid */
150 {0.00, 0.00, 0.00, 1.00}, /* font */
151 {0.50, 0.12, 0.12, 1.00}, /* arrow */
152 {0.12, 0.12, 0.12, 1.00}, /* axis */
153 {0.00, 0.00, 0.00, 1.00} /* frame */
160 # define DPRINT(x) (void)(printf x, printf("\n"))
166 /* initialize with xtr(im,0); */
174 pixie = (double) im->xsize / (double) (im->end - im->start);
177 return (int) ((double) im->xorigin + pixie * (mytime - im->start));
180 /* translate data values into y coordinates */
189 if (!im->logarithmic)
190 pixie = (double) im->ysize / (im->maxval - im->minval);
193 (double) im->ysize / (log10(im->maxval) - log10(im->minval));
195 } else if (!im->logarithmic) {
196 yval = im->yorigin - pixie * (value - im->minval);
198 if (value < im->minval) {
201 yval = im->yorigin - pixie * (log10(value) - log10(im->minval));
209 /* conversion function for symbolic entry names */
212 #define conv_if(VV,VVV) \
213 if (strcmp(#VV, string) == 0) return VVV ;
219 conv_if(PRINT, GF_PRINT);
220 conv_if(GPRINT, GF_GPRINT);
221 conv_if(COMMENT, GF_COMMENT);
222 conv_if(HRULE, GF_HRULE);
223 conv_if(VRULE, GF_VRULE);
224 conv_if(LINE, GF_LINE);
225 conv_if(AREA, GF_AREA);
226 conv_if(STACK, GF_STACK);
227 conv_if(TICK, GF_TICK);
228 conv_if(TEXTALIGN, GF_TEXTALIGN);
229 conv_if(DEF, GF_DEF);
230 conv_if(CDEF, GF_CDEF);
231 conv_if(VDEF, GF_VDEF);
232 conv_if(XPORT, GF_XPORT);
233 conv_if(SHIFT, GF_SHIFT);
238 enum gfx_if_en if_conv(
242 conv_if(PNG, IF_PNG);
243 conv_if(SVG, IF_SVG);
244 conv_if(EPS, IF_EPS);
245 conv_if(PDF, IF_PDF);
250 enum tmt_en tmt_conv(
254 conv_if(SECOND, TMT_SECOND);
255 conv_if(MINUTE, TMT_MINUTE);
256 conv_if(HOUR, TMT_HOUR);
257 conv_if(DAY, TMT_DAY);
258 conv_if(WEEK, TMT_WEEK);
259 conv_if(MONTH, TMT_MONTH);
260 conv_if(YEAR, TMT_YEAR);
264 enum grc_en grc_conv(
268 conv_if(BACK, GRC_BACK);
269 conv_if(CANVAS, GRC_CANVAS);
270 conv_if(SHADEA, GRC_SHADEA);
271 conv_if(SHADEB, GRC_SHADEB);
272 conv_if(GRID, GRC_GRID);
273 conv_if(MGRID, GRC_MGRID);
274 conv_if(FONT, GRC_FONT);
275 conv_if(ARROW, GRC_ARROW);
276 conv_if(AXIS, GRC_AXIS);
277 conv_if(FRAME, GRC_FRAME);
282 enum text_prop_en text_prop_conv(
286 conv_if(DEFAULT, TEXT_PROP_DEFAULT);
287 conv_if(TITLE, TEXT_PROP_TITLE);
288 conv_if(AXIS, TEXT_PROP_AXIS);
289 conv_if(UNIT, TEXT_PROP_UNIT);
290 conv_if(LEGEND, TEXT_PROP_LEGEND);
301 cairo_status_t status = 0;
305 for (i = 0; i < (unsigned) im->gdes_c; i++) {
306 if (im->gdes[i].data_first) {
307 /* careful here, because a single pointer can occur several times */
308 free(im->gdes[i].data);
309 if (im->gdes[i].ds_namv) {
310 for (ii = 0; ii < im->gdes[i].ds_cnt; ii++)
311 free(im->gdes[i].ds_namv[ii]);
312 free(im->gdes[i].ds_namv);
315 /* free allocated memory used for dashed lines */
316 if (im->gdes[i].p_dashes != NULL)
317 free(im->gdes[i].p_dashes);
319 free(im->gdes[i].p_data);
320 free(im->gdes[i].rpnp);
323 if (im->font_options)
324 cairo_font_options_destroy(im->font_options);
327 status = cairo_status(im->cr);
328 cairo_destroy(im->cr);
330 if (im->rendered_image) {
331 free(im->rendered_image);
334 cairo_surface_destroy(im->surface);
336 fprintf(stderr, "OOPS: Cairo has issues it can't even die: %s\n",
337 cairo_status_to_string(status));
342 /* find SI magnitude symbol for the given number*/
344 image_desc_t *im, /* image description */
350 char *symbol[] = { "a", /* 10e-18 Atto */
351 "f", /* 10e-15 Femto */
352 "p", /* 10e-12 Pico */
353 "n", /* 10e-9 Nano */
354 "u", /* 10e-6 Micro */
355 "m", /* 10e-3 Milli */
360 "T", /* 10e12 Tera */
361 "P", /* 10e15 Peta */
368 if (*value == 0.0 || isnan(*value)) {
372 sindex = floor(log(fabs(*value)) / log((double) im->base));
373 *magfact = pow((double) im->base, (double) sindex);
374 (*value) /= (*magfact);
376 if (sindex <= symbcenter && sindex >= -symbcenter) {
377 (*symb_ptr) = symbol[sindex + symbcenter];
384 static char si_symbol[] = {
385 'a', /* 10e-18 Atto */
386 'f', /* 10e-15 Femto */
387 'p', /* 10e-12 Pico */
388 'n', /* 10e-9 Nano */
389 'u', /* 10e-6 Micro */
390 'm', /* 10e-3 Milli */
395 'T', /* 10e12 Tera */
396 'P', /* 10e15 Peta */
399 static const int si_symbcenter = 6;
401 /* find SI magnitude symbol for the numbers on the y-axis*/
403 image_desc_t *im /* image description */
407 double digits, viewdigits = 0;
410 floor(log(max(fabs(im->minval), fabs(im->maxval))) /
411 log((double) im->base));
413 if (im->unitsexponent != 9999) {
414 /* unitsexponent = 9, 6, 3, 0, -3, -6, -9, etc */
415 viewdigits = floor(im->unitsexponent / 3);
420 im->magfact = pow((double) im->base, digits);
423 printf("digits %6.3f im->magfact %6.3f\n", digits, im->magfact);
426 im->viewfactor = im->magfact / pow((double) im->base, viewdigits);
428 if (((viewdigits + si_symbcenter) < sizeof(si_symbol)) &&
429 ((viewdigits + si_symbcenter) >= 0))
430 im->symbol = si_symbol[(int) viewdigits + si_symbcenter];
435 /* move min and max values around to become sensible */
440 double sensiblevalues[] = { 1000.0, 900.0, 800.0, 750.0, 700.0,
441 600.0, 500.0, 400.0, 300.0, 250.0,
442 200.0, 125.0, 100.0, 90.0, 80.0,
443 75.0, 70.0, 60.0, 50.0, 40.0, 30.0,
444 25.0, 20.0, 10.0, 9.0, 8.0,
445 7.0, 6.0, 5.0, 4.0, 3.5, 3.0,
446 2.5, 2.0, 1.8, 1.5, 1.2, 1.0,
447 0.8, 0.7, 0.6, 0.5, 0.4, 0.3, 0.2, 0.1, 0.0, -1
450 double scaled_min, scaled_max;
457 printf("Min: %6.2f Max: %6.2f MagFactor: %6.2f\n",
458 im->minval, im->maxval, im->magfact);
461 if (isnan(im->ygridstep)) {
462 if (im->extra_flags & ALTAUTOSCALE) {
463 /* measure the amplitude of the function. Make sure that
464 graph boundaries are slightly higher then max/min vals
465 so we can see amplitude on the graph */
468 delt = im->maxval - im->minval;
470 fact = 2.0 * pow(10.0,
472 (max(fabs(im->minval), fabs(im->maxval)) /
475 adj = (fact - delt) * 0.55;
478 ("Min: %6.2f Max: %6.2f delt: %6.2f fact: %6.2f adj: %6.2f\n",
479 im->minval, im->maxval, delt, fact, adj);
484 } else if (im->extra_flags & ALTAUTOSCALE_MIN) {
485 /* measure the amplitude of the function. Make sure that
486 graph boundaries are slightly lower than min vals
487 so we can see amplitude on the graph */
488 adj = (im->maxval - im->minval) * 0.1;
490 } else if (im->extra_flags & ALTAUTOSCALE_MAX) {
491 /* measure the amplitude of the function. Make sure that
492 graph boundaries are slightly higher than max vals
493 so we can see amplitude on the graph */
494 adj = (im->maxval - im->minval) * 0.1;
497 scaled_min = im->minval / im->magfact;
498 scaled_max = im->maxval / im->magfact;
500 for (i = 1; sensiblevalues[i] > 0; i++) {
501 if (sensiblevalues[i - 1] >= scaled_min &&
502 sensiblevalues[i] <= scaled_min)
503 im->minval = sensiblevalues[i] * (im->magfact);
505 if (-sensiblevalues[i - 1] <= scaled_min &&
506 -sensiblevalues[i] >= scaled_min)
507 im->minval = -sensiblevalues[i - 1] * (im->magfact);
509 if (sensiblevalues[i - 1] >= scaled_max &&
510 sensiblevalues[i] <= scaled_max)
511 im->maxval = sensiblevalues[i - 1] * (im->magfact);
513 if (-sensiblevalues[i - 1] <= scaled_max &&
514 -sensiblevalues[i] >= scaled_max)
515 im->maxval = -sensiblevalues[i] * (im->magfact);
519 /* adjust min and max to the grid definition if there is one */
520 im->minval = (double) im->ylabfact * im->ygridstep *
521 floor(im->minval / ((double) im->ylabfact * im->ygridstep));
522 im->maxval = (double) im->ylabfact * im->ygridstep *
523 ceil(im->maxval / ((double) im->ylabfact * im->ygridstep));
527 fprintf(stderr, "SCALED Min: %6.2f Max: %6.2f Factor: %6.2f\n",
528 im->minval, im->maxval, im->magfact);
536 if (isnan(im->minval) || isnan(im->maxval))
539 if (im->logarithmic) {
540 double ya, yb, ypix, ypixfrac;
541 double log10_range = log10(im->maxval) - log10(im->minval);
543 ya = pow((double) 10, floor(log10(im->minval)));
544 while (ya < im->minval)
547 return; /* don't have y=10^x gridline */
549 if (yb <= im->maxval) {
550 /* we have at least 2 y=10^x gridlines.
551 Make sure distance between them in pixels
552 are an integer by expanding im->maxval */
553 double y_pixel_delta = ytr(im, ya) - ytr(im, yb);
554 double factor = y_pixel_delta / floor(y_pixel_delta);
555 double new_log10_range = factor * log10_range;
556 double new_ymax_log10 = log10(im->minval) + new_log10_range;
558 im->maxval = pow(10, new_ymax_log10);
559 ytr(im, DNAN); /* reset precalc */
560 log10_range = log10(im->maxval) - log10(im->minval);
562 /* make sure first y=10^x gridline is located on
563 integer pixel position by moving scale slightly
564 downwards (sub-pixel movement) */
565 ypix = ytr(im, ya) + im->ysize; /* add im->ysize so it always is positive */
566 ypixfrac = ypix - floor(ypix);
567 if (ypixfrac > 0 && ypixfrac < 1) {
568 double yfrac = ypixfrac / im->ysize;
570 im->minval = pow(10, log10(im->minval) - yfrac * log10_range);
571 im->maxval = pow(10, log10(im->maxval) - yfrac * log10_range);
572 ytr(im, DNAN); /* reset precalc */
575 /* Make sure we have an integer pixel distance between
576 each minor gridline */
577 double ypos1 = ytr(im, im->minval);
578 double ypos2 = ytr(im, im->minval + im->ygrid_scale.gridstep);
579 double y_pixel_delta = ypos1 - ypos2;
580 double factor = y_pixel_delta / floor(y_pixel_delta);
581 double new_range = factor * (im->maxval - im->minval);
582 double gridstep = im->ygrid_scale.gridstep;
583 double minor_y, minor_y_px, minor_y_px_frac;
585 if (im->maxval > 0.0)
586 im->maxval = im->minval + new_range;
588 im->minval = im->maxval - new_range;
589 ytr(im, DNAN); /* reset precalc */
590 /* make sure first minor gridline is on integer pixel y coord */
591 minor_y = gridstep * floor(im->minval / gridstep);
592 while (minor_y < im->minval)
594 minor_y_px = ytr(im, minor_y) + im->ysize; /* ensure > 0 by adding ysize */
595 minor_y_px_frac = minor_y_px - floor(minor_y_px);
596 if (minor_y_px_frac > 0 && minor_y_px_frac < 1) {
597 double yfrac = minor_y_px_frac / im->ysize;
598 double range = im->maxval - im->minval;
600 im->minval = im->minval - yfrac * range;
601 im->maxval = im->maxval - yfrac * range;
602 ytr(im, DNAN); /* reset precalc */
604 calc_horizontal_grid(im); /* recalc with changed im->maxval */
608 /* reduce data reimplementation by Alex */
611 enum cf_en cf, /* which consolidation function ? */
612 unsigned long cur_step, /* step the data currently is in */
613 time_t *start, /* start, end and step as requested ... */
614 time_t *end, /* ... by the application will be ... */
615 unsigned long *step, /* ... adjusted to represent reality */
616 unsigned long *ds_cnt, /* number of data sources in file */
618 { /* two dimensional array containing the data */
619 int i, reduce_factor = ceil((double) (*step) / (double) cur_step);
620 unsigned long col, dst_row, row_cnt, start_offset, end_offset, skiprows =
622 rrd_value_t *srcptr, *dstptr;
624 (*step) = cur_step * reduce_factor; /* set new step size for reduced data */
627 row_cnt = ((*end) - (*start)) / cur_step;
633 printf("Reducing %lu rows with factor %i time %lu to %lu, step %lu\n",
634 row_cnt, reduce_factor, *start, *end, cur_step);
635 for (col = 0; col < row_cnt; col++) {
636 printf("time %10lu: ", *start + (col + 1) * cur_step);
637 for (i = 0; i < *ds_cnt; i++)
638 printf(" %8.2e", srcptr[*ds_cnt * col + i]);
643 /* We have to combine [reduce_factor] rows of the source
644 ** into one row for the destination. Doing this we also
645 ** need to take care to combine the correct rows. First
646 ** alter the start and end time so that they are multiples
647 ** of the new step time. We cannot reduce the amount of
648 ** time so we have to move the end towards the future and
649 ** the start towards the past.
651 end_offset = (*end) % (*step);
652 start_offset = (*start) % (*step);
654 /* If there is a start offset (which cannot be more than
655 ** one destination row), skip the appropriate number of
656 ** source rows and one destination row. The appropriate
657 ** number is what we do know (start_offset/cur_step) of
658 ** the new interval (*step/cur_step aka reduce_factor).
661 printf("start_offset: %lu end_offset: %lu\n", start_offset, end_offset);
662 printf("row_cnt before: %lu\n", row_cnt);
665 (*start) = (*start) - start_offset;
666 skiprows = reduce_factor - start_offset / cur_step;
667 srcptr += skiprows * *ds_cnt;
668 for (col = 0; col < (*ds_cnt); col++)
673 printf("row_cnt between: %lu\n", row_cnt);
676 /* At the end we have some rows that are not going to be
677 ** used, the amount is end_offset/cur_step
680 (*end) = (*end) - end_offset + (*step);
681 skiprows = end_offset / cur_step;
685 printf("row_cnt after: %lu\n", row_cnt);
688 /* Sanity check: row_cnt should be multiple of reduce_factor */
689 /* if this gets triggered, something is REALLY WRONG ... we die immediately */
691 if (row_cnt % reduce_factor) {
692 printf("SANITY CHECK: %lu rows cannot be reduced by %i \n",
693 row_cnt, reduce_factor);
694 printf("BUG in reduce_data()\n");
698 /* Now combine reduce_factor intervals at a time
699 ** into one interval for the destination.
702 for (dst_row = 0; (long int) row_cnt >= reduce_factor; dst_row++) {
703 for (col = 0; col < (*ds_cnt); col++) {
704 rrd_value_t newval = DNAN;
705 unsigned long validval = 0;
707 for (i = 0; i < reduce_factor; i++) {
708 if (isnan(srcptr[i * (*ds_cnt) + col])) {
713 newval = srcptr[i * (*ds_cnt) + col];
722 newval += srcptr[i * (*ds_cnt) + col];
725 newval = min(newval, srcptr[i * (*ds_cnt) + col]);
728 /* an interval contains a failure if any subintervals contained a failure */
730 newval = max(newval, srcptr[i * (*ds_cnt) + col]);
733 newval = srcptr[i * (*ds_cnt) + col];
759 srcptr += (*ds_cnt) * reduce_factor;
760 row_cnt -= reduce_factor;
762 /* If we had to alter the endtime, we didn't have enough
763 ** source rows to fill the last row. Fill it with NaN.
766 for (col = 0; col < (*ds_cnt); col++)
769 row_cnt = ((*end) - (*start)) / *step;
771 printf("Done reducing. Currently %lu rows, time %lu to %lu, step %lu\n",
772 row_cnt, *start, *end, *step);
773 for (col = 0; col < row_cnt; col++) {
774 printf("time %10lu: ", *start + (col + 1) * (*step));
775 for (i = 0; i < *ds_cnt; i++)
776 printf(" %8.2e", srcptr[*ds_cnt * col + i]);
783 /* get the data required for the graphs from the
792 /* pull the data from the rrd files ... */
793 for (i = 0; i < (int) im->gdes_c; i++) {
794 /* only GF_DEF elements fetch data */
795 if (im->gdes[i].gf != GF_DEF)
799 /* do we have it already ? */
800 for (ii = 0; ii < i; ii++) {
801 if (im->gdes[ii].gf != GF_DEF)
803 if ((strcmp(im->gdes[i].rrd, im->gdes[ii].rrd) == 0)
804 && (im->gdes[i].cf == im->gdes[ii].cf)
805 && (im->gdes[i].cf_reduce == im->gdes[ii].cf_reduce)
806 && (im->gdes[i].start_orig == im->gdes[ii].start_orig)
807 && (im->gdes[i].end_orig == im->gdes[ii].end_orig)
808 && (im->gdes[i].step_orig == im->gdes[ii].step_orig)) {
809 /* OK, the data is already there.
810 ** Just copy the header portion
812 im->gdes[i].start = im->gdes[ii].start;
813 im->gdes[i].end = im->gdes[ii].end;
814 im->gdes[i].step = im->gdes[ii].step;
815 im->gdes[i].ds_cnt = im->gdes[ii].ds_cnt;
816 im->gdes[i].ds_namv = im->gdes[ii].ds_namv;
817 im->gdes[i].data = im->gdes[ii].data;
818 im->gdes[i].data_first = 0;
825 unsigned long ft_step = im->gdes[i].step; /* ft_step will record what we got from fetch */
827 if ((rrd_fetch_fn(im->gdes[i].rrd,
833 &im->gdes[i].ds_namv,
834 &im->gdes[i].data)) == -1) {
837 im->gdes[i].data_first = 1;
839 if (ft_step < im->gdes[i].step) {
840 reduce_data(im->gdes[i].cf_reduce,
845 &im->gdes[i].ds_cnt, &im->gdes[i].data);
847 im->gdes[i].step = ft_step;
851 /* lets see if the required data source is really there */
852 for (ii = 0; ii < (int) im->gdes[i].ds_cnt; ii++) {
853 if (strcmp(im->gdes[i].ds_namv[ii], im->gdes[i].ds_nam) == 0) {
857 if (im->gdes[i].ds == -1) {
858 rrd_set_error("No DS called '%s' in '%s'",
859 im->gdes[i].ds_nam, im->gdes[i].rrd);
867 /* evaluate the expressions in the CDEF functions */
869 /*************************************************************
871 *************************************************************/
873 long find_var_wrapper(
877 return find_var((image_desc_t *) arg1, key);
880 /* find gdes containing var*/
887 for (ii = 0; ii < im->gdes_c - 1; ii++) {
888 if ((im->gdes[ii].gf == GF_DEF
889 || im->gdes[ii].gf == GF_VDEF || im->gdes[ii].gf == GF_CDEF)
890 && (strcmp(im->gdes[ii].vname, key) == 0)) {
897 /* find the largest common denominator for all the numbers
898 in the 0 terminated num array */
905 for (i = 0; num[i + 1] != 0; i++) {
907 rest = num[i] % num[i + 1];
913 /* return i==0?num[i]:num[i-1]; */
917 /* run the rpn calculator on all the VDEF and CDEF arguments */
924 long *steparray, rpi;
929 rpnstack_init(&rpnstack);
931 for (gdi = 0; gdi < im->gdes_c; gdi++) {
932 /* Look for GF_VDEF and GF_CDEF in the same loop,
933 * so CDEFs can use VDEFs and vice versa
935 switch (im->gdes[gdi].gf) {
939 graph_desc_t *vdp = &im->gdes[im->gdes[gdi].vidx];
941 /* remove current shift */
942 vdp->start -= vdp->shift;
943 vdp->end -= vdp->shift;
946 if (im->gdes[gdi].shidx >= 0)
947 vdp->shift = im->gdes[im->gdes[gdi].shidx].vf.val;
950 vdp->shift = im->gdes[gdi].shval;
952 /* normalize shift to multiple of consolidated step */
953 vdp->shift = (vdp->shift / (long) vdp->step) * (long) vdp->step;
956 vdp->start += vdp->shift;
957 vdp->end += vdp->shift;
961 /* A VDEF has no DS. This also signals other parts
962 * of rrdtool that this is a VDEF value, not a CDEF.
964 im->gdes[gdi].ds_cnt = 0;
965 if (vdef_calc(im, gdi)) {
966 rrd_set_error("Error processing VDEF '%s'",
967 im->gdes[gdi].vname);
968 rpnstack_free(&rpnstack);
973 im->gdes[gdi].ds_cnt = 1;
974 im->gdes[gdi].ds = 0;
975 im->gdes[gdi].data_first = 1;
976 im->gdes[gdi].start = 0;
977 im->gdes[gdi].end = 0;
982 /* Find the variables in the expression.
983 * - VDEF variables are substituted by their values
984 * and the opcode is changed into OP_NUMBER.
985 * - CDEF variables are analized for their step size,
986 * the lowest common denominator of all the step
987 * sizes of the data sources involved is calculated
988 * and the resulting number is the step size for the
989 * resulting data source.
991 for (rpi = 0; im->gdes[gdi].rpnp[rpi].op != OP_END; rpi++) {
992 if (im->gdes[gdi].rpnp[rpi].op == OP_VARIABLE ||
993 im->gdes[gdi].rpnp[rpi].op == OP_PREV_OTHER) {
994 long ptr = im->gdes[gdi].rpnp[rpi].ptr;
996 if (im->gdes[ptr].ds_cnt == 0) { /* this is a VDEF data source */
999 ("DEBUG: inside CDEF '%s' processing VDEF '%s'\n",
1000 im->gdes[gdi].vname, im->gdes[ptr].vname);
1001 printf("DEBUG: value from vdef is %f\n",
1002 im->gdes[ptr].vf.val);
1004 im->gdes[gdi].rpnp[rpi].val = im->gdes[ptr].vf.val;
1005 im->gdes[gdi].rpnp[rpi].op = OP_NUMBER;
1006 } else { /* normal variables and PREF(variables) */
1008 /* add one entry to the array that keeps track of the step sizes of the
1009 * data sources going into the CDEF. */
1011 rrd_realloc(steparray,
1013 1) * sizeof(*steparray))) == NULL) {
1014 rrd_set_error("realloc steparray");
1015 rpnstack_free(&rpnstack);
1019 steparray[stepcnt - 1] = im->gdes[ptr].step;
1021 /* adjust start and end of cdef (gdi) so
1022 * that it runs from the latest start point
1023 * to the earliest endpoint of any of the
1024 * rras involved (ptr)
1027 if (im->gdes[gdi].start < im->gdes[ptr].start)
1028 im->gdes[gdi].start = im->gdes[ptr].start;
1030 if (im->gdes[gdi].end == 0 ||
1031 im->gdes[gdi].end > im->gdes[ptr].end)
1032 im->gdes[gdi].end = im->gdes[ptr].end;
1034 /* store pointer to the first element of
1035 * the rra providing data for variable,
1036 * further save step size and data source
1039 im->gdes[gdi].rpnp[rpi].data =
1040 im->gdes[ptr].data + im->gdes[ptr].ds;
1041 im->gdes[gdi].rpnp[rpi].step = im->gdes[ptr].step;
1042 im->gdes[gdi].rpnp[rpi].ds_cnt = im->gdes[ptr].ds_cnt;
1044 /* backoff the *.data ptr; this is done so
1045 * rpncalc() function doesn't have to treat
1046 * the first case differently
1048 } /* if ds_cnt != 0 */
1049 } /* if OP_VARIABLE */
1050 } /* loop through all rpi */
1052 /* move the data pointers to the correct period */
1053 for (rpi = 0; im->gdes[gdi].rpnp[rpi].op != OP_END; rpi++) {
1054 if (im->gdes[gdi].rpnp[rpi].op == OP_VARIABLE ||
1055 im->gdes[gdi].rpnp[rpi].op == OP_PREV_OTHER) {
1056 long ptr = im->gdes[gdi].rpnp[rpi].ptr;
1058 im->gdes[gdi].start - im->gdes[ptr].start;
1061 im->gdes[gdi].rpnp[rpi].data +=
1062 (diff / im->gdes[ptr].step) *
1063 im->gdes[ptr].ds_cnt;
1067 if (steparray == NULL) {
1068 rrd_set_error("rpn expressions without DEF"
1069 " or CDEF variables are not supported");
1070 rpnstack_free(&rpnstack);
1073 steparray[stepcnt] = 0;
1074 /* Now find the resulting step. All steps in all
1075 * used RRAs have to be visited
1077 im->gdes[gdi].step = lcd(steparray);
1079 if ((im->gdes[gdi].data = malloc(((im->gdes[gdi].end -
1080 im->gdes[gdi].start)
1081 / im->gdes[gdi].step)
1082 * sizeof(double))) == NULL) {
1083 rrd_set_error("malloc im->gdes[gdi].data");
1084 rpnstack_free(&rpnstack);
1088 /* Step through the new cdef results array and
1089 * calculate the values
1091 for (now = im->gdes[gdi].start + im->gdes[gdi].step;
1092 now <= im->gdes[gdi].end; now += im->gdes[gdi].step) {
1093 rpnp_t *rpnp = im->gdes[gdi].rpnp;
1095 /* 3rd arg of rpn_calc is for OP_VARIABLE lookups;
1096 * in this case we are advancing by timesteps;
1097 * we use the fact that time_t is a synonym for long
1099 if (rpn_calc(rpnp, &rpnstack, (long) now,
1100 im->gdes[gdi].data, ++dataidx) == -1) {
1101 /* rpn_calc sets the error string */
1102 rpnstack_free(&rpnstack);
1105 } /* enumerate over time steps within a CDEF */
1110 } /* enumerate over CDEFs */
1111 rpnstack_free(&rpnstack);
1115 /* from http://www.cygnus-software.com/papers/comparingfloats/comparingfloats.htm */
1116 /* yes we are loosing precision by doing tos with floats instead of doubles
1117 but it seems more stable this way. */
1119 static int AlmostEqual2sComplement(
1125 int aInt = *(int *) &A;
1126 int bInt = *(int *) &B;
1129 /* Make sure maxUlps is non-negative and small enough that the
1130 default NAN won't compare as equal to anything. */
1132 /* assert(maxUlps > 0 && maxUlps < 4 * 1024 * 1024); */
1134 /* Make aInt lexicographically ordered as a twos-complement int */
1137 aInt = 0x80000000l - aInt;
1139 /* Make bInt lexicographically ordered as a twos-complement int */
1142 bInt = 0x80000000l - bInt;
1144 intDiff = abs(aInt - bInt);
1146 if (intDiff <= maxUlps)
1152 /* massage data so, that we get one value for each x coordinate in the graph */
1157 double pixstep = (double) (im->end - im->start)
1158 / (double) im->xsize; /* how much time
1159 passes in one pixel */
1161 double minval = DNAN, maxval = DNAN;
1163 unsigned long gr_time;
1165 /* memory for the processed data */
1166 for (i = 0; i < im->gdes_c; i++) {
1167 if ((im->gdes[i].gf == GF_LINE) ||
1168 (im->gdes[i].gf == GF_AREA) || (im->gdes[i].gf == GF_TICK)) {
1169 if ((im->gdes[i].p_data = malloc((im->xsize + 1)
1170 * sizeof(rrd_value_t))) == NULL) {
1171 rrd_set_error("malloc data_proc");
1177 for (i = 0; i < im->xsize; i++) { /* for each pixel */
1180 gr_time = im->start + pixstep * i; /* time of the current step */
1183 for (ii = 0; ii < im->gdes_c; ii++) {
1186 switch (im->gdes[ii].gf) {
1190 if (!im->gdes[ii].stack)
1192 value = im->gdes[ii].yrule;
1193 if (isnan(value) || (im->gdes[ii].gf == GF_TICK)) {
1194 /* The time of the data doesn't necessarily match
1195 ** the time of the graph. Beware.
1197 vidx = im->gdes[ii].vidx;
1198 if (im->gdes[vidx].gf == GF_VDEF) {
1199 value = im->gdes[vidx].vf.val;
1201 if (((long int) gr_time >=
1202 (long int) im->gdes[vidx].start)
1203 && ((long int) gr_time <=
1204 (long int) im->gdes[vidx].end)) {
1205 value = im->gdes[vidx].data[(unsigned long)
1211 im->gdes[vidx].step)
1212 * im->gdes[vidx].ds_cnt +
1219 if (!isnan(value)) {
1221 im->gdes[ii].p_data[i] = paintval;
1222 /* GF_TICK: the data values are not
1223 ** relevant for min and max
1225 if (finite(paintval) && im->gdes[ii].gf != GF_TICK) {
1226 if ((isnan(minval) || paintval < minval) &&
1227 !(im->logarithmic && paintval <= 0.0))
1229 if (isnan(maxval) || paintval > maxval)
1233 im->gdes[ii].p_data[i] = DNAN;
1238 ("STACK should already be turned into LINE or AREA here");
1247 /* if min or max have not been asigned a value this is because
1248 there was no data in the graph ... this is not good ...
1249 lets set these to dummy values then ... */
1251 if (im->logarithmic) {
1252 if (isnan(minval) || isnan(maxval) || maxval <= 0) {
1253 minval = 0.0; /* catching this right away below */
1256 /* in logarithm mode, where minval is smaller or equal
1257 to 0 make the beast just way smaller than maxval */
1259 minval = maxval / 10e8;
1262 if (isnan(minval) || isnan(maxval)) {
1268 /* adjust min and max values given by the user */
1269 /* for logscale we add something on top */
1270 if (isnan(im->minval)
1271 || ((!im->rigid) && im->minval > minval)
1273 if (im->logarithmic)
1274 im->minval = minval / 2.0;
1276 im->minval = minval;
1278 if (isnan(im->maxval)
1279 || (!im->rigid && im->maxval < maxval)
1281 if (im->logarithmic)
1282 im->maxval = maxval * 2.0;
1284 im->maxval = maxval;
1287 /* make sure min is smaller than max */
1288 if (im->minval > im->maxval) {
1290 im->minval = 0.99 * im->maxval;
1292 im->minval = 1.01 * im->maxval;
1295 /* make sure min and max are not equal */
1296 if (AlmostEqual2sComplement(im->minval, im->maxval, 4)) {
1302 /* make sure min and max are not both zero */
1303 if (AlmostEqual2sComplement(im->maxval, 0, 4)) {
1312 /* identify the point where the first gridline, label ... gets placed */
1314 time_t find_first_time(
1315 time_t start, /* what is the initial time */
1316 enum tmt_en baseint, /* what is the basic interval */
1317 long basestep /* how many if these do we jump a time */
1322 localtime_r(&start, &tm);
1326 tm. tm_sec -= tm.tm_sec % basestep;
1331 tm. tm_min -= tm.tm_min % basestep;
1337 tm. tm_hour -= tm.tm_hour % basestep;
1341 /* we do NOT look at the basestep for this ... */
1348 /* we do NOT look at the basestep for this ... */
1352 tm. tm_mday -= tm.tm_wday - 1; /* -1 because we want the monday */
1354 if (tm.tm_wday == 0)
1355 tm. tm_mday -= 7; /* we want the *previous* monday */
1363 tm. tm_mon -= tm.tm_mon % basestep;
1374 tm.tm_year + 1900) %basestep;
1380 /* identify the point where the next gridline, label ... gets placed */
1381 time_t find_next_time(
1382 time_t current, /* what is the initial time */
1383 enum tmt_en baseint, /* what is the basic interval */
1384 long basestep /* how many if these do we jump a time */
1390 localtime_r(¤t, &tm);
1395 tm. tm_sec += basestep;
1399 tm. tm_min += basestep;
1403 tm. tm_hour += basestep;
1407 tm. tm_mday += basestep;
1411 tm. tm_mday += 7 * basestep;
1415 tm. tm_mon += basestep;
1419 tm. tm_year += basestep;
1421 madetime = mktime(&tm);
1422 } while (madetime == -1); /* this is necessary to skip impssible times
1423 like the daylight saving time skips */
1429 /* calculate values required for PRINT and GPRINT functions */
1434 long i, ii, validsteps;
1437 int graphelement = 0;
1440 double magfact = -1;
1445 /* wow initializing tmvdef is quite a task :-) */
1446 time_t now = time(NULL);
1448 localtime_r(&now, &tmvdef);
1449 for (i = 0; i < im->gdes_c; i++) {
1450 vidx = im->gdes[i].vidx;
1451 switch (im->gdes[i].gf) {
1454 /* PRINT and GPRINT can now print VDEF generated values.
1455 * There's no need to do any calculations on them as these
1456 * calculations were already made.
1458 if (im->gdes[vidx].gf == GF_VDEF) { /* simply use vals */
1459 printval = im->gdes[vidx].vf.val;
1460 localtime_r(&im->gdes[vidx].vf.when, &tmvdef);
1461 } else { /* need to calculate max,min,avg etcetera */
1462 max_ii = ((im->gdes[vidx].end - im->gdes[vidx].start)
1463 / im->gdes[vidx].step * im->gdes[vidx].ds_cnt);
1466 for (ii = im->gdes[vidx].ds;
1467 ii < max_ii; ii += im->gdes[vidx].ds_cnt) {
1468 if (!finite(im->gdes[vidx].data[ii]))
1470 if (isnan(printval)) {
1471 printval = im->gdes[vidx].data[ii];
1476 switch (im->gdes[i].cf) {
1480 case CF_DEVSEASONAL:
1484 printval += im->gdes[vidx].data[ii];
1487 printval = min(printval, im->gdes[vidx].data[ii]);
1491 printval = max(printval, im->gdes[vidx].data[ii]);
1494 printval = im->gdes[vidx].data[ii];
1497 if (im->gdes[i].cf == CF_AVERAGE || im->gdes[i].cf > CF_LAST) {
1498 if (validsteps > 1) {
1499 printval = (printval / validsteps);
1502 } /* prepare printval */
1504 if ((percent_s = strstr(im->gdes[i].format, "%S")) != NULL) {
1505 /* Magfact is set to -1 upon entry to print_calc. If it
1506 * is still less than 0, then we need to run auto_scale.
1507 * Otherwise, put the value into the correct units. If
1508 * the value is 0, then do not set the symbol or magnification
1509 * so next the calculation will be performed again. */
1510 if (magfact < 0.0) {
1511 auto_scale(im, &printval, &si_symb, &magfact);
1512 if (printval == 0.0)
1515 printval /= magfact;
1517 *(++percent_s) = 's';
1518 } else if (strstr(im->gdes[i].format, "%s") != NULL) {
1519 auto_scale(im, &printval, &si_symb, &magfact);
1522 if (im->gdes[i].gf == GF_PRINT) {
1523 rrd_infoval_t prline;
1525 if (im->gdes[i].strftm) {
1526 prline.u_str = malloc((FMT_LEG_LEN + 2) * sizeof(char));
1527 strftime(prline.u_str,
1528 FMT_LEG_LEN, im->gdes[i].format, &tmvdef);
1529 } else if (bad_format(im->gdes[i].format)) {
1531 ("bad format for PRINT in '%s'", im->gdes[i].format);
1535 sprintf_alloc(im->gdes[i].format, printval, si_symb);
1539 ("print[%ld]", prline_cnt++), RD_I_STR, prline);
1544 if (im->gdes[i].strftm) {
1545 strftime(im->gdes[i].legend,
1546 FMT_LEG_LEN, im->gdes[i].format, &tmvdef);
1548 if (bad_format(im->gdes[i].format)) {
1550 ("bad format for GPRINT in '%s'",
1551 im->gdes[i].format);
1554 #ifdef HAVE_SNPRINTF
1555 snprintf(im->gdes[i].legend,
1557 im->gdes[i].format, printval, si_symb);
1559 sprintf(im->gdes[i].legend,
1560 im->gdes[i].format, printval, si_symb);
1572 if (isnan(im->gdes[i].yrule)) { /* we must set this here or the legend printer can not decide to print the legend */
1573 im->gdes[i].yrule = im->gdes[vidx].vf.val;
1578 if (im->gdes[i].xrule == 0) { /* again ... the legend printer needs it */
1579 im->gdes[i].xrule = im->gdes[vidx].vf.when;
1588 #ifdef WITH_PIECHART
1596 ("STACK should already be turned into LINE or AREA here");
1601 return graphelement;
1605 /* place legends with color spots */
1611 int interleg = im->text_prop[TEXT_PROP_LEGEND].size * 2.0;
1612 int border = im->text_prop[TEXT_PROP_LEGEND].size * 2.0;
1613 int fill = 0, fill_last;
1616 int leg_y = im->yimg;
1617 int leg_y_prev = im->yimg;
1620 int i, ii, mark = 0;
1621 char prt_fctn; /*special printfunctions */
1622 char default_txtalign = TXA_JUSTIFIED; /*default line orientation */
1626 if (!(im->extra_flags & NOLEGEND) & !(im->extra_flags & ONLY_GRAPH)) {
1627 if ((legspace = malloc(im->gdes_c * sizeof(int))) == NULL) {
1628 rrd_set_error("malloc for legspace");
1632 if (im->extra_flags & FULL_SIZE_MODE)
1633 leg_y = leg_y_prev =
1634 leg_y - (int) (im->text_prop[TEXT_PROP_LEGEND].size * 1.8);
1635 for (i = 0; i < im->gdes_c; i++) {
1637 /* hide legends for rules which are not displayed */
1638 if (im->gdes[i].gf == GF_TEXTALIGN) {
1639 default_txtalign = im->gdes[i].txtalign;
1642 if (!(im->extra_flags & FORCE_RULES_LEGEND)) {
1643 if (im->gdes[i].gf == GF_HRULE
1644 && (im->gdes[i].yrule <
1645 im->minval || im->gdes[i].yrule > im->maxval))
1646 im->gdes[i].legend[0] = '\0';
1647 if (im->gdes[i].gf == GF_VRULE
1648 && (im->gdes[i].xrule <
1649 im->start || im->gdes[i].xrule > im->end))
1650 im->gdes[i].legend[0] = '\0';
1653 /* turn \\t into tab */
1654 while ((tab = strstr(im->gdes[i].legend, "\\t"))) {
1655 memmove(tab, tab + 1, strlen(tab));
1658 leg_cc = strlen(im->gdes[i].legend);
1659 /* is there a controle code ant the end of the legend string ? */
1660 if (leg_cc >= 2 && im->gdes[i].legend[leg_cc - 2] == '\\') {
1661 prt_fctn = im->gdes[i].legend[leg_cc - 1];
1663 im->gdes[i].legend[leg_cc] = '\0';
1667 /* only valid control codes */
1668 if (prt_fctn != 'l' && prt_fctn != 'n' && /* a synonym for l */
1672 prt_fctn != 's' && prt_fctn != '\0' && prt_fctn != 'g') {
1675 ("Unknown control code at the end of '%s\\%c'",
1676 im->gdes[i].legend, prt_fctn);
1680 if (prt_fctn == 'n') {
1684 /* remove exess space from the end of the legend for \g */
1685 while (prt_fctn == 'g' &&
1686 leg_cc > 0 && im->gdes[i].legend[leg_cc - 1] == ' ') {
1688 im->gdes[i].legend[leg_cc] = '\0';
1693 /* no interleg space if string ends in \g */
1694 legspace[i] = (prt_fctn == 'g' ? 0 : interleg);
1696 fill += legspace[i];
1699 gfx_get_text_width(im,
1709 im->tabwidth, im->gdes[i].legend);
1714 /* who said there was a special tag ... ? */
1715 if (prt_fctn == 'g') {
1719 if (prt_fctn == '\0') {
1720 if (i == im->gdes_c - 1 || fill > im->ximg - 2 * border) {
1721 /* just one legend item is left right or center */
1722 switch (default_txtalign) {
1737 /* is it time to place the legends ? */
1738 if (fill > im->ximg - 2 * border) {
1746 if (leg_c == 1 && prt_fctn == 'j') {
1752 if (prt_fctn != '\0') {
1754 if (leg_c >= 2 && prt_fctn == 'j') {
1755 glue = (im->ximg - fill - 2 * border) / (leg_c - 1);
1759 if (prt_fctn == 'c')
1760 leg_x = (im->ximg - fill) / 2.0;
1761 if (prt_fctn == 'r')
1762 leg_x = im->ximg - fill - border;
1763 for (ii = mark; ii <= i; ii++) {
1764 if (im->gdes[ii].legend[0] == '\0')
1765 continue; /* skip empty legends */
1766 im->gdes[ii].leg_x = leg_x;
1767 im->gdes[ii].leg_y = leg_y;
1769 gfx_get_text_width(im, leg_x,
1778 im->tabwidth, im->gdes[ii].legend)
1783 if (im->extra_flags & FULL_SIZE_MODE) {
1784 /* only add y space if there was text on the line */
1785 if (leg_x > border || prt_fctn == 's')
1786 leg_y -= im->text_prop[TEXT_PROP_LEGEND].size * 1.8;
1787 if (prt_fctn == 's')
1788 leg_y += im->text_prop[TEXT_PROP_LEGEND].size;
1790 if (leg_x > border || prt_fctn == 's')
1791 leg_y += im->text_prop[TEXT_PROP_LEGEND].size * 1.8;
1792 if (prt_fctn == 's')
1793 leg_y -= im->text_prop[TEXT_PROP_LEGEND].size;
1801 if (im->extra_flags & FULL_SIZE_MODE) {
1802 if (leg_y != leg_y_prev) {
1803 *gY = leg_y - im->text_prop[TEXT_PROP_LEGEND].size * 1.8;
1805 leg_y - im->text_prop[TEXT_PROP_LEGEND].size * 1.8;
1809 leg_y - im->text_prop[TEXT_PROP_LEGEND].size * 1.8 +
1817 /* create a grid on the graph. it determines what to do
1818 from the values of xsize, start and end */
1820 /* the xaxis labels are determined from the number of seconds per pixel
1821 in the requested graph */
1823 int calc_horizontal_grid(
1831 int decimals, fractionals;
1833 im->ygrid_scale.labfact = 2;
1834 range = im->maxval - im->minval;
1835 scaledrange = range / im->magfact;
1836 /* does the scale of this graph make it impossible to put lines
1837 on it? If so, give up. */
1838 if (isnan(scaledrange)) {
1842 /* find grid spaceing */
1844 if (isnan(im->ygridstep)) {
1845 if (im->extra_flags & ALTYGRID) {
1846 /* find the value with max number of digits. Get number of digits */
1849 (max(fabs(im->maxval), fabs(im->minval)) *
1850 im->viewfactor / im->magfact));
1851 if (decimals <= 0) /* everything is small. make place for zero */
1853 im->ygrid_scale.gridstep =
1855 floor(log10(range * im->viewfactor / im->magfact))) /
1856 im->viewfactor * im->magfact;
1857 if (im->ygrid_scale.gridstep == 0) /* range is one -> 0.1 is reasonable scale */
1858 im->ygrid_scale.gridstep = 0.1;
1859 /* should have at least 5 lines but no more then 15 */
1860 if (range / im->ygrid_scale.gridstep < 5
1861 && im->ygrid_scale.gridstep >= 30)
1862 im->ygrid_scale.gridstep /= 10;
1863 if (range / im->ygrid_scale.gridstep > 15)
1864 im->ygrid_scale.gridstep *= 10;
1865 if (range / im->ygrid_scale.gridstep > 5) {
1866 im->ygrid_scale.labfact = 1;
1867 if (range / im->ygrid_scale.gridstep > 8
1868 || im->ygrid_scale.gridstep <
1869 1.8 * im->text_prop[TEXT_PROP_AXIS].size)
1870 im->ygrid_scale.labfact = 2;
1872 im->ygrid_scale.gridstep /= 5;
1873 im->ygrid_scale.labfact = 5;
1877 (im->ygrid_scale.gridstep *
1878 (double) im->ygrid_scale.labfact * im->viewfactor /
1880 if (fractionals < 0) { /* small amplitude. */
1881 int len = decimals - fractionals + 1;
1883 if (im->unitslength < len + 2)
1884 im->unitslength = len + 2;
1885 sprintf(im->ygrid_scale.labfmt,
1887 -fractionals, (im->symbol != ' ' ? " %c" : ""));
1889 int len = decimals + 1;
1891 if (im->unitslength < len + 2)
1892 im->unitslength = len + 2;
1893 sprintf(im->ygrid_scale.labfmt,
1894 "%%%d.0f%s", len, (im->symbol != ' ' ? " %c" : ""));
1896 } else { /* classic rrd grid */
1897 for (i = 0; ylab[i].grid > 0; i++) {
1898 pixel = im->ysize / (scaledrange / ylab[i].grid);
1904 for (i = 0; i < 4; i++) {
1905 if (pixel * ylab[gridind].lfac[i] >=
1906 1.8 * im->text_prop[TEXT_PROP_AXIS].size) {
1907 im->ygrid_scale.labfact = ylab[gridind].lfac[i];
1912 im->ygrid_scale.gridstep = ylab[gridind].grid * im->magfact;
1915 im->ygrid_scale.gridstep = im->ygridstep;
1916 im->ygrid_scale.labfact = im->ylabfact;
1921 int draw_horizontal_grid(
1927 char graph_label[100];
1929 double X0 = im->xorigin;
1930 double X1 = im->xorigin + im->xsize;
1931 int sgrid = (int) (im->minval / im->ygrid_scale.gridstep - 1);
1932 int egrid = (int) (im->maxval / im->ygrid_scale.gridstep + 1);
1936 im->ygrid_scale.gridstep /
1937 (double) im->magfact * (double) im->viewfactor;
1938 MaxY = scaledstep * (double) egrid;
1939 for (i = sgrid; i <= egrid; i++) {
1941 im->ygrid_scale.gridstep * i);
1943 im->ygrid_scale.gridstep * (i + 1));
1945 if (floor(Y0 + 0.5) >=
1946 im->yorigin - im->ysize && floor(Y0 + 0.5) <= im->yorigin) {
1947 /* Make sure at least 2 grid labels are shown, even if it doesn't agree
1948 with the chosen settings. Add a label if required by settings, or if
1949 there is only one label so far and the next grid line is out of bounds. */
1950 if (i % im->ygrid_scale.labfact == 0
1952 && (YN < im->yorigin - im->ysize || YN > im->yorigin))) {
1953 if (im->symbol == ' ') {
1954 if (im->extra_flags & ALTYGRID) {
1955 sprintf(graph_label,
1956 im->ygrid_scale.labfmt,
1957 scaledstep * (double) i);
1960 sprintf(graph_label, "%4.1f",
1961 scaledstep * (double) i);
1963 sprintf(graph_label, "%4.0f",
1964 scaledstep * (double) i);
1968 char sisym = (i == 0 ? ' ' : im->symbol);
1970 if (im->extra_flags & ALTYGRID) {
1971 sprintf(graph_label,
1972 im->ygrid_scale.labfmt,
1973 scaledstep * (double) i, sisym);
1976 sprintf(graph_label, "%4.1f %c",
1977 scaledstep * (double) i, sisym);
1979 sprintf(graph_label, "%4.0f %c",
1980 scaledstep * (double) i, sisym);
1988 text_prop[TEXT_PROP_AXIS].
1990 im->graph_col[GRC_FONT],
1992 text_prop[TEXT_PROP_AXIS].
1995 text_prop[TEXT_PROP_AXIS].
1996 size, im->tabwidth, 0.0,
1997 GFX_H_RIGHT, GFX_V_CENTER, graph_label);
1998 gfx_line(im, X0 - 2, Y0, X0, Y0,
1999 MGRIDWIDTH, im->graph_col[GRC_MGRID]);
2000 gfx_line(im, X1, Y0, X1 + 2, Y0,
2001 MGRIDWIDTH, im->graph_col[GRC_MGRID]);
2002 gfx_dashed_line(im, X0 - 2, Y0,
2008 im->grid_dash_on, im->grid_dash_off);
2009 } else if (!(im->extra_flags & NOMINOR)) {
2012 X0, Y0, GRIDWIDTH, im->graph_col[GRC_GRID]);
2013 gfx_line(im, X1, Y0, X1 + 2, Y0,
2014 GRIDWIDTH, im->graph_col[GRC_GRID]);
2015 gfx_dashed_line(im, X0 - 1, Y0,
2019 graph_col[GRC_GRID],
2020 im->grid_dash_on, im->grid_dash_off);
2027 /* this is frexp for base 10 */
2038 iexp = floor(log(fabs(x)) / log(10));
2039 mnt = x / pow(10.0, iexp);
2042 mnt = x / pow(10.0, iexp);
2049 /* logaritmic horizontal grid */
2050 int horizontal_log_grid(
2054 double yloglab[][10] = {
2056 1.0, 10., 0.0, 0.0, 0.0, 0.0, 0.0,
2058 1.0, 5.0, 10., 0.0, 0.0, 0.0, 0.0,
2060 1.0, 2.0, 5.0, 7.0, 10., 0.0, 0.0,
2077 0, 0, 0, 0, 0, 0, 0, 0, 0, 0} /* last line */
2079 int i, j, val_exp, min_exp;
2080 double nex; /* number of decades in data */
2081 double logscale; /* scale in logarithmic space */
2082 int exfrac = 1; /* decade spacing */
2083 int mid = -1; /* row in yloglab for major grid */
2084 double mspac; /* smallest major grid spacing (pixels) */
2085 int flab; /* first value in yloglab to use */
2086 double value, tmp, pre_value;
2088 char graph_label[100];
2090 nex = log10(im->maxval / im->minval);
2091 logscale = im->ysize / nex;
2092 /* major spacing for data with high dynamic range */
2093 while (logscale * exfrac < 3 * im->text_prop[TEXT_PROP_LEGEND].size) {
2100 /* major spacing for less dynamic data */
2102 /* search best row in yloglab */
2104 for (i = 0; yloglab[mid][i + 1] < 10.0; i++);
2105 mspac = logscale * log10(10.0 / yloglab[mid][i]);
2108 2 * im->text_prop[TEXT_PROP_LEGEND].size && yloglab[mid][0] > 0);
2111 /* find first value in yloglab */
2113 yloglab[mid][flab] < 10
2114 && frexp10(im->minval, &tmp) > yloglab[mid][flab]; flab++);
2115 if (yloglab[mid][flab] == 10.0) {
2120 if (val_exp % exfrac)
2121 val_exp += abs(-val_exp % exfrac);
2123 X1 = im->xorigin + im->xsize;
2128 value = yloglab[mid][flab] * pow(10.0, val_exp);
2129 if (AlmostEqual2sComplement(value, pre_value, 4))
2130 break; /* it seems we are not converging */
2132 Y0 = ytr(im, value);
2133 if (floor(Y0 + 0.5) <= im->yorigin - im->ysize)
2135 /* major grid line */
2137 X0 - 2, Y0, X0, Y0, MGRIDWIDTH, im->graph_col[GRC_MGRID]);
2138 gfx_line(im, X1, Y0, X1 + 2, Y0,
2139 MGRIDWIDTH, im->graph_col[GRC_MGRID]);
2140 gfx_dashed_line(im, X0 - 2, Y0,
2145 [GRC_MGRID], im->grid_dash_on, im->grid_dash_off);
2147 if (im->extra_flags & FORCE_UNITS_SI) {
2152 scale = floor(val_exp / 3.0);
2154 pvalue = pow(10.0, val_exp % 3);
2156 pvalue = pow(10.0, ((val_exp + 1) % 3) + 2);
2157 pvalue *= yloglab[mid][flab];
2158 if (((scale + si_symbcenter) < (int) sizeof(si_symbol))
2159 && ((scale + si_symbcenter) >= 0))
2160 symbol = si_symbol[scale + si_symbcenter];
2163 sprintf(graph_label, "%3.0f %c", pvalue, symbol);
2165 sprintf(graph_label, "%3.0e", value);
2169 text_prop[TEXT_PROP_AXIS].
2171 im->graph_col[GRC_FONT],
2173 text_prop[TEXT_PROP_AXIS].
2176 text_prop[TEXT_PROP_AXIS].
2177 size, im->tabwidth, 0.0,
2178 GFX_H_RIGHT, GFX_V_CENTER, graph_label);
2180 if (mid < 4 && exfrac == 1) {
2181 /* find first and last minor line behind current major line
2182 * i is the first line and j tha last */
2184 min_exp = val_exp - 1;
2185 for (i = 1; yloglab[mid][i] < 10.0; i++);
2186 i = yloglab[mid][i - 1] + 1;
2190 i = yloglab[mid][flab - 1] + 1;
2191 j = yloglab[mid][flab];
2194 /* draw minor lines below current major line */
2195 for (; i < j; i++) {
2197 value = i * pow(10.0, min_exp);
2198 if (value < im->minval)
2200 Y0 = ytr(im, value);
2201 if (floor(Y0 + 0.5) <= im->yorigin - im->ysize)
2206 X0, Y0, GRIDWIDTH, im->graph_col[GRC_GRID]);
2207 gfx_line(im, X1, Y0, X1 + 2, Y0,
2208 GRIDWIDTH, im->graph_col[GRC_GRID]);
2209 gfx_dashed_line(im, X0 - 1, Y0,
2213 graph_col[GRC_GRID],
2214 im->grid_dash_on, im->grid_dash_off);
2216 } else if (exfrac > 1) {
2217 for (i = val_exp - exfrac / 3 * 2; i < val_exp; i += exfrac / 3) {
2218 value = pow(10.0, i);
2219 if (value < im->minval)
2221 Y0 = ytr(im, value);
2222 if (floor(Y0 + 0.5) <= im->yorigin - im->ysize)
2227 X0, Y0, GRIDWIDTH, im->graph_col[GRC_GRID]);
2228 gfx_line(im, X1, Y0, X1 + 2, Y0,
2229 GRIDWIDTH, im->graph_col[GRC_GRID]);
2230 gfx_dashed_line(im, X0 - 1, Y0,
2234 graph_col[GRC_GRID],
2235 im->grid_dash_on, im->grid_dash_off);
2240 if (yloglab[mid][++flab] == 10.0) {
2246 /* draw minor lines after highest major line */
2247 if (mid < 4 && exfrac == 1) {
2248 /* find first and last minor line below current major line
2249 * i is the first line and j tha last */
2251 min_exp = val_exp - 1;
2252 for (i = 1; yloglab[mid][i] < 10.0; i++);
2253 i = yloglab[mid][i - 1] + 1;
2257 i = yloglab[mid][flab - 1] + 1;
2258 j = yloglab[mid][flab];
2261 /* draw minor lines below current major line */
2262 for (; i < j; i++) {
2264 value = i * pow(10.0, min_exp);
2265 if (value < im->minval)
2267 Y0 = ytr(im, value);
2268 if (floor(Y0 + 0.5) <= im->yorigin - im->ysize)
2272 X0 - 2, Y0, X0, Y0, GRIDWIDTH, im->graph_col[GRC_GRID]);
2273 gfx_line(im, X1, Y0, X1 + 2, Y0,
2274 GRIDWIDTH, im->graph_col[GRC_GRID]);
2275 gfx_dashed_line(im, X0 - 1, Y0,
2279 graph_col[GRC_GRID],
2280 im->grid_dash_on, im->grid_dash_off);
2283 /* fancy minor gridlines */
2284 else if (exfrac > 1) {
2285 for (i = val_exp - exfrac / 3 * 2; i < val_exp; i += exfrac / 3) {
2286 value = pow(10.0, i);
2287 if (value < im->minval)
2289 Y0 = ytr(im, value);
2290 if (floor(Y0 + 0.5) <= im->yorigin - im->ysize)
2294 X0 - 2, Y0, X0, Y0, GRIDWIDTH, im->graph_col[GRC_GRID]);
2295 gfx_line(im, X1, Y0, X1 + 2, Y0,
2296 GRIDWIDTH, im->graph_col[GRC_GRID]);
2297 gfx_dashed_line(im, X0 - 1, Y0,
2301 graph_col[GRC_GRID],
2302 im->grid_dash_on, im->grid_dash_off);
2313 int xlab_sel; /* which sort of label and grid ? */
2314 time_t ti, tilab, timajor;
2316 char graph_label[100];
2317 double X0, Y0, Y1; /* points for filled graph and more */
2320 /* the type of time grid is determined by finding
2321 the number of seconds per pixel in the graph */
2322 if (im->xlab_user.minsec == -1) {
2323 factor = (im->end - im->start) / im->xsize;
2325 while (xlab[xlab_sel + 1].minsec !=
2326 -1 && xlab[xlab_sel + 1].minsec <= factor) {
2328 } /* pick the last one */
2329 while (xlab[xlab_sel - 1].minsec ==
2330 xlab[xlab_sel].minsec
2331 && xlab[xlab_sel].length > (im->end - im->start)) {
2333 } /* go back to the smallest size */
2334 im->xlab_user.gridtm = xlab[xlab_sel].gridtm;
2335 im->xlab_user.gridst = xlab[xlab_sel].gridst;
2336 im->xlab_user.mgridtm = xlab[xlab_sel].mgridtm;
2337 im->xlab_user.mgridst = xlab[xlab_sel].mgridst;
2338 im->xlab_user.labtm = xlab[xlab_sel].labtm;
2339 im->xlab_user.labst = xlab[xlab_sel].labst;
2340 im->xlab_user.precis = xlab[xlab_sel].precis;
2341 im->xlab_user.stst = xlab[xlab_sel].stst;
2344 /* y coords are the same for every line ... */
2346 Y1 = im->yorigin - im->ysize;
2347 /* paint the minor grid */
2348 if (!(im->extra_flags & NOMINOR)) {
2349 for (ti = find_first_time(im->start,
2357 find_first_time(im->start,
2364 find_next_time(ti, im->xlab_user.gridtm, im->xlab_user.gridst)
2366 /* are we inside the graph ? */
2367 if (ti < im->start || ti > im->end)
2369 while (timajor < ti) {
2370 timajor = find_next_time(timajor,
2373 mgridtm, im->xlab_user.mgridst);
2376 continue; /* skip as falls on major grid line */
2378 gfx_line(im, X0, Y1 - 2, X0, Y1,
2379 GRIDWIDTH, im->graph_col[GRC_GRID]);
2380 gfx_line(im, X0, Y0, X0, Y0 + 2,
2381 GRIDWIDTH, im->graph_col[GRC_GRID]);
2382 gfx_dashed_line(im, X0, Y0 + 1, X0,
2385 graph_col[GRC_GRID],
2386 im->grid_dash_on, im->grid_dash_off);
2390 /* paint the major grid */
2391 for (ti = find_first_time(im->start,
2399 ti = find_next_time(ti, im->xlab_user.mgridtm, im->xlab_user.mgridst)
2401 /* are we inside the graph ? */
2402 if (ti < im->start || ti > im->end)
2405 gfx_line(im, X0, Y1 - 2, X0, Y1,
2406 MGRIDWIDTH, im->graph_col[GRC_MGRID]);
2407 gfx_line(im, X0, Y0, X0, Y0 + 3,
2408 MGRIDWIDTH, im->graph_col[GRC_MGRID]);
2409 gfx_dashed_line(im, X0, Y0 + 3, X0,
2413 [GRC_MGRID], im->grid_dash_on, im->grid_dash_off);
2415 /* paint the labels below the graph */
2417 find_first_time(im->start -
2426 im->xlab_user.precis / 2;
2427 ti = find_next_time(ti, im->xlab_user.labtm, im->xlab_user.labst)
2429 tilab = ti + im->xlab_user.precis / 2; /* correct time for the label */
2430 /* are we inside the graph ? */
2431 if (tilab < im->start || tilab > im->end)
2434 localtime_r(&tilab, &tm);
2435 strftime(graph_label, 99, im->xlab_user.stst, &tm);
2437 # error "your libc has no strftime I guess we'll abort the exercise here."
2442 im->graph_col[GRC_FONT],
2444 text_prop[TEXT_PROP_AXIS].
2447 text_prop[TEXT_PROP_AXIS].
2448 size, im->tabwidth, 0.0,
2449 GFX_H_CENTER, GFX_V_TOP, graph_label);
2458 /* draw x and y axis */
2459 /* gfx_line ( im->canvas, im->xorigin+im->xsize,im->yorigin,
2460 im->xorigin+im->xsize,im->yorigin-im->ysize,
2461 GRIDWIDTH, im->graph_col[GRC_AXIS]);
2463 gfx_line ( im->canvas, im->xorigin,im->yorigin-im->ysize,
2464 im->xorigin+im->xsize,im->yorigin-im->ysize,
2465 GRIDWIDTH, im->graph_col[GRC_AXIS]); */
2467 gfx_line(im, im->xorigin - 4,
2469 im->xorigin + im->xsize +
2470 4, im->yorigin, MGRIDWIDTH, im->graph_col[GRC_AXIS]);
2471 gfx_line(im, im->xorigin,
2474 im->yorigin - im->ysize -
2475 4, MGRIDWIDTH, im->graph_col[GRC_AXIS]);
2476 /* arrow for X and Y axis direction */
2477 gfx_new_area(im, im->xorigin + im->xsize + 2, im->yorigin - 3, im->xorigin + im->xsize + 2, im->yorigin + 3, im->xorigin + im->xsize + 7, im->yorigin, /* horyzontal */
2478 im->graph_col[GRC_ARROW]);
2480 gfx_new_area(im, im->xorigin - 3, im->yorigin - im->ysize - 2, im->xorigin + 3, im->yorigin - im->ysize - 2, im->xorigin, im->yorigin - im->ysize - 7, /* vertical */
2481 im->graph_col[GRC_ARROW]);
2490 double X0, Y0; /* points for filled graph and more */
2491 struct gfx_color_t water_color;
2493 /* draw 3d border */
2494 gfx_new_area(im, 0, im->yimg,
2495 2, im->yimg - 2, 2, 2, im->graph_col[GRC_SHADEA]);
2496 gfx_add_point(im, im->ximg - 2, 2);
2497 gfx_add_point(im, im->ximg, 0);
2498 gfx_add_point(im, 0, 0);
2500 gfx_new_area(im, 2, im->yimg - 2,
2502 im->yimg - 2, im->ximg - 2, 2, im->graph_col[GRC_SHADEB]);
2503 gfx_add_point(im, im->ximg, 0);
2504 gfx_add_point(im, im->ximg, im->yimg);
2505 gfx_add_point(im, 0, im->yimg);
2507 if (im->draw_x_grid == 1)
2509 if (im->draw_y_grid == 1) {
2510 if (im->logarithmic) {
2511 res = horizontal_log_grid(im);
2513 res = draw_horizontal_grid(im);
2516 /* dont draw horizontal grid if there is no min and max val */
2518 char *nodata = "No Data found";
2520 gfx_text(im, im->ximg / 2,
2523 im->graph_col[GRC_FONT],
2525 text_prop[TEXT_PROP_AXIS].
2528 text_prop[TEXT_PROP_AXIS].
2529 size, im->tabwidth, 0.0,
2530 GFX_H_CENTER, GFX_V_CENTER, nodata);
2534 /* yaxis unit description */
2539 im->graph_col[GRC_FONT],
2541 text_prop[TEXT_PROP_UNIT].
2544 text_prop[TEXT_PROP_UNIT].
2546 RRDGRAPH_YLEGEND_ANGLE, GFX_H_CENTER, GFX_V_CENTER, im->ylegend);
2550 im->graph_col[GRC_FONT],
2552 text_prop[TEXT_PROP_TITLE].
2555 text_prop[TEXT_PROP_TITLE].
2556 size, im->tabwidth, 0.0, GFX_H_CENTER, GFX_V_TOP, im->title);
2557 /* rrdtool 'logo' */
2558 water_color = im->graph_col[GRC_FONT];
2559 water_color.alpha = 0.3;
2560 gfx_text(im, im->ximg - 4, 5,
2563 text_prop[TEXT_PROP_AXIS].
2564 font, 5.5, im->tabwidth,
2565 -90, GFX_H_LEFT, GFX_V_TOP, "RRDTOOL / TOBI OETIKER");
2566 /* graph watermark */
2567 if (im->watermark[0] != '\0') {
2569 im->ximg / 2, im->yimg - 6,
2572 text_prop[TEXT_PROP_AXIS].
2573 font, 5.5, im->tabwidth, 0,
2574 GFX_H_CENTER, GFX_V_BOTTOM, im->watermark);
2578 if (!(im->extra_flags & NOLEGEND) & !(im->extra_flags & ONLY_GRAPH)) {
2579 for (i = 0; i < im->gdes_c; i++) {
2580 if (im->gdes[i].legend[0] == '\0')
2582 /* im->gdes[i].leg_y is the bottom of the legend */
2583 X0 = im->gdes[i].leg_x;
2584 Y0 = im->gdes[i].leg_y;
2585 gfx_text(im, X0, Y0,
2586 im->graph_col[GRC_FONT],
2589 [TEXT_PROP_LEGEND].font,
2592 [TEXT_PROP_LEGEND].size,
2594 GFX_H_LEFT, GFX_V_BOTTOM, im->gdes[i].legend);
2595 /* The legend for GRAPH items starts with "M " to have
2596 enough space for the box */
2597 if (im->gdes[i].gf != GF_PRINT &&
2598 im->gdes[i].gf != GF_GPRINT && im->gdes[i].gf != GF_COMMENT) {
2602 boxH = gfx_get_text_width(im, 0,
2610 size, im->tabwidth, "o") * 1.2;
2612 /* shift the box up a bit */
2614 /* make sure transparent colors show up the same way as in the graph */
2617 X0, Y0, X0 + boxH, Y0, im->graph_col[GRC_BACK]);
2618 gfx_add_point(im, X0 + boxH, Y0 - boxV);
2620 gfx_new_area(im, X0, Y0 - boxV, X0,
2621 Y0, X0 + boxH, Y0, im->gdes[i].col);
2622 gfx_add_point(im, X0 + boxH, Y0 - boxV);
2625 cairo_new_path(im->cr);
2626 cairo_set_line_width(im->cr, 1.0);
2629 gfx_line_fit(im, &X0, &Y0);
2630 gfx_line_fit(im, &X1, &Y1);
2631 cairo_move_to(im->cr, X0, Y0);
2632 cairo_line_to(im->cr, X1, Y0);
2633 cairo_line_to(im->cr, X1, Y1);
2634 cairo_line_to(im->cr, X0, Y1);
2635 cairo_close_path(im->cr);
2636 cairo_set_source_rgba(im->cr,
2648 blue, im->graph_col[GRC_FRAME].alpha);
2649 if (im->gdes[i].dash) {
2650 /* make box borders in legend dashed if the graph is dashed */
2654 cairo_set_dash(im->cr, dashes, 1, 0.0);
2656 cairo_stroke(im->cr);
2657 cairo_restore(im->cr);
2664 /*****************************************************
2665 * lazy check make sure we rely need to create this graph
2666 *****************************************************/
2673 struct stat imgstat;
2676 return 0; /* no lazy option */
2677 if (strlen(im->graphfile) == 0)
2678 return 0; /* inmemory option */
2679 if (stat(im->graphfile, &imgstat) != 0)
2680 return 0; /* can't stat */
2681 /* one pixel in the existing graph is more then what we would
2683 if (time(NULL) - imgstat.st_mtime > (im->end - im->start) / im->xsize)
2685 if ((fd = fopen(im->graphfile, "rb")) == NULL)
2686 return 0; /* the file does not exist */
2687 switch (im->imgformat) {
2689 size = PngSize(fd, &(im->ximg), &(im->yimg));
2699 int graph_size_location(
2704 /* The actual size of the image to draw is determined from
2705 ** several sources. The size given on the command line is
2706 ** the graph area but we need more as we have to draw labels
2707 ** and other things outside the graph area
2710 int Xvertical = 0, Ytitle =
2711 0, Xylabel = 0, Xmain = 0, Ymain =
2712 0, Yxlabel = 0, Xspacing = 15, Yspacing = 15, Ywatermark = 4;
2714 if (im->extra_flags & ONLY_GRAPH) {
2716 im->ximg = im->xsize;
2717 im->yimg = im->ysize;
2718 im->yorigin = im->ysize;
2723 /** +---+--------------------------------------------+
2724 ** | y |...............graph title..................|
2725 ** | +---+-------------------------------+--------+
2728 ** | i | a | | pie |
2729 ** | s | x | main graph area | chart |
2734 ** | l | b +-------------------------------+--------+
2735 ** | e | l | x axis labels | |
2736 ** +---+---+-------------------------------+--------+
2737 ** |....................legends.....................|
2738 ** +------------------------------------------------+
2740 ** +------------------------------------------------+
2743 if (im->ylegend[0] != '\0') {
2744 Xvertical = im->text_prop[TEXT_PROP_UNIT].size * 2;
2747 if (im->title[0] != '\0') {
2748 /* The title is placed "inbetween" two text lines so it
2749 ** automatically has some vertical spacing. The horizontal
2750 ** spacing is added here, on each side.
2752 /* if necessary, reduce the font size of the title until it fits the image width */
2753 Ytitle = im->text_prop[TEXT_PROP_TITLE].size * 2.6 + 10;
2757 if (im->draw_x_grid) {
2758 Yxlabel = im->text_prop[TEXT_PROP_AXIS].size * 2.5;
2760 if (im->draw_y_grid || im->forceleftspace) {
2762 gfx_get_text_width(im, 0,
2770 size, im->tabwidth, "0") * im->unitslength;
2774 if (im->extra_flags & FULL_SIZE_MODE) {
2775 /* The actual size of the image to draw has been determined by the user.
2776 ** The graph area is the space remaining after accounting for the legend,
2777 ** the watermark, the pie chart, the axis labels, and the title.
2780 im->ximg = im->xsize;
2781 im->yimg = im->ysize;
2782 im->yorigin = im->ysize;
2785 im->yorigin += Ytitle;
2786 /* Now calculate the total size. Insert some spacing where
2787 desired. im->xorigin and im->yorigin need to correspond
2788 with the lower left corner of the main graph area or, if
2789 this one is not set, the imaginary box surrounding the
2791 /* Initial size calculation for the main graph area */
2792 Xmain = im->ximg - (Xylabel + 2 * Xspacing);
2794 Xmain -= Xspacing; /* put space between main graph area and right edge */
2795 im->xorigin = Xspacing + Xylabel;
2796 /* the length of the title should not influence with width of the graph
2797 if (Xtitle > im->ximg) im->ximg = Xtitle; */
2798 if (Xvertical) { /* unit description */
2800 im->xorigin += Xvertical;
2804 /* The vertical size of the image is known in advance. The main graph area
2805 ** (Ymain) and im->yorigin must be set according to the space requirements
2806 ** of the legend and the axis labels.
2808 if (im->extra_flags & NOLEGEND) {
2809 /* set dimensions correctly if using full size mode with no legend */
2812 im->text_prop[TEXT_PROP_AXIS].size * 2.5 - Yspacing;
2813 Ymain = im->yorigin;
2815 /* Determine where to place the legends onto the image.
2816 ** Set Ymain and adjust im->yorigin to match the space requirements.
2818 if (leg_place(im, &Ymain) == -1)
2823 /* remove title space *or* some padding above the graph from the main graph area */
2827 Ymain -= 1.5 * Yspacing;
2830 /* watermark doesn't seem to effect the vertical size of the main graph area, oh well! */
2831 if (im->watermark[0] != '\0') {
2832 Ymain -= Ywatermark;
2836 } else { /* dimension options -width and -height refer to the dimensions of the main graph area */
2838 /* The actual size of the image to draw is determined from
2839 ** several sources. The size given on the command line is
2840 ** the graph area but we need more as we have to draw labels
2841 ** and other things outside the graph area.
2844 if (im->ylegend[0] != '\0') {
2845 Xvertical = im->text_prop[TEXT_PROP_UNIT].size * 2;
2849 if (im->title[0] != '\0') {
2850 /* The title is placed "inbetween" two text lines so it
2851 ** automatically has some vertical spacing. The horizontal
2852 ** spacing is added here, on each side.
2854 /* don't care for the with of the title
2855 Xtitle = gfx_get_text_width(im->canvas, 0,
2856 im->text_prop[TEXT_PROP_TITLE].font,
2857 im->text_prop[TEXT_PROP_TITLE].size,
2859 im->title, 0) + 2*Xspacing; */
2860 Ytitle = im->text_prop[TEXT_PROP_TITLE].size * 2.6 + 10;
2867 /* Now calculate the total size. Insert some spacing where
2868 desired. im->xorigin and im->yorigin need to correspond
2869 with the lower left corner of the main graph area or, if
2870 this one is not set, the imaginary box surrounding the
2873 /* The legend width cannot yet be determined, as a result we
2874 ** have problems adjusting the image to it. For now, we just
2875 ** forget about it at all; the legend will have to fit in the
2876 ** size already allocated.
2878 im->ximg = Xylabel + Xmain + 2 * Xspacing;
2880 im->ximg += Xspacing;
2881 im->xorigin = Xspacing + Xylabel;
2882 /* the length of the title should not influence with width of the graph
2883 if (Xtitle > im->ximg) im->ximg = Xtitle; */
2884 if (Xvertical) { /* unit description */
2885 im->ximg += Xvertical;
2886 im->xorigin += Xvertical;
2889 /* The vertical size is interesting... we need to compare
2890 ** the sum of {Ytitle, Ymain, Yxlabel, Ylegend, Ywatermark} with
2891 ** Yvertical however we need to know {Ytitle+Ymain+Yxlabel}
2892 ** in order to start even thinking about Ylegend or Ywatermark.
2894 ** Do it in three portions: First calculate the inner part,
2895 ** then do the legend, then adjust the total height of the img,
2896 ** adding space for a watermark if one exists;
2898 /* reserve space for main and/or pie */
2899 im->yimg = Ymain + Yxlabel;
2900 im->yorigin = im->yimg - Yxlabel;
2901 /* reserve space for the title *or* some padding above the graph */
2904 im->yorigin += Ytitle;
2906 im->yimg += 1.5 * Yspacing;
2907 im->yorigin += 1.5 * Yspacing;
2909 /* reserve space for padding below the graph */
2910 im->yimg += Yspacing;
2911 /* Determine where to place the legends onto the image.
2912 ** Adjust im->yimg to match the space requirements.
2914 if (leg_place(im, 0) == -1)
2916 if (im->watermark[0] != '\0') {
2917 im->yimg += Ywatermark;
2925 static cairo_status_t cairo_output(
2929 unsigned int length)
2931 image_desc_t *im = closure;
2933 im->rendered_image =
2934 realloc(im->rendered_image, im->rendered_image_size + length);
2935 if (im->rendered_image == NULL)
2936 return CAIRO_STATUS_WRITE_ERROR;
2937 memcpy(im->rendered_image + im->rendered_image_size, data, length);
2938 im->rendered_image_size += length;
2939 return CAIRO_STATUS_SUCCESS;
2942 /* draw that picture thing ... */
2947 int lazy = lazy_check(im);
2948 double areazero = 0.0;
2949 graph_desc_t *lastgdes = NULL;
2951 PangoFontMap *font_map = pango_cairo_font_map_get_default();
2953 /* if we are lazy and there is nothing to PRINT ... quit now */
2954 if (lazy && im->prt_c == 0) {
2955 info.u_cnt = im->ximg;
2956 grinfo_push(im, sprintf_alloc("image_width"), RD_I_CNT, info);
2957 info.u_cnt = im->yimg;
2958 grinfo_push(im, sprintf_alloc("image_height"), RD_I_CNT, info);
2961 /* pull the data from the rrd files ... */
2962 if (data_fetch(im) == -1)
2964 /* evaluate VDEF and CDEF operations ... */
2965 if (data_calc(im) == -1)
2967 /* calculate and PRINT and GPRINT definitions. We have to do it at
2968 * this point because it will affect the length of the legends
2969 * if there are no graph elements (i==0) we stop here ...
2970 * if we are lazy, try to quit ...
2976 if ((i == 0) || lazy)
2979 /**************************************************************
2980 *** Calculating sizes and locations became a bit confusing ***
2981 *** so I moved this into a separate function. ***
2982 **************************************************************/
2983 if (graph_size_location(im, i) == -1)
2986 info.u_cnt = im->xorigin;
2987 grinfo_push(im, sprintf_alloc("graph_left"), RD_I_CNT, info);
2988 info.u_cnt = im->yorigin - im->ysize;
2989 grinfo_push(im, sprintf_alloc("graph_top"), RD_I_CNT, info);
2990 info.u_cnt = im->xsize;
2991 grinfo_push(im, sprintf_alloc("graph_width"), RD_I_CNT, info);
2992 info.u_cnt = im->ysize;
2993 grinfo_push(im, sprintf_alloc("graph_height"), RD_I_CNT, info);
2994 info.u_cnt = im->ximg;
2995 grinfo_push(im, sprintf_alloc("image_width"), RD_I_CNT, info);
2996 info.u_cnt = im->yimg;
2997 grinfo_push(im, sprintf_alloc("image_height"), RD_I_CNT, info);
2999 /* get actual drawing data and find min and max values */
3000 if (data_proc(im) == -1)
3002 if (!im->logarithmic) {
3006 /* identify si magnitude Kilo, Mega Giga ? */
3007 if (!im->rigid && !im->logarithmic)
3008 expand_range(im); /* make sure the upper and lower limit are
3011 info.u_val = im->minval;
3012 grinfo_push(im, sprintf_alloc("value_min"), RD_I_VAL, info);
3013 info.u_val = im->maxval;
3014 grinfo_push(im, sprintf_alloc("value_max"), RD_I_VAL, info);
3016 if (!calc_horizontal_grid(im))
3021 apply_gridfit(im); */
3022 /* the actual graph is created by going through the individual
3023 graph elements and then drawing them */
3024 cairo_surface_destroy(im->surface);
3025 switch (im->imgformat) {
3028 cairo_image_surface_create(CAIRO_FORMAT_ARGB32,
3029 im->ximg * im->zoom,
3030 im->yimg * im->zoom);
3034 im->surface = strlen(im->graphfile)
3035 ? cairo_pdf_surface_create(im->graphfile, im->ximg * im->zoom,
3036 im->yimg * im->zoom)
3037 : cairo_pdf_surface_create_for_stream
3038 (&cairo_output, im, im->ximg * im->zoom, im->yimg * im->zoom);
3042 im->surface = strlen(im->graphfile)
3044 cairo_ps_surface_create(im->graphfile, im->ximg * im->zoom,
3045 im->yimg * im->zoom)
3046 : cairo_ps_surface_create_for_stream
3047 (&cairo_output, im, im->ximg * im->zoom, im->yimg * im->zoom);
3051 im->surface = strlen(im->graphfile)
3053 cairo_svg_surface_create(im->
3055 im->ximg * im->zoom, im->yimg * im->zoom)
3056 : cairo_svg_surface_create_for_stream
3057 (&cairo_output, im, im->ximg * im->zoom, im->yimg * im->zoom);
3058 cairo_svg_surface_restrict_to_version
3059 (im->surface, CAIRO_SVG_VERSION_1_1);
3062 im->cr = cairo_create(im->surface);
3063 cairo_set_antialias(im->cr, im->graph_antialias);
3064 cairo_scale(im->cr, im->zoom, im->zoom);
3065 pango_cairo_font_map_set_resolution(PANGO_CAIRO_FONT_MAP(font_map), 100);
3066 gfx_new_area(im, 0, 0, 0, im->yimg,
3067 im->ximg, im->yimg, im->graph_col[GRC_BACK]);
3068 gfx_add_point(im, im->ximg, 0);
3070 gfx_new_area(im, im->xorigin,
3073 im->xsize, im->yorigin,
3076 im->yorigin - im->ysize, im->graph_col[GRC_CANVAS]);
3077 gfx_add_point(im, im->xorigin, im->yorigin - im->ysize);
3079 cairo_rectangle(im->cr, im->xorigin, im->yorigin - im->ysize - 1.0,
3080 im->xsize, im->ysize + 2.0);
3082 if (im->minval > 0.0)
3083 areazero = im->minval;
3084 if (im->maxval < 0.0)
3085 areazero = im->maxval;
3086 for (i = 0; i < im->gdes_c; i++) {
3087 switch (im->gdes[i].gf) {
3101 for (ii = 0; ii < im->xsize; ii++) {
3102 if (!isnan(im->gdes[i].p_data[ii])
3103 && im->gdes[i].p_data[ii] != 0.0) {
3104 if (im->gdes[i].yrule > 0) {
3111 im->ysize, 1.0, im->gdes[i].col);
3112 } else if (im->gdes[i].yrule < 0) {
3115 im->yorigin - im->ysize,
3120 im->ysize, 1.0, im->gdes[i].col);
3127 /* fix data points at oo and -oo */
3128 for (ii = 0; ii < im->xsize; ii++) {
3129 if (isinf(im->gdes[i].p_data[ii])) {
3130 if (im->gdes[i].p_data[ii] > 0) {
3131 im->gdes[i].p_data[ii] = im->maxval;
3133 im->gdes[i].p_data[ii] = im->minval;
3139 /* *******************************************************
3144 -------|--t-1--t--------------------------------
3146 if we know the value at time t was a then
3147 we draw a square from t-1 to t with the value a.
3149 ********************************************************* */
3150 if (im->gdes[i].col.alpha != 0.0) {
3151 /* GF_LINE and friend */
3152 if (im->gdes[i].gf == GF_LINE) {
3153 double last_y = 0.0;
3157 cairo_new_path(im->cr);
3158 cairo_set_line_width(im->cr, im->gdes[i].linewidth);
3159 if (im->gdes[i].dash) {
3160 cairo_set_dash(im->cr,
3161 im->gdes[i].p_dashes,
3162 im->gdes[i].ndash, im->gdes[i].offset);
3165 for (ii = 1; ii < im->xsize; ii++) {
3166 if (isnan(im->gdes[i].p_data[ii])
3167 || (im->slopemode == 1
3168 && isnan(im->gdes[i].p_data[ii - 1]))) {
3173 last_y = ytr(im, im->gdes[i].p_data[ii]);
3174 if (im->slopemode == 0) {
3175 double x = ii - 1 + im->xorigin;
3178 gfx_line_fit(im, &x, &y);
3179 cairo_move_to(im->cr, x, y);
3180 x = ii + im->xorigin;
3182 gfx_line_fit(im, &x, &y);
3183 cairo_line_to(im->cr, x, y);
3185 double x = ii - 1 + im->xorigin;
3187 ytr(im, im->gdes[i].p_data[ii - 1]);
3188 gfx_line_fit(im, &x, &y);
3189 cairo_move_to(im->cr, x, y);
3190 x = ii + im->xorigin;
3192 gfx_line_fit(im, &x, &y);
3193 cairo_line_to(im->cr, x, y);
3197 double x1 = ii + im->xorigin;
3198 double y1 = ytr(im, im->gdes[i].p_data[ii]);
3200 if (im->slopemode == 0
3201 && !AlmostEqual2sComplement(y1, last_y, 4)) {
3202 double x = ii - 1 + im->xorigin;
3205 gfx_line_fit(im, &x, &y);
3206 cairo_line_to(im->cr, x, y);
3209 gfx_line_fit(im, &x1, &y1);
3210 cairo_line_to(im->cr, x1, y1);
3213 cairo_set_source_rgba(im->cr,
3219 col.blue, im->gdes[i].col.alpha);
3220 cairo_set_line_cap(im->cr, CAIRO_LINE_CAP_ROUND);
3221 cairo_set_line_join(im->cr, CAIRO_LINE_JOIN_ROUND);
3222 cairo_stroke(im->cr);
3223 cairo_restore(im->cr);
3227 (double *) malloc(sizeof(double) * im->xsize * 2);
3229 (double *) malloc(sizeof(double) * im->xsize * 2);
3231 (double *) malloc(sizeof(double) * im->xsize * 2);
3233 (double *) malloc(sizeof(double) * im->xsize * 2);
3236 for (ii = 0; ii <= im->xsize; ii++) {
3239 if (idxI > 0 && (drawem != 0 || ii == im->xsize)) {
3245 AlmostEqual2sComplement(foreY
3249 AlmostEqual2sComplement(foreY
3259 foreY[cntI], im->gdes[i].col);
3260 while (cntI < idxI) {
3265 AlmostEqual2sComplement(foreY
3269 AlmostEqual2sComplement(foreY
3276 gfx_add_point(im, foreX[cntI], foreY[cntI]);
3278 gfx_add_point(im, backX[idxI], backY[idxI]);
3284 AlmostEqual2sComplement(backY
3288 AlmostEqual2sComplement(backY
3295 gfx_add_point(im, backX[idxI], backY[idxI]);
3305 if (ii == im->xsize)
3307 if (im->slopemode == 0 && ii == 0) {
3310 if (isnan(im->gdes[i].p_data[ii])) {
3314 ytop = ytr(im, im->gdes[i].p_data[ii]);
3315 if (lastgdes && im->gdes[i].stack) {
3316 ybase = ytr(im, lastgdes->p_data[ii]);
3318 ybase = ytr(im, areazero);
3320 if (ybase == ytop) {
3326 double extra = ytop;
3331 if (im->slopemode == 0) {
3332 backY[++idxI] = ybase - 0.2;
3333 backX[idxI] = ii + im->xorigin - 1;
3334 foreY[idxI] = ytop + 0.2;
3335 foreX[idxI] = ii + im->xorigin - 1;
3337 backY[++idxI] = ybase - 0.2;
3338 backX[idxI] = ii + im->xorigin;
3339 foreY[idxI] = ytop + 0.2;
3340 foreX[idxI] = ii + im->xorigin;
3342 /* close up any remaining area */
3347 } /* else GF_LINE */
3349 /* if color != 0x0 */
3350 /* make sure we do not run into trouble when stacking on NaN */
3351 for (ii = 0; ii < im->xsize; ii++) {
3352 if (isnan(im->gdes[i].p_data[ii])) {
3353 if (lastgdes && (im->gdes[i].stack)) {
3354 im->gdes[i].p_data[ii] = lastgdes->p_data[ii];
3356 im->gdes[i].p_data[ii] = areazero;
3360 lastgdes = &(im->gdes[i]);
3364 ("STACK should already be turned into LINE or AREA here");
3369 cairo_reset_clip(im->cr);
3371 /* grid_paint also does the text */
3372 if (!(im->extra_flags & ONLY_GRAPH))
3374 if (!(im->extra_flags & ONLY_GRAPH))
3376 /* the RULES are the last thing to paint ... */
3377 for (i = 0; i < im->gdes_c; i++) {
3379 switch (im->gdes[i].gf) {
3381 if (im->gdes[i].yrule >= im->minval
3382 && im->gdes[i].yrule <= im->maxval) {
3384 if (im->gdes[i].dash) {
3385 cairo_set_dash(im->cr,
3386 im->gdes[i].p_dashes,
3387 im->gdes[i].ndash, im->gdes[i].offset);
3389 gfx_line(im, im->xorigin,
3390 ytr(im, im->gdes[i].yrule),
3391 im->xorigin + im->xsize,
3392 ytr(im, im->gdes[i].yrule), 1.0, im->gdes[i].col);
3393 cairo_stroke(im->cr);
3394 cairo_restore(im->cr);
3398 if (im->gdes[i].xrule >= im->start
3399 && im->gdes[i].xrule <= im->end) {
3401 if (im->gdes[i].dash) {
3402 cairo_set_dash(im->cr,
3403 im->gdes[i].p_dashes,
3404 im->gdes[i].ndash, im->gdes[i].offset);
3407 xtr(im, im->gdes[i].xrule),
3408 im->yorigin, xtr(im,
3412 im->yorigin - im->ysize, 1.0, im->gdes[i].col);
3413 cairo_stroke(im->cr);
3414 cairo_restore(im->cr);
3423 switch (im->imgformat) {
3426 cairo_status_t status;
3428 status = strlen(im->graphfile) ?
3429 cairo_surface_write_to_png(im->surface, im->graphfile)
3430 : cairo_surface_write_to_png_stream(im->surface, &cairo_output,
3433 if (status != CAIRO_STATUS_SUCCESS) {
3434 rrd_set_error("Could not save png to '%s'", im->graphfile);
3440 if (strlen(im->graphfile)) {
3441 cairo_show_page(im->cr);
3443 cairo_surface_finish(im->surface);
3452 /*****************************************************
3454 *****************************************************/
3461 if ((im->gdes = (graph_desc_t *)
3462 rrd_realloc(im->gdes, (im->gdes_c)
3463 * sizeof(graph_desc_t))) == NULL) {
3464 rrd_set_error("realloc graph_descs");
3469 im->gdes[im->gdes_c - 1].step = im->step;
3470 im->gdes[im->gdes_c - 1].step_orig = im->step;
3471 im->gdes[im->gdes_c - 1].stack = 0;
3472 im->gdes[im->gdes_c - 1].linewidth = 0;
3473 im->gdes[im->gdes_c - 1].debug = 0;
3474 im->gdes[im->gdes_c - 1].start = im->start;
3475 im->gdes[im->gdes_c - 1].start_orig = im->start;
3476 im->gdes[im->gdes_c - 1].end = im->end;
3477 im->gdes[im->gdes_c - 1].end_orig = im->end;
3478 im->gdes[im->gdes_c - 1].vname[0] = '\0';
3479 im->gdes[im->gdes_c - 1].data = NULL;
3480 im->gdes[im->gdes_c - 1].ds_namv = NULL;
3481 im->gdes[im->gdes_c - 1].data_first = 0;
3482 im->gdes[im->gdes_c - 1].p_data = NULL;
3483 im->gdes[im->gdes_c - 1].rpnp = NULL;
3484 im->gdes[im->gdes_c - 1].p_dashes = NULL;
3485 im->gdes[im->gdes_c - 1].shift = 0.0;
3486 im->gdes[im->gdes_c - 1].dash = 0;
3487 im->gdes[im->gdes_c - 1].ndash = 0;
3488 im->gdes[im->gdes_c - 1].offset = 0;
3489 im->gdes[im->gdes_c - 1].col.red = 0.0;
3490 im->gdes[im->gdes_c - 1].col.green = 0.0;
3491 im->gdes[im->gdes_c - 1].col.blue = 0.0;
3492 im->gdes[im->gdes_c - 1].col.alpha = 0.0;
3493 im->gdes[im->gdes_c - 1].legend[0] = '\0';
3494 im->gdes[im->gdes_c - 1].format[0] = '\0';
3495 im->gdes[im->gdes_c - 1].strftm = 0;
3496 im->gdes[im->gdes_c - 1].rrd[0] = '\0';
3497 im->gdes[im->gdes_c - 1].ds = -1;
3498 im->gdes[im->gdes_c - 1].cf_reduce = CF_AVERAGE;
3499 im->gdes[im->gdes_c - 1].cf = CF_AVERAGE;
3500 im->gdes[im->gdes_c - 1].yrule = DNAN;
3501 im->gdes[im->gdes_c - 1].xrule = 0;
3505 /* copies input untill the first unescaped colon is found
3506 or until input ends. backslashes have to be escaped as well */
3508 const char *const input,
3514 for (inp = 0; inp < len && input[inp] != ':' && input[inp] != '\0'; inp++) {
3515 if (input[inp] == '\\'
3516 && input[inp + 1] != '\0'
3517 && (input[inp + 1] == '\\' || input[inp + 1] == ':')) {
3518 output[outp++] = input[++inp];
3520 output[outp++] = input[inp];
3523 output[outp] = '\0';
3527 /* Now just a wrapper around rrd_graph_v */
3539 rrd_info_t *grinfo = NULL;
3542 grinfo = rrd_graph_v(argc, argv);
3548 if (strcmp(walker->key, "image_info") == 0) {
3551 rrd_realloc((*prdata),
3552 (prlines + 1) * sizeof(char *))) == NULL) {
3553 rrd_set_error("realloc prdata");
3556 /* imginfo goes to position 0 in the prdata array */
3557 (*prdata)[prlines - 1] = malloc((strlen(walker->value.u_str)
3558 + 2) * sizeof(char));
3559 strcpy((*prdata)[prlines - 1], walker->value.u_str);
3560 (*prdata)[prlines] = NULL;
3562 /* skip anything else */
3563 walker = walker->next;
3571 if (strcmp(walker->key, "image_width") == 0) {
3572 *xsize = walker->value.u_int;
3573 } else if (strcmp(walker->key, "image_height") == 0) {
3574 *ysize = walker->value.u_int;
3575 } else if (strcmp(walker->key, "value_min") == 0) {
3576 *ymin = walker->value.u_val;
3577 } else if (strcmp(walker->key, "value_max") == 0) {
3578 *ymax = walker->value.u_val;
3579 } else if (strncmp(walker->key, "print", 5) == 0) { /* keys are prdate[0..] */
3582 rrd_realloc((*prdata),
3583 (prlines + 1) * sizeof(char *))) == NULL) {
3584 rrd_set_error("realloc prdata");
3587 (*prdata)[prlines - 1] = malloc((strlen(walker->value.u_str)
3588 + 2) * sizeof(char));
3589 (*prdata)[prlines] = NULL;
3590 strcpy((*prdata)[prlines - 1], walker->value.u_str);
3591 } else if (strcmp(walker->key, "image") == 0) {
3592 fwrite(walker->value.u_blo.ptr, walker->value.u_blo.size, 1,
3593 (stream ? stream : stdout));
3595 /* skip anything else */
3596 walker = walker->next;
3598 rrd_info_free(grinfo);
3603 /* Some surgery done on this function, it became ridiculously big.
3605 ** - initializing now in rrd_graph_init()
3606 ** - options parsing now in rrd_graph_options()
3607 ** - script parsing now in rrd_graph_script()
3609 rrd_info_t *rrd_graph_v(
3616 rrd_graph_init(&im);
3617 /* a dummy surface so that we can measure text sizes for placements */
3618 im.surface = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, 10, 10);
3619 im.cr = cairo_create(im.surface);
3620 rrd_graph_options(argc, argv, &im);
3621 if (rrd_test_error()) {
3622 rrd_info_free(im.grinfo);
3627 if (optind >= argc) {
3628 rrd_info_free(im.grinfo);
3630 rrd_set_error("missing filename");
3634 if (strlen(argv[optind]) >= MAXPATH) {
3635 rrd_set_error("filename (including path) too long");
3636 rrd_info_free(im.grinfo);
3641 strncpy(im.graphfile, argv[optind], MAXPATH - 1);
3642 im.graphfile[MAXPATH - 1] = '\0';
3644 if (strcmp(im.graphfile, "-") == 0) {
3645 im.graphfile[0] = '\0';
3648 rrd_graph_script(argc, argv, &im, 1);
3649 if (rrd_test_error()) {
3650 rrd_info_free(im.grinfo);
3655 /* Everything is now read and the actual work can start */
3657 if (graph_paint(&im) == -1) {
3658 rrd_info_free(im.grinfo);
3664 /* The image is generated and needs to be output.
3665 ** Also, if needed, print a line with information about the image.
3672 sprintf_alloc(im.imginfo,
3675 im.ximg), (long) (im.zoom * im.yimg));
3676 grinfo_push(&im, sprintf_alloc("image_info"), RD_I_STR, info);
3679 if (im.rendered_image) {
3682 img.u_blo.size = im.rendered_image_size;
3683 img.u_blo.ptr = im.rendered_image;
3684 grinfo_push(&im, sprintf_alloc("image"), RD_I_BLO, img);
3691 void rrd_graph_init(
3700 #ifdef HAVE_SETLOCALE
3701 setlocale(LC_TIME, "");
3702 #ifdef HAVE_MBSTOWCS
3703 setlocale(LC_CTYPE, "");
3708 im->draw_x_grid = 1;
3709 im->draw_y_grid = 1;
3710 im->extra_flags = 0;
3711 im->font_options = cairo_font_options_create();
3712 im->forceleftspace = 0;
3715 im->graph_antialias = CAIRO_ANTIALIAS_GRAY;
3716 im->grid_dash_off = 1;
3717 im->grid_dash_on = 1;
3719 im->grinfo = (rrd_info_t *) NULL;
3720 im->grinfo_current = (rrd_info_t *) NULL;
3721 im->imgformat = IF_PNG;
3724 im->logarithmic = 0;
3730 im->rendered_image_size = 0;
3731 im->rendered_image = NULL;
3736 im->tabwidth = 40.0;
3737 im->title[0] = '\0';
3738 im->unitsexponent = 9999;
3739 im->unitslength = 6;
3740 im->viewfactor = 1.0;
3741 im->watermark[0] = '\0';
3742 im->with_markup = 0;
3744 im->xlab_user.minsec = -1;
3747 im->ygridstep = DNAN;
3749 im->ylegend[0] = '\0';
3753 cairo_font_options_set_hint_style
3754 (im->font_options, CAIRO_HINT_STYLE_FULL);
3755 cairo_font_options_set_hint_metrics
3756 (im->font_options, CAIRO_HINT_METRICS_ON);
3757 cairo_font_options_set_antialias(im->font_options, CAIRO_ANTIALIAS_GRAY);
3758 for (i = 0; i < DIM(graph_col); i++)
3759 im->graph_col[i] = graph_col[i];
3763 deffont = getenv("RRD_DEFAULT_FONT");
3764 if (deffont != NULL) {
3765 for (i = 0; i < DIM(text_prop); i++) {
3766 strncpy(text_prop[i].font, deffont,
3767 sizeof(text_prop[i].font) - 1);
3768 text_prop[i].font[sizeof(text_prop[i].font) - 1] = '\0';
3772 for (i = 0; i < DIM(text_prop); i++) {
3773 im->text_prop[i].size = text_prop[i].size;
3774 strcpy(im->text_prop[i].font, text_prop[i].font);
3778 void rrd_graph_options(
3785 char *parsetime_error = NULL;
3786 char scan_gtm[12], scan_mtm[12], scan_ltm[12], col_nam[12];
3787 time_t start_tmp = 0, end_tmp = 0;
3789 rrd_time_value_t start_tv, end_tv;
3790 long unsigned int color;
3791 char *old_locale = "";
3793 /* defines for long options without a short equivalent. should be bytes,
3794 and may not collide with (the ASCII value of) short options */
3795 #define LONGOPT_UNITS_SI 255
3798 struct option long_options[] = {
3799 { "start", required_argument, 0, 's'},
3800 { "end", required_argument, 0, 'e'},
3801 { "x-grid", required_argument, 0, 'x'},
3802 { "y-grid", required_argument, 0, 'y'},
3803 { "vertical-label", required_argument, 0, 'v'},
3804 { "width", required_argument, 0, 'w'},
3805 { "height", required_argument, 0, 'h'},
3806 { "full-size-mode", no_argument, 0, 'D'},
3807 { "interlaced", no_argument, 0, 'i'},
3808 { "upper-limit", required_argument, 0, 'u'},
3809 { "lower-limit", required_argument, 0, 'l'},
3810 { "rigid", no_argument, 0, 'r'},
3811 { "base", required_argument, 0, 'b'},
3812 { "logarithmic", no_argument, 0, 'o'},
3813 { "color", required_argument, 0, 'c'},
3814 { "font", required_argument, 0, 'n'},
3815 { "title", required_argument, 0, 't'},
3816 { "imginfo", required_argument, 0, 'f'},
3817 { "imgformat", required_argument, 0, 'a'},
3818 { "lazy", no_argument, 0, 'z'},
3819 { "zoom", required_argument, 0, 'm'},
3820 { "no-legend", no_argument, 0, 'g'},
3821 { "force-rules-legend", no_argument, 0, 'F'},
3822 { "only-graph", no_argument, 0, 'j'},
3823 { "alt-y-grid", no_argument, 0, 'Y'},
3824 { "no-minor", no_argument, 0, 'I'},
3825 { "slope-mode", no_argument, 0, 'E'},
3826 { "alt-autoscale", no_argument, 0, 'A'},
3827 { "alt-autoscale-min", no_argument, 0, 'J'},
3828 { "alt-autoscale-max", no_argument, 0, 'M'},
3829 { "no-gridfit", no_argument, 0, 'N'},
3830 { "units-exponent", required_argument, 0, 'X'},
3831 { "units-length", required_argument, 0, 'L'},
3832 { "units", required_argument, 0, LONGOPT_UNITS_SI},
3833 { "step", required_argument, 0, 'S'},
3834 { "tabwidth", required_argument, 0, 'T'},
3835 { "font-render-mode", required_argument, 0, 'R'},
3836 { "graph-render-mode", required_argument, 0, 'G'},
3837 { "font-smoothing-threshold", required_argument, 0, 'B'},
3838 { "watermark", required_argument, 0, 'W'},
3839 { "alt-y-mrtg", no_argument, 0, 1000}, /* this has no effect it is just here to save old apps from crashing when they use it */
3840 { "pango-markup", no_argument, 0, 'P'},
3846 opterr = 0; /* initialize getopt */
3847 rrd_parsetime("end-24h", &start_tv);
3848 rrd_parsetime("now", &end_tv);
3850 int option_index = 0;
3852 int col_start, col_end;
3854 opt = getopt_long(argc, argv,
3855 "s:e:x:y:v:w:h:D:iu:l:rb:oc:n:m:t:f:a:I:zgjFYAMEX:L:S:T:NR:B:W:kP",
3856 long_options, &option_index);
3861 im->extra_flags |= NOMINOR;
3864 im->extra_flags |= ALTYGRID;
3867 im->extra_flags |= ALTAUTOSCALE;
3870 im->extra_flags |= ALTAUTOSCALE_MIN;
3873 im->extra_flags |= ALTAUTOSCALE_MAX;
3876 im->extra_flags |= ONLY_GRAPH;
3879 im->extra_flags |= NOLEGEND;
3882 im->extra_flags |= FORCE_RULES_LEGEND;
3884 case LONGOPT_UNITS_SI:
3885 if (im->extra_flags & FORCE_UNITS) {
3886 rrd_set_error("--units can only be used once!");
3887 setlocale(LC_NUMERIC, old_locale);
3890 if (strcmp(optarg, "si") == 0)
3891 im->extra_flags |= FORCE_UNITS_SI;
3893 rrd_set_error("invalid argument for --units: %s", optarg);
3898 im->unitsexponent = atoi(optarg);
3901 im->unitslength = atoi(optarg);
3902 im->forceleftspace = 1;
3905 old_locale = setlocale(LC_NUMERIC, "C");
3906 im->tabwidth = atof(optarg);
3907 setlocale(LC_NUMERIC, old_locale);
3910 old_locale = setlocale(LC_NUMERIC, "C");
3911 im->step = atoi(optarg);
3912 setlocale(LC_NUMERIC, old_locale);
3918 im->with_markup = 1;
3921 if ((parsetime_error = rrd_parsetime(optarg, &start_tv))) {
3922 rrd_set_error("start time: %s", parsetime_error);
3927 if ((parsetime_error = rrd_parsetime(optarg, &end_tv))) {
3928 rrd_set_error("end time: %s", parsetime_error);
3933 if (strcmp(optarg, "none") == 0) {
3934 im->draw_x_grid = 0;
3938 "%10[A-Z]:%ld:%10[A-Z]:%ld:%10[A-Z]:%ld:%ld:%n",
3940 &im->xlab_user.gridst,
3942 &im->xlab_user.mgridst,
3944 &im->xlab_user.labst,
3945 &im->xlab_user.precis, &stroff) == 7 && stroff != 0) {
3946 strncpy(im->xlab_form, optarg + stroff,
3947 sizeof(im->xlab_form) - 1);
3948 im->xlab_form[sizeof(im->xlab_form) - 1] = '\0';
3950 (im->xlab_user.gridtm = tmt_conv(scan_gtm)) == -1) {
3951 rrd_set_error("unknown keyword %s", scan_gtm);
3954 (im->xlab_user.mgridtm = tmt_conv(scan_mtm))
3956 rrd_set_error("unknown keyword %s", scan_mtm);
3959 (im->xlab_user.labtm = tmt_conv(scan_ltm)) == -1) {
3960 rrd_set_error("unknown keyword %s", scan_ltm);
3963 im->xlab_user.minsec = 1;
3964 im->xlab_user.stst = im->xlab_form;
3966 rrd_set_error("invalid x-grid format");
3972 if (strcmp(optarg, "none") == 0) {
3973 im->draw_y_grid = 0;
3976 old_locale = setlocale(LC_NUMERIC, "C");
3977 if (sscanf(optarg, "%lf:%d", &im->ygridstep, &im->ylabfact) == 2) {
3978 setlocale(LC_NUMERIC, old_locale);
3979 if (im->ygridstep <= 0) {
3980 rrd_set_error("grid step must be > 0");
3982 } else if (im->ylabfact < 1) {
3983 rrd_set_error("label factor must be > 0");
3987 setlocale(LC_NUMERIC, old_locale);
3988 rrd_set_error("invalid y-grid format");
3993 strncpy(im->ylegend, optarg, 150);
3994 im->ylegend[150] = '\0';
3997 old_locale = setlocale(LC_NUMERIC, "C");
3998 im->maxval = atof(optarg);
3999 setlocale(LC_NUMERIC, old_locale);
4002 old_locale = setlocale(LC_NUMERIC, "C");
4003 im->minval = atof(optarg);
4004 setlocale(LC_NUMERIC, old_locale);
4007 im->base = atol(optarg);
4008 if (im->base != 1024 && im->base != 1000) {
4010 ("the only sensible value for base apart from 1000 is 1024");
4015 long_tmp = atol(optarg);
4016 if (long_tmp < 10) {
4017 rrd_set_error("width below 10 pixels");
4020 im->xsize = long_tmp;
4023 long_tmp = atol(optarg);
4024 if (long_tmp < 10) {
4025 rrd_set_error("height below 10 pixels");
4028 im->ysize = long_tmp;
4031 im->extra_flags |= FULL_SIZE_MODE;
4034 /* interlaced png not supported at the moment */
4040 im->imginfo = optarg;
4044 (im->imgformat = if_conv(optarg)) == -1) {
4045 rrd_set_error("unsupported graphics format '%s'", optarg);
4056 im->logarithmic = 1;
4060 "%10[A-Z]#%n%8lx%n",
4061 col_nam, &col_start, &color, &col_end) == 2) {
4063 int col_len = col_end - col_start;
4068 (((color & 0xF00) * 0x110000) | ((color & 0x0F0) *
4076 (((color & 0xF000) *
4077 0x11000) | ((color & 0x0F00) *
4078 0x01100) | ((color &
4081 ((color & 0x000F) * 0x00011)
4085 color = (color << 8) + 0xff /* shift left by 8 */ ;
4090 rrd_set_error("the color format is #RRGGBB[AA]");
4093 if ((ci = grc_conv(col_nam)) != -1) {
4094 im->graph_col[ci] = gfx_hex_to_col(color);
4096 rrd_set_error("invalid color name '%s'", col_nam);
4100 rrd_set_error("invalid color def format");
4109 old_locale = setlocale(LC_NUMERIC, "C");
4110 if (sscanf(optarg, "%10[A-Z]:%lf%n", prop, &size, &end) >= 2) {
4111 int sindex, propidx;
4113 setlocale(LC_NUMERIC, old_locale);
4114 if ((sindex = text_prop_conv(prop)) != -1) {
4115 for (propidx = sindex;
4116 propidx < TEXT_PROP_LAST; propidx++) {
4118 im->text_prop[propidx].size = size;
4120 if ((int) strlen(optarg) > end) {
4121 if (optarg[end] == ':') {
4122 strncpy(im->text_prop[propidx].font,
4123 optarg + end + 1, 255);
4124 im->text_prop[propidx].font[255] = '\0';
4127 ("expected : after font size in '%s'",
4132 /* only run the for loop for DEFAULT (0) for
4133 all others, we break here. woodo programming */
4134 if (propidx == sindex && sindex != 0)
4138 rrd_set_error("invalid fonttag '%s'", prop);
4142 setlocale(LC_NUMERIC, old_locale);
4143 rrd_set_error("invalid text property format");
4149 old_locale = setlocale(LC_NUMERIC, "C");
4150 im->zoom = atof(optarg);
4151 setlocale(LC_NUMERIC, old_locale);
4152 if (im->zoom <= 0.0) {
4153 rrd_set_error("zoom factor must be > 0");
4158 strncpy(im->title, optarg, 150);
4159 im->title[150] = '\0';
4162 if (strcmp(optarg, "normal") == 0) {
4163 cairo_font_options_set_antialias
4164 (im->font_options, CAIRO_ANTIALIAS_GRAY);
4165 cairo_font_options_set_hint_style
4166 (im->font_options, CAIRO_HINT_STYLE_FULL);
4167 } else if (strcmp(optarg, "light") == 0) {
4168 cairo_font_options_set_antialias
4169 (im->font_options, CAIRO_ANTIALIAS_GRAY);
4170 cairo_font_options_set_hint_style
4171 (im->font_options, CAIRO_HINT_STYLE_SLIGHT);
4172 } else if (strcmp(optarg, "mono") == 0) {
4173 cairo_font_options_set_antialias
4174 (im->font_options, CAIRO_ANTIALIAS_NONE);
4175 cairo_font_options_set_hint_style
4176 (im->font_options, CAIRO_HINT_STYLE_FULL);
4178 rrd_set_error("unknown font-render-mode '%s'", optarg);
4183 if (strcmp(optarg, "normal") == 0)
4184 im->graph_antialias = CAIRO_ANTIALIAS_GRAY;
4185 else if (strcmp(optarg, "mono") == 0)
4186 im->graph_antialias = CAIRO_ANTIALIAS_NONE;
4188 rrd_set_error("unknown graph-render-mode '%s'", optarg);
4193 /* not supported curently */
4196 strncpy(im->watermark, optarg, 100);
4197 im->watermark[99] = '\0';
4201 rrd_set_error("unknown option '%c'", optopt);
4203 rrd_set_error("unknown option '%s'", argv[optind - 1]);
4208 if (im->logarithmic && im->minval <= 0) {
4210 ("for a logarithmic yaxis you must specify a lower-limit > 0");
4214 if (rrd_proc_start_end(&start_tv, &end_tv, &start_tmp, &end_tmp) == -1) {
4215 /* error string is set in rrd_parsetime.c */
4219 if (start_tmp < 3600 * 24 * 365 * 10) {
4221 ("the first entry to fetch should be after 1980 (%ld)",
4226 if (end_tmp < start_tmp) {
4228 ("start (%ld) should be less than end (%ld)", start_tmp, end_tmp);
4232 im->start = start_tmp;
4234 im->step = max((long) im->step, (im->end - im->start) / im->xsize);
4237 int rrd_graph_color(
4245 graph_desc_t *gdp = &im->gdes[im->gdes_c - 1];
4247 color = strstr(var, "#");
4248 if (color == NULL) {
4249 if (optional == 0) {
4250 rrd_set_error("Found no color in %s", err);
4257 long unsigned int col;
4259 rest = strstr(color, ":");
4266 sscanf(color, "#%6lx%n", &col, &n);
4267 col = (col << 8) + 0xff /* shift left by 8 */ ;
4269 rrd_set_error("Color problem in %s", err);
4272 sscanf(color, "#%8lx%n", &col, &n);
4276 rrd_set_error("Color problem in %s", err);
4278 if (rrd_test_error())
4280 gdp->col = gfx_hex_to_col(col);
4293 while (*ptr != '\0')
4294 if (*ptr++ == '%') {
4296 /* line cannot end with percent char */
4299 /* '%s', '%S' and '%%' are allowed */
4300 if (*ptr == 's' || *ptr == 'S' || *ptr == '%')
4302 /* %c is allowed (but use only with vdef!) */
4303 else if (*ptr == 'c') {
4308 /* or else '% 6.2lf' and such are allowed */
4310 /* optional padding character */
4311 if (*ptr == ' ' || *ptr == '+' || *ptr == '-')
4313 /* This should take care of 'm.n' with all three optional */
4314 while (*ptr >= '0' && *ptr <= '9')
4318 while (*ptr >= '0' && *ptr <= '9')
4320 /* Either 'le', 'lf' or 'lg' must follow here */
4323 if (*ptr == 'e' || *ptr == 'f' || *ptr == 'g')
4338 const char *const str)
4340 /* A VDEF currently is either "func" or "param,func"
4341 * so the parsing is rather simple. Change if needed.
4349 old_locale = setlocale(LC_NUMERIC, "C");
4350 sscanf(str, "%le,%29[A-Z]%n", ¶m, func, &n);
4351 setlocale(LC_NUMERIC, old_locale);
4352 if (n == (int) strlen(str)) { /* matched */
4356 sscanf(str, "%29[A-Z]%n", func, &n);
4357 if (n == (int) strlen(str)) { /* matched */
4361 ("Unknown function string '%s' in VDEF '%s'",
4366 if (!strcmp("PERCENT", func))
4367 gdes->vf.op = VDEF_PERCENT;
4368 else if (!strcmp("MAXIMUM", func))
4369 gdes->vf.op = VDEF_MAXIMUM;
4370 else if (!strcmp("AVERAGE", func))
4371 gdes->vf.op = VDEF_AVERAGE;
4372 else if (!strcmp("STDEV", func))
4373 gdes->vf.op = VDEF_STDEV;
4374 else if (!strcmp("MINIMUM", func))
4375 gdes->vf.op = VDEF_MINIMUM;
4376 else if (!strcmp("TOTAL", func))
4377 gdes->vf.op = VDEF_TOTAL;
4378 else if (!strcmp("FIRST", func))
4379 gdes->vf.op = VDEF_FIRST;
4380 else if (!strcmp("LAST", func))
4381 gdes->vf.op = VDEF_LAST;
4382 else if (!strcmp("LSLSLOPE", func))
4383 gdes->vf.op = VDEF_LSLSLOPE;
4384 else if (!strcmp("LSLINT", func))
4385 gdes->vf.op = VDEF_LSLINT;
4386 else if (!strcmp("LSLCORREL", func))
4387 gdes->vf.op = VDEF_LSLCORREL;
4390 ("Unknown function '%s' in VDEF '%s'\n", func, gdes->vname);
4393 switch (gdes->vf.op) {
4395 if (isnan(param)) { /* no parameter given */
4397 ("Function '%s' needs parameter in VDEF '%s'\n",
4401 if (param >= 0.0 && param <= 100.0) {
4402 gdes->vf.param = param;
4403 gdes->vf.val = DNAN; /* undefined */
4404 gdes->vf.when = 0; /* undefined */
4407 ("Parameter '%f' out of range in VDEF '%s'\n",
4408 param, gdes->vname);
4421 case VDEF_LSLCORREL:
4423 gdes->vf.param = DNAN;
4424 gdes->vf.val = DNAN;
4428 ("Function '%s' needs no parameter in VDEF '%s'\n",
4442 graph_desc_t *src, *dst;
4447 dst = &im->gdes[gdi];
4448 src = &im->gdes[dst->vidx];
4449 data = src->data + src->ds;
4451 src->end_orig % (long)src->step ==
4452 0 ? src->end_orig : (src->end_orig + (long)src->step -
4453 src->end_orig % (long)src->step);
4455 steps = (end - src->start) / src->step;
4458 ("DEBUG: start == %lu, end == %lu, %lu steps\n",
4459 src->start, src->end_orig, steps);
4461 switch (dst->vf.op) {
4465 if ((array = malloc(steps * sizeof(double))) == NULL) {
4466 rrd_set_error("malloc VDEV_PERCENT");
4469 for (step = 0; step < steps; step++) {
4470 array[step] = data[step * src->ds_cnt];
4472 qsort(array, step, sizeof(double), vdef_percent_compar);
4473 field = (steps - 1) * dst->vf.param / 100;
4474 dst->vf.val = array[field];
4475 dst->vf.when = 0; /* no time component */
4478 for (step = 0; step < steps; step++)
4479 printf("DEBUG: %3li:%10.2f %c\n",
4480 step, array[step], step == field ? '*' : ' ');
4486 while (step != steps && isnan(data[step * src->ds_cnt]))
4488 if (step == steps) {
4492 dst->vf.val = data[step * src->ds_cnt];
4493 dst->vf.when = src->start + (step + 1) * src->step;
4495 while (step != steps) {
4496 if (finite(data[step * src->ds_cnt])) {
4497 if (data[step * src->ds_cnt] > dst->vf.val) {
4498 dst->vf.val = data[step * src->ds_cnt];
4499 dst->vf.when = src->start + (step + 1) * src->step;
4510 double average = 0.0;
4512 for (step = 0; step < steps; step++) {
4513 if (finite(data[step * src->ds_cnt])) {
4514 sum += data[step * src->ds_cnt];
4519 if (dst->vf.op == VDEF_TOTAL) {
4520 dst->vf.val = sum * src->step;
4521 dst->vf.when = 0; /* no time component */
4522 } else if (dst->vf.op == VDEF_AVERAGE) {
4523 dst->vf.val = sum / cnt;
4524 dst->vf.when = 0; /* no time component */
4526 average = sum / cnt;
4528 for (step = 0; step < steps; step++) {
4529 if (finite(data[step * src->ds_cnt])) {
4530 sum += pow((data[step * src->ds_cnt] - average), 2.0);
4533 dst->vf.val = pow(sum / cnt, 0.5);
4534 dst->vf.when = 0; /* no time component */
4544 while (step != steps && isnan(data[step * src->ds_cnt]))
4546 if (step == steps) {
4550 dst->vf.val = data[step * src->ds_cnt];
4551 dst->vf.when = src->start + (step + 1) * src->step;
4553 while (step != steps) {
4554 if (finite(data[step * src->ds_cnt])) {
4555 if (data[step * src->ds_cnt] < dst->vf.val) {
4556 dst->vf.val = data[step * src->ds_cnt];
4557 dst->vf.when = src->start + (step + 1) * src->step;
4564 /* The time value returned here is one step before the
4565 * actual time value. This is the start of the first
4569 while (step != steps && isnan(data[step * src->ds_cnt]))
4571 if (step == steps) { /* all entries were NaN */
4575 dst->vf.val = data[step * src->ds_cnt];
4576 dst->vf.when = src->start + step * src->step;
4580 /* The time value returned here is the
4581 * actual time value. This is the end of the last
4585 while (step >= 0 && isnan(data[step * src->ds_cnt]))
4587 if (step < 0) { /* all entries were NaN */
4591 dst->vf.val = data[step * src->ds_cnt];
4592 dst->vf.when = src->start + (step + 1) * src->step;
4597 case VDEF_LSLCORREL:{
4598 /* Bestfit line by linear least squares method */
4601 double SUMx, SUMy, SUMxy, SUMxx, SUMyy, slope, y_intercept, correl;
4608 for (step = 0; step < steps; step++) {
4609 if (finite(data[step * src->ds_cnt])) {
4612 SUMxx += step * step;
4613 SUMxy += step * data[step * src->ds_cnt];
4614 SUMy += data[step * src->ds_cnt];
4615 SUMyy += data[step * src->ds_cnt] * data[step * src->ds_cnt];
4619 slope = (SUMx * SUMy - cnt * SUMxy) / (SUMx * SUMx - cnt * SUMxx);
4620 y_intercept = (SUMy - slope * SUMx) / cnt;
4623 (SUMx * SUMy) / cnt) /
4625 (SUMx * SUMx) / cnt) * (SUMyy - (SUMy * SUMy) / cnt));
4627 if (dst->vf.op == VDEF_LSLSLOPE) {
4628 dst->vf.val = slope;
4630 } else if (dst->vf.op == VDEF_LSLINT) {
4631 dst->vf.val = y_intercept;
4633 } else if (dst->vf.op == VDEF_LSLCORREL) {
4634 dst->vf.val = correl;
4647 /* NaN < -INF < finite_values < INF */
4648 int vdef_percent_compar(
4654 /* Equality is not returned; this doesn't hurt except
4655 * (maybe) for a little performance.
4658 /* First catch NaN values. They are smallest */
4659 if (isnan(*(double *) a))
4661 if (isnan(*(double *) b))
4663 /* NaN doesn't reach this part so INF and -INF are extremes.
4664 * The sign from isinf() is compatible with the sign we return
4666 if (isinf(*(double *) a))
4667 return isinf(*(double *) a);
4668 if (isinf(*(double *) b))
4669 return isinf(*(double *) b);
4670 /* If we reach this, both values must be finite */
4671 if (*(double *) a < *(double *) b)
4680 rrd_info_type_t type,
4681 rrd_infoval_t value)
4683 im->grinfo_current = rrd_info_push(im->grinfo_current, key, type, value);
4684 if (im->grinfo == NULL) {
4685 im->grinfo = im->grinfo_current;