/* PSPP - a program for statistical analysis.
- Copyright (C) 2009, 2011 Free Software Foundation, Inc.
+ Copyright (C) 2009, 2011, 2014, 2015 Free Software Foundation, Inc.
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
along with this program. If not, see <http://www.gnu.org/licenses/>. */
#include <config.h>
-
+#include "math/chart-geometry.h"
#include "output/charts/plot-hist.h"
+#include <float.h>
#include <gsl/gsl_randist.h>
#include "data/val-type.h"
#include "output/cairo-chart.h"
#include "gl/xvasprintf.h"
+#include "gl/minmax.h"
#include "gettext.h"
#define _(msgid) gettext (msgid)
histogram_write_legend (cairo_t *cr, const struct xrchart_geometry *geom,
double n, double mean, double stddev)
{
- double y = geom->data_bottom;
+ double y = geom->axis[SCALE_ORDINATE].data_min;
cairo_save (cr);
if (n != SYSMIS)
{
- char *buf = xasprintf ("N = %.2f", n);
+ char *buf = xasprintf (_("N = %.2f"), n);
cairo_move_to (cr, geom->legend_left, y);
xrchart_label (cr, 'l', 'b', geom->font_size, buf);
y += geom->font_size * 1.5;
if (mean != SYSMIS)
{
- char *buf = xasprintf ("Mean = %.1f", mean);
+ char *buf = xasprintf (_("Mean = %.1f"), mean);
cairo_move_to (cr,geom->legend_left, y);
xrchart_label (cr, 'l', 'b', geom->font_size, buf);
y += geom->font_size * 1.5;
if (stddev != SYSMIS)
{
- char *buf = xasprintf ("Std. Dev = %.2f", stddev);
+ char *buf = xasprintf (_("Std. Dev = %.2f"), stddev);
cairo_move_to (cr, geom->legend_left, y);
xrchart_label (cr, 'l', 'b', geom->font_size, buf);
free (buf);
double lower;
double height;
- const size_t bins = gsl_histogram_bins (h);
- const double x_pos = (geom->data_right - geom->data_left) * bar / (double) bins ;
- const double width = (geom->data_right - geom->data_left) / (double) bins ;
-
- assert ( 0 == gsl_histogram_get_range (h, bar, &lower, &upper));
+ assert (0 == gsl_histogram_get_range (h, bar, &lower, &upper));
+ assert (upper >= lower);
- assert ( upper >= lower);
+ const double x_pos =
+ (lower - geom->axis[SCALE_ABSCISSA].min) * geom->axis[SCALE_ABSCISSA].scale
+ + geom->axis[SCALE_ABSCISSA].data_min;
+ const double width = (upper - lower) * geom->axis[SCALE_ABSCISSA].scale;
- height = gsl_histogram_get (h, bar) *
- (geom->data_top - geom->data_bottom) / gsl_histogram_max_val (h);
+ height = geom->axis[SCALE_ORDINATE].scale * gsl_histogram_get (h, bar);
- cairo_rectangle (cr, geom->data_left + x_pos, geom->data_bottom,
+ cairo_rectangle (cr,
+ x_pos,
+ geom->axis[SCALE_ORDINATE].data_min,
width, height);
cairo_save (cr);
cairo_set_source_rgb (cr,
cairo_fill_preserve (cr);
cairo_restore (cr);
cairo_stroke (cr);
-
- draw_tick (cr, geom, TICK_ABSCISSA,
- x_pos + width / 2.0, "%g", (upper + lower) / 2.0);
}
void
-xrchart_draw_histogram (const struct chart_item *chart_item, cairo_t *cr,
+xrchart_draw_histogram (const struct chart *chart, cairo_t *cr,
struct xrchart_geometry *geom)
{
- struct histogram_chart *h = to_histogram_chart (chart_item);
+ struct histogram_chart *h = to_histogram_chart (chart);
int i;
int bins;
xrchart_write_title (cr, geom, _("HISTOGRAM"));
xrchart_write_ylabel (cr, geom, _("Frequency"));
- xrchart_write_xlabel (cr, geom, chart_item_get_title (chart_item));
+ xrchart_write_xlabel (cr, geom, chart_get_title (chart));
if (h->gsl_hist == NULL)
{
return;
}
- bins = gsl_histogram_bins (h->gsl_hist);
+ if (! xrchart_write_yscale (cr, geom, 0, gsl_histogram_max_val (h->gsl_hist)))
+ return;
+ if (! xrchart_write_xscale (cr, geom, gsl_histogram_min (h->gsl_hist),
+ gsl_histogram_max (h->gsl_hist)))
+ return;
- xrchart_write_yscale (cr, geom, 0, gsl_histogram_max_val (h->gsl_hist), 5);
+
+ /* Draw the ticks and compute if the rendered tick text is wider than the bin */
+ bins = gsl_histogram_bins (h->gsl_hist);
for (i = 0; i < bins; i++)
- hist_draw_bar (cr, geom, h->gsl_hist, i);
+ {
+ hist_draw_bar (cr, geom, h->gsl_hist, i);
+ }
histogram_write_legend (cr, geom, h->n, h->mean, h->stddev);
&& h->n != SYSMIS && h->mean != SYSMIS && h->stddev != SYSMIS)
{
/* Draw the normal curve */
- double d;
- double x_min, x_max, not_used;
- double abscissa_scale;
+ double x_min, x_max;
double ordinate_scale;
- double range;
-
- gsl_histogram_get_range (h->gsl_hist, 0, &x_min, ¬_used);
- range = not_used - x_min;
- gsl_histogram_get_range (h->gsl_hist, bins - 1, ¬_used, &x_max);
-
- abscissa_scale = (geom->data_right - geom->data_left) / (x_max - x_min);
- ordinate_scale = (geom->data_top - geom->data_bottom) /
- gsl_histogram_max_val (h->gsl_hist);
-
- cairo_move_to (cr, geom->data_left, geom->data_bottom);
- for (d = geom->data_left;
- d <= geom->data_right;
- d += (geom->data_right - geom->data_left) / 100.0)
+ double binwidth;
+ double x;
+
+ gsl_histogram_get_range (h->gsl_hist, 0, &x_min, &x_max);
+ binwidth = x_max - x_min;
+
+ /* The integral over the histogram is binwidth * sum(bin_i), while the integral over the pdf is 1 */
+ /* Therefore the pdf has to be scaled accordingly such that the integrals are equal */
+ ordinate_scale = binwidth * gsl_histogram_sum(h->gsl_hist);
+
+ /* Clip normal curve to the rectangle formed by the axes. */
+ cairo_save (cr);
+ cairo_rectangle (cr, geom->axis[SCALE_ABSCISSA].data_min, geom->axis[SCALE_ORDINATE].data_min,
+ geom->axis[SCALE_ABSCISSA].data_max - geom->axis[SCALE_ABSCISSA].data_min,
+ geom->axis[SCALE_ORDINATE].data_max - geom->axis[SCALE_ORDINATE].data_min);
+ cairo_clip (cr);
+
+ cairo_move_to (cr, geom->axis[SCALE_ABSCISSA].data_min, geom->axis[SCALE_ORDINATE].data_min);
+ for (x = geom->axis[SCALE_ABSCISSA].min;
+ x <= geom->axis[SCALE_ABSCISSA].max;
+ x += (geom->axis[SCALE_ABSCISSA].max - geom->axis[SCALE_ABSCISSA].min) / 100.0)
{
- const double x = (d - geom->data_left) / abscissa_scale + x_min;
- const double y = h->n * range *
- gsl_ran_gaussian_pdf (x - h->mean, h->stddev);
-
- cairo_line_to (cr, d, geom->data_bottom + y * ordinate_scale);
-
+ const double y = gsl_ran_gaussian_pdf (x - h->mean, h->stddev) * ordinate_scale;
+ /* Transform to drawing coordinates */
+ const double x_pos = (x - geom->axis[SCALE_ABSCISSA].min) * geom->axis[SCALE_ABSCISSA].scale + geom->axis[SCALE_ABSCISSA].data_min;
+ const double y_pos = (y - geom->axis[SCALE_ORDINATE].min) * geom->axis[SCALE_ORDINATE].scale + geom->axis[SCALE_ORDINATE].data_min;
+ cairo_line_to (cr, x_pos, y_pos);
}
cairo_stroke (cr);
+
+ cairo_restore (cr);
}
}