eBookReaderSwitch/mupdf/source/fitz/svg-device.c

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#include "fitz-imp.h"
#include <string.h>
#include <float.h>
#include <math.h>
typedef struct svg_device_s svg_device;
typedef struct tile_s tile;
typedef struct font_s font;
typedef struct glyph_s glyph;
typedef struct image_s image;
struct tile_s
{
int pattern;
fz_matrix ctm;
fz_rect view;
fz_rect area;
fz_point step;
};
struct glyph_s
{
float x_off;
float y_off;
};
struct font_s
{
int id;
fz_font *font;
int max_sentlist;
glyph *sentlist;
};
struct image_s
{
int id;
fz_image *image;
};
struct svg_device_s
{
fz_device super;
int text_as_text;
int reuse_images;
fz_output *out;
fz_output *out_store;
fz_output *defs;
fz_buffer *defs_buffer;
int def_count;
int *save_id;
int id;
int blend_bitmask;
int num_tiles;
int max_tiles;
tile *tiles;
int num_fonts;
int max_fonts;
font *fonts;
int num_images;
int max_images;
image *images;
int layers;
};
/* SVG is awkward about letting us define things within symbol definitions
* so we have to delay definitions until after the symbol definition ends. */
static fz_output *
start_def(fz_context *ctx, svg_device *sdev)
{
sdev->def_count++;
if (sdev->def_count == 2)
{
if (sdev->defs == NULL)
{
if (sdev->defs_buffer == NULL)
sdev->defs_buffer = fz_new_buffer(ctx, 1024);
sdev->defs = fz_new_output_with_buffer(ctx, sdev->defs_buffer);
}
sdev->out = sdev->defs;
}
return sdev->out;
}
static fz_output *
end_def(fz_context *ctx, svg_device *sdev)
{
if (sdev->def_count > 0)
sdev->def_count--;
if (sdev->def_count == 1)
sdev->out = sdev->out_store;
if (sdev->def_count == 0 && sdev->defs_buffer != NULL)
{
fz_write_data(ctx, sdev->out, sdev->defs_buffer->data, sdev->defs_buffer->len);
sdev->defs_buffer->len = 0;
}
return sdev->out;
}
/* Helper functions */
static void
svg_path_moveto(fz_context *ctx, void *arg, float x, float y)
{
fz_output *out = (fz_output *)arg;
fz_write_printf(ctx, out, "M %g %g ", x, y);
}
static void
svg_path_lineto(fz_context *ctx, void *arg, float x, float y)
{
fz_output *out = (fz_output *)arg;
fz_write_printf(ctx, out, "L %g %g ", x, y);
}
static void
svg_path_curveto(fz_context *ctx, void *arg, float x1, float y1, float x2, float y2, float x3, float y3)
{
fz_output *out = (fz_output *)arg;
fz_write_printf(ctx, out, "C %g %g %g %g %g %g ", x1, y1, x2, y2, x3, y3);
}
static void
svg_path_close(fz_context *ctx, void *arg)
{
fz_output *out = (fz_output *)arg;
fz_write_printf(ctx, out, "Z ");
}
static const fz_path_walker svg_path_walker =
{
svg_path_moveto,
svg_path_lineto,
svg_path_curveto,
svg_path_close
};
static void
svg_dev_path(fz_context *ctx, svg_device *sdev, const fz_path *path)
{
fz_write_printf(ctx, sdev->out, " d=\"");
fz_walk_path(ctx, path, &svg_path_walker, sdev->out);
fz_write_printf(ctx, sdev->out, "\"");
}
static void
svg_dev_ctm(fz_context *ctx, svg_device *sdev, fz_matrix ctm)
{
fz_output *out = sdev->out;
if (ctm.a != 1.0f || ctm.b != 0 || ctm.c != 0 || ctm.d != 1.0f || ctm.e != 0 || ctm.f != 0)
{
fz_write_printf(ctx, out, " transform=\"matrix(%g,%g,%g,%g,%g,%g)\"",
ctm.a, ctm.b, ctm.c, ctm.d, ctm.e, ctm.f);
}
}
static void
svg_dev_stroke_state(fz_context *ctx, svg_device *sdev, const fz_stroke_state *stroke_state, fz_matrix ctm)
{
fz_output *out = sdev->out;
float exp;
exp = fz_matrix_expansion(ctm);
if (exp == 0)
exp = 1;
exp = stroke_state->linewidth/exp;
fz_write_printf(ctx, out, " stroke-width=\"%g\"", exp);
fz_write_printf(ctx, out, " stroke-linecap=\"%s\"",
(stroke_state->start_cap == FZ_LINECAP_SQUARE ? "square" :
(stroke_state->start_cap == FZ_LINECAP_ROUND ? "round" : "butt")));
if (stroke_state->dash_len != 0)
{
int i;
fz_write_printf(ctx, out, " stroke-dasharray=");
for (i = 0; i < stroke_state->dash_len; i++)
fz_write_printf(ctx, out, "%c%g", (i == 0 ? '\"' : ','), stroke_state->dash_list[i]);
fz_write_printf(ctx, out, "\"");
if (stroke_state->dash_phase != 0)
fz_write_printf(ctx, out, " stroke-dashoffset=\"%g\"", stroke_state->dash_phase);
}
if (stroke_state->linejoin == FZ_LINEJOIN_MITER || stroke_state->linejoin == FZ_LINEJOIN_MITER_XPS)
fz_write_printf(ctx, out, " stroke-miterlimit=\"%g\"", stroke_state->miterlimit);
fz_write_printf(ctx, out, " stroke-linejoin=\"%s\"",
(stroke_state->linejoin == FZ_LINEJOIN_BEVEL ? "bevel" :
(stroke_state->linejoin == FZ_LINEJOIN_ROUND ? "round" : "miter")));
}
static unsigned int
svg_hex_color(fz_context *ctx, fz_colorspace *colorspace, const float *color, fz_color_params color_params)
{
float rgb[3];
int r, g, b;
if (colorspace != fz_device_rgb(ctx))
{
fz_convert_color(ctx, colorspace, color, fz_device_rgb(ctx), rgb, NULL, color_params);
color = rgb;
}
r = fz_clampi(255 * color[0] + 0.5f, 0, 255);
g = fz_clampi(255 * color[1] + 0.5f, 0, 255);
b = fz_clampi(255 * color[2] + 0.5f, 0, 255);
return (r << 16) | (g << 8) | b;
}
static void
svg_dev_fill_color(fz_context *ctx, svg_device *sdev, fz_colorspace *colorspace, const float *color, float alpha, fz_color_params color_params)
{
fz_output *out = sdev->out;
if (colorspace)
{
int rgb = svg_hex_color(ctx, colorspace, color, color_params);
if (rgb != 0) /* black is the default value */
fz_write_printf(ctx, out, " fill=\"#%06x\"", rgb);
}
else
fz_write_printf(ctx, out, " fill=\"none\"");
if (alpha != 1)
fz_write_printf(ctx, out, " fill-opacity=\"%g\"", alpha);
}
static void
svg_dev_stroke_color(fz_context *ctx, svg_device *sdev, fz_colorspace *colorspace, const float *color, float alpha, fz_color_params color_params)
{
fz_output *out = sdev->out;
if (colorspace)
fz_write_printf(ctx, out, " fill=\"none\" stroke=\"#%06x\"", svg_hex_color(ctx, colorspace, color, color_params));
else
fz_write_printf(ctx, out, " fill=\"none\" stroke=\"none\"");
if (alpha != 1)
fz_write_printf(ctx, out, " stroke-opacity=\"%g\"", alpha);
}
static void
svg_font_family(fz_context *ctx, char buf[], int size, const char *name)
{
/* Remove "ABCDEF+" prefix and "-Bold" suffix. */
char *p = strchr(name, '+');
if (p) fz_strlcpy(buf, p+1, size);
else fz_strlcpy(buf, name, size);
p = strrchr(buf, '-');
if (p) *p = 0;
}
static int
find_first_char(fz_context *ctx, const fz_text_span *span, int i)
{
for (; i < span->len; ++i)
if (span->items[i].ucs >= 0)
return i;
return i;
}
static int
find_next_line_break(fz_context *ctx, const fz_text_span *span, fz_matrix inv_tm, int i)
{
fz_point p, old_p;
old_p.x = span->items[i].x;
old_p.y = span->items[i].y;
old_p = fz_transform_point(old_p, inv_tm);
for (++i; i < span->len; ++i)
{
if (span->items[i].ucs >= 0)
{
p.x = span->items[i].x;
p.y = span->items[i].y;
p = fz_transform_point(p, inv_tm);
if (span->wmode == 0)
{
if (p.y != old_p.y)
return i;
}
else
{
if (p.x != old_p.x)
return i;
}
old_p = p;
}
}
return i;
}
static float
svg_cluster_advance(fz_context *ctx, const fz_text_span *span, int i, int end)
{
int n = 1;
while (i + n < end && span->items[i + n].gid == -1)
++n;
if (n > 1)
return fz_advance_glyph(ctx, span->font, span->items[i].gid, span->wmode) / n;
return 0; /* this value is never used (since n==1) */
}
static void
svg_dev_text_span(fz_context *ctx, svg_device *sdev, fz_matrix ctm, const fz_text_span *span)
{
fz_output *out = sdev->out;
char font_family[100];
int is_bold, is_italic;
fz_matrix tm, inv_tm, final_tm;
fz_point p;
float font_size;
fz_text_item *it;
int start, end, i;
float cluster_advance = 0;
if (span->len == 0)
{
fz_write_printf(ctx, out, "/>\n");
return;
}
tm = span->trm;
font_size = fz_matrix_expansion(tm);
final_tm.a = tm.a / font_size;
final_tm.b = tm.b / font_size;
final_tm.c = -tm.c / font_size;
final_tm.d = -tm.d / font_size;
final_tm.e = 0;
final_tm.f = 0;
inv_tm = fz_invert_matrix(final_tm);
final_tm = fz_concat(final_tm, ctm);
tm.e = span->items[0].x;
tm.f = span->items[0].y;
svg_font_family(ctx, font_family, sizeof font_family, fz_font_name(ctx, span->font));
is_bold = fz_font_is_bold(ctx, span->font);
is_italic = fz_font_is_italic(ctx, span->font);
fz_write_printf(ctx, out, " xml:space=\"preserve\"");
fz_write_printf(ctx, out, " transform=\"matrix(%M)\"", &final_tm);
fz_write_printf(ctx, out, " font-size=\"%g\"", font_size);
fz_write_printf(ctx, out, " font-family=\"%s\"", font_family);
if (is_bold) fz_write_printf(ctx, out, " font-weight=\"bold\"");
if (is_italic) fz_write_printf(ctx, out, " font-style=\"italic\"");
if (span->wmode != 0) fz_write_printf(ctx, out, " writing-mode=\"tb\"");
fz_write_byte(ctx, out, '>');
start = find_first_char(ctx, span, 0);
while (start < span->len)
{
end = find_next_line_break(ctx, span, inv_tm, start);
p.x = span->items[start].x;
p.y = span->items[start].y;
p = fz_transform_point(p, inv_tm);
if (span->items[start].gid >= 0)
cluster_advance = svg_cluster_advance(ctx, span, start, end);
if (span->wmode == 0)
fz_write_printf(ctx, out, "<tspan y=\"%g\" x=\"%g", p.y, p.x);
else
fz_write_printf(ctx, out, "<tspan x=\"%g\" y=\"%g", p.x, p.y);
for (i = start + 1; i < end; ++i)
{
it = &span->items[i];
if (it->gid >= 0)
cluster_advance = svg_cluster_advance(ctx, span, i, end);
if (it->ucs >= 0)
{
if (it->gid >= 0)
{
p.x = it->x;
p.y = it->y;
p = fz_transform_point(p, inv_tm);
}
else
{
/* we have no glyph (such as in a ligature) -- advance a bit */
if (span->wmode == 0)
p.x += font_size * cluster_advance;
else
p.y += font_size * cluster_advance;
}
fz_write_printf(ctx, out, " %g", span->wmode == 0 ? p.x : p.y);
}
}
fz_write_printf(ctx, out, "\">");
for (i = start; i < end; ++i)
{
it = &span->items[i];
if (it->ucs >= 0)
{
int c = it->ucs;
if (c >= 32 && c <= 127 && c != '<' && c != '&' && c != '>')
fz_write_byte(ctx, out, c);
else
fz_write_printf(ctx, out, "&#x%04x;", c);
}
}
fz_write_printf(ctx, out, "</tspan>");
start = find_first_char(ctx, span, end);
}
fz_write_printf(ctx, out, "</text>\n");
}
static font *
svg_dev_text_span_as_paths_defs(fz_context *ctx, fz_device *dev, fz_text_span *span, fz_matrix ctm)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
int i, font_idx;
font *fnt;
fz_matrix shift = fz_identity;
for (font_idx = 0; font_idx < sdev->num_fonts; font_idx++)
{
if (sdev->fonts[font_idx].font == span->font)
break;
}
if (font_idx == sdev->num_fonts)
{
/* New font */
if (font_idx == sdev->max_fonts)
{
int newmax = sdev->max_fonts * 2;
if (newmax == 0)
newmax = 4;
sdev->fonts = fz_realloc_array(ctx, sdev->fonts, newmax, font);
memset(&sdev->fonts[font_idx], 0, (newmax - font_idx) * sizeof(font));
sdev->max_fonts = newmax;
}
sdev->fonts[font_idx].id = sdev->id++;
sdev->fonts[font_idx].font = fz_keep_font(ctx, span->font);
sdev->num_fonts++;
}
fnt = &sdev->fonts[font_idx];
for (i=0; i < span->len; i++)
{
fz_text_item *it = &span->items[i];
int gid = it->gid;
if (gid < 0)
continue;
if (gid >= fnt->max_sentlist)
{
int j;
fnt->sentlist = fz_realloc_array(ctx, fnt->sentlist, gid+1, glyph);
for (j = fnt->max_sentlist; j <= gid; j++)
{
fnt->sentlist[j].x_off = FLT_MIN;
fnt->sentlist[j].y_off = FLT_MIN;
}
fnt->max_sentlist = gid+1;
}
if (fnt->sentlist[gid].x_off == FLT_MIN)
{
/* Need to send this one */
fz_rect rect;
fz_path *path;
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<symbol id=\"font_%x_%x\">\n", fnt->id, gid);
if (fz_font_ft_face(ctx, span->font))
{
path = fz_outline_glyph(ctx, span->font, gid, fz_identity);
if (path)
{
rect = fz_bound_path(ctx, path, NULL, fz_identity);
shift.e = -rect.x0;
shift.f = -rect.y0;
fz_transform_path(ctx, path, shift);
fz_write_printf(ctx, out, "<path");
svg_dev_path(ctx, sdev, path);
fz_write_printf(ctx, out, "/>\n");
fz_drop_path(ctx, path);
}
else
{
rect = fz_empty_rect;
}
}
else if (fz_font_t3_procs(ctx, span->font))
{
rect = fz_bound_glyph(ctx, span->font, gid, fz_identity);
shift.e = -rect.x0;
shift.f = -rect.y0;
fz_run_t3_glyph(ctx, span->font, gid, shift, dev);
}
fz_write_printf(ctx, out, "</symbol>\n");
out = end_def(ctx, sdev);
fnt->sentlist[gid].x_off = rect.x0;
fnt->sentlist[gid].y_off = rect.y0;
}
}
return fnt;
}
static void
svg_dev_text_span_as_paths_fill(fz_context *ctx, fz_device *dev, const fz_text_span *span, fz_matrix ctm,
fz_colorspace *colorspace, const float *color, float alpha, font *fnt, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_matrix shift = { 1, 0, 0, 1, 0, 0};
fz_matrix trm, mtx;
int i;
/* Rely on the fact that trm.{e,f} == 0 */
trm.a = span->trm.a;
trm.b = span->trm.b;
trm.c = span->trm.c;
trm.d = span->trm.d;
trm.e = 0;
trm.f = 0;
for (i=0; i < span->len; i++)
{
fz_text_item *it = &span->items[i];
int gid = it->gid;
if (gid < 0)
continue;
shift.e = fnt->sentlist[gid].x_off;
shift.f = fnt->sentlist[gid].y_off;
trm.e = it->x;
trm.f = it->y;
mtx = fz_concat(shift, fz_concat(trm, ctm));
fz_write_printf(ctx, out, "<use xlink:href=\"#font_%x_%x\"", fnt->id, gid);
svg_dev_ctm(ctx, sdev, mtx);
svg_dev_fill_color(ctx, sdev, colorspace, color, alpha, color_params);
fz_write_printf(ctx, out, "/>\n");
}
}
static void
svg_dev_text_span_as_paths_stroke(fz_context *ctx, fz_device *dev, const fz_text_span *span,
const fz_stroke_state *stroke, fz_matrix ctm,
fz_colorspace *colorspace, const float *color, float alpha, font *fnt, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_matrix shift = { 1, 0, 0, 1, 0, 0};
fz_matrix trm, mtx;
int i;
/* Rely on the fact that trm.{e,f} == 0 */
trm.a = span->trm.a;
trm.b = span->trm.b;
trm.c = span->trm.c;
trm.d = span->trm.d;
trm.e = 0;
trm.f = 0;
for (i=0; i < span->len; i++)
{
fz_text_item *it = &span->items[i];
int gid = it->gid;
if (gid < 0)
continue;
shift.e = fnt->sentlist[gid].x_off;
shift.f = fnt->sentlist[gid].y_off;
trm.e = it->x;
trm.f = it->y;
mtx = fz_concat(shift, fz_concat(trm, ctm));
fz_write_printf(ctx, out, "<use xlink:href=\"#font_%x_%x\"", fnt->id, gid);
svg_dev_stroke_state(ctx, sdev, stroke, mtx);
svg_dev_ctm(ctx, sdev, mtx);
svg_dev_stroke_color(ctx, sdev, colorspace, color, alpha, color_params);
fz_write_printf(ctx, out, "/>\n");
}
}
/* Entry points */
static void
svg_dev_fill_path(fz_context *ctx, fz_device *dev, const fz_path *path, int even_odd, fz_matrix ctm,
fz_colorspace *colorspace, const float *color, float alpha, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_write_printf(ctx, out, "<path");
svg_dev_ctm(ctx, sdev, ctm);
svg_dev_path(ctx, sdev, path);
svg_dev_fill_color(ctx, sdev, colorspace, color, alpha, color_params);
if (even_odd)
fz_write_printf(ctx, out, " fill-rule=\"evenodd\"");
fz_write_printf(ctx, out, "/>\n");
}
static void
svg_dev_stroke_path(fz_context *ctx, fz_device *dev, const fz_path *path, const fz_stroke_state *stroke, fz_matrix ctm,
fz_colorspace *colorspace, const float *color, float alpha, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_write_printf(ctx, out, "<path");
svg_dev_ctm(ctx, sdev, ctm);
svg_dev_stroke_state(ctx, sdev, stroke, fz_identity);
svg_dev_stroke_color(ctx, sdev, colorspace, color, alpha, color_params);
svg_dev_path(ctx, sdev, path);
fz_write_printf(ctx, out, "/>\n");
}
static void
svg_dev_clip_path(fz_context *ctx, fz_device *dev, const fz_path *path, int even_odd, fz_matrix ctm, fz_rect scissor)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out;
int num = sdev->id++;
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<clipPath id=\"cp%d\">\n", num);
fz_write_printf(ctx, out, "<path");
svg_dev_ctm(ctx, sdev, ctm);
svg_dev_path(ctx, sdev, path);
if (even_odd)
fz_write_printf(ctx, out, " fill-rule=\"evenodd\"");
fz_write_printf(ctx, out, "/>\n</clipPath>\n");
out = end_def(ctx, sdev);
fz_write_printf(ctx, out, "<g clip-path=\"url(#cp%d)\">\n", num);
}
static void
svg_dev_clip_stroke_path(fz_context *ctx, fz_device *dev, const fz_path *path, const fz_stroke_state *stroke, fz_matrix ctm, fz_rect scissor)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out;
fz_rect bounds;
int num = sdev->id++;
float white[3] = { 1, 1, 1 };
bounds = fz_bound_path(ctx, path, stroke, ctm);
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<mask id=\"ma%d\" x=\"%g\" y=\"%g\" width=\"%g\" height=\"%g\" maskUnits=\"userSpaceOnUse\" maskContentUnits=\"userSpaceOnUse\">\n",
num, bounds.x0, bounds.y0, bounds.x1 - bounds.x0, bounds.y1 - bounds.y0);
fz_write_printf(ctx, out, "<path");
svg_dev_ctm(ctx, sdev, ctm);
svg_dev_stroke_state(ctx, sdev, stroke, fz_identity);
svg_dev_stroke_color(ctx, sdev, fz_device_rgb(ctx), white, 1, fz_default_color_params);
svg_dev_path(ctx, sdev, path);
fz_write_printf(ctx, out, "/>\n</mask>\n");
out = end_def(ctx, sdev);
fz_write_printf(ctx, out, "<g mask=\"url(#ma%d)\">\n", num);
}
static void
svg_dev_fill_text(fz_context *ctx, fz_device *dev, const fz_text *text, fz_matrix ctm,
fz_colorspace *colorspace, const float *color, float alpha, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
font *fnt;
fz_text_span *span;
if (sdev->text_as_text)
{
for (span = text->head; span; span = span->next)
{
fz_write_printf(ctx, out, "<text");
svg_dev_fill_color(ctx, sdev, colorspace, color, alpha, color_params);
svg_dev_text_span(ctx, sdev, ctm, span);
}
}
else
{
for (span = text->head; span; span = span->next)
{
fnt = svg_dev_text_span_as_paths_defs(ctx, dev, span, ctm);
svg_dev_text_span_as_paths_fill(ctx, dev, span, ctm, colorspace, color, alpha, fnt, color_params);
}
}
}
static void
svg_dev_stroke_text(fz_context *ctx, fz_device *dev, const fz_text *text, const fz_stroke_state *stroke, fz_matrix ctm,
fz_colorspace *colorspace, const float *color, float alpha, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
font *fnt;
fz_text_span *span;
if (sdev->text_as_text)
{
for (span = text->head; span; span = span->next)
{
fz_write_printf(ctx, out, "<text");
svg_dev_fill_color(ctx, sdev, colorspace, color, alpha, color_params);
svg_dev_text_span(ctx, sdev, ctm, span);
}
}
else
{
for (span = text->head; span; span = span->next)
{
fnt = svg_dev_text_span_as_paths_defs(ctx, dev, span, ctm);
svg_dev_text_span_as_paths_stroke(ctx, dev, span, stroke, ctm, colorspace, color, alpha, fnt, color_params);
}
}
}
static void
svg_dev_clip_text(fz_context *ctx, fz_device *dev, const fz_text *text, fz_matrix ctm, fz_rect scissor)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_rect bounds;
int num = sdev->id++;
float white[3] = { 1, 1, 1 };
font *fnt;
fz_text_span *span;
bounds = fz_bound_text(ctx, text, NULL, ctm);
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<mask id=\"ma%d\" x=\"%g\" y=\"%g\" width=\"%g\" height=\"%g\"",
num, bounds.x0, bounds.y0, bounds.x1 - bounds.x0, bounds.y1 - bounds.y0);
fz_write_printf(ctx, out, " maskUnits=\"userSpaceOnUse\" maskContentUnits=\"userSpaceOnUse\">\n");
if (sdev->text_as_text)
{
for (span = text->head; span; span = span->next)
{
fz_write_printf(ctx, out, "<text");
svg_dev_fill_color(ctx, sdev, fz_device_rgb(ctx), white, 1, fz_default_color_params);
svg_dev_text_span(ctx, sdev, ctm, span);
}
}
else
{
for (span = text->head; span; span = span->next)
{
fnt = svg_dev_text_span_as_paths_defs(ctx, dev, span, ctm);
svg_dev_text_span_as_paths_fill(ctx, dev, span, ctm, fz_device_rgb(ctx), white, 1.0f, fnt, fz_default_color_params);
}
}
fz_write_printf(ctx, out, "</mask>\n");
out = end_def(ctx, sdev);
fz_write_printf(ctx, out, "<g mask=\"url(#ma%d)\">\n", num);
}
static void
svg_dev_clip_stroke_text(fz_context *ctx, fz_device *dev, const fz_text *text, const fz_stroke_state *stroke, fz_matrix ctm, fz_rect scissor)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out;
fz_rect bounds;
int num = sdev->id++;
float white[3] = { 255, 255, 255 };
font *fnt;
fz_text_span *span;
bounds = fz_bound_text(ctx, text, NULL, ctm);
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<mask id=\"ma%d\" x=\"%g\" y=\"%g\" width=\"%g\" height=\"%g\"",
num, bounds.x0, bounds.y0, bounds.x1 - bounds.x0, bounds.y1 - bounds.y0);
fz_write_printf(ctx, out, " maskUnits=\"userSpaceOnUse\" maskContentUnits=\"userSpaceOnUse\">\n");
if (sdev->text_as_text)
{
for (span = text->head; span; span = span->next)
{
fz_write_printf(ctx, out, "<text");
svg_dev_stroke_state(ctx, sdev, stroke, fz_identity);
svg_dev_stroke_color(ctx, sdev, fz_device_rgb(ctx), white, 1, fz_default_color_params);
svg_dev_text_span(ctx, sdev, ctm, span);
}
}
else
{
for (span = text->head; span; span = span->next)
{
fnt = svg_dev_text_span_as_paths_defs(ctx, dev, span, ctm);
svg_dev_text_span_as_paths_stroke(ctx, dev, span, stroke, ctm, fz_device_rgb(ctx), white, 1.0f, fnt, fz_default_color_params);
}
}
fz_write_printf(ctx, out, "</mask>\n");
out = end_def(ctx, sdev);
fz_write_printf(ctx, out, "<g mask=\"url(#ma%d)\">\n", num);
}
static void
svg_dev_ignore_text(fz_context *ctx, fz_device *dev, const fz_text *text, fz_matrix ctm)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_text_span *span;
float black[3] = { 0, 0, 0};
if (sdev->text_as_text)
{
for (span = text->head; span; span = span->next)
{
fz_write_printf(ctx, out, "<text");
svg_dev_fill_color(ctx, sdev, fz_device_rgb(ctx), black, 0.0f, fz_default_color_params);
svg_dev_text_span(ctx, sdev, ctm, span);
}
}
}
/* We spot repeated images, and send them just once using
* symbols. Unfortunately, for pathological files, such
* as the example in Bug695988, this can cause viewers to
* have conniptions. We therefore have an option that is
* made to avoid this (reuse-images=no). */
static void
svg_send_image(fz_context *ctx, svg_device *sdev, fz_image *img, fz_color_params color_params)
{
fz_output *out = sdev->out;
int i;
int id;
if (sdev->reuse_images)
{
for (i = sdev->num_images-1; i >= 0; i--)
if (img == sdev->images[i].image)
break;
if (i >= 0)
{
fz_write_printf(ctx, out, "<use xlink:href=\"#im%d\" x=\"0\" y=\"0\" width=\"%d\" height=\"%d\"/>\n",
sdev->images[i].id, img->w, img->h);
return;
}
/* We need to send this image for the first time */
if (sdev->num_images == sdev->max_images)
{
int new_max = sdev->max_images * 2;
if (new_max == 0)
new_max = 32;
sdev->images = fz_realloc_array(ctx, sdev->images, new_max, image);
sdev->max_images = new_max;
}
id = sdev->id++;
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<symbol id=\"im%d\" viewBox=\"0 0 %d %d\">\n", id, img->w, img->h);
fz_write_printf(ctx, out, "<image width=\"%d\" height=\"%d\" xlink:href=\"", img->w, img->h);
fz_write_image_as_data_uri(ctx, out, img);
fz_write_printf(ctx, out, "\"/>\n");
fz_write_printf(ctx, out, "</symbol>\n");
out = end_def(ctx, sdev);
sdev->images[sdev->num_images].id = id;
sdev->images[sdev->num_images].image = fz_keep_image(ctx, img);
sdev->num_images++;
fz_write_printf(ctx, out, "<use xlink:href=\"#im%d\" x=\"0\" y=\"0\" width=\"%d\" height=\"%d\"/>\n",
id, img->w, img->h);
}
else
{
fz_write_printf(ctx, out, "<image width=\"%d\" height=\"%d\" xlink:href=\"", img->w, img->h);
fz_write_image_as_data_uri(ctx, out, img);
fz_write_printf(ctx, out, "\"/>\n");
}
}
static void
svg_dev_fill_image(fz_context *ctx, fz_device *dev, fz_image *image, fz_matrix ctm, float alpha, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_matrix local_ctm = ctm;
fz_matrix scale = { 0 };
scale.a = 1.0f / image->w;
scale.d = 1.0f / image->h;
local_ctm = fz_concat(scale, ctm);
fz_write_printf(ctx, out, "<g");
if (alpha != 1.0f)
fz_write_printf(ctx, out, " opacity=\"%g\"", alpha);
svg_dev_ctm(ctx, sdev, local_ctm);
fz_write_printf(ctx, out, ">\n");
svg_send_image(ctx, sdev, image, color_params);
fz_write_printf(ctx, out, "</g>\n");
}
static void
svg_dev_fill_shade(fz_context *ctx, fz_device *dev, fz_shade *shade, fz_matrix ctm, float alpha, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_irect bbox;
fz_pixmap *pix;
bbox = fz_round_rect(fz_intersect_rect(fz_bound_shade(ctx, shade, ctm), fz_device_current_scissor(ctx, dev)));
if (fz_is_empty_irect(bbox))
return;
pix = fz_new_pixmap_with_bbox(ctx, fz_device_rgb(ctx), bbox, NULL, 1);
fz_clear_pixmap(ctx, pix);
fz_try(ctx)
{
fz_paint_shade(ctx, shade, NULL, ctm, pix, color_params, bbox, NULL);
if (alpha != 1.0f)
fz_write_printf(ctx, out, "<g opacity=\"%g\">\n", alpha);
fz_write_printf(ctx, out, "<image x=\"%d\" y=\"%d\" width=\"%d\" height=\"%d\" xlink:href=\"", pix->x, pix->y, pix->w, pix->h);
fz_write_pixmap_as_data_uri(ctx, out, pix);
fz_write_printf(ctx, out, "\"/>\n");
if (alpha != 1.0f)
fz_write_printf(ctx, out, "</g>\n");
}
fz_always(ctx)
{
fz_drop_pixmap(ctx, pix);
}
fz_catch(ctx)
{
fz_rethrow(ctx);
}
}
static void
svg_dev_fill_image_mask(fz_context *ctx, fz_device *dev, fz_image *image, fz_matrix ctm,
fz_colorspace *colorspace, const float *color, float alpha, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out;
fz_matrix local_ctm = ctm;
fz_matrix scale = { 0 };
int mask = sdev->id++;
scale.a = 1.0f / image->w;
scale.d = 1.0f / image->h;
local_ctm = fz_concat(scale, ctm);
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<mask id=\"ma%d\">\n", mask);
svg_send_image(ctx, sdev, image, color_params);
fz_write_printf(ctx, out, "</mask>\n");
out = end_def(ctx, sdev);
fz_write_printf(ctx, out, "<rect x=\"0\" y=\"0\" width=\"%d\" height=\"%d\"", image->w, image->h);
svg_dev_fill_color(ctx, sdev, colorspace, color, alpha, color_params);
svg_dev_ctm(ctx, sdev, local_ctm);
fz_write_printf(ctx, out, " mask=\"url(#ma%d)\"/>\n", mask);
}
static void
svg_dev_clip_image_mask(fz_context *ctx, fz_device *dev, fz_image *image, fz_matrix ctm, fz_rect scissor)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out;
fz_matrix local_ctm = ctm;
fz_matrix scale = { 0 };
int mask = sdev->id++;
scale.a = 1.0f / image->w;
scale.d = 1.0f / image->h;
local_ctm = fz_concat(scale, ctm);
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<mask id=\"ma%d\">\n<g", mask);
svg_dev_ctm(ctx, sdev, local_ctm);
fz_write_printf(ctx, out, ">\n");
svg_send_image(ctx, sdev, image, fz_default_color_params/* FIXME */);
fz_write_printf(ctx, out, "</g>\n</mask>\n");
out = end_def(ctx, sdev);
fz_write_printf(ctx, out, "<g mask=\"url(#ma%d)\">\n", mask);
}
static void
svg_dev_pop_clip(fz_context *ctx, fz_device *dev)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
/* FIXME */
fz_write_printf(ctx, out, "</g>\n");
}
static void
svg_dev_begin_mask(fz_context *ctx, fz_device *dev, fz_rect bbox, int luminosity, fz_colorspace *colorspace, const float *color, fz_color_params color_params)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out;
int mask = sdev->id++;
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<mask id=\"ma%d\">\n", mask);
if (dev->container_len > 0)
dev->container[dev->container_len-1].user = mask;
}
static void
svg_dev_end_mask(fz_context *ctx, fz_device *dev)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
int mask = 0;
if (dev->container_len > 0)
mask = dev->container[dev->container_len-1].user;
fz_write_printf(ctx, out, "\"/>\n</mask>\n");
out = end_def(ctx, sdev);
fz_write_printf(ctx, out, "<g mask=\"url(#ma%d)\">\n", mask);
}
static void
svg_dev_begin_group(fz_context *ctx, fz_device *dev, fz_rect bbox, fz_colorspace *cs, int isolated, int knockout, int blendmode, float alpha)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
/* SVG only supports normal/multiply/screen/darken/lighten,
* but we'll send them all, as the spec says that unrecognised
* ones are treated as normal. */
static char *blend_names[] = {
"normal", /* FZ_BLEND_NORMAL */
"multiply", /* FZ_BLEND_MULTIPLY */
"screen", /* FZ_BLEND_SCREEN */
"overlay", /* FZ_BLEND_OVERLAY */
"darken", /* FZ_BLEND_DARKEN */
"lighten", /* FZ_BLEND_LIGHTEN */
"color_dodge", /* FZ_BLEND_COLOR_DODGE */
"color_burn", /* FZ_BLEND_COLOR_BURN */
"hard_light", /* FZ_BLEND_HARD_LIGHT */
"soft_light", /* FZ_BLEND_SOFT_LIGHT */
"difference", /* FZ_BLEND_DIFFERENCE */
"exclusion", /* FZ_BLEND_EXCLUSION */
"hue", /* FZ_BLEND_HUE */
"saturation", /* FZ_BLEND_SATURATION */
"color", /* FZ_BLEND_COLOR */
"luminosity", /* FZ_BLEND_LUMINOSITY */
};
if (blendmode < FZ_BLEND_NORMAL || blendmode > FZ_BLEND_LUMINOSITY)
blendmode = FZ_BLEND_NORMAL;
if (blendmode != FZ_BLEND_NORMAL && (sdev->blend_bitmask & (1<<blendmode)) == 0)
{
sdev->blend_bitmask |= (1<<blendmode);
out = start_def(ctx, sdev);
fz_write_printf(ctx, out,
"<filter id=\"blend_%d\"><feBlend mode=\"%s\" in2=\"BackgroundImage\" in=\"SourceGraphic\"/></filter>\n",
blendmode, blend_names[blendmode]);
out = end_def(ctx, sdev);
}
/* SVG 1.1 doesn't support adequate blendmodes/knockout etc, so just ignore it for now */
if (alpha == 1)
fz_write_printf(ctx, out, "<g");
else
fz_write_printf(ctx, out, "<g opacity=\"%g\"", alpha);
if (blendmode != FZ_BLEND_NORMAL)
fz_write_printf(ctx, out, " filter=\"url(#blend_%d)\"", blendmode);
fz_write_printf(ctx, out, ">\n");
}
static void
svg_dev_end_group(fz_context *ctx, fz_device *dev)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
fz_write_printf(ctx, out, "</g>\n");
}
static int
svg_dev_begin_tile(fz_context *ctx, fz_device *dev, fz_rect area, fz_rect view, float xstep, float ystep, fz_matrix ctm, int id)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out;
int num;
tile *t;
if (sdev->num_tiles == sdev->max_tiles)
{
int n = (sdev->num_tiles == 0 ? 4 : sdev->num_tiles * 2);
sdev->tiles = fz_realloc_array(ctx, sdev->tiles, n, tile);
sdev->max_tiles = n;
}
num = sdev->num_tiles++;
t = &sdev->tiles[num];
t->area = area;
t->view = view;
t->ctm = ctm;
t->pattern = sdev->id++;
xstep = fabsf(xstep);
ystep = fabsf(ystep);
if (xstep == 0 || ystep == 0) {
fz_warn(ctx, "Pattern cannot have x or ystep == 0.");
if (xstep == 0)
xstep = 1;
if (ystep == 0)
ystep = 1;
}
t->step.x = xstep;
t->step.y = ystep;
/* view = area of our reference tile in pattern space.
* area = area to tile into in pattern space.
* xstep/ystep = pattern repeat step in pattern space.
* All of these need to be transformed by ctm to get to device space.
* SVG only allows us to specify pattern tiles as axis aligned
* rectangles, so we send these through as is, and ensure that the
* correct matrix is used on the fill.
*/
/* The first thing we do is to capture the contents of the pattern
* as a symbol we can reuse. */
out = start_def(ctx, sdev);
fz_write_printf(ctx, out, "<symbol id=\"pac%d\">\n", t->pattern);
return 0;
}
static void
svg_dev_end_tile(fz_context *ctx, fz_device *dev)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
int num, cp = -1;
tile *t;
fz_matrix inverse;
float x, y, w, h;
if (sdev->num_tiles == 0)
return;
num = --sdev->num_tiles;
t = &sdev->tiles[num];
fz_write_printf(ctx, out, "</symbol>\n");
/* In svg, the reference tile is taken from (x,y) to (x+width,y+height)
* and is repeated at (x+n*width,y+m*height) for all integer n and m.
* This means that width and height generally correspond to xstep and
* ystep. There are exceptional cases where we have to break this
* though; when xstep/ystep are smaller than the width/height of the
* pattern tile, we need to render the pattern contents several times
* to ensure that the pattern tile contains everything. */
fz_write_printf(ctx, out, "<pattern id=\"pa%d\" patternUnits=\"userSpaceOnUse\" patternContentUnits=\"userSpaceOnUse\"",
t->pattern);
fz_write_printf(ctx, out, " x=\"0\" y=\"0\" width=\"%g\" height=\"%g\">\n",
t->step.x, t->step.y);
if (t->view.x0 > 0 || t->step.x < t->view.x1 || t->view.y0 > 0 || t->step.y < t->view.y1)
{
cp = sdev->id++;
fz_write_printf(ctx, out, "<clipPath id=\"cp%d\">\n", cp);
fz_write_printf(ctx, out, "<path d=\"M %g %g L %g %g L %g %g L %g %g Z\"/>\n",
t->view.x0, t->view.y0,
t->view.x1, t->view.y0,
t->view.x1, t->view.y1,
t->view.x0, t->view.y1);
fz_write_printf(ctx, out, "</clipPath>\n");
fz_write_printf(ctx, out, "<g clip-path=\"url(#cp%d)\">\n", cp);
}
/* All the pattern contents will have their own ctm applied. Let's
* undo the current one to allow for this */
inverse = fz_invert_matrix(t->ctm);
fz_write_printf(ctx, out, "<g");
svg_dev_ctm(ctx, sdev, inverse);
fz_write_printf(ctx, out, ">\n");
w = t->view.x1 - t->view.x0;
h = t->view.y1 - t->view.y0;
for (x = 0; x > -w; x -= t->step.x)
for (y = 0; y > -h; y -= t->step.y)
fz_write_printf(ctx, out, "<use x=\"%g\" y=\"%g\" xlink:href=\"#pac%d\"/>\n", x, y, t->pattern);
fz_write_printf(ctx, out, "</g>\n");
if (cp != -1)
fz_write_printf(ctx, out, "</g>\n");
fz_write_printf(ctx, out, "</pattern>\n");
out = end_def(ctx, sdev);
/* Finally, fill a rectangle with the pattern. */
fz_write_printf(ctx, out, "<rect");
svg_dev_ctm(ctx, sdev, t->ctm);
fz_write_printf(ctx, out, " fill=\"url(#pa%d)\" x=\"%g\" y=\"%g\" width=\"%g\" height=\"%g\"/>\n",
t->pattern, t->area.x0, t->area.y0, t->area.x1 - t->area.x0, t->area.y1 - t->area.y0);
}
static void
svg_dev_begin_layer(fz_context *ctx, fz_device *dev, const char *name)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
sdev->layers++;
fz_write_printf(ctx, out, "<g id=\"Layer-%d\" data-name=\"%s\">\n", sdev->layers, name);
}
static void
svg_dev_end_layer(fz_context *ctx, fz_device *dev)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
if (sdev->layers == 0)
return;
sdev->layers--;
fz_write_printf(ctx, out, "</g>\n");
}
static void
svg_dev_close_device(fz_context *ctx, fz_device *dev)
{
svg_device *sdev = (svg_device*)dev;
fz_output *out = sdev->out;
while (sdev->layers > 0)
{
fz_write_printf(ctx, out, "</g>\n");
sdev->layers--;
}
if (sdev->save_id)
*sdev->save_id = sdev->id;
fz_write_printf(ctx, out, "</g>\n");
fz_write_printf(ctx, out, "</svg>\n");
}
static void
svg_dev_drop_device(fz_context *ctx, fz_device *dev)
{
svg_device *sdev = (svg_device*)dev;
int i;
fz_free(ctx, sdev->tiles);
fz_drop_buffer(ctx, sdev->defs_buffer);
fz_drop_output(ctx, sdev->defs);
for (i = 0; i < sdev->num_fonts; i++)
{
fz_drop_font(ctx, sdev->fonts[i].font);
fz_free(ctx, sdev->fonts[i].sentlist);
}
fz_free(ctx, sdev->fonts);
for (i = 0; i < sdev->num_images; i++)
{
fz_drop_image(ctx, sdev->images[i].image);
}
fz_free(ctx, sdev->images);
}
/*
Create a device that outputs (single page)
SVG files to the given output stream.
output: The output stream to send the constructed SVG page to.
page_width, page_height: The page dimensions to use (in points).
text_format: How to emit text. One of the following values:
FZ_SVG_TEXT_AS_TEXT: As <text> elements with possible layout errors and mismatching fonts.
FZ_SVG_TEXT_AS_PATH: As <path> elements with exact visual appearance.
reuse_images: Share image resources using <symbol> definitions.
id: ID parameter to keep generated IDs unique across SVG files.
*/
fz_device *fz_new_svg_device_with_id(fz_context *ctx, fz_output *out, float page_width, float page_height, int text_format, int reuse_images, int *id)
{
svg_device *dev = fz_new_derived_device(ctx, svg_device);
dev->super.close_device = svg_dev_close_device;
dev->super.drop_device = svg_dev_drop_device;
dev->super.fill_path = svg_dev_fill_path;
dev->super.stroke_path = svg_dev_stroke_path;
dev->super.clip_path = svg_dev_clip_path;
dev->super.clip_stroke_path = svg_dev_clip_stroke_path;
dev->super.fill_text = svg_dev_fill_text;
dev->super.stroke_text = svg_dev_stroke_text;
dev->super.clip_text = svg_dev_clip_text;
dev->super.clip_stroke_text = svg_dev_clip_stroke_text;
dev->super.ignore_text = svg_dev_ignore_text;
dev->super.fill_shade = svg_dev_fill_shade;
dev->super.fill_image = svg_dev_fill_image;
dev->super.fill_image_mask = svg_dev_fill_image_mask;
dev->super.clip_image_mask = svg_dev_clip_image_mask;
dev->super.pop_clip = svg_dev_pop_clip;
dev->super.begin_mask = svg_dev_begin_mask;
dev->super.end_mask = svg_dev_end_mask;
dev->super.begin_group = svg_dev_begin_group;
dev->super.end_group = svg_dev_end_group;
dev->super.begin_tile = svg_dev_begin_tile;
dev->super.end_tile = svg_dev_end_tile;
dev->super.begin_layer = svg_dev_begin_layer;
dev->super.end_layer = svg_dev_end_layer;
dev->out = out;
dev->out_store = out;
dev->save_id = id;
dev->id = id ? *id : 0;
dev->layers = 0;
dev->text_as_text = (text_format == FZ_SVG_TEXT_AS_TEXT);
dev->reuse_images = reuse_images;
fz_write_printf(ctx, out, "<?xml version=\"1.0\" encoding=\"UTF-8\" standalone=\"no\"?>\n");
fz_write_printf(ctx, out, "<!DOCTYPE svg PUBLIC \"-//W3C//DTD SVG 1.1//EN\" \"http://www.w3.org/Graphics/SVG/1.1/DTD/svg11.dtd\">\n");
fz_write_printf(ctx, out, "<svg xmlns=\"http://www.w3.org/2000/svg\" "
"xmlns:xlink=\"http://www.w3.org/1999/xlink\" version=\"1.1\" "
"width=\"%gpt\" height=\"%gpt\" viewBox=\"0 0 %g %g\">\n",
page_width, page_height, page_width, page_height);
fz_write_printf(ctx, out, "<g enable-background=\"new\">\n");
return (fz_device*)dev;
}
fz_device *fz_new_svg_device(fz_context *ctx, fz_output *out, float page_width, float page_height, int text_format, int reuse_images)
{
return fz_new_svg_device_with_id(ctx, out, page_width, page_height, text_format, reuse_images, NULL);
}