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1 // stb_truetype.h - v1.26 - public domain
2 // authored from 2009-2021 by Sean Barrett / RAD Game Tools
3 //
4 // =======================================================================
5 //
6 // NO SECURITY GUARANTEE -- DO NOT USE THIS ON UNTRUSTED FONT FILES
7 //
8 // This library does no range checking of the offsets found in the file,
9 // meaning an attacker can use it to read arbitrary memory.
10 //
11 // =======================================================================
12 //
13 // This library processes TrueType files:
14 // parse files
15 // extract glyph metrics
16 // extract glyph shapes
17 // render glyphs to one-channel bitmaps with antialiasing (box filter)
18 // render glyphs to one-channel SDF bitmaps (signed-distance field/function)
19 //
20 // Todo:
21 // non-MS cmaps
22 // crashproof on bad data
23 // hinting? (no longer patented)
24 // cleartype-style AA?
25 // optimize: use simple memory allocator for intermediates
26 // optimize: build edge-list directly from curves
27 // optimize: rasterize directly from curves?
28 //
29 // ADDITIONAL CONTRIBUTORS
30 //
31 // Mikko Mononen: compound shape support, more cmap formats
32 // Tor Andersson: kerning, subpixel rendering
33 // Dougall Johnson: OpenType / Type 2 font handling
34 // Daniel Ribeiro Maciel: basic GPOS-based kerning
35 //
36 // Misc other:
37 // Ryan Gordon
38 // Simon Glass
39 // github:IntellectualKitty
40 // Imanol Celaya
41 // Daniel Ribeiro Maciel
42 //
43 // Bug/warning reports/fixes:
44 // "Zer" on mollyrocket Fabian "ryg" Giesen github:NiLuJe
45 // Cass Everitt Martins Mozeiko github:aloucks
46 // stoiko (Haemimont Games) Cap Petschulat github:oyvindjam
47 // Brian Hook Omar Cornut github:vassvik
48 // Walter van Niftrik Ryan Griege
49 // David Gow Peter LaValle
50 // David Given Sergey Popov
51 // Ivan-Assen Ivanov Giumo X. Clanjor
52 // Anthony Pesch Higor Euripedes
53 // Johan Duparc Thomas Fields
54 // Hou Qiming Derek Vinyard
55 // Rob Loach Cort Stratton
56 // Kenney Phillis Jr. Brian Costabile
57 // Ken Voskuil (kaesve)
58 //
59 // VERSION HISTORY
60 //
61 // 1.26 (2021-08-28) fix broken rasterizer
62 // 1.25 (2021-07-11) many fixes
63 // 1.24 (2020-02-05) fix warning
64 // 1.23 (2020-02-02) query SVG data for glyphs; query whole kerning table (but only kern not GPOS)
65 // 1.22 (2019-08-11) minimize missing-glyph duplication; fix kerning if both 'GPOS' and 'kern' are defined
66 // 1.21 (2019-02-25) fix warning
67 // 1.20 (2019-02-07) PackFontRange skips missing codepoints; GetScaleFontVMetrics()
68 // 1.19 (2018-02-11) GPOS kerning, STBTT_fmod
69 // 1.18 (2018-01-29) add missing function
70 // 1.17 (2017-07-23) make more arguments const; doc fix
71 // 1.16 (2017-07-12) SDF support
72 // 1.15 (2017-03-03) make more arguments const
73 // 1.14 (2017-01-16) num-fonts-in-TTC function
74 // 1.13 (2017-01-02) support OpenType fonts, certain Apple fonts
75 // 1.12 (2016-10-25) suppress warnings about casting away const with -Wcast-qual
76 // 1.11 (2016-04-02) fix unused-variable warning
77 // 1.10 (2016-04-02) user-defined fabs(); rare memory leak; remove duplicate typedef
78 // 1.09 (2016-01-16) warning fix; avoid crash on outofmem; use allocation userdata properly
79 // 1.08 (2015-09-13) document stbtt_Rasterize(); fixes for vertical & horizontal edges
80 // 1.07 (2015-08-01) allow PackFontRanges to accept arrays of sparse codepoints;
81 // variant PackFontRanges to pack and render in separate phases;
82 // fix stbtt_GetFontOFfsetForIndex (never worked for non-0 input?);
83 // fixed an assert() bug in the new rasterizer
84 // replace assert() with STBTT_assert() in new rasterizer
85 //
86 // Full history can be found at the end of this file.
87 //
88 // LICENSE
89 //
90 // See end of file for license information.
91 //
92 // USAGE
93 //
94 // Include this file in whatever places need to refer to it. In ONE C/C++
95 // file, write:
96 // #define STB_TRUETYPE_IMPLEMENTATION
97 // before the #include of this file. This expands out the actual
98 // implementation into that C/C++ file.
99 //
100 // To make the implementation private to the file that generates the implementation,
101 // #define STBTT_STATIC
102 //
103 // Simple 3D API (don't ship this, but it's fine for tools and quick start)
104 // stbtt_BakeFontBitmap() -- bake a font to a bitmap for use as texture
105 // stbtt_GetBakedQuad() -- compute quad to draw for a given char
106 //
107 // Improved 3D API (more shippable):
108 // #include "stb_rect_pack.h" -- optional, but you really want it
109 // stbtt_PackBegin()
110 // stbtt_PackSetOversampling() -- for improved quality on small fonts
111 // stbtt_PackFontRanges() -- pack and renders
112 // stbtt_PackEnd()
113 // stbtt_GetPackedQuad()
114 //
115 // "Load" a font file from a memory buffer (you have to keep the buffer loaded)
116 // stbtt_InitFont()
117 // stbtt_GetFontOffsetForIndex() -- indexing for TTC font collections
118 // stbtt_GetNumberOfFonts() -- number of fonts for TTC font collections
119 //
120 // Render a unicode codepoint to a bitmap
121 // stbtt_GetCodepointBitmap() -- allocates and returns a bitmap
122 // stbtt_MakeCodepointBitmap() -- renders into bitmap you provide
123 // stbtt_GetCodepointBitmapBox() -- how big the bitmap must be
124 //
125 // Character advance/positioning
126 // stbtt_GetCodepointHMetrics()
127 // stbtt_GetFontVMetrics()
128 // stbtt_GetFontVMetricsOS2()
129 // stbtt_GetCodepointKernAdvance()
130 //
131 // Starting with version 1.06, the rasterizer was replaced with a new,
132 // faster and generally-more-precise rasterizer. The new rasterizer more
133 // accurately measures pixel coverage for anti-aliasing, except in the case
134 // where multiple shapes overlap, in which case it overestimates the AA pixel
135 // coverage. Thus, anti-aliasing of intersecting shapes may look wrong. If
136 // this turns out to be a problem, you can re-enable the old rasterizer with
137 // #define STBTT_RASTERIZER_VERSION 1
138 // which will incur about a 15% speed hit.
139 //
140 // ADDITIONAL DOCUMENTATION
141 //
142 // Immediately after this block comment are a series of sample programs.
143 //
144 // After the sample programs is the "header file" section. This section
145 // includes documentation for each API function.
146 //
147 // Some important concepts to understand to use this library:
148 //
149 // Codepoint
150 // Characters are defined by unicode codepoints, e.g. 65 is
151 // uppercase A, 231 is lowercase c with a cedilla, 0x7e30 is
152 // the hiragana for "ma".
153 //
154 // Glyph
155 // A visual character shape (every codepoint is rendered as
156 // some glyph)
157 //
158 // Glyph index
159 // A font-specific integer ID representing a glyph
160 //
161 // Baseline
162 // Glyph shapes are defined relative to a baseline, which is the
163 // bottom of uppercase characters. Characters extend both above
164 // and below the baseline.
165 //
166 // Current Point
167 // As you draw text to the screen, you keep track of a "current point"
168 // which is the origin of each character. The current point's vertical
169 // position is the baseline. Even "baked fonts" use this model.
170 //
171 // Vertical Font Metrics
172 // The vertical qualities of the font, used to vertically position
173 // and space the characters. See docs for stbtt_GetFontVMetrics.
174 //
175 // Font Size in Pixels or Points
176 // The preferred interface for specifying font sizes in stb_truetype
177 // is to specify how tall the font's vertical extent should be in pixels.
178 // If that sounds good enough, skip the next paragraph.
179 //
180 // Most font APIs instead use "points", which are a common typographic
181 // measurement for describing font size, defined as 72 points per inch.
182 // stb_truetype provides a point API for compatibility. However, true
183 // "per inch" conventions don't make much sense on computer displays
184 // since different monitors have different number of pixels per
185 // inch. For example, Windows traditionally uses a convention that
186 // there are 96 pixels per inch, thus making 'inch' measurements have
187 // nothing to do with inches, and thus effectively defining a point to
188 // be 1.333 pixels. Additionally, the TrueType font data provides
189 // an explicit scale factor to scale a given font's glyphs to points,
190 // but the author has observed that this scale factor is often wrong
191 // for non-commercial fonts, thus making fonts scaled in points
192 // according to the TrueType spec incoherently sized in practice.
193 //
194 // DETAILED USAGE:
195 //
196 // Scale:
197 // Select how high you want the font to be, in points or pixels.
198 // Call ScaleForPixelHeight or ScaleForMappingEmToPixels to compute
199 // a scale factor SF that will be used by all other functions.
200 //
201 // Baseline:
202 // You need to select a y-coordinate that is the baseline of where
203 // your text will appear. Call GetFontBoundingBox to get the baseline-relative
204 // bounding box for all characters. SF*-y0 will be the distance in pixels
205 // that the worst-case character could extend above the baseline, so if
206 // you want the top edge of characters to appear at the top of the
207 // screen where y=0, then you would set the baseline to SF*-y0.
208 //
209 // Current point:
210 // Set the current point where the first character will appear. The
211 // first character could extend left of the current point; this is font
212 // dependent. You can either choose a current point that is the leftmost
213 // point and hope, or add some padding, or check the bounding box or
214 // left-side-bearing of the first character to be displayed and set
215 // the current point based on that.
216 //
217 // Displaying a character:
218 // Compute the bounding box of the character. It will contain signed values
219 // relative to <current_point, baseline>. I.e. if it returns x0,y0,x1,y1,
220 // then the character should be displayed in the rectangle from
221 // <current_point+SF*x0, baseline+SF*y0> to <current_point+SF*x1,baseline+SF*y1).
222 //
223 // Advancing for the next character:
224 // Call GlyphHMetrics, and compute 'current_point += SF * advance'.
225 //
226 //
227 // ADVANCED USAGE
228 //
229 // Quality:
230 //
231 // - Use the functions with Subpixel at the end to allow your characters
232 // to have subpixel positioning. Since the font is anti-aliased, not
233 // hinted, this is very import for quality. (This is not possible with
234 // baked fonts.)
235 //
236 // - Kerning is now supported, and if you're supporting subpixel rendering
237 // then kerning is worth using to give your text a polished look.
238 //
239 // Performance:
240 //
241 // - Convert Unicode codepoints to glyph indexes and operate on the glyphs;
242 // if you don't do this, stb_truetype is forced to do the conversion on
243 // every call.
244 //
245 // - There are a lot of memory allocations. We should modify it to take
246 // a temp buffer and allocate from the temp buffer (without freeing),
247 // should help performance a lot.
248 //
249 // NOTES
250 //
251 // The system uses the raw data found in the .ttf file without changing it
252 // and without building auxiliary data structures. This is a bit inefficient
253 // on little-endian systems (the data is big-endian), but assuming you're
254 // caching the bitmaps or glyph shapes this shouldn't be a big deal.
255 //
256 // It appears to be very hard to programmatically determine what font a
257 // given file is in a general way. I provide an API for this, but I don't
258 // recommend it.
259 //
260 //
261 // PERFORMANCE MEASUREMENTS FOR 1.06:
262 //
263 // 32-bit 64-bit
264 // Previous release: 8.83 s 7.68 s
265 // Pool allocations: 7.72 s 6.34 s
266 // Inline sort : 6.54 s 5.65 s
267 // New rasterizer : 5.63 s 5.00 s
268
269 //////////////////////////////////////////////////////////////////////////////
270 //////////////////////////////////////////////////////////////////////////////
271 ////
272 //// SAMPLE PROGRAMS
273 ////
274 //
275 // Incomplete text-in-3d-api example, which draws quads properly aligned to be lossless.
276 // See "tests/truetype_demo_win32.c" for a complete version.
277 #if 0
278 #define STB_TRUETYPE_IMPLEMENTATION // force following include to generate implementation
279 #include "stb_truetype.h"
280
281 unsigned char ttf_buffer[1<<20];
282 unsigned char temp_bitmap[512*512];
283
284 stbtt_bakedchar cdata[96]; // ASCII 32..126 is 95 glyphs
285 GLuint ftex;
286
287 void my_stbtt_initfont(void)
288 {
289 fread(ttf_buffer, 1, 1<<20, fopen("c:/windows/fonts/times.ttf", "rb"));
290 stbtt_BakeFontBitmap(ttf_buffer,0, 32.0, temp_bitmap,512,512, 32,96, cdata); // no guarantee this fits!
291 // can free ttf_buffer at this point
292 glGenTextures(1, &ftex);
293 glBindTexture(GL_TEXTURE_2D, ftex);
294 glTexImage2D(GL_TEXTURE_2D, 0, GL_ALPHA, 512,512, 0, GL_ALPHA, GL_UNSIGNED_BYTE, temp_bitmap);
295 // can free temp_bitmap at this point
296 glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
297 }
298
299 void my_stbtt_print(float x, float y, char *text)
300 {
301 // assume orthographic projection with units = screen pixels, origin at top left
302 glEnable(GL_BLEND);
303 glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
304 glEnable(GL_TEXTURE_2D);
305 glBindTexture(GL_TEXTURE_2D, ftex);
306 glBegin(GL_QUADS);
307 while (*text) {
308 if (*text >= 32 && *text < 128) {
309 stbtt_aligned_quad q;
310 stbtt_GetBakedQuad(cdata, 512,512, *text-32, &x,&y,&q,1);//1=opengl & d3d10+,0=d3d9
311 glTexCoord2f(q.s0,q.t0); glVertex2f(q.x0,q.y0);
312 glTexCoord2f(q.s1,q.t0); glVertex2f(q.x1,q.y0);
313 glTexCoord2f(q.s1,q.t1); glVertex2f(q.x1,q.y1);
314 glTexCoord2f(q.s0,q.t1); glVertex2f(q.x0,q.y1);
315 }
316 ++text;
317 }
318 glEnd();
319 }
320 #endif
321 //
322 //
323 //////////////////////////////////////////////////////////////////////////////
324 //
325 // Complete program (this compiles): get a single bitmap, print as ASCII art
326 //
327 #if 0
328 #include <stdio.h>
329 #define STB_TRUETYPE_IMPLEMENTATION // force following include to generate implementation
330 #include "stb_truetype.h"
331
332 char ttf_buffer[1<<25];
333
334 int main(int argc, char **argv)
335 {
336 stbtt_fontinfo font;
337 unsigned char *bitmap;
338 int w,h,i,j,c = (argc > 1 ? atoi(argv[1]) : 'a'), s = (argc > 2 ? atoi(argv[2]) : 20);
339
340 fread(ttf_buffer, 1, 1<<25, fopen(argc > 3 ? argv[3] : "c:/windows/fonts/arialbd.ttf", "rb"));
341
342 stbtt_InitFont(&font, ttf_buffer, stbtt_GetFontOffsetForIndex(ttf_buffer,0));
343 bitmap = stbtt_GetCodepointBitmap(&font, 0,stbtt_ScaleForPixelHeight(&font, s), c, &w, &h, 0,0);
344
345 for (j=0; j < h; ++j) {
346 for (i=0; i < w; ++i)
347 putchar(" .:ioVM@"[bitmap[j*w+i]>>5]);
348 putchar('\n');
349 }
350 return 0;
351 }
352 #endif
353 //
354 // Output:
355 //
356 // .ii.
357 // @@@@@@.
358 // V@Mio@@o
359 // :i. V@V
360 // :oM@@M
361 // :@@@MM@M
362 // @@o o@M
363 // :@@. M@M
364 // @@@o@@@@
365 // :M@@V:@@.
366 //
367 //////////////////////////////////////////////////////////////////////////////
368 //
369 // Complete program: print "Hello World!" banner, with bugs
370 //
371 #if 0
372 char buffer[24<<20];
373 unsigned char screen[20][79];
374
375 int main(int arg, char **argv)
376 {
377 stbtt_fontinfo font;
378 int i,j,ascent,baseline,ch=0;
379 float scale, xpos=2; // leave a little padding in case the character extends left
380 char *text = "Heljo World!"; // intentionally misspelled to show 'lj' brokenness
381
382 fread(buffer, 1, 1000000, fopen("c:/windows/fonts/arialbd.ttf", "rb"));
383 stbtt_InitFont(&font, buffer, 0);
384
385 scale = stbtt_ScaleForPixelHeight(&font, 15);
386 stbtt_GetFontVMetrics(&font, &ascent,0,0);
387 baseline = (int) (ascent*scale);
388
389 while (text[ch]) {
390 int advance,lsb,x0,y0,x1,y1;
391 float x_shift = xpos - (float) floor(xpos);
392 stbtt_GetCodepointHMetrics(&font, text[ch], &advance, &lsb);
393 stbtt_GetCodepointBitmapBoxSubpixel(&font, text[ch], scale,scale,x_shift,0, &x0,&y0,&x1,&y1);
394 stbtt_MakeCodepointBitmapSubpixel(&font, &screen[baseline + y0][(int) xpos + x0], x1-x0,y1-y0, 79, scale,scale,x_shift,0, text[ch]);
395 // note that this stomps the old data, so where character boxes overlap (e.g. 'lj') it's wrong
396 // because this API is really for baking character bitmaps into textures. if you want to render
397 // a sequence of characters, you really need to render each bitmap to a temp buffer, then
398 // "alpha blend" that into the working buffer
399 xpos += (advance * scale);
400 if (text[ch+1])
401 xpos += scale*stbtt_GetCodepointKernAdvance(&font, text[ch],text[ch+1]);
402 ++ch;
403 }
404
405 for (j=0; j < 20; ++j) {
406 for (i=0; i < 78; ++i)
407 putchar(" .:ioVM@"[screen[j][i]>>5]);
408 putchar('\n');
409 }
410
411 return 0;
412 }
413 #endif
414
415
416 //////////////////////////////////////////////////////////////////////////////
417 //////////////////////////////////////////////////////////////////////////////
418 ////
419 //// INTEGRATION WITH YOUR CODEBASE
420 ////
421 //// The following sections allow you to supply alternate definitions
422 //// of C library functions used by stb_truetype, e.g. if you don't
423 //// link with the C runtime library.
424
425 #ifdef STB_TRUETYPE_IMPLEMENTATION
426 // #define your own (u)stbtt_int8/16/32 before including to override this
427 #ifndef stbtt_uint8
428 typedef unsigned char stbtt_uint8;
429 typedef signed char stbtt_int8;
430 typedef unsigned short stbtt_uint16;
431 typedef signed short stbtt_int16;
432 typedef unsigned int stbtt_uint32;
433 typedef signed int stbtt_int32;
434 #endif
435
436 typedef char stbtt__check_size32[sizeof(stbtt_int32)==4 ? 1 : -1];
437 typedef char stbtt__check_size16[sizeof(stbtt_int16)==2 ? 1 : -1];
438
439 // e.g. #define your own STBTT_ifloor/STBTT_iceil() to avoid math.h
440 #ifndef STBTT_ifloor
441 #include <math.h>
442 #define STBTT_ifloor(x) ((int) floor(x))
443 #define STBTT_iceil(x) ((int) ceil(x))
444 #endif
445
446 #ifndef STBTT_sqrt
447 #include <math.h>
448 #define STBTT_sqrt(x) sqrt(x)
449 #define STBTT_pow(x,y) pow(x,y)
450 #endif
451
452 #ifndef STBTT_fmod
453 #include <math.h>
454 #define STBTT_fmod(x,y) fmod(x,y)
455 #endif
456
457 #ifndef STBTT_cos
458 #include <math.h>
459 #define STBTT_cos(x) cos(x)
460 #define STBTT_acos(x) acos(x)
461 #endif
462
463 #ifndef STBTT_fabs
464 #include <math.h>
465 #define STBTT_fabs(x) fabs(x)
466 #endif
467
468 // #define your own functions "STBTT_malloc" / "STBTT_free" to avoid malloc.h
469 #ifndef STBTT_malloc
470 #include <stdlib.h>
471 #define STBTT_malloc(x,u) ((void)(u),malloc(x))
472 #define STBTT_free(x,u) ((void)(u),free(x))
473 #endif
474
475 #ifndef STBTT_assert
476 #include <assert.h>
477 #define STBTT_assert(x) assert(x)
478 #endif
479
480 #ifndef STBTT_strlen
481 #include <string.h>
482 #define STBTT_strlen(x) strlen(x)
483 #endif
484
485 #ifndef STBTT_memcpy
486 #include <string.h>
487 #define STBTT_memcpy memcpy
488 #define STBTT_memset memset
489 #endif
490 #endif
491
492 ///////////////////////////////////////////////////////////////////////////////
493 ///////////////////////////////////////////////////////////////////////////////
494 ////
495 //// INTERFACE
496 ////
497 ////
498
499 #ifndef __STB_INCLUDE_STB_TRUETYPE_H__
500 #define __STB_INCLUDE_STB_TRUETYPE_H__
501
502 #ifdef STBTT_STATIC
503 #define STBTT_DEF static
504 #else
505 #define STBTT_DEF extern
506 #endif
507
508 #ifdef __cplusplus
509 extern "C" {
510 #endif
511
512 // private structure
513 typedef struct
514 {
515 unsigned char *data;
516 int cursor;
517 int size;
518 } stbtt__buf;
519
520 //////////////////////////////////////////////////////////////////////////////
521 //
522 // TEXTURE BAKING API
523 //
524 // If you use this API, you only have to call two functions ever.
525 //
526
527 typedef struct
528 {
529 unsigned short x0,y0,x1,y1; // coordinates of bbox in bitmap
530 float xoff,yoff,xadvance;
531 } stbtt_bakedchar;
532
533 STBTT_DEF int stbtt_BakeFontBitmap(const unsigned char *data, int offset, // font location (use offset=0 for plain .ttf)
534 float pixel_height, // height of font in pixels
535 unsigned char *pixels, int pw, int ph, // bitmap to be filled in
536 int first_char, int num_chars, // characters to bake
537 stbtt_bakedchar *chardata); // you allocate this, it's num_chars long
538 // if return is positive, the first unused row of the bitmap
539 // if return is negative, returns the negative of the number of characters that fit
540 // if return is 0, no characters fit and no rows were used
541 // This uses a very crappy packing.
542
543 typedef struct
544 {
545 float x0,y0,s0,t0; // top-left
546 float x1,y1,s1,t1; // bottom-right
547 } stbtt_aligned_quad;
548
549 STBTT_DEF void stbtt_GetBakedQuad(const stbtt_bakedchar *chardata, int pw, int ph, // same data as above
550 int char_index, // character to display
551 float *xpos, float *ypos, // pointers to current position in screen pixel space
552 stbtt_aligned_quad *q, // output: quad to draw
553 int opengl_fillrule); // true if opengl fill rule; false if DX9 or earlier
554 // Call GetBakedQuad with char_index = 'character - first_char', and it
555 // creates the quad you need to draw and advances the current position.
556 //
557 // The coordinate system used assumes y increases downwards.
558 //
559 // Characters will extend both above and below the current position;
560 // see discussion of "BASELINE" above.
561 //
562 // It's inefficient; you might want to c&p it and optimize it.
563
564 STBTT_DEF void stbtt_GetScaledFontVMetrics(const unsigned char *fontdata, int index, float size, float *ascent, float *descent, float *lineGap);
565 // Query the font vertical metrics without having to create a font first.
566
567
568 //////////////////////////////////////////////////////////////////////////////
569 //
570 // NEW TEXTURE BAKING API
571 //
572 // This provides options for packing multiple fonts into one atlas, not
573 // perfectly but better than nothing.
574
575 typedef struct
576 {
577 unsigned short x0,y0,x1,y1; // coordinates of bbox in bitmap
578 float xoff,yoff,xadvance;
579 float xoff2,yoff2;
580 } stbtt_packedchar;
581
582 typedef struct stbtt_pack_context stbtt_pack_context;
583 typedef struct stbtt_fontinfo stbtt_fontinfo;
584 #ifndef STB_RECT_PACK_VERSION
585 typedef struct stbrp_rect stbrp_rect;
586 #endif
587
588 STBTT_DEF int stbtt_PackBegin(stbtt_pack_context *spc, unsigned char *pixels, int width, int height, int stride_in_bytes, int padding, void *alloc_context);
589 // Initializes a packing context stored in the passed-in stbtt_pack_context.
590 // Future calls using this context will pack characters into the bitmap passed
591 // in here: a 1-channel bitmap that is width * height. stride_in_bytes is
592 // the distance from one row to the next (or 0 to mean they are packed tightly
593 // together). "padding" is the amount of padding to leave between each
594 // character (normally you want '1' for bitmaps you'll use as textures with
595 // bilinear filtering).
596 //
597 // Returns 0 on failure, 1 on success.
598
599 STBTT_DEF void stbtt_PackEnd (stbtt_pack_context *spc);
600 // Cleans up the packing context and frees all memory.
601
602 #define STBTT_POINT_SIZE(x) (-(x))
603
604 STBTT_DEF int stbtt_PackFontRange(stbtt_pack_context *spc, const unsigned char *fontdata, int font_index, float font_size,
605 int first_unicode_char_in_range, int num_chars_in_range, stbtt_packedchar *chardata_for_range);
606 // Creates character bitmaps from the font_index'th font found in fontdata (use
607 // font_index=0 if you don't know what that is). It creates num_chars_in_range
608 // bitmaps for characters with unicode values starting at first_unicode_char_in_range
609 // and increasing. Data for how to render them is stored in chardata_for_range;
610 // pass these to stbtt_GetPackedQuad to get back renderable quads.
611 //
612 // font_size is the full height of the character from ascender to descender,
613 // as computed by stbtt_ScaleForPixelHeight. To use a point size as computed
614 // by stbtt_ScaleForMappingEmToPixels, wrap the point size in STBTT_POINT_SIZE()
615 // and pass that result as 'font_size':
616 // ..., 20 , ... // font max minus min y is 20 pixels tall
617 // ..., STBTT_POINT_SIZE(20), ... // 'M' is 20 pixels tall
618
619 typedef struct
620 {
621 float font_size;
622 int first_unicode_codepoint_in_range; // if non-zero, then the chars are continuous, and this is the first codepoint
623 int *array_of_unicode_codepoints; // if non-zero, then this is an array of unicode codepoints
624 int num_chars;
625 stbtt_packedchar *chardata_for_range; // output
626 unsigned char h_oversample, v_oversample; // don't set these, they're used internally
627 } stbtt_pack_range;
628
629 STBTT_DEF int stbtt_PackFontRanges(stbtt_pack_context *spc, const unsigned char *fontdata, int font_index, stbtt_pack_range *ranges, int num_ranges);
630 // Creates character bitmaps from multiple ranges of characters stored in
631 // ranges. This will usually create a better-packed bitmap than multiple
632 // calls to stbtt_PackFontRange. Note that you can call this multiple
633 // times within a single PackBegin/PackEnd.
634
635 STBTT_DEF void stbtt_PackSetOversampling(stbtt_pack_context *spc, unsigned int h_oversample, unsigned int v_oversample);
636 // Oversampling a font increases the quality by allowing higher-quality subpixel
637 // positioning, and is especially valuable at smaller text sizes.
638 //
639 // This function sets the amount of oversampling for all following calls to
640 // stbtt_PackFontRange(s) or stbtt_PackFontRangesGatherRects for a given
641 // pack context. The default (no oversampling) is achieved by h_oversample=1
642 // and v_oversample=1. The total number of pixels required is
643 // h_oversample*v_oversample larger than the default; for example, 2x2
644 // oversampling requires 4x the storage of 1x1. For best results, render
645 // oversampled textures with bilinear filtering. Look at the readme in
646 // stb/tests/oversample for information about oversampled fonts
647 //
648 // To use with PackFontRangesGather etc., you must set it before calls
649 // call to PackFontRangesGatherRects.
650
651 STBTT_DEF void stbtt_PackSetSkipMissingCodepoints(stbtt_pack_context *spc, int skip);
652 // If skip != 0, this tells stb_truetype to skip any codepoints for which
653 // there is no corresponding glyph. If skip=0, which is the default, then
654 // codepoints without a glyph recived the font's "missing character" glyph,
655 // typically an empty box by convention.
656
657 STBTT_DEF void stbtt_GetPackedQuad(const stbtt_packedchar *chardata, int pw, int ph, // same data as above
658 int char_index, // character to display
659 float *xpos, float *ypos, // pointers to current position in screen pixel space
660 stbtt_aligned_quad *q, // output: quad to draw
661 int align_to_integer);
662
663 STBTT_DEF int stbtt_PackFontRangesGatherRects(stbtt_pack_context *spc, const stbtt_fontinfo *info, stbtt_pack_range *ranges, int num_ranges, stbrp_rect *rects);
664 STBTT_DEF void stbtt_PackFontRangesPackRects(stbtt_pack_context *spc, stbrp_rect *rects, int num_rects);
665 STBTT_DEF int stbtt_PackFontRangesRenderIntoRects(stbtt_pack_context *spc, const stbtt_fontinfo *info, stbtt_pack_range *ranges, int num_ranges, stbrp_rect *rects);
666 // Calling these functions in sequence is roughly equivalent to calling
667 // stbtt_PackFontRanges(). If you more control over the packing of multiple
668 // fonts, or if you want to pack custom data into a font texture, take a look
669 // at the source to of stbtt_PackFontRanges() and create a custom version
670 // using these functions, e.g. call GatherRects multiple times,
671 // building up a single array of rects, then call PackRects once,
672 // then call RenderIntoRects repeatedly. This may result in a
673 // better packing than calling PackFontRanges multiple times
674 // (or it may not).
675
676 // this is an opaque structure that you shouldn't mess with which holds
677 // all the context needed from PackBegin to PackEnd.
678 struct stbtt_pack_context {
679 void *user_allocator_context;
680 void *pack_info;
681 int width;
682 int height;
683 int stride_in_bytes;
684 int padding;
685 int skip_missing;
686 unsigned int h_oversample, v_oversample;
687 unsigned char *pixels;
688 void *nodes;
689 };
690
691 //////////////////////////////////////////////////////////////////////////////
692 //
693 // FONT LOADING
694 //
695 //
696
697 STBTT_DEF int stbtt_GetNumberOfFonts(const unsigned char *data);
698 // This function will determine the number of fonts in a font file. TrueType
699 // collection (.ttc) files may contain multiple fonts, while TrueType font
700 // (.ttf) files only contain one font. The number of fonts can be used for
701 // indexing with the previous function where the index is between zero and one
702 // less than the total fonts. If an error occurs, -1 is returned.
703
704 STBTT_DEF int stbtt_GetFontOffsetForIndex(const unsigned char *data, int index);
705 // Each .ttf/.ttc file may have more than one font. Each font has a sequential
706 // index number starting from 0. Call this function to get the font offset for
707 // a given index; it returns -1 if the index is out of range. A regular .ttf
708 // file will only define one font and it always be at offset 0, so it will
709 // return '0' for index 0, and -1 for all other indices.
710
711 // The following structure is defined publicly so you can declare one on
712 // the stack or as a global or etc, but you should treat it as opaque.
713 struct stbtt_fontinfo
714 {
715 void * userdata;
716 unsigned char * data; // pointer to .ttf file
717 int fontstart; // offset of start of font
718
719 int numGlyphs; // number of glyphs, needed for range checking
720
721 int loca,head,glyf,hhea,hmtx,kern,gpos,svg; // table locations as offset from start of .ttf
722 int index_map; // a cmap mapping for our chosen character encoding
723 int indexToLocFormat; // format needed to map from glyph index to glyph
724
725 stbtt__buf cff; // cff font data
726 stbtt__buf charstrings; // the charstring index
727 stbtt__buf gsubrs; // global charstring subroutines index
728 stbtt__buf subrs; // private charstring subroutines index
729 stbtt__buf fontdicts; // array of font dicts
730 stbtt__buf fdselect; // map from glyph to fontdict
731 };
732
733 STBTT_DEF int stbtt_InitFont(stbtt_fontinfo *info, const unsigned char *data, int offset);
734 // Given an offset into the file that defines a font, this function builds
735 // the necessary cached info for the rest of the system. You must allocate
736 // the stbtt_fontinfo yourself, and stbtt_InitFont will fill it out. You don't
737 // need to do anything special to free it, because the contents are pure
738 // value data with no additional data structures. Returns 0 on failure.
739
740
741 //////////////////////////////////////////////////////////////////////////////
742 //
743 // CHARACTER TO GLYPH-INDEX CONVERSIOn
744
745 STBTT_DEF int stbtt_FindGlyphIndex(const stbtt_fontinfo *info, int unicode_codepoint);
746 // If you're going to perform multiple operations on the same character
747 // and you want a speed-up, call this function with the character you're
748 // going to process, then use glyph-based functions instead of the
749 // codepoint-based functions.
750 // Returns 0 if the character codepoint is not defined in the font.
751
752
753 //////////////////////////////////////////////////////////////////////////////
754 //
755 // CHARACTER PROPERTIES
756 //
757
758 STBTT_DEF float stbtt_ScaleForPixelHeight(const stbtt_fontinfo *info, float pixels);
759 // computes a scale factor to produce a font whose "height" is 'pixels' tall.
760 // Height is measured as the distance from the highest ascender to the lowest
761 // descender; in other words, it's equivalent to calling stbtt_GetFontVMetrics
762 // and computing:
763 // scale = pixels / (ascent - descent)
764 // so if you prefer to measure height by the ascent only, use a similar calculation.
765
766 STBTT_DEF float stbtt_ScaleForMappingEmToPixels(const stbtt_fontinfo *info, float pixels);
767 // computes a scale factor to produce a font whose EM size is mapped to
768 // 'pixels' tall. This is probably what traditional APIs compute, but
769 // I'm not positive.
770
771 STBTT_DEF void stbtt_GetFontVMetrics(const stbtt_fontinfo *info, int *ascent, int *descent, int *lineGap);
772 // ascent is the coordinate above the baseline the font extends; descent
773 // is the coordinate below the baseline the font extends (i.e. it is typically negative)
774 // lineGap is the spacing between one row's descent and the next row's ascent...
775 // so you should advance the vertical position by "*ascent - *descent + *lineGap"
776 // these are expressed in unscaled coordinates, so you must multiply by
777 // the scale factor for a given size
778
779 STBTT_DEF int stbtt_GetFontVMetricsOS2(const stbtt_fontinfo *info, int *typoAscent, int *typoDescent, int *typoLineGap);
780 // analogous to GetFontVMetrics, but returns the "typographic" values from the OS/2
781 // table (specific to MS/Windows TTF files).
782 //
783 // Returns 1 on success (table present), 0 on failure.
784
785 STBTT_DEF void stbtt_GetFontBoundingBox(const stbtt_fontinfo *info, int *x0, int *y0, int *x1, int *y1);
786 // the bounding box around all possible characters
787
788 STBTT_DEF void stbtt_GetCodepointHMetrics(const stbtt_fontinfo *info, int codepoint, int *advanceWidth, int *leftSideBearing);
789 // leftSideBearing is the offset from the current horizontal position to the left edge of the character
790 // advanceWidth is the offset from the current horizontal position to the next horizontal position
791 // these are expressed in unscaled coordinates
792
793 STBTT_DEF int stbtt_GetCodepointKernAdvance(const stbtt_fontinfo *info, int ch1, int ch2);
794 // an additional amount to add to the 'advance' value between ch1 and ch2
795
796 STBTT_DEF int stbtt_GetCodepointBox(const stbtt_fontinfo *info, int codepoint, int *x0, int *y0, int *x1, int *y1);
797 // Gets the bounding box of the visible part of the glyph, in unscaled coordinates
798
799 STBTT_DEF void stbtt_GetGlyphHMetrics(const stbtt_fontinfo *info, int glyph_index, int *advanceWidth, int *leftSideBearing);
800 STBTT_DEF int stbtt_GetGlyphKernAdvance(const stbtt_fontinfo *info, int glyph1, int glyph2);
801 STBTT_DEF int stbtt_GetGlyphBox(const stbtt_fontinfo *info, int glyph_index, int *x0, int *y0, int *x1, int *y1);
802 // as above, but takes one or more glyph indices for greater efficiency
803
804 typedef struct stbtt_kerningentry
805 {
806 int glyph1; // use stbtt_FindGlyphIndex
807 int glyph2;
808 int advance;
809 } stbtt_kerningentry;
810
811 STBTT_DEF int stbtt_GetKerningTableLength(const stbtt_fontinfo *info);
812 STBTT_DEF int stbtt_GetKerningTable(const stbtt_fontinfo *info, stbtt_kerningentry* table, int table_length);
813 // Retrieves a complete list of all of the kerning pairs provided by the font
814 // stbtt_GetKerningTable never writes more than table_length entries and returns how many entries it did write.
815 // The table will be sorted by (a.glyph1 == b.glyph1)?(a.glyph2 < b.glyph2):(a.glyph1 < b.glyph1)
816
817 //////////////////////////////////////////////////////////////////////////////
818 //
819 // GLYPH SHAPES (you probably don't need these, but they have to go before
820 // the bitmaps for C declaration-order reasons)
821 //
822
823 #ifndef STBTT_vmove // you can predefine these to use different values (but why?)
824 enum {
825 STBTT_vmove=1,
826 STBTT_vline,
827 STBTT_vcurve,
828 STBTT_vcubic
829 };
830 #endif
831
832 #ifndef stbtt_vertex // you can predefine this to use different values
833 // (we share this with other code at RAD)
834 #define stbtt_vertex_type short // can't use stbtt_int16 because that's not visible in the header file
835 typedef struct
836 {
837 stbtt_vertex_type x,y,cx,cy,cx1,cy1;
838 unsigned char type,padding;
839 } stbtt_vertex;
840 #endif
841
842 STBTT_DEF int stbtt_IsGlyphEmpty(const stbtt_fontinfo *info, int glyph_index);
843 // returns non-zero if nothing is drawn for this glyph
844
845 STBTT_DEF int stbtt_GetCodepointShape(const stbtt_fontinfo *info, int unicode_codepoint, stbtt_vertex **vertices);
846 STBTT_DEF int stbtt_GetGlyphShape(const stbtt_fontinfo *info, int glyph_index, stbtt_vertex **vertices);
847 // returns # of vertices and fills *vertices with the pointer to them
848 // these are expressed in "unscaled" coordinates
849 //
850 // The shape is a series of contours. Each one starts with
851 // a STBTT_moveto, then consists of a series of mixed
852 // STBTT_lineto and STBTT_curveto segments. A lineto
853 // draws a line from previous endpoint to its x,y; a curveto
854 // draws a quadratic bezier from previous endpoint to
855 // its x,y, using cx,cy as the bezier control point.
856
857 STBTT_DEF void stbtt_FreeShape(const stbtt_fontinfo *info, stbtt_vertex *vertices);
858 // frees the data allocated above
859
860 STBTT_DEF unsigned char *stbtt_FindSVGDoc(const stbtt_fontinfo *info, int gl);
861 STBTT_DEF int stbtt_GetCodepointSVG(const stbtt_fontinfo *info, int unicode_codepoint, const char **svg);
862 STBTT_DEF int stbtt_GetGlyphSVG(const stbtt_fontinfo *info, int gl, const char **svg);
863 // fills svg with the character's SVG data.
864 // returns data size or 0 if SVG not found.
865
866 //////////////////////////////////////////////////////////////////////////////
867 //
868 // BITMAP RENDERING
869 //
870
871 STBTT_DEF void stbtt_FreeBitmap(unsigned char *bitmap, void *userdata);
872 // frees the bitmap allocated below
873
874 STBTT_DEF unsigned char *stbtt_GetCodepointBitmap(const stbtt_fontinfo *info, float scale_x, float scale_y, int codepoint, int *width, int *height, int *xoff, int *yoff);
875 // allocates a large-enough single-channel 8bpp bitmap and renders the
876 // specified character/glyph at the specified scale into it, with
877 // antialiasing. 0 is no coverage (transparent), 255 is fully covered (opaque).
878 // *width & *height are filled out with the width & height of the bitmap,
879 // which is stored left-to-right, top-to-bottom.
880 //
881 // xoff/yoff are the offset it pixel space from the glyph origin to the top-left of the bitmap
882
883 STBTT_DEF unsigned char *stbtt_GetCodepointBitmapSubpixel(const stbtt_fontinfo *info, float scale_x, float scale_y, float shift_x, float shift_y, int codepoint, int *width, int *height, int *xoff, int *yoff);
884 // the same as stbtt_GetCodepoitnBitmap, but you can specify a subpixel
885 // shift for the character
886
887 STBTT_DEF void stbtt_MakeCodepointBitmap(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, int codepoint);
888 // the same as stbtt_GetCodepointBitmap, but you pass in storage for the bitmap
889 // in the form of 'output', with row spacing of 'out_stride' bytes. the bitmap
890 // is clipped to out_w/out_h bytes. Call stbtt_GetCodepointBitmapBox to get the
891 // width and height and positioning info for it first.
892
893 STBTT_DEF void stbtt_MakeCodepointBitmapSubpixel(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, float shift_x, float shift_y, int codepoint);
894 // same as stbtt_MakeCodepointBitmap, but you can specify a subpixel
895 // shift for the character
896
897 STBTT_DEF void stbtt_MakeCodepointBitmapSubpixelPrefilter(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, float shift_x, float shift_y, int oversample_x, int oversample_y, float *sub_x, float *sub_y, int codepoint);
898 // same as stbtt_MakeCodepointBitmapSubpixel, but prefiltering
899 // is performed (see stbtt_PackSetOversampling)
900
901 STBTT_DEF void stbtt_GetCodepointBitmapBox(const stbtt_fontinfo *font, int codepoint, float scale_x, float scale_y, int *ix0, int *iy0, int *ix1, int *iy1);
902 // get the bbox of the bitmap centered around the glyph origin; so the
903 // bitmap width is ix1-ix0, height is iy1-iy0, and location to place
904 // the bitmap top left is (leftSideBearing*scale,iy0).
905 // (Note that the bitmap uses y-increases-down, but the shape uses
906 // y-increases-up, so CodepointBitmapBox and CodepointBox are inverted.)
907
908 STBTT_DEF void stbtt_GetCodepointBitmapBoxSubpixel(const stbtt_fontinfo *font, int codepoint, float scale_x, float scale_y, float shift_x, float shift_y, int *ix0, int *iy0, int *ix1, int *iy1);
909 // same as stbtt_GetCodepointBitmapBox, but you can specify a subpixel
910 // shift for the character
911
912 // the following functions are equivalent to the above functions, but operate
913 // on glyph indices instead of Unicode codepoints (for efficiency)
914 STBTT_DEF unsigned char *stbtt_GetGlyphBitmap(const stbtt_fontinfo *info, float scale_x, float scale_y, int glyph, int *width, int *height, int *xoff, int *yoff);
915 STBTT_DEF unsigned char *stbtt_GetGlyphBitmapSubpixel(const stbtt_fontinfo *info, float scale_x, float scale_y, float shift_x, float shift_y, int glyph, int *width, int *height, int *xoff, int *yoff);
916 STBTT_DEF void stbtt_MakeGlyphBitmap(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, int glyph);
917 STBTT_DEF void stbtt_MakeGlyphBitmapSubpixel(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, float shift_x, float shift_y, int glyph);
918 STBTT_DEF void stbtt_MakeGlyphBitmapSubpixelPrefilter(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, float shift_x, float shift_y, int oversample_x, int oversample_y, float *sub_x, float *sub_y, int glyph);
919 STBTT_DEF void stbtt_GetGlyphBitmapBox(const stbtt_fontinfo *font, int glyph, float scale_x, float scale_y, int *ix0, int *iy0, int *ix1, int *iy1);
920 STBTT_DEF void stbtt_GetGlyphBitmapBoxSubpixel(const stbtt_fontinfo *font, int glyph, float scale_x, float scale_y,float shift_x, float shift_y, int *ix0, int *iy0, int *ix1, int *iy1);
921
922
923 // @TODO: don't expose this structure
924 typedef struct
925 {
926 int w,h,stride;
927 unsigned char *pixels;
928 } stbtt__bitmap;
929
930 // rasterize a shape with quadratic beziers into a bitmap
931 STBTT_DEF void stbtt_Rasterize(stbtt__bitmap *result, // 1-channel bitmap to draw into
932 float flatness_in_pixels, // allowable error of curve in pixels
933 stbtt_vertex *vertices, // array of vertices defining shape
934 int num_verts, // number of vertices in above array
935 float scale_x, float scale_y, // scale applied to input vertices
936 float shift_x, float shift_y, // translation applied to input vertices
937 int x_off, int y_off, // another translation applied to input
938 int invert, // if non-zero, vertically flip shape
939 void *userdata); // context for to STBTT_MALLOC
940
941 //////////////////////////////////////////////////////////////////////////////
942 //
943 // Signed Distance Function (or Field) rendering
944
945 STBTT_DEF void stbtt_FreeSDF(unsigned char *bitmap, void *userdata);
946 // frees the SDF bitmap allocated below
947
948 STBTT_DEF unsigned char * stbtt_GetGlyphSDF(const stbtt_fontinfo *info, float scale, int glyph, int padding, unsigned char onedge_value, float pixel_dist_scale, int *width, int *height, int *xoff, int *yoff);
949 STBTT_DEF unsigned char * stbtt_GetCodepointSDF(const stbtt_fontinfo *info, float scale, int codepoint, int padding, unsigned char onedge_value, float pixel_dist_scale, int *width, int *height, int *xoff, int *yoff);
950 // These functions compute a discretized SDF field for a single character, suitable for storing
951 // in a single-channel texture, sampling with bilinear filtering, and testing against
952 // larger than some threshold to produce scalable fonts.
953 // info -- the font
954 // scale -- controls the size of the resulting SDF bitmap, same as it would be creating a regular bitmap
955 // glyph/codepoint -- the character to generate the SDF for
956 // padding -- extra "pixels" around the character which are filled with the distance to the character (not 0),
957 // which allows effects like bit outlines
958 // onedge_value -- value 0-255 to test the SDF against to reconstruct the character (i.e. the isocontour of the character)
959 // pixel_dist_scale -- what value the SDF should increase by when moving one SDF "pixel" away from the edge (on the 0..255 scale)
960 // if positive, > onedge_value is inside; if negative, < onedge_value is inside
961 // width,height -- output height & width of the SDF bitmap (including padding)
962 // xoff,yoff -- output origin of the character
963 // return value -- a 2D array of bytes 0..255, width*height in size
964 //
965 // pixel_dist_scale & onedge_value are a scale & bias that allows you to make
966 // optimal use of the limited 0..255 for your application, trading off precision
967 // and special effects. SDF values outside the range 0..255 are clamped to 0..255.
968 //
969 // Example:
970 // scale = stbtt_ScaleForPixelHeight(22)
971 // padding = 5
972 // onedge_value = 180
973 // pixel_dist_scale = 180/5.0 = 36.0
974 //
975 // This will create an SDF bitmap in which the character is about 22 pixels
976 // high but the whole bitmap is about 22+5+5=32 pixels high. To produce a filled
977 // shape, sample the SDF at each pixel and fill the pixel if the SDF value
978 // is greater than or equal to 180/255. (You'll actually want to antialias,
979 // which is beyond the scope of this example.) Additionally, you can compute
980 // offset outlines (e.g. to stroke the character border inside & outside,
981 // or only outside). For example, to fill outside the character up to 3 SDF
982 // pixels, you would compare against (180-36.0*3)/255 = 72/255. The above
983 // choice of variables maps a range from 5 pixels outside the shape to
984 // 2 pixels inside the shape to 0..255; this is intended primarily for apply
985 // outside effects only (the interior range is needed to allow proper
986 // antialiasing of the font at *smaller* sizes)
987 //
988 // The function computes the SDF analytically at each SDF pixel, not by e.g.
989 // building a higher-res bitmap and approximating it. In theory the quality
990 // should be as high as possible for an SDF of this size & representation, but
991 // unclear if this is true in practice (perhaps building a higher-res bitmap
992 // and computing from that can allow drop-out prevention).
993 //
994 // The algorithm has not been optimized at all, so expect it to be slow
995 // if computing lots of characters or very large sizes.
996
997
998
999 //////////////////////////////////////////////////////////////////////////////
1000 //
1001 // Finding the right font...
1002 //
1003 // You should really just solve this offline, keep your own tables
1004 // of what font is what, and don't try to get it out of the .ttf file.
1005 // That's because getting it out of the .ttf file is really hard, because
1006 // the names in the file can appear in many possible encodings, in many
1007 // possible languages, and e.g. if you need a case-insensitive comparison,
1008 // the details of that depend on the encoding & language in a complex way
1009 // (actually underspecified in truetype, but also gigantic).
1010 //
1011 // But you can use the provided functions in two possible ways:
1012 // stbtt_FindMatchingFont() will use *case-sensitive* comparisons on
1013 // unicode-encoded names to try to find the font you want;
1014 // you can run this before calling stbtt_InitFont()
1015 //
1016 // stbtt_GetFontNameString() lets you get any of the various strings
1017 // from the file yourself and do your own comparisons on them.
1018 // You have to have called stbtt_InitFont() first.
1019
1020
1021 STBTT_DEF int stbtt_FindMatchingFont(const unsigned char *fontdata, const char *name, int flags);
1022 // returns the offset (not index) of the font that matches, or -1 if none
1023 // if you use STBTT_MACSTYLE_DONTCARE, use a font name like "Arial Bold".
1024 // if you use any other flag, use a font name like "Arial"; this checks
1025 // the 'macStyle' header field; i don't know if fonts set this consistently
1026 #define STBTT_MACSTYLE_DONTCARE 0
1027 #define STBTT_MACSTYLE_BOLD 1
1028 #define STBTT_MACSTYLE_ITALIC 2
1029 #define STBTT_MACSTYLE_UNDERSCORE 4
1030 #define STBTT_MACSTYLE_NONE 8 // <= not same as 0, this makes us check the bitfield is 0
1031
1032 STBTT_DEF int stbtt_CompareUTF8toUTF16_bigendian(const char *s1, int len1, const char *s2, int len2);
1033 // returns 1/0 whether the first string interpreted as utf8 is identical to
1034 // the second string interpreted as big-endian utf16... useful for strings from next func
1035
1036 STBTT_DEF const char *stbtt_GetFontNameString(const stbtt_fontinfo *font, int *length, int platformID, int encodingID, int languageID, int nameID);
1037 // returns the string (which may be big-endian double byte, e.g. for unicode)
1038 // and puts the length in bytes in *length.
1039 //
1040 // some of the values for the IDs are below; for more see the truetype spec:
1041 // http://developer.apple.com/textfonts/TTRefMan/RM06/Chap6name.html
1042 // http://www.microsoft.com/typography/otspec/name.htm
1043
1044 enum { // platformID
1045 STBTT_PLATFORM_ID_UNICODE =0,
1046 STBTT_PLATFORM_ID_MAC =1,
1047 STBTT_PLATFORM_ID_ISO =2,
1048 STBTT_PLATFORM_ID_MICROSOFT =3
1049 };
1050
1051 enum { // encodingID for STBTT_PLATFORM_ID_UNICODE
1052 STBTT_UNICODE_EID_UNICODE_1_0 =0,
1053 STBTT_UNICODE_EID_UNICODE_1_1 =1,
1054 STBTT_UNICODE_EID_ISO_10646 =2,
1055 STBTT_UNICODE_EID_UNICODE_2_0_BMP=3,
1056 STBTT_UNICODE_EID_UNICODE_2_0_FULL=4
1057 };
1058
1059 enum { // encodingID for STBTT_PLATFORM_ID_MICROSOFT
1060 STBTT_MS_EID_SYMBOL =0,
1061 STBTT_MS_EID_UNICODE_BMP =1,
1062 STBTT_MS_EID_SHIFTJIS =2,
1063 STBTT_MS_EID_UNICODE_FULL =10
1064 };
1065
1066 enum { // encodingID for STBTT_PLATFORM_ID_MAC; same as Script Manager codes
1067 STBTT_MAC_EID_ROMAN =0, STBTT_MAC_EID_ARABIC =4,
1068 STBTT_MAC_EID_JAPANESE =1, STBTT_MAC_EID_HEBREW =5,
1069 STBTT_MAC_EID_CHINESE_TRAD =2, STBTT_MAC_EID_GREEK =6,
1070 STBTT_MAC_EID_KOREAN =3, STBTT_MAC_EID_RUSSIAN =7
1071 };
1072
1073 enum { // languageID for STBTT_PLATFORM_ID_MICROSOFT; same as LCID...
1074 // problematic because there are e.g. 16 english LCIDs and 16 arabic LCIDs
1075 STBTT_MS_LANG_ENGLISH =0x0409, STBTT_MS_LANG_ITALIAN =0x0410,
1076 STBTT_MS_LANG_CHINESE =0x0804, STBTT_MS_LANG_JAPANESE =0x0411,
1077 STBTT_MS_LANG_DUTCH =0x0413, STBTT_MS_LANG_KOREAN =0x0412,
1078 STBTT_MS_LANG_FRENCH =0x040c, STBTT_MS_LANG_RUSSIAN =0x0419,
1079 STBTT_MS_LANG_GERMAN =0x0407, STBTT_MS_LANG_SPANISH =0x0409,
1080 STBTT_MS_LANG_HEBREW =0x040d, STBTT_MS_LANG_SWEDISH =0x041D
1081 };
1082
1083 enum { // languageID for STBTT_PLATFORM_ID_MAC
1084 STBTT_MAC_LANG_ENGLISH =0 , STBTT_MAC_LANG_JAPANESE =11,
1085 STBTT_MAC_LANG_ARABIC =12, STBTT_MAC_LANG_KOREAN =23,
1086 STBTT_MAC_LANG_DUTCH =4 , STBTT_MAC_LANG_RUSSIAN =32,
1087 STBTT_MAC_LANG_FRENCH =1 , STBTT_MAC_LANG_SPANISH =6 ,
1088 STBTT_MAC_LANG_GERMAN =2 , STBTT_MAC_LANG_SWEDISH =5 ,
1089 STBTT_MAC_LANG_HEBREW =10, STBTT_MAC_LANG_CHINESE_SIMPLIFIED =33,
1090 STBTT_MAC_LANG_ITALIAN =3 , STBTT_MAC_LANG_CHINESE_TRAD =19
1091 };
1092
1093 #ifdef __cplusplus
1094 }
1095 #endif
1096
1097 #endif // __STB_INCLUDE_STB_TRUETYPE_H__
1098
1099 ///////////////////////////////////////////////////////////////////////////////
1100 ///////////////////////////////////////////////////////////////////////////////
1101 ////
1102 //// IMPLEMENTATION
1103 ////
1104 ////
1105
1106 #ifdef STB_TRUETYPE_IMPLEMENTATION
1107
1108 #ifndef STBTT_MAX_OVERSAMPLE
1109 #define STBTT_MAX_OVERSAMPLE 8
1110 #endif
1111
1112 #if STBTT_MAX_OVERSAMPLE > 255
1113 #error "STBTT_MAX_OVERSAMPLE cannot be > 255"
1114 #endif
1115
1116 typedef int stbtt__test_oversample_pow2[(STBTT_MAX_OVERSAMPLE & (STBTT_MAX_OVERSAMPLE-1)) == 0 ? 1 : -1];
1117
1118 #ifndef STBTT_RASTERIZER_VERSION
1119 #define STBTT_RASTERIZER_VERSION 2
1120 #endif
1121
1122 #ifdef _MSC_VER
1123 #define STBTT__NOTUSED(v) (void)(v)
1124 #else
1125 #define STBTT__NOTUSED(v) (void)sizeof(v)
1126 #endif
1127
1128 //////////////////////////////////////////////////////////////////////////
1129 //
1130 // stbtt__buf helpers to parse data from file
1131 //
1132
1133 static stbtt_uint8 stbtt__buf_get8(stbtt__buf *b)
1134 {
1135 if (b->cursor >= b->size)
1136 return 0;
1137 return b->data[b->cursor++];
1138 }
1139
1140 static stbtt_uint8 stbtt__buf_peek8(stbtt__buf *b)
1141 {
1142 if (b->cursor >= b->size)
1143 return 0;
1144 return b->data[b->cursor];
1145 }
1146
1147 static void stbtt__buf_seek(stbtt__buf *b, int o)
1148 {
1149 STBTT_assert(!(o > b->size || o < 0));
1150 b->cursor = (o > b->size || o < 0) ? b->size : o;
1151 }
1152
1153 static void stbtt__buf_skip(stbtt__buf *b, int o)
1154 {
1155 stbtt__buf_seek(b, b->cursor + o);
1156 }
1157
1158 static stbtt_uint32 stbtt__buf_get(stbtt__buf *b, int n)
1159 {
1160 stbtt_uint32 v = 0;
1161 int i;
1162 STBTT_assert(n >= 1 && n <= 4);
1163 for (i = 0; i < n; i++)
1164 v = (v << 8) | stbtt__buf_get8(b);
1165 return v;
1166 }
1167
1168 static stbtt__buf stbtt__new_buf(const void *p, size_t size)
1169 {
1170 stbtt__buf r;
1171 STBTT_assert(size < 0x40000000);
1172 r.data = (stbtt_uint8*) p;
1173 r.size = (int) size;
1174 r.cursor = 0;
1175 return r;
1176 }
1177
1178 #define stbtt__buf_get16(b) stbtt__buf_get((b), 2)
1179 #define stbtt__buf_get32(b) stbtt__buf_get((b), 4)
1180
1181 static stbtt__buf stbtt__buf_range(const stbtt__buf *b, int o, int s)
1182 {
1183 stbtt__buf r = stbtt__new_buf(NULL, 0);
1184 if (o < 0 || s < 0 || o > b->size || s > b->size - o) return r;
1185 r.data = b->data + o;
1186 r.size = s;
1187 return r;
1188 }
1189
1190 static stbtt__buf stbtt__cff_get_index(stbtt__buf *b)
1191 {
1192 int count, start, offsize;
1193 start = b->cursor;
1194 count = stbtt__buf_get16(b);
1195 if (count) {
1196 offsize = stbtt__buf_get8(b);
1197 STBTT_assert(offsize >= 1 && offsize <= 4);
1198 stbtt__buf_skip(b, offsize * count);
1199 stbtt__buf_skip(b, stbtt__buf_get(b, offsize) - 1);
1200 }
1201 return stbtt__buf_range(b, start, b->cursor - start);
1202 }
1203
1204 static stbtt_uint32 stbtt__cff_int(stbtt__buf *b)
1205 {
1206 int b0 = stbtt__buf_get8(b);
1207 if (b0 >= 32 && b0 <= 246) return b0 - 139;
1208 else if (b0 >= 247 && b0 <= 250) return (b0 - 247)*256 + stbtt__buf_get8(b) + 108;
1209 else if (b0 >= 251 && b0 <= 254) return -(b0 - 251)*256 - stbtt__buf_get8(b) - 108;
1210 else if (b0 == 28) return stbtt__buf_get16(b);
1211 else if (b0 == 29) return stbtt__buf_get32(b);
1212 STBTT_assert(0);
1213 return 0;
1214 }
1215
1216 static void stbtt__cff_skip_operand(stbtt__buf *b) {
1217 int v, b0 = stbtt__buf_peek8(b);
1218 STBTT_assert(b0 >= 28);
1219 if (b0 == 30) {
1220 stbtt__buf_skip(b, 1);
1221 while (b->cursor < b->size) {
1222 v = stbtt__buf_get8(b);
1223 if ((v & 0xF) == 0xF || (v >> 4) == 0xF)
1224 break;
1225 }
1226 } else {
1227 stbtt__cff_int(b);
1228 }
1229 }
1230
1231 static stbtt__buf stbtt__dict_get(stbtt__buf *b, int key)
1232 {
1233 stbtt__buf_seek(b, 0);
1234 while (b->cursor < b->size) {
1235 int start = b->cursor, end, op;
1236 while (stbtt__buf_peek8(b) >= 28)
1237 stbtt__cff_skip_operand(b);
1238 end = b->cursor;
1239 op = stbtt__buf_get8(b);
1240 if (op == 12) op = stbtt__buf_get8(b) | 0x100;
1241 if (op == key) return stbtt__buf_range(b, start, end-start);
1242 }
1243 return stbtt__buf_range(b, 0, 0);
1244 }
1245
1246 static void stbtt__dict_get_ints(stbtt__buf *b, int key, int outcount, stbtt_uint32 *out)
1247 {
1248 int i;
1249 stbtt__buf operands = stbtt__dict_get(b, key);
1250 for (i = 0; i < outcount && operands.cursor < operands.size; i++)
1251 out[i] = stbtt__cff_int(&operands);
1252 }
1253
1254 static int stbtt__cff_index_count(stbtt__buf *b)
1255 {
1256 stbtt__buf_seek(b, 0);
1257 return stbtt__buf_get16(b);
1258 }
1259
1260 static stbtt__buf stbtt__cff_index_get(stbtt__buf b, int i)
1261 {
1262 int count, offsize, start, end;
1263 stbtt__buf_seek(&b, 0);
1264 count = stbtt__buf_get16(&b);
1265 offsize = stbtt__buf_get8(&b);
1266 STBTT_assert(i >= 0 && i < count);
1267 STBTT_assert(offsize >= 1 && offsize <= 4);
1268 stbtt__buf_skip(&b, i*offsize);
1269 start = stbtt__buf_get(&b, offsize);
1270 end = stbtt__buf_get(&b, offsize);
1271 return stbtt__buf_range(&b, 2+(count+1)*offsize+start, end - start);
1272 }
1273
1274 //////////////////////////////////////////////////////////////////////////
1275 //
1276 // accessors to parse data from file
1277 //
1278
1279 // on platforms that don't allow misaligned reads, if we want to allow
1280 // truetype fonts that aren't padded to alignment, define ALLOW_UNALIGNED_TRUETYPE
1281
1282 #define ttBYTE(p) (* (stbtt_uint8 *) (p))
1283 #define ttCHAR(p) (* (stbtt_int8 *) (p))
1284 #define ttFixed(p) ttLONG(p)
1285
1286 static stbtt_uint16 ttUSHORT(stbtt_uint8 *p) { return p[0]*256 + p[1]; }
1287 static stbtt_int16 ttSHORT(stbtt_uint8 *p) { return p[0]*256 + p[1]; }
1288 static stbtt_uint32 ttULONG(stbtt_uint8 *p) { return (p[0]<<24) + (p[1]<<16) + (p[2]<<8) + p[3]; }
1289 static stbtt_int32 ttLONG(stbtt_uint8 *p) { return (p[0]<<24) + (p[1]<<16) + (p[2]<<8) + p[3]; }
1290
1291 #define stbtt_tag4(p,c0,c1,c2,c3) ((p)[0] == (c0) && (p)[1] == (c1) && (p)[2] == (c2) && (p)[3] == (c3))
1292 #define stbtt_tag(p,str) stbtt_tag4(p,str[0],str[1],str[2],str[3])
1293
1294 static int stbtt__isfont(stbtt_uint8 *font)
1295 {
1296 // check the version number
1297 if (stbtt_tag4(font, '1',0,0,0)) return 1; // TrueType 1
1298 if (stbtt_tag(font, "typ1")) return 1; // TrueType with type 1 font -- we don't support this!
1299 if (stbtt_tag(font, "OTTO")) return 1; // OpenType with CFF
1300 if (stbtt_tag4(font, 0,1,0,0)) return 1; // OpenType 1.0
1301 if (stbtt_tag(font, "true")) return 1; // Apple specification for TrueType fonts
1302 return 0;
1303 }
1304
1305 // @OPTIMIZE: binary search
1306 static stbtt_uint32 stbtt__find_table(stbtt_uint8 *data, stbtt_uint32 fontstart, const char *tag)
1307 {
1308 stbtt_int32 num_tables = ttUSHORT(data+fontstart+4);
1309 stbtt_uint32 tabledir = fontstart + 12;
1310 stbtt_int32 i;
1311 for (i=0; i < num_tables; ++i) {
1312 stbtt_uint32 loc = tabledir + 16*i;
1313 if (stbtt_tag(data+loc+0, tag))
1314 return ttULONG(data+loc+8);
1315 }
1316 return 0;
1317 }
1318
1319 static int stbtt_GetFontOffsetForIndex_internal(unsigned char *font_collection, int index)
1320 {
1321 // if it's just a font, there's only one valid index
1322 if (stbtt__isfont(font_collection))
1323 return index == 0 ? 0 : -1;
1324
1325 // check if it's a TTC
1326 if (stbtt_tag(font_collection, "ttcf")) {
1327 // version 1?
1328 if (ttULONG(font_collection+4) == 0x00010000 || ttULONG(font_collection+4) == 0x00020000) {
1329 stbtt_int32 n = ttLONG(font_collection+8);
1330 if (index >= n)
1331 return -1;
1332 return ttULONG(font_collection+12+index*4);
1333 }
1334 }
1335 return -1;
1336 }
1337
1338 static int stbtt_GetNumberOfFonts_internal(unsigned char *font_collection)
1339 {
1340 // if it's just a font, there's only one valid font
1341 if (stbtt__isfont(font_collection))
1342 return 1;
1343
1344 // check if it's a TTC
1345 if (stbtt_tag(font_collection, "ttcf")) {
1346 // version 1?
1347 if (ttULONG(font_collection+4) == 0x00010000 || ttULONG(font_collection+4) == 0x00020000) {
1348 return ttLONG(font_collection+8);
1349 }
1350 }
1351 return 0;
1352 }
1353
1354 static stbtt__buf stbtt__get_subrs(stbtt__buf cff, stbtt__buf fontdict)
1355 {
1356 stbtt_uint32 subrsoff = 0, private_loc[2] = { 0, 0 };
1357 stbtt__buf pdict;
1358 stbtt__dict_get_ints(&fontdict, 18, 2, private_loc);
1359 if (!private_loc[1] || !private_loc[0]) return stbtt__new_buf(NULL, 0);
1360 pdict = stbtt__buf_range(&cff, private_loc[1], private_loc[0]);
1361 stbtt__dict_get_ints(&pdict, 19, 1, &subrsoff);
1362 if (!subrsoff) return stbtt__new_buf(NULL, 0);
1363 stbtt__buf_seek(&cff, private_loc[1]+subrsoff);
1364 return stbtt__cff_get_index(&cff);
1365 }
1366
1367 // since most people won't use this, find this table the first time it's needed
1368 static int stbtt__get_svg(stbtt_fontinfo *info)
1369 {
1370 stbtt_uint32 t;
1371 if (info->svg < 0) {
1372 t = stbtt__find_table(info->data, info->fontstart, "SVG ");
1373 if (t) {
1374 stbtt_uint32 offset = ttULONG(info->data + t + 2);
1375 info->svg = t + offset;
1376 } else {
1377 info->svg = 0;
1378 }
1379 }
1380 return info->svg;
1381 }
1382
1383 static int stbtt_InitFont_internal(stbtt_fontinfo *info, unsigned char *data, int fontstart)
1384 {
1385 stbtt_uint32 cmap, t;
1386 stbtt_int32 i,numTables;
1387
1388 info->data = data;
1389 info->fontstart = fontstart;
1390 info->cff = stbtt__new_buf(NULL, 0);
1391
1392 cmap = stbtt__find_table(data, fontstart, "cmap"); // required
1393 info->loca = stbtt__find_table(data, fontstart, "loca"); // required
1394 info->head = stbtt__find_table(data, fontstart, "head"); // required
1395 info->glyf = stbtt__find_table(data, fontstart, "glyf"); // required
1396 info->hhea = stbtt__find_table(data, fontstart, "hhea"); // required
1397 info->hmtx = stbtt__find_table(data, fontstart, "hmtx"); // required
1398 info->kern = stbtt__find_table(data, fontstart, "kern"); // not required
1399 info->gpos = stbtt__find_table(data, fontstart, "GPOS"); // not required
1400
1401 if (!cmap || !info->head || !info->hhea || !info->hmtx)
1402 return 0;
1403 if (info->glyf) {
1404 // required for truetype
1405 if (!info->loca) return 0;
1406 } else {
1407 // initialization for CFF / Type2 fonts (OTF)
1408 stbtt__buf b, topdict, topdictidx;
1409 stbtt_uint32 cstype = 2, charstrings = 0, fdarrayoff = 0, fdselectoff = 0;
1410 stbtt_uint32 cff;
1411
1412 cff = stbtt__find_table(data, fontstart, "CFF ");
1413 if (!cff) return 0;
1414
1415 info->fontdicts = stbtt__new_buf(NULL, 0);
1416 info->fdselect = stbtt__new_buf(NULL, 0);
1417
1418 // @TODO this should use size from table (not 512MB)
1419 info->cff = stbtt__new_buf(data+cff, 512*1024*1024);
1420 b = info->cff;
1421
1422 // read the header
1423 stbtt__buf_skip(&b, 2);
1424 stbtt__buf_seek(&b, stbtt__buf_get8(&b)); // hdrsize
1425
1426 // @TODO the name INDEX could list multiple fonts,
1427 // but we just use the first one.
1428 stbtt__cff_get_index(&b); // name INDEX
1429 topdictidx = stbtt__cff_get_index(&b);
1430 topdict = stbtt__cff_index_get(topdictidx, 0);
1431 stbtt__cff_get_index(&b); // string INDEX
1432 info->gsubrs = stbtt__cff_get_index(&b);
1433
1434 stbtt__dict_get_ints(&topdict, 17, 1, &charstrings);
1435 stbtt__dict_get_ints(&topdict, 0x100 | 6, 1, &cstype);
1436 stbtt__dict_get_ints(&topdict, 0x100 | 36, 1, &fdarrayoff);
1437 stbtt__dict_get_ints(&topdict, 0x100 | 37, 1, &fdselectoff);
1438 info->subrs = stbtt__get_subrs(b, topdict);
1439
1440 // we only support Type 2 charstrings
1441 if (cstype != 2) return 0;
1442 if (charstrings == 0) return 0;
1443
1444 if (fdarrayoff) {
1445 // looks like a CID font
1446 if (!fdselectoff) return 0;
1447 stbtt__buf_seek(&b, fdarrayoff);
1448 info->fontdicts = stbtt__cff_get_index(&b);
1449 info->fdselect = stbtt__buf_range(&b, fdselectoff, b.size-fdselectoff);
1450 }
1451
1452 stbtt__buf_seek(&b, charstrings);
1453 info->charstrings = stbtt__cff_get_index(&b);
1454 }
1455
1456 t = stbtt__find_table(data, fontstart, "maxp");
1457 if (t)
1458 info->numGlyphs = ttUSHORT(data+t+4);
1459 else
1460 info->numGlyphs = 0xffff;
1461
1462 info->svg = -1;
1463
1464 // find a cmap encoding table we understand *now* to avoid searching
1465 // later. (todo: could make this installable)
1466 // the same regardless of glyph.
1467 numTables = ttUSHORT(data + cmap + 2);
1468 info->index_map = 0;
1469 for (i=0; i < numTables; ++i) {
1470 stbtt_uint32 encoding_record = cmap + 4 + 8 * i;
1471 // find an encoding we understand:
1472 switch(ttUSHORT(data+encoding_record)) {
1473 case STBTT_PLATFORM_ID_MICROSOFT:
1474 switch (ttUSHORT(data+encoding_record+2)) {
1475 case STBTT_MS_EID_UNICODE_BMP:
1476 case STBTT_MS_EID_UNICODE_FULL:
1477 // MS/Unicode
1478 info->index_map = cmap + ttULONG(data+encoding_record+4);
1479 break;
1480 }
1481 break;
1482 case STBTT_PLATFORM_ID_UNICODE:
1483 // Mac/iOS has these
1484 // all the encodingIDs are unicode, so we don't bother to check it
1485 info->index_map = cmap + ttULONG(data+encoding_record+4);
1486 break;
1487 }
1488 }
1489 if (info->index_map == 0)
1490 return 0;
1491
1492 info->indexToLocFormat = ttUSHORT(data+info->head + 50);
1493 return 1;
1494 }
1495
1496 STBTT_DEF int stbtt_FindGlyphIndex(const stbtt_fontinfo *info, int unicode_codepoint)
1497 {
1498 stbtt_uint8 *data = info->data;
1499 stbtt_uint32 index_map = info->index_map;
1500
1501 stbtt_uint16 format = ttUSHORT(data + index_map + 0);
1502 if (format == 0) { // apple byte encoding
1503 stbtt_int32 bytes = ttUSHORT(data + index_map + 2);
1504 if (unicode_codepoint < bytes-6)
1505 return ttBYTE(data + index_map + 6 + unicode_codepoint);
1506 return 0;
1507 } else if (format == 6) {
1508 stbtt_uint32 first = ttUSHORT(data + index_map + 6);
1509 stbtt_uint32 count = ttUSHORT(data + index_map + 8);
1510 if ((stbtt_uint32) unicode_codepoint >= first && (stbtt_uint32) unicode_codepoint < first+count)
1511 return ttUSHORT(data + index_map + 10 + (unicode_codepoint - first)*2);
1512 return 0;
1513 } else if (format == 2) {
1514 STBTT_assert(0); // @TODO: high-byte mapping for japanese/chinese/korean
1515 return 0;
1516 } else if (format == 4) { // standard mapping for windows fonts: binary search collection of ranges
1517 stbtt_uint16 segcount = ttUSHORT(data+index_map+6) >> 1;
1518 stbtt_uint16 searchRange = ttUSHORT(data+index_map+8) >> 1;
1519 stbtt_uint16 entrySelector = ttUSHORT(data+index_map+10);
1520 stbtt_uint16 rangeShift = ttUSHORT(data+index_map+12) >> 1;
1521
1522 // do a binary search of the segments
1523 stbtt_uint32 endCount = index_map + 14;
1524 stbtt_uint32 search = endCount;
1525
1526 if (unicode_codepoint > 0xffff)
1527 return 0;
1528
1529 // they lie from endCount .. endCount + segCount
1530 // but searchRange is the nearest power of two, so...
1531 if (unicode_codepoint >= ttUSHORT(data + search + rangeShift*2))
1532 search += rangeShift*2;
1533
1534 // now decrement to bias correctly to find smallest
1535 search -= 2;
1536 while (entrySelector) {
1537 stbtt_uint16 end;
1538 searchRange >>= 1;
1539 end = ttUSHORT(data + search + searchRange*2);
1540 if (unicode_codepoint > end)
1541 search += searchRange*2;
1542 --entrySelector;
1543 }
1544 search += 2;
1545
1546 {
1547 stbtt_uint16 offset, start, last;
1548 stbtt_uint16 item = (stbtt_uint16) ((search - endCount) >> 1);
1549
1550 start = ttUSHORT(data + index_map + 14 + segcount*2 + 2 + 2*item);
1551 last = ttUSHORT(data + endCount + 2*item);
1552 if (unicode_codepoint < start || unicode_codepoint > last)
1553 return 0;
1554
1555 offset = ttUSHORT(data + index_map + 14 + segcount*6 + 2 + 2*item);
1556 if (offset == 0)
1557 return (stbtt_uint16) (unicode_codepoint + ttSHORT(data + index_map + 14 + segcount*4 + 2 + 2*item));
1558
1559 return ttUSHORT(data + offset + (unicode_codepoint-start)*2 + index_map + 14 + segcount*6 + 2 + 2*item);
1560 }
1561 } else if (format == 12 || format == 13) {
1562 stbtt_uint32 ngroups = ttULONG(data+index_map+12);
1563 stbtt_int32 low,high;
1564 low = 0; high = (stbtt_int32)ngroups;
1565 // Binary search the right group.
1566 while (low < high) {
1567 stbtt_int32 mid = low + ((high-low) >> 1); // rounds down, so low <= mid < high
1568 stbtt_uint32 start_char = ttULONG(data+index_map+16+mid*12);
1569 stbtt_uint32 end_char = ttULONG(data+index_map+16+mid*12+4);
1570 if ((stbtt_uint32) unicode_codepoint < start_char)
1571 high = mid;
1572 else if ((stbtt_uint32) unicode_codepoint > end_char)
1573 low = mid+1;
1574 else {
1575 stbtt_uint32 start_glyph = ttULONG(data+index_map+16+mid*12+8);
1576 if (format == 12)
1577 return start_glyph + unicode_codepoint-start_char;
1578 else // format == 13
1579 return start_glyph;
1580 }
1581 }
1582 return 0; // not found
1583 }
1584 // @TODO
1585 STBTT_assert(0);
1586 return 0;
1587 }
1588
1589 STBTT_DEF int stbtt_GetCodepointShape(const stbtt_fontinfo *info, int unicode_codepoint, stbtt_vertex **vertices)
1590 {
1591 return stbtt_GetGlyphShape(info, stbtt_FindGlyphIndex(info, unicode_codepoint), vertices);
1592 }
1593
1594 static void stbtt_setvertex(stbtt_vertex *v, stbtt_uint8 type, stbtt_int32 x, stbtt_int32 y, stbtt_int32 cx, stbtt_int32 cy)
1595 {
1596 v->type = type;
1597 v->x = (stbtt_int16) x;
1598 v->y = (stbtt_int16) y;
1599 v->cx = (stbtt_int16) cx;
1600 v->cy = (stbtt_int16) cy;
1601 }
1602
1603 static int stbtt__GetGlyfOffset(const stbtt_fontinfo *info, int glyph_index)
1604 {
1605 int g1,g2;
1606
1607 STBTT_assert(!info->cff.size);
1608
1609 if (glyph_index >= info->numGlyphs) return -1; // glyph index out of range
1610 if (info->indexToLocFormat >= 2) return -1; // unknown index->glyph map format
1611
1612 if (info->indexToLocFormat == 0) {
1613 g1 = info->glyf + ttUSHORT(info->data + info->loca + glyph_index * 2) * 2;
1614 g2 = info->glyf + ttUSHORT(info->data + info->loca + glyph_index * 2 + 2) * 2;
1615 } else {
1616 g1 = info->glyf + ttULONG (info->data + info->loca + glyph_index * 4);
1617 g2 = info->glyf + ttULONG (info->data + info->loca + glyph_index * 4 + 4);
1618 }
1619
1620 return g1==g2 ? -1 : g1; // if length is 0, return -1
1621 }
1622
1623 static int stbtt__GetGlyphInfoT2(const stbtt_fontinfo *info, int glyph_index, int *x0, int *y0, int *x1, int *y1);
1624
1625 STBTT_DEF int stbtt_GetGlyphBox(const stbtt_fontinfo *info, int glyph_index, int *x0, int *y0, int *x1, int *y1)
1626 {
1627 if (info->cff.size) {
1628 stbtt__GetGlyphInfoT2(info, glyph_index, x0, y0, x1, y1);
1629 } else {
1630 int g = stbtt__GetGlyfOffset(info, glyph_index);
1631 if (g < 0) return 0;
1632
1633 if (x0) *x0 = ttSHORT(info->data + g + 2);
1634 if (y0) *y0 = ttSHORT(info->data + g + 4);
1635 if (x1) *x1 = ttSHORT(info->data + g + 6);
1636 if (y1) *y1 = ttSHORT(info->data + g + 8);
1637 }
1638 return 1;
1639 }
1640
1641 STBTT_DEF int stbtt_GetCodepointBox(const stbtt_fontinfo *info, int codepoint, int *x0, int *y0, int *x1, int *y1)
1642 {
1643 return stbtt_GetGlyphBox(info, stbtt_FindGlyphIndex(info,codepoint), x0,y0,x1,y1);
1644 }
1645
1646 STBTT_DEF int stbtt_IsGlyphEmpty(const stbtt_fontinfo *info, int glyph_index)
1647 {
1648 stbtt_int16 numberOfContours;
1649 int g;
1650 if (info->cff.size)
1651 return stbtt__GetGlyphInfoT2(info, glyph_index, NULL, NULL, NULL, NULL) == 0;
1652 g = stbtt__GetGlyfOffset(info, glyph_index);
1653 if (g < 0) return 1;
1654 numberOfContours = ttSHORT(info->data + g);
1655 return numberOfContours == 0;
1656 }
1657
1658 static int stbtt__close_shape(stbtt_vertex *vertices, int num_vertices, int was_off, int start_off,
1659 stbtt_int32 sx, stbtt_int32 sy, stbtt_int32 scx, stbtt_int32 scy, stbtt_int32 cx, stbtt_int32 cy)
1660 {
1661 if (start_off) {
1662 if (was_off)
1663 stbtt_setvertex(&vertices[num_vertices++], STBTT_vcurve, (cx+scx)>>1, (cy+scy)>>1, cx,cy);
1664 stbtt_setvertex(&vertices[num_vertices++], STBTT_vcurve, sx,sy,scx,scy);
1665 } else {
1666 if (was_off)
1667 stbtt_setvertex(&vertices[num_vertices++], STBTT_vcurve,sx,sy,cx,cy);
1668 else
1669 stbtt_setvertex(&vertices[num_vertices++], STBTT_vline,sx,sy,0,0);
1670 }
1671 return num_vertices;
1672 }
1673
1674 static int stbtt__GetGlyphShapeTT(const stbtt_fontinfo *info, int glyph_index, stbtt_vertex **pvertices)
1675 {
1676 stbtt_int16 numberOfContours;
1677 stbtt_uint8 *endPtsOfContours;
1678 stbtt_uint8 *data = info->data;
1679 stbtt_vertex *vertices=0;
1680 int num_vertices=0;
1681 int g = stbtt__GetGlyfOffset(info, glyph_index);
1682
1683 *pvertices = NULL;
1684
1685 if (g < 0) return 0;
1686
1687 numberOfContours = ttSHORT(data + g);
1688
1689 if (numberOfContours > 0) {
1690 stbtt_uint8 flags=0,flagcount;
1691 stbtt_int32 ins, i,j=0,m,n, next_move, was_off=0, off, start_off=0;
1692 stbtt_int32 x,y,cx,cy,sx,sy, scx,scy;
1693 stbtt_uint8 *points;
1694 endPtsOfContours = (data + g + 10);
1695 ins = ttUSHORT(data + g + 10 + numberOfContours * 2);
1696 points = data + g + 10 + numberOfContours * 2 + 2 + ins;
1697
1698 n = 1+ttUSHORT(endPtsOfContours + numberOfContours*2-2);
1699
1700 m = n + 2*numberOfContours; // a loose bound on how many vertices we might need
1701 vertices = (stbtt_vertex *) STBTT_malloc(m * sizeof(vertices[0]), info->userdata);
1702 if (vertices == 0)
1703 return 0;
1704
1705 next_move = 0;
1706 flagcount=0;
1707
1708 // in first pass, we load uninterpreted data into the allocated array
1709 // above, shifted to the end of the array so we won't overwrite it when
1710 // we create our final data starting from the front
1711
1712 off = m - n; // starting offset for uninterpreted data, regardless of how m ends up being calculated
1713
1714 // first load flags
1715
1716 for (i=0; i < n; ++i) {
1717 if (flagcount == 0) {
1718 flags = *points++;
1719 if (flags & 8)
1720 flagcount = *points++;
1721 } else
1722 --flagcount;
1723 vertices[off+i].type = flags;
1724 }
1725
1726 // now load x coordinates
1727 x=0;
1728 for (i=0; i < n; ++i) {
1729 flags = vertices[off+i].type;
1730 if (flags & 2) {
1731 stbtt_int16 dx = *points++;
1732 x += (flags & 16) ? dx : -dx; // ???
1733 } else {
1734 if (!(flags & 16)) {
1735 x = x + (stbtt_int16) (points[0]*256 + points[1]);
1736 points += 2;
1737 }
1738 }
1739 vertices[off+i].x = (stbtt_int16) x;
1740 }
1741
1742 // now load y coordinates
1743 y=0;
1744 for (i=0; i < n; ++i) {
1745 flags = vertices[off+i].type;
1746 if (flags & 4) {
1747 stbtt_int16 dy = *points++;
1748 y += (flags & 32) ? dy : -dy; // ???
1749 } else {
1750 if (!(flags & 32)) {
1751 y = y + (stbtt_int16) (points[0]*256 + points[1]);
1752 points += 2;
1753 }
1754 }
1755 vertices[off+i].y = (stbtt_int16) y;
1756 }
1757
1758 // now convert them to our format
1759 num_vertices=0;
1760 sx = sy = cx = cy = scx = scy = 0;
1761 for (i=0; i < n; ++i) {
1762 flags = vertices[off+i].type;
1763 x = (stbtt_int16) vertices[off+i].x;
1764 y = (stbtt_int16) vertices[off+i].y;
1765
1766 if (next_move == i) {
1767 if (i != 0)
1768 num_vertices = stbtt__close_shape(vertices, num_vertices, was_off, start_off, sx,sy,scx,scy,cx,cy);
1769
1770 // now start the new one
1771 start_off = !(flags & 1);
1772 if (start_off) {
1773 // if we start off with an off-curve point, then when we need to find a point on the curve
1774 // where we can start, and we need to save some state for when we wraparound.
1775 scx = x;
1776 scy = y;
1777 if (!(vertices[off+i+1].type & 1)) {
1778 // next point is also a curve point, so interpolate an on-point curve
1779 sx = (x + (stbtt_int32) vertices[off+i+1].x) >> 1;
1780 sy = (y + (stbtt_int32) vertices[off+i+1].y) >> 1;
1781 } else {
1782 // otherwise just use the next point as our start point
1783 sx = (stbtt_int32) vertices[off+i+1].x;
1784 sy = (stbtt_int32) vertices[off+i+1].y;
1785 ++i; // we're using point i+1 as the starting point, so skip it
1786 }
1787 } else {
1788 sx = x;
1789 sy = y;
1790 }
1791 stbtt_setvertex(&vertices[num_vertices++], STBTT_vmove,sx,sy,0,0);
1792 was_off = 0;
1793 next_move = 1 + ttUSHORT(endPtsOfContours+j*2);
1794 ++j;
1795 } else {
1796 if (!(flags & 1)) { // if it's a curve
1797 if (was_off) // two off-curve control points in a row means interpolate an on-curve midpoint
1798 stbtt_setvertex(&vertices[num_vertices++], STBTT_vcurve, (cx+x)>>1, (cy+y)>>1, cx, cy);
1799 cx = x;
1800 cy = y;
1801 was_off = 1;
1802 } else {
1803 if (was_off)
1804 stbtt_setvertex(&vertices[num_vertices++], STBTT_vcurve, x,y, cx, cy);
1805 else
1806 stbtt_setvertex(&vertices[num_vertices++], STBTT_vline, x,y,0,0);
1807 was_off = 0;
1808 }
1809 }
1810 }
1811 num_vertices = stbtt__close_shape(vertices, num_vertices, was_off, start_off, sx,sy,scx,scy,cx,cy);
1812 } else if (numberOfContours < 0) {
1813 // Compound shapes.
1814 int more = 1;
1815 stbtt_uint8 *comp = data + g + 10;
1816 num_vertices = 0;
1817 vertices = 0;
1818 while (more) {
1819 stbtt_uint16 flags, gidx;
1820 int comp_num_verts = 0, i;
1821 stbtt_vertex *comp_verts = 0, *tmp = 0;
1822 float mtx[6] = {1,0,0,1,0,0}, m, n;
1823
1824 flags = ttSHORT(comp); comp+=2;
1825 gidx = ttSHORT(comp); comp+=2;
1826
1827 if (flags & 2) { // XY values
1828 if (flags & 1) { // shorts
1829 mtx[4] = ttSHORT(comp); comp+=2;
1830 mtx[5] = ttSHORT(comp); comp+=2;
1831 } else {
1832 mtx[4] = ttCHAR(comp); comp+=1;
1833 mtx[5] = ttCHAR(comp); comp+=1;
1834 }
1835 }
1836 else {
1837 // @TODO handle matching point
1838 STBTT_assert(0);
1839 }
1840 if (flags & (1<<3)) { // WE_HAVE_A_SCALE
1841 mtx[0] = mtx[3] = ttSHORT(comp)/16384.0f; comp+=2;
1842 mtx[1] = mtx[2] = 0;
1843 } else if (flags & (1<<6)) { // WE_HAVE_AN_X_AND_YSCALE
1844 mtx[0] = ttSHORT(comp)/16384.0f; comp+=2;
1845 mtx[1] = mtx[2] = 0;
1846 mtx[3] = ttSHORT(comp)/16384.0f; comp+=2;
1847 } else if (flags & (1<<7)) { // WE_HAVE_A_TWO_BY_TWO
1848 mtx[0] = ttSHORT(comp)/16384.0f; comp+=2;
1849 mtx[1] = ttSHORT(comp)/16384.0f; comp+=2;
1850 mtx[2] = ttSHORT(comp)/16384.0f; comp+=2;
1851 mtx[3] = ttSHORT(comp)/16384.0f; comp+=2;
1852 }
1853
1854 // Find transformation scales.
1855 m = (float) STBTT_sqrt(mtx[0]*mtx[0] + mtx[1]*mtx[1]);
1856 n = (float) STBTT_sqrt(mtx[2]*mtx[2] + mtx[3]*mtx[3]);
1857
1858 // Get indexed glyph.
1859 comp_num_verts = stbtt_GetGlyphShape(info, gidx, &comp_verts);
1860 if (comp_num_verts > 0) {
1861 // Transform vertices.
1862 for (i = 0; i < comp_num_verts; ++i) {
1863 stbtt_vertex* v = &comp_verts[i];
1864 stbtt_vertex_type x,y;
1865 x=v->x; y=v->y;
1866 v->x = (stbtt_vertex_type)(m * (mtx[0]*x + mtx[2]*y + mtx[4]));
1867 v->y = (stbtt_vertex_type)(n * (mtx[1]*x + mtx[3]*y + mtx[5]));
1868 x=v->cx; y=v->cy;
1869 v->cx = (stbtt_vertex_type)(m * (mtx[0]*x + mtx[2]*y + mtx[4]));
1870 v->cy = (stbtt_vertex_type)(n * (mtx[1]*x + mtx[3]*y + mtx[5]));
1871 }
1872 // Append vertices.
1873 tmp = (stbtt_vertex*)STBTT_malloc((num_vertices+comp_num_verts)*sizeof(stbtt_vertex), info->userdata);
1874 if (!tmp) {
1875 if (vertices) STBTT_free(vertices, info->userdata);
1876 if (comp_verts) STBTT_free(comp_verts, info->userdata);
1877 return 0;
1878 }
1879 if (num_vertices > 0 && vertices) STBTT_memcpy(tmp, vertices, num_vertices*sizeof(stbtt_vertex));
1880 STBTT_memcpy(tmp+num_vertices, comp_verts, comp_num_verts*sizeof(stbtt_vertex));
1881 if (vertices) STBTT_free(vertices, info->userdata);
1882 vertices = tmp;
1883 STBTT_free(comp_verts, info->userdata);
1884 num_vertices += comp_num_verts;
1885 }
1886 // More components ?
1887 more = flags & (1<<5);
1888 }
1889 } else {
1890 // numberOfCounters == 0, do nothing
1891 }
1892
1893 *pvertices = vertices;
1894 return num_vertices;
1895 }
1896
1897 typedef struct
1898 {
1899 int bounds;
1900 int started;
1901 float first_x, first_y;
1902 float x, y;
1903 stbtt_int32 min_x, max_x, min_y, max_y;
1904
1905 stbtt_vertex *pvertices;
1906 int num_vertices;
1907 } stbtt__csctx;
1908
1909 #define STBTT__CSCTX_INIT(bounds) {bounds,0, 0,0, 0,0, 0,0,0,0, NULL, 0}
1910
1911 static void stbtt__track_vertex(stbtt__csctx *c, stbtt_int32 x, stbtt_int32 y)
1912 {
1913 if (x > c->max_x || !c->started) c->max_x = x;
1914 if (y > c->max_y || !c->started) c->max_y = y;
1915 if (x < c->min_x || !c->started) c->min_x = x;
1916 if (y < c->min_y || !c->started) c->min_y = y;
1917 c->started = 1;
1918 }
1919
1920 static void stbtt__csctx_v(stbtt__csctx *c, stbtt_uint8 type, stbtt_int32 x, stbtt_int32 y, stbtt_int32 cx, stbtt_int32 cy, stbtt_int32 cx1, stbtt_int32 cy1)
1921 {
1922 if (c->bounds) {
1923 stbtt__track_vertex(c, x, y);
1924 if (type == STBTT_vcubic) {
1925 stbtt__track_vertex(c, cx, cy);
1926 stbtt__track_vertex(c, cx1, cy1);
1927 }
1928 } else {
1929 stbtt_setvertex(&c->pvertices[c->num_vertices], type, x, y, cx, cy);
1930 c->pvertices[c->num_vertices].cx1 = (stbtt_int16) cx1;
1931 c->pvertices[c->num_vertices].cy1 = (stbtt_int16) cy1;
1932 }
1933 c->num_vertices++;
1934 }
1935
1936 static void stbtt__csctx_close_shape(stbtt__csctx *ctx)
1937 {
1938 if (ctx->first_x != ctx->x || ctx->first_y != ctx->y)
1939 stbtt__csctx_v(ctx, STBTT_vline, (int)ctx->first_x, (int)ctx->first_y, 0, 0, 0, 0);
1940 }
1941
1942 static void stbtt__csctx_rmove_to(stbtt__csctx *ctx, float dx, float dy)
1943 {
1944 stbtt__csctx_close_shape(ctx);
1945 ctx->first_x = ctx->x = ctx->x + dx;
1946 ctx->first_y = ctx->y = ctx->y + dy;
1947 stbtt__csctx_v(ctx, STBTT_vmove, (int)ctx->x, (int)ctx->y, 0, 0, 0, 0);
1948 }
1949
1950 static void stbtt__csctx_rline_to(stbtt__csctx *ctx, float dx, float dy)
1951 {
1952 ctx->x += dx;
1953 ctx->y += dy;
1954 stbtt__csctx_v(ctx, STBTT_vline, (int)ctx->x, (int)ctx->y, 0, 0, 0, 0);
1955 }
1956
1957 static void stbtt__csctx_rccurve_to(stbtt__csctx *ctx, float dx1, float dy1, float dx2, float dy2, float dx3, float dy3)
1958 {
1959 float cx1 = ctx->x + dx1;
1960 float cy1 = ctx->y + dy1;
1961 float cx2 = cx1 + dx2;
1962 float cy2 = cy1 + dy2;
1963 ctx->x = cx2 + dx3;
1964 ctx->y = cy2 + dy3;
1965 stbtt__csctx_v(ctx, STBTT_vcubic, (int)ctx->x, (int)ctx->y, (int)cx1, (int)cy1, (int)cx2, (int)cy2);
1966 }
1967
1968 static stbtt__buf stbtt__get_subr(stbtt__buf idx, int n)
1969 {
1970 int count = stbtt__cff_index_count(&idx);
1971 int bias = 107;
1972 if (count >= 33900)
1973 bias = 32768;
1974 else if (count >= 1240)
1975 bias = 1131;
1976 n += bias;
1977 if (n < 0 || n >= count)
1978 return stbtt__new_buf(NULL, 0);
1979 return stbtt__cff_index_get(idx, n);
1980 }
1981
1982 static stbtt__buf stbtt__cid_get_glyph_subrs(const stbtt_fontinfo *info, int glyph_index)
1983 {
1984 stbtt__buf fdselect = info->fdselect;
1985 int nranges, start, end, v, fmt, fdselector = -1, i;
1986
1987 stbtt__buf_seek(&fdselect, 0);
1988 fmt = stbtt__buf_get8(&fdselect);
1989 if (fmt == 0) {
1990 // untested
1991 stbtt__buf_skip(&fdselect, glyph_index);
1992 fdselector = stbtt__buf_get8(&fdselect);
1993 } else if (fmt == 3) {
1994 nranges = stbtt__buf_get16(&fdselect);
1995 start = stbtt__buf_get16(&fdselect);
1996 for (i = 0; i < nranges; i++) {
1997 v = stbtt__buf_get8(&fdselect);
1998 end = stbtt__buf_get16(&fdselect);
1999 if (glyph_index >= start && glyph_index < end) {
2000 fdselector = v;
2001 break;
2002 }
2003 start = end;
2004 }
2005 }
2006 if (fdselector == -1) stbtt__new_buf(NULL, 0);
2007 return stbtt__get_subrs(info->cff, stbtt__cff_index_get(info->fontdicts, fdselector));
2008 }
2009
2010 static int stbtt__run_charstring(const stbtt_fontinfo *info, int glyph_index, stbtt__csctx *c)
2011 {
2012 int in_header = 1, maskbits = 0, subr_stack_height = 0, sp = 0, v, i, b0;
2013 int has_subrs = 0, clear_stack;
2014 float s[48];
2015 stbtt__buf subr_stack[10], subrs = info->subrs, b;
2016 float f;
2017
2018 #define STBTT__CSERR(s) (0)
2019
2020 // this currently ignores the initial width value, which isn't needed if we have hmtx
2021 b = stbtt__cff_index_get(info->charstrings, glyph_index);
2022 while (b.cursor < b.size) {
2023 i = 0;
2024 clear_stack = 1;
2025 b0 = stbtt__buf_get8(&b);
2026 switch (b0) {
2027 // @TODO implement hinting
2028 case 0x13: // hintmask
2029 case 0x14: // cntrmask
2030 if (in_header)
2031 maskbits += (sp / 2); // implicit "vstem"
2032 in_header = 0;
2033 stbtt__buf_skip(&b, (maskbits + 7) / 8);
2034 break;
2035
2036 case 0x01: // hstem
2037 case 0x03: // vstem
2038 case 0x12: // hstemhm
2039 case 0x17: // vstemhm
2040 maskbits += (sp / 2);
2041 break;
2042
2043 case 0x15: // rmoveto
2044 in_header = 0;
2045 if (sp < 2) return STBTT__CSERR("rmoveto stack");
2046 stbtt__csctx_rmove_to(c, s[sp-2], s[sp-1]);
2047 break;
2048 case 0x04: // vmoveto
2049 in_header = 0;
2050 if (sp < 1) return STBTT__CSERR("vmoveto stack");
2051 stbtt__csctx_rmove_to(c, 0, s[sp-1]);
2052 break;
2053 case 0x16: // hmoveto
2054 in_header = 0;
2055 if (sp < 1) return STBTT__CSERR("hmoveto stack");
2056 stbtt__csctx_rmove_to(c, s[sp-1], 0);
2057 break;
2058
2059 case 0x05: // rlineto
2060 if (sp < 2) return STBTT__CSERR("rlineto stack");
2061 for (; i + 1 < sp; i += 2)
2062 stbtt__csctx_rline_to(c, s[i], s[i+1]);
2063 break;
2064
2065 // hlineto/vlineto and vhcurveto/hvcurveto alternate horizontal and vertical
2066 // starting from a different place.
2067
2068 case 0x07: // vlineto
2069 if (sp < 1) return STBTT__CSERR("vlineto stack");
2070 goto vlineto;
2071 case 0x06: // hlineto
2072 if (sp < 1) return STBTT__CSERR("hlineto stack");
2073 for (;;) {
2074 if (i >= sp) break;
2075 stbtt__csctx_rline_to(c, s[i], 0);
2076 i++;
2077 vlineto:
2078 if (i >= sp) break;
2079 stbtt__csctx_rline_to(c, 0, s[i]);
2080 i++;
2081 }
2082 break;
2083
2084 case 0x1F: // hvcurveto
2085 if (sp < 4) return STBTT__CSERR("hvcurveto stack");
2086 goto hvcurveto;
2087 case 0x1E: // vhcurveto
2088 if (sp < 4) return STBTT__CSERR("vhcurveto stack");
2089 for (;;) {
2090 if (i + 3 >= sp) break;
2091 stbtt__csctx_rccurve_to(c, 0, s[i], s[i+1], s[i+2], s[i+3], (sp - i == 5) ? s[i + 4] : 0.0f);
2092 i += 4;
2093 hvcurveto:
2094 if (i + 3 >= sp) break;
2095 stbtt__csctx_rccurve_to(c, s[i], 0, s[i+1], s[i+2], (sp - i == 5) ? s[i+4] : 0.0f, s[i+3]);
2096 i += 4;
2097 }
2098 break;
2099
2100 case 0x08: // rrcurveto
2101 if (sp < 6) return STBTT__CSERR("rcurveline stack");
2102 for (; i + 5 < sp; i += 6)
2103 stbtt__csctx_rccurve_to(c, s[i], s[i+1], s[i+2], s[i+3], s[i+4], s[i+5]);
2104 break;
2105
2106 case 0x18: // rcurveline
2107 if (sp < 8) return STBTT__CSERR("rcurveline stack");
2108 for (; i + 5 < sp - 2; i += 6)
2109 stbtt__csctx_rccurve_to(c, s[i], s[i+1], s[i+2], s[i+3], s[i+4], s[i+5]);
2110 if (i + 1 >= sp) return STBTT__CSERR("rcurveline stack");
2111 stbtt__csctx_rline_to(c, s[i], s[i+1]);
2112 break;
2113
2114 case 0x19: // rlinecurve
2115 if (sp < 8) return STBTT__CSERR("rlinecurve stack");
2116 for (; i + 1 < sp - 6; i += 2)
2117 stbtt__csctx_rline_to(c, s[i], s[i+1]);
2118 if (i + 5 >= sp) return STBTT__CSERR("rlinecurve stack");
2119 stbtt__csctx_rccurve_to(c, s[i], s[i+1], s[i+2], s[i+3], s[i+4], s[i+5]);
2120 break;
2121
2122 case 0x1A: // vvcurveto
2123 case 0x1B: // hhcurveto
2124 if (sp < 4) return STBTT__CSERR("(vv|hh)curveto stack");
2125 f = 0.0;
2126 if (sp & 1) { f = s[i]; i++; }
2127 for (; i + 3 < sp; i += 4) {
2128 if (b0 == 0x1B)
2129 stbtt__csctx_rccurve_to(c, s[i], f, s[i+1], s[i+2], s[i+3], 0.0);
2130 else
2131 stbtt__csctx_rccurve_to(c, f, s[i], s[i+1], s[i+2], 0.0, s[i+3]);
2132 f = 0.0;
2133 }
2134 break;
2135
2136 case 0x0A: // callsubr
2137 if (!has_subrs) {
2138 if (info->fdselect.size)
2139 subrs = stbtt__cid_get_glyph_subrs(info, glyph_index);
2140 has_subrs = 1;
2141 }
2142 // FALLTHROUGH
2143 case 0x1D: // callgsubr
2144 if (sp < 1) return STBTT__CSERR("call(g|)subr stack");
2145 v = (int) s[--sp];
2146 if (subr_stack_height >= 10) return STBTT__CSERR("recursion limit");
2147 subr_stack[subr_stack_height++] = b;
2148 b = stbtt__get_subr(b0 == 0x0A ? subrs : info->gsubrs, v);
2149 if (b.size == 0) return STBTT__CSERR("subr not found");
2150 b.cursor = 0;
2151 clear_stack = 0;
2152 break;
2153
2154 case 0x0B: // return
2155 if (subr_stack_height <= 0) return STBTT__CSERR("return outside subr");
2156 b = subr_stack[--subr_stack_height];
2157 clear_stack = 0;
2158 break;
2159
2160 case 0x0E: // endchar
2161 stbtt__csctx_close_shape(c);
2162 return 1;
2163
2164 case 0x0C: { // two-byte escape
2165 float dx1, dx2, dx3, dx4, dx5, dx6, dy1, dy2, dy3, dy4, dy5, dy6;
2166 float dx, dy;
2167 int b1 = stbtt__buf_get8(&b);
2168 switch (b1) {
2169 // @TODO These "flex" implementations ignore the flex-depth and resolution,
2170 // and always draw beziers.
2171 case 0x22: // hflex
2172 if (sp < 7) return STBTT__CSERR("hflex stack");
2173 dx1 = s[0];
2174 dx2 = s[1];
2175 dy2 = s[2];
2176 dx3 = s[3];
2177 dx4 = s[4];
2178 dx5 = s[5];
2179 dx6 = s[6];
2180 stbtt__csctx_rccurve_to(c, dx1, 0, dx2, dy2, dx3, 0);
2181 stbtt__csctx_rccurve_to(c, dx4, 0, dx5, -dy2, dx6, 0);
2182 break;
2183
2184 case 0x23: // flex
2185 if (sp < 13) return STBTT__CSERR("flex stack");
2186 dx1 = s[0];
2187 dy1 = s[1];
2188 dx2 = s[2];
2189 dy2 = s[3];
2190 dx3 = s[4];
2191 dy3 = s[5];
2192 dx4 = s[6];
2193 dy4 = s[7];
2194 dx5 = s[8];
2195 dy5 = s[9];
2196 dx6 = s[10];
2197 dy6 = s[11];
2198 //fd is s[12]
2199 stbtt__csctx_rccurve_to(c, dx1, dy1, dx2, dy2, dx3, dy3);
2200 stbtt__csctx_rccurve_to(c, dx4, dy4, dx5, dy5, dx6, dy6);
2201 break;
2202
2203 case 0x24: // hflex1
2204 if (sp < 9) return STBTT__CSERR("hflex1 stack");
2205 dx1 = s[0];
2206 dy1 = s[1];
2207 dx2 = s[2];
2208 dy2 = s[3];
2209 dx3 = s[4];
2210 dx4 = s[5];
2211 dx5 = s[6];
2212 dy5 = s[7];
2213 dx6 = s[8];
2214 stbtt__csctx_rccurve_to(c, dx1, dy1, dx2, dy2, dx3, 0);
2215 stbtt__csctx_rccurve_to(c, dx4, 0, dx5, dy5, dx6, -(dy1+dy2+dy5));
2216 break;
2217
2218 case 0x25: // flex1
2219 if (sp < 11) return STBTT__CSERR("flex1 stack");
2220 dx1 = s[0];
2221 dy1 = s[1];
2222 dx2 = s[2];
2223 dy2 = s[3];
2224 dx3 = s[4];
2225 dy3 = s[5];
2226 dx4 = s[6];
2227 dy4 = s[7];
2228 dx5 = s[8];
2229 dy5 = s[9];
2230 dx6 = dy6 = s[10];
2231 dx = dx1+dx2+dx3+dx4+dx5;
2232 dy = dy1+dy2+dy3+dy4+dy5;
2233 if (STBTT_fabs(dx) > STBTT_fabs(dy))
2234 dy6 = -dy;
2235 else
2236 dx6 = -dx;
2237 stbtt__csctx_rccurve_to(c, dx1, dy1, dx2, dy2, dx3, dy3);
2238 stbtt__csctx_rccurve_to(c, dx4, dy4, dx5, dy5, dx6, dy6);
2239 break;
2240
2241 default:
2242 return STBTT__CSERR("unimplemented");
2243 }
2244 } break;
2245
2246 default:
2247 if (b0 != 255 && b0 != 28 && b0 < 32)
2248 return STBTT__CSERR("reserved operator");
2249
2250 // push immediate
2251 if (b0 == 255) {
2252 f = (float)(stbtt_int32)stbtt__buf_get32(&b) / 0x10000;
2253 } else {
2254 stbtt__buf_skip(&b, -1);
2255 f = (float)(stbtt_int16)stbtt__cff_int(&b);
2256 }
2257 if (sp >= 48) return STBTT__CSERR("push stack overflow");
2258 s[sp++] = f;
2259 clear_stack = 0;
2260 break;
2261 }
2262 if (clear_stack) sp = 0;
2263 }
2264 return STBTT__CSERR("no endchar");
2265
2266 #undef STBTT__CSERR
2267 }
2268
2269 static int stbtt__GetGlyphShapeT2(const stbtt_fontinfo *info, int glyph_index, stbtt_vertex **pvertices)
2270 {
2271 // runs the charstring twice, once to count and once to output (to avoid realloc)
2272 stbtt__csctx count_ctx = STBTT__CSCTX_INIT(1);
2273 stbtt__csctx output_ctx = STBTT__CSCTX_INIT(0);
2274 if (stbtt__run_charstring(info, glyph_index, &count_ctx)) {
2275 *pvertices = (stbtt_vertex*)STBTT_malloc(count_ctx.num_vertices*sizeof(stbtt_vertex), info->userdata);
2276 output_ctx.pvertices = *pvertices;
2277 if (stbtt__run_charstring(info, glyph_index, &output_ctx)) {
2278 STBTT_assert(output_ctx.num_vertices == count_ctx.num_vertices);
2279 return output_ctx.num_vertices;
2280 }
2281 }
2282 *pvertices = NULL;
2283 return 0;
2284 }
2285
2286 static int stbtt__GetGlyphInfoT2(const stbtt_fontinfo *info, int glyph_index, int *x0, int *y0, int *x1, int *y1)
2287 {
2288 stbtt__csctx c = STBTT__CSCTX_INIT(1);
2289 int r = stbtt__run_charstring(info, glyph_index, &c);
2290 if (x0) *x0 = r ? c.min_x : 0;
2291 if (y0) *y0 = r ? c.min_y : 0;
2292 if (x1) *x1 = r ? c.max_x : 0;
2293 if (y1) *y1 = r ? c.max_y : 0;
2294 return r ? c.num_vertices : 0;
2295 }
2296
2297 STBTT_DEF int stbtt_GetGlyphShape(const stbtt_fontinfo *info, int glyph_index, stbtt_vertex **pvertices)
2298 {
2299 if (!info->cff.size)
2300 return stbtt__GetGlyphShapeTT(info, glyph_index, pvertices);
2301 else
2302 return stbtt__GetGlyphShapeT2(info, glyph_index, pvertices);
2303 }
2304
2305 STBTT_DEF void stbtt_GetGlyphHMetrics(const stbtt_fontinfo *info, int glyph_index, int *advanceWidth, int *leftSideBearing)
2306 {
2307 stbtt_uint16 numOfLongHorMetrics = ttUSHORT(info->data+info->hhea + 34);
2308 if (glyph_index < numOfLongHorMetrics) {
2309 if (advanceWidth) *advanceWidth = ttSHORT(info->data + info->hmtx + 4*glyph_index);
2310 if (leftSideBearing) *leftSideBearing = ttSHORT(info->data + info->hmtx + 4*glyph_index + 2);
2311 } else {
2312 if (advanceWidth) *advanceWidth = ttSHORT(info->data + info->hmtx + 4*(numOfLongHorMetrics-1));
2313 if (leftSideBearing) *leftSideBearing = ttSHORT(info->data + info->hmtx + 4*numOfLongHorMetrics + 2*(glyph_index - numOfLongHorMetrics));
2314 }
2315 }
2316
2317 STBTT_DEF int stbtt_GetKerningTableLength(const stbtt_fontinfo *info)
2318 {
2319 stbtt_uint8 *data = info->data + info->kern;
2320
2321 // we only look at the first table. it must be 'horizontal' and format 0.
2322 if (!info->kern)
2323 return 0;
2324 if (ttUSHORT(data+2) < 1) // number of tables, need at least 1
2325 return 0;
2326 if (ttUSHORT(data+8) != 1) // horizontal flag must be set in format
2327 return 0;
2328
2329 return ttUSHORT(data+10);
2330 }
2331
2332 STBTT_DEF int stbtt_GetKerningTable(const stbtt_fontinfo *info, stbtt_kerningentry* table, int table_length)
2333 {
2334 stbtt_uint8 *data = info->data + info->kern;
2335 int k, length;
2336
2337 // we only look at the first table. it must be 'horizontal' and format 0.
2338 if (!info->kern)
2339 return 0;
2340 if (ttUSHORT(data+2) < 1) // number of tables, need at least 1
2341 return 0;
2342 if (ttUSHORT(data+8) != 1) // horizontal flag must be set in format
2343 return 0;
2344
2345 length = ttUSHORT(data+10);
2346 if (table_length < length)
2347 length = table_length;
2348
2349 for (k = 0; k < length; k++)
2350 {
2351 table[k].glyph1 = ttUSHORT(data+18+(k*6));
2352 table[k].glyph2 = ttUSHORT(data+20+(k*6));
2353 table[k].advance = ttSHORT(data+22+(k*6));
2354 }
2355
2356 return length;
2357 }
2358
2359 static int stbtt__GetGlyphKernInfoAdvance(const stbtt_fontinfo *info, int glyph1, int glyph2)
2360 {
2361 stbtt_uint8 *data = info->data + info->kern;
2362 stbtt_uint32 needle, straw;
2363 int l, r, m;
2364
2365 // we only look at the first table. it must be 'horizontal' and format 0.
2366 if (!info->kern)
2367 return 0;
2368 if (ttUSHORT(data+2) < 1) // number of tables, need at least 1
2369 return 0;
2370 if (ttUSHORT(data+8) != 1) // horizontal flag must be set in format
2371 return 0;
2372
2373 l = 0;
2374 r = ttUSHORT(data+10) - 1;
2375 needle = glyph1 << 16 | glyph2;
2376 while (l <= r) {
2377 m = (l + r) >> 1;
2378 straw = ttULONG(data+18+(m*6)); // note: unaligned read
2379 if (needle < straw)
2380 r = m - 1;
2381 else if (needle > straw)
2382 l = m + 1;
2383 else
2384 return ttSHORT(data+22+(m*6));
2385 }
2386 return 0;
2387 }
2388
2389 static stbtt_int32 stbtt__GetCoverageIndex(stbtt_uint8 *coverageTable, int glyph)
2390 {
2391 stbtt_uint16 coverageFormat = ttUSHORT(coverageTable);
2392 switch (coverageFormat) {
2393 case 1: {
2394 stbtt_uint16 glyphCount = ttUSHORT(coverageTable + 2);
2395
2396 // Binary search.
2397 stbtt_int32 l=0, r=glyphCount-1, m;
2398 int straw, needle=glyph;
2399 while (l <= r) {
2400 stbtt_uint8 *glyphArray = coverageTable + 4;
2401 stbtt_uint16 glyphID;
2402 m = (l + r) >> 1;
2403 glyphID = ttUSHORT(glyphArray + 2 * m);
2404 straw = glyphID;
2405 if (needle < straw)
2406 r = m - 1;
2407 else if (needle > straw)
2408 l = m + 1;
2409 else {
2410 return m;
2411 }
2412 }
2413 break;
2414 }
2415
2416 case 2: {
2417 stbtt_uint16 rangeCount = ttUSHORT(coverageTable + 2);
2418 stbtt_uint8 *rangeArray = coverageTable + 4;
2419
2420 // Binary search.
2421 stbtt_int32 l=0, r=rangeCount-1, m;
2422 int strawStart, strawEnd, needle=glyph;
2423 while (l <= r) {
2424 stbtt_uint8 *rangeRecord;
2425 m = (l + r) >> 1;
2426 rangeRecord = rangeArray + 6 * m;
2427 strawStart = ttUSHORT(rangeRecord);
2428 strawEnd = ttUSHORT(rangeRecord + 2);
2429 if (needle < strawStart)
2430 r = m - 1;
2431 else if (needle > strawEnd)
2432 l = m + 1;
2433 else {
2434 stbtt_uint16 startCoverageIndex = ttUSHORT(rangeRecord + 4);
2435 return startCoverageIndex + glyph - strawStart;
2436 }
2437 }
2438 break;
2439 }
2440
2441 default: return -1; // unsupported
2442 }
2443
2444 return -1;
2445 }
2446
2447 static stbtt_int32 stbtt__GetGlyphClass(stbtt_uint8 *classDefTable, int glyph)
2448 {
2449 stbtt_uint16 classDefFormat = ttUSHORT(classDefTable);
2450 switch (classDefFormat)
2451 {
2452 case 1: {
2453 stbtt_uint16 startGlyphID = ttUSHORT(classDefTable + 2);
2454 stbtt_uint16 glyphCount = ttUSHORT(classDefTable + 4);
2455 stbtt_uint8 *classDef1ValueArray = classDefTable + 6;
2456
2457 if (glyph >= startGlyphID && glyph < startGlyphID + glyphCount)
2458 return (stbtt_int32)ttUSHORT(classDef1ValueArray + 2 * (glyph - startGlyphID));
2459 break;
2460 }
2461
2462 case 2: {
2463 stbtt_uint16 classRangeCount = ttUSHORT(classDefTable + 2);
2464 stbtt_uint8 *classRangeRecords = classDefTable + 4;
2465
2466 // Binary search.
2467 stbtt_int32 l=0, r=classRangeCount-1, m;
2468 int strawStart, strawEnd, needle=glyph;
2469 while (l <= r) {
2470 stbtt_uint8 *classRangeRecord;
2471 m = (l + r) >> 1;
2472 classRangeRecord = classRangeRecords + 6 * m;
2473 strawStart = ttUSHORT(classRangeRecord);
2474 strawEnd = ttUSHORT(classRangeRecord + 2);
2475 if (needle < strawStart)
2476 r = m - 1;
2477 else if (needle > strawEnd)
2478 l = m + 1;
2479 else
2480 return (stbtt_int32)ttUSHORT(classRangeRecord + 4);
2481 }
2482 break;
2483 }
2484
2485 default:
2486 return -1; // Unsupported definition type, return an error.
2487 }
2488
2489 // "All glyphs not assigned to a class fall into class 0". (OpenType spec)
2490 return 0;
2491 }
2492
2493 // Define to STBTT_assert(x) if you want to break on unimplemented formats.
2494 #define STBTT_GPOS_TODO_assert(x)
2495
2496 static stbtt_int32 stbtt__GetGlyphGPOSInfoAdvance(const stbtt_fontinfo *info, int glyph1, int glyph2)
2497 {
2498 stbtt_uint16 lookupListOffset;
2499 stbtt_uint8 *lookupList;
2500 stbtt_uint16 lookupCount;
2501 stbtt_uint8 *data;
2502 stbtt_int32 i, sti;
2503
2504 if (!info->gpos) return 0;
2505
2506 data = info->data + info->gpos;
2507
2508 if (ttUSHORT(data+0) != 1) return 0; // Major version 1
2509 if (ttUSHORT(data+2) != 0) return 0; // Minor version 0
2510
2511 lookupListOffset = ttUSHORT(data+8);
2512 lookupList = data + lookupListOffset;
2513 lookupCount = ttUSHORT(lookupList);
2514
2515 for (i=0; i<lookupCount; ++i) {
2516 stbtt_uint16 lookupOffset = ttUSHORT(lookupList + 2 + 2 * i);
2517 stbtt_uint8 *lookupTable = lookupList + lookupOffset;
2518
2519 stbtt_uint16 lookupType = ttUSHORT(lookupTable);
2520 stbtt_uint16 subTableCount = ttUSHORT(lookupTable + 4);
2521 stbtt_uint8 *subTableOffsets = lookupTable + 6;
2522 if (lookupType != 2) // Pair Adjustment Positioning Subtable
2523 continue;
2524
2525 for (sti=0; sti<subTableCount; sti++) {
2526 stbtt_uint16 subtableOffset = ttUSHORT(subTableOffsets + 2 * sti);
2527 stbtt_uint8 *table = lookupTable + subtableOffset;
2528 stbtt_uint16 posFormat = ttUSHORT(table);
2529 stbtt_uint16 coverageOffset = ttUSHORT(table + 2);
2530 stbtt_int32 coverageIndex = stbtt__GetCoverageIndex(table + coverageOffset, glyph1);
2531 if (coverageIndex == -1) continue;
2532
2533 switch (posFormat) {
2534 case 1: {
2535 stbtt_int32 l, r, m;
2536 int straw, needle;
2537 stbtt_uint16 valueFormat1 = ttUSHORT(table + 4);
2538 stbtt_uint16 valueFormat2 = ttUSHORT(table + 6);
2539 if (valueFormat1 == 4 && valueFormat2 == 0) { // Support more formats?
2540 stbtt_int32 valueRecordPairSizeInBytes = 2;
2541 stbtt_uint16 pairSetCount = ttUSHORT(table + 8);
2542 stbtt_uint16 pairPosOffset = ttUSHORT(table + 10 + 2 * coverageIndex);
2543 stbtt_uint8 *pairValueTable = table + pairPosOffset;
2544 stbtt_uint16 pairValueCount = ttUSHORT(pairValueTable);
2545 stbtt_uint8 *pairValueArray = pairValueTable + 2;
2546
2547 if (coverageIndex >= pairSetCount) return 0;
2548
2549 needle=glyph2;
2550 r=pairValueCount-1;
2551 l=0;
2552
2553 // Binary search.
2554 while (l <= r) {
2555 stbtt_uint16 secondGlyph;
2556 stbtt_uint8 *pairValue;
2557 m = (l + r) >> 1;
2558 pairValue = pairValueArray + (2 + valueRecordPairSizeInBytes) * m;
2559 secondGlyph = ttUSHORT(pairValue);
2560 straw = secondGlyph;
2561 if (needle < straw)
2562 r = m - 1;
2563 else if (needle > straw)
2564 l = m + 1;
2565 else {
2566 stbtt_int16 xAdvance = ttSHORT(pairValue + 2);
2567 return xAdvance;
2568 }
2569 }
2570 } else
2571 return 0;
2572 break;
2573 }
2574
2575 case 2: {
2576 stbtt_uint16 valueFormat1 = ttUSHORT(table + 4);
2577 stbtt_uint16 valueFormat2 = ttUSHORT(table + 6);
2578 if (valueFormat1 == 4 && valueFormat2 == 0) { // Support more formats?
2579 stbtt_uint16 classDef1Offset = ttUSHORT(table + 8);
2580 stbtt_uint16 classDef2Offset = ttUSHORT(table + 10);
2581 int glyph1class = stbtt__GetGlyphClass(table + classDef1Offset, glyph1);
2582 int glyph2class = stbtt__GetGlyphClass(table + classDef2Offset, glyph2);
2583
2584 stbtt_uint16 class1Count = ttUSHORT(table + 12);
2585 stbtt_uint16 class2Count = ttUSHORT(table + 14);
2586 stbtt_uint8 *class1Records, *class2Records;
2587 stbtt_int16 xAdvance;
2588
2589 if (glyph1class < 0 || glyph1class >= class1Count) return 0; // malformed
2590 if (glyph2class < 0 || glyph2class >= class2Count) return 0; // malformed
2591
2592 class1Records = table + 16;
2593 class2Records = class1Records + 2 * (glyph1class * class2Count);
2594 xAdvance = ttSHORT(class2Records + 2 * glyph2class);
2595 return xAdvance;
2596 } else
2597 return 0;
2598 break;
2599 }
2600
2601 default:
2602 return 0; // Unsupported position format
2603 }
2604 }
2605 }
2606
2607 return 0;
2608 }
2609
2610 STBTT_DEF int stbtt_GetGlyphKernAdvance(const stbtt_fontinfo *info, int g1, int g2)
2611 {
2612 int xAdvance = 0;
2613
2614 if (info->gpos)
2615 xAdvance += stbtt__GetGlyphGPOSInfoAdvance(info, g1, g2);
2616 else if (info->kern)
2617 xAdvance += stbtt__GetGlyphKernInfoAdvance(info, g1, g2);
2618
2619 return xAdvance;
2620 }
2621
2622 STBTT_DEF int stbtt_GetCodepointKernAdvance(const stbtt_fontinfo *info, int ch1, int ch2)
2623 {
2624 if (!info->kern && !info->gpos) // if no kerning table, don't waste time looking up both codepoint->glyphs
2625 return 0;
2626 return stbtt_GetGlyphKernAdvance(info, stbtt_FindGlyphIndex(info,ch1), stbtt_FindGlyphIndex(info,ch2));
2627 }
2628
2629 STBTT_DEF void stbtt_GetCodepointHMetrics(const stbtt_fontinfo *info, int codepoint, int *advanceWidth, int *leftSideBearing)
2630 {
2631 stbtt_GetGlyphHMetrics(info, stbtt_FindGlyphIndex(info,codepoint), advanceWidth, leftSideBearing);
2632 }
2633
2634 STBTT_DEF void stbtt_GetFontVMetrics(const stbtt_fontinfo *info, int *ascent, int *descent, int *lineGap)
2635 {
2636 if (ascent ) *ascent = ttSHORT(info->data+info->hhea + 4);
2637 if (descent) *descent = ttSHORT(info->data+info->hhea + 6);
2638 if (lineGap) *lineGap = ttSHORT(info->data+info->hhea + 8);
2639 }
2640
2641 STBTT_DEF int stbtt_GetFontVMetricsOS2(const stbtt_fontinfo *info, int *typoAscent, int *typoDescent, int *typoLineGap)
2642 {
2643 int tab = stbtt__find_table(info->data, info->fontstart, "OS/2");
2644 if (!tab)
2645 return 0;
2646 if (typoAscent ) *typoAscent = ttSHORT(info->data+tab + 68);
2647 if (typoDescent) *typoDescent = ttSHORT(info->data+tab + 70);
2648 if (typoLineGap) *typoLineGap = ttSHORT(info->data+tab + 72);
2649 return 1;
2650 }
2651
2652 STBTT_DEF void stbtt_GetFontBoundingBox(const stbtt_fontinfo *info, int *x0, int *y0, int *x1, int *y1)
2653 {
2654 *x0 = ttSHORT(info->data + info->head + 36);
2655 *y0 = ttSHORT(info->data + info->head + 38);
2656 *x1 = ttSHORT(info->data + info->head + 40);
2657 *y1 = ttSHORT(info->data + info->head + 42);
2658 }
2659
2660 STBTT_DEF float stbtt_ScaleForPixelHeight(const stbtt_fontinfo *info, float height)
2661 {
2662 int fheight = ttSHORT(info->data + info->hhea + 4) - ttSHORT(info->data + info->hhea + 6);
2663 return (float) height / fheight;
2664 }
2665
2666 STBTT_DEF float stbtt_ScaleForMappingEmToPixels(const stbtt_fontinfo *info, float pixels)
2667 {
2668 int unitsPerEm = ttUSHORT(info->data + info->head + 18);
2669 return pixels / unitsPerEm;
2670 }
2671
2672 STBTT_DEF void stbtt_FreeShape(const stbtt_fontinfo *info, stbtt_vertex *v)
2673 {
2674 STBTT_free(v, info->userdata);
2675 }
2676
2677 STBTT_DEF stbtt_uint8 *stbtt_FindSVGDoc(const stbtt_fontinfo *info, int gl)
2678 {
2679 int i;
2680 stbtt_uint8 *data = info->data;
2681 stbtt_uint8 *svg_doc_list = data + stbtt__get_svg((stbtt_fontinfo *) info);
2682
2683 int numEntries = ttUSHORT(svg_doc_list);
2684 stbtt_uint8 *svg_docs = svg_doc_list + 2;
2685
2686 for(i=0; i<numEntries; i++) {
2687 stbtt_uint8 *svg_doc = svg_docs + (12 * i);
2688 if ((gl >= ttUSHORT(svg_doc)) && (gl <= ttUSHORT(svg_doc + 2)))
2689 return svg_doc;
2690 }
2691 return 0;
2692 }
2693
2694 STBTT_DEF int stbtt_GetGlyphSVG(const stbtt_fontinfo *info, int gl, const char **svg)
2695 {
2696 stbtt_uint8 *data = info->data;
2697 stbtt_uint8 *svg_doc;
2698
2699 if (info->svg == 0)
2700 return 0;
2701
2702 svg_doc = stbtt_FindSVGDoc(info, gl);
2703 if (svg_doc != NULL) {
2704 *svg = (char *) data + info->svg + ttULONG(svg_doc + 4);
2705 return ttULONG(svg_doc + 8);
2706 } else {
2707 return 0;
2708 }
2709 }
2710
2711 STBTT_DEF int stbtt_GetCodepointSVG(const stbtt_fontinfo *info, int unicode_codepoint, const char **svg)
2712 {
2713 return stbtt_GetGlyphSVG(info, stbtt_FindGlyphIndex(info, unicode_codepoint), svg);
2714 }
2715
2716 //////////////////////////////////////////////////////////////////////////////
2717 //
2718 // antialiasing software rasterizer
2719 //
2720
2721 STBTT_DEF void stbtt_GetGlyphBitmapBoxSubpixel(const stbtt_fontinfo *font, int glyph, float scale_x, float scale_y,float shift_x, float shift_y, int *ix0, int *iy0, int *ix1, int *iy1)
2722 {
2723 int x0=0,y0=0,x1,y1; // =0 suppresses compiler warning
2724 if (!stbtt_GetGlyphBox(font, glyph, &x0,&y0,&x1,&y1)) {
2725 // e.g. space character
2726 if (ix0) *ix0 = 0;
2727 if (iy0) *iy0 = 0;
2728 if (ix1) *ix1 = 0;
2729 if (iy1) *iy1 = 0;
2730 } else {
2731 // move to integral bboxes (treating pixels as little squares, what pixels get touched)?
2732 if (ix0) *ix0 = STBTT_ifloor( x0 * scale_x + shift_x);
2733 if (iy0) *iy0 = STBTT_ifloor(-y1 * scale_y + shift_y);
2734 if (ix1) *ix1 = STBTT_iceil ( x1 * scale_x + shift_x);
2735 if (iy1) *iy1 = STBTT_iceil (-y0 * scale_y + shift_y);
2736 }
2737 }
2738
2739 STBTT_DEF void stbtt_GetGlyphBitmapBox(const stbtt_fontinfo *font, int glyph, float scale_x, float scale_y, int *ix0, int *iy0, int *ix1, int *iy1)
2740 {
2741 stbtt_GetGlyphBitmapBoxSubpixel(font, glyph, scale_x, scale_y,0.0f,0.0f, ix0, iy0, ix1, iy1);
2742 }
2743
2744 STBTT_DEF void stbtt_GetCodepointBitmapBoxSubpixel(const stbtt_fontinfo *font, int codepoint, float scale_x, float scale_y, float shift_x, float shift_y, int *ix0, int *iy0, int *ix1, int *iy1)
2745 {
2746 stbtt_GetGlyphBitmapBoxSubpixel(font, stbtt_FindGlyphIndex(font,codepoint), scale_x, scale_y,shift_x,shift_y, ix0,iy0,ix1,iy1);
2747 }
2748
2749 STBTT_DEF void stbtt_GetCodepointBitmapBox(const stbtt_fontinfo *font, int codepoint, float scale_x, float scale_y, int *ix0, int *iy0, int *ix1, int *iy1)
2750 {
2751 stbtt_GetCodepointBitmapBoxSubpixel(font, codepoint, scale_x, scale_y,0.0f,0.0f, ix0,iy0,ix1,iy1);
2752 }
2753
2754 //////////////////////////////////////////////////////////////////////////////
2755 //
2756 // Rasterizer
2757
2758 typedef struct stbtt__hheap_chunk
2759 {
2760 struct stbtt__hheap_chunk *next;
2761 } stbtt__hheap_chunk;
2762
2763 typedef struct stbtt__hheap
2764 {
2765 struct stbtt__hheap_chunk *head;
2766 void *first_free;
2767 int num_remaining_in_head_chunk;
2768 } stbtt__hheap;
2769
2770 static void *stbtt__hheap_alloc(stbtt__hheap *hh, size_t size, void *userdata)
2771 {
2772 if (hh->first_free) {
2773 void *p = hh->first_free;
2774 hh->first_free = * (void **) p;
2775 return p;
2776 } else {
2777 if (hh->num_remaining_in_head_chunk == 0) {
2778 int count = (size < 32 ? 2000 : size < 128 ? 800 : 100);
2779 stbtt__hheap_chunk *c = (stbtt__hheap_chunk *) STBTT_malloc(sizeof(stbtt__hheap_chunk) + size * count, userdata);
2780 if (c == NULL)
2781 return NULL;
2782 c->next = hh->head;
2783 hh->head = c;
2784 hh->num_remaining_in_head_chunk = count;
2785 }
2786 --hh->num_remaining_in_head_chunk;
2787 return (char *) (hh->head) + sizeof(stbtt__hheap_chunk) + size * hh->num_remaining_in_head_chunk;
2788 }
2789 }
2790
2791 static void stbtt__hheap_free(stbtt__hheap *hh, void *p)
2792 {
2793 *(void **) p = hh->first_free;
2794 hh->first_free = p;
2795 }
2796
2797 static void stbtt__hheap_cleanup(stbtt__hheap *hh, void *userdata)
2798 {
2799 stbtt__hheap_chunk *c = hh->head;
2800 while (c) {
2801 stbtt__hheap_chunk *n = c->next;
2802 STBTT_free(c, userdata);
2803 c = n;
2804 }
2805 }
2806
2807 typedef struct stbtt__edge {
2808 float x0,y0, x1,y1;
2809 int invert;
2810 } stbtt__edge;
2811
2812
2813 typedef struct stbtt__active_edge
2814 {
2815 struct stbtt__active_edge *next;
2816 #if STBTT_RASTERIZER_VERSION==1
2817 int x,dx;
2818 float ey;
2819 int direction;
2820 #elif STBTT_RASTERIZER_VERSION==2
2821 float fx,fdx,fdy;
2822 float direction;
2823 float sy;
2824 float ey;
2825 #else
2826 #error "Unrecognized value of STBTT_RASTERIZER_VERSION"
2827 #endif
2828 } stbtt__active_edge;
2829
2830 #if STBTT_RASTERIZER_VERSION == 1
2831 #define STBTT_FIXSHIFT 10
2832 #define STBTT_FIX (1 << STBTT_FIXSHIFT)
2833 #define STBTT_FIXMASK (STBTT_FIX-1)
2834
2835 static stbtt__active_edge *stbtt__new_active(stbtt__hheap *hh, stbtt__edge *e, int off_x, float start_point, void *userdata)
2836 {
2837 stbtt__active_edge *z = (stbtt__active_edge *) stbtt__hheap_alloc(hh, sizeof(*z), userdata);
2838 float dxdy = (e->x1 - e->x0) / (e->y1 - e->y0);
2839 STBTT_assert(z != NULL);
2840 if (!z) return z;
2841
2842 // round dx down to avoid overshooting
2843 if (dxdy < 0)
2844 z->dx = -STBTT_ifloor(STBTT_FIX * -dxdy);
2845 else
2846 z->dx = STBTT_ifloor(STBTT_FIX * dxdy);
2847
2848 z->x = STBTT_ifloor(STBTT_FIX * e->x0 + z->dx * (start_point - e->y0)); // use z->dx so when we offset later it's by the same amount
2849 z->x -= off_x * STBTT_FIX;
2850
2851 z->ey = e->y1;
2852 z->next = 0;
2853 z->direction = e->invert ? 1 : -1;
2854 return z;
2855 }
2856 #elif STBTT_RASTERIZER_VERSION == 2
2857 static stbtt__active_edge *stbtt__new_active(stbtt__hheap *hh, stbtt__edge *e, int off_x, float start_point, void *userdata)
2858 {
2859 stbtt__active_edge *z = (stbtt__active_edge *) stbtt__hheap_alloc(hh, sizeof(*z), userdata);
2860 float dxdy = (e->x1 - e->x0) / (e->y1 - e->y0);
2861 STBTT_assert(z != NULL);
2862 //STBTT_assert(e->y0 <= start_point);
2863 if (!z) return z;
2864 z->fdx = dxdy;
2865 z->fdy = dxdy != 0.0f ? (1.0f/dxdy) : 0.0f;
2866 z->fx = e->x0 + dxdy * (start_point - e->y0);
2867 z->fx -= off_x;
2868 z->direction = e->invert ? 1.0f : -1.0f;
2869 z->sy = e->y0;
2870 z->ey = e->y1;
2871 z->next = 0;
2872 return z;
2873 }
2874 #else
2875 #error "Unrecognized value of STBTT_RASTERIZER_VERSION"
2876 #endif
2877
2878 #if STBTT_RASTERIZER_VERSION == 1
2879 // note: this routine clips fills that extend off the edges... ideally this
2880 // wouldn't happen, but it could happen if the truetype glyph bounding boxes
2881 // are wrong, or if the user supplies a too-small bitmap
2882 static void stbtt__fill_active_edges(unsigned char *scanline, int len, stbtt__active_edge *e, int max_weight)
2883 {
2884 // non-zero winding fill
2885 int x0=0, w=0;
2886
2887 while (e) {
2888 if (w == 0) {
2889 // if we're currently at zero, we need to record the edge start point
2890 x0 = e->x; w += e->direction;
2891 } else {
2892 int x1 = e->x; w += e->direction;
2893 // if we went to zero, we need to draw
2894 if (w == 0) {
2895 int i = x0 >> STBTT_FIXSHIFT;
2896 int j = x1 >> STBTT_FIXSHIFT;
2897
2898 if (i < len && j >= 0) {
2899 if (i == j) {
2900 // x0,x1 are the same pixel, so compute combined coverage
2901 scanline[i] = scanline[i] + (stbtt_uint8) ((x1 - x0) * max_weight >> STBTT_FIXSHIFT);
2902 } else {
2903 if (i >= 0) // add antialiasing for x0
2904 scanline[i] = scanline[i] + (stbtt_uint8) (((STBTT_FIX - (x0 & STBTT_FIXMASK)) * max_weight) >> STBTT_FIXSHIFT);
2905 else
2906 i = -1; // clip
2907
2908 if (j < len) // add antialiasing for x1
2909 scanline[j] = scanline[j] + (stbtt_uint8) (((x1 & STBTT_FIXMASK) * max_weight) >> STBTT_FIXSHIFT);
2910 else
2911 j = len; // clip
2912
2913 for (++i; i < j; ++i) // fill pixels between x0 and x1
2914 scanline[i] = scanline[i] + (stbtt_uint8) max_weight;
2915 }
2916 }
2917 }
2918 }
2919
2920 e = e->next;
2921 }
2922 }
2923
2924 static void stbtt__rasterize_sorted_edges(stbtt__bitmap *result, stbtt__edge *e, int n, int vsubsample, int off_x, int off_y, void *userdata)
2925 {
2926 stbtt__hheap hh = { 0, 0, 0 };
2927 stbtt__active_edge *active = NULL;
2928 int y,j=0;
2929 int max_weight = (255 / vsubsample); // weight per vertical scanline
2930 int s; // vertical subsample index
2931 unsigned char scanline_data[512], *scanline;
2932
2933 if (result->w > 512)
2934 scanline = (unsigned char *) STBTT_malloc(result->w, userdata);
2935 else
2936 scanline = scanline_data;
2937
2938 y = off_y * vsubsample;
2939 e[n].y0 = (off_y + result->h) * (float) vsubsample + 1;
2940
2941 while (j < result->h) {
2942 STBTT_memset(scanline, 0, result->w);
2943 for (s=0; s < vsubsample; ++s) {
2944 // find center of pixel for this scanline
2945 float scan_y = y + 0.5f;
2946 stbtt__active_edge **step = &active;
2947
2948 // update all active edges;
2949 // remove all active edges that terminate before the center of this scanline
2950 while (*step) {
2951 stbtt__active_edge * z = *step;
2952 if (z->ey <= scan_y) {
2953 *step = z->next; // delete from list
2954 STBTT_assert(z->direction);
2955 z->direction = 0;
2956 stbtt__hheap_free(&hh, z);
2957 } else {
2958 z->x += z->dx; // advance to position for current scanline
2959 step = &((*step)->next); // advance through list
2960 }
2961 }
2962
2963 // resort the list if needed
2964 for(;;) {
2965 int changed=0;
2966 step = &active;
2967 while (*step && (*step)->next) {
2968 if ((*step)->x > (*step)->next->x) {
2969 stbtt__active_edge *t = *step;
2970 stbtt__active_edge *q = t->next;
2971
2972 t->next = q->next;
2973 q->next = t;
2974 *step = q;
2975 changed = 1;
2976 }
2977 step = &(*step)->next;
2978 }
2979 if (!changed) break;
2980 }
2981
2982 // insert all edges that start before the center of this scanline -- omit ones that also end on this scanline
2983 while (e->y0 <= scan_y) {
2984 if (e->y1 > scan_y) {
2985 stbtt__active_edge *z = stbtt__new_active(&hh, e, off_x, scan_y, userdata);
2986 if (z != NULL) {
2987 // find insertion point
2988 if (active == NULL)
2989 active = z;
2990 else if (z->x < active->x) {
2991 // insert at front
2992 z->next = active;
2993 active = z;
2994 } else {
2995 // find thing to insert AFTER
2996 stbtt__active_edge *p = active;
2997 while (p->next && p->next->x < z->x)
2998 p = p->next;
2999 // at this point, p->next->x is NOT < z->x
3000 z->next = p->next;
3001 p->next = z;
3002 }
3003 }
3004 }
3005 ++e;
3006 }
3007
3008 // now process all active edges in XOR fashion
3009 if (active)
3010 stbtt__fill_active_edges(scanline, result->w, active, max_weight);
3011
3012 ++y;
3013 }
3014 STBTT_memcpy(result->pixels + j * result->stride, scanline, result->w);
3015 ++j;
3016 }
3017
3018 stbtt__hheap_cleanup(&hh, userdata);
3019
3020 if (scanline != scanline_data)
3021 STBTT_free(scanline, userdata);
3022 }
3023
3024 #elif STBTT_RASTERIZER_VERSION == 2
3025
3026 // the edge passed in here does not cross the vertical line at x or the vertical line at x+1
3027 // (i.e. it has already been clipped to those)
3028 static void stbtt__handle_clipped_edge(float *scanline, int x, stbtt__active_edge *e, float x0, float y0, float x1, float y1)
3029 {
3030 if (y0 == y1) return;
3031 STBTT_assert(y0 < y1);
3032 STBTT_assert(e->sy <= e->ey);
3033 if (y0 > e->ey) return;
3034 if (y1 < e->sy) return;
3035 if (y0 < e->sy) {
3036 x0 += (x1-x0) * (e->sy - y0) / (y1-y0);
3037 y0 = e->sy;
3038 }
3039 if (y1 > e->ey) {
3040 x1 += (x1-x0) * (e->ey - y1) / (y1-y0);
3041 y1 = e->ey;
3042 }
3043
3044 if (x0 == x)
3045 STBTT_assert(x1 <= x+1);
3046 else if (x0 == x+1)
3047 STBTT_assert(x1 >= x);
3048 else if (x0 <= x)
3049 STBTT_assert(x1 <= x);
3050 else if (x0 >= x+1)
3051 STBTT_assert(x1 >= x+1);
3052 else
3053 STBTT_assert(x1 >= x && x1 <= x+1);
3054
3055 if (x0 <= x && x1 <= x)
3056 scanline[x] += e->direction * (y1-y0);
3057 else if (x0 >= x+1 && x1 >= x+1)
3058 ;
3059 else {
3060 STBTT_assert(x0 >= x && x0 <= x+1 && x1 >= x && x1 <= x+1);
3061 scanline[x] += e->direction * (y1-y0) * (1-((x0-x)+(x1-x))/2); // coverage = 1 - average x position
3062 }
3063 }
3064
3065 static float stbtt__sized_trapezoid_area(float height, float top_width, float bottom_width)
3066 {
3067 STBTT_assert(top_width >= 0);
3068 STBTT_assert(bottom_width >= 0);
3069 return (top_width + bottom_width) / 2.0f * height;
3070 }
3071
3072 static float stbtt__position_trapezoid_area(float height, float tx0, float tx1, float bx0, float bx1)
3073 {
3074 return stbtt__sized_trapezoid_area(height, tx1 - tx0, bx1 - bx0);
3075 }
3076
3077 static float stbtt__sized_triangle_area(float height, float width)
3078 {
3079 return height * width / 2;
3080 }
3081
3082 static void stbtt__fill_active_edges_new(float *scanline, float *scanline_fill, int len, stbtt__active_edge *e, float y_top)
3083 {
3084 float y_bottom = y_top+1;
3085
3086 while (e) {
3087 // brute force every pixel
3088
3089 // compute intersection points with top & bottom
3090 STBTT_assert(e->ey >= y_top);
3091
3092 if (e->fdx == 0) {
3093 float x0 = e->fx;
3094 if (x0 < len) {
3095 if (x0 >= 0) {
3096 stbtt__handle_clipped_edge(scanline,(int) x0,e, x0,y_top, x0,y_bottom);
3097 stbtt__handle_clipped_edge(scanline_fill-1,(int) x0+1,e, x0,y_top, x0,y_bottom);
3098 } else {
3099 stbtt__handle_clipped_edge(scanline_fill-1,0,e, x0,y_top, x0,y_bottom);
3100 }
3101 }
3102 } else {
3103 float x0 = e->fx;
3104 float dx = e->fdx;
3105 float xb = x0 + dx;
3106 float x_top, x_bottom;
3107 float sy0,sy1;
3108 float dy = e->fdy;
3109 STBTT_assert(e->sy <= y_bottom && e->ey >= y_top);
3110
3111 // compute endpoints of line segment clipped to this scanline (if the
3112 // line segment starts on this scanline. x0 is the intersection of the
3113 // line with y_top, but that may be off the line segment.
3114 if (e->sy > y_top) {
3115 x_top = x0 + dx * (e->sy - y_top);
3116 sy0 = e->sy;
3117 } else {
3118 x_top = x0;
3119 sy0 = y_top;
3120 }
3121 if (e->ey < y_bottom) {
3122 x_bottom = x0 + dx * (e->ey - y_top);
3123 sy1 = e->ey;
3124 } else {
3125 x_bottom = xb;
3126 sy1 = y_bottom;
3127 }
3128
3129 if (x_top >= 0 && x_bottom >= 0 && x_top < len && x_bottom < len) {
3130 // from here on, we don't have to range check x values
3131
3132 if ((int) x_top == (int) x_bottom) {
3133 float height;
3134 // simple case, only spans one pixel
3135 int x = (int) x_top;
3136 height = (sy1 - sy0) * e->direction;
3137 STBTT_assert(x >= 0 && x < len);
3138 scanline[x] += stbtt__position_trapezoid_area(height, x_top, x+1.0f, x_bottom, x+1.0f);
3139 scanline_fill[x] += height; // everything right of this pixel is filled
3140 } else {
3141 int x,x1,x2;
3142 float y_crossing, y_final, step, sign, area;
3143 // covers 2+ pixels
3144 if (x_top > x_bottom) {
3145 // flip scanline vertically; signed area is the same
3146 float t;
3147 sy0 = y_bottom - (sy0 - y_top);
3148 sy1 = y_bottom - (sy1 - y_top);
3149 t = sy0, sy0 = sy1, sy1 = t;
3150 t = x_bottom, x_bottom = x_top, x_top = t;
3151 dx = -dx;
3152 dy = -dy;
3153 t = x0, x0 = xb, xb = t;
3154 }
3155 STBTT_assert(dy >= 0);
3156 STBTT_assert(dx >= 0);
3157
3158 x1 = (int) x_top;
3159 x2 = (int) x_bottom;
3160 // compute intersection with y axis at x1+1
3161 y_crossing = y_top + dy * (x1+1 - x0);
3162
3163 // compute intersection with y axis at x2
3164 y_final = y_top + dy * (x2 - x0);
3165
3166 // x1 x_top x2 x_bottom
3167 // y_top +------|-----+------------+------------+--------|---+------------+
3168 // | | | | | |
3169 // | | | | | |
3170 // sy0 | Txxxxx|............|............|............|............|
3171 // y_crossing | *xxxxx.......|............|............|............|
3172 // | | xxxxx..|............|............|............|
3173 // | | /- xx*xxxx........|............|............|
3174 // | | dy < | xxxxxx..|............|............|
3175 // y_final | | \- | xx*xxx.........|............|
3176 // sy1 | | | | xxxxxB...|............|
3177 // | | | | | |
3178 // | | | | | |
3179 // y_bottom +------------+------------+------------+------------+------------+
3180 //
3181 // goal is to measure the area covered by '.' in each pixel
3182
3183 // if x2 is right at the right edge of x1, y_crossing can blow up, github #1057
3184 // @TODO: maybe test against sy1 rather than y_bottom?
3185 if (y_crossing > y_bottom)
3186 y_crossing = y_bottom;
3187
3188 sign = e->direction;
3189
3190 // area of the rectangle covered from sy0..y_crossing
3191 area = sign * (y_crossing-sy0);
3192
3193 // area of the triangle (x_top,sy0), (x1+1,sy0), (x1+1,y_crossing)
3194 scanline[x1] += stbtt__sized_triangle_area(area, x1+1 - x_top);
3195
3196 // check if final y_crossing is blown up; no test case for this
3197 if (y_final > y_bottom) {
3198 y_final = y_bottom;
3199 dy = (y_final - y_crossing ) / (x2 - (x1+1)); // if denom=0, y_final = y_crossing, so y_final <= y_bottom
3200 }
3201
3202 // in second pixel, area covered by line segment found in first pixel
3203 // is always a rectangle 1 wide * the height of that line segment; this
3204 // is exactly what the variable 'area' stores. it also gets a contribution
3205 // from the line segment within it. the THIRD pixel will get the first
3206 // pixel's rectangle contribution, the second pixel's rectangle contribution,
3207 // and its own contribution. the 'own contribution' is the same in every pixel except
3208 // the leftmost and rightmost, a trapezoid that slides down in each pixel.
3209 // the second pixel's contribution to the third pixel will be the
3210 // rectangle 1 wide times the height change in the second pixel, which is dy.
3211
3212 step = sign * dy * 1; // dy is dy/dx, change in y for every 1 change in x,
3213 // which multiplied by 1-pixel-width is how much pixel area changes for each step in x
3214 // so the area advances by 'step' every time
3215
3216 for (x = x1+1; x < x2; ++x) {
3217 scanline[x] += area + step/2; // area of trapezoid is 1*step/2
3218 area += step;
3219 }
3220 STBTT_assert(STBTT_fabs(area) <= 1.01f); // accumulated error from area += step unless we round step down
3221 STBTT_assert(sy1 > y_final-0.01f);
3222
3223 // area covered in the last pixel is the rectangle from all the pixels to the left,
3224 // plus the trapezoid filled by the line segment in this pixel all the way to the right edge
3225 scanline[x2] += area + sign * stbtt__position_trapezoid_area(sy1-y_final, (float) x2, x2+1.0f, x_bottom, x2+1.0f);
3226
3227 // the rest of the line is filled based on the total height of the line segment in this pixel
3228 scanline_fill[x2] += sign * (sy1-sy0);
3229 }
3230 } else {
3231 // if edge goes outside of box we're drawing, we require
3232 // clipping logic. since this does not match the intended use
3233 // of this library, we use a different, very slow brute
3234 // force implementation
3235 // note though that this does happen some of the time because
3236 // x_top and x_bottom can be extrapolated at the top & bottom of
3237 // the shape and actually lie outside the bounding box
3238 int x;
3239 for (x=0; x < len; ++x) {
3240 // cases:
3241 //
3242 // there can be up to two intersections with the pixel. any intersection
3243 // with left or right edges can be handled by splitting into two (or three)
3244 // regions. intersections with top & bottom do not necessitate case-wise logic.
3245 //
3246 // the old way of doing this found the intersections with the left & right edges,
3247 // then used some simple logic to produce up to three segments in sorted order
3248 // from top-to-bottom. however, this had a problem: if an x edge was epsilon
3249 // across the x border, then the corresponding y position might not be distinct
3250 // from the other y segment, and it might ignored as an empty segment. to avoid
3251 // that, we need to explicitly produce segments based on x positions.
3252
3253 // rename variables to clearly-defined pairs
3254 float y0 = y_top;
3255 float x1 = (float) (x);
3256 float x2 = (float) (x+1);
3257 float x3 = xb;
3258 float y3 = y_bottom;
3259
3260 // x = e->x + e->dx * (y-y_top)
3261 // (y-y_top) = (x - e->x) / e->dx
3262 // y = (x - e->x) / e->dx + y_top
3263 float y1 = (x - x0) / dx + y_top;
3264 float y2 = (x+1 - x0) / dx + y_top;
3265
3266 if (x0 < x1 && x3 > x2) { // three segments descending down-right
3267 stbtt__handle_clipped_edge(scanline,x,e, x0,y0, x1,y1);
3268 stbtt__handle_clipped_edge(scanline,x,e, x1,y1, x2,y2);
3269 stbtt__handle_clipped_edge(scanline,x,e, x2,y2, x3,y3);
3270 } else if (x3 < x1 && x0 > x2) { // three segments descending down-left
3271 stbtt__handle_clipped_edge(scanline,x,e, x0,y0, x2,y2);
3272 stbtt__handle_clipped_edge(scanline,x,e, x2,y2, x1,y1);
3273 stbtt__handle_clipped_edge(scanline,x,e, x1,y1, x3,y3);
3274 } else if (x0 < x1 && x3 > x1) { // two segments across x, down-right
3275 stbtt__handle_clipped_edge(scanline,x,e, x0,y0, x1,y1);
3276 stbtt__handle_clipped_edge(scanline,x,e, x1,y1, x3,y3);
3277 } else if (x3 < x1 && x0 > x1) { // two segments across x, down-left
3278 stbtt__handle_clipped_edge(scanline,x,e, x0,y0, x1,y1);
3279 stbtt__handle_clipped_edge(scanline,x,e, x1,y1, x3,y3);
3280 } else if (x0 < x2 && x3 > x2) { // two segments across x+1, down-right
3281 stbtt__handle_clipped_edge(scanline,x,e, x0,y0, x2,y2);
3282 stbtt__handle_clipped_edge(scanline,x,e, x2,y2, x3,y3);
3283 } else if (x3 < x2 && x0 > x2) { // two segments across x+1, down-left
3284 stbtt__handle_clipped_edge(scanline,x,e, x0,y0, x2,y2);
3285 stbtt__handle_clipped_edge(scanline,x,e, x2,y2, x3,y3);
3286 } else { // one segment
3287 stbtt__handle_clipped_edge(scanline,x,e, x0,y0, x3,y3);
3288 }
3289 }
3290 }
3291 }
3292 e = e->next;
3293 }
3294 }
3295
3296 // directly AA rasterize edges w/o supersampling
3297 static void stbtt__rasterize_sorted_edges(stbtt__bitmap *result, stbtt__edge *e, int n, int vsubsample, int off_x, int off_y, void *userdata)
3298 {
3299 stbtt__hheap hh = { 0, 0, 0 };
3300 stbtt__active_edge *active = NULL;
3301 int y,j=0, i;
3302 float scanline_data[129], *scanline, *scanline2;
3303
3304 STBTT__NOTUSED(vsubsample);
3305
3306 if (result->w > 64)
3307 scanline = (float *) STBTT_malloc((result->w*2+1) * sizeof(float), userdata);
3308 else
3309 scanline = scanline_data;
3310
3311 scanline2 = scanline + result->w;
3312
3313 y = off_y;
3314 e[n].y0 = (float) (off_y + result->h) + 1;
3315
3316 while (j < result->h) {
3317 // find center of pixel for this scanline
3318 float scan_y_top = y + 0.0f;
3319 float scan_y_bottom = y + 1.0f;
3320 stbtt__active_edge **step = &active;
3321
3322 STBTT_memset(scanline , 0, result->w*sizeof(scanline[0]));
3323 STBTT_memset(scanline2, 0, (result->w+1)*sizeof(scanline[0]));
3324
3325 // update all active edges;
3326 // remove all active edges that terminate before the top of this scanline
3327 while (*step) {
3328 stbtt__active_edge * z = *step;
3329 if (z->ey <= scan_y_top) {
3330 *step = z->next; // delete from list
3331 STBTT_assert(z->direction);
3332 z->direction = 0;
3333 stbtt__hheap_free(&hh, z);
3334 } else {
3335 step = &((*step)->next); // advance through list
3336 }
3337 }
3338
3339 // insert all edges that start before the bottom of this scanline
3340 while (e->y0 <= scan_y_bottom) {
3341 if (e->y0 != e->y1) {
3342 stbtt__active_edge *z = stbtt__new_active(&hh, e, off_x, scan_y_top, userdata);
3343 if (z != NULL) {
3344 if (j == 0 && off_y != 0) {
3345 if (z->ey < scan_y_top) {
3346 // this can happen due to subpixel positioning and some kind of fp rounding error i think
3347 z->ey = scan_y_top;
3348 }
3349 }
3350 STBTT_assert(z->ey >= scan_y_top); // if we get really unlucky a tiny bit of an edge can be out of bounds
3351 // insert at front
3352 z->next = active;
3353 active = z;
3354 }
3355 }
3356 ++e;
3357 }
3358
3359 // now process all active edges
3360 if (active)
3361 stbtt__fill_active_edges_new(scanline, scanline2+1, result->w, active, scan_y_top);
3362
3363 {
3364 float sum = 0;
3365 for (i=0; i < result->w; ++i) {
3366 float k;
3367 int m;
3368 sum += scanline2[i];
3369 k = scanline[i] + sum;
3370 k = (float) STBTT_fabs(k)*255 + 0.5f;
3371 m = (int) k;
3372 if (m > 255) m = 255;
3373 result->pixels[j*result->stride + i] = (unsigned char) m;
3374 }
3375 }
3376 // advance all the edges
3377 step = &active;
3378 while (*step) {
3379 stbtt__active_edge *z = *step;
3380 z->fx += z->fdx; // advance to position for current scanline
3381 step = &((*step)->next); // advance through list
3382 }
3383
3384 ++y;
3385 ++j;
3386 }
3387
3388 stbtt__hheap_cleanup(&hh, userdata);
3389
3390 if (scanline != scanline_data)
3391 STBTT_free(scanline, userdata);
3392 }
3393 #else
3394 #error "Unrecognized value of STBTT_RASTERIZER_VERSION"
3395 #endif
3396
3397 #define STBTT__COMPARE(a,b) ((a)->y0 < (b)->y0)
3398
3399 static void stbtt__sort_edges_ins_sort(stbtt__edge *p, int n)
3400 {
3401 int i,j;
3402 for (i=1; i < n; ++i) {
3403 stbtt__edge t = p[i], *a = &t;
3404 j = i;
3405 while (j > 0) {
3406 stbtt__edge *b = &p[j-1];
3407 int c = STBTT__COMPARE(a,b);
3408 if (!c) break;
3409 p[j] = p[j-1];
3410 --j;
3411 }
3412 if (i != j)
3413 p[j] = t;
3414 }
3415 }
3416
3417 static void stbtt__sort_edges_quicksort(stbtt__edge *p, int n)
3418 {
3419 /* threshold for transitioning to insertion sort */
3420 while (n > 12) {
3421 stbtt__edge t;
3422 int c01,c12,c,m,i,j;
3423
3424 /* compute median of three */
3425 m = n >> 1;
3426 c01 = STBTT__COMPARE(&p[0],&p[m]);
3427 c12 = STBTT__COMPARE(&p[m],&p[n-1]);
3428 /* if 0 >= mid >= end, or 0 < mid < end, then use mid */
3429 if (c01 != c12) {
3430 /* otherwise, we'll need to swap something else to middle */
3431 int z;
3432 c = STBTT__COMPARE(&p[0],&p[n-1]);
3433 /* 0>mid && mid<n: 0>n => n; 0<n => 0 */
3434 /* 0<mid && mid>n: 0>n => 0; 0<n => n */
3435 z = (c == c12) ? 0 : n-1;
3436 t = p[z];
3437 p[z] = p[m];
3438 p[m] = t;
3439 }
3440 /* now p[m] is the median-of-three */
3441 /* swap it to the beginning so it won't move around */
3442 t = p[0];
3443 p[0] = p[m];
3444 p[m] = t;
3445
3446 /* partition loop */
3447 i=1;
3448 j=n-1;
3449 for(;;) {
3450 /* handling of equality is crucial here */
3451 /* for sentinels & efficiency with duplicates */
3452 for (;;++i) {
3453 if (!STBTT__COMPARE(&p[i], &p[0])) break;
3454 }
3455 for (;;--j) {
3456 if (!STBTT__COMPARE(&p[0], &p[j])) break;
3457 }
3458 /* make sure we haven't crossed */
3459 if (i >= j) break;
3460 t = p[i];
3461 p[i] = p[j];
3462 p[j] = t;
3463
3464 ++i;
3465 --j;
3466 }
3467 /* recurse on smaller side, iterate on larger */
3468 if (j < (n-i)) {
3469 stbtt__sort_edges_quicksort(p,j);
3470 p = p+i;
3471 n = n-i;
3472 } else {
3473 stbtt__sort_edges_quicksort(p+i, n-i);
3474 n = j;
3475 }
3476 }
3477 }
3478
3479 static void stbtt__sort_edges(stbtt__edge *p, int n)
3480 {
3481 stbtt__sort_edges_quicksort(p, n);
3482 stbtt__sort_edges_ins_sort(p, n);
3483 }
3484
3485 typedef struct
3486 {
3487 float x,y;
3488 } stbtt__point;
3489
3490 static void stbtt__rasterize(stbtt__bitmap *result, stbtt__point *pts, int *wcount, int windings, float scale_x, float scale_y, float shift_x, float shift_y, int off_x, int off_y, int invert, void *userdata)
3491 {
3492 float y_scale_inv = invert ? -scale_y : scale_y;
3493 stbtt__edge *e;
3494 int n,i,j,k,m;
3495 #if STBTT_RASTERIZER_VERSION == 1
3496 int vsubsample = result->h < 8 ? 15 : 5;
3497 #elif STBTT_RASTERIZER_VERSION == 2
3498 int vsubsample = 1;
3499 #else
3500 #error "Unrecognized value of STBTT_RASTERIZER_VERSION"
3501 #endif
3502 // vsubsample should divide 255 evenly; otherwise we won't reach full opacity
3503
3504 // now we have to blow out the windings into explicit edge lists
3505 n = 0;
3506 for (i=0; i < windings; ++i)
3507 n += wcount[i];
3508
3509 e = (stbtt__edge *) STBTT_malloc(sizeof(*e) * (n+1), userdata); // add an extra one as a sentinel
3510 if (e == 0) return;
3511 n = 0;
3512
3513 m=0;
3514 for (i=0; i < windings; ++i) {
3515 stbtt__point *p = pts + m;
3516 m += wcount[i];
3517 j = wcount[i]-1;
3518 for (k=0; k < wcount[i]; j=k++) {
3519 int a=k,b=j;
3520 // skip the edge if horizontal
3521 if (p[j].y == p[k].y)
3522 continue;
3523 // add edge from j to k to the list
3524 e[n].invert = 0;
3525 if (invert ? p[j].y > p[k].y : p[j].y < p[k].y) {
3526 e[n].invert = 1;
3527 a=j,b=k;
3528 }
3529 e[n].x0 = p[a].x * scale_x + shift_x;
3530 e[n].y0 = (p[a].y * y_scale_inv + shift_y) * vsubsample;
3531 e[n].x1 = p[b].x * scale_x + shift_x;
3532 e[n].y1 = (p[b].y * y_scale_inv + shift_y) * vsubsample;
3533 ++n;
3534 }
3535 }
3536
3537 // now sort the edges by their highest point (should snap to integer, and then by x)
3538 //STBTT_sort(e, n, sizeof(e[0]), stbtt__edge_compare);
3539 stbtt__sort_edges(e, n);
3540
3541 // now, traverse the scanlines and find the intersections on each scanline, use xor winding rule
3542 stbtt__rasterize_sorted_edges(result, e, n, vsubsample, off_x, off_y, userdata);
3543
3544 STBTT_free(e, userdata);
3545 }
3546
3547 static void stbtt__add_point(stbtt__point *points, int n, float x, float y)
3548 {
3549 if (!points) return; // during first pass, it's unallocated
3550 points[n].x = x;
3551 points[n].y = y;
3552 }
3553
3554 // tessellate until threshold p is happy... @TODO warped to compensate for non-linear stretching
3555 static int stbtt__tesselate_curve(stbtt__point *points, int *num_points, float x0, float y0, float x1, float y1, float x2, float y2, float objspace_flatness_squared, int n)
3556 {
3557 // midpoint
3558 float mx = (x0 + 2*x1 + x2)/4;
3559 float my = (y0 + 2*y1 + y2)/4;
3560 // versus directly drawn line
3561 float dx = (x0+x2)/2 - mx;
3562 float dy = (y0+y2)/2 - my;
3563 if (n > 16) // 65536 segments on one curve better be enough!
3564 return 1;
3565 if (dx*dx+dy*dy > objspace_flatness_squared) { // half-pixel error allowed... need to be smaller if AA
3566 stbtt__tesselate_curve(points, num_points, x0,y0, (x0+x1)/2.0f,(y0+y1)/2.0f, mx,my, objspace_flatness_squared,n+1);
3567 stbtt__tesselate_curve(points, num_points, mx,my, (x1+x2)/2.0f,(y1+y2)/2.0f, x2,y2, objspace_flatness_squared,n+1);
3568 } else {
3569 stbtt__add_point(points, *num_points,x2,y2);
3570 *num_points = *num_points+1;
3571 }
3572 return 1;
3573 }
3574
3575 static void stbtt__tesselate_cubic(stbtt__point *points, int *num_points, float x0, float y0, float x1, float y1, float x2, float y2, float x3, float y3, float objspace_flatness_squared, int n)
3576 {
3577 // @TODO this "flatness" calculation is just made-up nonsense that seems to work well enough
3578 float dx0 = x1-x0;
3579 float dy0 = y1-y0;
3580 float dx1 = x2-x1;
3581 float dy1 = y2-y1;
3582 float dx2 = x3-x2;
3583 float dy2 = y3-y2;
3584 float dx = x3-x0;
3585 float dy = y3-y0;
3586 float longlen = (float) (STBTT_sqrt(dx0*dx0+dy0*dy0)+STBTT_sqrt(dx1*dx1+dy1*dy1)+STBTT_sqrt(dx2*dx2+dy2*dy2));
3587 float shortlen = (float) STBTT_sqrt(dx*dx+dy*dy);
3588 float flatness_squared = longlen*longlen-shortlen*shortlen;
3589
3590 if (n > 16) // 65536 segments on one curve better be enough!
3591 return;
3592
3593 if (flatness_squared > objspace_flatness_squared) {
3594 float x01 = (x0+x1)/2;
3595 float y01 = (y0+y1)/2;
3596 float x12 = (x1+x2)/2;
3597 float y12 = (y1+y2)/2;
3598 float x23 = (x2+x3)/2;
3599 float y23 = (y2+y3)/2;
3600
3601 float xa = (x01+x12)/2;
3602 float ya = (y01+y12)/2;
3603 float xb = (x12+x23)/2;
3604 float yb = (y12+y23)/2;
3605
3606 float mx = (xa+xb)/2;
3607 float my = (ya+yb)/2;
3608
3609 stbtt__tesselate_cubic(points, num_points, x0,y0, x01,y01, xa,ya, mx,my, objspace_flatness_squared,n+1);
3610 stbtt__tesselate_cubic(points, num_points, mx,my, xb,yb, x23,y23, x3,y3, objspace_flatness_squared,n+1);
3611 } else {
3612 stbtt__add_point(points, *num_points,x3,y3);
3613 *num_points = *num_points+1;
3614 }
3615 }
3616
3617 // returns number of contours
3618 static stbtt__point *stbtt_FlattenCurves(stbtt_vertex *vertices, int num_verts, float objspace_flatness, int **contour_lengths, int *num_contours, void *userdata)
3619 {
3620 stbtt__point *points=0;
3621 int num_points=0;
3622
3623 float objspace_flatness_squared = objspace_flatness * objspace_flatness;
3624 int i,n=0,start=0, pass;
3625
3626 // count how many "moves" there are to get the contour count
3627 for (i=0; i < num_verts; ++i)
3628 if (vertices[i].type == STBTT_vmove)
3629 ++n;
3630
3631 *num_contours = n;
3632 if (n == 0) return 0;
3633
3634 *contour_lengths = (int *) STBTT_malloc(sizeof(**contour_lengths) * n, userdata);
3635
3636 if (*contour_lengths == 0) {
3637 *num_contours = 0;
3638 return 0;
3639 }
3640
3641 // make two passes through the points so we don't need to realloc
3642 for (pass=0; pass < 2; ++pass) {
3643 float x=0,y=0;
3644 if (pass == 1) {
3645 points = (stbtt__point *) STBTT_malloc(num_points * sizeof(points[0]), userdata);
3646 if (points == NULL) goto error;
3647 }
3648 num_points = 0;
3649 n= -1;
3650 for (i=0; i < num_verts; ++i) {
3651 switch (vertices[i].type) {
3652 case STBTT_vmove:
3653 // start the next contour
3654 if (n >= 0)
3655 (*contour_lengths)[n] = num_points - start;
3656 ++n;
3657 start = num_points;
3658
3659 x = vertices[i].x, y = vertices[i].y;
3660 stbtt__add_point(points, num_points++, x,y);
3661 break;
3662 case STBTT_vline:
3663 x = vertices[i].x, y = vertices[i].y;
3664 stbtt__add_point(points, num_points++, x, y);
3665 break;
3666 case STBTT_vcurve:
3667 stbtt__tesselate_curve(points, &num_points, x,y,
3668 vertices[i].cx, vertices[i].cy,
3669 vertices[i].x, vertices[i].y,
3670 objspace_flatness_squared, 0);
3671 x = vertices[i].x, y = vertices[i].y;
3672 break;
3673 case STBTT_vcubic:
3674 stbtt__tesselate_cubic(points, &num_points, x,y,
3675 vertices[i].cx, vertices[i].cy,
3676 vertices[i].cx1, vertices[i].cy1,
3677 vertices[i].x, vertices[i].y,
3678 objspace_flatness_squared, 0);
3679 x = vertices[i].x, y = vertices[i].y;
3680 break;
3681 }
3682 }
3683 (*contour_lengths)[n] = num_points - start;
3684 }
3685
3686 return points;
3687 error:
3688 STBTT_free(points, userdata);
3689 STBTT_free(*contour_lengths, userdata);
3690 *contour_lengths = 0;
3691 *num_contours = 0;
3692 return NULL;
3693 }
3694
3695 STBTT_DEF void stbtt_Rasterize(stbtt__bitmap *result, float flatness_in_pixels, stbtt_vertex *vertices, int num_verts, float scale_x, float scale_y, float shift_x, float shift_y, int x_off, int y_off, int invert, void *userdata)
3696 {
3697 float scale = scale_x > scale_y ? scale_y : scale_x;
3698 int winding_count = 0;
3699 int *winding_lengths = NULL;
3700 stbtt__point *windings = stbtt_FlattenCurves(vertices, num_verts, flatness_in_pixels / scale, &winding_lengths, &winding_count, userdata);
3701 if (windings) {
3702 stbtt__rasterize(result, windings, winding_lengths, winding_count, scale_x, scale_y, shift_x, shift_y, x_off, y_off, invert, userdata);
3703 STBTT_free(winding_lengths, userdata);
3704 STBTT_free(windings, userdata);
3705 }
3706 }
3707
3708 STBTT_DEF void stbtt_FreeBitmap(unsigned char *bitmap, void *userdata)
3709 {
3710 STBTT_free(bitmap, userdata);
3711 }
3712
3713 STBTT_DEF unsigned char *stbtt_GetGlyphBitmapSubpixel(const stbtt_fontinfo *info, float scale_x, float scale_y, float shift_x, float shift_y, int glyph, int *width, int *height, int *xoff, int *yoff)
3714 {
3715 int ix0,iy0,ix1,iy1;
3716 stbtt__bitmap gbm;
3717 stbtt_vertex *vertices;
3718 int num_verts = stbtt_GetGlyphShape(info, glyph, &vertices);
3719
3720 if (scale_x == 0) scale_x = scale_y;
3721 if (scale_y == 0) {
3722 if (scale_x == 0) {
3723 STBTT_free(vertices, info->userdata);
3724 return NULL;
3725 }
3726 scale_y = scale_x;
3727 }
3728
3729 stbtt_GetGlyphBitmapBoxSubpixel(info, glyph, scale_x, scale_y, shift_x, shift_y, &ix0,&iy0,&ix1,&iy1);
3730
3731 // now we get the size
3732 gbm.w = (ix1 - ix0);
3733 gbm.h = (iy1 - iy0);
3734 gbm.pixels = NULL; // in case we error
3735
3736 if (width ) *width = gbm.w;
3737 if (height) *height = gbm.h;
3738 if (xoff ) *xoff = ix0;
3739 if (yoff ) *yoff = iy0;
3740
3741 if (gbm.w && gbm.h) {
3742 gbm.pixels = (unsigned char *) STBTT_malloc(gbm.w * gbm.h, info->userdata);
3743 if (gbm.pixels) {
3744 gbm.stride = gbm.w;
3745
3746 stbtt_Rasterize(&gbm, 0.35f, vertices, num_verts, scale_x, scale_y, shift_x, shift_y, ix0, iy0, 1, info->userdata);
3747 }
3748 }
3749 STBTT_free(vertices, info->userdata);
3750 return gbm.pixels;
3751 }
3752
3753 STBTT_DEF unsigned char *stbtt_GetGlyphBitmap(const stbtt_fontinfo *info, float scale_x, float scale_y, int glyph, int *width, int *height, int *xoff, int *yoff)
3754 {
3755 return stbtt_GetGlyphBitmapSubpixel(info, scale_x, scale_y, 0.0f, 0.0f, glyph, width, height, xoff, yoff);
3756 }
3757
3758 STBTT_DEF void stbtt_MakeGlyphBitmapSubpixel(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, float shift_x, float shift_y, int glyph)
3759 {
3760 int ix0,iy0;
3761 stbtt_vertex *vertices;
3762 int num_verts = stbtt_GetGlyphShape(info, glyph, &vertices);
3763 stbtt__bitmap gbm;
3764
3765 stbtt_GetGlyphBitmapBoxSubpixel(info, glyph, scale_x, scale_y, shift_x, shift_y, &ix0,&iy0,0,0);
3766 gbm.pixels = output;
3767 gbm.w = out_w;
3768 gbm.h = out_h;
3769 gbm.stride = out_stride;
3770
3771 if (gbm.w && gbm.h)
3772 stbtt_Rasterize(&gbm, 0.35f, vertices, num_verts, scale_x, scale_y, shift_x, shift_y, ix0,iy0, 1, info->userdata);
3773
3774 STBTT_free(vertices, info->userdata);
3775 }
3776
3777 STBTT_DEF void stbtt_MakeGlyphBitmap(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, int glyph)
3778 {
3779 stbtt_MakeGlyphBitmapSubpixel(info, output, out_w, out_h, out_stride, scale_x, scale_y, 0.0f,0.0f, glyph);
3780 }
3781
3782 STBTT_DEF unsigned char *stbtt_GetCodepointBitmapSubpixel(const stbtt_fontinfo *info, float scale_x, float scale_y, float shift_x, float shift_y, int codepoint, int *width, int *height, int *xoff, int *yoff)
3783 {
3784 return stbtt_GetGlyphBitmapSubpixel(info, scale_x, scale_y,shift_x,shift_y, stbtt_FindGlyphIndex(info,codepoint), width,height,xoff,yoff);
3785 }
3786
3787 STBTT_DEF void stbtt_MakeCodepointBitmapSubpixelPrefilter(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, float shift_x, float shift_y, int oversample_x, int oversample_y, float *sub_x, float *sub_y, int codepoint)
3788 {
3789 stbtt_MakeGlyphBitmapSubpixelPrefilter(info, output, out_w, out_h, out_stride, scale_x, scale_y, shift_x, shift_y, oversample_x, oversample_y, sub_x, sub_y, stbtt_FindGlyphIndex(info,codepoint));
3790 }
3791
3792 STBTT_DEF void stbtt_MakeCodepointBitmapSubpixel(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, float shift_x, float shift_y, int codepoint)
3793 {
3794 stbtt_MakeGlyphBitmapSubpixel(info, output, out_w, out_h, out_stride, scale_x, scale_y, shift_x, shift_y, stbtt_FindGlyphIndex(info,codepoint));
3795 }
3796
3797 STBTT_DEF unsigned char *stbtt_GetCodepointBitmap(const stbtt_fontinfo *info, float scale_x, float scale_y, int codepoint, int *width, int *height, int *xoff, int *yoff)
3798 {
3799 return stbtt_GetCodepointBitmapSubpixel(info, scale_x, scale_y, 0.0f,0.0f, codepoint, width,height,xoff,yoff);
3800 }
3801
3802 STBTT_DEF void stbtt_MakeCodepointBitmap(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, int codepoint)
3803 {
3804 stbtt_MakeCodepointBitmapSubpixel(info, output, out_w, out_h, out_stride, scale_x, scale_y, 0.0f,0.0f, codepoint);
3805 }
3806
3807 //////////////////////////////////////////////////////////////////////////////
3808 //
3809 // bitmap baking
3810 //
3811 // This is SUPER-CRAPPY packing to keep source code small
3812
3813 static int stbtt_BakeFontBitmap_internal(unsigned char *data, int offset, // font location (use offset=0 for plain .ttf)
3814 float pixel_height, // height of font in pixels
3815 unsigned char *pixels, int pw, int ph, // bitmap to be filled in
3816 int first_char, int num_chars, // characters to bake
3817 stbtt_bakedchar *chardata)
3818 {
3819 float scale;
3820 int x,y,bottom_y, i;
3821 stbtt_fontinfo f;
3822 f.userdata = NULL;
3823 if (!stbtt_InitFont(&f, data, offset))
3824 return -1;
3825 STBTT_memset(pixels, 0, pw*ph); // background of 0 around pixels
3826 x=y=1;
3827 bottom_y = 1;
3828
3829 scale = stbtt_ScaleForPixelHeight(&f, pixel_height);
3830
3831 for (i=0; i < num_chars; ++i) {
3832 int advance, lsb, x0,y0,x1,y1,gw,gh;
3833 int g = stbtt_FindGlyphIndex(&f, first_char + i);
3834 stbtt_GetGlyphHMetrics(&f, g, &advance, &lsb);
3835 stbtt_GetGlyphBitmapBox(&f, g, scale,scale, &x0,&y0,&x1,&y1);
3836 gw = x1-x0;
3837 gh = y1-y0;
3838 if (x + gw + 1 >= pw)
3839 y = bottom_y, x = 1; // advance to next row
3840 if (y + gh + 1 >= ph) // check if it fits vertically AFTER potentially moving to next row
3841 return -i;
3842 STBTT_assert(x+gw < pw);
3843 STBTT_assert(y+gh < ph);
3844 stbtt_MakeGlyphBitmap(&f, pixels+x+y*pw, gw,gh,pw, scale,scale, g);
3845 chardata[i].x0 = (stbtt_int16) x;
3846 chardata[i].y0 = (stbtt_int16) y;
3847 chardata[i].x1 = (stbtt_int16) (x + gw);
3848 chardata[i].y1 = (stbtt_int16) (y + gh);
3849 chardata[i].xadvance = scale * advance;
3850 chardata[i].xoff = (float) x0;
3851 chardata[i].yoff = (float) y0;
3852 x = x + gw + 1;
3853 if (y+gh+1 > bottom_y)
3854 bottom_y = y+gh+1;
3855 }
3856 return bottom_y;
3857 }
3858
3859 STBTT_DEF void stbtt_GetBakedQuad(const stbtt_bakedchar *chardata, int pw, int ph, int char_index, float *xpos, float *ypos, stbtt_aligned_quad *q, int opengl_fillrule)
3860 {
3861 float d3d_bias = opengl_fillrule ? 0 : -0.5f;
3862 float ipw = 1.0f / pw, iph = 1.0f / ph;
3863 const stbtt_bakedchar *b = chardata + char_index;
3864 int round_x = STBTT_ifloor((*xpos + b->xoff) + 0.5f);
3865 int round_y = STBTT_ifloor((*ypos + b->yoff) + 0.5f);
3866
3867 q->x0 = round_x + d3d_bias;
3868 q->y0 = round_y + d3d_bias;
3869 q->x1 = round_x + b->x1 - b->x0 + d3d_bias;
3870 q->y1 = round_y + b->y1 - b->y0 + d3d_bias;
3871
3872 q->s0 = b->x0 * ipw;
3873 q->t0 = b->y0 * iph;
3874 q->s1 = b->x1 * ipw;
3875 q->t1 = b->y1 * iph;
3876
3877 *xpos += b->xadvance;
3878 }
3879
3880 //////////////////////////////////////////////////////////////////////////////
3881 //
3882 // rectangle packing replacement routines if you don't have stb_rect_pack.h
3883 //
3884
3885 #ifndef STB_RECT_PACK_VERSION
3886
3887 typedef int stbrp_coord;
3888
3889 ////////////////////////////////////////////////////////////////////////////////////
3890 // //
3891 // //
3892 // COMPILER WARNING ?!?!? //
3893 // //
3894 // //
3895 // if you get a compile warning due to these symbols being defined more than //
3896 // once, move #include "stb_rect_pack.h" before #include "stb_truetype.h" //
3897 // //
3898 ////////////////////////////////////////////////////////////////////////////////////
3899
3900 typedef struct
3901 {
3902 int width,height;
3903 int x,y,bottom_y;
3904 } stbrp_context;
3905
3906 typedef struct
3907 {
3908 unsigned char x;
3909 } stbrp_node;
3910
3911 struct stbrp_rect
3912 {
3913 stbrp_coord x,y;
3914 int id,w,h,was_packed;
3915 };
3916
3917 static void stbrp_init_target(stbrp_context *con, int pw, int ph, stbrp_node *nodes, int num_nodes)
3918 {
3919 con->width = pw;
3920 con->height = ph;
3921 con->x = 0;
3922 con->y = 0;
3923 con->bottom_y = 0;
3924 STBTT__NOTUSED(nodes);
3925 STBTT__NOTUSED(num_nodes);
3926 }
3927
3928 static void stbrp_pack_rects(stbrp_context *con, stbrp_rect *rects, int num_rects)
3929 {
3930 int i;
3931 for (i=0; i < num_rects; ++i) {
3932 if (con->x + rects[i].w > con->width) {
3933 con->x = 0;
3934 con->y = con->bottom_y;
3935 }
3936 if (con->y + rects[i].h > con->height)
3937 break;
3938 rects[i].x = con->x;
3939 rects[i].y = con->y;
3940 rects[i].was_packed = 1;
3941 con->x += rects[i].w;
3942 if (con->y + rects[i].h > con->bottom_y)
3943 con->bottom_y = con->y + rects[i].h;
3944 }
3945 for ( ; i < num_rects; ++i)
3946 rects[i].was_packed = 0;
3947 }
3948 #endif
3949
3950 //////////////////////////////////////////////////////////////////////////////
3951 //
3952 // bitmap baking
3953 //
3954 // This is SUPER-AWESOME (tm Ryan Gordon) packing using stb_rect_pack.h. If
3955 // stb_rect_pack.h isn't available, it uses the BakeFontBitmap strategy.
3956
3957 STBTT_DEF int stbtt_PackBegin(stbtt_pack_context *spc, unsigned char *pixels, int pw, int ph, int stride_in_bytes, int padding, void *alloc_context)
3958 {
3959 stbrp_context *context = (stbrp_context *) STBTT_malloc(sizeof(*context) ,alloc_context);
3960 int num_nodes = pw - padding;
3961 stbrp_node *nodes = (stbrp_node *) STBTT_malloc(sizeof(*nodes ) * num_nodes,alloc_context);
3962
3963 if (context == NULL || nodes == NULL) {
3964 if (context != NULL) STBTT_free(context, alloc_context);
3965 if (nodes != NULL) STBTT_free(nodes , alloc_context);
3966 return 0;
3967 }
3968
3969 spc->user_allocator_context = alloc_context;
3970 spc->width = pw;
3971 spc->height = ph;
3972 spc->pixels = pixels;
3973 spc->pack_info = context;
3974 spc->nodes = nodes;
3975 spc->padding = padding;
3976 spc->stride_in_bytes = stride_in_bytes != 0 ? stride_in_bytes : pw;
3977 spc->h_oversample = 1;
3978 spc->v_oversample = 1;
3979 spc->skip_missing = 0;
3980
3981 stbrp_init_target(context, pw-padding, ph-padding, nodes, num_nodes);
3982
3983 if (pixels)
3984 STBTT_memset(pixels, 0, pw*ph); // background of 0 around pixels
3985
3986 return 1;
3987 }
3988
3989 STBTT_DEF void stbtt_PackEnd (stbtt_pack_context *spc)
3990 {
3991 STBTT_free(spc->nodes , spc->user_allocator_context);
3992 STBTT_free(spc->pack_info, spc->user_allocator_context);
3993 }
3994
3995 STBTT_DEF void stbtt_PackSetOversampling(stbtt_pack_context *spc, unsigned int h_oversample, unsigned int v_oversample)
3996 {
3997 STBTT_assert(h_oversample <= STBTT_MAX_OVERSAMPLE);
3998 STBTT_assert(v_oversample <= STBTT_MAX_OVERSAMPLE);
3999 if (h_oversample <= STBTT_MAX_OVERSAMPLE)
4000 spc->h_oversample = h_oversample;
4001 if (v_oversample <= STBTT_MAX_OVERSAMPLE)
4002 spc->v_oversample = v_oversample;
4003 }
4004
4005 STBTT_DEF void stbtt_PackSetSkipMissingCodepoints(stbtt_pack_context *spc, int skip)
4006 {
4007 spc->skip_missing = skip;
4008 }
4009
4010 #define STBTT__OVER_MASK (STBTT_MAX_OVERSAMPLE-1)
4011
4012 static void stbtt__h_prefilter(unsigned char *pixels, int w, int h, int stride_in_bytes, unsigned int kernel_width)
4013 {
4014 unsigned char buffer[STBTT_MAX_OVERSAMPLE];
4015 int safe_w = w - kernel_width;
4016 int j;
4017 STBTT_memset(buffer, 0, STBTT_MAX_OVERSAMPLE); // suppress bogus warning from VS2013 -analyze
4018 for (j=0; j < h; ++j) {
4019 int i;
4020 unsigned int total;
4021 STBTT_memset(buffer, 0, kernel_width);
4022
4023 total = 0;
4024
4025 // make kernel_width a constant in common cases so compiler can optimize out the divide
4026 switch (kernel_width) {
4027 case 2:
4028 for (i=0; i <= safe_w; ++i) {
4029 total += pixels[i] - buffer[i & STBTT__OVER_MASK];
4030 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i];
4031 pixels[i] = (unsigned char) (total / 2);
4032 }
4033 break;
4034 case 3:
4035 for (i=0; i <= safe_w; ++i) {
4036 total += pixels[i] - buffer[i & STBTT__OVER_MASK];
4037 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i];
4038 pixels[i] = (unsigned char) (total / 3);
4039 }
4040 break;
4041 case 4:
4042 for (i=0; i <= safe_w; ++i) {
4043 total += pixels[i] - buffer[i & STBTT__OVER_MASK];
4044 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i];
4045 pixels[i] = (unsigned char) (total / 4);
4046 }
4047 break;
4048 case 5:
4049 for (i=0; i <= safe_w; ++i) {
4050 total += pixels[i] - buffer[i & STBTT__OVER_MASK];
4051 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i];
4052 pixels[i] = (unsigned char) (total / 5);
4053 }
4054 break;
4055 default:
4056 for (i=0; i <= safe_w; ++i) {
4057 total += pixels[i] - buffer[i & STBTT__OVER_MASK];
4058 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i];
4059 pixels[i] = (unsigned char) (total / kernel_width);
4060 }
4061 break;
4062 }
4063
4064 for (; i < w; ++i) {
4065 STBTT_assert(pixels[i] == 0);
4066 total -= buffer[i & STBTT__OVER_MASK];
4067 pixels[i] = (unsigned char) (total / kernel_width);
4068 }
4069
4070 pixels += stride_in_bytes;
4071 }
4072 }
4073
4074 static void stbtt__v_prefilter(unsigned char *pixels, int w, int h, int stride_in_bytes, unsigned int kernel_width)
4075 {
4076 unsigned char buffer[STBTT_MAX_OVERSAMPLE];
4077 int safe_h = h - kernel_width;
4078 int j;
4079 STBTT_memset(buffer, 0, STBTT_MAX_OVERSAMPLE); // suppress bogus warning from VS2013 -analyze
4080 for (j=0; j < w; ++j) {
4081 int i;
4082 unsigned int total;
4083 STBTT_memset(buffer, 0, kernel_width);
4084
4085 total = 0;
4086
4087 // make kernel_width a constant in common cases so compiler can optimize out the divide
4088 switch (kernel_width) {
4089 case 2:
4090 for (i=0; i <= safe_h; ++i) {
4091 total += pixels[i*stride_in_bytes] - buffer[i & STBTT__OVER_MASK];
4092 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i*stride_in_bytes];
4093 pixels[i*stride_in_bytes] = (unsigned char) (total / 2);
4094 }
4095 break;
4096 case 3:
4097 for (i=0; i <= safe_h; ++i) {
4098 total += pixels[i*stride_in_bytes] - buffer[i & STBTT__OVER_MASK];
4099 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i*stride_in_bytes];
4100 pixels[i*stride_in_bytes] = (unsigned char) (total / 3);
4101 }
4102 break;
4103 case 4:
4104 for (i=0; i <= safe_h; ++i) {
4105 total += pixels[i*stride_in_bytes] - buffer[i & STBTT__OVER_MASK];
4106 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i*stride_in_bytes];
4107 pixels[i*stride_in_bytes] = (unsigned char) (total / 4);
4108 }
4109 break;
4110 case 5:
4111 for (i=0; i <= safe_h; ++i) {
4112 total += pixels[i*stride_in_bytes] - buffer[i & STBTT__OVER_MASK];
4113 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i*stride_in_bytes];
4114 pixels[i*stride_in_bytes] = (unsigned char) (total / 5);
4115 }
4116 break;
4117 default:
4118 for (i=0; i <= safe_h; ++i) {
4119 total += pixels[i*stride_in_bytes] - buffer[i & STBTT__OVER_MASK];
4120 buffer[(i+kernel_width) & STBTT__OVER_MASK] = pixels[i*stride_in_bytes];
4121 pixels[i*stride_in_bytes] = (unsigned char) (total / kernel_width);
4122 }
4123 break;
4124 }
4125
4126 for (; i < h; ++i) {
4127 STBTT_assert(pixels[i*stride_in_bytes] == 0);
4128 total -= buffer[i & STBTT__OVER_MASK];
4129 pixels[i*stride_in_bytes] = (unsigned char) (total / kernel_width);
4130 }
4131
4132 pixels += 1;
4133 }
4134 }
4135
4136 static float stbtt__oversample_shift(int oversample)
4137 {
4138 if (!oversample)
4139 return 0.0f;
4140
4141 // The prefilter is a box filter of width "oversample",
4142 // which shifts phase by (oversample - 1)/2 pixels in
4143 // oversampled space. We want to shift in the opposite
4144 // direction to counter this.
4145 return (float)-(oversample - 1) / (2.0f * (float)oversample);
4146 }
4147
4148 // rects array must be big enough to accommodate all characters in the given ranges
4149 STBTT_DEF int stbtt_PackFontRangesGatherRects(stbtt_pack_context *spc, const stbtt_fontinfo *info, stbtt_pack_range *ranges, int num_ranges, stbrp_rect *rects)
4150 {
4151 int i,j,k;
4152 int missing_glyph_added = 0;
4153
4154 k=0;
4155 for (i=0; i < num_ranges; ++i) {
4156 float fh = ranges[i].font_size;
4157 float scale = fh > 0 ? stbtt_ScaleForPixelHeight(info, fh) : stbtt_ScaleForMappingEmToPixels(info, -fh);
4158 ranges[i].h_oversample = (unsigned char) spc->h_oversample;
4159 ranges[i].v_oversample = (unsigned char) spc->v_oversample;
4160 for (j=0; j < ranges[i].num_chars; ++j) {
4161 int x0,y0,x1,y1;
4162 int codepoint = ranges[i].array_of_unicode_codepoints == NULL ? ranges[i].first_unicode_codepoint_in_range + j : ranges[i].array_of_unicode_codepoints[j];
4163 int glyph = stbtt_FindGlyphIndex(info, codepoint);
4164 if (glyph == 0 && (spc->skip_missing || missing_glyph_added)) {
4165 rects[k].w = rects[k].h = 0;
4166 } else {
4167 stbtt_GetGlyphBitmapBoxSubpixel(info,glyph,
4168 scale * spc->h_oversample,
4169 scale * spc->v_oversample,
4170 0,0,
4171 &x0,&y0,&x1,&y1);
4172 rects[k].w = (stbrp_coord) (x1-x0 + spc->padding + spc->h_oversample-1);
4173 rects[k].h = (stbrp_coord) (y1-y0 + spc->padding + spc->v_oversample-1);
4174 if (glyph == 0)
4175 missing_glyph_added = 1;
4176 }
4177 ++k;
4178 }
4179 }
4180
4181 return k;
4182 }
4183
4184 STBTT_DEF void stbtt_MakeGlyphBitmapSubpixelPrefilter(const stbtt_fontinfo *info, unsigned char *output, int out_w, int out_h, int out_stride, float scale_x, float scale_y, float shift_x, float shift_y, int prefilter_x, int prefilter_y, float *sub_x, float *sub_y, int glyph)
4185 {
4186 stbtt_MakeGlyphBitmapSubpixel(info,
4187 output,
4188 out_w - (prefilter_x - 1),
4189 out_h - (prefilter_y - 1),
4190 out_stride,
4191 scale_x,
4192 scale_y,
4193 shift_x,
4194 shift_y,
4195 glyph);
4196
4197 if (prefilter_x > 1)
4198 stbtt__h_prefilter(output, out_w, out_h, out_stride, prefilter_x);
4199
4200 if (prefilter_y > 1)
4201 stbtt__v_prefilter(output, out_w, out_h, out_stride, prefilter_y);
4202
4203 *sub_x = stbtt__oversample_shift(prefilter_x);
4204 *sub_y = stbtt__oversample_shift(prefilter_y);
4205 }
4206
4207 // rects array must be big enough to accommodate all characters in the given ranges
4208 STBTT_DEF int stbtt_PackFontRangesRenderIntoRects(stbtt_pack_context *spc, const stbtt_fontinfo *info, stbtt_pack_range *ranges, int num_ranges, stbrp_rect *rects)
4209 {
4210 int i,j,k, missing_glyph = -1, return_value = 1;
4211
4212 // save current values
4213 int old_h_over = spc->h_oversample;
4214 int old_v_over = spc->v_oversample;
4215
4216 k = 0;
4217 for (i=0; i < num_ranges; ++i) {
4218 float fh = ranges[i].font_size;
4219 float scale = fh > 0 ? stbtt_ScaleForPixelHeight(info, fh) : stbtt_ScaleForMappingEmToPixels(info, -fh);
4220 float recip_h,recip_v,sub_x,sub_y;
4221 spc->h_oversample = ranges[i].h_oversample;
4222 spc->v_oversample = ranges[i].v_oversample;
4223 recip_h = 1.0f / spc->h_oversample;
4224 recip_v = 1.0f / spc->v_oversample;
4225 sub_x = stbtt__oversample_shift(spc->h_oversample);
4226 sub_y = stbtt__oversample_shift(spc->v_oversample);
4227 for (j=0; j < ranges[i].num_chars; ++j) {
4228 stbrp_rect *r = &rects[k];
4229 if (r->was_packed && r->w != 0 && r->h != 0) {
4230 stbtt_packedchar *bc = &ranges[i].chardata_for_range[j];
4231 int advance, lsb, x0,y0,x1,y1;
4232 int codepoint = ranges[i].array_of_unicode_codepoints == NULL ? ranges[i].first_unicode_codepoint_in_range + j : ranges[i].array_of_unicode_codepoints[j];
4233 int glyph = stbtt_FindGlyphIndex(info, codepoint);
4234 stbrp_coord pad = (stbrp_coord) spc->padding;
4235
4236 // pad on left and top
4237 r->x += pad;
4238 r->y += pad;
4239 r->w -= pad;
4240 r->h -= pad;
4241 stbtt_GetGlyphHMetrics(info, glyph, &advance, &lsb);
4242 stbtt_GetGlyphBitmapBox(info, glyph,
4243 scale * spc->h_oversample,
4244 scale * spc->v_oversample,
4245 &x0,&y0,&x1,&y1);
4246 stbtt_MakeGlyphBitmapSubpixel(info,
4247 spc->pixels + r->x + r->y*spc->stride_in_bytes,
4248 r->w - spc->h_oversample+1,
4249 r->h - spc->v_oversample+1,
4250 spc->stride_in_bytes,
4251 scale * spc->h_oversample,
4252 scale * spc->v_oversample,
4253 0,0,
4254 glyph);
4255
4256 if (spc->h_oversample > 1)
4257 stbtt__h_prefilter(spc->pixels + r->x + r->y*spc->stride_in_bytes,
4258 r->w, r->h, spc->stride_in_bytes,
4259 spc->h_oversample);
4260
4261 if (spc->v_oversample > 1)
4262 stbtt__v_prefilter(spc->pixels + r->x + r->y*spc->stride_in_bytes,
4263 r->w, r->h, spc->stride_in_bytes,
4264 spc->v_oversample);
4265
4266 bc->x0 = (stbtt_int16) r->x;
4267 bc->y0 = (stbtt_int16) r->y;
4268 bc->x1 = (stbtt_int16) (r->x + r->w);
4269 bc->y1 = (stbtt_int16) (r->y + r->h);
4270 bc->xadvance = scale * advance;
4271 bc->xoff = (float) x0 * recip_h + sub_x;
4272 bc->yoff = (float) y0 * recip_v + sub_y;
4273 bc->xoff2 = (x0 + r->w) * recip_h + sub_x;
4274 bc->yoff2 = (y0 + r->h) * recip_v + sub_y;
4275
4276 if (glyph == 0)
4277 missing_glyph = j;
4278 } else if (spc->skip_missing) {
4279 return_value = 0;
4280 } else if (r->was_packed && r->w == 0 && r->h == 0 && missing_glyph >= 0) {
4281 ranges[i].chardata_for_range[j] = ranges[i].chardata_for_range[missing_glyph];
4282 } else {
4283 return_value = 0; // if any fail, report failure
4284 }
4285
4286 ++k;
4287 }
4288 }
4289
4290 // restore original values
4291 spc->h_oversample = old_h_over;
4292 spc->v_oversample = old_v_over;
4293
4294 return return_value;
4295 }
4296
4297 STBTT_DEF void stbtt_PackFontRangesPackRects(stbtt_pack_context *spc, stbrp_rect *rects, int num_rects)
4298 {
4299 stbrp_pack_rects((stbrp_context *) spc->pack_info, rects, num_rects);
4300 }
4301
4302 STBTT_DEF int stbtt_PackFontRanges(stbtt_pack_context *spc, const unsigned char *fontdata, int font_index, stbtt_pack_range *ranges, int num_ranges)
4303 {
4304 stbtt_fontinfo info;
4305 int i,j,n, return_value = 1;
4306 //stbrp_context *context = (stbrp_context *) spc->pack_info;
4307 stbrp_rect *rects;
4308
4309 // flag all characters as NOT packed
4310 for (i=0; i < num_ranges; ++i)
4311 for (j=0; j < ranges[i].num_chars; ++j)
4312 ranges[i].chardata_for_range[j].x0 =
4313 ranges[i].chardata_for_range[j].y0 =
4314 ranges[i].chardata_for_range[j].x1 =
4315 ranges[i].chardata_for_range[j].y1 = 0;
4316
4317 n = 0;
4318 for (i=0; i < num_ranges; ++i)
4319 n += ranges[i].num_chars;
4320
4321 rects = (stbrp_rect *) STBTT_malloc(sizeof(*rects) * n, spc->user_allocator_context);
4322 if (rects == NULL)
4323 return 0;
4324
4325 info.userdata = spc->user_allocator_context;
4326 stbtt_InitFont(&info, fontdata, stbtt_GetFontOffsetForIndex(fontdata,font_index));
4327
4328 n = stbtt_PackFontRangesGatherRects(spc, &info, ranges, num_ranges, rects);
4329
4330 stbtt_PackFontRangesPackRects(spc, rects, n);
4331
4332 return_value = stbtt_PackFontRangesRenderIntoRects(spc, &info, ranges, num_ranges, rects);
4333
4334 STBTT_free(rects, spc->user_allocator_context);
4335 return return_value;
4336 }
4337
4338 STBTT_DEF int stbtt_PackFontRange(stbtt_pack_context *spc, const unsigned char *fontdata, int font_index, float font_size,
4339 int first_unicode_codepoint_in_range, int num_chars_in_range, stbtt_packedchar *chardata_for_range)
4340 {
4341 stbtt_pack_range range;
4342 range.first_unicode_codepoint_in_range = first_unicode_codepoint_in_range;
4343 range.array_of_unicode_codepoints = NULL;
4344 range.num_chars = num_chars_in_range;
4345 range.chardata_for_range = chardata_for_range;
4346 range.font_size = font_size;
4347 return stbtt_PackFontRanges(spc, fontdata, font_index, &range, 1);
4348 }
4349
4350 STBTT_DEF void stbtt_GetScaledFontVMetrics(const unsigned char *fontdata, int index, float size, float *ascent, float *descent, float *lineGap)
4351 {
4352 int i_ascent, i_descent, i_lineGap;
4353 float scale;
4354 stbtt_fontinfo info;
4355 stbtt_InitFont(&info, fontdata, stbtt_GetFontOffsetForIndex(fontdata, index));
4356 scale = size > 0 ? stbtt_ScaleForPixelHeight(&info, size) : stbtt_ScaleForMappingEmToPixels(&info, -size);
4357 stbtt_GetFontVMetrics(&info, &i_ascent, &i_descent, &i_lineGap);
4358 *ascent = (float) i_ascent * scale;
4359 *descent = (float) i_descent * scale;
4360 *lineGap = (float) i_lineGap * scale;
4361 }
4362
4363 STBTT_DEF void stbtt_GetPackedQuad(const stbtt_packedchar *chardata, int pw, int ph, int char_index, float *xpos, float *ypos, stbtt_aligned_quad *q, int align_to_integer)
4364 {
4365 float ipw = 1.0f / pw, iph = 1.0f / ph;
4366 const stbtt_packedchar *b = chardata + char_index;
4367
4368 if (align_to_integer) {
4369 float x = (float) STBTT_ifloor((*xpos + b->xoff) + 0.5f);
4370 float y = (float) STBTT_ifloor((*ypos + b->yoff) + 0.5f);
4371 q->x0 = x;
4372 q->y0 = y;
4373 q->x1 = x + b->xoff2 - b->xoff;
4374 q->y1 = y + b->yoff2 - b->yoff;
4375 } else {
4376 q->x0 = *xpos + b->xoff;
4377 q->y0 = *ypos + b->yoff;
4378 q->x1 = *xpos + b->xoff2;
4379 q->y1 = *ypos + b->yoff2;
4380 }
4381
4382 q->s0 = b->x0 * ipw;
4383 q->t0 = b->y0 * iph;
4384 q->s1 = b->x1 * ipw;
4385 q->t1 = b->y1 * iph;
4386
4387 *xpos += b->xadvance;
4388 }
4389
4390 //////////////////////////////////////////////////////////////////////////////
4391 //
4392 // sdf computation
4393 //
4394
4395 #define STBTT_min(a,b) ((a) < (b) ? (a) : (b))
4396 #define STBTT_max(a,b) ((a) < (b) ? (b) : (a))
4397
4398 static int stbtt__ray_intersect_bezier(float orig[2], float ray[2], float q0[2], float q1[2], float q2[2], float hits[2][2])
4399 {
4400 float q0perp = q0[1]*ray[0] - q0[0]*ray[1];
4401 float q1perp = q1[1]*ray[0] - q1[0]*ray[1];
4402 float q2perp = q2[1]*ray[0] - q2[0]*ray[1];
4403 float roperp = orig[1]*ray[0] - orig[0]*ray[1];
4404
4405 float a = q0perp - 2*q1perp + q2perp;
4406 float b = q1perp - q0perp;
4407 float c = q0perp - roperp;
4408
4409 float s0 = 0., s1 = 0.;
4410 int num_s = 0;
4411
4412 if (a != 0.0) {
4413 float discr = b*b - a*c;
4414 if (discr > 0.0) {
4415 float rcpna = -1 / a;
4416 float d = (float) STBTT_sqrt(discr);
4417 s0 = (b+d) * rcpna;
4418 s1 = (b-d) * rcpna;
4419 if (s0 >= 0.0 && s0 <= 1.0)
4420 num_s = 1;
4421 if (d > 0.0 && s1 >= 0.0 && s1 <= 1.0) {
4422 if (num_s == 0) s0 = s1;
4423 ++num_s;
4424 }
4425 }
4426 } else {
4427 // 2*b*s + c = 0
4428 // s = -c / (2*b)
4429 s0 = c / (-2 * b);
4430 if (s0 >= 0.0 && s0 <= 1.0)
4431 num_s = 1;
4432 }
4433
4434 if (num_s == 0)
4435 return 0;
4436 else {
4437 float rcp_len2 = 1 / (ray[0]*ray[0] + ray[1]*ray[1]);
4438 float rayn_x = ray[0] * rcp_len2, rayn_y = ray[1] * rcp_len2;
4439
4440 float q0d = q0[0]*rayn_x + q0[1]*rayn_y;
4441 float q1d = q1[0]*rayn_x + q1[1]*rayn_y;
4442 float q2d = q2[0]*rayn_x + q2[1]*rayn_y;
4443 float rod = orig[0]*rayn_x + orig[1]*rayn_y;
4444
4445 float q10d = q1d - q0d;
4446 float q20d = q2d - q0d;
4447 float q0rd = q0d - rod;
4448
4449 hits[0][0] = q0rd + s0*(2.0f - 2.0f*s0)*q10d + s0*s0*q20d;
4450 hits[0][1] = a*s0+b;
4451
4452 if (num_s > 1) {
4453 hits[1][0] = q0rd + s1*(2.0f - 2.0f*s1)*q10d + s1*s1*q20d;
4454 hits[1][1] = a*s1+b;
4455 return 2;
4456 } else {
4457 return 1;
4458 }
4459 }
4460 }
4461
4462 static int equal(float *a, float *b)
4463 {
4464 return (a[0] == b[0] && a[1] == b[1]);
4465 }
4466
4467 static int stbtt__compute_crossings_x(float x, float y, int nverts, stbtt_vertex *verts)
4468 {
4469 int i;
4470 float orig[2], ray[2] = { 1, 0 };
4471 float y_frac;
4472 int winding = 0;
4473
4474 // make sure y never passes through a vertex of the shape
4475 y_frac = (float) STBTT_fmod(y, 1.0f);
4476 if (y_frac < 0.01f)
4477 y += 0.01f;
4478 else if (y_frac > 0.99f)
4479 y -= 0.01f;
4480
4481 orig[0] = x;
4482 orig[1] = y;
4483
4484 // test a ray from (-infinity,y) to (x,y)
4485 for (i=0; i < nverts; ++i) {
4486 if (verts[i].type == STBTT_vline) {
4487 int x0 = (int) verts[i-1].x, y0 = (int) verts[i-1].y;
4488 int x1 = (int) verts[i ].x, y1 = (int) verts[i ].y;
4489 if (y > STBTT_min(y0,y1) && y < STBTT_max(y0,y1) && x > STBTT_min(x0,x1)) {
4490 float x_inter = (y - y0) / (y1 - y0) * (x1-x0) + x0;
4491 if (x_inter < x)
4492 winding += (y0 < y1) ? 1 : -1;
4493 }
4494 }
4495 if (verts[i].type == STBTT_vcurve) {
4496 int x0 = (int) verts[i-1].x , y0 = (int) verts[i-1].y ;
4497 int x1 = (int) verts[i ].cx, y1 = (int) verts[i ].cy;
4498 int x2 = (int) verts[i ].x , y2 = (int) verts[i ].y ;
4499 int ax = STBTT_min(x0,STBTT_min(x1,x2)), ay = STBTT_min(y0,STBTT_min(y1,y2));
4500 int by = STBTT_max(y0,STBTT_max(y1,y2));
4501 if (y > ay && y < by && x > ax) {
4502 float q0[2],q1[2],q2[2];
4503 float hits[2][2];
4504 q0[0] = (float)x0;
4505 q0[1] = (float)y0;
4506 q1[0] = (float)x1;
4507 q1[1] = (float)y1;
4508 q2[0] = (float)x2;
4509 q2[1] = (float)y2;
4510 if (equal(q0,q1) || equal(q1,q2)) {
4511 x0 = (int)verts[i-1].x;
4512 y0 = (int)verts[i-1].y;
4513 x1 = (int)verts[i ].x;
4514 y1 = (int)verts[i ].y;
4515 if (y > STBTT_min(y0,y1) && y < STBTT_max(y0,y1) && x > STBTT_min(x0,x1)) {
4516 float x_inter = (y - y0) / (y1 - y0) * (x1-x0) + x0;
4517 if (x_inter < x)
4518 winding += (y0 < y1) ? 1 : -1;
4519 }
4520 } else {
4521 int num_hits = stbtt__ray_intersect_bezier(orig, ray, q0, q1, q2, hits);
4522 if (num_hits >= 1)
4523 if (hits[0][0] < 0)
4524 winding += (hits[0][1] < 0 ? -1 : 1);
4525 if (num_hits >= 2)
4526 if (hits[1][0] < 0)
4527 winding += (hits[1][1] < 0 ? -1 : 1);
4528 }
4529 }
4530 }
4531 }
4532 return winding;
4533 }
4534
4535 static float stbtt__cuberoot( float x )
4536 {
4537 if (x<0)
4538 return -(float) STBTT_pow(-x,1.0f/3.0f);
4539 else
4540 return (float) STBTT_pow( x,1.0f/3.0f);
4541 }
4542
4543 // x^3 + a*x^2 + b*x + c = 0
4544 static int stbtt__solve_cubic(float a, float b, float c, float* r)
4545 {
4546 float s = -a / 3;
4547 float p = b - a*a / 3;
4548 float q = a * (2*a*a - 9*b) / 27 + c;
4549 float p3 = p*p*p;
4550 float d = q*q + 4*p3 / 27;
4551 if (d >= 0) {
4552 float z = (float) STBTT_sqrt(d);
4553 float u = (-q + z) / 2;
4554 float v = (-q - z) / 2;
4555 u = stbtt__cuberoot(u);
4556 v = stbtt__cuberoot(v);
4557 r[0] = s + u + v;
4558 return 1;
4559 } else {
4560 float u = (float) STBTT_sqrt(-p/3);
4561 float v = (float) STBTT_acos(-STBTT_sqrt(-27/p3) * q / 2) / 3; // p3 must be negative, since d is negative
4562 float m = (float) STBTT_cos(v);
4563 float n = (float) STBTT_cos(v-3.141592/2)*1.732050808f;
4564 r[0] = s + u * 2 * m;
4565 r[1] = s - u * (m + n);
4566 r[2] = s - u * (m - n);
4567
4568 //STBTT_assert( STBTT_fabs(((r[0]+a)*r[0]+b)*r[0]+c) < 0.05f); // these asserts may not be safe at all scales, though they're in bezier t parameter units so maybe?
4569 //STBTT_assert( STBTT_fabs(((r[1]+a)*r[1]+b)*r[1]+c) < 0.05f);
4570 //STBTT_assert( STBTT_fabs(((r[2]+a)*r[2]+b)*r[2]+c) < 0.05f);
4571 return 3;
4572 }
4573 }
4574
4575 STBTT_DEF unsigned char * stbtt_GetGlyphSDF(const stbtt_fontinfo *info, float scale, int glyph, int padding, unsigned char onedge_value, float pixel_dist_scale, int *width, int *height, int *xoff, int *yoff)
4576 {
4577 float scale_x = scale, scale_y = scale;
4578 int ix0,iy0,ix1,iy1;
4579 int w,h;
4580 unsigned char *data;
4581
4582 if (scale == 0) return NULL;
4583
4584 stbtt_GetGlyphBitmapBoxSubpixel(info, glyph, scale, scale, 0.0f,0.0f, &ix0,&iy0,&ix1,&iy1);
4585
4586 // if empty, return NULL
4587 if (ix0 == ix1 || iy0 == iy1)
4588 return NULL;
4589
4590 ix0 -= padding;
4591 iy0 -= padding;
4592 ix1 += padding;
4593 iy1 += padding;
4594
4595 w = (ix1 - ix0);
4596 h = (iy1 - iy0);
4597
4598 if (width ) *width = w;
4599 if (height) *height = h;
4600 if (xoff ) *xoff = ix0;
4601 if (yoff ) *yoff = iy0;
4602
4603 // invert for y-downwards bitmaps
4604 scale_y = -scale_y;
4605
4606 {
4607 int x,y,i,j;
4608 float *precompute;
4609 stbtt_vertex *verts;
4610 int num_verts = stbtt_GetGlyphShape(info, glyph, &verts);
4611 data = (unsigned char *) STBTT_malloc(w * h, info->userdata);
4612 precompute = (float *) STBTT_malloc(num_verts * sizeof(float), info->userdata);
4613
4614 for (i=0,j=num_verts-1; i < num_verts; j=i++) {
4615 if (verts[i].type == STBTT_vline) {
4616 float x0 = verts[i].x*scale_x, y0 = verts[i].y*scale_y;
4617 float x1 = verts[j].x*scale_x, y1 = verts[j].y*scale_y;
4618 float dist = (float) STBTT_sqrt((x1-x0)*(x1-x0) + (y1-y0)*(y1-y0));
4619 precompute[i] = (dist == 0) ? 0.0f : 1.0f / dist;
4620 } else if (verts[i].type == STBTT_vcurve) {
4621 float x2 = verts[j].x *scale_x, y2 = verts[j].y *scale_y;
4622 float x1 = verts[i].cx*scale_x, y1 = verts[i].cy*scale_y;
4623 float x0 = verts[i].x *scale_x, y0 = verts[i].y *scale_y;
4624 float bx = x0 - 2*x1 + x2, by = y0 - 2*y1 + y2;
4625 float len2 = bx*bx + by*by;
4626 if (len2 != 0.0f)
4627 precompute[i] = 1.0f / (bx*bx + by*by);
4628 else
4629 precompute[i] = 0.0f;
4630 } else
4631 precompute[i] = 0.0f;
4632 }
4633
4634 for (y=iy0; y < iy1; ++y) {
4635 for (x=ix0; x < ix1; ++x) {
4636 float val;
4637 float min_dist = 999999.0f;
4638 float sx = (float) x + 0.5f;
4639 float sy = (float) y + 0.5f;
4640 float x_gspace = (sx / scale_x);
4641 float y_gspace = (sy / scale_y);
4642
4643 int winding = stbtt__compute_crossings_x(x_gspace, y_gspace, num_verts, verts); // @OPTIMIZE: this could just be a rasterization, but needs to be line vs. non-tesselated curves so a new path
4644
4645 for (i=0; i < num_verts; ++i) {
4646 float x0 = verts[i].x*scale_x, y0 = verts[i].y*scale_y;
4647
4648 if (verts[i].type == STBTT_vline && precompute[i] != 0.0f) {
4649 float x1 = verts[i-1].x*scale_x, y1 = verts[i-1].y*scale_y;
4650
4651 float dist,dist2 = (x0-sx)*(x0-sx) + (y0-sy)*(y0-sy);
4652 if (dist2 < min_dist*min_dist)
4653 min_dist = (float) STBTT_sqrt(dist2);
4654
4655 // coarse culling against bbox
4656 //if (sx > STBTT_min(x0,x1)-min_dist && sx < STBTT_max(x0,x1)+min_dist &&
4657 // sy > STBTT_min(y0,y1)-min_dist && sy < STBTT_max(y0,y1)+min_dist)
4658 dist = (float) STBTT_fabs((x1-x0)*(y0-sy) - (y1-y0)*(x0-sx)) * precompute[i];
4659 STBTT_assert(i != 0);
4660 if (dist < min_dist) {
4661 // check position along line
4662 // x' = x0 + t*(x1-x0), y' = y0 + t*(y1-y0)
4663 // minimize (x'-sx)*(x'-sx)+(y'-sy)*(y'-sy)
4664 float dx = x1-x0, dy = y1-y0;
4665 float px = x0-sx, py = y0-sy;
4666 // minimize (px+t*dx)^2 + (py+t*dy)^2 = px*px + 2*px*dx*t + t^2*dx*dx + py*py + 2*py*dy*t + t^2*dy*dy
4667 // derivative: 2*px*dx + 2*py*dy + (2*dx*dx+2*dy*dy)*t, set to 0 and solve
4668 float t = -(px*dx + py*dy) / (dx*dx + dy*dy);
4669 if (t >= 0.0f && t <= 1.0f)
4670 min_dist = dist;
4671 }
4672 } else if (verts[i].type == STBTT_vcurve) {
4673 float x2 = verts[i-1].x *scale_x, y2 = verts[i-1].y *scale_y;
4674 float x1 = verts[i ].cx*scale_x, y1 = verts[i ].cy*scale_y;
4675 float box_x0 = STBTT_min(STBTT_min(x0,x1),x2);
4676 float box_y0 = STBTT_min(STBTT_min(y0,y1),y2);
4677 float box_x1 = STBTT_max(STBTT_max(x0,x1),x2);
4678 float box_y1 = STBTT_max(STBTT_max(y0,y1),y2);
4679 // coarse culling against bbox to avoid computing cubic unnecessarily
4680 if (sx > box_x0-min_dist && sx < box_x1+min_dist && sy > box_y0-min_dist && sy < box_y1+min_dist) {
4681 int num=0;
4682 float ax = x1-x0, ay = y1-y0;
4683 float bx = x0 - 2*x1 + x2, by = y0 - 2*y1 + y2;
4684 float mx = x0 - sx, my = y0 - sy;
4685 float res[3] = {0.f,0.f,0.f};
4686 float px,py,t,it,dist2;
4687 float a_inv = precompute[i];
4688 if (a_inv == 0.0) { // if a_inv is 0, it's 2nd degree so use quadratic formula
4689 float a = 3*(ax*bx + ay*by);
4690 float b = 2*(ax*ax + ay*ay) + (mx*bx+my*by);
4691 float c = mx*ax+my*ay;
4692 if (a == 0.0) { // if a is 0, it's linear
4693 if (b != 0.0) {
4694 res[num++] = -c/b;
4695 }
4696 } else {
4697 float discriminant = b*b - 4*a*c;
4698 if (discriminant < 0)
4699 num = 0;
4700 else {
4701 float root = (float) STBTT_sqrt(discriminant);
4702 res[0] = (-b - root)/(2*a);
4703 res[1] = (-b + root)/(2*a);
4704 num = 2; // don't bother distinguishing 1-solution case, as code below will still work
4705 }
4706 }
4707 } else {
4708 float b = 3*(ax*bx + ay*by) * a_inv; // could precompute this as it doesn't depend on sample point
4709 float c = (2*(ax*ax + ay*ay) + (mx*bx+my*by)) * a_inv;
4710 float d = (mx*ax+my*ay) * a_inv;
4711 num = stbtt__solve_cubic(b, c, d, res);
4712 }
4713 dist2 = (x0-sx)*(x0-sx) + (y0-sy)*(y0-sy);
4714 if (dist2 < min_dist*min_dist)
4715 min_dist = (float) STBTT_sqrt(dist2);
4716
4717 if (num >= 1 && res[0] >= 0.0f && res[0] <= 1.0f) {
4718 t = res[0], it = 1.0f - t;
4719 px = it*it*x0 + 2*t*it*x1 + t*t*x2;
4720 py = it*it*y0 + 2*t*it*y1 + t*t*y2;
4721 dist2 = (px-sx)*(px-sx) + (py-sy)*(py-sy);
4722 if (dist2 < min_dist * min_dist)
4723 min_dist = (float) STBTT_sqrt(dist2);
4724 }
4725 if (num >= 2 && res[1] >= 0.0f && res[1] <= 1.0f) {
4726 t = res[1], it = 1.0f - t;
4727 px = it*it*x0 + 2*t*it*x1 + t*t*x2;
4728 py = it*it*y0 + 2*t*it*y1 + t*t*y2;
4729 dist2 = (px-sx)*(px-sx) + (py-sy)*(py-sy);
4730 if (dist2 < min_dist * min_dist)
4731 min_dist = (float) STBTT_sqrt(dist2);
4732 }
4733 if (num >= 3 && res[2] >= 0.0f && res[2] <= 1.0f) {
4734 t = res[2], it = 1.0f - t;
4735 px = it*it*x0 + 2*t*it*x1 + t*t*x2;
4736 py = it*it*y0 + 2*t*it*y1 + t*t*y2;
4737 dist2 = (px-sx)*(px-sx) + (py-sy)*(py-sy);
4738 if (dist2 < min_dist * min_dist)
4739 min_dist = (float) STBTT_sqrt(dist2);
4740 }
4741 }
4742 }
4743 }
4744 if (winding == 0)
4745 min_dist = -min_dist; // if outside the shape, value is negative
4746 val = onedge_value + pixel_dist_scale * min_dist;
4747 if (val < 0)
4748 val = 0;
4749 else if (val > 255)
4750 val = 255;
4751 data[(y-iy0)*w+(x-ix0)] = (unsigned char) val;
4752 }
4753 }
4754 STBTT_free(precompute, info->userdata);
4755 STBTT_free(verts, info->userdata);
4756 }
4757 return data;
4758 }
4759
4760 STBTT_DEF unsigned char * stbtt_GetCodepointSDF(const stbtt_fontinfo *info, float scale, int codepoint, int padding, unsigned char onedge_value, float pixel_dist_scale, int *width, int *height, int *xoff, int *yoff)
4761 {
4762 return stbtt_GetGlyphSDF(info, scale, stbtt_FindGlyphIndex(info, codepoint), padding, onedge_value, pixel_dist_scale, width, height, xoff, yoff);
4763 }
4764
4765 STBTT_DEF void stbtt_FreeSDF(unsigned char *bitmap, void *userdata)
4766 {
4767 STBTT_free(bitmap, userdata);
4768 }
4769
4770 //////////////////////////////////////////////////////////////////////////////
4771 //
4772 // font name matching -- recommended not to use this
4773 //
4774
4775 // check if a utf8 string contains a prefix which is the utf16 string; if so return length of matching utf8 string
4776 static stbtt_int32 stbtt__CompareUTF8toUTF16_bigendian_prefix(stbtt_uint8 *s1, stbtt_int32 len1, stbtt_uint8 *s2, stbtt_int32 len2)
4777 {
4778 stbtt_int32 i=0;
4779
4780 // convert utf16 to utf8 and compare the results while converting
4781 while (len2) {
4782 stbtt_uint16 ch = s2[0]*256 + s2[1];
4783 if (ch < 0x80) {
4784 if (i >= len1) return -1;
4785 if (s1[i++] != ch) return -1;
4786 } else if (ch < 0x800) {
4787 if (i+1 >= len1) return -1;
4788 if (s1[i++] != 0xc0 + (ch >> 6)) return -1;
4789 if (s1[i++] != 0x80 + (ch & 0x3f)) return -1;
4790 } else if (ch >= 0xd800 && ch < 0xdc00) {
4791 stbtt_uint32 c;
4792 stbtt_uint16 ch2 = s2[2]*256 + s2[3];
4793 if (i+3 >= len1) return -1;
4794 c = ((ch - 0xd800) << 10) + (ch2 - 0xdc00) + 0x10000;
4795 if (s1[i++] != 0xf0 + (c >> 18)) return -1;
4796 if (s1[i++] != 0x80 + ((c >> 12) & 0x3f)) return -1;
4797 if (s1[i++] != 0x80 + ((c >> 6) & 0x3f)) return -1;
4798 if (s1[i++] != 0x80 + ((c ) & 0x3f)) return -1;
4799 s2 += 2; // plus another 2 below
4800 len2 -= 2;
4801 } else if (ch >= 0xdc00 && ch < 0xe000) {
4802 return -1;
4803 } else {
4804 if (i+2 >= len1) return -1;
4805 if (s1[i++] != 0xe0 + (ch >> 12)) return -1;
4806 if (s1[i++] != 0x80 + ((ch >> 6) & 0x3f)) return -1;
4807 if (s1[i++] != 0x80 + ((ch ) & 0x3f)) return -1;
4808 }
4809 s2 += 2;
4810 len2 -= 2;
4811 }
4812 return i;
4813 }
4814
4815 static int stbtt_CompareUTF8toUTF16_bigendian_internal(char *s1, int len1, char *s2, int len2)
4816 {
4817 return len1 == stbtt__CompareUTF8toUTF16_bigendian_prefix((stbtt_uint8*) s1, len1, (stbtt_uint8*) s2, len2);
4818 }
4819
4820 // returns results in whatever encoding you request... but note that 2-byte encodings
4821 // will be BIG-ENDIAN... use stbtt_CompareUTF8toUTF16_bigendian() to compare
4822 STBTT_DEF const char *stbtt_GetFontNameString(const stbtt_fontinfo *font, int *length, int platformID, int encodingID, int languageID, int nameID)
4823 {
4824 stbtt_int32 i,count,stringOffset;
4825 stbtt_uint8 *fc = font->data;
4826 stbtt_uint32 offset = font->fontstart;
4827 stbtt_uint32 nm = stbtt__find_table(fc, offset, "name");
4828 if (!nm) return NULL;
4829
4830 count = ttUSHORT(fc+nm+2);
4831 stringOffset = nm + ttUSHORT(fc+nm+4);
4832 for (i=0; i < count; ++i) {
4833 stbtt_uint32 loc = nm + 6 + 12 * i;
4834 if (platformID == ttUSHORT(fc+loc+0) && encodingID == ttUSHORT(fc+loc+2)
4835 && languageID == ttUSHORT(fc+loc+4) && nameID == ttUSHORT(fc+loc+6)) {
4836 *length = ttUSHORT(fc+loc+8);
4837 return (const char *) (fc+stringOffset+ttUSHORT(fc+loc+10));
4838 }
4839 }
4840 return NULL;
4841 }
4842
4843 static int stbtt__matchpair(stbtt_uint8 *fc, stbtt_uint32 nm, stbtt_uint8 *name, stbtt_int32 nlen, stbtt_int32 target_id, stbtt_int32 next_id)
4844 {
4845 stbtt_int32 i;
4846 stbtt_int32 count = ttUSHORT(fc+nm+2);
4847 stbtt_int32 stringOffset = nm + ttUSHORT(fc+nm+4);
4848
4849 for (i=0; i < count; ++i) {
4850 stbtt_uint32 loc = nm + 6 + 12 * i;
4851 stbtt_int32 id = ttUSHORT(fc+loc+6);
4852 if (id == target_id) {
4853 // find the encoding
4854 stbtt_int32 platform = ttUSHORT(fc+loc+0), encoding = ttUSHORT(fc+loc+2), language = ttUSHORT(fc+loc+4);
4855
4856 // is this a Unicode encoding?
4857 if (platform == 0 || (platform == 3 && encoding == 1) || (platform == 3 && encoding == 10)) {
4858 stbtt_int32 slen = ttUSHORT(fc+loc+8);
4859 stbtt_int32 off = ttUSHORT(fc+loc+10);
4860
4861 // check if there's a prefix match
4862 stbtt_int32 matchlen = stbtt__CompareUTF8toUTF16_bigendian_prefix(name, nlen, fc+stringOffset+off,slen);
4863 if (matchlen >= 0) {
4864 // check for target_id+1 immediately following, with same encoding & language
4865 if (i+1 < count && ttUSHORT(fc+loc+12+6) == next_id && ttUSHORT(fc+loc+12) == platform && ttUSHORT(fc+loc+12+2) == encoding && ttUSHORT(fc+loc+12+4) == language) {
4866 slen = ttUSHORT(fc+loc+12+8);
4867 off = ttUSHORT(fc+loc+12+10);
4868 if (slen == 0) {
4869 if (matchlen == nlen)
4870 return 1;
4871 } else if (matchlen < nlen && name[matchlen] == ' ') {
4872 ++matchlen;
4873 if (stbtt_CompareUTF8toUTF16_bigendian_internal((char*) (name+matchlen), nlen-matchlen, (char*)(fc+stringOffset+off),slen))
4874 return 1;
4875 }
4876 } else {
4877 // if nothing immediately following
4878 if (matchlen == nlen)
4879 return 1;
4880 }
4881 }
4882 }
4883
4884 // @TODO handle other encodings
4885 }
4886 }
4887 return 0;
4888 }
4889
4890 static int stbtt__matches(stbtt_uint8 *fc, stbtt_uint32 offset, stbtt_uint8 *name, stbtt_int32 flags)
4891 {
4892 stbtt_int32 nlen = (stbtt_int32) STBTT_strlen((char *) name);
4893 stbtt_uint32 nm,hd;
4894 if (!stbtt__isfont(fc+offset)) return 0;
4895
4896 // check italics/bold/underline flags in macStyle...
4897 if (flags) {
4898 hd = stbtt__find_table(fc, offset, "head");
4899 if ((ttUSHORT(fc+hd+44) & 7) != (flags & 7)) return 0;
4900 }
4901
4902 nm = stbtt__find_table(fc, offset, "name");
4903 if (!nm) return 0;
4904
4905 if (flags) {
4906 // if we checked the macStyle flags, then just check the family and ignore the subfamily
4907 if (stbtt__matchpair(fc, nm, name, nlen, 16, -1)) return 1;
4908 if (stbtt__matchpair(fc, nm, name, nlen, 1, -1)) return 1;
4909 if (stbtt__matchpair(fc, nm, name, nlen, 3, -1)) return 1;
4910 } else {
4911 if (stbtt__matchpair(fc, nm, name, nlen, 16, 17)) return 1;
4912 if (stbtt__matchpair(fc, nm, name, nlen, 1, 2)) return 1;
4913 if (stbtt__matchpair(fc, nm, name, nlen, 3, -1)) return 1;
4914 }
4915
4916 return 0;
4917 }
4918
4919 static int stbtt_FindMatchingFont_internal(unsigned char *font_collection, char *name_utf8, stbtt_int32 flags)
4920 {
4921 stbtt_int32 i;
4922 for (i=0;;++i) {
4923 stbtt_int32 off = stbtt_GetFontOffsetForIndex(font_collection, i);
4924 if (off < 0) return off;
4925 if (stbtt__matches((stbtt_uint8 *) font_collection, off, (stbtt_uint8*) name_utf8, flags))
4926 return off;
4927 }
4928 }
4929
4930 #if defined(__GNUC__) || defined(__clang__)
4931 #pragma GCC diagnostic push
4932 #pragma GCC diagnostic ignored "-Wcast-qual"
4933 #endif
4934
4935 STBTT_DEF int stbtt_BakeFontBitmap(const unsigned char *data, int offset,
4936 float pixel_height, unsigned char *pixels, int pw, int ph,
4937 int first_char, int num_chars, stbtt_bakedchar *chardata)
4938 {
4939 return stbtt_BakeFontBitmap_internal((unsigned char *) data, offset, pixel_height, pixels, pw, ph, first_char, num_chars, chardata);
4940 }
4941
4942 STBTT_DEF int stbtt_GetFontOffsetForIndex(const unsigned char *data, int index)
4943 {
4944 return stbtt_GetFontOffsetForIndex_internal((unsigned char *) data, index);
4945 }
4946
4947 STBTT_DEF int stbtt_GetNumberOfFonts(const unsigned char *data)
4948 {
4949 return stbtt_GetNumberOfFonts_internal((unsigned char *) data);
4950 }
4951
4952 STBTT_DEF int stbtt_InitFont(stbtt_fontinfo *info, const unsigned char *data, int offset)
4953 {
4954 return stbtt_InitFont_internal(info, (unsigned char *) data, offset);
4955 }
4956
4957 STBTT_DEF int stbtt_FindMatchingFont(const unsigned char *fontdata, const char *name, int flags)
4958 {
4959 return stbtt_FindMatchingFont_internal((unsigned char *) fontdata, (char *) name, flags);
4960 }
4961
4962 STBTT_DEF int stbtt_CompareUTF8toUTF16_bigendian(const char *s1, int len1, const char *s2, int len2)
4963 {
4964 return stbtt_CompareUTF8toUTF16_bigendian_internal((char *) s1, len1, (char *) s2, len2);
4965 }
4966
4967 #if defined(__GNUC__) || defined(__clang__)
4968 #pragma GCC diagnostic pop
4969 #endif
4970
4971 #endif // STB_TRUETYPE_IMPLEMENTATION
4972
4973
4974 // FULL VERSION HISTORY
4975 //
4976 // 1.25 (2021-07-11) many fixes
4977 // 1.24 (2020-02-05) fix warning
4978 // 1.23 (2020-02-02) query SVG data for glyphs; query whole kerning table (but only kern not GPOS)
4979 // 1.22 (2019-08-11) minimize missing-glyph duplication; fix kerning if both 'GPOS' and 'kern' are defined
4980 // 1.21 (2019-02-25) fix warning
4981 // 1.20 (2019-02-07) PackFontRange skips missing codepoints; GetScaleFontVMetrics()
4982 // 1.19 (2018-02-11) OpenType GPOS kerning (horizontal only), STBTT_fmod
4983 // 1.18 (2018-01-29) add missing function
4984 // 1.17 (2017-07-23) make more arguments const; doc fix
4985 // 1.16 (2017-07-12) SDF support
4986 // 1.15 (2017-03-03) make more arguments const
4987 // 1.14 (2017-01-16) num-fonts-in-TTC function
4988 // 1.13 (2017-01-02) support OpenType fonts, certain Apple fonts
4989 // 1.12 (2016-10-25) suppress warnings about casting away const with -Wcast-qual
4990 // 1.11 (2016-04-02) fix unused-variable warning
4991 // 1.10 (2016-04-02) allow user-defined fabs() replacement
4992 // fix memory leak if fontsize=0.0
4993 // fix warning from duplicate typedef
4994 // 1.09 (2016-01-16) warning fix; avoid crash on outofmem; use alloc userdata for PackFontRanges
4995 // 1.08 (2015-09-13) document stbtt_Rasterize(); fixes for vertical & horizontal edges
4996 // 1.07 (2015-08-01) allow PackFontRanges to accept arrays of sparse codepoints;
4997 // allow PackFontRanges to pack and render in separate phases;
4998 // fix stbtt_GetFontOFfsetForIndex (never worked for non-0 input?);
4999 // fixed an assert() bug in the new rasterizer
5000 // replace assert() with STBTT_assert() in new rasterizer
5001 // 1.06 (2015-07-14) performance improvements (~35% faster on x86 and x64 on test machine)
5002 // also more precise AA rasterizer, except if shapes overlap
5003 // remove need for STBTT_sort
5004 // 1.05 (2015-04-15) fix misplaced definitions for STBTT_STATIC
5005 // 1.04 (2015-04-15) typo in example
5006 // 1.03 (2015-04-12) STBTT_STATIC, fix memory leak in new packing, various fixes
5007 // 1.02 (2014-12-10) fix various warnings & compile issues w/ stb_rect_pack, C++
5008 // 1.01 (2014-12-08) fix subpixel position when oversampling to exactly match
5009 // non-oversampled; STBTT_POINT_SIZE for packed case only
5010 // 1.00 (2014-12-06) add new PackBegin etc. API, w/ support for oversampling
5011 // 0.99 (2014-09-18) fix multiple bugs with subpixel rendering (ryg)
5012 // 0.9 (2014-08-07) support certain mac/iOS fonts without an MS platformID
5013 // 0.8b (2014-07-07) fix a warning
5014 // 0.8 (2014-05-25) fix a few more warnings
5015 // 0.7 (2013-09-25) bugfix: subpixel glyph bug fixed in 0.5 had come back
5016 // 0.6c (2012-07-24) improve documentation
5017 // 0.6b (2012-07-20) fix a few more warnings
5018 // 0.6 (2012-07-17) fix warnings; added stbtt_ScaleForMappingEmToPixels,
5019 // stbtt_GetFontBoundingBox, stbtt_IsGlyphEmpty
5020 // 0.5 (2011-12-09) bugfixes:
5021 // subpixel glyph renderer computed wrong bounding box
5022 // first vertex of shape can be off-curve (FreeSans)
5023 // 0.4b (2011-12-03) fixed an error in the font baking example
5024 // 0.4 (2011-12-01) kerning, subpixel rendering (tor)
5025 // bugfixes for:
5026 // codepoint-to-glyph conversion using table fmt=12
5027 // codepoint-to-glyph conversion using table fmt=4
5028 // stbtt_GetBakedQuad with non-square texture (Zer)
5029 // updated Hello World! sample to use kerning and subpixel
5030 // fixed some warnings
5031 // 0.3 (2009-06-24) cmap fmt=12, compound shapes (MM)
5032 // userdata, malloc-from-userdata, non-zero fill (stb)
5033 // 0.2 (2009-03-11) Fix unsigned/signed char warnings
5034 // 0.1 (2009-03-09) First public release
5035 //
5036
5037 /*
5038 ------------------------------------------------------------------------------
5039 This software is available under 2 licenses -- choose whichever you prefer.
5040 ------------------------------------------------------------------------------
5041 ALTERNATIVE A - MIT License
5042 Copyright (c) 2017 Sean Barrett
5043 Permission is hereby granted, free of charge, to any person obtaining a copy of
5044 this software and associated documentation files (the "Software"), to deal in
5045 the Software without restriction, including without limitation the rights to
5046 use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies
5047 of the Software, and to permit persons to whom the Software is furnished to do
5048 so, subject to the following conditions:
5049 The above copyright notice and this permission notice shall be included in all
5050 copies or substantial portions of the Software.
5051 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
5052 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
5053 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
5054 AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
5055 LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
5056 OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
5057 SOFTWARE.
5058 ------------------------------------------------------------------------------
5059 ALTERNATIVE B - Public Domain (www.unlicense.org)
5060 This is free and unencumbered software released into the public domain.
5061 Anyone is free to copy, modify, publish, use, compile, sell, or distribute this
5062 software, either in source code form or as a compiled binary, for any purpose,
5063 commercial or non-commercial, and by any means.
5064 In jurisdictions that recognize copyright laws, the author or authors of this
5065 software dedicate any and all copyright interest in the software to the public
5066 domain. We make this dedication for the benefit of the public at large and to
5067 the detriment of our heirs and successors. We intend this dedication to be an
5068 overt act of relinquishment in perpetuity of all present and future rights to
5069 this software under copyright law.
5070 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
5071 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
5072 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
5073 AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
5074 ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
5075 WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
5076 ------------------------------------------------------------------------------
5077 */