alpha_processing.c source code [Skia/third_party/externals/libwebp/src/dsp/alpha_processing.c]

1	// Copyright 2013 Google Inc. All Rights Reserved.
2	//
3	// Use of this source code is governed by a BSD-style license
4	// that can be found in the COPYING file in the root of the source
5	// tree. An additional intellectual property rights grant can be found
6	// in the file PATENTS. All contributing project authors may
7	// be found in the AUTHORS file in the root of the source tree.
8	// -----------------------------------------------------------------------------
9	//
10	// Utilities for processing transparent channel.
11	//
12	// Author: Skal (pascal.massimino@gmail.com)
13
14	#include <assert.h>
15	#include "src/dsp/dsp.h"
16
17	// Tables can be faster on some platform but incur some extra binary size (~2k).
18	#if !defined(USE_TABLES_FOR_ALPHA_MULT)
19	#define USE_TABLES_FOR_ALPHA_MULT 0 // ALTERNATE_CODE
20	#endif
21
22
23	// -----------------------------------------------------------------------------
24
25	#define MFIX 24 // 24bit fixed-point arithmetic
26	#define HALF ((1u << MFIX) >> 1)
27	#define KINV_255 ((1u << MFIX) / 255u)
28
29	static uint32_t Mult(uint8_t x, uint32_t mult) {
30	const uint32_t v = (x * mult + HALF) >> MFIX;
31	assert(v <= `255`); // <- 24bit precision is enough to ensure that.
32	return v;
33	}
34
35	#if (USE_TABLES_FOR_ALPHA_MULT == 1)
36
37	static const uint32_t kMultTables[`2`][`256`] = {
38	{ // (255u << MFIX) / alpha
39	`0x00000000`, `0xff000000`, `0x7f800000`, `0x55000000`, `0x3fc00000`, `0x33000000`,
40	`0x2a800000`, `0x246db6db`, `0x1fe00000`, `0x1c555555`, `0x19800000`, `0x172e8ba2`,
41	`0x15400000`, `0x139d89d8`, `0x1236db6d`, `0x11000000`, `0x0ff00000`, `0x0f000000`,
42	`0x0e2aaaaa`, `0x0d6bca1a`, `0x0cc00000`, `0x0c249249`, `0x0b9745d1`, `0x0b1642c8`,
43	`0x0aa00000`, `0x0a333333`, `0x09cec4ec`, `0x0971c71c`, `0x091b6db6`, `0x08cb08d3`,
44	`0x08800000`, `0x0839ce73`, `0x07f80000`, `0x07ba2e8b`, `0x07800000`, `0x07492492`,
45	`0x07155555`, `0x06e45306`, `0x06b5e50d`, `0x0689d89d`, `0x06600000`, `0x063831f3`,
46	`0x06124924`, `0x05ee23b8`, `0x05cba2e8`, `0x05aaaaaa`, `0x058b2164`, `0x056cefa8`,
47	`0x05500000`, `0x05343eb1`, `0x05199999`, `0x05000000`, `0x04e76276`, `0x04cfb2b7`,
48	`0x04b8e38e`, `0x04a2e8ba`, `0x048db6db`, `0x0479435e`, `0x04658469`, `0x045270d0`,
49	`0x04400000`, `0x042e29f7`, `0x041ce739`, `0x040c30c3`, `0x03fc0000`, `0x03ec4ec4`,
50	`0x03dd1745`, `0x03ce540f`, `0x03c00000`, `0x03b21642`, `0x03a49249`, `0x03976fc6`,
51	`0x038aaaaa`, `0x037e3f1f`, `0x03722983`, `0x03666666`, `0x035af286`, `0x034fcace`,
52	`0x0344ec4e`, `0x033a5440`, `0x03300000`, `0x0325ed09`, `0x031c18f9`, `0x0312818a`,
53	`0x03092492`, `0x03000000`, `0x02f711dc`, `0x02ee5846`, `0x02e5d174`, `0x02dd7baf`,
54	`0x02d55555`, `0x02cd5cd5`, `0x02c590b2`, `0x02bdef7b`, `0x02b677d4`, `0x02af286b`,
55	`0x02a80000`, `0x02a0fd5c`, `0x029a1f58`, `0x029364d9`, `0x028ccccc`, `0x0286562d`,
56	`0x02800000`, `0x0279c952`, `0x0273b13b`, `0x026db6db`, `0x0267d95b`, `0x026217ec`,
57	`0x025c71c7`, `0x0256e62a`, `0x0251745d`, `0x024c1bac`, `0x0246db6d`, `0x0241b2f9`,
58	`0x023ca1af`, `0x0237a6f4`, `0x0232c234`, `0x022df2df`, `0x02293868`, `0x02249249`,
59	`0x02200000`, `0x021b810e`, `0x021714fb`, `0x0212bb51`, `0x020e739c`, `0x020a3d70`,
60	`0x02061861`, `0x02020408`, `0x01fe0000`, `0x01fa0be8`, `0x01f62762`, `0x01f25213`,
61	`0x01ee8ba2`, `0x01ead3ba`, `0x01e72a07`, `0x01e38e38`, `0x01e00000`, `0x01dc7f10`,
62	`0x01d90b21`, `0x01d5a3e9`, `0x01d24924`, `0x01cefa8d`, `0x01cbb7e3`, `0x01c880e5`,
63	`0x01c55555`, `0x01c234f7`, `0x01bf1f8f`, `0x01bc14e5`, `0x01b914c1`, `0x01b61eed`,
64	`0x01b33333`, `0x01b05160`, `0x01ad7943`, `0x01aaaaaa`, `0x01a7e567`, `0x01a5294a`,
65	`0x01a27627`, `0x019fcbd2`, `0x019d2a20`, `0x019a90e7`, `0x01980000`, `0x01957741`,
66	`0x0192f684`, `0x01907da4`, `0x018e0c7c`, `0x018ba2e8`, `0x018940c5`, `0x0186e5f0`,
67	`0x01849249`, `0x018245ae`, `0x01800000`, `0x017dc11f`, `0x017b88ee`, `0x0179574e`,
68	`0x01772c23`, `0x01750750`, `0x0172e8ba`, `0x0170d045`, `0x016ebdd7`, `0x016cb157`,
69	`0x016aaaaa`, `0x0168a9b9`, `0x0166ae6a`, `0x0164b8a7`, `0x0162c859`, `0x0160dd67`,
70	`0x015ef7bd`, `0x015d1745`, `0x015b3bea`, `0x01596596`, `0x01579435`, `0x0155c7b4`,
71	`0x01540000`, `0x01523d03`, `0x01507eae`, `0x014ec4ec`, `0x014d0fac`, `0x014b5edc`,
72	`0x0149b26c`, `0x01480a4a`, `0x01466666`, `0x0144c6af`, `0x01432b16`, `0x0141938b`,
73	`0x01400000`, `0x013e7063`, `0x013ce4a9`, `0x013b5cc0`, `0x0139d89d`, `0x01385830`,
74	`0x0136db6d`, `0x01356246`, `0x0133ecad`, `0x01327a97`, `0x01310bf6`, `0x012fa0be`,
75	`0x012e38e3`, `0x012cd459`, `0x012b7315`, `0x012a150a`, `0x0128ba2e`, `0x01276276`,
76	`0x01260dd6`, `0x0124bc44`, `0x01236db6`, `0x01222222`, `0x0120d97c`, `0x011f93bc`,
77	`0x011e50d7`, `0x011d10c4`, `0x011bd37a`, `0x011a98ef`, `0x0119611a`, `0x01182bf2`,
78	`0x0116f96f`, `0x0115c988`, `0x01149c34`, `0x0113716a`, `0x01124924`, `0x01112358`,
79	`0x01100000`, `0x010edf12`, `0x010dc087`, `0x010ca458`, `0x010b8a7d`, `0x010a72f0`,
80	`0x01095da8`, `0x01084a9f`, `0x010739ce`, `0x01062b2e`, `0x01051eb8`, `0x01041465`,
81	`0x01030c30`, `0x01020612`, `0x01010204`, `0x01000000` },
82	{ // alpha KINV_255*
83	`0x00000000`, `0x00010101`, `0x00020202`, `0x00030303`, `0x00040404`, `0x00050505`,
84	`0x00060606`, `0x00070707`, `0x00080808`, `0x00090909`, `0x000a0a0a`, `0x000b0b0b`,
85	`0x000c0c0c`, `0x000d0d0d`, `0x000e0e0e`, `0x000f0f0f`, `0x00101010`, `0x00111111`,
86	`0x00121212`, `0x00131313`, `0x00141414`, `0x00151515`, `0x00161616`, `0x00171717`,
87	`0x00181818`, `0x00191919`, `0x001a1a1a`, `0x001b1b1b`, `0x001c1c1c`, `0x001d1d1d`,
88	`0x001e1e1e`, `0x001f1f1f`, `0x00202020`, `0x00212121`, `0x00222222`, `0x00232323`,
89	`0x00242424`, `0x00252525`, `0x00262626`, `0x00272727`, `0x00282828`, `0x00292929`,
90	`0x002a2a2a`, `0x002b2b2b`, `0x002c2c2c`, `0x002d2d2d`, `0x002e2e2e`, `0x002f2f2f`,
91	`0x00303030`, `0x00313131`, `0x00323232`, `0x00333333`, `0x00343434`, `0x00353535`,
92	`0x00363636`, `0x00373737`, `0x00383838`, `0x00393939`, `0x003a3a3a`, `0x003b3b3b`,
93	`0x003c3c3c`, `0x003d3d3d`, `0x003e3e3e`, `0x003f3f3f`, `0x00404040`, `0x00414141`,
94	`0x00424242`, `0x00434343`, `0x00444444`, `0x00454545`, `0x00464646`, `0x00474747`,
95	`0x00484848`, `0x00494949`, `0x004a4a4a`, `0x004b4b4b`, `0x004c4c4c`, `0x004d4d4d`,
96	`0x004e4e4e`, `0x004f4f4f`, `0x00505050`, `0x00515151`, `0x00525252`, `0x00535353`,
97	`0x00545454`, `0x00555555`, `0x00565656`, `0x00575757`, `0x00585858`, `0x00595959`,
98	`0x005a5a5a`, `0x005b5b5b`, `0x005c5c5c`, `0x005d5d5d`, `0x005e5e5e`, `0x005f5f5f`,
99	`0x00606060`, `0x00616161`, `0x00626262`, `0x00636363`, `0x00646464`, `0x00656565`,
100	`0x00666666`, `0x00676767`, `0x00686868`, `0x00696969`, `0x006a6a6a`, `0x006b6b6b`,
101	`0x006c6c6c`, `0x006d6d6d`, `0x006e6e6e`, `0x006f6f6f`, `0x00707070`, `0x00717171`,
102	`0x00727272`, `0x00737373`, `0x00747474`, `0x00757575`, `0x00767676`, `0x00777777`,
103	`0x00787878`, `0x00797979`, `0x007a7a7a`, `0x007b7b7b`, `0x007c7c7c`, `0x007d7d7d`,
104	`0x007e7e7e`, `0x007f7f7f`, `0x00808080`, `0x00818181`, `0x00828282`, `0x00838383`,
105	`0x00848484`, `0x00858585`, `0x00868686`, `0x00878787`, `0x00888888`, `0x00898989`,
106	`0x008a8a8a`, `0x008b8b8b`, `0x008c8c8c`, `0x008d8d8d`, `0x008e8e8e`, `0x008f8f8f`,
107	`0x00909090`, `0x00919191`, `0x00929292`, `0x00939393`, `0x00949494`, `0x00959595`,
108	`0x00969696`, `0x00979797`, `0x00989898`, `0x00999999`, `0x009a9a9a`, `0x009b9b9b`,
109	`0x009c9c9c`, `0x009d9d9d`, `0x009e9e9e`, `0x009f9f9f`, `0x00a0a0a0`, `0x00a1a1a1`,
110	`0x00a2a2a2`, `0x00a3a3a3`, `0x00a4a4a4`, `0x00a5a5a5`, `0x00a6a6a6`, `0x00a7a7a7`,
111	`0x00a8a8a8`, `0x00a9a9a9`, `0x00aaaaaa`, `0x00ababab`, `0x00acacac`, `0x00adadad`,
112	`0x00aeaeae`, `0x00afafaf`, `0x00b0b0b0`, `0x00b1b1b1`, `0x00b2b2b2`, `0x00b3b3b3`,
113	`0x00b4b4b4`, `0x00b5b5b5`, `0x00b6b6b6`, `0x00b7b7b7`, `0x00b8b8b8`, `0x00b9b9b9`,
114	`0x00bababa`, `0x00bbbbbb`, `0x00bcbcbc`, `0x00bdbdbd`, `0x00bebebe`, `0x00bfbfbf`,
115	`0x00c0c0c0`, `0x00c1c1c1`, `0x00c2c2c2`, `0x00c3c3c3`, `0x00c4c4c4`, `0x00c5c5c5`,
116	`0x00c6c6c6`, `0x00c7c7c7`, `0x00c8c8c8`, `0x00c9c9c9`, `0x00cacaca`, `0x00cbcbcb`,
117	`0x00cccccc`, `0x00cdcdcd`, `0x00cecece`, `0x00cfcfcf`, `0x00d0d0d0`, `0x00d1d1d1`,
118	`0x00d2d2d2`, `0x00d3d3d3`, `0x00d4d4d4`, `0x00d5d5d5`, `0x00d6d6d6`, `0x00d7d7d7`,
119	`0x00d8d8d8`, `0x00d9d9d9`, `0x00dadada`, `0x00dbdbdb`, `0x00dcdcdc`, `0x00dddddd`,
120	`0x00dedede`, `0x00dfdfdf`, `0x00e0e0e0`, `0x00e1e1e1`, `0x00e2e2e2`, `0x00e3e3e3`,
121	`0x00e4e4e4`, `0x00e5e5e5`, `0x00e6e6e6`, `0x00e7e7e7`, `0x00e8e8e8`, `0x00e9e9e9`,
122	`0x00eaeaea`, `0x00ebebeb`, `0x00ececec`, `0x00ededed`, `0x00eeeeee`, `0x00efefef`,
123	`0x00f0f0f0`, `0x00f1f1f1`, `0x00f2f2f2`, `0x00f3f3f3`, `0x00f4f4f4`, `0x00f5f5f5`,
124	`0x00f6f6f6`, `0x00f7f7f7`, `0x00f8f8f8`, `0x00f9f9f9`, `0x00fafafa`, `0x00fbfbfb`,
125	`0x00fcfcfc`, `0x00fdfdfd`, `0x00fefefe`, `0x00ffffff` }
126	};
127
128	static WEBP_INLINE uint32_t GetScale(uint32_t a, int inverse) {
129	return kMultTables[!inverse][a];
130	}
131
132	#else
133
134	static WEBP_INLINE uint32_t GetScale(uint32_t a, int inverse) {
135	return inverse ? (`255u` << MFIX) / a : a * KINV_255;
136	}
137
138	#endif // USE_TABLES_FOR_ALPHA_MULT
139
140	void WebPMultARGBRow_C(uint32_t* const ptr, int width, int inverse) {
141	int x;
142	for (x = `0`; x < width; ++x) {
143	const uint32_t argb = ptr[x];
144	if (argb < `0xff000000u`) { // alpha < 255
145	if (argb <= `0x00ffffffu`) { // alpha == 0
146	ptr[x] = `0`;
147	} else {
148	const uint32_t alpha = (argb >> `24`) & `0xff`;
149	const uint32_t scale = GetScale(alpha, inverse);
150	uint32_t out = argb & `0xff000000u`;
151	out \|= Mult(argb >> `0`, scale) << `0`;
152	out \|= Mult(argb >> `8`, scale) << `8`;
153	out \|= Mult(argb >> `16`, scale) << `16`;
154	ptr[x] = out;
155	}
156	}
157	}
158	}
159
160	void WebPMultRow_C(uint8_t* const ptr, const uint8_t* const alpha,
161	int width, int inverse) {
162	int x;
163	for (x = `0`; x < width; ++x) {
164	const uint32_t a = alpha[x];
165	if (a != `255`) {
166	if (a == `0`) {
167	ptr[x] = `0`;
168	} else {
169	const uint32_t scale = GetScale(a, inverse);
170	ptr[x] = Mult(ptr[x], scale);
171	}
172	}
173	}
174	}
175
176	#undef KINV_255
177	#undef HALF
178	#undef MFIX
179
180	void (WebPMultARGBRow)(uint32_t const ptr, int width, int inverse);
181	void (WebPMultRow)(uint8_t const ptr, const uint8_t* const alpha,
182	int width, int inverse);
183
184	//------------------------------------------------------------------------------
185	// Generic per-plane calls
186
187	void WebPMultARGBRows(uint8_t* ptr, int stride, int width, int num_rows,
188	int inverse) {
189	int n;
190	for (n = `0`; n < num_rows; ++n) {
191	WebPMultARGBRow((uint32_t*)ptr, width, inverse);
192	ptr += stride;
193	}
194	}
195
196	void WebPMultRows(uint8_t* ptr, int stride,
197	const uint8_t* alpha, int alpha_stride,
198	int width, int num_rows, int inverse) {
199	int n;
200	for (n = `0`; n < num_rows; ++n) {
201	WebPMultRow(ptr, alpha, width, inverse);
202	ptr += stride;
203	alpha += alpha_stride;
204	}
205	}
206
207	//------------------------------------------------------------------------------
208	// Premultiplied modes
209
210	// non dithered-modes
211
212	// (x a * 32897) >> 23 is bit-wise equivalent to (int)(x * a / 255.)*
213	// for all 8bit x or a. For bit-wise equivalence to (int)(x a / 255. + .5),*
214	// one can use instead: (x a * 65793 + (1 << 23)) >> 24*
215	#if 1 // (int)(x * a / 255.)
216	#define MULTIPLIER(a) ((a) * 32897U)
217	#define PREMULTIPLY(x, m) (((x) * (m)) >> 23)
218	#else // (int)(x * a / 255. + .5)
219	#define MULTIPLIER(a) ((a) * 65793U)
220	#define PREMULTIPLY(x, m) (((x) * (m) + (1U << 23)) >> 24)
221	#endif
222
223	#if !WEBP_NEON_OMIT_C_CODE
224	static void ApplyAlphaMultiply_C(uint8_t* rgba, int alpha_first,
225	int w, int h, int stride) {
226	while (h-- > `0`) {
227	uint8_t* const rgb = rgba + (alpha_first ? `1` : `0`);
228	const uint8_t* const alpha = rgba + (alpha_first ? `0` : `3`);
229	int i;
230	for (i = `0`; i < w; ++i) {
231	const uint32_t a = alpha[`4` * i];
232	if (a != `0xff`) {
233	const uint32_t mult = MULTIPLIER(a);
234	rgb[`4` * i + `0`] = PREMULTIPLY(rgb[`4` * i + `0`], mult);
235	rgb[`4` * i + `1`] = PREMULTIPLY(rgb[`4` * i + `1`], mult);
236	rgb[`4` * i + `2`] = PREMULTIPLY(rgb[`4` * i + `2`], mult);
237	}
238	}
239	rgba += stride;
240	}
241	}
242	#endif // !WEBP_NEON_OMIT_C_CODE
243	#undef MULTIPLIER
244	#undef PREMULTIPLY
245
246	// rgbA4444
247
248	#define MULTIPLIER(a) ((a) * 0x1111) // 0x1111 ~= (1 << 16) / 15
249
250	static WEBP_INLINE uint8_t dither_hi(uint8_t x) {
251	return (x & `0xf0`) \| (x >> `4`);
252	}
253
254	static WEBP_INLINE uint8_t dither_lo(uint8_t x) {
255	return (x & `0x0f`) \| (x << `4`);
256	}
257
258	static WEBP_INLINE uint8_t multiply(uint8_t x, uint32_t m) {
259	return (x * m) >> `16`;
260	}
261
262	static WEBP_INLINE void ApplyAlphaMultiply4444_C(uint8_t* rgba4444,
263	int w, int h, int stride,
264	int rg_byte_pos / 0 or 1 /) {
265	while (h-- > `0`) {
266	int i;
267	for (i = `0`; i < w; ++i) {
268	const uint32_t rg = rgba4444[`2` * i + rg_byte_pos];
269	const uint32_t ba = rgba4444[`2` * i + (rg_byte_pos ^ `1`)];
270	const uint8_t a = ba & `0x0f`;
271	const uint32_t mult = MULTIPLIER(a);
272	const uint8_t r = multiply(dither_hi(rg), mult);
273	const uint8_t g = multiply(dither_lo(rg), mult);
274	const uint8_t b = multiply(dither_hi(ba), mult);
275	rgba4444[`2` * i + rg_byte_pos] = (r & `0xf0`) \| ((g >> `4`) & `0x0f`);
276	rgba4444[`2` * i + (rg_byte_pos ^ `1`)] = (b & `0xf0`) \| a;
277	}
278	rgba4444 += stride;
279	}
280	}
281	#undef MULTIPLIER
282
283	static void ApplyAlphaMultiply_16b_C(uint8_t* rgba4444,
284	int w, int h, int stride) {
285	#if (WEBP_SWAP_16BIT_CSP == 1)
286	ApplyAlphaMultiply4444_C(rgba4444, w, h, stride, `1`);
287	#else
288	ApplyAlphaMultiply4444_C(rgba4444, w, h, stride, `0`);
289	#endif
290	}
291
292	#if !WEBP_NEON_OMIT_C_CODE
293	static int DispatchAlpha_C(const uint8_t* alpha, int alpha_stride,
294	int width, int height,
295	uint8_t* dst, int dst_stride) {
296	uint32_t alpha_mask = `0xff`;
297	int i, j;
298
299	for (j = `0`; j < height; ++j) {
300	for (i = `0`; i < width; ++i) {
301	const uint32_t alpha_value = alpha[i];
302	dst[`4` * i] = alpha_value;
303	alpha_mask &= alpha_value;
304	}
305	alpha += alpha_stride;
306	dst += dst_stride;
307	}
308
309	return (alpha_mask != `0xff`);
310	}
311
312	static void DispatchAlphaToGreen_C(const uint8_t* alpha, int alpha_stride,
313	int width, int height,
314	uint32_t* dst, int dst_stride) {
315	int i, j;
316	for (j = `0`; j < height; ++j) {
317	for (i = `0`; i < width; ++i) {
318	dst[i] = alpha[i] << `8`; // leave A/R/B channels zero'd.
319	}
320	alpha += alpha_stride;
321	dst += dst_stride;
322	}
323	}
324
325	static int ExtractAlpha_C(const uint8_t* argb, int argb_stride,
326	int width, int height,
327	uint8_t* alpha, int alpha_stride) {
328	uint8_t alpha_mask = `0xff`;
329	int i, j;
330
331	for (j = `0`; j < height; ++j) {
332	for (i = `0`; i < width; ++i) {
333	const uint8_t alpha_value = argb[`4` * i];
334	alpha[i] = alpha_value;
335	alpha_mask &= alpha_value;
336	}
337	argb += argb_stride;
338	alpha += alpha_stride;
339	}
340	return (alpha_mask == `0xff`);
341	}
342
343	static void ExtractGreen_C(const uint32_t* argb, uint8_t* alpha, int size) {
344	int i;
345	for (i = `0`; i < size; ++i) alpha[i] = argb[i] >> `8`;
346	}
347	#endif // !WEBP_NEON_OMIT_C_CODE
348
349	//------------------------------------------------------------------------------
350
351	static int HasAlpha8b_C(const uint8_t* src, int length) {
352	while (length-- > `0`) if (src++ != `0xff`) return* `1`;
353	return `0`;
354	}
355
356	static int HasAlpha32b_C(const uint8_t* src, int length) {
357	int x;
358	for (x = `0`; length-- > `0`; x += `4`) if (src[x] != `0xff`) return `1`;
359	return `0`;
360	}
361
362	//------------------------------------------------------------------------------
363	// Simple channel manipulations.
364
365	static WEBP_INLINE uint32_t MakeARGB32(int a, int r, int g, int b) {
366	return (((uint32_t)a << `24`) \| (r << `16`) \| (g << `8`) \| b);
367	}
368
369	#ifdef WORDS_BIGENDIAN
370	static void PackARGB_C(const uint8_t* a, const uint8_t* r, const uint8_t* g,
371	const uint8_t* b, int len, uint32_t* out) {
372	int i;
373	for (i = `0`; i < len; ++i) {
374	out[i] = MakeARGB32(a[`4` * i], r[`4` * i], g[`4` * i], b[`4` * i]);
375	}
376	}
377	#endif
378
379	static void PackRGB_C(const uint8_t* r, const uint8_t* g, const uint8_t* b,
380	int len, int step, uint32_t* out) {
381	int i, offset = `0`;
382	for (i = `0`; i < len; ++i) {
383	out[i] = MakeARGB32(`0xff`, r[offset], g[offset], b[offset]);
384	offset += step;
385	}
386	}
387
388	void (WebPApplyAlphaMultiply)(uint8_t, int, int, int, int);
389	void (WebPApplyAlphaMultiply4444)(uint8_t, int, int, int);
390	int (WebPDispatchAlpha)(const* uint8_t, int, int, int, uint8_t, int);
391	void (WebPDispatchAlphaToGreen)(const* uint8_t, int, int, int, uint32_t, int);
392	int (WebPExtractAlpha)(const* uint8_t, int, int, int, uint8_t, int);
393	void (WebPExtractGreen)(const* uint32_t* argb, uint8_t* alpha, int size);
394	#ifdef WORDS_BIGENDIAN
395	void (WebPPackARGB)(const* uint8_t* a, const uint8_t* r, const uint8_t* g,
396	const uint8_t* b, int, uint32_t*);
397	#endif
398	void (WebPPackRGB)(const* uint8_t* r, const uint8_t* g, const uint8_t* b,
399	int len, int step, uint32_t* out);
400
401	int (WebPHasAlpha8b)(const* uint8_t* src, int length);
402	int (WebPHasAlpha32b)(const* uint8_t* src, int length);
403
404	//------------------------------------------------------------------------------
405	// Init function
406
407	extern void WebPInitAlphaProcessingMIPSdspR2(void);
408	extern void WebPInitAlphaProcessingSSE2(void);
409	extern void WebPInitAlphaProcessingSSE41(void);
410	extern void WebPInitAlphaProcessingNEON(void);
411
412	WEBP_DSP_INIT_FUNC(WebPInitAlphaProcessing) {
413	WebPMultARGBRow = WebPMultARGBRow_C;
414	WebPMultRow = WebPMultRow_C;
415	WebPApplyAlphaMultiply4444 = ApplyAlphaMultiply_16b_C;
416
417	#ifdef WORDS_BIGENDIAN
418	WebPPackARGB = PackARGB_C;
419	#endif
420	WebPPackRGB = PackRGB_C;
421	#if !WEBP_NEON_OMIT_C_CODE
422	WebPApplyAlphaMultiply = ApplyAlphaMultiply_C;
423	WebPDispatchAlpha = DispatchAlpha_C;
424	WebPDispatchAlphaToGreen = DispatchAlphaToGreen_C;
425	WebPExtractAlpha = ExtractAlpha_C;
426	WebPExtractGreen = ExtractGreen_C;
427	#endif
428
429	WebPHasAlpha8b = HasAlpha8b_C;
430	WebPHasAlpha32b = HasAlpha32b_C;
431
432	// If defined, use CPUInfo() to overwrite some pointers with faster versions.
433	if (VP8GetCPUInfo != NULL) {
434	#if defined(WEBP_USE_SSE2)
435	if (VP8GetCPUInfo(kSSE2)) {
436	WebPInitAlphaProcessingSSE2();
437	#if defined(WEBP_USE_SSE41)
438	if (VP8GetCPUInfo(kSSE4_1)) {
439	WebPInitAlphaProcessingSSE41();
440	}
441	#endif
442	}
443	#endif
444	#if defined(WEBP_USE_MIPS_DSP_R2)
445	if (VP8GetCPUInfo(kMIPSdspR2)) {
446	WebPInitAlphaProcessingMIPSdspR2();
447	}
448	#endif
449	}
450
451	#if defined(WEBP_USE_NEON)
452	if (WEBP_NEON_OMIT_C_CODE \|\|
453	(VP8GetCPUInfo != NULL && VP8GetCPUInfo(kNEON))) {
454	WebPInitAlphaProcessingNEON();
455	}
456	#endif
457
458	assert(WebPMultARGBRow != NULL);
459	assert(WebPMultRow != NULL);
460	assert(WebPApplyAlphaMultiply != NULL);
461	assert(WebPApplyAlphaMultiply4444 != NULL);
462	assert(WebPDispatchAlpha != NULL);
463	assert(WebPDispatchAlphaToGreen != NULL);
464	assert(WebPExtractAlpha != NULL);
465	assert(WebPExtractGreen != NULL);
466	#ifdef WORDS_BIGENDIAN
467	assert(WebPPackARGB != NULL);
468	#endif
469	assert(WebPPackRGB != NULL);
470	assert(WebPHasAlpha8b != NULL);
471	assert(WebPHasAlpha32b != NULL);
472	}
473

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