/*
 * This file is part of the Scale2x project.
 *
 * Copyright (C) 2001, 2002, 2003, 2004 Andrea Mazzoleni
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 */

/*
 * This file contains a C and MMX implementation of the Scale2x effect.
 *
 * You can find an high level description of the effect at :
 *
 * http://scale2x.sourceforge.net/
 *
 * Alternatively at the previous license terms, you are allowed to use this
 * code in your program with these conditions:
 * - the program is not used in commercial activities.
 * - the whole source code of the program is released with the binary.
 * - derivative works of the program are allowed.
 */

#if HAVE_CONFIG_H
#include <config.h>
#endif

#include "scale2x.h"

#include <assert.h>

/***************************************************************************/
/* Scale2x C implementation */

/**
 * Define the macro USE_SCALE_RANDOMWRITE to enable
 * an optimized version which writes memory in random order.
 * This version is a little faster if you write in system memory.
 * But it's a lot slower if you write in video memory.
 * So, enable it only if you are sure to never write directly in video memory.
 */
/* #define USE_SCALE_RANDOMWRITE */

#ifdef USE_SCALE_RANDOMWRITE

static inline void scale2x_8_def_whole(scale2x_uint8* restrict dst0, scale2x_uint8* restrict dst1, const scale2x_uint8* restrict src0, const scale2x_uint8* restrict src1, const scale2x_uint8* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst0[0] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst0[1] = src1[1] == src0[0] ? src0[0] : src1[0];
		dst1[0] = src1[0] == src2[0] ? src2[0] : src1[0];
		dst1[1] = src1[1] == src2[0] ? src2[0] : src1[0];
	} else {
		dst0[0] = src1[0];
		dst0[1] = src1[0];
		dst1[0] = src1[0];
		dst1[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst0 += 2;
	dst1 += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst0[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
			dst0[1] = src1[1] == src0[0] ? src0[0] : src1[0];
			dst1[0] = src1[-1] == src2[0] ? src2[0] : src1[0];
			dst1[1] = src1[1] == src2[0] ? src2[0] : src1[0];
		} else {
			dst0[0] = src1[0];
			dst0[1] = src1[0];
			dst1[0] = src1[0];
			dst1[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst0 += 2;
		dst1 += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst0[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
		dst0[1] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst1[0] = src1[-1] == src2[0] ? src2[0] : src1[0];
		dst1[1] = src1[0] == src2[0] ? src2[0] : src1[0];
	} else {
		dst0[0] = src1[0];
		dst0[1] = src1[0];
		dst1[0] = src1[0];
		dst1[1] = src1[0];
	}
}

#else /* USE_SCALE_RANDOMWRITE */

static inline void scale2x_8_def_border(scale2x_uint8* restrict dst, const scale2x_uint8* restrict src0, const scale2x_uint8* restrict src1, const scale2x_uint8* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst[0] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst[1] = src1[1] == src0[0] ? src0[0] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
			dst[1] = src1[1] == src0[0] ? src0[0] : src1[0];
		} else {
			dst[0] = src1[0];
			dst[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
		dst[1] = src1[0] == src0[0] ? src0[0] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
}

static inline void scale2x_8_def_center(scale2x_uint8* restrict dst, const scale2x_uint8* restrict src0, const scale2x_uint8* restrict src1, const scale2x_uint8* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst[0] = src1[0];
		dst[1] = (src1[1] == src0[0] && src1[0] != src2[1]) || (src1[1] == src2[0] && src1[0] != src0[1]) ? src1[1] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst[0] = (src1[-1] == src0[0] && src1[0] != src2[-1]) || (src1[-1] == src2[0] && src1[0] != src0[-1]) ? src1[-1] : src1[0];
			dst[1] = (src1[1] == src0[0] && src1[0] != src2[1]) || (src1[1] == src2[0] && src1[0] != src0[1]) ? src1[1] : src1[0];
		} else {
			dst[0] = src1[0];
			dst[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst[0] = (src1[-1] == src0[0] && src1[0] != src2[-1]) || (src1[-1] == src2[0] && src1[0] != src0[-1]) ? src1[-1] : src1[0];
		dst[1] = src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
}

#endif /* USE_SCALE_RANDOMWRITE */

#ifdef USE_SCALE_RANDOMWRITE

static inline void scale2x_16_def_whole(scale2x_uint16* restrict dst0, scale2x_uint16* restrict dst1, const scale2x_uint16* restrict src0, const scale2x_uint16* restrict src1, const scale2x_uint16* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst0[0] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst0[1] = src1[1] == src0[0] ? src0[0] : src1[0];
		dst1[0] = src1[0] == src2[0] ? src2[0] : src1[0];
		dst1[1] = src1[1] == src2[0] ? src2[0] : src1[0];
	} else {
		dst0[0] = src1[0];
		dst0[1] = src1[0];
		dst1[0] = src1[0];
		dst1[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst0 += 2;
	dst1 += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst0[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
			dst0[1] = src1[1] == src0[0] ? src0[0] : src1[0];
			dst1[0] = src1[-1] == src2[0] ? src2[0] : src1[0];
			dst1[1] = src1[1] == src2[0] ? src2[0] : src1[0];
		} else {
			dst0[0] = src1[0];
			dst0[1] = src1[0];
			dst1[0] = src1[0];
			dst1[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst0 += 2;
		dst1 += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst0[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
		dst0[1] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst1[0] = src1[-1] == src2[0] ? src2[0] : src1[0];
		dst1[1] = src1[0] == src2[0] ? src2[0] : src1[0];
	} else {
		dst0[0] = src1[0];
		dst0[1] = src1[0];
		dst1[0] = src1[0];
		dst1[1] = src1[0];
	}
}

#else /* USE_SCALE_RANDOMWRITE */

static inline void scale2x_16_def_border(scale2x_uint16* restrict dst, const scale2x_uint16* restrict src0, const scale2x_uint16* restrict src1, const scale2x_uint16* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst[0] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst[1] = src1[1] == src0[0] ? src0[0] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
			dst[1] = src1[1] == src0[0] ? src0[0] : src1[0];
		} else {
			dst[0] = src1[0];
			dst[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
		dst[1] = src1[0] == src0[0] ? src0[0] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
}

static inline void scale2x_16_def_center(scale2x_uint16* restrict dst, const scale2x_uint16* restrict src0, const scale2x_uint16* restrict src1, const scale2x_uint16* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst[0] = src1[0];
		dst[1] = (src1[1] == src0[0] && src1[0] != src2[1]) || (src1[1] == src2[0] && src1[0] != src0[1]) ? src1[1] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst[0] = (src1[-1] == src0[0] && src1[0] != src2[-1]) || (src1[-1] == src2[0] && src1[0] != src0[-1]) ? src1[-1] : src1[0];
			dst[1] = (src1[1] == src0[0] && src1[0] != src2[1]) || (src1[1] == src2[0] && src1[0] != src0[1]) ? src1[1] : src1[0];
		} else {
			dst[0] = src1[0];
			dst[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst[0] = (src1[-1] == src0[0] && src1[0] != src2[-1]) || (src1[-1] == src2[0] && src1[0] != src0[-1]) ? src1[-1] : src1[0];
		dst[1] = src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
}

#endif /* USE_SCALE_RANDOMWRITE */

#ifdef USE_SCALE_RANDOMWRITE

static inline void scale2x_32_def_whole(scale2x_uint32* restrict dst0, scale2x_uint32* restrict dst1, const scale2x_uint32* restrict src0, const scale2x_uint32* restrict src1, const scale2x_uint32* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst0[0] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst0[1] = src1[1] == src0[0] ? src0[0] : src1[0];
		dst1[0] = src1[0] == src2[0] ? src2[0] : src1[0];
		dst1[1] = src1[1] == src2[0] ? src2[0] : src1[0];
	} else {
		dst0[0] = src1[0];
		dst0[1] = src1[0];
		dst1[0] = src1[0];
		dst1[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst0 += 2;
	dst1 += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst0[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
			dst0[1] = src1[1] == src0[0] ? src0[0] : src1[0];
			dst1[0] = src1[-1] == src2[0] ? src2[0] : src1[0];
			dst1[1] = src1[1] == src2[0] ? src2[0] : src1[0];
		} else {
			dst0[0] = src1[0];
			dst0[1] = src1[0];
			dst1[0] = src1[0];
			dst1[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst0 += 2;
		dst1 += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst0[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
		dst0[1] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst1[0] = src1[-1] == src2[0] ? src2[0] : src1[0];
		dst1[1] = src1[0] == src2[0] ? src2[0] : src1[0];
	} else {
		dst0[0] = src1[0];
		dst0[1] = src1[0];
		dst1[0] = src1[0];
		dst1[1] = src1[0];
	}
}

#else /* USE_SCALE_RANDOMWRITE */

static inline void scale2x_32_def_border(scale2x_uint32* restrict dst, const scale2x_uint32* restrict src0, const scale2x_uint32* restrict src1, const scale2x_uint32* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst[0] = src1[0] == src0[0] ? src0[0] : src1[0];
		dst[1] = src1[1] == src0[0] ? src0[0] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
			dst[1] = src1[1] == src0[0] ? src0[0] : src1[0];
		} else {
			dst[0] = src1[0];
			dst[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst[0] = src1[-1] == src0[0] ? src0[0] : src1[0];
		dst[1] = src1[0] == src0[0] ? src0[0] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
}

static inline void scale2x_32_def_center(scale2x_uint32* restrict dst, const scale2x_uint32* restrict src0, const scale2x_uint32* restrict src1, const scale2x_uint32* restrict src2, unsigned count)
{
	assert(count >= 2);

	/* first pixel */
	if (src0[0] != src2[0] && src1[0] != src1[1]) {
		dst[0] = src1[0];
		dst[1] = (src1[1] == src0[0] && src1[0] != src2[1]) || (src1[1] == src2[0] && src1[0] != src0[1]) ? src1[1] : src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
	++src0;
	++src1;
	++src2;
	dst += 2;

	/* central pixels */
	count -= 2;
	while (count) {
		if (src0[0] != src2[0] && src1[-1] != src1[1]) {
			dst[0] = (src1[-1] == src0[0] && src1[0] != src2[-1]) || (src1[-1] == src2[0] && src1[0] != src0[-1]) ? src1[-1] : src1[0];
			dst[1] = (src1[1] == src0[0] && src1[0] != src2[1]) || (src1[1] == src2[0] && src1[0] != src0[1]) ? src1[1] : src1[0];
		} else {
			dst[0] = src1[0];
			dst[1] = src1[0];
		}

		++src0;
		++src1;
		++src2;
		dst += 2;
		--count;
	}

	/* last pixel */
	if (src0[0] != src2[0] && src1[-1] != src1[0]) {
		dst[0] = (src1[-1] == src0[0] && src1[0] != src2[-1]) || (src1[-1] == src2[0] && src1[0] != src0[-1]) ? src1[-1] : src1[0];
		dst[1] = src1[0];
	} else {
		dst[0] = src1[0];
		dst[1] = src1[0];
	}
}

#endif /* USE_SCALE_RANDOMWRITE */

/**
 * Scale by a factor of 2 a row of pixels of 8 bits.
 * The function is implemented in C.
 * The pixels over the left and right borders are assumed of the same color of
 * the pixels on the border.
 * Note that the implementation is optimized to write data sequentially to
 * maximize the bandwidth on video memory.
 * \param src0 Pointer at the first pixel of the previous row.
 * \param src1 Pointer at the first pixel of the current row.
 * \param src2 Pointer at the first pixel of the next row.
 * \param count Length in pixels of the src0, src1 and src2 rows.
 * It must be at least 2.
 * \param dst0 First destination row, double length in pixels.
 * \param dst1 Second destination row, double length in pixels.
 */
void scale2x_8_def(scale2x_uint8* dst0, scale2x_uint8* dst1, const scale2x_uint8* src0, const scale2x_uint8* src1, const scale2x_uint8* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_8_def_whole(dst0, dst1, src0, src1, src2, count);
#else
	scale2x_8_def_border(dst0, src0, src1, src2, count);
	scale2x_8_def_border(dst1, src2, src1, src0, count);
#endif
}

/**
 * Scale by a factor of 2 a row of pixels of 16 bits.
 * This function operates like scale2x_8_def() but for 16 bits pixels.
 * \param src0 Pointer at the first pixel of the previous row.
 * \param src1 Pointer at the first pixel of the current row.
 * \param src2 Pointer at the first pixel of the next row.
 * \param count Length in pixels of the src0, src1 and src2 rows.
 * It must be at least 2.
 * \param dst0 First destination row, double length in pixels.
 * \param dst1 Second destination row, double length in pixels.
 */
void scale2x_16_def(scale2x_uint16* dst0, scale2x_uint16* dst1, const scale2x_uint16* src0, const scale2x_uint16* src1, const scale2x_uint16* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_16_def_whole(dst0, dst1, src0, src1, src2, count);
#else
	scale2x_16_def_border(dst0, src0, src1, src2, count);
	scale2x_16_def_border(dst1, src2, src1, src0, count);
#endif
}

/**
 * Scale by a factor of 2 a row of pixels of 32 bits.
 * This function operates like scale2x_8_def() but for 32 bits pixels.
 * \param src0 Pointer at the first pixel of the previous row.
 * \param src1 Pointer at the first pixel of the current row.
 * \param src2 Pointer at the first pixel of the next row.
 * \param count Length in pixels of the src0, src1 and src2 rows.
 * It must be at least 2.
 * \param dst0 First destination row, double length in pixels.
 * \param dst1 Second destination row, double length in pixels.
 */
void scale2x_32_def(scale2x_uint32* dst0, scale2x_uint32* dst1, const scale2x_uint32* src0, const scale2x_uint32* src1, const scale2x_uint32* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_32_def_whole(dst0, dst1, src0, src1, src2, count);
#else
	scale2x_32_def_border(dst0, src0, src1, src2, count);
	scale2x_32_def_border(dst1, src2, src1, src0, count);
#endif
}

/**
 * Scale by a factor of 2x3 a row of pixels of 8 bits.
 * \note Like scale2x_8_def();
 */
void scale2x3_8_def(scale2x_uint8* dst0, scale2x_uint8* dst1, scale2x_uint8* dst2, const scale2x_uint8* src0, const scale2x_uint8* src1, const scale2x_uint8* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_8_def_whole(dst0, dst2, src0, src1, src2, count);
	scale2x_8_def_center(dst1, src0, src1, src2, count);
#else
	scale2x_8_def_border(dst0, src0, src1, src2, count);
	scale2x_8_def_center(dst1, src0, src1, src2, count);
	scale2x_8_def_border(dst2, src2, src1, src0, count);
#endif
}

/**
 * Scale by a factor of 2x3 a row of pixels of 16 bits.
 * \note Like scale2x_16_def();
 */
void scale2x3_16_def(scale2x_uint16* dst0, scale2x_uint16* dst1, scale2x_uint16* dst2, const scale2x_uint16* src0, const scale2x_uint16* src1, const scale2x_uint16* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_16_def_whole(dst0, dst2, src0, src1, src2, count);
	scale2x_16_def_center(dst1, src0, src1, src2, count);
#else
	scale2x_16_def_border(dst0, src0, src1, src2, count);
	scale2x_16_def_center(dst1, src0, src1, src2, count);
	scale2x_16_def_border(dst2, src2, src1, src0, count);
#endif
}

/**
 * Scale by a factor of 2x3 a row of pixels of 32 bits.
 * \note Like scale2x_32_def();
 */
void scale2x3_32_def(scale2x_uint32* dst0, scale2x_uint32* dst1, scale2x_uint32* dst2, const scale2x_uint32* src0, const scale2x_uint32* src1, const scale2x_uint32* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_32_def_whole(dst0, dst2, src0, src1, src2, count);
	scale2x_32_def_center(dst1, src0, src1, src2, count);
#else
	scale2x_32_def_border(dst0, src0, src1, src2, count);
	scale2x_32_def_center(dst1, src0, src1, src2, count);
	scale2x_32_def_border(dst2, src2, src1, src0, count);
#endif
}

/**
 * Scale by a factor of 2x4 a row of pixels of 8 bits.
 * \note Like scale2x_8_def();
 */
void scale2x4_8_def(scale2x_uint8* dst0, scale2x_uint8* dst1, scale2x_uint8* dst2, scale2x_uint8* dst3, const scale2x_uint8* src0, const scale2x_uint8* src1, const scale2x_uint8* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_8_def_whole(dst0, dst3, src0, src1, src2, count);
	scale2x_8_def_center(dst1, src0, src1, src2, count);
	scale2x_8_def_center(dst2, src0, src1, src2, count);
#else
	scale2x_8_def_border(dst0, src0, src1, src2, count);
	scale2x_8_def_center(dst1, src0, src1, src2, count);
	scale2x_8_def_center(dst2, src0, src1, src2, count);
	scale2x_8_def_border(dst3, src2, src1, src0, count);
#endif
}

/**
 * Scale by a factor of 2x4 a row of pixels of 16 bits.
 * \note Like scale2x_16_def();
 */
void scale2x4_16_def(scale2x_uint16* dst0, scale2x_uint16* dst1, scale2x_uint16* dst2, scale2x_uint16* dst3, const scale2x_uint16* src0, const scale2x_uint16* src1, const scale2x_uint16* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_16_def_whole(dst0, dst3, src0, src1, src2, count);
	scale2x_16_def_center(dst1, src0, src1, src2, count);
	scale2x_16_def_center(dst2, src0, src1, src2, count);
#else
	scale2x_16_def_border(dst0, src0, src1, src2, count);
	scale2x_16_def_center(dst1, src0, src1, src2, count);
	scale2x_16_def_center(dst2, src0, src1, src2, count);
	scale2x_16_def_border(dst3, src2, src1, src0, count);
#endif
}

/**
 * Scale by a factor of 2x4 a row of pixels of 32 bits.
 * \note Like scale2x_32_def();
 */
void scale2x4_32_def(scale2x_uint32* dst0, scale2x_uint32* dst1, scale2x_uint32* dst2, scale2x_uint32* dst3, const scale2x_uint32* src0, const scale2x_uint32* src1, const scale2x_uint32* src2, unsigned count)
{
#ifdef USE_SCALE_RANDOMWRITE
	scale2x_32_def_whole(dst0, dst3, src0, src1, src2, count);
	scale2x_32_def_center(dst1, src0, src1, src2, count);
	scale2x_32_def_center(dst2, src0, src1, src2, count);
#else
	scale2x_32_def_border(dst0, src0, src1, src2, count);
	scale2x_32_def_center(dst1, src0, src1, src2, count);
	scale2x_32_def_center(dst2, src0, src1, src2, count);
	scale2x_32_def_border(dst3, src2, src1, src0, count);
#endif
}

/***************************************************************************/
/* Scale2x MMX implementation */

#if defined(__GNUC__) && (defined(__i386__) || defined(__x86_64__))

/*
 * Apply the Scale2x effect at a single row.
 * This function must be called only by the other scale2x functions.
 *
 * Considering the pixel map :
 *
 *      ABC (src0)
 *      DEF (src1)
 *      GHI (src2)
 *
 * this functions compute 2 new pixels in substitution of the source pixel E
 * like this map :
 *
 *      ab (dst)
 *
 * with these variables :
 *
 *      &current -> E
 *      &current_left -> D
 *      &current_right -> F
 *      &current_upper -> B
 *      &current_lower -> H
 *
 *      %0 -> current_upper
 *      %1 -> current
 *      %2 -> current_lower
 *      %3 -> dst
 *      %4 -> counter
 *
 *      %mm0 -> *current_left
 *      %mm1 -> *current_next
 *      %mm2 -> tmp0
 *      %mm3 -> tmp1
 *      %mm4 -> tmp2
 *      %mm5 -> tmp3
 *      %mm6 -> *current_upper
 *      %mm7 -> *current
 */
static inline void scale2x_8_mmx_border(scale2x_uint8* dst, const scale2x_uint8* src0, const scale2x_uint8* src1, const scale2x_uint8* src2, unsigned count)
{
	assert(count >= 16);
	assert(count % 8 == 0);

	/* always do the first and last run */
	count -= 2*8;

	__asm__ __volatile__(
/* first run */
		/* set the current, current_pre, current_next registers */
		"movq 0(%1), %%mm0\n"
		"movq 0(%1), %%mm7\n"
		"movq 8(%1), %%mm1\n"
		"psllq $56, %%mm0\n"
		"psllq $56, %%mm1\n"
		"psrlq $56, %%mm0\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $8, %%mm2\n"
		"psrlq $8, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqb %%mm6, %%mm2\n"
		"pcmpeqb %%mm6, %%mm4\n"
		"pcmpeqb (%2), %%mm3\n"
		"pcmpeqb (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqb %%mm1, %%mm2\n"
		"pcmpeqb %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpcklbw %%mm4, %%mm2\n"
		"punpckhbw %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		/* next */
		"add $8, %0\n"
		"add $8, %1\n"
		"add $8, %2\n"
		"add $16, %3\n"

/* central runs */
		"shr $3, %4\n"
		"jz 1f\n"

		"0:\n"

		/* set the current, current_pre, current_next registers */
		"movq -8(%1), %%mm0\n"
		"movq (%1), %%mm7\n"
		"movq 8(%1), %%mm1\n"
		"psrlq $56, %%mm0\n"
		"psllq $56, %%mm1\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $8, %%mm2\n"
		"psrlq $8, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqb %%mm6, %%mm2\n"
		"pcmpeqb %%mm6, %%mm4\n"
		"pcmpeqb (%2), %%mm3\n"
		"pcmpeqb (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqb %%mm1, %%mm2\n"
		"pcmpeqb %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpcklbw %%mm4, %%mm2\n"
		"punpckhbw %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		/* next */
		"add $8, %0\n"
		"add $8, %1\n"
		"add $8, %2\n"
		"add $16, %3\n"

		"dec %4\n"
		"jnz 0b\n"
		"1:\n"

/* final run */
		/* set the current, current_pre, current_next registers */
		"movq (%1), %%mm1\n"
		"movq (%1), %%mm7\n"
		"movq -8(%1), %%mm0\n"
		"psrlq $56, %%mm1\n"
		"psrlq $56, %%mm0\n"
		"psllq $56, %%mm1\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $8, %%mm2\n"
		"psrlq $8, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqb %%mm6, %%mm2\n"
		"pcmpeqb %%mm6, %%mm4\n"
		"pcmpeqb (%2), %%mm3\n"
		"pcmpeqb (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqb %%mm1, %%mm2\n"
		"pcmpeqb %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpcklbw %%mm4, %%mm2\n"
		"punpckhbw %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		: "+r" (src0), "+r" (src1), "+r" (src2), "+r" (dst), "+r" (count)
		:
		: "cc"
	);
}

static inline void scale2x_16_mmx_border(scale2x_uint16* dst, const scale2x_uint16* src0, const scale2x_uint16* src1, const scale2x_uint16* src2, unsigned count)
{
	assert(count >= 8);
	assert(count % 4 == 0);

	/* always do the first and last run */
	count -= 2*4;

	__asm__ __volatile__(
/* first run */
		/* set the current, current_pre, current_next registers */
		"movq 0(%1), %%mm0\n"
		"movq 0(%1), %%mm7\n"
		"movq 8(%1), %%mm1\n"
		"psllq $48, %%mm0\n"
		"psllq $48, %%mm1\n"
		"psrlq $48, %%mm0\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $16, %%mm2\n"
		"psrlq $16, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqw %%mm6, %%mm2\n"
		"pcmpeqw %%mm6, %%mm4\n"
		"pcmpeqw (%2), %%mm3\n"
		"pcmpeqw (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqw %%mm1, %%mm2\n"
		"pcmpeqw %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpcklwd %%mm4, %%mm2\n"
		"punpckhwd %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		/* next */
		"add $8, %0\n"
		"add $8, %1\n"
		"add $8, %2\n"
		"add $16, %3\n"

/* central runs */
		"shr $2, %4\n"
		"jz 1f\n"

		"0:\n"

		/* set the current, current_pre, current_next registers */
		"movq -8(%1), %%mm0\n"
		"movq (%1), %%mm7\n"
		"movq 8(%1), %%mm1\n"
		"psrlq $48, %%mm0\n"
		"psllq $48, %%mm1\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $16, %%mm2\n"
		"psrlq $16, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqw %%mm6, %%mm2\n"
		"pcmpeqw %%mm6, %%mm4\n"
		"pcmpeqw (%2), %%mm3\n"
		"pcmpeqw (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqw %%mm1, %%mm2\n"
		"pcmpeqw %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpcklwd %%mm4, %%mm2\n"
		"punpckhwd %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		/* next */
		"add $8, %0\n"
		"add $8, %1\n"
		"add $8, %2\n"
		"add $16, %3\n"

		"dec %4\n"
		"jnz 0b\n"
		"1:\n"

/* final run */
		/* set the current, current_pre, current_next registers */
		"movq (%1), %%mm1\n"
		"movq (%1), %%mm7\n"
		"movq -8(%1), %%mm0\n"
		"psrlq $48, %%mm1\n"
		"psrlq $48, %%mm0\n"
		"psllq $48, %%mm1\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $16, %%mm2\n"
		"psrlq $16, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqw %%mm6, %%mm2\n"
		"pcmpeqw %%mm6, %%mm4\n"
		"pcmpeqw (%2), %%mm3\n"
		"pcmpeqw (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqw %%mm1, %%mm2\n"
		"pcmpeqw %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpcklwd %%mm4, %%mm2\n"
		"punpckhwd %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		: "+r" (src0), "+r" (src1), "+r" (src2), "+r" (dst), "+r" (count)
		:
		: "cc"
	);
}

static inline void scale2x_32_mmx_border(scale2x_uint32* dst, const scale2x_uint32* src0, const scale2x_uint32* src1, const scale2x_uint32* src2, unsigned count)
{
	assert(count >= 4);
	assert(count % 2 == 0);

	/* always do the first and last run */
	count -= 2*2;

	__asm__ __volatile__(
/* first run */
		/* set the current, current_pre, current_next registers */
		"movq 0(%1), %%mm0\n"
		"movq 0(%1), %%mm7\n"
		"movq 8(%1), %%mm1\n"
		"psllq $32, %%mm0\n"
		"psllq $32, %%mm1\n"
		"psrlq $32, %%mm0\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $32, %%mm2\n"
		"psrlq $32, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqd %%mm6, %%mm2\n"
		"pcmpeqd %%mm6, %%mm4\n"
		"pcmpeqd (%2), %%mm3\n"
		"pcmpeqd (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqd %%mm1, %%mm2\n"
		"pcmpeqd %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpckldq %%mm4, %%mm2\n"
		"punpckhdq %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		/* next */
		"add $8, %0\n"
		"add $8, %1\n"
		"add $8, %2\n"
		"add $16, %3\n"

/* central runs */
		"shr $1, %4\n"
		"jz 1f\n"

		"0:\n"

		/* set the current, current_pre, current_next registers */
		"movq -8(%1), %%mm0\n"
		"movq (%1), %%mm7\n"
		"movq 8(%1), %%mm1\n"
		"psrlq $32, %%mm0\n"
		"psllq $32, %%mm1\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $32, %%mm2\n"
		"psrlq $32, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqd %%mm6, %%mm2\n"
		"pcmpeqd %%mm6, %%mm4\n"
		"pcmpeqd (%2), %%mm3\n"
		"pcmpeqd (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqd %%mm1, %%mm2\n"
		"pcmpeqd %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpckldq %%mm4, %%mm2\n"
		"punpckhdq %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		/* next */
		"add $8, %0\n"
		"add $8, %1\n"
		"add $8, %2\n"
		"add $16, %3\n"

		"dec %4\n"
		"jnz 0b\n"
		"1:\n"

/* final run */
		/* set the current, current_pre, current_next registers */
		"movq (%1), %%mm1\n"
		"movq (%1), %%mm7\n"
		"movq -8(%1), %%mm0\n"
		"psrlq $32, %%mm1\n"
		"psrlq $32, %%mm0\n"
		"psllq $32, %%mm1\n"
		"movq %%mm7, %%mm2\n"
		"movq %%mm7, %%mm3\n"
		"psllq $32, %%mm2\n"
		"psrlq $32, %%mm3\n"
		"por %%mm2, %%mm0\n"
		"por %%mm3, %%mm1\n"

		/* current_upper */
		"movq (%0), %%mm6\n"

		/* compute the upper-left pixel for dst on %%mm2 */
		/* compute the upper-right pixel for dst on %%mm4 */
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"movq %%mm0, %%mm3\n"
		"movq %%mm1, %%mm5\n"
		"pcmpeqd %%mm6, %%mm2\n"
		"pcmpeqd %%mm6, %%mm4\n"
		"pcmpeqd (%2), %%mm3\n"
		"pcmpeqd (%2), %%mm5\n"
		"pandn %%mm2, %%mm3\n"
		"pandn %%mm4, %%mm5\n"
		"movq %%mm0, %%mm2\n"
		"movq %%mm1, %%mm4\n"
		"pcmpeqd %%mm1, %%mm2\n"
		"pcmpeqd %%mm0, %%mm4\n"
		"pandn %%mm3, %%mm2\n"
		"pandn %%mm5, %%mm4\n"
		"movq %%mm2, %%mm3\n"
		"movq %%mm4, %%mm5\n"
		"pand %%mm6, %%mm2\n"
		"pand %%mm6, %%mm4\n"
		"pandn %%mm7, %%mm3\n"
		"pandn %%mm7, %%mm5\n"
		"por %%mm3, %%mm2\n"
		"por %%mm5, %%mm4\n"

		/* set *dst */
		"movq %%mm2, %%mm3\n"
		"punpckldq %%mm4, %%mm2\n"
		"punpckhdq %%mm4, %%mm3\n"
		"movq %%mm2, (%3)\n"
		"movq %%mm3, 8(%3)\n"

		: "+r" (src0), "+r" (src1), "+r" (src2), "+r" (dst), "+r" (count)
		:
		: "cc"
	);
}

/**
 * Scale by a factor of 2 a row of pixels of 8 bits.
 * This is a very fast MMX implementation.
 * The implementation uses a combination of cmp/and/not operations to
 * completly remove the need of conditional jumps. This trick give the
 * major speed improvement.
 * Also, using the 8 bytes MMX registers more than one pixel are computed
 * at the same time.
 * Before calling this function you must ensure that the currenct CPU supports
 * the MMX instruction set. After calling it you must be sure to call the EMMS
 * instruction before any floating-point operation.
 * The pixels over the left and right borders are assumed of the same color of
 * the pixels on the border.
 * Note that the implementation is optimized to write data sequentially to
 * maximize the bandwidth on video memory.
 * \param src0 Pointer at the first pixel of the previous row.
 * \param src1 Pointer at the first pixel of the current row.
 * \param src2 Pointer at the first pixel of the next row.
 * \param count Length in pixels of the src0, src1 and src2 rows. It must
 * be at least 16 and a multiple of 8.
 * \param dst0 First destination row, double length in pixels.
 * \param dst1 Second destination row, double length in pixels.
 */
void scale2x_8_mmx(scale2x_uint8* dst0, scale2x_uint8* dst1, const scale2x_uint8* src0, const scale2x_uint8* src1, const scale2x_uint8* src2, unsigned count)
{
	if (count % 8 != 0 || count < 16) {
		scale2x_8_def(dst0, dst1, src0, src1, src2, count);
	} else {
		scale2x_8_mmx_border(dst0, src0, src1, src2, count);
		scale2x_8_mmx_border(dst1, src2, src1, src0, count);
	}
}

/**
 * Scale by a factor of 2 a row of pixels of 16 bits.
 * This function operates like scale2x_8_mmx() but for 16 bits pixels.
 * \param src0 Pointer at the first pixel of the previous row.
 * \param src1 Pointer at the first pixel of the current row.
 * \param src2 Pointer at the first pixel of the next row.
 * \param count Length in pixels of the src0, src1 and src2 rows. It must
 * be at least 8 and a multiple of 4.
 * \param dst0 First destination row, double length in pixels.
 * \param dst1 Second destination row, double length in pixels.
 */
void scale2x_16_mmx(scale2x_uint16* dst0, scale2x_uint16* dst1, const scale2x_uint16* src0, const scale2x_uint16* src1, const scale2x_uint16* src2, unsigned count)
{
	if (count % 4 != 0 || count < 8) {
		scale2x_16_def(dst0, dst1, src0, src1, src2, count);
	} else {
		scale2x_16_mmx_border(dst0, src0, src1, src2, count);
		scale2x_16_mmx_border(dst1, src2, src1, src0, count);
	}
}

/**
 * Scale by a factor of 2 a row of pixels of 32 bits.
 * This function operates like scale2x_8_mmx() but for 32 bits pixels.
 * \param src0 Pointer at the first pixel of the previous row.
 * \param src1 Pointer at the first pixel of the current row.
 * \param src2 Pointer at the first pixel of the next row.
 * \param count Length in pixels of the src0, src1 and src2 rows. It must
 * be at least 4 and a multiple of 2.
 * \param dst0 First destination row, double length in pixels.
 * \param dst1 Second destination row, double length in pixels.
 */
void scale2x_32_mmx(scale2x_uint32* dst0, scale2x_uint32* dst1, const scale2x_uint32* src0, const scale2x_uint32* src1, const scale2x_uint32* src2, unsigned count)
{
	if (count % 2 != 0 || count < 4) {
		scale2x_32_def(dst0, dst1, src0, src1, src2, count);
	} else {
		scale2x_32_mmx_border(dst0, src0, src1, src2, count);
		scale2x_32_mmx_border(dst1, src2, src1, src0, count);
	}
}

/**
 * Scale by a factor of 2x3 a row of pixels of 8 bits.
 * This function operates like scale2x_8_mmx() but with an expansion
 * factor of 2x3 instead of 2x2.
 */
void scale2x3_8_mmx(scale2x_uint8* dst0, scale2x_uint8* dst1, scale2x_uint8* dst2, const scale2x_uint8* src0, const scale2x_uint8* src1, const scale2x_uint8* src2, unsigned count)
{
	if (count % 8 != 0 || count < 16) {
		scale2x3_8_def(dst0, dst1, dst2, src0, src1, src2, count);
	} else {
		scale2x_8_mmx_border(dst0, src0, src1, src2, count);
		scale2x_8_def_center(dst1, src0, src1, src2, count);
		scale2x_8_mmx_border(dst2, src2, src1, src0, count);
	}
}

/**
 * Scale by a factor of 2x3 a row of pixels of 16 bits.
 * This function operates like scale2x_16_mmx() but with an expansion
 * factor of 2x3 instead of 2x2.
 */
void scale2x3_16_mmx(scale2x_uint16* dst0, scale2x_uint16* dst1, scale2x_uint16* dst2, const scale2x_uint16* src0, const scale2x_uint16* src1, const scale2x_uint16* src2, unsigned count)
{
	if (count % 4 != 0 || count < 8) {
		scale2x3_16_def(dst0, dst1, dst2, src0, src1, src2, count);
	} else {
		scale2x_16_mmx_border(dst0, src0, src1, src2, count);
		scale2x_16_def_center(dst1, src0, src1, src2, count);
		scale2x_16_mmx_border(dst2, src2, src1, src0, count);
	}
}

/**
 * Scale by a factor of 2x3 a row of pixels of 32 bits.
 * This function operates like scale2x_32_mmx() but with an expansion
 * factor of 2x3 instead of 2x2.
 */
void scale2x3_32_mmx(scale2x_uint32* dst0, scale2x_uint32* dst1, scale2x_uint32* dst2, const scale2x_uint32* src0, const scale2x_uint32* src1, const scale2x_uint32* src2, unsigned count)
{
	if (count % 2 != 0 || count < 4) {
		scale2x3_32_def(dst0, dst1, dst2, src0, src1, src2, count);
	} else {
		scale2x_32_mmx_border(dst0, src0, src1, src2, count);
		scale2x_32_def_center(dst1, src0, src1, src2, count);
		scale2x_32_mmx_border(dst2, src2, src1, src0, count);
	}
}

/**
 * Scale by a factor of 2x4 a row of pixels of 8 bits.
 * This function operates like scale2x_8_mmx() but with an expansion
 * factor of 2x4 instead of 2x2.
 */
void scale2x4_8_mmx(scale2x_uint8* dst0, scale2x_uint8* dst1, scale2x_uint8* dst2, scale2x_uint8* dst3, const scale2x_uint8* src0, const scale2x_uint8* src1, const scale2x_uint8* src2, unsigned count)
{
	if (count % 8 != 0 || count < 16) {
		scale2x4_8_def(dst0, dst1, dst2, dst3, src0, src1, src2, count);
	} else {
		scale2x_8_mmx_border(dst0, src0, src1, src2, count);
		scale2x_8_def_center(dst1, src0, src1, src2, count);
		scale2x_8_def_center(dst2, src0, src1, src2, count);
		scale2x_8_mmx_border(dst3, src2, src1, src0, count);
	}
}

/**
 * Scale by a factor of 2x4 a row of pixels of 16 bits.
 * This function operates like scale2x_16_mmx() but with an expansion
 * factor of 2x4 instead of 2x2.
 */
void scale2x4_16_mmx(scale2x_uint16* dst0, scale2x_uint16* dst1, scale2x_uint16* dst2, scale2x_uint16* dst3, const scale2x_uint16* src0, const scale2x_uint16* src1, const scale2x_uint16* src2, unsigned count)
{
	if (count % 4 != 0 || count < 8) {
		scale2x4_16_def(dst0, dst1, dst2, dst3, src0, src1, src2, count);
	} else {
		scale2x_16_mmx_border(dst0, src0, src1, src2, count);
		scale2x_16_def_center(dst1, src0, src1, src2, count);
		scale2x_16_def_center(dst2, src0, src1, src2, count);
		scale2x_16_mmx_border(dst3, src2, src1, src0, count);
	}
}

/**
 * Scale by a factor of 2x4 a row of pixels of 32 bits.
 * This function operates like scale2x_32_mmx() but with an expansion
 * factor of 2x4 instead of 2x2.
 */
void scale2x4_32_mmx(scale2x_uint32* dst0, scale2x_uint32* dst1, scale2x_uint32* dst2, scale2x_uint32* dst3, const scale2x_uint32* src0, const scale2x_uint32* src1, const scale2x_uint32* src2, unsigned count)
{
	if (count % 2 != 0 || count < 4) {
		scale2x4_32_def(dst0, dst1, dst2, dst3, src0, src1, src2, count);
	} else {
		scale2x_32_mmx_border(dst0, src0, src1, src2, count);
		scale2x_32_def_center(dst1, src0, src1, src2, count);
		scale2x_32_def_center(dst2, src0, src1, src2, count);
		scale2x_32_mmx_border(dst3, src2, src1, src0, count);
	}
}

#endif