basisu_pvrtc1_4.cpp - external/github.com/BinomialLLC/basis_universal - Git at Google

 // basisu_pvrtc1_4.cpp
 // Copyright (C) 2019 Binomial LLC. All Rights Reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //    http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #include "basisu_pvrtc1_4.h"

 namespace basisu
 {
 	uint32_t pvrtc4_swizzle_uv(uint32_t width, uint32_t height, uint32_t x, uint32_t y)
 	{
 		assert((x < width) && (y < height) && basisu::is_pow2(height) && basisu::is_pow2(width));

 		uint32_t min_d = width, max_v = y;
 		if (height < width)
 		{
 			min_d = height;
 			max_v = x;
 		}

 		// Interleave the XY LSB's
 		uint32_t shift_ofs = 0, swizzled = 0;
 		for (uint32_t s_bit = 1, d_bit = 1; s_bit < min_d; s_bit <<= 1, d_bit <<= 2, ++shift_ofs)
 		{
 			if (y & s_bit) swizzled |= d_bit;
 			if (x & s_bit) swizzled |= (2 * d_bit);
 		}

 		max_v >>= shift_ofs;

 		// OR in the rest of the bits from the largest dimension
 		swizzled |= (max_v << (2 * shift_ofs));

 		return swizzled;
 	}

 	color_rgba pvrtc4_block::get_endpoint(uint32_t endpoint_index, bool unpack) const
 	{
 		assert(endpoint_index < 2);
 		const uint32_t packed = m_endpoints >> (endpoint_index * 16);

 		uint32_t r, g, b, a;
 		if (packed & 0x8000)
 		{
 			// opaque 554 or 555
 			if (!endpoint_index)
 			{
 				r = (packed >> 10) & 31;
 				g = (packed >> 5) & 31;
 				b = (packed >> 1) & 15;

 				if (unpack)
 				{
 					b = (b << 1) | (b >> 3);
 				}
 			}
 			else
 			{
 				r = (packed >> 10) & 31;
 				g = (packed >> 5) & 31;
 				b = packed & 31;
 			}

 			a = unpack ? 255 : 7;
 		}
 		else
 		{
 			// translucent 4433 or 4443
 			if (!endpoint_index)
 			{
 				a = (packed >> 12) & 7;
 				r = (packed >> 8) & 15;
 				g = (packed >> 4) & 15;
 				b = (packed >> 1) & 7;

 				if (unpack)
 				{
 					a = (a << 1);
 					a = (a << 4) | a;

 					r = (r << 1) | (r >> 3);
 					g = (g << 1) | (g >> 3);
 					b = (b << 2) | (b >> 1);
 				}
 			}
 			else
 			{
 				a = (packed >> 12) & 7;
 				r = (packed >> 8) & 15;
 				g = (packed >> 4) & 15;
 				b = packed & 15;

 				if (unpack)
 				{
 					a = (a << 1);
 					a = (a << 4) | a;

 					r = (r << 1) | (r >> 3);
 					g = (g << 1) | (g >> 3);
 					b = (b << 1) | (b >> 3);
 				}
 			}
 		}

 		if (unpack)
 		{
 			r = (r << 3) | (r >> 2);
 			g = (g << 3) | (g >> 2);
 			b = (b << 3) | (b >> 2);
 		}

 		assert((r < 256) && (g < 256) && (b < 256) && (a < 256));

 		return color_rgba(r, g, b, a);
 	}

 	color_rgba pvrtc4_block::get_endpoint_5554(uint32_t endpoint_index) const
 	{
 		assert(endpoint_index < 2);
 		const uint32_t packed = m_endpoints >> (endpoint_index * 16);

 		uint32_t r, g, b, a;
 		if (packed & 0x8000)
 		{
 			// opaque 554 or 555
 			if (!endpoint_index)
 			{
 				r = (packed >> 10) & 31;
 				g = (packed >> 5) & 31;
 				b = (packed >> 1) & 15;

 				b = (b << 1) | (b >> 3);
 			}
 			else
 			{
 				r = (packed >> 10) & 31;
 				g = (packed >> 5) & 31;
 				b = packed & 31;
 			}

 			a = 15;
 		}
 		else
 		{
 			// translucent 4433 or 4443
 			if (!endpoint_index)
 			{
 				a = (packed >> 12) & 7;
 				r = (packed >> 8) & 15;
 				g = (packed >> 4) & 15;
 				b = (packed >> 1) & 7;

 				a = a << 1;

 				r = (r << 1) | (r >> 3);
 				g = (g << 1) | (g >> 3);
 				b = (b << 2) | (b >> 1);
 			}
 			else
 			{
 				a = (packed >> 12) & 7;
 				r = (packed >> 8) & 15;
 				g = (packed >> 4) & 15;
 				b = packed & 15;

 				a = a << 1;

 				r = (r << 1) | (r >> 3);
 				g = (g << 1) | (g >> 3);
 				b = (b << 1) | (b >> 3);
 			}
 		}

 		assert((r < 32) && (g < 32) && (b < 32) && (a < 16));

 		return color_rgba(r, g, b, a);
 	}

 	bool pvrtc4_image::get_interpolated_colors(uint32_t x, uint32_t y, color_rgba* pColors) const
 	{
 		assert((x < m_width) && (y < m_height));

 		int block_x0 = (static_cast<int>(x) - 2) >> 2;
 		int block_x1 = block_x0 + 1;
 		int block_y0 = (static_cast<int>(y) - 2) >> 2;
 		int block_y1 = block_y0 + 1;

 		block_x0 = posmod(block_x0, m_block_width);
 		block_x1 = posmod(block_x1, m_block_width);
 		block_y0 = posmod(block_y0, m_block_height);
 		block_y1 = posmod(block_y1, m_block_height);

 		pColors[0] = interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0));
 		pColors[3] = interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1));

 		if (get_block_uses_transparent_modulation(x >> 2, y >> 2))
 		{
 			for (uint32_t c = 0; c < 4; c++)
 			{
 				uint32_t m = (pColors[0][c] + pColors[3][c]) / 2;
 				pColors[1][c] = static_cast<uint8_t>(m);
 				pColors[2][c] = static_cast<uint8_t>(m);
 			}
 			pColors[2][3] = 0;
 			return true;
 		}

 		for (uint32_t c = 0; c < 4; c++)
 		{
 			pColors[1][c] = static_cast<uint8_t>((pColors[0][c] * 5 + pColors[3][c] * 3) / 8);
 			pColors[2][c] = static_cast<uint8_t>((pColors[0][c] * 3 + pColors[3][c] * 5) / 8);
 		}

 		return false;
 	}

 	color_rgba pvrtc4_image::get_pixel(uint32_t x, uint32_t y, uint32_t m) const
 	{
 		assert((x < m_width) && (y < m_height));

 		int block_x0 = (static_cast<int>(x) - 2) >> 2;
 		int block_x1 = block_x0 + 1;
 		int block_y0 = (static_cast<int>(y) - 2) >> 2;
 		int block_y1 = block_y0 + 1;

 		block_x0 = posmod(block_x0, m_block_width);
 		block_x1 = posmod(block_x1, m_block_width);
 		block_y0 = posmod(block_y0, m_block_height);
 		block_y1 = posmod(block_y1, m_block_height);

 		if (get_block_uses_transparent_modulation(x >> 2, y >> 2))
 		{
 			if (m == 0)
 				return interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0));
 			else if (m == 3)
 				return interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1));

 			color_rgba l(interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0)));
 			color_rgba h(interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1)));

 			return color_rgba((l[0] + h[0]) / 2, (l[1] + h[1]) / 2, (l[2] + h[2]) / 2, (m == 2) ? 0 : (l[3] + h[3]) / 2);
 		}
 		else
 		{
 			if (m == 0)
 				return interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0));
 			else if (m == 3)
 				return interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1));

 			color_rgba l(interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0)));
 			color_rgba h(interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1)));

 			if (m == 2)
 				return color_rgba((l[0] * 3 + h[0] * 5) / 8, (l[1] * 3 + h[1] * 5) / 8, (l[2] * 3 + h[2] * 5) / 8, (l[3] * 3 + h[3] * 5) / 8);
 			else
 				return color_rgba((l[0] * 5 + h[0] * 3) / 8, (l[1] * 5 + h[1] * 3) / 8, (l[2] * 5 + h[2] * 3) / 8, (l[3] * 5 + h[3] * 3) / 8);
 		}
 	}

 } // basisu
	// basisu_pvrtc1_4.cpp
	// Copyright (C) 2019 Binomial LLC. All Rights Reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.
	#include "basisu_pvrtc1_4.h"

	namespace basisu
	{
	uint32_t pvrtc4_swizzle_uv(uint32_t width, uint32_t height, uint32_t x, uint32_t y)
	{
	assert((x < width) && (y < height) && basisu::is_pow2(height) && basisu::is_pow2(width));

	uint32_t min_d = width, max_v = y;
	if (height < width)
	{
	min_d = height;
	max_v = x;
	}

	// Interleave the XY LSB's
	uint32_t shift_ofs = 0, swizzled = 0;
	for (uint32_t s_bit = 1, d_bit = 1; s_bit < min_d; s_bit <<= 1, d_bit <<= 2, ++shift_ofs)
	{
	if (y & s_bit) swizzled \|= d_bit;
	if (x & s_bit) swizzled \|= (2 * d_bit);
	}

	max_v >>= shift_ofs;

	// OR in the rest of the bits from the largest dimension
	swizzled \|= (max_v << (2 * shift_ofs));

	return swizzled;
	}

	color_rgba pvrtc4_block::get_endpoint(uint32_t endpoint_index, bool unpack) const
	{
	assert(endpoint_index < 2);
	const uint32_t packed = m_endpoints >> (endpoint_index * 16);

	uint32_t r, g, b, a;
	if (packed & 0x8000)
	{
	// opaque 554 or 555
	if (!endpoint_index)
	{
	r = (packed >> 10) & 31;
	g = (packed >> 5) & 31;
	b = (packed >> 1) & 15;

	if (unpack)
	{
	b = (b << 1) \| (b >> 3);
	}
	}
	else
	{
	r = (packed >> 10) & 31;
	g = (packed >> 5) & 31;
	b = packed & 31;
	}

	a = unpack ? 255 : 7;
	}
	else
	{
	// translucent 4433 or 4443
	if (!endpoint_index)
	{
	a = (packed >> 12) & 7;
	r = (packed >> 8) & 15;
	g = (packed >> 4) & 15;
	b = (packed >> 1) & 7;

	if (unpack)
	{
	a = (a << 1);
	a = (a << 4) \| a;

	r = (r << 1) \| (r >> 3);
	g = (g << 1) \| (g >> 3);
	b = (b << 2) \| (b >> 1);
	}
	}
	else
	{
	a = (packed >> 12) & 7;
	r = (packed >> 8) & 15;
	g = (packed >> 4) & 15;
	b = packed & 15;

	if (unpack)
	{
	a = (a << 1);
	a = (a << 4) \| a;

	r = (r << 1) \| (r >> 3);
	g = (g << 1) \| (g >> 3);
	b = (b << 1) \| (b >> 3);
	}
	}
	}

	if (unpack)
	{
	r = (r << 3) \| (r >> 2);
	g = (g << 3) \| (g >> 2);
	b = (b << 3) \| (b >> 2);
	}

	assert((r < 256) && (g < 256) && (b < 256) && (a < 256));

	return color_rgba(r, g, b, a);
	}

	color_rgba pvrtc4_block::get_endpoint_5554(uint32_t endpoint_index) const
	{
	assert(endpoint_index < 2);
	const uint32_t packed = m_endpoints >> (endpoint_index * 16);

	uint32_t r, g, b, a;
	if (packed & 0x8000)
	{
	// opaque 554 or 555
	if (!endpoint_index)
	{
	r = (packed >> 10) & 31;
	g = (packed >> 5) & 31;
	b = (packed >> 1) & 15;

	b = (b << 1) \| (b >> 3);
	}
	else
	{
	r = (packed >> 10) & 31;
	g = (packed >> 5) & 31;
	b = packed & 31;
	}

	a = 15;
	}
	else
	{
	// translucent 4433 or 4443
	if (!endpoint_index)
	{
	a = (packed >> 12) & 7;
	r = (packed >> 8) & 15;
	g = (packed >> 4) & 15;
	b = (packed >> 1) & 7;

	a = a << 1;

	r = (r << 1) \| (r >> 3);
	g = (g << 1) \| (g >> 3);
	b = (b << 2) \| (b >> 1);
	}
	else
	{
	a = (packed >> 12) & 7;
	r = (packed >> 8) & 15;
	g = (packed >> 4) & 15;
	b = packed & 15;

	a = a << 1;

	r = (r << 1) \| (r >> 3);
	g = (g << 1) \| (g >> 3);
	b = (b << 1) \| (b >> 3);
	}
	}

	assert((r < 32) && (g < 32) && (b < 32) && (a < 16));

	return color_rgba(r, g, b, a);
	}

	bool pvrtc4_image::get_interpolated_colors(uint32_t x, uint32_t y, color_rgba* pColors) const
	{
	assert((x < m_width) && (y < m_height));

	int block_x0 = (static_cast<int>(x) - 2) >> 2;
	int block_x1 = block_x0 + 1;
	int block_y0 = (static_cast<int>(y) - 2) >> 2;
	int block_y1 = block_y0 + 1;

	block_x0 = posmod(block_x0, m_block_width);
	block_x1 = posmod(block_x1, m_block_width);
	block_y0 = posmod(block_y0, m_block_height);
	block_y1 = posmod(block_y1, m_block_height);

	pColors[0] = interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0));
	pColors[3] = interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1));

	if (get_block_uses_transparent_modulation(x >> 2, y >> 2))
	{
	for (uint32_t c = 0; c < 4; c++)
	{
	uint32_t m = (pColors[0][c] + pColors[3][c]) / 2;
	pColors[1][c] = static_cast<uint8_t>(m);
	pColors[2][c] = static_cast<uint8_t>(m);
	}
	pColors[2][3] = 0;
	return true;
	}

	for (uint32_t c = 0; c < 4; c++)
	{
	pColors[1][c] = static_cast<uint8_t>((pColors[0][c] * 5 + pColors[3][c] * 3) / 8);
	pColors[2][c] = static_cast<uint8_t>((pColors[0][c] * 3 + pColors[3][c] * 5) / 8);
	}

	return false;
	}

	color_rgba pvrtc4_image::get_pixel(uint32_t x, uint32_t y, uint32_t m) const
	{
	assert((x < m_width) && (y < m_height));

	int block_x0 = (static_cast<int>(x) - 2) >> 2;
	int block_x1 = block_x0 + 1;
	int block_y0 = (static_cast<int>(y) - 2) >> 2;
	int block_y1 = block_y0 + 1;

	block_x0 = posmod(block_x0, m_block_width);
	block_x1 = posmod(block_x1, m_block_width);
	block_y0 = posmod(block_y0, m_block_height);
	block_y1 = posmod(block_y1, m_block_height);

	if (get_block_uses_transparent_modulation(x >> 2, y >> 2))
	{
	if (m == 0)
	return interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0));
	else if (m == 3)
	return interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1));

	color_rgba l(interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0)));
	color_rgba h(interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1)));

	return color_rgba((l[0] + h[0]) / 2, (l[1] + h[1]) / 2, (l[2] + h[2]) / 2, (m == 2) ? 0 : (l[3] + h[3]) / 2);
	}
	else
	{
	if (m == 0)
	return interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0));
	else if (m == 3)
	return interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1));

	color_rgba l(interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(0), m_blocks(block_x1, block_y0).get_endpoint_5554(0), m_blocks(block_x0, block_y1).get_endpoint_5554(0), m_blocks(block_x1, block_y1).get_endpoint_5554(0)));
	color_rgba h(interpolate(x, y, m_blocks(block_x0, block_y0).get_endpoint_5554(1), m_blocks(block_x1, block_y0).get_endpoint_5554(1), m_blocks(block_x0, block_y1).get_endpoint_5554(1), m_blocks(block_x1, block_y1).get_endpoint_5554(1)));

	if (m == 2)
	return color_rgba((l[0] * 3 + h[0] * 5) / 8, (l[1] * 3 + h[1] * 5) / 8, (l[2] * 3 + h[2] * 5) / 8, (l[3] * 3 + h[3] * 5) / 8);
	else
	return color_rgba((l[0] * 5 + h[0] * 3) / 8, (l[1] * 5 + h[1] * 3) / 8, (l[2] * 5 + h[2] * 3) / 8, (l[3] * 5 + h[3] * 3) / 8);
	}
	}

	} // basisu