third-party/astc-encoder/Source/astcenc_image.cpp - third_party/android/device/generic/vulkan-cereal - Git at Google

 // SPDX-License-Identifier: Apache-2.0
 // ----------------------------------------------------------------------------
 // Copyright 2011-2022 Arm Limited
 //
 // 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.
 // ----------------------------------------------------------------------------

 /**
  * @brief Functions for creating in-memory ASTC image structures.
  */

 #include <cassert>
 #include <cstring>

 #include "astcenc_internal.h"

 /**
  * @brief Loader pipeline function type for data fetch from memory.
  */
 using pixel_loader = vfloat4(*)(const void*, int);

 /**
  * @brief Loader pipeline function type for swizzling data in a vector.
  */
 using pixel_swizzler = vfloat4(*)(vfloat4, const astcenc_swizzle&);

 /**
  * @brief Loader pipeline function type for converting data in a vector to LNS.
  */
 using pixel_converter = vfloat4(*)(vfloat4, vmask4);

 /**
  * @brief Load a 8-bit UNORM texel from a data array.
  *
  * @param data          The data pointer.
  * @param base_offset   The index offset to the start of the pixel.
  */
 static vfloat4 load_texel_u8(
 	const void* data,
 	int base_offset
 ) {
 	const uint8_t* data8 = static_cast<const uint8_t*>(data);
 	return int_to_float(vint4(data8 + base_offset)) / 255.0f;
 }

 /**
  * @brief Load a 16-bit fp16 texel from a data array.
  *
  * @param data          The data pointer.
  * @param base_offset   The index offset to the start of the pixel.
  */
 static vfloat4 load_texel_f16(
 	const void* data,
 	int base_offset
 ) {
 	const uint16_t* data16 = static_cast<const uint16_t*>(data);
 	int r = data16[base_offset    ];
 	int g = data16[base_offset + 1];
 	int b = data16[base_offset + 2];
 	int a = data16[base_offset + 3];
 	return float16_to_float(vint4(r, g, b, a));
 }

 /**
  * @brief Load a 32-bit float texel from a data array.
  *
  * @param data          The data pointer.
  * @param base_offset   The index offset to the start of the pixel.
  */
 static vfloat4 load_texel_f32(
 	const void* data,
 	int base_offset
 ) {
 	const float* data32 = static_cast<const float*>(data);
 	return vfloat4(data32 + base_offset);
 }

 /**
  * @brief Dummy no-op swizzle function.
  *
  * @param data   The source RGBA vector to swizzle.
  * @param swz    The swizzle to use.
  */
 static vfloat4 swz_texel_skip(
 	vfloat4 data,
 	const astcenc_swizzle& swz
 ) {
 	(void)swz;
 	return data;
 }

 /**
  * @brief Swizzle a texel into a new arrangement.
  *
  * @param data   The source RGBA vector to swizzle.
  * @param swz    The swizzle to use.
  */
 static vfloat4 swz_texel(
 	vfloat4 data,
 	const astcenc_swizzle& swz
 ) {
 	alignas(16) float datas[6];

 	storea(data, datas);
 	datas[ASTCENC_SWZ_0] = 0.0f;
 	datas[ASTCENC_SWZ_1] = 1.0f;

 	return vfloat4(datas[swz.r], datas[swz.g], datas[swz.b], datas[swz.a]);
 }

 /**
  * @brief Encode a texel that is entirely LDR linear.
  *
  * @param data       The RGBA data to encode.
  * @param lns_mask   The mask for the HDR channels than need LNS encoding.
  */
 static vfloat4 encode_texel_unorm(
 	vfloat4 data,
 	vmask4 lns_mask
 ) {
 	(void)lns_mask;
 	return data * 65535.0f;
 }

 /**
  * @brief Encode a texel that includes at least some HDR LNS texels.
  *
  * @param data       The RGBA data to encode.
  * @param lns_mask   The mask for the HDR channels than need LNS encoding.
  */
 static vfloat4 encode_texel_lns(
 	vfloat4 data,
 	vmask4 lns_mask
 ) {
 	vfloat4 datav_unorm = data * 65535.0f;
 	vfloat4 datav_lns = float_to_lns(data);
 	return select(datav_unorm, datav_lns, lns_mask);
 }

 /* See header for documentation. */
 void load_image_block(
 	astcenc_profile decode_mode,
 	const astcenc_image& img,
 	image_block& blk,
 	const block_size_descriptor& bsd,
 	unsigned int xpos,
 	unsigned int ypos,
 	unsigned int zpos,
 	const astcenc_swizzle& swz
 ) {
 	unsigned int xsize = img.dim_x;
 	unsigned int ysize = img.dim_y;
 	unsigned int zsize = img.dim_z;

 	blk.xpos = xpos;
 	blk.ypos = ypos;
 	blk.zpos = zpos;

 	// True if any non-identity swizzle
 	bool needs_swz = (swz.r != ASTCENC_SWZ_R) || (swz.g != ASTCENC_SWZ_G) ||
 	                 (swz.b != ASTCENC_SWZ_B) || (swz.a != ASTCENC_SWZ_A);

 	int idx = 0;

 	vfloat4 data_min(1e38f);
 	vfloat4 data_mean(0.0f);
 	vfloat4 data_mean_scale(1.0f / static_cast<float>(bsd.texel_count));
 	vfloat4 data_max(-1e38f);
 	vmask4 grayscalev(true);

 	// This works because we impose the same choice everywhere during encode
 	uint8_t rgb_lns = (decode_mode == ASTCENC_PRF_HDR) ||
 	                  (decode_mode == ASTCENC_PRF_HDR_RGB_LDR_A) ? 1 : 0;
 	uint8_t a_lns = decode_mode == ASTCENC_PRF_HDR ? 1 : 0;
 	vint4 use_lns(rgb_lns, rgb_lns, rgb_lns, a_lns);
 	vmask4 lns_mask = use_lns != vint4::zero();

 	// Set up the function pointers for loading pipeline as needed
 	pixel_loader loader = load_texel_u8;
 	if (img.data_type == ASTCENC_TYPE_F16)
 	{
 		loader = load_texel_f16;
 	}
 	else if  (img.data_type == ASTCENC_TYPE_F32)
 	{
 		loader = load_texel_f32;
 	}

 	pixel_swizzler swizzler = swz_texel_skip;
 	if (needs_swz)
 	{
 		swizzler = swz_texel;
 	}

 	pixel_converter converter = encode_texel_unorm;
 	if (any(lns_mask))
 	{
 		converter = encode_texel_lns;
 	}

 	for (unsigned int z = 0; z < bsd.zdim; z++)
 	{
 		unsigned int zi = astc::min(zpos + z, zsize - 1);
 		void* plane = img.data[zi];

 		for (unsigned int y = 0; y < bsd.ydim; y++)
 		{
 			unsigned int yi = astc::min(ypos + y, ysize - 1);

 			for (unsigned int x = 0; x < bsd.xdim; x++)
 			{
 				unsigned int xi = astc::min(xpos + x, xsize - 1);

 				vfloat4 datav = loader(plane, (4 * xsize * yi) + (4 * xi));
 				datav = swizzler(datav, swz);
 				datav = converter(datav, lns_mask);

 				// Compute block metadata
 				data_min = min(data_min, datav);
 				data_mean += datav * data_mean_scale;
 				data_max = max(data_max, datav);

 				grayscalev = grayscalev & (datav.swz<0,0,0,0>() == datav.swz<1,1,2,2>());

 				blk.data_r[idx] = datav.lane<0>();
 				blk.data_g[idx] = datav.lane<1>();
 				blk.data_b[idx] = datav.lane<2>();
 				blk.data_a[idx] = datav.lane<3>();

 				blk.rgb_lns[idx] = rgb_lns;
 				blk.alpha_lns[idx] = a_lns;

 				idx++;
 			}
 		}
 	}

 	// Reverse the encoding so we store origin block in the original format
 	vfloat4 data_enc = blk.texel(0);
 	vfloat4 data_enc_unorm = data_enc / 65535.0f;
 	vfloat4 data_enc_lns = vfloat4::zero();

 	if (rgb_lns || a_lns)
 	{
 		data_enc_lns = float16_to_float(lns_to_sf16(float_to_int(data_enc)));
 	}

 	blk.origin_texel = select(data_enc_unorm, data_enc_lns, lns_mask);

 	// Store block metadata
 	blk.data_min = data_min;
 	blk.data_mean = data_mean;
 	blk.data_max = data_max;
 	blk.grayscale = all(grayscalev);
 }

 /* See header for documentation. */
 void load_image_block_fast_ldr(
 	astcenc_profile decode_mode,
 	const astcenc_image& img,
 	image_block& blk,
 	const block_size_descriptor& bsd,
 	unsigned int xpos,
 	unsigned int ypos,
 	unsigned int zpos,
 	const astcenc_swizzle& swz
 ) {
 	(void)swz;
 	(void)decode_mode;

 	unsigned int xsize = img.dim_x;
 	unsigned int ysize = img.dim_y;

 	blk.xpos = xpos;
 	blk.ypos = ypos;
 	blk.zpos = zpos;

 	vfloat4 data_min(1e38f);
 	vfloat4 data_mean = vfloat4::zero();
 	vfloat4 data_max(-1e38f);
 	vmask4 grayscalev(true);
 	int idx = 0;

 	const uint8_t* plane = static_cast<const uint8_t*>(img.data[0]);
 	for (unsigned int y = ypos; y < ypos + bsd.ydim; y++)
 	{
 		unsigned int yi = astc::min(y, ysize - 1);

 		for (unsigned int x = xpos; x < xpos + bsd.xdim; x++)
 		{
 			unsigned int xi = astc::min(x, xsize - 1);

 			vint4 datavi = vint4(plane + (4 * xsize * yi) + (4 * xi));
 			vfloat4 datav = int_to_float(datavi) * (65535.0f / 255.0f);

 			// Compute block metadata
 			data_min = min(data_min, datav);
 			data_mean += datav;
 			data_max = max(data_max, datav);

 			grayscalev = grayscalev & (datav.swz<0,0,0,0>() == datav.swz<1,1,2,2>());

 			blk.data_r[idx] = datav.lane<0>();
 			blk.data_g[idx] = datav.lane<1>();
 			blk.data_b[idx] = datav.lane<2>();
 			blk.data_a[idx] = datav.lane<3>();

 			idx++;
 		}
 	}

 	// Reverse the encoding so we store origin block in the original format
 	blk.origin_texel = blk.texel(0) / 65535.0f;

 	// Store block metadata
 	blk.rgb_lns[0] = 0;
 	blk.alpha_lns[0] = 0;
 	blk.data_min = data_min;
 	blk.data_mean = data_mean / static_cast<float>(bsd.texel_count);
 	blk.data_max = data_max;
 	blk.grayscale = all(grayscalev);
 }

 /* See header for documentation. */
 void store_image_block(
 	astcenc_image& img,
 	const image_block& blk,
 	const block_size_descriptor& bsd,
 	unsigned int xpos,
 	unsigned int ypos,
 	unsigned int zpos,
 	const astcenc_swizzle& swz
 ) {
 	unsigned int x_size = img.dim_x;
 	unsigned int x_start = xpos;
 	unsigned int x_end = astc::min(x_size, xpos + bsd.xdim);
 	unsigned int x_count = x_end - x_start;
 	unsigned int x_nudge = bsd.xdim - x_count;

 	unsigned int y_size = img.dim_y;
 	unsigned int y_start = ypos;
 	unsigned int y_end = astc::min(y_size, ypos + bsd.ydim);
 	unsigned int y_count = y_end - y_start;
 	unsigned int y_nudge = (bsd.ydim - y_count) * bsd.xdim;

 	unsigned int z_size = img.dim_z;
 	unsigned int z_start = zpos;
 	unsigned int z_end = astc::min(z_size, zpos + bsd.zdim);

 	// True if any non-identity swizzle
 	bool needs_swz = (swz.r != ASTCENC_SWZ_R) || (swz.g != ASTCENC_SWZ_G) ||
 	                 (swz.b != ASTCENC_SWZ_B) || (swz.a != ASTCENC_SWZ_A);

 	// True if any swizzle uses Z reconstruct
 	bool needs_z = (swz.r == ASTCENC_SWZ_Z) || (swz.g == ASTCENC_SWZ_Z) ||
 	               (swz.b == ASTCENC_SWZ_Z) || (swz.a == ASTCENC_SWZ_Z);

 	int idx = 0;
 	if (img.data_type == ASTCENC_TYPE_U8)
 	{
 		for (unsigned int z = z_start; z < z_end; z++)
 		{
 			// Fetch the image plane
 			uint8_t* data8 = static_cast<uint8_t*>(img.data[z]);

 			for (unsigned int y = y_start; y < y_end; y++)
 			{
 				uint8_t* data8_row = data8 + (4 * x_size * y) + (4 * x_start);

 				for (unsigned int x = 0; x < x_count; x += ASTCENC_SIMD_WIDTH)
 				{
 					unsigned int max_texels = ASTCENC_SIMD_WIDTH;
 					unsigned int used_texels = astc::min(x_count - x, max_texels);

 					// Unaligned load as rows are not always SIMD_WIDTH long
 					vfloat data_r(blk.data_r + idx);
 					vfloat data_g(blk.data_g + idx);
 					vfloat data_b(blk.data_b + idx);
 					vfloat data_a(blk.data_a + idx);

 					vint data_ri = float_to_int_rtn(min(data_r, 1.0f) * 255.0f);
 					vint data_gi = float_to_int_rtn(min(data_g, 1.0f) * 255.0f);
 					vint data_bi = float_to_int_rtn(min(data_b, 1.0f) * 255.0f);
 					vint data_ai = float_to_int_rtn(min(data_a, 1.0f) * 255.0f);

 					if (needs_swz)
 					{
 						vint swizzle_table[7];
 						swizzle_table[ASTCENC_SWZ_0] = vint(0);
 						swizzle_table[ASTCENC_SWZ_1] = vint(255);
 						swizzle_table[ASTCENC_SWZ_R] = data_ri;
 						swizzle_table[ASTCENC_SWZ_G] = data_gi;
 						swizzle_table[ASTCENC_SWZ_B] = data_bi;
 						swizzle_table[ASTCENC_SWZ_A] = data_ai;

 						if (needs_z)
 						{
 							vfloat data_x = (data_r * vfloat(2.0f)) - vfloat(1.0f);
 							vfloat data_y = (data_a * vfloat(2.0f)) - vfloat(1.0f);
 							vfloat data_z = vfloat(1.0f) - (data_x * data_x) - (data_y * data_y);
 							data_z = max(data_z, 0.0f);
 							data_z = (sqrt(data_z) * vfloat(0.5f)) + vfloat(0.5f);

 							swizzle_table[ASTCENC_SWZ_Z] = float_to_int_rtn(min(data_z, 1.0f) * 255.0f);
 						}

 						data_ri = swizzle_table[swz.r];
 						data_gi = swizzle_table[swz.g];
 						data_bi = swizzle_table[swz.b];
 						data_ai = swizzle_table[swz.a];
 					}

 					// Errors are NaN encoded - convert to magenta error color
 					// Branch is OK here - it is almost never true so predicts well
 					vmask nan_mask = data_r != data_r;
 					if (any(nan_mask))
 					{
 						data_ri = select(data_ri, vint(0xFF), nan_mask);
 						data_gi = select(data_gi, vint(0x00), nan_mask);
 						data_bi = select(data_bi, vint(0xFF), nan_mask);
 						data_ai = select(data_ai, vint(0xFF), nan_mask);
 					}

 					vint data_rgbai = interleave_rgba8(data_ri, data_gi, data_bi, data_ai);
 					vmask store_mask = vint::lane_id() < vint(used_texels);
 					store_lanes_masked(reinterpret_cast<int*>(data8_row), data_rgbai, store_mask);

 					data8_row += ASTCENC_SIMD_WIDTH * 4;
 					idx += used_texels;
 				}
 				idx += x_nudge;
 			}
 			idx += y_nudge;
 		}
 	}
 	else if (img.data_type == ASTCENC_TYPE_F16)
 	{
 		for (unsigned int z = z_start; z < z_end; z++)
 		{
 			// Fetch the image plane
 			uint16_t* data16 = static_cast<uint16_t*>(img.data[z]);

 			for (unsigned int y = y_start; y < y_end; y++)
 			{
 				uint16_t* data16_row = data16 + (4 * x_size * y) + (4 * x_start);

 				for (unsigned int x = 0; x < x_count; x++)
 				{
 					vint4 color;

 					// NaNs are handled inline - no need to special case
 					if (needs_swz)
 					{
 						float data[7];
 						data[ASTCENC_SWZ_0] = 0.0f;
 						data[ASTCENC_SWZ_1] = 1.0f;
 						data[ASTCENC_SWZ_R] = blk.data_r[idx];
 						data[ASTCENC_SWZ_G] = blk.data_g[idx];
 						data[ASTCENC_SWZ_B] = blk.data_b[idx];
 						data[ASTCENC_SWZ_A] = blk.data_a[idx];

 						if (needs_z)
 						{
 							float xN = (data[0] * 2.0f) - 1.0f;
 							float yN = (data[3] * 2.0f) - 1.0f;
 							float zN = 1.0f - xN * xN - yN * yN;
 							if (zN < 0.0f)
 							{
 								zN = 0.0f;
 							}
 							data[ASTCENC_SWZ_Z] = (astc::sqrt(zN) * 0.5f) + 0.5f;
 						}

 						vfloat4 colorf(data[swz.r], data[swz.g], data[swz.b], data[swz.a]);
 						color = float_to_float16(colorf);
 					}
 					else
 					{
 						vfloat4 colorf = blk.texel(idx);
 						color = float_to_float16(colorf);
 					}

 					// TODO: Vectorize with store N shorts?
 					data16_row[0] = static_cast<uint16_t>(color.lane<0>());
 					data16_row[1] = static_cast<uint16_t>(color.lane<1>());
 					data16_row[2] = static_cast<uint16_t>(color.lane<2>());
 					data16_row[3] = static_cast<uint16_t>(color.lane<3>());
 					data16_row += 4;
 					idx++;
 				}
 				idx += x_nudge;
 			}
 			idx += y_nudge;
 		}
 	}
 	else // if (img.data_type == ASTCENC_TYPE_F32)
 	{
 		assert(img.data_type == ASTCENC_TYPE_F32);

 		for (unsigned int z = z_start; z < z_end; z++)
 		{
 			// Fetch the image plane
 			float* data32 = static_cast<float*>(img.data[z]);

 			for (unsigned int y = y_start; y < y_end; y++)
 			{
 				float* data32_row = data32 + (4 * x_size * y) + (4 * x_start);

 				for (unsigned int x = 0; x < x_count; x++)
 				{
 					vfloat4 color = blk.texel(idx);

 					// NaNs are handled inline - no need to special case
 					if (needs_swz)
 					{
 						float data[7];
 						data[ASTCENC_SWZ_0] = 0.0f;
 						data[ASTCENC_SWZ_1] = 1.0f;
 						data[ASTCENC_SWZ_R] = color.lane<0>();
 						data[ASTCENC_SWZ_G] = color.lane<1>();
 						data[ASTCENC_SWZ_B] = color.lane<2>();
 						data[ASTCENC_SWZ_A] = color.lane<3>();

 						if (needs_z)
 						{
 							float xN = (data[0] * 2.0f) - 1.0f;
 							float yN = (data[3] * 2.0f) - 1.0f;
 							float zN = 1.0f - xN * xN - yN * yN;
 							if (zN < 0.0f)
 							{
 								zN = 0.0f;
 							}
 							data[ASTCENC_SWZ_Z] = (astc::sqrt(zN) * 0.5f) + 0.5f;
 						}

 						color = vfloat4(data[swz.r], data[swz.g], data[swz.b], data[swz.a]);
 					}

 					store(color, data32_row);
 					data32_row += 4;
 					idx++;
 				}
 				idx += x_nudge;
 			}
 			idx += y_nudge;
 		}
 	}
 }
	// SPDX-License-Identifier: Apache-2.0
	// ----------------------------------------------------------------------------
	// Copyright 2011-2022 Arm Limited
	//
	// 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.
	// ----------------------------------------------------------------------------

	/**
	* @brief Functions for creating in-memory ASTC image structures.
	*/

	#include <cassert>
	#include <cstring>

	#include "astcenc_internal.h"

	/**
	* @brief Loader pipeline function type for data fetch from memory.
	*/
	using pixel_loader = vfloat4()(const void, int);

	/**
	* @brief Loader pipeline function type for swizzling data in a vector.
	*/
	using pixel_swizzler = vfloat4(*)(vfloat4, const astcenc_swizzle&);

	/**
	* @brief Loader pipeline function type for converting data in a vector to LNS.
	*/
	using pixel_converter = vfloat4(*)(vfloat4, vmask4);

	/**
	* @brief Load a 8-bit UNORM texel from a data array.
	*
	* @param data The data pointer.
	* @param base_offset The index offset to the start of the pixel.
	*/
	static vfloat4 load_texel_u8(
	const void* data,
	int base_offset
	) {
	const uint8_t* data8 = static_cast<const uint8_t*>(data);
	return int_to_float(vint4(data8 + base_offset)) / 255.0f;
	}

	/**
	* @brief Load a 16-bit fp16 texel from a data array.
	*
	* @param data The data pointer.
	* @param base_offset The index offset to the start of the pixel.
	*/
	static vfloat4 load_texel_f16(
	const void* data,
	int base_offset
	) {
	const uint16_t* data16 = static_cast<const uint16_t*>(data);
	int r = data16[base_offset ];
	int g = data16[base_offset + 1];
	int b = data16[base_offset + 2];
	int a = data16[base_offset + 3];
	return float16_to_float(vint4(r, g, b, a));
	}

	/**
	* @brief Load a 32-bit float texel from a data array.
	*
	* @param data The data pointer.
	* @param base_offset The index offset to the start of the pixel.
	*/
	static vfloat4 load_texel_f32(
	const void* data,
	int base_offset
	) {
	const float* data32 = static_cast<const float*>(data);
	return vfloat4(data32 + base_offset);
	}

	/**
	* @brief Dummy no-op swizzle function.
	*
	* @param data The source RGBA vector to swizzle.
	* @param swz The swizzle to use.
	*/
	static vfloat4 swz_texel_skip(
	vfloat4 data,
	const astcenc_swizzle& swz
	) {
	(void)swz;
	return data;
	}

	/**
	* @brief Swizzle a texel into a new arrangement.
	*
	* @param data The source RGBA vector to swizzle.
	* @param swz The swizzle to use.
	*/
	static vfloat4 swz_texel(
	vfloat4 data,
	const astcenc_swizzle& swz
	) {
	alignas(16) float datas[6];

	storea(data, datas);
	datas[ASTCENC_SWZ_0] = 0.0f;
	datas[ASTCENC_SWZ_1] = 1.0f;

	return vfloat4(datas[swz.r], datas[swz.g], datas[swz.b], datas[swz.a]);
	}

	/**
	* @brief Encode a texel that is entirely LDR linear.
	*
	* @param data The RGBA data to encode.
	* @param lns_mask The mask for the HDR channels than need LNS encoding.
	*/
	static vfloat4 encode_texel_unorm(
	vfloat4 data,
	vmask4 lns_mask
	) {
	(void)lns_mask;
	return data * 65535.0f;
	}

	/**
	* @brief Encode a texel that includes at least some HDR LNS texels.
	*
	* @param data The RGBA data to encode.
	* @param lns_mask The mask for the HDR channels than need LNS encoding.
	*/
	static vfloat4 encode_texel_lns(
	vfloat4 data,
	vmask4 lns_mask
	) {
	vfloat4 datav_unorm = data * 65535.0f;
	vfloat4 datav_lns = float_to_lns(data);
	return select(datav_unorm, datav_lns, lns_mask);
	}

	/* See header for documentation. */
	void load_image_block(
	astcenc_profile decode_mode,
	const astcenc_image& img,
	image_block& blk,
	const block_size_descriptor& bsd,
	unsigned int xpos,
	unsigned int ypos,
	unsigned int zpos,
	const astcenc_swizzle& swz
	) {
	unsigned int xsize = img.dim_x;
	unsigned int ysize = img.dim_y;
	unsigned int zsize = img.dim_z;

	blk.xpos = xpos;
	blk.ypos = ypos;
	blk.zpos = zpos;

	// True if any non-identity swizzle
	bool needs_swz = (swz.r != ASTCENC_SWZ_R) \|\| (swz.g != ASTCENC_SWZ_G) \|\|
	(swz.b != ASTCENC_SWZ_B) \|\| (swz.a != ASTCENC_SWZ_A);

	int idx = 0;

	vfloat4 data_min(1e38f);
	vfloat4 data_mean(0.0f);
	vfloat4 data_mean_scale(1.0f / static_cast<float>(bsd.texel_count));
	vfloat4 data_max(-1e38f);
	vmask4 grayscalev(true);

	// This works because we impose the same choice everywhere during encode
	uint8_t rgb_lns = (decode_mode == ASTCENC_PRF_HDR) \|\|
	(decode_mode == ASTCENC_PRF_HDR_RGB_LDR_A) ? 1 : 0;
	uint8_t a_lns = decode_mode == ASTCENC_PRF_HDR ? 1 : 0;
	vint4 use_lns(rgb_lns, rgb_lns, rgb_lns, a_lns);
	vmask4 lns_mask = use_lns != vint4::zero();

	// Set up the function pointers for loading pipeline as needed
	pixel_loader loader = load_texel_u8;
	if (img.data_type == ASTCENC_TYPE_F16)
	{
	loader = load_texel_f16;
	}
	else if (img.data_type == ASTCENC_TYPE_F32)
	{
	loader = load_texel_f32;
	}

	pixel_swizzler swizzler = swz_texel_skip;
	if (needs_swz)
	{
	swizzler = swz_texel;
	}

	pixel_converter converter = encode_texel_unorm;
	if (any(lns_mask))
	{
	converter = encode_texel_lns;
	}

	for (unsigned int z = 0; z < bsd.zdim; z++)
	{
	unsigned int zi = astc::min(zpos + z, zsize - 1);
	void* plane = img.data[zi];

	for (unsigned int y = 0; y < bsd.ydim; y++)
	{
	unsigned int yi = astc::min(ypos + y, ysize - 1);

	for (unsigned int x = 0; x < bsd.xdim; x++)
	{
	unsigned int xi = astc::min(xpos + x, xsize - 1);

	vfloat4 datav = loader(plane, (4 * xsize * yi) + (4 * xi));
	datav = swizzler(datav, swz);
	datav = converter(datav, lns_mask);

	// Compute block metadata
	data_min = min(data_min, datav);
	data_mean += datav * data_mean_scale;
	data_max = max(data_max, datav);

	grayscalev = grayscalev & (datav.swz<0,0,0,0>() == datav.swz<1,1,2,2>());

	blk.data_r[idx] = datav.lane<0>();
	blk.data_g[idx] = datav.lane<1>();
	blk.data_b[idx] = datav.lane<2>();
	blk.data_a[idx] = datav.lane<3>();

	blk.rgb_lns[idx] = rgb_lns;
	blk.alpha_lns[idx] = a_lns;

	idx++;
	}
	}
	}

	// Reverse the encoding so we store origin block in the original format
	vfloat4 data_enc = blk.texel(0);
	vfloat4 data_enc_unorm = data_enc / 65535.0f;
	vfloat4 data_enc_lns = vfloat4::zero();

	if (rgb_lns \|\| a_lns)
	{
	data_enc_lns = float16_to_float(lns_to_sf16(float_to_int(data_enc)));
	}

	blk.origin_texel = select(data_enc_unorm, data_enc_lns, lns_mask);

	// Store block metadata
	blk.data_min = data_min;
	blk.data_mean = data_mean;
	blk.data_max = data_max;
	blk.grayscale = all(grayscalev);
	}

	/* See header for documentation. */
	void load_image_block_fast_ldr(
	astcenc_profile decode_mode,
	const astcenc_image& img,
	image_block& blk,
	const block_size_descriptor& bsd,
	unsigned int xpos,
	unsigned int ypos,
	unsigned int zpos,
	const astcenc_swizzle& swz
	) {
	(void)swz;
	(void)decode_mode;

	unsigned int xsize = img.dim_x;
	unsigned int ysize = img.dim_y;

	blk.xpos = xpos;
	blk.ypos = ypos;
	blk.zpos = zpos;

	vfloat4 data_min(1e38f);
	vfloat4 data_mean = vfloat4::zero();
	vfloat4 data_max(-1e38f);
	vmask4 grayscalev(true);
	int idx = 0;

	const uint8_t* plane = static_cast<const uint8_t*>(img.data[0]);
	for (unsigned int y = ypos; y < ypos + bsd.ydim; y++)
	{
	unsigned int yi = astc::min(y, ysize - 1);

	for (unsigned int x = xpos; x < xpos + bsd.xdim; x++)
	{
	unsigned int xi = astc::min(x, xsize - 1);

	vint4 datavi = vint4(plane + (4 * xsize * yi) + (4 * xi));
	vfloat4 datav = int_to_float(datavi) * (65535.0f / 255.0f);

	// Compute block metadata
	data_min = min(data_min, datav);
	data_mean += datav;
	data_max = max(data_max, datav);

	grayscalev = grayscalev & (datav.swz<0,0,0,0>() == datav.swz<1,1,2,2>());

	blk.data_r[idx] = datav.lane<0>();
	blk.data_g[idx] = datav.lane<1>();
	blk.data_b[idx] = datav.lane<2>();
	blk.data_a[idx] = datav.lane<3>();

	idx++;
	}
	}

	// Reverse the encoding so we store origin block in the original format
	blk.origin_texel = blk.texel(0) / 65535.0f;

	// Store block metadata
	blk.rgb_lns[0] = 0;
	blk.alpha_lns[0] = 0;
	blk.data_min = data_min;
	blk.data_mean = data_mean / static_cast<float>(bsd.texel_count);
	blk.data_max = data_max;
	blk.grayscale = all(grayscalev);
	}

	/* See header for documentation. */
	void store_image_block(
	astcenc_image& img,
	const image_block& blk,
	const block_size_descriptor& bsd,
	unsigned int xpos,
	unsigned int ypos,
	unsigned int zpos,
	const astcenc_swizzle& swz
	) {
	unsigned int x_size = img.dim_x;
	unsigned int x_start = xpos;
	unsigned int x_end = astc::min(x_size, xpos + bsd.xdim);
	unsigned int x_count = x_end - x_start;
	unsigned int x_nudge = bsd.xdim - x_count;

	unsigned int y_size = img.dim_y;
	unsigned int y_start = ypos;
	unsigned int y_end = astc::min(y_size, ypos + bsd.ydim);
	unsigned int y_count = y_end - y_start;
	unsigned int y_nudge = (bsd.ydim - y_count) * bsd.xdim;

	unsigned int z_size = img.dim_z;
	unsigned int z_start = zpos;
	unsigned int z_end = astc::min(z_size, zpos + bsd.zdim);

	// True if any non-identity swizzle
	bool needs_swz = (swz.r != ASTCENC_SWZ_R) \|\| (swz.g != ASTCENC_SWZ_G) \|\|
	(swz.b != ASTCENC_SWZ_B) \|\| (swz.a != ASTCENC_SWZ_A);

	// True if any swizzle uses Z reconstruct
	bool needs_z = (swz.r == ASTCENC_SWZ_Z) \|\| (swz.g == ASTCENC_SWZ_Z) \|\|
	(swz.b == ASTCENC_SWZ_Z) \|\| (swz.a == ASTCENC_SWZ_Z);

	int idx = 0;
	if (img.data_type == ASTCENC_TYPE_U8)
	{
	for (unsigned int z = z_start; z < z_end; z++)
	{
	// Fetch the image plane
	uint8_t* data8 = static_cast<uint8_t*>(img.data[z]);

	for (unsigned int y = y_start; y < y_end; y++)
	{
	uint8_t* data8_row = data8 + (4 * x_size * y) + (4 * x_start);

	for (unsigned int x = 0; x < x_count; x += ASTCENC_SIMD_WIDTH)
	{
	unsigned int max_texels = ASTCENC_SIMD_WIDTH;
	unsigned int used_texels = astc::min(x_count - x, max_texels);

	// Unaligned load as rows are not always SIMD_WIDTH long
	vfloat data_r(blk.data_r + idx);
	vfloat data_g(blk.data_g + idx);
	vfloat data_b(blk.data_b + idx);
	vfloat data_a(blk.data_a + idx);

	vint data_ri = float_to_int_rtn(min(data_r, 1.0f) * 255.0f);
	vint data_gi = float_to_int_rtn(min(data_g, 1.0f) * 255.0f);
	vint data_bi = float_to_int_rtn(min(data_b, 1.0f) * 255.0f);
	vint data_ai = float_to_int_rtn(min(data_a, 1.0f) * 255.0f);

	if (needs_swz)
	{
	vint swizzle_table[7];
	swizzle_table[ASTCENC_SWZ_0] = vint(0);
	swizzle_table[ASTCENC_SWZ_1] = vint(255);
	swizzle_table[ASTCENC_SWZ_R] = data_ri;
	swizzle_table[ASTCENC_SWZ_G] = data_gi;
	swizzle_table[ASTCENC_SWZ_B] = data_bi;
	swizzle_table[ASTCENC_SWZ_A] = data_ai;

	if (needs_z)
	{
	vfloat data_x = (data_r * vfloat(2.0f)) - vfloat(1.0f);
	vfloat data_y = (data_a * vfloat(2.0f)) - vfloat(1.0f);
	vfloat data_z = vfloat(1.0f) - (data_x * data_x) - (data_y * data_y);
	data_z = max(data_z, 0.0f);
	data_z = (sqrt(data_z) * vfloat(0.5f)) + vfloat(0.5f);

	swizzle_table[ASTCENC_SWZ_Z] = float_to_int_rtn(min(data_z, 1.0f) * 255.0f);
	}

	data_ri = swizzle_table[swz.r];
	data_gi = swizzle_table[swz.g];
	data_bi = swizzle_table[swz.b];
	data_ai = swizzle_table[swz.a];
	}

	// Errors are NaN encoded - convert to magenta error color
	// Branch is OK here - it is almost never true so predicts well
	vmask nan_mask = data_r != data_r;
	if (any(nan_mask))
	{
	data_ri = select(data_ri, vint(0xFF), nan_mask);
	data_gi = select(data_gi, vint(0x00), nan_mask);
	data_bi = select(data_bi, vint(0xFF), nan_mask);
	data_ai = select(data_ai, vint(0xFF), nan_mask);
	}

	vint data_rgbai = interleave_rgba8(data_ri, data_gi, data_bi, data_ai);
	vmask store_mask = vint::lane_id() < vint(used_texels);
	store_lanes_masked(reinterpret_cast<int*>(data8_row), data_rgbai, store_mask);

	data8_row += ASTCENC_SIMD_WIDTH * 4;
	idx += used_texels;
	}
	idx += x_nudge;
	}
	idx += y_nudge;
	}
	}
	else if (img.data_type == ASTCENC_TYPE_F16)
	{
	for (unsigned int z = z_start; z < z_end; z++)
	{
	// Fetch the image plane
	uint16_t* data16 = static_cast<uint16_t*>(img.data[z]);

	for (unsigned int y = y_start; y < y_end; y++)
	{
	uint16_t* data16_row = data16 + (4 * x_size * y) + (4 * x_start);

	for (unsigned int x = 0; x < x_count; x++)
	{
	vint4 color;

	// NaNs are handled inline - no need to special case
	if (needs_swz)
	{
	float data[7];
	data[ASTCENC_SWZ_0] = 0.0f;
	data[ASTCENC_SWZ_1] = 1.0f;
	data[ASTCENC_SWZ_R] = blk.data_r[idx];
	data[ASTCENC_SWZ_G] = blk.data_g[idx];
	data[ASTCENC_SWZ_B] = blk.data_b[idx];
	data[ASTCENC_SWZ_A] = blk.data_a[idx];

	if (needs_z)
	{
	float xN = (data[0] * 2.0f) - 1.0f;
	float yN = (data[3] * 2.0f) - 1.0f;
	float zN = 1.0f - xN * xN - yN * yN;
	if (zN < 0.0f)
	{
	zN = 0.0f;
	}
	data[ASTCENC_SWZ_Z] = (astc::sqrt(zN) * 0.5f) + 0.5f;
	}

	vfloat4 colorf(data[swz.r], data[swz.g], data[swz.b], data[swz.a]);
	color = float_to_float16(colorf);
	}
	else
	{
	vfloat4 colorf = blk.texel(idx);
	color = float_to_float16(colorf);
	}

	// TODO: Vectorize with store N shorts?
	data16_row[0] = static_cast<uint16_t>(color.lane<0>());
	data16_row[1] = static_cast<uint16_t>(color.lane<1>());
	data16_row[2] = static_cast<uint16_t>(color.lane<2>());
	data16_row[3] = static_cast<uint16_t>(color.lane<3>());
	data16_row += 4;
	idx++;
	}
	idx += x_nudge;
	}
	idx += y_nudge;
	}
	}
	else // if (img.data_type == ASTCENC_TYPE_F32)
	{
	assert(img.data_type == ASTCENC_TYPE_F32);

	for (unsigned int z = z_start; z < z_end; z++)
	{
	// Fetch the image plane
	float* data32 = static_cast<float*>(img.data[z]);

	for (unsigned int y = y_start; y < y_end; y++)
	{
	float* data32_row = data32 + (4 * x_size * y) + (4 * x_start);

	for (unsigned int x = 0; x < x_count; x++)
	{
	vfloat4 color = blk.texel(idx);

	// NaNs are handled inline - no need to special case
	if (needs_swz)
	{
	float data[7];
	data[ASTCENC_SWZ_0] = 0.0f;
	data[ASTCENC_SWZ_1] = 1.0f;
	data[ASTCENC_SWZ_R] = color.lane<0>();
	data[ASTCENC_SWZ_G] = color.lane<1>();
	data[ASTCENC_SWZ_B] = color.lane<2>();
	data[ASTCENC_SWZ_A] = color.lane<3>();

	if (needs_z)
	{
	float xN = (data[0] * 2.0f) - 1.0f;
	float yN = (data[3] * 2.0f) - 1.0f;
	float zN = 1.0f - xN * xN - yN * yN;
	if (zN < 0.0f)
	{
	zN = 0.0f;
	}
	data[ASTCENC_SWZ_Z] = (astc::sqrt(zN) * 0.5f) + 0.5f;
	}

	color = vfloat4(data[swz.r], data[swz.g], data[swz.b], data[swz.a]);
	}

	store(color, data32_row);
	data32_row += 4;
	idx++;
	}
	idx += x_nudge;
	}
	idx += y_nudge;
	}
	}
	}