drivers/gpu/drm/vkms/vkms_formats.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0+

 #include <linux/kernel.h>
 #include <linux/minmax.h>

 #include <drm/drm_blend.h>
 #include <drm/drm_rect.h>
 #include <drm/drm_fixed.h>

 #include "vkms_formats.h"

 static size_t pixel_offset(const struct vkms_frame_info *frame_info, int x, int y)
 {
 	return frame_info->offset + (y * frame_info->pitch)
 				  + (x * frame_info->cpp);
 }

 /*
  * packed_pixels_addr - Get the pointer to pixel of a given pair of coordinates
  *
  * @frame_info: Buffer metadata
  * @x: The x(width) coordinate of the 2D buffer
  * @y: The y(Heigth) coordinate of the 2D buffer
  *
  * Takes the information stored in the frame_info, a pair of coordinates, and
  * returns the address of the first color channel.
  * This function assumes the channels are packed together, i.e. a color channel
  * comes immediately after another in the memory. And therefore, this function
  * doesn't work for YUV with chroma subsampling (e.g. YUV420 and NV21).
  */
 static void *packed_pixels_addr(const struct vkms_frame_info *frame_info,
 				int x, int y)
 {
 	size_t offset = pixel_offset(frame_info, x, y);

 	return (u8 *)frame_info->map[0].vaddr + offset;
 }

 static void *get_packed_src_addr(const struct vkms_frame_info *frame_info, int y)
 {
 	int x_src = frame_info->src.x1 >> 16;
 	int y_src = y - frame_info->rotated.y1 + (frame_info->src.y1 >> 16);

 	return packed_pixels_addr(frame_info, x_src, y_src);
 }

 static int get_x_position(const struct vkms_frame_info *frame_info, int limit, int x)
 {
 	if (frame_info->rotation & (DRM_MODE_REFLECT_X | DRM_MODE_ROTATE_270))
 		return limit - x - 1;
 	return x;
 }

 static void ARGB8888_to_argb_u16(u8 *src_pixels, struct pixel_argb_u16 *out_pixel)
 {
 	/*
 	 * The 257 is the "conversion ratio". This number is obtained by the
 	 * (2^16 - 1) / (2^8 - 1) division. Which, in this case, tries to get
 	 * the best color value in a pixel format with more possibilities.
 	 * A similar idea applies to others RGB color conversions.
 	 */
 	out_pixel->a = (u16)src_pixels[3] * 257;
 	out_pixel->r = (u16)src_pixels[2] * 257;
 	out_pixel->g = (u16)src_pixels[1] * 257;
 	out_pixel->b = (u16)src_pixels[0] * 257;
 }

 static void XRGB8888_to_argb_u16(u8 *src_pixels, struct pixel_argb_u16 *out_pixel)
 {
 	out_pixel->a = (u16)0xffff;
 	out_pixel->r = (u16)src_pixels[2] * 257;
 	out_pixel->g = (u16)src_pixels[1] * 257;
 	out_pixel->b = (u16)src_pixels[0] * 257;
 }

 static void ARGB16161616_to_argb_u16(u8 *src_pixels, struct pixel_argb_u16 *out_pixel)
 {
 	u16 *pixels = (u16 *)src_pixels;

 	out_pixel->a = le16_to_cpu(pixels[3]);
 	out_pixel->r = le16_to_cpu(pixels[2]);
 	out_pixel->g = le16_to_cpu(pixels[1]);
 	out_pixel->b = le16_to_cpu(pixels[0]);
 }

 static void XRGB16161616_to_argb_u16(u8 *src_pixels, struct pixel_argb_u16 *out_pixel)
 {
 	u16 *pixels = (u16 *)src_pixels;

 	out_pixel->a = (u16)0xffff;
 	out_pixel->r = le16_to_cpu(pixels[2]);
 	out_pixel->g = le16_to_cpu(pixels[1]);
 	out_pixel->b = le16_to_cpu(pixels[0]);
 }

 static void RGB565_to_argb_u16(u8 *src_pixels, struct pixel_argb_u16 *out_pixel)
 {
 	u16 *pixels = (u16 *)src_pixels;

 	s64 fp_rb_ratio = drm_fixp_div(drm_int2fixp(65535), drm_int2fixp(31));
 	s64 fp_g_ratio = drm_fixp_div(drm_int2fixp(65535), drm_int2fixp(63));

 	u16 rgb_565 = le16_to_cpu(*pixels);
 	s64 fp_r = drm_int2fixp((rgb_565 >> 11) & 0x1f);
 	s64 fp_g = drm_int2fixp((rgb_565 >> 5) & 0x3f);
 	s64 fp_b = drm_int2fixp(rgb_565 & 0x1f);

 	out_pixel->a = (u16)0xffff;
 	out_pixel->r = drm_fixp2int_round(drm_fixp_mul(fp_r, fp_rb_ratio));
 	out_pixel->g = drm_fixp2int_round(drm_fixp_mul(fp_g, fp_g_ratio));
 	out_pixel->b = drm_fixp2int_round(drm_fixp_mul(fp_b, fp_rb_ratio));
 }

 /**
  * vkms_compose_row - compose a single row of a plane
  * @stage_buffer: output line with the composed pixels
  * @plane: state of the plane that is being composed
  * @y: y coordinate of the row
  *
  * This function composes a single row of a plane. It gets the source pixels
  * through the y coordinate (see get_packed_src_addr()) and goes linearly
  * through the source pixel, reading the pixels and converting it to
  * ARGB16161616 (see the pixel_read() callback). For rotate-90 and rotate-270,
  * the source pixels are not traversed linearly. The source pixels are queried
  * on each iteration in order to traverse the pixels vertically.
  */
 void vkms_compose_row(struct line_buffer *stage_buffer, struct vkms_plane_state *plane, int y)
 {
 	struct pixel_argb_u16 *out_pixels = stage_buffer->pixels;
 	struct vkms_frame_info *frame_info = plane->frame_info;
 	u8 *src_pixels = get_packed_src_addr(frame_info, y);
 	int limit = min_t(size_t, drm_rect_width(&frame_info->dst), stage_buffer->n_pixels);

 	for (size_t x = 0; x < limit; x++, src_pixels += frame_info->cpp) {
 		int x_pos = get_x_position(frame_info, limit, x);

 		if (drm_rotation_90_or_270(frame_info->rotation))
 			src_pixels = get_packed_src_addr(frame_info, x + frame_info->rotated.y1)
 				+ frame_info->cpp * y;

 		plane->pixel_read(src_pixels, &out_pixels[x_pos]);
 	}
 }

 /*
  * The following  functions take an line of argb_u16 pixels from the
  * src_buffer, convert them to a specific format, and store them in the
  * destination.
  *
  * They are used in the `compose_active_planes` to convert and store a line
  * from the src_buffer to the writeback buffer.
  */
 static void argb_u16_to_ARGB8888(u8 *dst_pixels, struct pixel_argb_u16 *in_pixel)
 {
 	/*
 	 * This sequence below is important because the format's byte order is
 	 * in little-endian. In the case of the ARGB8888 the memory is
 	 * organized this way:
 	 *
 	 * | Addr     | = blue channel
 	 * | Addr + 1 | = green channel
 	 * | Addr + 2 | = Red channel
 	 * | Addr + 3 | = Alpha channel
 	 */
 	dst_pixels[3] = DIV_ROUND_CLOSEST(in_pixel->a, 257);
 	dst_pixels[2] = DIV_ROUND_CLOSEST(in_pixel->r, 257);
 	dst_pixels[1] = DIV_ROUND_CLOSEST(in_pixel->g, 257);
 	dst_pixels[0] = DIV_ROUND_CLOSEST(in_pixel->b, 257);
 }

 static void argb_u16_to_XRGB8888(u8 *dst_pixels, struct pixel_argb_u16 *in_pixel)
 {
 	dst_pixels[3] = 0xff;
 	dst_pixels[2] = DIV_ROUND_CLOSEST(in_pixel->r, 257);
 	dst_pixels[1] = DIV_ROUND_CLOSEST(in_pixel->g, 257);
 	dst_pixels[0] = DIV_ROUND_CLOSEST(in_pixel->b, 257);
 }

 static void argb_u16_to_ARGB16161616(u8 *dst_pixels, struct pixel_argb_u16 *in_pixel)
 {
 	u16 *pixels = (u16 *)dst_pixels;

 	pixels[3] = cpu_to_le16(in_pixel->a);
 	pixels[2] = cpu_to_le16(in_pixel->r);
 	pixels[1] = cpu_to_le16(in_pixel->g);
 	pixels[0] = cpu_to_le16(in_pixel->b);
 }

 static void argb_u16_to_XRGB16161616(u8 *dst_pixels, struct pixel_argb_u16 *in_pixel)
 {
 	u16 *pixels = (u16 *)dst_pixels;

 	pixels[3] = 0xffff;
 	pixels[2] = cpu_to_le16(in_pixel->r);
 	pixels[1] = cpu_to_le16(in_pixel->g);
 	pixels[0] = cpu_to_le16(in_pixel->b);
 }

 static void argb_u16_to_RGB565(u8 *dst_pixels, struct pixel_argb_u16 *in_pixel)
 {
 	u16 *pixels = (u16 *)dst_pixels;

 	s64 fp_rb_ratio = drm_fixp_div(drm_int2fixp(65535), drm_int2fixp(31));
 	s64 fp_g_ratio = drm_fixp_div(drm_int2fixp(65535), drm_int2fixp(63));

 	s64 fp_r = drm_int2fixp(in_pixel->r);
 	s64 fp_g = drm_int2fixp(in_pixel->g);
 	s64 fp_b = drm_int2fixp(in_pixel->b);

 	u16 r = drm_fixp2int(drm_fixp_div(fp_r, fp_rb_ratio));
 	u16 g = drm_fixp2int(drm_fixp_div(fp_g, fp_g_ratio));
 	u16 b = drm_fixp2int(drm_fixp_div(fp_b, fp_rb_ratio));

 	*pixels = cpu_to_le16(r << 11 | g << 5 | b);
 }

 void vkms_writeback_row(struct vkms_writeback_job *wb,
 			const struct line_buffer *src_buffer, int y)
 {
 	struct vkms_frame_info *frame_info = &wb->wb_frame_info;
 	int x_dst = frame_info->dst.x1;
 	u8 *dst_pixels = packed_pixels_addr(frame_info, x_dst, y);
 	struct pixel_argb_u16 *in_pixels = src_buffer->pixels;
 	int x_limit = min_t(size_t, drm_rect_width(&frame_info->dst), src_buffer->n_pixels);

 	for (size_t x = 0; x < x_limit; x++, dst_pixels += frame_info->cpp)
 		wb->pixel_write(dst_pixels, &in_pixels[x]);
 }

 void *get_pixel_conversion_function(u32 format)
 {
 	switch (format) {
 	case DRM_FORMAT_ARGB8888:
 		return &ARGB8888_to_argb_u16;
 	case DRM_FORMAT_XRGB8888:
 		return &XRGB8888_to_argb_u16;
 	case DRM_FORMAT_ARGB16161616:
 		return &ARGB16161616_to_argb_u16;
 	case DRM_FORMAT_XRGB16161616:
 		return &XRGB16161616_to_argb_u16;
 	case DRM_FORMAT_RGB565:
 		return &RGB565_to_argb_u16;
 	default:
 		return NULL;
 	}
 }

 void *get_pixel_write_function(u32 format)
 {
 	switch (format) {
 	case DRM_FORMAT_ARGB8888:
 		return &argb_u16_to_ARGB8888;
 	case DRM_FORMAT_XRGB8888:
 		return &argb_u16_to_XRGB8888;
 	case DRM_FORMAT_ARGB16161616:
 		return &argb_u16_to_ARGB16161616;
 	case DRM_FORMAT_XRGB16161616:
 		return &argb_u16_to_XRGB16161616;
 	case DRM_FORMAT_RGB565:
 		return &argb_u16_to_RGB565;
 	default:
 		return NULL;
 	}
 }
	// SPDX-License-Identifier: GPL-2.0+

	#include <linux/kernel.h>
	#include <linux/minmax.h>

	#include <drm/drm_blend.h>
	#include <drm/drm_rect.h>
	#include <drm/drm_fixed.h>

	#include "vkms_formats.h"

	static size_t pixel_offset(const struct vkms_frame_info *frame_info, int x, int y)
	{
	return frame_info->offset + (y * frame_info->pitch)
	+ (x * frame_info->cpp);
	}

	/*
	* packed_pixels_addr - Get the pointer to pixel of a given pair of coordinates
	*
	* @frame_info: Buffer metadata
	* @x: The x(width) coordinate of the 2D buffer
	* @y: The y(Heigth) coordinate of the 2D buffer
	*
	* Takes the information stored in the frame_info, a pair of coordinates, and
	* returns the address of the first color channel.
	* This function assumes the channels are packed together, i.e. a color channel
	* comes immediately after another in the memory. And therefore, this function
	* doesn't work for YUV with chroma subsampling (e.g. YUV420 and NV21).
	*/
	static void packed_pixels_addr(const struct vkms_frame_info frame_info,
	int x, int y)
	{
	size_t offset = pixel_offset(frame_info, x, y);

	return (u8 *)frame_info->map[0].vaddr + offset;
	}

	static void get_packed_src_addr(const struct vkms_frame_info frame_info, int y)
	{
	int x_src = frame_info->src.x1 >> 16;
	int y_src = y - frame_info->rotated.y1 + (frame_info->src.y1 >> 16);

	return packed_pixels_addr(frame_info, x_src, y_src);
	}

	static int get_x_position(const struct vkms_frame_info *frame_info, int limit, int x)
	{
	if (frame_info->rotation & (DRM_MODE_REFLECT_X \| DRM_MODE_ROTATE_270))
	return limit - x - 1;
	return x;
	}

	static void ARGB8888_to_argb_u16(u8 src_pixels, struct pixel_argb_u16 out_pixel)
	{
	/*
	* The 257 is the "conversion ratio". This number is obtained by the
	* (2^16 - 1) / (2^8 - 1) division. Which, in this case, tries to get
	* the best color value in a pixel format with more possibilities.
	* A similar idea applies to others RGB color conversions.
	*/
	out_pixel->a = (u16)src_pixels[3] * 257;
	out_pixel->r = (u16)src_pixels[2] * 257;
	out_pixel->g = (u16)src_pixels[1] * 257;
	out_pixel->b = (u16)src_pixels[0] * 257;
	}

	static void XRGB8888_to_argb_u16(u8 src_pixels, struct pixel_argb_u16 out_pixel)
	{
	out_pixel->a = (u16)0xffff;
	out_pixel->r = (u16)src_pixels[2] * 257;
	out_pixel->g = (u16)src_pixels[1] * 257;
	out_pixel->b = (u16)src_pixels[0] * 257;
	}

	static void ARGB16161616_to_argb_u16(u8 src_pixels, struct pixel_argb_u16 out_pixel)
	{
	u16 pixels = (u16 )src_pixels;

	out_pixel->a = le16_to_cpu(pixels[3]);
	out_pixel->r = le16_to_cpu(pixels[2]);
	out_pixel->g = le16_to_cpu(pixels[1]);
	out_pixel->b = le16_to_cpu(pixels[0]);
	}

	static void XRGB16161616_to_argb_u16(u8 src_pixels, struct pixel_argb_u16 out_pixel)
	{
	u16 pixels = (u16 )src_pixels;

	out_pixel->a = (u16)0xffff;
	out_pixel->r = le16_to_cpu(pixels[2]);
	out_pixel->g = le16_to_cpu(pixels[1]);
	out_pixel->b = le16_to_cpu(pixels[0]);
	}

	static void RGB565_to_argb_u16(u8 src_pixels, struct pixel_argb_u16 out_pixel)
	{
	u16 pixels = (u16 )src_pixels;

	s64 fp_rb_ratio = drm_fixp_div(drm_int2fixp(65535), drm_int2fixp(31));
	s64 fp_g_ratio = drm_fixp_div(drm_int2fixp(65535), drm_int2fixp(63));

	u16 rgb_565 = le16_to_cpu(*pixels);
	s64 fp_r = drm_int2fixp((rgb_565 >> 11) & 0x1f);
	s64 fp_g = drm_int2fixp((rgb_565 >> 5) & 0x3f);
	s64 fp_b = drm_int2fixp(rgb_565 & 0x1f);

	out_pixel->a = (u16)0xffff;
	out_pixel->r = drm_fixp2int_round(drm_fixp_mul(fp_r, fp_rb_ratio));
	out_pixel->g = drm_fixp2int_round(drm_fixp_mul(fp_g, fp_g_ratio));
	out_pixel->b = drm_fixp2int_round(drm_fixp_mul(fp_b, fp_rb_ratio));
	}

	/**
	* vkms_compose_row - compose a single row of a plane
	* @stage_buffer: output line with the composed pixels
	* @plane: state of the plane that is being composed
	* @y: y coordinate of the row
	*
	* This function composes a single row of a plane. It gets the source pixels
	* through the y coordinate (see get_packed_src_addr()) and goes linearly
	* through the source pixel, reading the pixels and converting it to
	* ARGB16161616 (see the pixel_read() callback). For rotate-90 and rotate-270,
	* the source pixels are not traversed linearly. The source pixels are queried
	* on each iteration in order to traverse the pixels vertically.
	*/
	void vkms_compose_row(struct line_buffer stage_buffer, struct vkms_plane_state plane, int y)
	{
	struct pixel_argb_u16 *out_pixels = stage_buffer->pixels;
	struct vkms_frame_info *frame_info = plane->frame_info;
	u8 *src_pixels = get_packed_src_addr(frame_info, y);
	int limit = min_t(size_t, drm_rect_width(&frame_info->dst), stage_buffer->n_pixels);

	for (size_t x = 0; x < limit; x++, src_pixels += frame_info->cpp) {
	int x_pos = get_x_position(frame_info, limit, x);

	if (drm_rotation_90_or_270(frame_info->rotation))
	src_pixels = get_packed_src_addr(frame_info, x + frame_info->rotated.y1)
	+ frame_info->cpp * y;

	plane->pixel_read(src_pixels, &out_pixels[x_pos]);
	}
	}

	/*
	* The following functions take an line of argb_u16 pixels from the
	* src_buffer, convert them to a specific format, and store them in the
	* destination.
	*
	* They are used in the `compose_active_planes` to convert and store a line
	* from the src_buffer to the writeback buffer.
	*/
	static void argb_u16_to_ARGB8888(u8 dst_pixels, struct pixel_argb_u16 in_pixel)
	{
	/*
	* This sequence below is important because the format's byte order is
	* in little-endian. In the case of the ARGB8888 the memory is
	* organized this way:
	*
	* \| Addr \| = blue channel
	* \| Addr + 1 \| = green channel
	* \| Addr + 2 \| = Red channel
	* \| Addr + 3 \| = Alpha channel
	*/
	dst_pixels[3] = DIV_ROUND_CLOSEST(in_pixel->a, 257);
	dst_pixels[2] = DIV_ROUND_CLOSEST(in_pixel->r, 257);
	dst_pixels[1] = DIV_ROUND_CLOSEST(in_pixel->g, 257);
	dst_pixels[0] = DIV_ROUND_CLOSEST(in_pixel->b, 257);
	}

	static void argb_u16_to_XRGB8888(u8 dst_pixels, struct pixel_argb_u16 in_pixel)
	{
	dst_pixels[3] = 0xff;
	dst_pixels[2] = DIV_ROUND_CLOSEST(in_pixel->r, 257);
	dst_pixels[1] = DIV_ROUND_CLOSEST(in_pixel->g, 257);
	dst_pixels[0] = DIV_ROUND_CLOSEST(in_pixel->b, 257);
	}

	static void argb_u16_to_ARGB16161616(u8 dst_pixels, struct pixel_argb_u16 in_pixel)
	{
	u16 pixels = (u16 )dst_pixels;

	pixels[3] = cpu_to_le16(in_pixel->a);
	pixels[2] = cpu_to_le16(in_pixel->r);
	pixels[1] = cpu_to_le16(in_pixel->g);
	pixels[0] = cpu_to_le16(in_pixel->b);
	}

	static void argb_u16_to_XRGB16161616(u8 dst_pixels, struct pixel_argb_u16 in_pixel)
	{
	u16 pixels = (u16 )dst_pixels;

	pixels[3] = 0xffff;
	pixels[2] = cpu_to_le16(in_pixel->r);
	pixels[1] = cpu_to_le16(in_pixel->g);
	pixels[0] = cpu_to_le16(in_pixel->b);
	}

	static void argb_u16_to_RGB565(u8 dst_pixels, struct pixel_argb_u16 in_pixel)
	{
	u16 pixels = (u16 )dst_pixels;

	s64 fp_rb_ratio = drm_fixp_div(drm_int2fixp(65535), drm_int2fixp(31));
	s64 fp_g_ratio = drm_fixp_div(drm_int2fixp(65535), drm_int2fixp(63));

	s64 fp_r = drm_int2fixp(in_pixel->r);
	s64 fp_g = drm_int2fixp(in_pixel->g);
	s64 fp_b = drm_int2fixp(in_pixel->b);

	u16 r = drm_fixp2int(drm_fixp_div(fp_r, fp_rb_ratio));
	u16 g = drm_fixp2int(drm_fixp_div(fp_g, fp_g_ratio));
	u16 b = drm_fixp2int(drm_fixp_div(fp_b, fp_rb_ratio));

	*pixels = cpu_to_le16(r << 11 \| g << 5 \| b);
	}

	void vkms_writeback_row(struct vkms_writeback_job *wb,
	const struct line_buffer *src_buffer, int y)
	{
	struct vkms_frame_info *frame_info = &wb->wb_frame_info;
	int x_dst = frame_info->dst.x1;
	u8 *dst_pixels = packed_pixels_addr(frame_info, x_dst, y);
	struct pixel_argb_u16 *in_pixels = src_buffer->pixels;
	int x_limit = min_t(size_t, drm_rect_width(&frame_info->dst), src_buffer->n_pixels);

	for (size_t x = 0; x < x_limit; x++, dst_pixels += frame_info->cpp)
	wb->pixel_write(dst_pixels, &in_pixels[x]);
	}

	void *get_pixel_conversion_function(u32 format)
	{
	switch (format) {
	case DRM_FORMAT_ARGB8888:
	return &ARGB8888_to_argb_u16;
	case DRM_FORMAT_XRGB8888:
	return &XRGB8888_to_argb_u16;
	case DRM_FORMAT_ARGB16161616:
	return &ARGB16161616_to_argb_u16;
	case DRM_FORMAT_XRGB16161616:
	return &XRGB16161616_to_argb_u16;
	case DRM_FORMAT_RGB565:
	return &RGB565_to_argb_u16;
	default:
	return NULL;
	}
	}

	void *get_pixel_write_function(u32 format)
	{
	switch (format) {
	case DRM_FORMAT_ARGB8888:
	return &argb_u16_to_ARGB8888;
	case DRM_FORMAT_XRGB8888:
	return &argb_u16_to_XRGB8888;
	case DRM_FORMAT_ARGB16161616:
	return &argb_u16_to_ARGB16161616;
	case DRM_FORMAT_XRGB16161616:
	return &argb_u16_to_XRGB16161616;
	case DRM_FORMAT_RGB565:
	return &argb_u16_to_RGB565;
	default:
	return NULL;
	}
	}