android_kernel_xiaomi_sm8350/drivers/video/msm/mdp_ppp.c
Pavel Machek d480ace08d fbdev: framebuffer support for HTC Dream
Add a framebuffer driver for Qualcomm MSM/QSD SoCs, tested on HTC Dream
smartphone (aka T-Mobile G1, aka ADP1).

Brian said:

  I did the original quick and dirty version for bringup.  Rebecca took
  over and (re)wrote the bulk of the driver, getting things stable for
  production ship of Dream and Sapphire, and Dima is currently adding
  support for later Qualcomm chipsets (QSD8x50, etc).

Signed-off-by: Pavel Machek <pavel@ucw.cz>
Cc: Brian Swetland <swetland@google.com>
Cc: Krzysztof Helt <krzysztof.h1@poczta.fm>
Cc: Rebecca Schultz Zavin <rebecca@android.com>
Cc: Dima Zavin <dima@android.com>
Signed-off-by: Andrew Morton <akpm@linux-foundation.org>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2009-09-23 07:39:50 -07:00

751 lines
22 KiB
C

/* drivers/video/msm/mdp_ppp.c
*
* Copyright (C) 2007 QUALCOMM Incorporated
* Copyright (C) 2007 Google Incorporated
*
* This software is licensed under the terms of the GNU General Public
* License version 2, as published by the Free Software Foundation, and
* may be copied, distributed, and modified under those terms.
*
* 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.
*/
#include <linux/fb.h>
#include <linux/file.h>
#include <linux/delay.h>
#include <linux/msm_mdp.h>
#include <linux/android_pmem.h>
#include <mach/msm_fb.h>
#include "mdp_hw.h"
#include "mdp_scale_tables.h"
#define DLOG(x...) do {} while (0)
#define MDP_DOWNSCALE_BLUR (MDP_DOWNSCALE_MAX + 1)
static int downscale_y_table = MDP_DOWNSCALE_MAX;
static int downscale_x_table = MDP_DOWNSCALE_MAX;
struct mdp_regs {
uint32_t src0;
uint32_t src1;
uint32_t dst0;
uint32_t dst1;
uint32_t src_cfg;
uint32_t dst_cfg;
uint32_t src_pack;
uint32_t dst_pack;
uint32_t src_rect;
uint32_t dst_rect;
uint32_t src_ystride;
uint32_t dst_ystride;
uint32_t op;
uint32_t src_bpp;
uint32_t dst_bpp;
uint32_t edge;
uint32_t phasex_init;
uint32_t phasey_init;
uint32_t phasex_step;
uint32_t phasey_step;
};
static uint32_t pack_pattern[] = {
PPP_ARRAY0(PACK_PATTERN)
};
static uint32_t src_img_cfg[] = {
PPP_ARRAY1(CFG, SRC)
};
static uint32_t dst_img_cfg[] = {
PPP_ARRAY1(CFG, DST)
};
static uint32_t bytes_per_pixel[] = {
[MDP_RGB_565] = 2,
[MDP_RGB_888] = 3,
[MDP_XRGB_8888] = 4,
[MDP_ARGB_8888] = 4,
[MDP_RGBA_8888] = 4,
[MDP_BGRA_8888] = 4,
[MDP_Y_CBCR_H2V1] = 1,
[MDP_Y_CBCR_H2V2] = 1,
[MDP_Y_CRCB_H2V1] = 1,
[MDP_Y_CRCB_H2V2] = 1,
[MDP_YCRYCB_H2V1] = 2
};
static uint32_t dst_op_chroma[] = {
PPP_ARRAY1(CHROMA_SAMP, DST)
};
static uint32_t src_op_chroma[] = {
PPP_ARRAY1(CHROMA_SAMP, SRC)
};
static uint32_t bg_op_chroma[] = {
PPP_ARRAY1(CHROMA_SAMP, BG)
};
static void rotate_dst_addr_x(struct mdp_blit_req *req, struct mdp_regs *regs)
{
regs->dst0 += (req->dst_rect.w -
min((uint32_t)16, req->dst_rect.w)) * regs->dst_bpp;
regs->dst1 += (req->dst_rect.w -
min((uint32_t)16, req->dst_rect.w)) * regs->dst_bpp;
}
static void rotate_dst_addr_y(struct mdp_blit_req *req, struct mdp_regs *regs)
{
regs->dst0 += (req->dst_rect.h -
min((uint32_t)16, req->dst_rect.h)) *
regs->dst_ystride;
regs->dst1 += (req->dst_rect.h -
min((uint32_t)16, req->dst_rect.h)) *
regs->dst_ystride;
}
static void blit_rotate(struct mdp_blit_req *req,
struct mdp_regs *regs)
{
if (req->flags == MDP_ROT_NOP)
return;
regs->op |= PPP_OP_ROT_ON;
if ((req->flags & MDP_ROT_90 || req->flags & MDP_FLIP_LR) &&
!(req->flags & MDP_ROT_90 && req->flags & MDP_FLIP_LR))
rotate_dst_addr_x(req, regs);
if (req->flags & MDP_ROT_90)
regs->op |= PPP_OP_ROT_90;
if (req->flags & MDP_FLIP_UD) {
regs->op |= PPP_OP_FLIP_UD;
rotate_dst_addr_y(req, regs);
}
if (req->flags & MDP_FLIP_LR)
regs->op |= PPP_OP_FLIP_LR;
}
static void blit_convert(struct mdp_blit_req *req, struct mdp_regs *regs)
{
if (req->src.format == req->dst.format)
return;
if (IS_RGB(req->src.format) && IS_YCRCB(req->dst.format)) {
regs->op |= PPP_OP_CONVERT_RGB2YCBCR | PPP_OP_CONVERT_ON;
} else if (IS_YCRCB(req->src.format) && IS_RGB(req->dst.format)) {
regs->op |= PPP_OP_CONVERT_YCBCR2RGB | PPP_OP_CONVERT_ON;
if (req->dst.format == MDP_RGB_565)
regs->op |= PPP_OP_CONVERT_MATRIX_SECONDARY;
}
}
#define GET_BIT_RANGE(value, high, low) \
(((1 << (high - low + 1)) - 1) & (value >> low))
static uint32_t transp_convert(struct mdp_blit_req *req)
{
uint32_t transp = 0;
if (req->src.format == MDP_RGB_565) {
/* pad each value to 8 bits by copying the high bits into the
* low end, convert RGB to RBG by switching low 2 components */
transp |= ((GET_BIT_RANGE(req->transp_mask, 15, 11) << 3) |
(GET_BIT_RANGE(req->transp_mask, 15, 13))) << 16;
transp |= ((GET_BIT_RANGE(req->transp_mask, 4, 0) << 3) |
(GET_BIT_RANGE(req->transp_mask, 4, 2))) << 8;
transp |= (GET_BIT_RANGE(req->transp_mask, 10, 5) << 2) |
(GET_BIT_RANGE(req->transp_mask, 10, 9));
} else {
/* convert RGB to RBG */
transp |= (GET_BIT_RANGE(req->transp_mask, 15, 8)) |
(GET_BIT_RANGE(req->transp_mask, 23, 16) << 16) |
(GET_BIT_RANGE(req->transp_mask, 7, 0) << 8);
}
return transp;
}
#undef GET_BIT_RANGE
static void blit_blend(struct mdp_blit_req *req, struct mdp_regs *regs)
{
/* TRANSP BLEND */
if (req->transp_mask != MDP_TRANSP_NOP) {
req->transp_mask = transp_convert(req);
if (req->alpha != MDP_ALPHA_NOP) {
/* use blended transparancy mode
* pixel = (src == transp) ? dst : blend
* blend is combo of blend_eq_sel and
* blend_alpha_sel */
regs->op |= PPP_OP_ROT_ON | PPP_OP_BLEND_ON |
PPP_OP_BLEND_ALPHA_BLEND_NORMAL |
PPP_OP_BLEND_CONSTANT_ALPHA |
PPP_BLEND_ALPHA_TRANSP;
} else {
/* simple transparancy mode
* pixel = (src == transp) ? dst : src */
regs->op |= PPP_OP_ROT_ON | PPP_OP_BLEND_ON |
PPP_OP_BLEND_SRCPIXEL_TRANSP;
}
}
req->alpha &= 0xff;
/* ALPHA BLEND */
if (HAS_ALPHA(req->src.format)) {
regs->op |= PPP_OP_ROT_ON | PPP_OP_BLEND_ON |
PPP_OP_BLEND_SRCPIXEL_ALPHA;
} else if (req->alpha < MDP_ALPHA_NOP) {
/* just blend by alpha */
regs->op |= PPP_OP_ROT_ON | PPP_OP_BLEND_ON |
PPP_OP_BLEND_ALPHA_BLEND_NORMAL |
PPP_OP_BLEND_CONSTANT_ALPHA;
}
regs->op |= bg_op_chroma[req->dst.format];
}
#define ONE_HALF (1LL << 32)
#define ONE (1LL << 33)
#define TWO (2LL << 33)
#define THREE (3LL << 33)
#define FRAC_MASK (ONE - 1)
#define INT_MASK (~FRAC_MASK)
static int scale_params(uint32_t dim_in, uint32_t dim_out, uint32_t origin,
uint32_t *phase_init, uint32_t *phase_step)
{
/* to improve precicsion calculations are done in U31.33 and converted
* to U3.29 at the end */
int64_t k1, k2, k3, k4, tmp;
uint64_t n, d, os, os_p, od, od_p, oreq;
unsigned rpa = 0;
int64_t ip64, delta;
if (dim_out % 3 == 0)
rpa = !(dim_in % (dim_out / 3));
n = ((uint64_t)dim_out) << 34;
d = dim_in;
if (!d)
return -1;
do_div(n, d);
k3 = (n + 1) >> 1;
if ((k3 >> 4) < (1LL << 27) || (k3 >> 4) > (1LL << 31)) {
DLOG("crap bad scale\n");
return -1;
}
n = ((uint64_t)dim_in) << 34;
d = (uint64_t)dim_out;
if (!d)
return -1;
do_div(n, d);
k1 = (n + 1) >> 1;
k2 = (k1 - ONE) >> 1;
*phase_init = (int)(k2 >> 4);
k4 = (k3 - ONE) >> 1;
if (rpa) {
os = ((uint64_t)origin << 33) - ONE_HALF;
tmp = (dim_out * os) + ONE_HALF;
if (!dim_in)
return -1;
do_div(tmp, dim_in);
od = tmp - ONE_HALF;
} else {
os = ((uint64_t)origin << 1) - 1;
od = (((k3 * os) >> 1) + k4);
}
od_p = od & INT_MASK;
if (od_p != od)
od_p += ONE;
if (rpa) {
tmp = (dim_in * od_p) + ONE_HALF;
if (!dim_in)
return -1;
do_div(tmp, dim_in);
os_p = tmp - ONE_HALF;
} else {
os_p = ((k1 * (od_p >> 33)) + k2);
}
oreq = (os_p & INT_MASK) - ONE;
ip64 = os_p - oreq;
delta = ((int64_t)(origin) << 33) - oreq;
ip64 -= delta;
/* limit to valid range before the left shift */
delta = (ip64 & (1LL << 63)) ? 4 : -4;
delta <<= 33;
while (abs((int)(ip64 >> 33)) > 4)
ip64 += delta;
*phase_init = (int)(ip64 >> 4);
*phase_step = (uint32_t)(k1 >> 4);
return 0;
}
static void load_scale_table(const struct mdp_info *mdp,
struct mdp_table_entry *table, int len)
{
int i;
for (i = 0; i < len; i++)
mdp_writel(mdp, table[i].val, table[i].reg);
}
enum {
IMG_LEFT,
IMG_RIGHT,
IMG_TOP,
IMG_BOTTOM,
};
static void get_edge_info(uint32_t src, uint32_t src_coord, uint32_t dst,
uint32_t *interp1, uint32_t *interp2,
uint32_t *repeat1, uint32_t *repeat2) {
if (src > 3 * dst) {
*interp1 = 0;
*interp2 = src - 1;
*repeat1 = 0;
*repeat2 = 0;
} else if (src == 3 * dst) {
*interp1 = 0;
*interp2 = src;
*repeat1 = 0;
*repeat2 = 1;
} else if (src > dst && src < 3 * dst) {
*interp1 = -1;
*interp2 = src;
*repeat1 = 1;
*repeat2 = 1;
} else if (src == dst) {
*interp1 = -1;
*interp2 = src + 1;
*repeat1 = 1;
*repeat2 = 2;
} else {
*interp1 = -2;
*interp2 = src + 1;
*repeat1 = 2;
*repeat2 = 2;
}
*interp1 += src_coord;
*interp2 += src_coord;
}
static int get_edge_cond(struct mdp_blit_req *req, struct mdp_regs *regs)
{
int32_t luma_interp[4];
int32_t luma_repeat[4];
int32_t chroma_interp[4];
int32_t chroma_bound[4];
int32_t chroma_repeat[4];
uint32_t dst_w, dst_h;
memset(&luma_interp, 0, sizeof(int32_t) * 4);
memset(&luma_repeat, 0, sizeof(int32_t) * 4);
memset(&chroma_interp, 0, sizeof(int32_t) * 4);
memset(&chroma_bound, 0, sizeof(int32_t) * 4);
memset(&chroma_repeat, 0, sizeof(int32_t) * 4);
regs->edge = 0;
if (req->flags & MDP_ROT_90) {
dst_w = req->dst_rect.h;
dst_h = req->dst_rect.w;
} else {
dst_w = req->dst_rect.w;
dst_h = req->dst_rect.h;
}
if (regs->op & (PPP_OP_SCALE_Y_ON | PPP_OP_SCALE_X_ON)) {
get_edge_info(req->src_rect.h, req->src_rect.y, dst_h,
&luma_interp[IMG_TOP], &luma_interp[IMG_BOTTOM],
&luma_repeat[IMG_TOP], &luma_repeat[IMG_BOTTOM]);
get_edge_info(req->src_rect.w, req->src_rect.x, dst_w,
&luma_interp[IMG_LEFT], &luma_interp[IMG_RIGHT],
&luma_repeat[IMG_LEFT], &luma_repeat[IMG_RIGHT]);
} else {
luma_interp[IMG_LEFT] = req->src_rect.x;
luma_interp[IMG_RIGHT] = req->src_rect.x + req->src_rect.w - 1;
luma_interp[IMG_TOP] = req->src_rect.y;
luma_interp[IMG_BOTTOM] = req->src_rect.y + req->src_rect.h - 1;
luma_repeat[IMG_LEFT] = 0;
luma_repeat[IMG_TOP] = 0;
luma_repeat[IMG_RIGHT] = 0;
luma_repeat[IMG_BOTTOM] = 0;
}
chroma_interp[IMG_LEFT] = luma_interp[IMG_LEFT];
chroma_interp[IMG_RIGHT] = luma_interp[IMG_RIGHT];
chroma_interp[IMG_TOP] = luma_interp[IMG_TOP];
chroma_interp[IMG_BOTTOM] = luma_interp[IMG_BOTTOM];
chroma_bound[IMG_LEFT] = req->src_rect.x;
chroma_bound[IMG_RIGHT] = req->src_rect.x + req->src_rect.w - 1;
chroma_bound[IMG_TOP] = req->src_rect.y;
chroma_bound[IMG_BOTTOM] = req->src_rect.y + req->src_rect.h - 1;
if (IS_YCRCB(req->src.format)) {
chroma_interp[IMG_LEFT] = chroma_interp[IMG_LEFT] >> 1;
chroma_interp[IMG_RIGHT] = (chroma_interp[IMG_RIGHT] + 1) >> 1;
chroma_bound[IMG_LEFT] = chroma_bound[IMG_LEFT] >> 1;
chroma_bound[IMG_RIGHT] = chroma_bound[IMG_RIGHT] >> 1;
}
if (req->src.format == MDP_Y_CBCR_H2V2 ||
req->src.format == MDP_Y_CRCB_H2V2) {
chroma_interp[IMG_TOP] = (chroma_interp[IMG_TOP] - 1) >> 1;
chroma_interp[IMG_BOTTOM] = (chroma_interp[IMG_BOTTOM] + 1)
>> 1;
chroma_bound[IMG_TOP] = (chroma_bound[IMG_TOP] + 1) >> 1;
chroma_bound[IMG_BOTTOM] = chroma_bound[IMG_BOTTOM] >> 1;
}
chroma_repeat[IMG_LEFT] = chroma_bound[IMG_LEFT] -
chroma_interp[IMG_LEFT];
chroma_repeat[IMG_RIGHT] = chroma_interp[IMG_RIGHT] -
chroma_bound[IMG_RIGHT];
chroma_repeat[IMG_TOP] = chroma_bound[IMG_TOP] -
chroma_interp[IMG_TOP];
chroma_repeat[IMG_BOTTOM] = chroma_interp[IMG_BOTTOM] -
chroma_bound[IMG_BOTTOM];
if (chroma_repeat[IMG_LEFT] < 0 || chroma_repeat[IMG_LEFT] > 3 ||
chroma_repeat[IMG_RIGHT] < 0 || chroma_repeat[IMG_RIGHT] > 3 ||
chroma_repeat[IMG_TOP] < 0 || chroma_repeat[IMG_TOP] > 3 ||
chroma_repeat[IMG_BOTTOM] < 0 || chroma_repeat[IMG_BOTTOM] > 3 ||
luma_repeat[IMG_LEFT] < 0 || luma_repeat[IMG_LEFT] > 3 ||
luma_repeat[IMG_RIGHT] < 0 || luma_repeat[IMG_RIGHT] > 3 ||
luma_repeat[IMG_TOP] < 0 || luma_repeat[IMG_TOP] > 3 ||
luma_repeat[IMG_BOTTOM] < 0 || luma_repeat[IMG_BOTTOM] > 3)
return -1;
regs->edge |= (chroma_repeat[IMG_LEFT] & 3) << MDP_LEFT_CHROMA;
regs->edge |= (chroma_repeat[IMG_RIGHT] & 3) << MDP_RIGHT_CHROMA;
regs->edge |= (chroma_repeat[IMG_TOP] & 3) << MDP_TOP_CHROMA;
regs->edge |= (chroma_repeat[IMG_BOTTOM] & 3) << MDP_BOTTOM_CHROMA;
regs->edge |= (luma_repeat[IMG_LEFT] & 3) << MDP_LEFT_LUMA;
regs->edge |= (luma_repeat[IMG_RIGHT] & 3) << MDP_RIGHT_LUMA;
regs->edge |= (luma_repeat[IMG_TOP] & 3) << MDP_TOP_LUMA;
regs->edge |= (luma_repeat[IMG_BOTTOM] & 3) << MDP_BOTTOM_LUMA;
return 0;
}
static int blit_scale(const struct mdp_info *mdp, struct mdp_blit_req *req,
struct mdp_regs *regs)
{
uint32_t phase_init_x, phase_init_y, phase_step_x, phase_step_y;
uint32_t scale_factor_x, scale_factor_y;
uint32_t downscale;
uint32_t dst_w, dst_h;
if (req->flags & MDP_ROT_90) {
dst_w = req->dst_rect.h;
dst_h = req->dst_rect.w;
} else {
dst_w = req->dst_rect.w;
dst_h = req->dst_rect.h;
}
if ((req->src_rect.w == dst_w) && (req->src_rect.h == dst_h) &&
!(req->flags & MDP_BLUR)) {
regs->phasex_init = 0;
regs->phasey_init = 0;
regs->phasex_step = 0;
regs->phasey_step = 0;
return 0;
}
if (scale_params(req->src_rect.w, dst_w, 1, &phase_init_x,
&phase_step_x) ||
scale_params(req->src_rect.h, dst_h, 1, &phase_init_y,
&phase_step_y))
return -1;
scale_factor_x = (dst_w * 10) / req->src_rect.w;
scale_factor_y = (dst_h * 10) / req->src_rect.h;
if (scale_factor_x > 8)
downscale = MDP_DOWNSCALE_PT8TO1;
else if (scale_factor_x > 6)
downscale = MDP_DOWNSCALE_PT6TOPT8;
else if (scale_factor_x > 4)
downscale = MDP_DOWNSCALE_PT4TOPT6;
else
downscale = MDP_DOWNSCALE_PT2TOPT4;
if (downscale != downscale_x_table) {
load_scale_table(mdp, mdp_downscale_x_table[downscale], 64);
downscale_x_table = downscale;
}
if (scale_factor_y > 8)
downscale = MDP_DOWNSCALE_PT8TO1;
else if (scale_factor_y > 6)
downscale = MDP_DOWNSCALE_PT6TOPT8;
else if (scale_factor_y > 4)
downscale = MDP_DOWNSCALE_PT4TOPT6;
else
downscale = MDP_DOWNSCALE_PT2TOPT4;
if (downscale != downscale_y_table) {
load_scale_table(mdp, mdp_downscale_y_table[downscale], 64);
downscale_y_table = downscale;
}
regs->phasex_init = phase_init_x;
regs->phasey_init = phase_init_y;
regs->phasex_step = phase_step_x;
regs->phasey_step = phase_step_y;
regs->op |= (PPP_OP_SCALE_Y_ON | PPP_OP_SCALE_X_ON);
return 0;
}
static void blit_blur(const struct mdp_info *mdp, struct mdp_blit_req *req,
struct mdp_regs *regs)
{
if (!(req->flags & MDP_BLUR))
return;
if (!(downscale_x_table == MDP_DOWNSCALE_BLUR &&
downscale_y_table == MDP_DOWNSCALE_BLUR)) {
load_scale_table(mdp, mdp_gaussian_blur_table, 128);
downscale_x_table = MDP_DOWNSCALE_BLUR;
downscale_y_table = MDP_DOWNSCALE_BLUR;
}
regs->op |= (PPP_OP_SCALE_Y_ON | PPP_OP_SCALE_X_ON);
}
#define IMG_LEN(rect_h, w, rect_w, bpp) (((rect_h) * w) * bpp)
#define Y_TO_CRCB_RATIO(format) \
((format == MDP_Y_CBCR_H2V2 || format == MDP_Y_CRCB_H2V2) ? 2 :\
(format == MDP_Y_CBCR_H2V1 || format == MDP_Y_CRCB_H2V1) ? 1 : 1)
static void get_len(struct mdp_img *img, struct mdp_rect *rect, uint32_t bpp,
uint32_t *len0, uint32_t *len1)
{
*len0 = IMG_LEN(rect->h, img->width, rect->w, bpp);
if (IS_PSEUDOPLNR(img->format))
*len1 = *len0/Y_TO_CRCB_RATIO(img->format);
else
*len1 = 0;
}
static int valid_src_dst(unsigned long src_start, unsigned long src_len,
unsigned long dst_start, unsigned long dst_len,
struct mdp_blit_req *req, struct mdp_regs *regs)
{
unsigned long src_min_ok = src_start;
unsigned long src_max_ok = src_start + src_len;
unsigned long dst_min_ok = dst_start;
unsigned long dst_max_ok = dst_start + dst_len;
uint32_t src0_len, src1_len, dst0_len, dst1_len;
get_len(&req->src, &req->src_rect, regs->src_bpp, &src0_len,
&src1_len);
get_len(&req->dst, &req->dst_rect, regs->dst_bpp, &dst0_len,
&dst1_len);
if (regs->src0 < src_min_ok || regs->src0 > src_max_ok ||
regs->src0 + src0_len > src_max_ok) {
DLOG("invalid_src %x %x %lx %lx\n", regs->src0,
src0_len, src_min_ok, src_max_ok);
return 0;
}
if (regs->src_cfg & PPP_SRC_PLANE_PSEUDOPLNR) {
if (regs->src1 < src_min_ok || regs->src1 > src_max_ok ||
regs->src1 + src1_len > src_max_ok) {
DLOG("invalid_src1");
return 0;
}
}
if (regs->dst0 < dst_min_ok || regs->dst0 > dst_max_ok ||
regs->dst0 + dst0_len > dst_max_ok) {
DLOG("invalid_dst");
return 0;
}
if (regs->dst_cfg & PPP_SRC_PLANE_PSEUDOPLNR) {
if (regs->dst1 < dst_min_ok || regs->dst1 > dst_max_ok ||
regs->dst1 + dst1_len > dst_max_ok) {
DLOG("invalid_dst1");
return 0;
}
}
return 1;
}
static void flush_imgs(struct mdp_blit_req *req, struct mdp_regs *regs,
struct file *src_file, struct file *dst_file)
{
#ifdef CONFIG_ANDROID_PMEM
uint32_t src0_len, src1_len, dst0_len, dst1_len;
/* flush src images to memory before dma to mdp */
get_len(&req->src, &req->src_rect, regs->src_bpp, &src0_len,
&src1_len);
flush_pmem_file(src_file, req->src.offset, src0_len);
if (IS_PSEUDOPLNR(req->src.format))
flush_pmem_file(src_file, req->src.offset + src0_len,
src1_len);
/* flush dst images */
get_len(&req->dst, &req->dst_rect, regs->dst_bpp, &dst0_len,
&dst1_len);
flush_pmem_file(dst_file, req->dst.offset, dst0_len);
if (IS_PSEUDOPLNR(req->dst.format))
flush_pmem_file(dst_file, req->dst.offset + dst0_len,
dst1_len);
#endif
}
static void get_chroma_addr(struct mdp_img *img, struct mdp_rect *rect,
uint32_t base, uint32_t bpp, uint32_t cfg,
uint32_t *addr, uint32_t *ystride)
{
uint32_t compress_v = Y_TO_CRCB_RATIO(img->format);
uint32_t compress_h = 2;
uint32_t offset;
if (IS_PSEUDOPLNR(img->format)) {
offset = (rect->x / compress_h) * compress_h;
offset += rect->y == 0 ? 0 :
((rect->y + 1) / compress_v) * img->width;
*addr = base + (img->width * img->height * bpp);
*addr += offset * bpp;
*ystride |= *ystride << 16;
} else {
*addr = 0;
}
}
static int send_blit(const struct mdp_info *mdp, struct mdp_blit_req *req,
struct mdp_regs *regs, struct file *src_file,
struct file *dst_file)
{
mdp_writel(mdp, 1, 0x060);
mdp_writel(mdp, regs->src_rect, PPP_ADDR_SRC_ROI);
mdp_writel(mdp, regs->src0, PPP_ADDR_SRC0);
mdp_writel(mdp, regs->src1, PPP_ADDR_SRC1);
mdp_writel(mdp, regs->src_ystride, PPP_ADDR_SRC_YSTRIDE);
mdp_writel(mdp, regs->src_cfg, PPP_ADDR_SRC_CFG);
mdp_writel(mdp, regs->src_pack, PPP_ADDR_SRC_PACK_PATTERN);
mdp_writel(mdp, regs->op, PPP_ADDR_OPERATION);
mdp_writel(mdp, regs->phasex_init, PPP_ADDR_PHASEX_INIT);
mdp_writel(mdp, regs->phasey_init, PPP_ADDR_PHASEY_INIT);
mdp_writel(mdp, regs->phasex_step, PPP_ADDR_PHASEX_STEP);
mdp_writel(mdp, regs->phasey_step, PPP_ADDR_PHASEY_STEP);
mdp_writel(mdp, (req->alpha << 24) | (req->transp_mask & 0xffffff),
PPP_ADDR_ALPHA_TRANSP);
mdp_writel(mdp, regs->dst_cfg, PPP_ADDR_DST_CFG);
mdp_writel(mdp, regs->dst_pack, PPP_ADDR_DST_PACK_PATTERN);
mdp_writel(mdp, regs->dst_rect, PPP_ADDR_DST_ROI);
mdp_writel(mdp, regs->dst0, PPP_ADDR_DST0);
mdp_writel(mdp, regs->dst1, PPP_ADDR_DST1);
mdp_writel(mdp, regs->dst_ystride, PPP_ADDR_DST_YSTRIDE);
mdp_writel(mdp, regs->edge, PPP_ADDR_EDGE);
if (regs->op & PPP_OP_BLEND_ON) {
mdp_writel(mdp, regs->dst0, PPP_ADDR_BG0);
mdp_writel(mdp, regs->dst1, PPP_ADDR_BG1);
mdp_writel(mdp, regs->dst_ystride, PPP_ADDR_BG_YSTRIDE);
mdp_writel(mdp, src_img_cfg[req->dst.format], PPP_ADDR_BG_CFG);
mdp_writel(mdp, pack_pattern[req->dst.format],
PPP_ADDR_BG_PACK_PATTERN);
}
flush_imgs(req, regs, src_file, dst_file);
mdp_writel(mdp, 0x1000, MDP_DISPLAY0_START);
return 0;
}
int mdp_ppp_blit(const struct mdp_info *mdp, struct mdp_blit_req *req,
struct file *src_file, unsigned long src_start, unsigned long src_len,
struct file *dst_file, unsigned long dst_start, unsigned long dst_len)
{
struct mdp_regs regs = {0};
if (unlikely(req->src.format >= MDP_IMGTYPE_LIMIT ||
req->dst.format >= MDP_IMGTYPE_LIMIT)) {
printk(KERN_ERR "mpd_ppp: img is of wrong format\n");
return -EINVAL;
}
if (unlikely(req->src_rect.x > req->src.width ||
req->src_rect.y > req->src.height ||
req->dst_rect.x > req->dst.width ||
req->dst_rect.y > req->dst.height)) {
printk(KERN_ERR "mpd_ppp: img rect is outside of img!\n");
return -EINVAL;
}
/* set the src image configuration */
regs.src_cfg = src_img_cfg[req->src.format];
regs.src_cfg |= (req->src_rect.x & 0x1) ? PPP_SRC_BPP_ROI_ODD_X : 0;
regs.src_cfg |= (req->src_rect.y & 0x1) ? PPP_SRC_BPP_ROI_ODD_Y : 0;
regs.src_rect = (req->src_rect.h << 16) | req->src_rect.w;
regs.src_pack = pack_pattern[req->src.format];
/* set the dest image configuration */
regs.dst_cfg = dst_img_cfg[req->dst.format] | PPP_DST_OUT_SEL_AXI;
regs.dst_rect = (req->dst_rect.h << 16) | req->dst_rect.w;
regs.dst_pack = pack_pattern[req->dst.format];
/* set src, bpp, start pixel and ystride */
regs.src_bpp = bytes_per_pixel[req->src.format];
regs.src0 = src_start + req->src.offset;
regs.src_ystride = req->src.width * regs.src_bpp;
get_chroma_addr(&req->src, &req->src_rect, regs.src0, regs.src_bpp,
regs.src_cfg, &regs.src1, &regs.src_ystride);
regs.src0 += (req->src_rect.x + (req->src_rect.y * req->src.width)) *
regs.src_bpp;
/* set dst, bpp, start pixel and ystride */
regs.dst_bpp = bytes_per_pixel[req->dst.format];
regs.dst0 = dst_start + req->dst.offset;
regs.dst_ystride = req->dst.width * regs.dst_bpp;
get_chroma_addr(&req->dst, &req->dst_rect, regs.dst0, regs.dst_bpp,
regs.dst_cfg, &regs.dst1, &regs.dst_ystride);
regs.dst0 += (req->dst_rect.x + (req->dst_rect.y * req->dst.width)) *
regs.dst_bpp;
if (!valid_src_dst(src_start, src_len, dst_start, dst_len, req,
&regs)) {
printk(KERN_ERR "mpd_ppp: final src or dst location is "
"invalid, are you trying to make an image too large "
"or to place it outside the screen?\n");
return -EINVAL;
}
/* set up operation register */
regs.op = 0;
blit_rotate(req, &regs);
blit_convert(req, &regs);
if (req->flags & MDP_DITHER)
regs.op |= PPP_OP_DITHER_EN;
blit_blend(req, &regs);
if (blit_scale(mdp, req, &regs)) {
printk(KERN_ERR "mpd_ppp: error computing scale for img.\n");
return -EINVAL;
}
blit_blur(mdp, req, &regs);
regs.op |= dst_op_chroma[req->dst.format] |
src_op_chroma[req->src.format];
/* if the image is YCRYCB, the x and w must be even */
if (unlikely(req->src.format == MDP_YCRYCB_H2V1)) {
req->src_rect.x = req->src_rect.x & (~0x1);
req->src_rect.w = req->src_rect.w & (~0x1);
req->dst_rect.x = req->dst_rect.x & (~0x1);
req->dst_rect.w = req->dst_rect.w & (~0x1);
}
if (get_edge_cond(req, &regs))
return -EINVAL;
send_blit(mdp, req, &regs, src_file, dst_file);
return 0;
}