linux/drivers/media/video/davinci/vpbe_osd.c
Thomas Meyer fbc09d3aa1 [media] davinci vpbe: Use resource_size()
Use resource_size function on resource object
 instead of explicit computation.

 The semantic patch that makes this output is available
 in scripts/coccinelle/api/resource_size.cocci.

 More information about semantic patching is available at
 http://coccinelle.lip6.fr/

Signed-off-by: Thomas Meyer <thomas@m3y3r.de>
Signed-off-by: Mauro Carvalho Chehab <mchehab@redhat.com>
2011-09-21 14:10:34 -03:00

1232 lines
31 KiB
C

/*
* Copyright (C) 2007-2010 Texas Instruments Inc
* Copyright (C) 2007 MontaVista Software, Inc.
*
* Andy Lowe (alowe@mvista.com), MontaVista Software
* - Initial version
* Murali Karicheri (mkaricheri@gmail.com), Texas Instruments Ltd.
* - ported to sub device interface
*
* 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 version 2.
*
* 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/interrupt.h>
#include <linux/platform_device.h>
#include <linux/clk.h>
#include <linux/slab.h>
#include <mach/io.h>
#include <mach/cputype.h>
#include <mach/hardware.h>
#include <media/davinci/vpss.h>
#include <media/v4l2-device.h>
#include <media/davinci/vpbe_types.h>
#include <media/davinci/vpbe_osd.h>
#include <linux/io.h>
#include "vpbe_osd_regs.h"
#define MODULE_NAME VPBE_OSD_SUBDEV_NAME
/* register access routines */
static inline u32 osd_read(struct osd_state *sd, u32 offset)
{
struct osd_state *osd = sd;
return readl(osd->osd_base + offset);
}
static inline u32 osd_write(struct osd_state *sd, u32 val, u32 offset)
{
struct osd_state *osd = sd;
writel(val, osd->osd_base + offset);
return val;
}
static inline u32 osd_set(struct osd_state *sd, u32 mask, u32 offset)
{
struct osd_state *osd = sd;
u32 addr = osd->osd_base + offset;
u32 val = readl(addr) | mask;
writel(val, addr);
return val;
}
static inline u32 osd_clear(struct osd_state *sd, u32 mask, u32 offset)
{
struct osd_state *osd = sd;
u32 addr = osd->osd_base + offset;
u32 val = readl(addr) & ~mask;
writel(val, addr);
return val;
}
static inline u32 osd_modify(struct osd_state *sd, u32 mask, u32 val,
u32 offset)
{
struct osd_state *osd = sd;
u32 addr = osd->osd_base + offset;
u32 new_val = (readl(addr) & ~mask) | (val & mask);
writel(new_val, addr);
return new_val;
}
/* define some macros for layer and pixfmt classification */
#define is_osd_win(layer) (((layer) == WIN_OSD0) || ((layer) == WIN_OSD1))
#define is_vid_win(layer) (((layer) == WIN_VID0) || ((layer) == WIN_VID1))
#define is_rgb_pixfmt(pixfmt) \
(((pixfmt) == PIXFMT_RGB565) || ((pixfmt) == PIXFMT_RGB888))
#define is_yc_pixfmt(pixfmt) \
(((pixfmt) == PIXFMT_YCbCrI) || ((pixfmt) == PIXFMT_YCrCbI) || \
((pixfmt) == PIXFMT_NV12))
#define MAX_WIN_SIZE OSD_VIDWIN0XP_V0X
#define MAX_LINE_LENGTH (OSD_VIDWIN0OFST_V0LO << 5)
/**
* _osd_dm6446_vid0_pingpong() - field inversion fix for DM6446
* @sd - ptr to struct osd_state
* @field_inversion - inversion flag
* @fb_base_phys - frame buffer address
* @lconfig - ptr to layer config
*
* This routine implements a workaround for the field signal inversion silicon
* erratum described in Advisory 1.3.8 for the DM6446. The fb_base_phys and
* lconfig parameters apply to the vid0 window. This routine should be called
* whenever the vid0 layer configuration or start address is modified, or when
* the OSD field inversion setting is modified.
* Returns: 1 if the ping-pong buffers need to be toggled in the vsync isr, or
* 0 otherwise
*/
static int _osd_dm6446_vid0_pingpong(struct osd_state *sd,
int field_inversion,
unsigned long fb_base_phys,
const struct osd_layer_config *lconfig)
{
struct osd_platform_data *pdata;
pdata = (struct osd_platform_data *)sd->dev->platform_data;
if (pdata->field_inv_wa_enable) {
if (!field_inversion || !lconfig->interlaced) {
osd_write(sd, fb_base_phys & ~0x1F, OSD_VIDWIN0ADR);
osd_write(sd, fb_base_phys & ~0x1F, OSD_PPVWIN0ADR);
osd_modify(sd, OSD_MISCCTL_PPSW | OSD_MISCCTL_PPRV, 0,
OSD_MISCCTL);
return 0;
} else {
unsigned miscctl = OSD_MISCCTL_PPRV;
osd_write(sd,
(fb_base_phys & ~0x1F) - lconfig->line_length,
OSD_VIDWIN0ADR);
osd_write(sd,
(fb_base_phys & ~0x1F) + lconfig->line_length,
OSD_PPVWIN0ADR);
osd_modify(sd,
OSD_MISCCTL_PPSW | OSD_MISCCTL_PPRV, miscctl,
OSD_MISCCTL);
return 1;
}
}
return 0;
}
static void _osd_set_field_inversion(struct osd_state *sd, int enable)
{
unsigned fsinv = 0;
if (enable)
fsinv = OSD_MODE_FSINV;
osd_modify(sd, OSD_MODE_FSINV, fsinv, OSD_MODE);
}
static void _osd_set_blink_attribute(struct osd_state *sd, int enable,
enum osd_blink_interval blink)
{
u32 osdatrmd = 0;
if (enable) {
osdatrmd |= OSD_OSDATRMD_BLNK;
osdatrmd |= blink << OSD_OSDATRMD_BLNKINT_SHIFT;
}
/* caller must ensure that OSD1 is configured in attribute mode */
osd_modify(sd, OSD_OSDATRMD_BLNKINT | OSD_OSDATRMD_BLNK, osdatrmd,
OSD_OSDATRMD);
}
static void _osd_set_rom_clut(struct osd_state *sd,
enum osd_rom_clut rom_clut)
{
if (rom_clut == ROM_CLUT0)
osd_clear(sd, OSD_MISCCTL_RSEL, OSD_MISCCTL);
else
osd_set(sd, OSD_MISCCTL_RSEL, OSD_MISCCTL);
}
static void _osd_set_palette_map(struct osd_state *sd,
enum osd_win_layer osdwin,
unsigned char pixel_value,
unsigned char clut_index,
enum osd_pix_format pixfmt)
{
static const int map_2bpp[] = { 0, 5, 10, 15 };
static const int map_1bpp[] = { 0, 15 };
int bmp_offset;
int bmp_shift;
int bmp_mask;
int bmp_reg;
switch (pixfmt) {
case PIXFMT_1BPP:
bmp_reg = map_1bpp[pixel_value & 0x1];
break;
case PIXFMT_2BPP:
bmp_reg = map_2bpp[pixel_value & 0x3];
break;
case PIXFMT_4BPP:
bmp_reg = pixel_value & 0xf;
break;
default:
return;
}
switch (osdwin) {
case OSDWIN_OSD0:
bmp_offset = OSD_W0BMP01 + (bmp_reg >> 1) * sizeof(u32);
break;
case OSDWIN_OSD1:
bmp_offset = OSD_W1BMP01 + (bmp_reg >> 1) * sizeof(u32);
break;
default:
return;
}
if (bmp_reg & 1) {
bmp_shift = 8;
bmp_mask = 0xff << 8;
} else {
bmp_shift = 0;
bmp_mask = 0xff;
}
osd_modify(sd, bmp_mask, clut_index << bmp_shift, bmp_offset);
}
static void _osd_set_rec601_attenuation(struct osd_state *sd,
enum osd_win_layer osdwin, int enable)
{
switch (osdwin) {
case OSDWIN_OSD0:
osd_modify(sd, OSD_OSDWIN0MD_ATN0E,
enable ? OSD_OSDWIN0MD_ATN0E : 0,
OSD_OSDWIN0MD);
break;
case OSDWIN_OSD1:
osd_modify(sd, OSD_OSDWIN1MD_ATN1E,
enable ? OSD_OSDWIN1MD_ATN1E : 0,
OSD_OSDWIN1MD);
break;
}
}
static void _osd_set_blending_factor(struct osd_state *sd,
enum osd_win_layer osdwin,
enum osd_blending_factor blend)
{
switch (osdwin) {
case OSDWIN_OSD0:
osd_modify(sd, OSD_OSDWIN0MD_BLND0,
blend << OSD_OSDWIN0MD_BLND0_SHIFT, OSD_OSDWIN0MD);
break;
case OSDWIN_OSD1:
osd_modify(sd, OSD_OSDWIN1MD_BLND1,
blend << OSD_OSDWIN1MD_BLND1_SHIFT, OSD_OSDWIN1MD);
break;
}
}
static void _osd_enable_color_key(struct osd_state *sd,
enum osd_win_layer osdwin,
unsigned colorkey,
enum osd_pix_format pixfmt)
{
switch (pixfmt) {
case PIXFMT_RGB565:
osd_write(sd, colorkey & OSD_TRANSPVAL_RGBTRANS,
OSD_TRANSPVAL);
break;
default:
break;
}
switch (osdwin) {
case OSDWIN_OSD0:
osd_set(sd, OSD_OSDWIN0MD_TE0, OSD_OSDWIN0MD);
break;
case OSDWIN_OSD1:
osd_set(sd, OSD_OSDWIN1MD_TE1, OSD_OSDWIN1MD);
break;
}
}
static void _osd_disable_color_key(struct osd_state *sd,
enum osd_win_layer osdwin)
{
switch (osdwin) {
case OSDWIN_OSD0:
osd_clear(sd, OSD_OSDWIN0MD_TE0, OSD_OSDWIN0MD);
break;
case OSDWIN_OSD1:
osd_clear(sd, OSD_OSDWIN1MD_TE1, OSD_OSDWIN1MD);
break;
}
}
static void _osd_set_osd_clut(struct osd_state *sd,
enum osd_win_layer osdwin,
enum osd_clut clut)
{
u32 winmd = 0;
switch (osdwin) {
case OSDWIN_OSD0:
if (clut == RAM_CLUT)
winmd |= OSD_OSDWIN0MD_CLUTS0;
osd_modify(sd, OSD_OSDWIN0MD_CLUTS0, winmd, OSD_OSDWIN0MD);
break;
case OSDWIN_OSD1:
if (clut == RAM_CLUT)
winmd |= OSD_OSDWIN1MD_CLUTS1;
osd_modify(sd, OSD_OSDWIN1MD_CLUTS1, winmd, OSD_OSDWIN1MD);
break;
}
}
static void _osd_set_zoom(struct osd_state *sd, enum osd_layer layer,
enum osd_zoom_factor h_zoom,
enum osd_zoom_factor v_zoom)
{
u32 winmd = 0;
switch (layer) {
case WIN_OSD0:
winmd |= (h_zoom << OSD_OSDWIN0MD_OHZ0_SHIFT);
winmd |= (v_zoom << OSD_OSDWIN0MD_OVZ0_SHIFT);
osd_modify(sd, OSD_OSDWIN0MD_OHZ0 | OSD_OSDWIN0MD_OVZ0, winmd,
OSD_OSDWIN0MD);
break;
case WIN_VID0:
winmd |= (h_zoom << OSD_VIDWINMD_VHZ0_SHIFT);
winmd |= (v_zoom << OSD_VIDWINMD_VVZ0_SHIFT);
osd_modify(sd, OSD_VIDWINMD_VHZ0 | OSD_VIDWINMD_VVZ0, winmd,
OSD_VIDWINMD);
break;
case WIN_OSD1:
winmd |= (h_zoom << OSD_OSDWIN1MD_OHZ1_SHIFT);
winmd |= (v_zoom << OSD_OSDWIN1MD_OVZ1_SHIFT);
osd_modify(sd, OSD_OSDWIN1MD_OHZ1 | OSD_OSDWIN1MD_OVZ1, winmd,
OSD_OSDWIN1MD);
break;
case WIN_VID1:
winmd |= (h_zoom << OSD_VIDWINMD_VHZ1_SHIFT);
winmd |= (v_zoom << OSD_VIDWINMD_VVZ1_SHIFT);
osd_modify(sd, OSD_VIDWINMD_VHZ1 | OSD_VIDWINMD_VVZ1, winmd,
OSD_VIDWINMD);
break;
}
}
static void _osd_disable_layer(struct osd_state *sd, enum osd_layer layer)
{
switch (layer) {
case WIN_OSD0:
osd_clear(sd, OSD_OSDWIN0MD_OACT0, OSD_OSDWIN0MD);
break;
case WIN_VID0:
osd_clear(sd, OSD_VIDWINMD_ACT0, OSD_VIDWINMD);
break;
case WIN_OSD1:
/* disable attribute mode as well as disabling the window */
osd_clear(sd, OSD_OSDWIN1MD_OASW | OSD_OSDWIN1MD_OACT1,
OSD_OSDWIN1MD);
break;
case WIN_VID1:
osd_clear(sd, OSD_VIDWINMD_ACT1, OSD_VIDWINMD);
break;
}
}
static void osd_disable_layer(struct osd_state *sd, enum osd_layer layer)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
unsigned long flags;
spin_lock_irqsave(&osd->lock, flags);
if (!win->is_enabled) {
spin_unlock_irqrestore(&osd->lock, flags);
return;
}
win->is_enabled = 0;
_osd_disable_layer(sd, layer);
spin_unlock_irqrestore(&osd->lock, flags);
}
static void _osd_enable_attribute_mode(struct osd_state *sd)
{
/* enable attribute mode for OSD1 */
osd_set(sd, OSD_OSDWIN1MD_OASW, OSD_OSDWIN1MD);
}
static void _osd_enable_layer(struct osd_state *sd, enum osd_layer layer)
{
switch (layer) {
case WIN_OSD0:
osd_set(sd, OSD_OSDWIN0MD_OACT0, OSD_OSDWIN0MD);
break;
case WIN_VID0:
osd_set(sd, OSD_VIDWINMD_ACT0, OSD_VIDWINMD);
break;
case WIN_OSD1:
/* enable OSD1 and disable attribute mode */
osd_modify(sd, OSD_OSDWIN1MD_OASW | OSD_OSDWIN1MD_OACT1,
OSD_OSDWIN1MD_OACT1, OSD_OSDWIN1MD);
break;
case WIN_VID1:
osd_set(sd, OSD_VIDWINMD_ACT1, OSD_VIDWINMD);
break;
}
}
static int osd_enable_layer(struct osd_state *sd, enum osd_layer layer,
int otherwin)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
struct osd_layer_config *cfg = &win->lconfig;
unsigned long flags;
spin_lock_irqsave(&osd->lock, flags);
/*
* use otherwin flag to know this is the other vid window
* in YUV420 mode, if is, skip this check
*/
if (!otherwin && (!win->is_allocated ||
!win->fb_base_phys ||
!cfg->line_length ||
!cfg->xsize ||
!cfg->ysize)) {
spin_unlock_irqrestore(&osd->lock, flags);
return -1;
}
if (win->is_enabled) {
spin_unlock_irqrestore(&osd->lock, flags);
return 0;
}
win->is_enabled = 1;
if (cfg->pixfmt != PIXFMT_OSD_ATTR)
_osd_enable_layer(sd, layer);
else {
_osd_enable_attribute_mode(sd);
_osd_set_blink_attribute(sd, osd->is_blinking, osd->blink);
}
spin_unlock_irqrestore(&osd->lock, flags);
return 0;
}
static void _osd_start_layer(struct osd_state *sd, enum osd_layer layer,
unsigned long fb_base_phys,
unsigned long cbcr_ofst)
{
switch (layer) {
case WIN_OSD0:
osd_write(sd, fb_base_phys & ~0x1F, OSD_OSDWIN0ADR);
break;
case WIN_VID0:
osd_write(sd, fb_base_phys & ~0x1F, OSD_VIDWIN0ADR);
break;
case WIN_OSD1:
osd_write(sd, fb_base_phys & ~0x1F, OSD_OSDWIN1ADR);
break;
case WIN_VID1:
osd_write(sd, fb_base_phys & ~0x1F, OSD_VIDWIN1ADR);
break;
}
}
static void osd_start_layer(struct osd_state *sd, enum osd_layer layer,
unsigned long fb_base_phys,
unsigned long cbcr_ofst)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
struct osd_layer_config *cfg = &win->lconfig;
unsigned long flags;
spin_lock_irqsave(&osd->lock, flags);
win->fb_base_phys = fb_base_phys & ~0x1F;
_osd_start_layer(sd, layer, fb_base_phys, cbcr_ofst);
if (layer == WIN_VID0) {
osd->pingpong =
_osd_dm6446_vid0_pingpong(sd, osd->field_inversion,
win->fb_base_phys,
cfg);
}
spin_unlock_irqrestore(&osd->lock, flags);
}
static void osd_get_layer_config(struct osd_state *sd, enum osd_layer layer,
struct osd_layer_config *lconfig)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
unsigned long flags;
spin_lock_irqsave(&osd->lock, flags);
*lconfig = win->lconfig;
spin_unlock_irqrestore(&osd->lock, flags);
}
/**
* try_layer_config() - Try a specific configuration for the layer
* @sd - ptr to struct osd_state
* @layer - layer to configure
* @lconfig - layer configuration to try
*
* If the requested lconfig is completely rejected and the value of lconfig on
* exit is the current lconfig, then try_layer_config() returns 1. Otherwise,
* try_layer_config() returns 0. A return value of 0 does not necessarily mean
* that the value of lconfig on exit is identical to the value of lconfig on
* entry, but merely that it represents a change from the current lconfig.
*/
static int try_layer_config(struct osd_state *sd, enum osd_layer layer,
struct osd_layer_config *lconfig)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
int bad_config;
/* verify that the pixel format is compatible with the layer */
switch (lconfig->pixfmt) {
case PIXFMT_1BPP:
case PIXFMT_2BPP:
case PIXFMT_4BPP:
case PIXFMT_8BPP:
case PIXFMT_RGB565:
bad_config = !is_osd_win(layer);
break;
case PIXFMT_YCbCrI:
case PIXFMT_YCrCbI:
bad_config = !is_vid_win(layer);
break;
case PIXFMT_RGB888:
bad_config = !is_vid_win(layer);
break;
case PIXFMT_NV12:
bad_config = 1;
break;
case PIXFMT_OSD_ATTR:
bad_config = (layer != WIN_OSD1);
break;
default:
bad_config = 1;
break;
}
if (bad_config) {
/*
* The requested pixel format is incompatible with the layer,
* so keep the current layer configuration.
*/
*lconfig = win->lconfig;
return bad_config;
}
/* DM6446: */
/* only one OSD window at a time can use RGB pixel formats */
if (is_osd_win(layer) && is_rgb_pixfmt(lconfig->pixfmt)) {
enum osd_pix_format pixfmt;
if (layer == WIN_OSD0)
pixfmt = osd->win[WIN_OSD1].lconfig.pixfmt;
else
pixfmt = osd->win[WIN_OSD0].lconfig.pixfmt;
if (is_rgb_pixfmt(pixfmt)) {
/*
* The other OSD window is already configured for an
* RGB, so keep the current layer configuration.
*/
*lconfig = win->lconfig;
return 1;
}
}
/* DM6446: only one video window at a time can use RGB888 */
if (is_vid_win(layer) && lconfig->pixfmt == PIXFMT_RGB888) {
enum osd_pix_format pixfmt;
if (layer == WIN_VID0)
pixfmt = osd->win[WIN_VID1].lconfig.pixfmt;
else
pixfmt = osd->win[WIN_VID0].lconfig.pixfmt;
if (pixfmt == PIXFMT_RGB888) {
/*
* The other video window is already configured for
* RGB888, so keep the current layer configuration.
*/
*lconfig = win->lconfig;
return 1;
}
}
/* window dimensions must be non-zero */
if (!lconfig->line_length || !lconfig->xsize || !lconfig->ysize) {
*lconfig = win->lconfig;
return 1;
}
/* round line_length up to a multiple of 32 */
lconfig->line_length = ((lconfig->line_length + 31) / 32) * 32;
lconfig->line_length =
min(lconfig->line_length, (unsigned)MAX_LINE_LENGTH);
lconfig->xsize = min(lconfig->xsize, (unsigned)MAX_WIN_SIZE);
lconfig->ysize = min(lconfig->ysize, (unsigned)MAX_WIN_SIZE);
lconfig->xpos = min(lconfig->xpos, (unsigned)MAX_WIN_SIZE);
lconfig->ypos = min(lconfig->ypos, (unsigned)MAX_WIN_SIZE);
lconfig->interlaced = (lconfig->interlaced != 0);
if (lconfig->interlaced) {
/* ysize and ypos must be even for interlaced displays */
lconfig->ysize &= ~1;
lconfig->ypos &= ~1;
}
return 0;
}
static void _osd_disable_vid_rgb888(struct osd_state *sd)
{
/*
* The DM6446 supports RGB888 pixel format in a single video window.
* This routine disables RGB888 pixel format for both video windows.
* The caller must ensure that neither video window is currently
* configured for RGB888 pixel format.
*/
osd_clear(sd, OSD_MISCCTL_RGBEN, OSD_MISCCTL);
}
static void _osd_enable_vid_rgb888(struct osd_state *sd,
enum osd_layer layer)
{
/*
* The DM6446 supports RGB888 pixel format in a single video window.
* This routine enables RGB888 pixel format for the specified video
* window. The caller must ensure that the other video window is not
* currently configured for RGB888 pixel format, as this routine will
* disable RGB888 pixel format for the other window.
*/
if (layer == WIN_VID0) {
osd_modify(sd, OSD_MISCCTL_RGBEN | OSD_MISCCTL_RGBWIN,
OSD_MISCCTL_RGBEN, OSD_MISCCTL);
} else if (layer == WIN_VID1) {
osd_modify(sd, OSD_MISCCTL_RGBEN | OSD_MISCCTL_RGBWIN,
OSD_MISCCTL_RGBEN | OSD_MISCCTL_RGBWIN,
OSD_MISCCTL);
}
}
static void _osd_set_cbcr_order(struct osd_state *sd,
enum osd_pix_format pixfmt)
{
/*
* The caller must ensure that all windows using YC pixfmt use the same
* Cb/Cr order.
*/
if (pixfmt == PIXFMT_YCbCrI)
osd_clear(sd, OSD_MODE_CS, OSD_MODE);
else if (pixfmt == PIXFMT_YCrCbI)
osd_set(sd, OSD_MODE_CS, OSD_MODE);
}
static void _osd_set_layer_config(struct osd_state *sd, enum osd_layer layer,
const struct osd_layer_config *lconfig)
{
u32 winmd = 0, winmd_mask = 0, bmw = 0;
_osd_set_cbcr_order(sd, lconfig->pixfmt);
switch (layer) {
case WIN_OSD0:
winmd_mask |= OSD_OSDWIN0MD_RGB0E;
if (lconfig->pixfmt == PIXFMT_RGB565)
winmd |= OSD_OSDWIN0MD_RGB0E;
winmd_mask |= OSD_OSDWIN0MD_BMW0 | OSD_OSDWIN0MD_OFF0;
switch (lconfig->pixfmt) {
case PIXFMT_1BPP:
bmw = 0;
break;
case PIXFMT_2BPP:
bmw = 1;
break;
case PIXFMT_4BPP:
bmw = 2;
break;
case PIXFMT_8BPP:
bmw = 3;
break;
default:
break;
}
winmd |= (bmw << OSD_OSDWIN0MD_BMW0_SHIFT);
if (lconfig->interlaced)
winmd |= OSD_OSDWIN0MD_OFF0;
osd_modify(sd, winmd_mask, winmd, OSD_OSDWIN0MD);
osd_write(sd, lconfig->line_length >> 5, OSD_OSDWIN0OFST);
osd_write(sd, lconfig->xpos, OSD_OSDWIN0XP);
osd_write(sd, lconfig->xsize, OSD_OSDWIN0XL);
if (lconfig->interlaced) {
osd_write(sd, lconfig->ypos >> 1, OSD_OSDWIN0YP);
osd_write(sd, lconfig->ysize >> 1, OSD_OSDWIN0YL);
} else {
osd_write(sd, lconfig->ypos, OSD_OSDWIN0YP);
osd_write(sd, lconfig->ysize, OSD_OSDWIN0YL);
}
break;
case WIN_VID0:
winmd_mask |= OSD_VIDWINMD_VFF0;
if (lconfig->interlaced)
winmd |= OSD_VIDWINMD_VFF0;
osd_modify(sd, winmd_mask, winmd, OSD_VIDWINMD);
osd_write(sd, lconfig->line_length >> 5, OSD_VIDWIN0OFST);
osd_write(sd, lconfig->xpos, OSD_VIDWIN0XP);
osd_write(sd, lconfig->xsize, OSD_VIDWIN0XL);
/*
* For YUV420P format the register contents are
* duplicated in both VID registers
*/
if (lconfig->interlaced) {
osd_write(sd, lconfig->ypos >> 1, OSD_VIDWIN0YP);
osd_write(sd, lconfig->ysize >> 1, OSD_VIDWIN0YL);
} else {
osd_write(sd, lconfig->ypos, OSD_VIDWIN0YP);
osd_write(sd, lconfig->ysize, OSD_VIDWIN0YL);
}
break;
case WIN_OSD1:
/*
* The caller must ensure that OSD1 is disabled prior to
* switching from a normal mode to attribute mode or from
* attribute mode to a normal mode.
*/
if (lconfig->pixfmt == PIXFMT_OSD_ATTR) {
winmd_mask |=
OSD_OSDWIN1MD_ATN1E | OSD_OSDWIN1MD_RGB1E |
OSD_OSDWIN1MD_CLUTS1 |
OSD_OSDWIN1MD_BLND1 | OSD_OSDWIN1MD_TE1;
} else {
winmd_mask |= OSD_OSDWIN1MD_RGB1E;
if (lconfig->pixfmt == PIXFMT_RGB565)
winmd |= OSD_OSDWIN1MD_RGB1E;
winmd_mask |= OSD_OSDWIN1MD_BMW1;
switch (lconfig->pixfmt) {
case PIXFMT_1BPP:
bmw = 0;
break;
case PIXFMT_2BPP:
bmw = 1;
break;
case PIXFMT_4BPP:
bmw = 2;
break;
case PIXFMT_8BPP:
bmw = 3;
break;
default:
break;
}
winmd |= (bmw << OSD_OSDWIN1MD_BMW1_SHIFT);
}
winmd_mask |= OSD_OSDWIN1MD_OFF1;
if (lconfig->interlaced)
winmd |= OSD_OSDWIN1MD_OFF1;
osd_modify(sd, winmd_mask, winmd, OSD_OSDWIN1MD);
osd_write(sd, lconfig->line_length >> 5, OSD_OSDWIN1OFST);
osd_write(sd, lconfig->xpos, OSD_OSDWIN1XP);
osd_write(sd, lconfig->xsize, OSD_OSDWIN1XL);
if (lconfig->interlaced) {
osd_write(sd, lconfig->ypos >> 1, OSD_OSDWIN1YP);
osd_write(sd, lconfig->ysize >> 1, OSD_OSDWIN1YL);
} else {
osd_write(sd, lconfig->ypos, OSD_OSDWIN1YP);
osd_write(sd, lconfig->ysize, OSD_OSDWIN1YL);
}
break;
case WIN_VID1:
winmd_mask |= OSD_VIDWINMD_VFF1;
if (lconfig->interlaced)
winmd |= OSD_VIDWINMD_VFF1;
osd_modify(sd, winmd_mask, winmd, OSD_VIDWINMD);
osd_write(sd, lconfig->line_length >> 5, OSD_VIDWIN1OFST);
osd_write(sd, lconfig->xpos, OSD_VIDWIN1XP);
osd_write(sd, lconfig->xsize, OSD_VIDWIN1XL);
/*
* For YUV420P format the register contents are
* duplicated in both VID registers
*/
osd_modify(sd, OSD_MISCCTL_S420D, ~OSD_MISCCTL_S420D,
OSD_MISCCTL);
if (lconfig->interlaced) {
osd_write(sd, lconfig->ypos >> 1, OSD_VIDWIN1YP);
osd_write(sd, lconfig->ysize >> 1, OSD_VIDWIN1YL);
} else {
osd_write(sd, lconfig->ypos, OSD_VIDWIN1YP);
osd_write(sd, lconfig->ysize, OSD_VIDWIN1YL);
}
break;
}
}
static int osd_set_layer_config(struct osd_state *sd, enum osd_layer layer,
struct osd_layer_config *lconfig)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
struct osd_layer_config *cfg = &win->lconfig;
unsigned long flags;
int reject_config;
spin_lock_irqsave(&osd->lock, flags);
reject_config = try_layer_config(sd, layer, lconfig);
if (reject_config) {
spin_unlock_irqrestore(&osd->lock, flags);
return reject_config;
}
/* update the current Cb/Cr order */
if (is_yc_pixfmt(lconfig->pixfmt))
osd->yc_pixfmt = lconfig->pixfmt;
/*
* If we are switching OSD1 from normal mode to attribute mode or from
* attribute mode to normal mode, then we must disable the window.
*/
if (layer == WIN_OSD1) {
if (((lconfig->pixfmt == PIXFMT_OSD_ATTR) &&
(cfg->pixfmt != PIXFMT_OSD_ATTR)) ||
((lconfig->pixfmt != PIXFMT_OSD_ATTR) &&
(cfg->pixfmt == PIXFMT_OSD_ATTR))) {
win->is_enabled = 0;
_osd_disable_layer(sd, layer);
}
}
_osd_set_layer_config(sd, layer, lconfig);
if (layer == WIN_OSD1) {
struct osd_osdwin_state *osdwin_state =
&osd->osdwin[OSDWIN_OSD1];
if ((lconfig->pixfmt != PIXFMT_OSD_ATTR) &&
(cfg->pixfmt == PIXFMT_OSD_ATTR)) {
/*
* We just switched OSD1 from attribute mode to normal
* mode, so we must initialize the CLUT select, the
* blend factor, transparency colorkey enable, and
* attenuation enable (DM6446 only) bits in the
* OSDWIN1MD register.
*/
_osd_set_osd_clut(sd, OSDWIN_OSD1,
osdwin_state->clut);
_osd_set_blending_factor(sd, OSDWIN_OSD1,
osdwin_state->blend);
if (osdwin_state->colorkey_blending) {
_osd_enable_color_key(sd, OSDWIN_OSD1,
osdwin_state->
colorkey,
lconfig->pixfmt);
} else
_osd_disable_color_key(sd, OSDWIN_OSD1);
_osd_set_rec601_attenuation(sd, OSDWIN_OSD1,
osdwin_state->
rec601_attenuation);
} else if ((lconfig->pixfmt == PIXFMT_OSD_ATTR) &&
(cfg->pixfmt != PIXFMT_OSD_ATTR)) {
/*
* We just switched OSD1 from normal mode to attribute
* mode, so we must initialize the blink enable and
* blink interval bits in the OSDATRMD register.
*/
_osd_set_blink_attribute(sd, osd->is_blinking,
osd->blink);
}
}
/*
* If we just switched to a 1-, 2-, or 4-bits-per-pixel bitmap format
* then configure a default palette map.
*/
if ((lconfig->pixfmt != cfg->pixfmt) &&
((lconfig->pixfmt == PIXFMT_1BPP) ||
(lconfig->pixfmt == PIXFMT_2BPP) ||
(lconfig->pixfmt == PIXFMT_4BPP))) {
enum osd_win_layer osdwin =
((layer == WIN_OSD0) ? OSDWIN_OSD0 : OSDWIN_OSD1);
struct osd_osdwin_state *osdwin_state =
&osd->osdwin[osdwin];
unsigned char clut_index;
unsigned char clut_entries = 0;
switch (lconfig->pixfmt) {
case PIXFMT_1BPP:
clut_entries = 2;
break;
case PIXFMT_2BPP:
clut_entries = 4;
break;
case PIXFMT_4BPP:
clut_entries = 16;
break;
default:
break;
}
/*
* The default palette map maps the pixel value to the clut
* index, i.e. pixel value 0 maps to clut entry 0, pixel value
* 1 maps to clut entry 1, etc.
*/
for (clut_index = 0; clut_index < 16; clut_index++) {
osdwin_state->palette_map[clut_index] = clut_index;
if (clut_index < clut_entries) {
_osd_set_palette_map(sd, osdwin, clut_index,
clut_index,
lconfig->pixfmt);
}
}
}
*cfg = *lconfig;
/* DM6446: configure the RGB888 enable and window selection */
if (osd->win[WIN_VID0].lconfig.pixfmt == PIXFMT_RGB888)
_osd_enable_vid_rgb888(sd, WIN_VID0);
else if (osd->win[WIN_VID1].lconfig.pixfmt == PIXFMT_RGB888)
_osd_enable_vid_rgb888(sd, WIN_VID1);
else
_osd_disable_vid_rgb888(sd);
if (layer == WIN_VID0) {
osd->pingpong =
_osd_dm6446_vid0_pingpong(sd, osd->field_inversion,
win->fb_base_phys,
cfg);
}
spin_unlock_irqrestore(&osd->lock, flags);
return 0;
}
static void osd_init_layer(struct osd_state *sd, enum osd_layer layer)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
enum osd_win_layer osdwin;
struct osd_osdwin_state *osdwin_state;
struct osd_layer_config *cfg = &win->lconfig;
unsigned long flags;
spin_lock_irqsave(&osd->lock, flags);
win->is_enabled = 0;
_osd_disable_layer(sd, layer);
win->h_zoom = ZOOM_X1;
win->v_zoom = ZOOM_X1;
_osd_set_zoom(sd, layer, win->h_zoom, win->v_zoom);
win->fb_base_phys = 0;
_osd_start_layer(sd, layer, win->fb_base_phys, 0);
cfg->line_length = 0;
cfg->xsize = 0;
cfg->ysize = 0;
cfg->xpos = 0;
cfg->ypos = 0;
cfg->interlaced = 0;
switch (layer) {
case WIN_OSD0:
case WIN_OSD1:
osdwin = (layer == WIN_OSD0) ? OSDWIN_OSD0 : OSDWIN_OSD1;
osdwin_state = &osd->osdwin[osdwin];
/*
* Other code relies on the fact that OSD windows default to a
* bitmap pixel format when they are deallocated, so don't
* change this default pixel format.
*/
cfg->pixfmt = PIXFMT_8BPP;
_osd_set_layer_config(sd, layer, cfg);
osdwin_state->clut = RAM_CLUT;
_osd_set_osd_clut(sd, osdwin, osdwin_state->clut);
osdwin_state->colorkey_blending = 0;
_osd_disable_color_key(sd, osdwin);
osdwin_state->blend = OSD_8_VID_0;
_osd_set_blending_factor(sd, osdwin, osdwin_state->blend);
osdwin_state->rec601_attenuation = 0;
_osd_set_rec601_attenuation(sd, osdwin,
osdwin_state->
rec601_attenuation);
if (osdwin == OSDWIN_OSD1) {
osd->is_blinking = 0;
osd->blink = BLINK_X1;
}
break;
case WIN_VID0:
case WIN_VID1:
cfg->pixfmt = osd->yc_pixfmt;
_osd_set_layer_config(sd, layer, cfg);
break;
}
spin_unlock_irqrestore(&osd->lock, flags);
}
static void osd_release_layer(struct osd_state *sd, enum osd_layer layer)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
unsigned long flags;
spin_lock_irqsave(&osd->lock, flags);
if (!win->is_allocated) {
spin_unlock_irqrestore(&osd->lock, flags);
return;
}
spin_unlock_irqrestore(&osd->lock, flags);
osd_init_layer(sd, layer);
spin_lock_irqsave(&osd->lock, flags);
win->is_allocated = 0;
spin_unlock_irqrestore(&osd->lock, flags);
}
static int osd_request_layer(struct osd_state *sd, enum osd_layer layer)
{
struct osd_state *osd = sd;
struct osd_window_state *win = &osd->win[layer];
unsigned long flags;
spin_lock_irqsave(&osd->lock, flags);
if (win->is_allocated) {
spin_unlock_irqrestore(&osd->lock, flags);
return -1;
}
win->is_allocated = 1;
spin_unlock_irqrestore(&osd->lock, flags);
return 0;
}
static void _osd_init(struct osd_state *sd)
{
osd_write(sd, 0, OSD_MODE);
osd_write(sd, 0, OSD_VIDWINMD);
osd_write(sd, 0, OSD_OSDWIN0MD);
osd_write(sd, 0, OSD_OSDWIN1MD);
osd_write(sd, 0, OSD_RECTCUR);
osd_write(sd, 0, OSD_MISCCTL);
}
static void osd_set_left_margin(struct osd_state *sd, u32 val)
{
osd_write(sd, val, OSD_BASEPX);
}
static void osd_set_top_margin(struct osd_state *sd, u32 val)
{
osd_write(sd, val, OSD_BASEPY);
}
static int osd_initialize(struct osd_state *osd)
{
if (osd == NULL)
return -ENODEV;
_osd_init(osd);
/* set default Cb/Cr order */
osd->yc_pixfmt = PIXFMT_YCbCrI;
_osd_set_field_inversion(osd, osd->field_inversion);
_osd_set_rom_clut(osd, osd->rom_clut);
osd_init_layer(osd, WIN_OSD0);
osd_init_layer(osd, WIN_VID0);
osd_init_layer(osd, WIN_OSD1);
osd_init_layer(osd, WIN_VID1);
return 0;
}
static const struct vpbe_osd_ops osd_ops = {
.initialize = osd_initialize,
.request_layer = osd_request_layer,
.release_layer = osd_release_layer,
.enable_layer = osd_enable_layer,
.disable_layer = osd_disable_layer,
.set_layer_config = osd_set_layer_config,
.get_layer_config = osd_get_layer_config,
.start_layer = osd_start_layer,
.set_left_margin = osd_set_left_margin,
.set_top_margin = osd_set_top_margin,
};
static int osd_probe(struct platform_device *pdev)
{
struct osd_platform_data *pdata;
struct osd_state *osd;
struct resource *res;
int ret = 0;
osd = kzalloc(sizeof(struct osd_state), GFP_KERNEL);
if (osd == NULL)
return -ENOMEM;
osd->dev = &pdev->dev;
pdata = (struct osd_platform_data *)pdev->dev.platform_data;
osd->vpbe_type = (enum vpbe_version)pdata->vpbe_type;
if (NULL == pdev->dev.platform_data) {
dev_err(osd->dev, "No platform data defined for OSD"
" sub device\n");
ret = -ENOENT;
goto free_mem;
}
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (!res) {
dev_err(osd->dev, "Unable to get OSD register address map\n");
ret = -ENODEV;
goto free_mem;
}
osd->osd_base_phys = res->start;
osd->osd_size = resource_size(res);
if (!request_mem_region(osd->osd_base_phys, osd->osd_size,
MODULE_NAME)) {
dev_err(osd->dev, "Unable to reserve OSD MMIO region\n");
ret = -ENODEV;
goto free_mem;
}
osd->osd_base = (unsigned long)ioremap_nocache(res->start,
osd->osd_size);
if (!osd->osd_base) {
dev_err(osd->dev, "Unable to map the OSD region\n");
ret = -ENODEV;
goto release_mem_region;
}
spin_lock_init(&osd->lock);
osd->ops = osd_ops;
platform_set_drvdata(pdev, osd);
dev_notice(osd->dev, "OSD sub device probe success\n");
return ret;
release_mem_region:
release_mem_region(osd->osd_base_phys, osd->osd_size);
free_mem:
kfree(osd);
return ret;
}
static int osd_remove(struct platform_device *pdev)
{
struct osd_state *osd = platform_get_drvdata(pdev);
iounmap((void *)osd->osd_base);
release_mem_region(osd->osd_base_phys, osd->osd_size);
kfree(osd);
return 0;
}
static struct platform_driver osd_driver = {
.probe = osd_probe,
.remove = osd_remove,
.driver = {
.name = MODULE_NAME,
.owner = THIS_MODULE,
},
};
static int osd_init(void)
{
if (platform_driver_register(&osd_driver)) {
printk(KERN_ERR "Unable to register davinci osd driver\n");
return -ENODEV;
}
return 0;
}
static void osd_exit(void)
{
platform_driver_unregister(&osd_driver);
}
module_init(osd_init);
module_exit(osd_exit);
MODULE_LICENSE("GPL");
MODULE_DESCRIPTION("DaVinci OSD Manager Driver");
MODULE_AUTHOR("Texas Instruments");