linux_dsm_epyc7002/drivers/video/omap2/dss/dispc.c

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/*
* linux/drivers/video/omap2/dss/dispc.c
*
* Copyright (C) 2009 Nokia Corporation
* Author: Tomi Valkeinen <tomi.valkeinen@nokia.com>
*
* Some code and ideas taken from drivers/video/omap/ driver
* by Imre Deak.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 as published by
* the Free Software Foundation.
*
* 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, see <http://www.gnu.org/licenses/>.
*/
#define DSS_SUBSYS_NAME "DISPC"
#include <linux/kernel.h>
#include <linux/dma-mapping.h>
#include <linux/vmalloc.h>
#include <linux/export.h>
#include <linux/clk.h>
#include <linux/io.h>
#include <linux/jiffies.h>
#include <linux/seq_file.h>
#include <linux/delay.h>
#include <linux/workqueue.h>
#include <linux/hardirq.h>
#include <linux/interrupt.h>
#include <linux/platform_device.h>
#include <linux/pm_runtime.h>
#include <video/omapdss.h>
#include "dss.h"
#include "dss_features.h"
#include "dispc.h"
/* DISPC */
#define DISPC_SZ_REGS SZ_4K
#define DISPC_IRQ_MASK_ERROR (DISPC_IRQ_GFX_FIFO_UNDERFLOW | \
DISPC_IRQ_OCP_ERR | \
DISPC_IRQ_VID1_FIFO_UNDERFLOW | \
DISPC_IRQ_VID2_FIFO_UNDERFLOW | \
DISPC_IRQ_SYNC_LOST | \
DISPC_IRQ_SYNC_LOST_DIGIT)
#define DISPC_MAX_NR_ISRS 8
struct omap_dispc_isr_data {
omap_dispc_isr_t isr;
void *arg;
u32 mask;
};
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
enum omap_burst_size {
BURST_SIZE_X2 = 0,
BURST_SIZE_X4 = 1,
BURST_SIZE_X8 = 2,
};
#define REG_GET(idx, start, end) \
FLD_GET(dispc_read_reg(idx), start, end)
#define REG_FLD_MOD(idx, val, start, end) \
dispc_write_reg(idx, FLD_MOD(dispc_read_reg(idx), val, start, end))
struct dispc_irq_stats {
unsigned long last_reset;
unsigned irq_count;
unsigned irqs[32];
};
struct dispc_features {
u8 sw_start;
u8 fp_start;
u8 bp_start;
u16 sw_max;
u16 vp_max;
u16 hp_max;
int (*calc_scaling) (enum omap_channel channel,
const struct omap_video_timings *mgr_timings,
u16 width, u16 height, u16 out_width, u16 out_height,
enum omap_color_mode color_mode, bool *five_taps,
int *x_predecim, int *y_predecim, int *decim_x, int *decim_y,
u16 pos_x, unsigned long *core_clk);
unsigned long (*calc_core_clk) (enum omap_channel channel,
u16 width, u16 height, u16 out_width, u16 out_height);
u8 num_fifos;
/* swap GFX & WB fifos */
bool gfx_fifo_workaround:1;
};
#define DISPC_MAX_NR_FIFOS 5
static struct {
struct platform_device *pdev;
void __iomem *base;
int ctx_loss_cnt;
int irq;
struct clk *dss_clk;
u32 fifo_size[DISPC_MAX_NR_FIFOS];
/* maps which plane is using a fifo. fifo-id -> plane-id */
int fifo_assignment[DISPC_MAX_NR_FIFOS];
spinlock_t irq_lock;
u32 irq_error_mask;
struct omap_dispc_isr_data registered_isr[DISPC_MAX_NR_ISRS];
u32 error_irqs;
struct work_struct error_work;
bool ctx_valid;
u32 ctx[DISPC_SZ_REGS / sizeof(u32)];
const struct dispc_features *feat;
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
spinlock_t irq_stats_lock;
struct dispc_irq_stats irq_stats;
#endif
} dispc;
enum omap_color_component {
/* used for all color formats for OMAP3 and earlier
* and for RGB and Y color component on OMAP4
*/
DISPC_COLOR_COMPONENT_RGB_Y = 1 << 0,
/* used for UV component for
* OMAP_DSS_COLOR_YUV2, OMAP_DSS_COLOR_UYVY, OMAP_DSS_COLOR_NV12
* color formats on OMAP4
*/
DISPC_COLOR_COMPONENT_UV = 1 << 1,
};
enum mgr_reg_fields {
DISPC_MGR_FLD_ENABLE,
DISPC_MGR_FLD_STNTFT,
DISPC_MGR_FLD_GO,
DISPC_MGR_FLD_TFTDATALINES,
DISPC_MGR_FLD_STALLMODE,
DISPC_MGR_FLD_TCKENABLE,
DISPC_MGR_FLD_TCKSELECTION,
DISPC_MGR_FLD_CPR,
DISPC_MGR_FLD_FIFOHANDCHECK,
/* used to maintain a count of the above fields */
DISPC_MGR_FLD_NUM,
};
static const struct {
const char *name;
u32 vsync_irq;
u32 framedone_irq;
u32 sync_lost_irq;
struct reg_field reg_desc[DISPC_MGR_FLD_NUM];
} mgr_desc[] = {
[OMAP_DSS_CHANNEL_LCD] = {
.name = "LCD",
.vsync_irq = DISPC_IRQ_VSYNC,
.framedone_irq = DISPC_IRQ_FRAMEDONE,
.sync_lost_irq = DISPC_IRQ_SYNC_LOST,
.reg_desc = {
[DISPC_MGR_FLD_ENABLE] = { DISPC_CONTROL, 0, 0 },
[DISPC_MGR_FLD_STNTFT] = { DISPC_CONTROL, 3, 3 },
[DISPC_MGR_FLD_GO] = { DISPC_CONTROL, 5, 5 },
[DISPC_MGR_FLD_TFTDATALINES] = { DISPC_CONTROL, 9, 8 },
[DISPC_MGR_FLD_STALLMODE] = { DISPC_CONTROL, 11, 11 },
[DISPC_MGR_FLD_TCKENABLE] = { DISPC_CONFIG, 10, 10 },
[DISPC_MGR_FLD_TCKSELECTION] = { DISPC_CONFIG, 11, 11 },
[DISPC_MGR_FLD_CPR] = { DISPC_CONFIG, 15, 15 },
[DISPC_MGR_FLD_FIFOHANDCHECK] = { DISPC_CONFIG, 16, 16 },
},
},
[OMAP_DSS_CHANNEL_DIGIT] = {
.name = "DIGIT",
.vsync_irq = DISPC_IRQ_EVSYNC_ODD | DISPC_IRQ_EVSYNC_EVEN,
.framedone_irq = 0,
.sync_lost_irq = DISPC_IRQ_SYNC_LOST_DIGIT,
.reg_desc = {
[DISPC_MGR_FLD_ENABLE] = { DISPC_CONTROL, 1, 1 },
[DISPC_MGR_FLD_STNTFT] = { },
[DISPC_MGR_FLD_GO] = { DISPC_CONTROL, 6, 6 },
[DISPC_MGR_FLD_TFTDATALINES] = { },
[DISPC_MGR_FLD_STALLMODE] = { },
[DISPC_MGR_FLD_TCKENABLE] = { DISPC_CONFIG, 12, 12 },
[DISPC_MGR_FLD_TCKSELECTION] = { DISPC_CONFIG, 13, 13 },
[DISPC_MGR_FLD_CPR] = { },
[DISPC_MGR_FLD_FIFOHANDCHECK] = { DISPC_CONFIG, 16, 16 },
},
},
[OMAP_DSS_CHANNEL_LCD2] = {
.name = "LCD2",
.vsync_irq = DISPC_IRQ_VSYNC2,
.framedone_irq = DISPC_IRQ_FRAMEDONE2,
.sync_lost_irq = DISPC_IRQ_SYNC_LOST2,
.reg_desc = {
[DISPC_MGR_FLD_ENABLE] = { DISPC_CONTROL2, 0, 0 },
[DISPC_MGR_FLD_STNTFT] = { DISPC_CONTROL2, 3, 3 },
[DISPC_MGR_FLD_GO] = { DISPC_CONTROL2, 5, 5 },
[DISPC_MGR_FLD_TFTDATALINES] = { DISPC_CONTROL2, 9, 8 },
[DISPC_MGR_FLD_STALLMODE] = { DISPC_CONTROL2, 11, 11 },
[DISPC_MGR_FLD_TCKENABLE] = { DISPC_CONFIG2, 10, 10 },
[DISPC_MGR_FLD_TCKSELECTION] = { DISPC_CONFIG2, 11, 11 },
[DISPC_MGR_FLD_CPR] = { DISPC_CONFIG2, 15, 15 },
[DISPC_MGR_FLD_FIFOHANDCHECK] = { DISPC_CONFIG2, 16, 16 },
},
},
[OMAP_DSS_CHANNEL_LCD3] = {
.name = "LCD3",
.vsync_irq = DISPC_IRQ_VSYNC3,
.framedone_irq = DISPC_IRQ_FRAMEDONE3,
.sync_lost_irq = DISPC_IRQ_SYNC_LOST3,
.reg_desc = {
[DISPC_MGR_FLD_ENABLE] = { DISPC_CONTROL3, 0, 0 },
[DISPC_MGR_FLD_STNTFT] = { DISPC_CONTROL3, 3, 3 },
[DISPC_MGR_FLD_GO] = { DISPC_CONTROL3, 5, 5 },
[DISPC_MGR_FLD_TFTDATALINES] = { DISPC_CONTROL3, 9, 8 },
[DISPC_MGR_FLD_STALLMODE] = { DISPC_CONTROL3, 11, 11 },
[DISPC_MGR_FLD_TCKENABLE] = { DISPC_CONFIG3, 10, 10 },
[DISPC_MGR_FLD_TCKSELECTION] = { DISPC_CONFIG3, 11, 11 },
[DISPC_MGR_FLD_CPR] = { DISPC_CONFIG3, 15, 15 },
[DISPC_MGR_FLD_FIFOHANDCHECK] = { DISPC_CONFIG3, 16, 16 },
},
},
};
static void _omap_dispc_set_irqs(void);
static inline void dispc_write_reg(const u16 idx, u32 val)
{
__raw_writel(val, dispc.base + idx);
}
static inline u32 dispc_read_reg(const u16 idx)
{
return __raw_readl(dispc.base + idx);
}
static u32 mgr_fld_read(enum omap_channel channel, enum mgr_reg_fields regfld)
{
const struct reg_field rfld = mgr_desc[channel].reg_desc[regfld];
return REG_GET(rfld.reg, rfld.high, rfld.low);
}
static void mgr_fld_write(enum omap_channel channel,
enum mgr_reg_fields regfld, int val) {
const struct reg_field rfld = mgr_desc[channel].reg_desc[regfld];
REG_FLD_MOD(rfld.reg, val, rfld.high, rfld.low);
}
#define SR(reg) \
dispc.ctx[DISPC_##reg / sizeof(u32)] = dispc_read_reg(DISPC_##reg)
#define RR(reg) \
dispc_write_reg(DISPC_##reg, dispc.ctx[DISPC_##reg / sizeof(u32)])
static void dispc_save_context(void)
{
int i, j;
DSSDBG("dispc_save_context\n");
SR(IRQENABLE);
SR(CONTROL);
SR(CONFIG);
SR(LINE_NUMBER);
OMAPDSS/OMAP_VOUT: Fix incorrect OMAP3-alpha compatibility setting On OMAP3, in order to enable alpha blending for LCD and TV managers, we needed to set LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits in DISPC_CONFIG. On OMAP4, alpha blending is always enabled by default, if the above bits are set, we switch to an OMAP3 compatibility mode where the zorder values in the pipeline attribute registers are ignored and a fixed priority is configured. Rename the manager_info member "alpha_enabled" to "partial_alpha_enabled" for more clarity. Introduce two dss_features FEAT_ALPHA_FIXED_ZORDER and FEAT_ALPHA_FREE_ZORDER which represent OMAP3-alpha compatibility mode and OMAP4 alpha mode respectively. Introduce an overlay cap for ZORDER. The DSS2 user is expected to check for the ZORDER cap, if an overlay doesn't have this cap, the user is expected to set the parameter partial_alpha_enabled. If the overlay has ZORDER cap, the DSS2 user can assume that alpha blending is already enabled. Don't support OMAP3 compatibility mode for now. Trying to read/write to alpha_blending_enabled sysfs attribute issues a warning for OMAP4 and does not set the LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits. Change alpha_enabled to partial_alpha_enabled in the omap_vout driver. Use overlay cap "OMAP_DSS_OVL_CAP_GLOBAL_ALPHA" to check if overlay supports alpha blending or not. Replace this with checks for VIDEO1 pipeline. Cc: linux-media@vger.kernel.org Cc: Lajos Molnar <molnar@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Acked-by: Vaibhav Hiremath <hvaibhav@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-09-26 13:17:29 +07:00
if (dss_has_feature(FEAT_ALPHA_FIXED_ZORDER) ||
dss_has_feature(FEAT_ALPHA_FREE_ZORDER))
SR(GLOBAL_ALPHA);
if (dss_has_feature(FEAT_MGR_LCD2)) {
SR(CONTROL2);
SR(CONFIG2);
}
if (dss_has_feature(FEAT_MGR_LCD3)) {
SR(CONTROL3);
SR(CONFIG3);
}
for (i = 0; i < dss_feat_get_num_mgrs(); i++) {
SR(DEFAULT_COLOR(i));
SR(TRANS_COLOR(i));
SR(SIZE_MGR(i));
if (i == OMAP_DSS_CHANNEL_DIGIT)
continue;
SR(TIMING_H(i));
SR(TIMING_V(i));
SR(POL_FREQ(i));
SR(DIVISORo(i));
SR(DATA_CYCLE1(i));
SR(DATA_CYCLE2(i));
SR(DATA_CYCLE3(i));
if (dss_has_feature(FEAT_CPR)) {
SR(CPR_COEF_R(i));
SR(CPR_COEF_G(i));
SR(CPR_COEF_B(i));
}
}
for (i = 0; i < dss_feat_get_num_ovls(); i++) {
SR(OVL_BA0(i));
SR(OVL_BA1(i));
SR(OVL_POSITION(i));
SR(OVL_SIZE(i));
SR(OVL_ATTRIBUTES(i));
SR(OVL_FIFO_THRESHOLD(i));
SR(OVL_ROW_INC(i));
SR(OVL_PIXEL_INC(i));
if (dss_has_feature(FEAT_PRELOAD))
SR(OVL_PRELOAD(i));
if (i == OMAP_DSS_GFX) {
SR(OVL_WINDOW_SKIP(i));
SR(OVL_TABLE_BA(i));
continue;
}
SR(OVL_FIR(i));
SR(OVL_PICTURE_SIZE(i));
SR(OVL_ACCU0(i));
SR(OVL_ACCU1(i));
for (j = 0; j < 8; j++)
SR(OVL_FIR_COEF_H(i, j));
for (j = 0; j < 8; j++)
SR(OVL_FIR_COEF_HV(i, j));
for (j = 0; j < 5; j++)
SR(OVL_CONV_COEF(i, j));
if (dss_has_feature(FEAT_FIR_COEF_V)) {
for (j = 0; j < 8; j++)
SR(OVL_FIR_COEF_V(i, j));
}
if (dss_has_feature(FEAT_HANDLE_UV_SEPARATE)) {
SR(OVL_BA0_UV(i));
SR(OVL_BA1_UV(i));
SR(OVL_FIR2(i));
SR(OVL_ACCU2_0(i));
SR(OVL_ACCU2_1(i));
for (j = 0; j < 8; j++)
SR(OVL_FIR_COEF_H2(i, j));
for (j = 0; j < 8; j++)
SR(OVL_FIR_COEF_HV2(i, j));
for (j = 0; j < 8; j++)
SR(OVL_FIR_COEF_V2(i, j));
}
if (dss_has_feature(FEAT_ATTR2))
SR(OVL_ATTRIBUTES2(i));
}
if (dss_has_feature(FEAT_CORE_CLK_DIV))
SR(DIVISOR);
dispc.ctx_loss_cnt = dss_get_ctx_loss_count(&dispc.pdev->dev);
dispc.ctx_valid = true;
DSSDBG("context saved, ctx_loss_count %d\n", dispc.ctx_loss_cnt);
}
static void dispc_restore_context(void)
{
int i, j, ctx;
DSSDBG("dispc_restore_context\n");
if (!dispc.ctx_valid)
return;
ctx = dss_get_ctx_loss_count(&dispc.pdev->dev);
if (ctx >= 0 && ctx == dispc.ctx_loss_cnt)
return;
DSSDBG("ctx_loss_count: saved %d, current %d\n",
dispc.ctx_loss_cnt, ctx);
/*RR(IRQENABLE);*/
/*RR(CONTROL);*/
RR(CONFIG);
RR(LINE_NUMBER);
OMAPDSS/OMAP_VOUT: Fix incorrect OMAP3-alpha compatibility setting On OMAP3, in order to enable alpha blending for LCD and TV managers, we needed to set LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits in DISPC_CONFIG. On OMAP4, alpha blending is always enabled by default, if the above bits are set, we switch to an OMAP3 compatibility mode where the zorder values in the pipeline attribute registers are ignored and a fixed priority is configured. Rename the manager_info member "alpha_enabled" to "partial_alpha_enabled" for more clarity. Introduce two dss_features FEAT_ALPHA_FIXED_ZORDER and FEAT_ALPHA_FREE_ZORDER which represent OMAP3-alpha compatibility mode and OMAP4 alpha mode respectively. Introduce an overlay cap for ZORDER. The DSS2 user is expected to check for the ZORDER cap, if an overlay doesn't have this cap, the user is expected to set the parameter partial_alpha_enabled. If the overlay has ZORDER cap, the DSS2 user can assume that alpha blending is already enabled. Don't support OMAP3 compatibility mode for now. Trying to read/write to alpha_blending_enabled sysfs attribute issues a warning for OMAP4 and does not set the LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits. Change alpha_enabled to partial_alpha_enabled in the omap_vout driver. Use overlay cap "OMAP_DSS_OVL_CAP_GLOBAL_ALPHA" to check if overlay supports alpha blending or not. Replace this with checks for VIDEO1 pipeline. Cc: linux-media@vger.kernel.org Cc: Lajos Molnar <molnar@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Acked-by: Vaibhav Hiremath <hvaibhav@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-09-26 13:17:29 +07:00
if (dss_has_feature(FEAT_ALPHA_FIXED_ZORDER) ||
dss_has_feature(FEAT_ALPHA_FREE_ZORDER))
RR(GLOBAL_ALPHA);
if (dss_has_feature(FEAT_MGR_LCD2))
RR(CONFIG2);
if (dss_has_feature(FEAT_MGR_LCD3))
RR(CONFIG3);
for (i = 0; i < dss_feat_get_num_mgrs(); i++) {
RR(DEFAULT_COLOR(i));
RR(TRANS_COLOR(i));
RR(SIZE_MGR(i));
if (i == OMAP_DSS_CHANNEL_DIGIT)
continue;
RR(TIMING_H(i));
RR(TIMING_V(i));
RR(POL_FREQ(i));
RR(DIVISORo(i));
RR(DATA_CYCLE1(i));
RR(DATA_CYCLE2(i));
RR(DATA_CYCLE3(i));
if (dss_has_feature(FEAT_CPR)) {
RR(CPR_COEF_R(i));
RR(CPR_COEF_G(i));
RR(CPR_COEF_B(i));
}
}
for (i = 0; i < dss_feat_get_num_ovls(); i++) {
RR(OVL_BA0(i));
RR(OVL_BA1(i));
RR(OVL_POSITION(i));
RR(OVL_SIZE(i));
RR(OVL_ATTRIBUTES(i));
RR(OVL_FIFO_THRESHOLD(i));
RR(OVL_ROW_INC(i));
RR(OVL_PIXEL_INC(i));
if (dss_has_feature(FEAT_PRELOAD))
RR(OVL_PRELOAD(i));
if (i == OMAP_DSS_GFX) {
RR(OVL_WINDOW_SKIP(i));
RR(OVL_TABLE_BA(i));
continue;
}
RR(OVL_FIR(i));
RR(OVL_PICTURE_SIZE(i));
RR(OVL_ACCU0(i));
RR(OVL_ACCU1(i));
for (j = 0; j < 8; j++)
RR(OVL_FIR_COEF_H(i, j));
for (j = 0; j < 8; j++)
RR(OVL_FIR_COEF_HV(i, j));
for (j = 0; j < 5; j++)
RR(OVL_CONV_COEF(i, j));
if (dss_has_feature(FEAT_FIR_COEF_V)) {
for (j = 0; j < 8; j++)
RR(OVL_FIR_COEF_V(i, j));
}
if (dss_has_feature(FEAT_HANDLE_UV_SEPARATE)) {
RR(OVL_BA0_UV(i));
RR(OVL_BA1_UV(i));
RR(OVL_FIR2(i));
RR(OVL_ACCU2_0(i));
RR(OVL_ACCU2_1(i));
for (j = 0; j < 8; j++)
RR(OVL_FIR_COEF_H2(i, j));
for (j = 0; j < 8; j++)
RR(OVL_FIR_COEF_HV2(i, j));
for (j = 0; j < 8; j++)
RR(OVL_FIR_COEF_V2(i, j));
}
if (dss_has_feature(FEAT_ATTR2))
RR(OVL_ATTRIBUTES2(i));
}
if (dss_has_feature(FEAT_CORE_CLK_DIV))
RR(DIVISOR);
/* enable last, because LCD & DIGIT enable are here */
RR(CONTROL);
if (dss_has_feature(FEAT_MGR_LCD2))
RR(CONTROL2);
if (dss_has_feature(FEAT_MGR_LCD3))
RR(CONTROL3);
/* clear spurious SYNC_LOST_DIGIT interrupts */
dispc_write_reg(DISPC_IRQSTATUS, DISPC_IRQ_SYNC_LOST_DIGIT);
/*
* enable last so IRQs won't trigger before
* the context is fully restored
*/
RR(IRQENABLE);
DSSDBG("context restored\n");
}
#undef SR
#undef RR
int dispc_runtime_get(void)
{
int r;
DSSDBG("dispc_runtime_get\n");
r = pm_runtime_get_sync(&dispc.pdev->dev);
WARN_ON(r < 0);
return r < 0 ? r : 0;
}
void dispc_runtime_put(void)
{
int r;
DSSDBG("dispc_runtime_put\n");
r = pm_runtime_put_sync(&dispc.pdev->dev);
WARN_ON(r < 0 && r != -ENOSYS);
}
u32 dispc_mgr_get_vsync_irq(enum omap_channel channel)
{
return mgr_desc[channel].vsync_irq;
}
u32 dispc_mgr_get_framedone_irq(enum omap_channel channel)
{
return mgr_desc[channel].framedone_irq;
}
bool dispc_mgr_go_busy(enum omap_channel channel)
{
return mgr_fld_read(channel, DISPC_MGR_FLD_GO) == 1;
}
void dispc_mgr_go(enum omap_channel channel)
{
bool enable_bit, go_bit;
/* if the channel is not enabled, we don't need GO */
enable_bit = mgr_fld_read(channel, DISPC_MGR_FLD_ENABLE) == 1;
if (!enable_bit)
return;
go_bit = mgr_fld_read(channel, DISPC_MGR_FLD_GO) == 1;
if (go_bit) {
DSSERR("GO bit not down for channel %d\n", channel);
return;
}
DSSDBG("GO %s\n", mgr_desc[channel].name);
mgr_fld_write(channel, DISPC_MGR_FLD_GO, 1);
}
static void dispc_ovl_write_firh_reg(enum omap_plane plane, int reg, u32 value)
{
dispc_write_reg(DISPC_OVL_FIR_COEF_H(plane, reg), value);
}
static void dispc_ovl_write_firhv_reg(enum omap_plane plane, int reg, u32 value)
{
dispc_write_reg(DISPC_OVL_FIR_COEF_HV(plane, reg), value);
}
static void dispc_ovl_write_firv_reg(enum omap_plane plane, int reg, u32 value)
{
dispc_write_reg(DISPC_OVL_FIR_COEF_V(plane, reg), value);
}
static void dispc_ovl_write_firh2_reg(enum omap_plane plane, int reg, u32 value)
{
BUG_ON(plane == OMAP_DSS_GFX);
dispc_write_reg(DISPC_OVL_FIR_COEF_H2(plane, reg), value);
}
static void dispc_ovl_write_firhv2_reg(enum omap_plane plane, int reg,
u32 value)
{
BUG_ON(plane == OMAP_DSS_GFX);
dispc_write_reg(DISPC_OVL_FIR_COEF_HV2(plane, reg), value);
}
static void dispc_ovl_write_firv2_reg(enum omap_plane plane, int reg, u32 value)
{
BUG_ON(plane == OMAP_DSS_GFX);
dispc_write_reg(DISPC_OVL_FIR_COEF_V2(plane, reg), value);
}
static void dispc_ovl_set_scale_coef(enum omap_plane plane, int fir_hinc,
int fir_vinc, int five_taps,
enum omap_color_component color_comp)
{
const struct dispc_coef *h_coef, *v_coef;
int i;
h_coef = dispc_ovl_get_scale_coef(fir_hinc, true);
v_coef = dispc_ovl_get_scale_coef(fir_vinc, five_taps);
for (i = 0; i < 8; i++) {
u32 h, hv;
h = FLD_VAL(h_coef[i].hc0_vc00, 7, 0)
| FLD_VAL(h_coef[i].hc1_vc0, 15, 8)
| FLD_VAL(h_coef[i].hc2_vc1, 23, 16)
| FLD_VAL(h_coef[i].hc3_vc2, 31, 24);
hv = FLD_VAL(h_coef[i].hc4_vc22, 7, 0)
| FLD_VAL(v_coef[i].hc1_vc0, 15, 8)
| FLD_VAL(v_coef[i].hc2_vc1, 23, 16)
| FLD_VAL(v_coef[i].hc3_vc2, 31, 24);
if (color_comp == DISPC_COLOR_COMPONENT_RGB_Y) {
dispc_ovl_write_firh_reg(plane, i, h);
dispc_ovl_write_firhv_reg(plane, i, hv);
} else {
dispc_ovl_write_firh2_reg(plane, i, h);
dispc_ovl_write_firhv2_reg(plane, i, hv);
}
}
if (five_taps) {
for (i = 0; i < 8; i++) {
u32 v;
v = FLD_VAL(v_coef[i].hc0_vc00, 7, 0)
| FLD_VAL(v_coef[i].hc4_vc22, 15, 8);
if (color_comp == DISPC_COLOR_COMPONENT_RGB_Y)
dispc_ovl_write_firv_reg(plane, i, v);
else
dispc_ovl_write_firv2_reg(plane, i, v);
}
}
}
static void _dispc_setup_color_conv_coef(void)
{
int i;
const struct color_conv_coef {
int ry, rcr, rcb, gy, gcr, gcb, by, bcr, bcb;
int full_range;
} ctbl_bt601_5 = {
298, 409, 0, 298, -208, -100, 298, 0, 517, 0,
};
const struct color_conv_coef *ct;
#define CVAL(x, y) (FLD_VAL(x, 26, 16) | FLD_VAL(y, 10, 0))
ct = &ctbl_bt601_5;
for (i = 1; i < dss_feat_get_num_ovls(); i++) {
dispc_write_reg(DISPC_OVL_CONV_COEF(i, 0),
CVAL(ct->rcr, ct->ry));
dispc_write_reg(DISPC_OVL_CONV_COEF(i, 1),
CVAL(ct->gy, ct->rcb));
dispc_write_reg(DISPC_OVL_CONV_COEF(i, 2),
CVAL(ct->gcb, ct->gcr));
dispc_write_reg(DISPC_OVL_CONV_COEF(i, 3),
CVAL(ct->bcr, ct->by));
dispc_write_reg(DISPC_OVL_CONV_COEF(i, 4),
CVAL(0, ct->bcb));
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(i), ct->full_range,
11, 11);
}
#undef CVAL
}
static void dispc_ovl_set_ba0(enum omap_plane plane, u32 paddr)
{
dispc_write_reg(DISPC_OVL_BA0(plane), paddr);
}
static void dispc_ovl_set_ba1(enum omap_plane plane, u32 paddr)
{
dispc_write_reg(DISPC_OVL_BA1(plane), paddr);
}
static void dispc_ovl_set_ba0_uv(enum omap_plane plane, u32 paddr)
{
dispc_write_reg(DISPC_OVL_BA0_UV(plane), paddr);
}
static void dispc_ovl_set_ba1_uv(enum omap_plane plane, u32 paddr)
{
dispc_write_reg(DISPC_OVL_BA1_UV(plane), paddr);
}
static void dispc_ovl_set_pos(enum omap_plane plane,
enum omap_overlay_caps caps, int x, int y)
{
u32 val;
if ((caps & OMAP_DSS_OVL_CAP_POS) == 0)
return;
val = FLD_VAL(y, 26, 16) | FLD_VAL(x, 10, 0);
dispc_write_reg(DISPC_OVL_POSITION(plane), val);
}
static void dispc_ovl_set_input_size(enum omap_plane plane, int width,
int height)
{
u32 val = FLD_VAL(height - 1, 26, 16) | FLD_VAL(width - 1, 10, 0);
if (plane == OMAP_DSS_GFX)
dispc_write_reg(DISPC_OVL_SIZE(plane), val);
else
dispc_write_reg(DISPC_OVL_PICTURE_SIZE(plane), val);
}
static void dispc_ovl_set_output_size(enum omap_plane plane, int width,
int height)
{
u32 val;
BUG_ON(plane == OMAP_DSS_GFX);
val = FLD_VAL(height - 1, 26, 16) | FLD_VAL(width - 1, 10, 0);
dispc_write_reg(DISPC_OVL_SIZE(plane), val);
}
static void dispc_ovl_set_zorder(enum omap_plane plane,
enum omap_overlay_caps caps, u8 zorder)
{
if ((caps & OMAP_DSS_OVL_CAP_ZORDER) == 0)
return;
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), zorder, 27, 26);
}
static void dispc_ovl_enable_zorder_planes(void)
{
int i;
if (!dss_has_feature(FEAT_ALPHA_FREE_ZORDER))
return;
for (i = 0; i < dss_feat_get_num_ovls(); i++)
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(i), 1, 25, 25);
}
static void dispc_ovl_set_pre_mult_alpha(enum omap_plane plane,
enum omap_overlay_caps caps, bool enable)
{
if ((caps & OMAP_DSS_OVL_CAP_PRE_MULT_ALPHA) == 0)
return;
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), enable ? 1 : 0, 28, 28);
}
static void dispc_ovl_setup_global_alpha(enum omap_plane plane,
enum omap_overlay_caps caps, u8 global_alpha)
{
static const unsigned shifts[] = { 0, 8, 16, 24, };
int shift;
if ((caps & OMAP_DSS_OVL_CAP_GLOBAL_ALPHA) == 0)
return;
shift = shifts[plane];
REG_FLD_MOD(DISPC_GLOBAL_ALPHA, global_alpha, shift + 7, shift);
}
static void dispc_ovl_set_pix_inc(enum omap_plane plane, s32 inc)
{
dispc_write_reg(DISPC_OVL_PIXEL_INC(plane), inc);
}
static void dispc_ovl_set_row_inc(enum omap_plane plane, s32 inc)
{
dispc_write_reg(DISPC_OVL_ROW_INC(plane), inc);
}
static void dispc_ovl_set_color_mode(enum omap_plane plane,
enum omap_color_mode color_mode)
{
u32 m = 0;
if (plane != OMAP_DSS_GFX) {
switch (color_mode) {
case OMAP_DSS_COLOR_NV12:
m = 0x0; break;
case OMAP_DSS_COLOR_RGBX16:
m = 0x1; break;
case OMAP_DSS_COLOR_RGBA16:
m = 0x2; break;
case OMAP_DSS_COLOR_RGB12U:
m = 0x4; break;
case OMAP_DSS_COLOR_ARGB16:
m = 0x5; break;
case OMAP_DSS_COLOR_RGB16:
m = 0x6; break;
case OMAP_DSS_COLOR_ARGB16_1555:
m = 0x7; break;
case OMAP_DSS_COLOR_RGB24U:
m = 0x8; break;
case OMAP_DSS_COLOR_RGB24P:
m = 0x9; break;
case OMAP_DSS_COLOR_YUV2:
m = 0xa; break;
case OMAP_DSS_COLOR_UYVY:
m = 0xb; break;
case OMAP_DSS_COLOR_ARGB32:
m = 0xc; break;
case OMAP_DSS_COLOR_RGBA32:
m = 0xd; break;
case OMAP_DSS_COLOR_RGBX32:
m = 0xe; break;
case OMAP_DSS_COLOR_XRGB16_1555:
m = 0xf; break;
default:
BUG(); return;
}
} else {
switch (color_mode) {
case OMAP_DSS_COLOR_CLUT1:
m = 0x0; break;
case OMAP_DSS_COLOR_CLUT2:
m = 0x1; break;
case OMAP_DSS_COLOR_CLUT4:
m = 0x2; break;
case OMAP_DSS_COLOR_CLUT8:
m = 0x3; break;
case OMAP_DSS_COLOR_RGB12U:
m = 0x4; break;
case OMAP_DSS_COLOR_ARGB16:
m = 0x5; break;
case OMAP_DSS_COLOR_RGB16:
m = 0x6; break;
case OMAP_DSS_COLOR_ARGB16_1555:
m = 0x7; break;
case OMAP_DSS_COLOR_RGB24U:
m = 0x8; break;
case OMAP_DSS_COLOR_RGB24P:
m = 0x9; break;
case OMAP_DSS_COLOR_RGBX16:
m = 0xa; break;
case OMAP_DSS_COLOR_RGBA16:
m = 0xb; break;
case OMAP_DSS_COLOR_ARGB32:
m = 0xc; break;
case OMAP_DSS_COLOR_RGBA32:
m = 0xd; break;
case OMAP_DSS_COLOR_RGBX32:
m = 0xe; break;
case OMAP_DSS_COLOR_XRGB16_1555:
m = 0xf; break;
default:
BUG(); return;
}
}
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), m, 4, 1);
}
OMAPDSS: DISPC: Support rotation through TILER TILER is a block in OMAP4's DMM which lets DSS fetch frames in a rotated manner. Physical memory can be mapped to a portion of OMAP's system address space called TILER address space. The TILER address space is split into 8 views. Each view represents a rotated or mirrored form of the mapped physical memory. When a DISPC overlay's base address is programmed to one of these views, the TILER fetches the pixels according to the orientation of the view. A view is further split into 4 containers, each container holds elements of a particular size. Rotation can be achieved at the granularity of elements in the container. For more information on TILER, refer to the Memory Subsytem section in OMAP4 TRM. Rotation type TILER has been added which is used to exploit the capabilities of these 8 views for performing various rotations. When fetching from addresses mapped to TILER space, the DISPC DMA can fetch pixels in either 1D or 2D bursts. The fetch depends on which TILER container we are accessing. Accessing 8, 16 and 32 bit sized containers requires 2D bursts, and page mode sized containers require 1D bursts. The DSS2 user is expected to provide the Tiler address of the view that it is interested in. This is passed to the paddr and p_uv_addr parameters in omap_overlay_info. It is also expected to provide the stride value based on the view's orientation and container type, this should be passed to the screen_width parameter of omap_overlay_info. In calc_tiler_rotation_offset screen_width is used to calculate the required row_inc for DISPC. x_predecim and y_predecim are also used to calculate row_inc and pix_inc thereby adding predecimation support for TILER. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-11 20:49:55 +07:00
static void dispc_ovl_configure_burst_type(enum omap_plane plane,
enum omap_dss_rotation_type rotation_type)
{
if (dss_has_feature(FEAT_BURST_2D) == 0)
return;
if (rotation_type == OMAP_DSS_ROT_TILER)
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), 1, 29, 29);
else
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), 0, 29, 29);
}
void dispc_ovl_set_channel_out(enum omap_plane plane, enum omap_channel channel)
{
int shift;
u32 val;
int chan = 0, chan2 = 0;
switch (plane) {
case OMAP_DSS_GFX:
shift = 8;
break;
case OMAP_DSS_VIDEO1:
case OMAP_DSS_VIDEO2:
case OMAP_DSS_VIDEO3:
shift = 16;
break;
default:
BUG();
return;
}
val = dispc_read_reg(DISPC_OVL_ATTRIBUTES(plane));
if (dss_has_feature(FEAT_MGR_LCD2)) {
switch (channel) {
case OMAP_DSS_CHANNEL_LCD:
chan = 0;
chan2 = 0;
break;
case OMAP_DSS_CHANNEL_DIGIT:
chan = 1;
chan2 = 0;
break;
case OMAP_DSS_CHANNEL_LCD2:
chan = 0;
chan2 = 1;
break;
case OMAP_DSS_CHANNEL_LCD3:
if (dss_has_feature(FEAT_MGR_LCD3)) {
chan = 0;
chan2 = 2;
} else {
BUG();
return;
}
break;
default:
BUG();
return;
}
val = FLD_MOD(val, chan, shift, shift);
val = FLD_MOD(val, chan2, 31, 30);
} else {
val = FLD_MOD(val, channel, shift, shift);
}
dispc_write_reg(DISPC_OVL_ATTRIBUTES(plane), val);
}
static enum omap_channel dispc_ovl_get_channel_out(enum omap_plane plane)
{
int shift;
u32 val;
enum omap_channel channel;
switch (plane) {
case OMAP_DSS_GFX:
shift = 8;
break;
case OMAP_DSS_VIDEO1:
case OMAP_DSS_VIDEO2:
case OMAP_DSS_VIDEO3:
shift = 16;
break;
default:
BUG();
return 0;
}
val = dispc_read_reg(DISPC_OVL_ATTRIBUTES(plane));
if (dss_has_feature(FEAT_MGR_LCD3)) {
if (FLD_GET(val, 31, 30) == 0)
channel = FLD_GET(val, shift, shift);
else if (FLD_GET(val, 31, 30) == 1)
channel = OMAP_DSS_CHANNEL_LCD2;
else
channel = OMAP_DSS_CHANNEL_LCD3;
} else if (dss_has_feature(FEAT_MGR_LCD2)) {
if (FLD_GET(val, 31, 30) == 0)
channel = FLD_GET(val, shift, shift);
else
channel = OMAP_DSS_CHANNEL_LCD2;
} else {
channel = FLD_GET(val, shift, shift);
}
return channel;
}
static void dispc_ovl_set_burst_size(enum omap_plane plane,
enum omap_burst_size burst_size)
{
static const unsigned shifts[] = { 6, 14, 14, 14, };
int shift;
shift = shifts[plane];
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), burst_size, shift + 1, shift);
}
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
static void dispc_configure_burst_sizes(void)
{
int i;
const int burst_size = BURST_SIZE_X8;
/* Configure burst size always to maximum size */
for (i = 0; i < omap_dss_get_num_overlays(); ++i)
dispc_ovl_set_burst_size(i, burst_size);
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
}
static u32 dispc_ovl_get_burst_size(enum omap_plane plane)
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
{
unsigned unit = dss_feat_get_burst_size_unit();
/* burst multiplier is always x8 (see dispc_configure_burst_sizes()) */
return unit * 8;
}
void dispc_enable_gamma_table(bool enable)
{
/*
* This is partially implemented to support only disabling of
* the gamma table.
*/
if (enable) {
DSSWARN("Gamma table enabling for TV not yet supported");
return;
}
REG_FLD_MOD(DISPC_CONFIG, enable, 9, 9);
}
static void dispc_mgr_enable_cpr(enum omap_channel channel, bool enable)
{
if (channel == OMAP_DSS_CHANNEL_DIGIT)
return;
mgr_fld_write(channel, DISPC_MGR_FLD_CPR, enable);
}
static void dispc_mgr_set_cpr_coef(enum omap_channel channel,
struct omap_dss_cpr_coefs *coefs)
{
u32 coef_r, coef_g, coef_b;
if (!dss_mgr_is_lcd(channel))
return;
coef_r = FLD_VAL(coefs->rr, 31, 22) | FLD_VAL(coefs->rg, 20, 11) |
FLD_VAL(coefs->rb, 9, 0);
coef_g = FLD_VAL(coefs->gr, 31, 22) | FLD_VAL(coefs->gg, 20, 11) |
FLD_VAL(coefs->gb, 9, 0);
coef_b = FLD_VAL(coefs->br, 31, 22) | FLD_VAL(coefs->bg, 20, 11) |
FLD_VAL(coefs->bb, 9, 0);
dispc_write_reg(DISPC_CPR_COEF_R(channel), coef_r);
dispc_write_reg(DISPC_CPR_COEF_G(channel), coef_g);
dispc_write_reg(DISPC_CPR_COEF_B(channel), coef_b);
}
static void dispc_ovl_set_vid_color_conv(enum omap_plane plane, bool enable)
{
u32 val;
BUG_ON(plane == OMAP_DSS_GFX);
val = dispc_read_reg(DISPC_OVL_ATTRIBUTES(plane));
val = FLD_MOD(val, enable, 9, 9);
dispc_write_reg(DISPC_OVL_ATTRIBUTES(plane), val);
}
static void dispc_ovl_enable_replication(enum omap_plane plane,
enum omap_overlay_caps caps, bool enable)
{
static const unsigned shifts[] = { 5, 10, 10, 10 };
int shift;
if ((caps & OMAP_DSS_OVL_CAP_REPLICATION) == 0)
return;
shift = shifts[plane];
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), enable, shift, shift);
}
static void dispc_mgr_set_size(enum omap_channel channel, u16 width,
u16 height)
{
u32 val;
val = FLD_VAL(height - 1, 26, 16) | FLD_VAL(width - 1, 10, 0);
dispc_write_reg(DISPC_SIZE_MGR(channel), val);
}
static void dispc_init_fifos(void)
{
u32 size;
int fifo;
u8 start, end;
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
u32 unit;
unit = dss_feat_get_buffer_size_unit();
dss_feat_get_reg_field(FEAT_REG_FIFOSIZE, &start, &end);
for (fifo = 0; fifo < dispc.feat->num_fifos; ++fifo) {
size = REG_GET(DISPC_OVL_FIFO_SIZE_STATUS(fifo), start, end);
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
size *= unit;
dispc.fifo_size[fifo] = size;
/*
* By default fifos are mapped directly to overlays, fifo 0 to
* ovl 0, fifo 1 to ovl 1, etc.
*/
dispc.fifo_assignment[fifo] = fifo;
}
/*
* The GFX fifo on OMAP4 is smaller than the other fifos. The small fifo
* causes problems with certain use cases, like using the tiler in 2D
* mode. The below hack swaps the fifos of GFX and WB planes, thus
* giving GFX plane a larger fifo. WB but should work fine with a
* smaller fifo.
*/
if (dispc.feat->gfx_fifo_workaround) {
u32 v;
v = dispc_read_reg(DISPC_GLOBAL_BUFFER);
v = FLD_MOD(v, 4, 2, 0); /* GFX BUF top to WB */
v = FLD_MOD(v, 4, 5, 3); /* GFX BUF bottom to WB */
v = FLD_MOD(v, 0, 26, 24); /* WB BUF top to GFX */
v = FLD_MOD(v, 0, 29, 27); /* WB BUF bottom to GFX */
dispc_write_reg(DISPC_GLOBAL_BUFFER, v);
dispc.fifo_assignment[OMAP_DSS_GFX] = OMAP_DSS_WB;
dispc.fifo_assignment[OMAP_DSS_WB] = OMAP_DSS_GFX;
}
}
static u32 dispc_ovl_get_fifo_size(enum omap_plane plane)
{
int fifo;
u32 size = 0;
for (fifo = 0; fifo < dispc.feat->num_fifos; ++fifo) {
if (dispc.fifo_assignment[fifo] == plane)
size += dispc.fifo_size[fifo];
}
return size;
}
void dispc_ovl_set_fifo_threshold(enum omap_plane plane, u32 low, u32 high)
{
u8 hi_start, hi_end, lo_start, lo_end;
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
u32 unit;
unit = dss_feat_get_buffer_size_unit();
WARN_ON(low % unit != 0);
WARN_ON(high % unit != 0);
low /= unit;
high /= unit;
dss_feat_get_reg_field(FEAT_REG_FIFOHIGHTHRESHOLD, &hi_start, &hi_end);
dss_feat_get_reg_field(FEAT_REG_FIFOLOWTHRESHOLD, &lo_start, &lo_end);
DSSDBG("fifo(%d) threshold (bytes), old %u/%u, new %u/%u\n",
plane,
REG_GET(DISPC_OVL_FIFO_THRESHOLD(plane),
lo_start, lo_end) * unit,
REG_GET(DISPC_OVL_FIFO_THRESHOLD(plane),
hi_start, hi_end) * unit,
low * unit, high * unit);
dispc_write_reg(DISPC_OVL_FIFO_THRESHOLD(plane),
FLD_VAL(high, hi_start, hi_end) |
FLD_VAL(low, lo_start, lo_end));
}
void dispc_enable_fifomerge(bool enable)
{
if (!dss_has_feature(FEAT_FIFO_MERGE)) {
WARN_ON(enable);
return;
}
DSSDBG("FIFO merge %s\n", enable ? "enabled" : "disabled");
REG_FLD_MOD(DISPC_CONFIG, enable ? 1 : 0, 14, 14);
}
void dispc_ovl_compute_fifo_thresholds(enum omap_plane plane,
u32 *fifo_low, u32 *fifo_high, bool use_fifomerge,
bool manual_update)
{
/*
* All sizes are in bytes. Both the buffer and burst are made of
* buffer_units, and the fifo thresholds must be buffer_unit aligned.
*/
unsigned buf_unit = dss_feat_get_buffer_size_unit();
unsigned ovl_fifo_size, total_fifo_size, burst_size;
int i;
burst_size = dispc_ovl_get_burst_size(plane);
ovl_fifo_size = dispc_ovl_get_fifo_size(plane);
if (use_fifomerge) {
total_fifo_size = 0;
for (i = 0; i < omap_dss_get_num_overlays(); ++i)
total_fifo_size += dispc_ovl_get_fifo_size(i);
} else {
total_fifo_size = ovl_fifo_size;
}
/*
* We use the same low threshold for both fifomerge and non-fifomerge
* cases, but for fifomerge we calculate the high threshold using the
* combined fifo size
*/
if (manual_update && dss_has_feature(FEAT_OMAP3_DSI_FIFO_BUG)) {
*fifo_low = ovl_fifo_size - burst_size * 2;
*fifo_high = total_fifo_size - burst_size;
} else {
*fifo_low = ovl_fifo_size - burst_size;
*fifo_high = total_fifo_size - buf_unit;
}
}
static void dispc_ovl_set_fir(enum omap_plane plane,
int hinc, int vinc,
enum omap_color_component color_comp)
{
u32 val;
if (color_comp == DISPC_COLOR_COMPONENT_RGB_Y) {
u8 hinc_start, hinc_end, vinc_start, vinc_end;
dss_feat_get_reg_field(FEAT_REG_FIRHINC,
&hinc_start, &hinc_end);
dss_feat_get_reg_field(FEAT_REG_FIRVINC,
&vinc_start, &vinc_end);
val = FLD_VAL(vinc, vinc_start, vinc_end) |
FLD_VAL(hinc, hinc_start, hinc_end);
dispc_write_reg(DISPC_OVL_FIR(plane), val);
} else {
val = FLD_VAL(vinc, 28, 16) | FLD_VAL(hinc, 12, 0);
dispc_write_reg(DISPC_OVL_FIR2(plane), val);
}
}
static void dispc_ovl_set_vid_accu0(enum omap_plane plane, int haccu, int vaccu)
{
u32 val;
u8 hor_start, hor_end, vert_start, vert_end;
dss_feat_get_reg_field(FEAT_REG_HORIZONTALACCU, &hor_start, &hor_end);
dss_feat_get_reg_field(FEAT_REG_VERTICALACCU, &vert_start, &vert_end);
val = FLD_VAL(vaccu, vert_start, vert_end) |
FLD_VAL(haccu, hor_start, hor_end);
dispc_write_reg(DISPC_OVL_ACCU0(plane), val);
}
static void dispc_ovl_set_vid_accu1(enum omap_plane plane, int haccu, int vaccu)
{
u32 val;
u8 hor_start, hor_end, vert_start, vert_end;
dss_feat_get_reg_field(FEAT_REG_HORIZONTALACCU, &hor_start, &hor_end);
dss_feat_get_reg_field(FEAT_REG_VERTICALACCU, &vert_start, &vert_end);
val = FLD_VAL(vaccu, vert_start, vert_end) |
FLD_VAL(haccu, hor_start, hor_end);
dispc_write_reg(DISPC_OVL_ACCU1(plane), val);
}
static void dispc_ovl_set_vid_accu2_0(enum omap_plane plane, int haccu,
int vaccu)
{
u32 val;
val = FLD_VAL(vaccu, 26, 16) | FLD_VAL(haccu, 10, 0);
dispc_write_reg(DISPC_OVL_ACCU2_0(plane), val);
}
static void dispc_ovl_set_vid_accu2_1(enum omap_plane plane, int haccu,
int vaccu)
{
u32 val;
val = FLD_VAL(vaccu, 26, 16) | FLD_VAL(haccu, 10, 0);
dispc_write_reg(DISPC_OVL_ACCU2_1(plane), val);
}
static void dispc_ovl_set_scale_param(enum omap_plane plane,
u16 orig_width, u16 orig_height,
u16 out_width, u16 out_height,
bool five_taps, u8 rotation,
enum omap_color_component color_comp)
{
int fir_hinc, fir_vinc;
fir_hinc = 1024 * orig_width / out_width;
fir_vinc = 1024 * orig_height / out_height;
dispc_ovl_set_scale_coef(plane, fir_hinc, fir_vinc, five_taps,
color_comp);
dispc_ovl_set_fir(plane, fir_hinc, fir_vinc, color_comp);
}
static void dispc_ovl_set_accu_uv(enum omap_plane plane,
u16 orig_width, u16 orig_height, u16 out_width, u16 out_height,
bool ilace, enum omap_color_mode color_mode, u8 rotation)
{
int h_accu2_0, h_accu2_1;
int v_accu2_0, v_accu2_1;
int chroma_hinc, chroma_vinc;
int idx;
struct accu {
s8 h0_m, h0_n;
s8 h1_m, h1_n;
s8 v0_m, v0_n;
s8 v1_m, v1_n;
};
const struct accu *accu_table;
const struct accu *accu_val;
static const struct accu accu_nv12[4] = {
{ 0, 1, 0, 1 , -1, 2, 0, 1 },
{ 1, 2, -3, 4 , 0, 1, 0, 1 },
{ -1, 1, 0, 1 , -1, 2, 0, 1 },
{ -1, 2, -1, 2 , -1, 1, 0, 1 },
};
static const struct accu accu_nv12_ilace[4] = {
{ 0, 1, 0, 1 , -3, 4, -1, 4 },
{ -1, 4, -3, 4 , 0, 1, 0, 1 },
{ -1, 1, 0, 1 , -1, 4, -3, 4 },
{ -3, 4, -3, 4 , -1, 1, 0, 1 },
};
static const struct accu accu_yuv[4] = {
{ 0, 1, 0, 1, 0, 1, 0, 1 },
{ 0, 1, 0, 1, 0, 1, 0, 1 },
{ -1, 1, 0, 1, 0, 1, 0, 1 },
{ 0, 1, 0, 1, -1, 1, 0, 1 },
};
switch (rotation) {
case OMAP_DSS_ROT_0:
idx = 0;
break;
case OMAP_DSS_ROT_90:
idx = 1;
break;
case OMAP_DSS_ROT_180:
idx = 2;
break;
case OMAP_DSS_ROT_270:
idx = 3;
break;
default:
BUG();
return;
}
switch (color_mode) {
case OMAP_DSS_COLOR_NV12:
if (ilace)
accu_table = accu_nv12_ilace;
else
accu_table = accu_nv12;
break;
case OMAP_DSS_COLOR_YUV2:
case OMAP_DSS_COLOR_UYVY:
accu_table = accu_yuv;
break;
default:
BUG();
return;
}
accu_val = &accu_table[idx];
chroma_hinc = 1024 * orig_width / out_width;
chroma_vinc = 1024 * orig_height / out_height;
h_accu2_0 = (accu_val->h0_m * chroma_hinc / accu_val->h0_n) % 1024;
h_accu2_1 = (accu_val->h1_m * chroma_hinc / accu_val->h1_n) % 1024;
v_accu2_0 = (accu_val->v0_m * chroma_vinc / accu_val->v0_n) % 1024;
v_accu2_1 = (accu_val->v1_m * chroma_vinc / accu_val->v1_n) % 1024;
dispc_ovl_set_vid_accu2_0(plane, h_accu2_0, v_accu2_0);
dispc_ovl_set_vid_accu2_1(plane, h_accu2_1, v_accu2_1);
}
static void dispc_ovl_set_scaling_common(enum omap_plane plane,
u16 orig_width, u16 orig_height,
u16 out_width, u16 out_height,
bool ilace, bool five_taps,
bool fieldmode, enum omap_color_mode color_mode,
u8 rotation)
{
int accu0 = 0;
int accu1 = 0;
u32 l;
dispc_ovl_set_scale_param(plane, orig_width, orig_height,
out_width, out_height, five_taps,
rotation, DISPC_COLOR_COMPONENT_RGB_Y);
l = dispc_read_reg(DISPC_OVL_ATTRIBUTES(plane));
/* RESIZEENABLE and VERTICALTAPS */
l &= ~((0x3 << 5) | (0x1 << 21));
l |= (orig_width != out_width) ? (1 << 5) : 0;
l |= (orig_height != out_height) ? (1 << 6) : 0;
l |= five_taps ? (1 << 21) : 0;
/* VRESIZECONF and HRESIZECONF */
if (dss_has_feature(FEAT_RESIZECONF)) {
l &= ~(0x3 << 7);
l |= (orig_width <= out_width) ? 0 : (1 << 7);
l |= (orig_height <= out_height) ? 0 : (1 << 8);
}
/* LINEBUFFERSPLIT */
if (dss_has_feature(FEAT_LINEBUFFERSPLIT)) {
l &= ~(0x1 << 22);
l |= five_taps ? (1 << 22) : 0;
}
dispc_write_reg(DISPC_OVL_ATTRIBUTES(plane), l);
/*
* field 0 = even field = bottom field
* field 1 = odd field = top field
*/
if (ilace && !fieldmode) {
accu1 = 0;
accu0 = ((1024 * orig_height / out_height) / 2) & 0x3ff;
if (accu0 >= 1024/2) {
accu1 = 1024/2;
accu0 -= accu1;
}
}
dispc_ovl_set_vid_accu0(plane, 0, accu0);
dispc_ovl_set_vid_accu1(plane, 0, accu1);
}
static void dispc_ovl_set_scaling_uv(enum omap_plane plane,
u16 orig_width, u16 orig_height,
u16 out_width, u16 out_height,
bool ilace, bool five_taps,
bool fieldmode, enum omap_color_mode color_mode,
u8 rotation)
{
int scale_x = out_width != orig_width;
int scale_y = out_height != orig_height;
if (!dss_has_feature(FEAT_HANDLE_UV_SEPARATE))
return;
if ((color_mode != OMAP_DSS_COLOR_YUV2 &&
color_mode != OMAP_DSS_COLOR_UYVY &&
color_mode != OMAP_DSS_COLOR_NV12)) {
/* reset chroma resampling for RGB formats */
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES2(plane), 0, 8, 8);
return;
}
dispc_ovl_set_accu_uv(plane, orig_width, orig_height, out_width,
out_height, ilace, color_mode, rotation);
switch (color_mode) {
case OMAP_DSS_COLOR_NV12:
/* UV is subsampled by 2 vertically*/
orig_height >>= 1;
/* UV is subsampled by 2 horz.*/
orig_width >>= 1;
break;
case OMAP_DSS_COLOR_YUV2:
case OMAP_DSS_COLOR_UYVY:
/*For YUV422 with 90/270 rotation,
*we don't upsample chroma
*/
if (rotation == OMAP_DSS_ROT_0 ||
rotation == OMAP_DSS_ROT_180)
/* UV is subsampled by 2 hrz*/
orig_width >>= 1;
/* must use FIR for YUV422 if rotated */
if (rotation != OMAP_DSS_ROT_0)
scale_x = scale_y = true;
break;
default:
BUG();
return;
}
if (out_width != orig_width)
scale_x = true;
if (out_height != orig_height)
scale_y = true;
dispc_ovl_set_scale_param(plane, orig_width, orig_height,
out_width, out_height, five_taps,
rotation, DISPC_COLOR_COMPONENT_UV);
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES2(plane),
(scale_x || scale_y) ? 1 : 0, 8, 8);
/* set H scaling */
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), scale_x ? 1 : 0, 5, 5);
/* set V scaling */
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), scale_y ? 1 : 0, 6, 6);
}
static void dispc_ovl_set_scaling(enum omap_plane plane,
u16 orig_width, u16 orig_height,
u16 out_width, u16 out_height,
bool ilace, bool five_taps,
bool fieldmode, enum omap_color_mode color_mode,
u8 rotation)
{
BUG_ON(plane == OMAP_DSS_GFX);
dispc_ovl_set_scaling_common(plane,
orig_width, orig_height,
out_width, out_height,
ilace, five_taps,
fieldmode, color_mode,
rotation);
dispc_ovl_set_scaling_uv(plane,
orig_width, orig_height,
out_width, out_height,
ilace, five_taps,
fieldmode, color_mode,
rotation);
}
static void dispc_ovl_set_rotation_attrs(enum omap_plane plane, u8 rotation,
bool mirroring, enum omap_color_mode color_mode)
{
bool row_repeat = false;
int vidrot = 0;
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY) {
if (mirroring) {
switch (rotation) {
case OMAP_DSS_ROT_0:
vidrot = 2;
break;
case OMAP_DSS_ROT_90:
vidrot = 1;
break;
case OMAP_DSS_ROT_180:
vidrot = 0;
break;
case OMAP_DSS_ROT_270:
vidrot = 3;
break;
}
} else {
switch (rotation) {
case OMAP_DSS_ROT_0:
vidrot = 0;
break;
case OMAP_DSS_ROT_90:
vidrot = 1;
break;
case OMAP_DSS_ROT_180:
vidrot = 2;
break;
case OMAP_DSS_ROT_270:
vidrot = 3;
break;
}
}
if (rotation == OMAP_DSS_ROT_90 || rotation == OMAP_DSS_ROT_270)
row_repeat = true;
else
row_repeat = false;
}
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), vidrot, 13, 12);
if (dss_has_feature(FEAT_ROWREPEATENABLE))
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane),
row_repeat ? 1 : 0, 18, 18);
}
static int color_mode_to_bpp(enum omap_color_mode color_mode)
{
switch (color_mode) {
case OMAP_DSS_COLOR_CLUT1:
return 1;
case OMAP_DSS_COLOR_CLUT2:
return 2;
case OMAP_DSS_COLOR_CLUT4:
return 4;
case OMAP_DSS_COLOR_CLUT8:
case OMAP_DSS_COLOR_NV12:
return 8;
case OMAP_DSS_COLOR_RGB12U:
case OMAP_DSS_COLOR_RGB16:
case OMAP_DSS_COLOR_ARGB16:
case OMAP_DSS_COLOR_YUV2:
case OMAP_DSS_COLOR_UYVY:
case OMAP_DSS_COLOR_RGBA16:
case OMAP_DSS_COLOR_RGBX16:
case OMAP_DSS_COLOR_ARGB16_1555:
case OMAP_DSS_COLOR_XRGB16_1555:
return 16;
case OMAP_DSS_COLOR_RGB24P:
return 24;
case OMAP_DSS_COLOR_RGB24U:
case OMAP_DSS_COLOR_ARGB32:
case OMAP_DSS_COLOR_RGBA32:
case OMAP_DSS_COLOR_RGBX32:
return 32;
default:
BUG();
return 0;
}
}
static s32 pixinc(int pixels, u8 ps)
{
if (pixels == 1)
return 1;
else if (pixels > 1)
return 1 + (pixels - 1) * ps;
else if (pixels < 0)
return 1 - (-pixels + 1) * ps;
else
BUG();
return 0;
}
static void calc_vrfb_rotation_offset(u8 rotation, bool mirror,
u16 screen_width,
u16 width, u16 height,
enum omap_color_mode color_mode, bool fieldmode,
unsigned int field_offset,
unsigned *offset0, unsigned *offset1,
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
s32 *row_inc, s32 *pix_inc, int x_predecim, int y_predecim)
{
u8 ps;
/* FIXME CLUT formats */
switch (color_mode) {
case OMAP_DSS_COLOR_CLUT1:
case OMAP_DSS_COLOR_CLUT2:
case OMAP_DSS_COLOR_CLUT4:
case OMAP_DSS_COLOR_CLUT8:
BUG();
return;
case OMAP_DSS_COLOR_YUV2:
case OMAP_DSS_COLOR_UYVY:
ps = 4;
break;
default:
ps = color_mode_to_bpp(color_mode) / 8;
break;
}
DSSDBG("calc_rot(%d): scrw %d, %dx%d\n", rotation, screen_width,
width, height);
/*
* field 0 = even field = bottom field
* field 1 = odd field = top field
*/
switch (rotation + mirror * 4) {
case OMAP_DSS_ROT_0:
case OMAP_DSS_ROT_180:
/*
* If the pixel format is YUV or UYVY divide the width
* of the image by 2 for 0 and 180 degree rotation.
*/
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY)
width = width >> 1;
case OMAP_DSS_ROT_90:
case OMAP_DSS_ROT_270:
*offset1 = 0;
if (field_offset)
*offset0 = field_offset * screen_width * ps;
else
*offset0 = 0;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(1 +
(y_predecim * screen_width - x_predecim * width) +
(fieldmode ? screen_width : 0), ps);
*pix_inc = pixinc(x_predecim, ps);
break;
case OMAP_DSS_ROT_0 + 4:
case OMAP_DSS_ROT_180 + 4:
/* If the pixel format is YUV or UYVY divide the width
* of the image by 2 for 0 degree and 180 degree
*/
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY)
width = width >> 1;
case OMAP_DSS_ROT_90 + 4:
case OMAP_DSS_ROT_270 + 4:
*offset1 = 0;
if (field_offset)
*offset0 = field_offset * screen_width * ps;
else
*offset0 = 0;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(1 -
(y_predecim * screen_width + x_predecim * width) -
(fieldmode ? screen_width : 0), ps);
*pix_inc = pixinc(x_predecim, ps);
break;
default:
BUG();
return;
}
}
static void calc_dma_rotation_offset(u8 rotation, bool mirror,
u16 screen_width,
u16 width, u16 height,
enum omap_color_mode color_mode, bool fieldmode,
unsigned int field_offset,
unsigned *offset0, unsigned *offset1,
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
s32 *row_inc, s32 *pix_inc, int x_predecim, int y_predecim)
{
u8 ps;
u16 fbw, fbh;
/* FIXME CLUT formats */
switch (color_mode) {
case OMAP_DSS_COLOR_CLUT1:
case OMAP_DSS_COLOR_CLUT2:
case OMAP_DSS_COLOR_CLUT4:
case OMAP_DSS_COLOR_CLUT8:
BUG();
return;
default:
ps = color_mode_to_bpp(color_mode) / 8;
break;
}
DSSDBG("calc_rot(%d): scrw %d, %dx%d\n", rotation, screen_width,
width, height);
/* width & height are overlay sizes, convert to fb sizes */
if (rotation == OMAP_DSS_ROT_0 || rotation == OMAP_DSS_ROT_180) {
fbw = width;
fbh = height;
} else {
fbw = height;
fbh = width;
}
/*
* field 0 = even field = bottom field
* field 1 = odd field = top field
*/
switch (rotation + mirror * 4) {
case OMAP_DSS_ROT_0:
*offset1 = 0;
if (field_offset)
*offset0 = *offset1 + field_offset * screen_width * ps;
else
*offset0 = *offset1;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(1 +
(y_predecim * screen_width - fbw * x_predecim) +
(fieldmode ? screen_width : 0), ps);
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY)
*pix_inc = pixinc(x_predecim, 2 * ps);
else
*pix_inc = pixinc(x_predecim, ps);
break;
case OMAP_DSS_ROT_90:
*offset1 = screen_width * (fbh - 1) * ps;
if (field_offset)
*offset0 = *offset1 + field_offset * ps;
else
*offset0 = *offset1;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(screen_width * (fbh * x_predecim - 1) +
y_predecim + (fieldmode ? 1 : 0), ps);
*pix_inc = pixinc(-x_predecim * screen_width, ps);
break;
case OMAP_DSS_ROT_180:
*offset1 = (screen_width * (fbh - 1) + fbw - 1) * ps;
if (field_offset)
*offset0 = *offset1 - field_offset * screen_width * ps;
else
*offset0 = *offset1;
*row_inc = pixinc(-1 -
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
(y_predecim * screen_width - fbw * x_predecim) -
(fieldmode ? screen_width : 0), ps);
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY)
*pix_inc = pixinc(-x_predecim, 2 * ps);
else
*pix_inc = pixinc(-x_predecim, ps);
break;
case OMAP_DSS_ROT_270:
*offset1 = (fbw - 1) * ps;
if (field_offset)
*offset0 = *offset1 - field_offset * ps;
else
*offset0 = *offset1;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(-screen_width * (fbh * x_predecim - 1) -
y_predecim - (fieldmode ? 1 : 0), ps);
*pix_inc = pixinc(x_predecim * screen_width, ps);
break;
/* mirroring */
case OMAP_DSS_ROT_0 + 4:
*offset1 = (fbw - 1) * ps;
if (field_offset)
*offset0 = *offset1 + field_offset * screen_width * ps;
else
*offset0 = *offset1;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(y_predecim * screen_width * 2 - 1 +
(fieldmode ? screen_width : 0),
ps);
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY)
*pix_inc = pixinc(-x_predecim, 2 * ps);
else
*pix_inc = pixinc(-x_predecim, ps);
break;
case OMAP_DSS_ROT_90 + 4:
*offset1 = 0;
if (field_offset)
*offset0 = *offset1 + field_offset * ps;
else
*offset0 = *offset1;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(-screen_width * (fbh * x_predecim - 1) +
y_predecim + (fieldmode ? 1 : 0),
ps);
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*pix_inc = pixinc(x_predecim * screen_width, ps);
break;
case OMAP_DSS_ROT_180 + 4:
*offset1 = screen_width * (fbh - 1) * ps;
if (field_offset)
*offset0 = *offset1 - field_offset * screen_width * ps;
else
*offset0 = *offset1;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(1 - y_predecim * screen_width * 2 -
(fieldmode ? screen_width : 0),
ps);
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY)
*pix_inc = pixinc(x_predecim, 2 * ps);
else
*pix_inc = pixinc(x_predecim, ps);
break;
case OMAP_DSS_ROT_270 + 4:
*offset1 = (screen_width * (fbh - 1) + fbw - 1) * ps;
if (field_offset)
*offset0 = *offset1 - field_offset * ps;
else
*offset0 = *offset1;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*row_inc = pixinc(screen_width * (fbh * x_predecim - 1) -
y_predecim - (fieldmode ? 1 : 0),
ps);
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*pix_inc = pixinc(-x_predecim * screen_width, ps);
break;
default:
BUG();
return;
}
}
OMAPDSS: DISPC: Support rotation through TILER TILER is a block in OMAP4's DMM which lets DSS fetch frames in a rotated manner. Physical memory can be mapped to a portion of OMAP's system address space called TILER address space. The TILER address space is split into 8 views. Each view represents a rotated or mirrored form of the mapped physical memory. When a DISPC overlay's base address is programmed to one of these views, the TILER fetches the pixels according to the orientation of the view. A view is further split into 4 containers, each container holds elements of a particular size. Rotation can be achieved at the granularity of elements in the container. For more information on TILER, refer to the Memory Subsytem section in OMAP4 TRM. Rotation type TILER has been added which is used to exploit the capabilities of these 8 views for performing various rotations. When fetching from addresses mapped to TILER space, the DISPC DMA can fetch pixels in either 1D or 2D bursts. The fetch depends on which TILER container we are accessing. Accessing 8, 16 and 32 bit sized containers requires 2D bursts, and page mode sized containers require 1D bursts. The DSS2 user is expected to provide the Tiler address of the view that it is interested in. This is passed to the paddr and p_uv_addr parameters in omap_overlay_info. It is also expected to provide the stride value based on the view's orientation and container type, this should be passed to the screen_width parameter of omap_overlay_info. In calc_tiler_rotation_offset screen_width is used to calculate the required row_inc for DISPC. x_predecim and y_predecim are also used to calculate row_inc and pix_inc thereby adding predecimation support for TILER. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-11 20:49:55 +07:00
static void calc_tiler_rotation_offset(u16 screen_width, u16 width,
enum omap_color_mode color_mode, bool fieldmode,
unsigned int field_offset, unsigned *offset0, unsigned *offset1,
s32 *row_inc, s32 *pix_inc, int x_predecim, int y_predecim)
{
u8 ps;
switch (color_mode) {
case OMAP_DSS_COLOR_CLUT1:
case OMAP_DSS_COLOR_CLUT2:
case OMAP_DSS_COLOR_CLUT4:
case OMAP_DSS_COLOR_CLUT8:
BUG();
return;
default:
ps = color_mode_to_bpp(color_mode) / 8;
break;
}
DSSDBG("scrw %d, width %d\n", screen_width, width);
/*
* field 0 = even field = bottom field
* field 1 = odd field = top field
*/
*offset1 = 0;
if (field_offset)
*offset0 = *offset1 + field_offset * screen_width * ps;
else
*offset0 = *offset1;
*row_inc = pixinc(1 + (y_predecim * screen_width - width * x_predecim) +
(fieldmode ? screen_width : 0), ps);
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY)
*pix_inc = pixinc(x_predecim, 2 * ps);
else
*pix_inc = pixinc(x_predecim, ps);
}
/*
* This function is used to avoid synclosts in OMAP3, because of some
* undocumented horizontal position and timing related limitations.
*/
static int check_horiz_timing_omap3(enum omap_channel channel,
const struct omap_video_timings *t, u16 pos_x,
u16 width, u16 height, u16 out_width, u16 out_height)
{
int DS = DIV_ROUND_UP(height, out_height);
unsigned long nonactive, lclk, pclk;
static const u8 limits[3] = { 8, 10, 20 };
u64 val, blank;
int i;
nonactive = t->x_res + t->hfp + t->hsw + t->hbp - out_width;
pclk = dispc_mgr_pclk_rate(channel);
if (dss_mgr_is_lcd(channel))
lclk = dispc_mgr_lclk_rate(channel);
else
lclk = dispc_fclk_rate();
i = 0;
if (out_height < height)
i++;
if (out_width < width)
i++;
blank = div_u64((u64)(t->hbp + t->hsw + t->hfp) * lclk, pclk);
DSSDBG("blanking period + ppl = %llu (limit = %u)\n", blank, limits[i]);
if (blank <= limits[i])
return -EINVAL;
/*
* Pixel data should be prepared before visible display point starts.
* So, atleast DS-2 lines must have already been fetched by DISPC
* during nonactive - pos_x period.
*/
val = div_u64((u64)(nonactive - pos_x) * lclk, pclk);
DSSDBG("(nonactive - pos_x) * pcd = %llu max(0, DS - 2) * width = %d\n",
val, max(0, DS - 2) * width);
if (val < max(0, DS - 2) * width)
return -EINVAL;
/*
* All lines need to be refilled during the nonactive period of which
* only one line can be loaded during the active period. So, atleast
* DS - 1 lines should be loaded during nonactive period.
*/
val = div_u64((u64)nonactive * lclk, pclk);
DSSDBG("nonactive * pcd = %llu, max(0, DS - 1) * width = %d\n",
val, max(0, DS - 1) * width);
if (val < max(0, DS - 1) * width)
return -EINVAL;
return 0;
}
static unsigned long calc_core_clk_five_taps(enum omap_channel channel,
const struct omap_video_timings *mgr_timings, u16 width,
u16 height, u16 out_width, u16 out_height,
enum omap_color_mode color_mode)
{
u32 core_clk = 0;
u64 tmp, pclk = dispc_mgr_pclk_rate(channel);
if (height <= out_height && width <= out_width)
return (unsigned long) pclk;
if (height > out_height) {
unsigned int ppl = mgr_timings->x_res;
tmp = pclk * height * out_width;
do_div(tmp, 2 * out_height * ppl);
core_clk = tmp;
if (height > 2 * out_height) {
if (ppl == out_width)
return 0;
tmp = pclk * (height - 2 * out_height) * out_width;
do_div(tmp, 2 * out_height * (ppl - out_width));
core_clk = max_t(u32, core_clk, tmp);
}
}
if (width > out_width) {
tmp = pclk * width;
do_div(tmp, out_width);
core_clk = max_t(u32, core_clk, tmp);
if (color_mode == OMAP_DSS_COLOR_RGB24U)
core_clk <<= 1;
}
return core_clk;
}
static unsigned long calc_core_clk_24xx(enum omap_channel channel, u16 width,
u16 height, u16 out_width, u16 out_height)
{
unsigned long pclk = dispc_mgr_pclk_rate(channel);
if (height > out_height && width > out_width)
return pclk * 4;
else
return pclk * 2;
}
static unsigned long calc_core_clk_34xx(enum omap_channel channel, u16 width,
u16 height, u16 out_width, u16 out_height)
{
unsigned int hf, vf;
unsigned long pclk = dispc_mgr_pclk_rate(channel);
/*
* FIXME how to determine the 'A' factor
* for the no downscaling case ?
*/
if (width > 3 * out_width)
hf = 4;
else if (width > 2 * out_width)
hf = 3;
else if (width > out_width)
hf = 2;
else
hf = 1;
if (height > out_height)
vf = 2;
else
vf = 1;
return pclk * vf * hf;
}
static unsigned long calc_core_clk_44xx(enum omap_channel channel, u16 width,
u16 height, u16 out_width, u16 out_height)
{
unsigned long pclk = dispc_mgr_pclk_rate(channel);
if (width > out_width)
return DIV_ROUND_UP(pclk, out_width) * width;
else
return pclk;
}
static int dispc_ovl_calc_scaling_24xx(enum omap_channel channel,
const struct omap_video_timings *mgr_timings,
u16 width, u16 height, u16 out_width, u16 out_height,
enum omap_color_mode color_mode, bool *five_taps,
int *x_predecim, int *y_predecim, int *decim_x, int *decim_y,
u16 pos_x, unsigned long *core_clk)
{
int error;
u16 in_width, in_height;
int min_factor = min(*decim_x, *decim_y);
const int maxsinglelinewidth =
dss_feat_get_param_max(FEAT_PARAM_LINEWIDTH);
*five_taps = false;
do {
in_height = DIV_ROUND_UP(height, *decim_y);
in_width = DIV_ROUND_UP(width, *decim_x);
*core_clk = dispc.feat->calc_core_clk(channel, in_width,
in_height, out_width, out_height);
error = (in_width > maxsinglelinewidth || !*core_clk ||
*core_clk > dispc_core_clk_rate());
if (error) {
if (*decim_x == *decim_y) {
*decim_x = min_factor;
++*decim_y;
} else {
swap(*decim_x, *decim_y);
if (*decim_x < *decim_y)
++*decim_x;
}
}
} while (*decim_x <= *x_predecim && *decim_y <= *y_predecim && error);
if (in_width > maxsinglelinewidth) {
DSSERR("Cannot scale max input width exceeded");
return -EINVAL;
}
return 0;
}
static int dispc_ovl_calc_scaling_34xx(enum omap_channel channel,
const struct omap_video_timings *mgr_timings,
u16 width, u16 height, u16 out_width, u16 out_height,
enum omap_color_mode color_mode, bool *five_taps,
int *x_predecim, int *y_predecim, int *decim_x, int *decim_y,
u16 pos_x, unsigned long *core_clk)
{
int error;
u16 in_width, in_height;
int min_factor = min(*decim_x, *decim_y);
const int maxsinglelinewidth =
dss_feat_get_param_max(FEAT_PARAM_LINEWIDTH);
do {
in_height = DIV_ROUND_UP(height, *decim_y);
in_width = DIV_ROUND_UP(width, *decim_x);
*core_clk = calc_core_clk_five_taps(channel, mgr_timings,
in_width, in_height, out_width, out_height, color_mode);
error = check_horiz_timing_omap3(channel, mgr_timings, pos_x,
in_width, in_height, out_width, out_height);
if (in_width > maxsinglelinewidth)
if (in_height > out_height &&
in_height < out_height * 2)
*five_taps = false;
if (!*five_taps)
*core_clk = dispc.feat->calc_core_clk(channel, in_width,
in_height, out_width, out_height);
error = (error || in_width > maxsinglelinewidth * 2 ||
(in_width > maxsinglelinewidth && *five_taps) ||
!*core_clk || *core_clk > dispc_core_clk_rate());
if (error) {
if (*decim_x == *decim_y) {
*decim_x = min_factor;
++*decim_y;
} else {
swap(*decim_x, *decim_y);
if (*decim_x < *decim_y)
++*decim_x;
}
}
} while (*decim_x <= *x_predecim && *decim_y <= *y_predecim && error);
if (check_horiz_timing_omap3(channel, mgr_timings, pos_x, width, height,
out_width, out_height)){
DSSERR("horizontal timing too tight\n");
return -EINVAL;
}
if (in_width > (maxsinglelinewidth * 2)) {
DSSERR("Cannot setup scaling");
DSSERR("width exceeds maximum width possible");
return -EINVAL;
}
if (in_width > maxsinglelinewidth && *five_taps) {
DSSERR("cannot setup scaling with five taps");
return -EINVAL;
}
return 0;
}
static int dispc_ovl_calc_scaling_44xx(enum omap_channel channel,
const struct omap_video_timings *mgr_timings,
u16 width, u16 height, u16 out_width, u16 out_height,
enum omap_color_mode color_mode, bool *five_taps,
int *x_predecim, int *y_predecim, int *decim_x, int *decim_y,
u16 pos_x, unsigned long *core_clk)
{
u16 in_width, in_width_max;
int decim_x_min = *decim_x;
u16 in_height = DIV_ROUND_UP(height, *decim_y);
const int maxsinglelinewidth =
dss_feat_get_param_max(FEAT_PARAM_LINEWIDTH);
in_width_max = dispc_core_clk_rate() /
DIV_ROUND_UP(dispc_mgr_pclk_rate(channel), out_width);
*decim_x = DIV_ROUND_UP(width, in_width_max);
*decim_x = *decim_x > decim_x_min ? *decim_x : decim_x_min;
if (*decim_x > *x_predecim)
return -EINVAL;
do {
in_width = DIV_ROUND_UP(width, *decim_x);
} while (*decim_x <= *x_predecim &&
in_width > maxsinglelinewidth && ++*decim_x);
if (in_width > maxsinglelinewidth) {
DSSERR("Cannot scale width exceeds max line width");
return -EINVAL;
}
*core_clk = dispc.feat->calc_core_clk(channel, in_width, in_height,
out_width, out_height);
return 0;
}
static int dispc_ovl_calc_scaling(enum omap_plane plane,
enum omap_overlay_caps caps, enum omap_channel channel,
const struct omap_video_timings *mgr_timings,
u16 width, u16 height, u16 out_width, u16 out_height,
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
enum omap_color_mode color_mode, bool *five_taps,
int *x_predecim, int *y_predecim, u16 pos_x,
enum omap_dss_rotation_type rotation_type)
{
const int maxdownscale = dss_feat_get_param_max(FEAT_PARAM_DOWNSCALE);
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
const int max_decim_limit = 16;
unsigned long core_clk = 0;
int decim_x, decim_y, ret;
if (width == out_width && height == out_height)
return 0;
if ((caps & OMAP_DSS_OVL_CAP_SCALE) == 0)
return -EINVAL;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*x_predecim = max_decim_limit;
*y_predecim = (rotation_type == OMAP_DSS_ROT_TILER &&
dss_has_feature(FEAT_BURST_2D)) ? 2 : max_decim_limit;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
if (color_mode == OMAP_DSS_COLOR_CLUT1 ||
color_mode == OMAP_DSS_COLOR_CLUT2 ||
color_mode == OMAP_DSS_COLOR_CLUT4 ||
color_mode == OMAP_DSS_COLOR_CLUT8) {
*x_predecim = 1;
*y_predecim = 1;
*five_taps = false;
return 0;
}
decim_x = DIV_ROUND_UP(DIV_ROUND_UP(width, out_width), maxdownscale);
decim_y = DIV_ROUND_UP(DIV_ROUND_UP(height, out_height), maxdownscale);
if (decim_x > *x_predecim || out_width > width * 8)
return -EINVAL;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
if (decim_y > *y_predecim || out_height > height * 8)
return -EINVAL;
ret = dispc.feat->calc_scaling(channel, mgr_timings, width, height,
out_width, out_height, color_mode, five_taps, x_predecim,
y_predecim, &decim_x, &decim_y, pos_x, &core_clk);
if (ret)
return ret;
DSSDBG("required core clk rate = %lu Hz\n", core_clk);
DSSDBG("current core clk rate = %lu Hz\n", dispc_core_clk_rate());
if (!core_clk || core_clk > dispc_core_clk_rate()) {
DSSERR("failed to set up scaling, "
"required core clk rate = %lu Hz, "
"current core clk rate = %lu Hz\n",
core_clk, dispc_core_clk_rate());
return -EINVAL;
}
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
*x_predecim = decim_x;
*y_predecim = decim_y;
return 0;
}
static int dispc_ovl_setup_common(enum omap_plane plane,
enum omap_channel channel, enum omap_overlay_caps caps,
u32 paddr, u32 p_uv_addr, u16 screen_width, int pos_x,
int pos_y, u16 width, u16 height, u16 out_width, u16 out_height,
enum omap_color_mode color_mode, u8 rotation, bool mirror,
u8 zorder, u8 pre_mult_alpha, u8 global_alpha,
enum omap_dss_rotation_type rotation_type,
bool replication, const struct omap_video_timings *mgr_timings)
{
bool five_taps = true;
bool fieldmode = 0;
int r, cconv = 0;
unsigned offset0, offset1;
s32 row_inc;
s32 pix_inc;
u16 frame_height = height;
unsigned int field_offset = 0;
u16 in_height = height;
u16 in_width = width;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
int x_predecim = 1, y_predecim = 1;
bool ilace = mgr_timings->interlace;
if (paddr == 0)
return -EINVAL;
out_width = out_width == 0 ? width : out_width;
out_height = out_height == 0 ? height : out_height;
if (ilace && height == out_height)
fieldmode = 1;
if (ilace) {
if (fieldmode)
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
in_height /= 2;
pos_y /= 2;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
out_height /= 2;
DSSDBG("adjusting for ilace: height %d, pos_y %d, "
"out_height %d\n", in_height, pos_y,
out_height);
}
if (!dss_feat_color_mode_supported(plane, color_mode))
return -EINVAL;
r = dispc_ovl_calc_scaling(plane, caps, channel, mgr_timings, in_width,
in_height, out_width, out_height, color_mode,
&five_taps, &x_predecim, &y_predecim, pos_x,
rotation_type);
if (r)
return r;
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
in_width = DIV_ROUND_UP(in_width, x_predecim);
in_height = DIV_ROUND_UP(in_height, y_predecim);
if (color_mode == OMAP_DSS_COLOR_YUV2 ||
color_mode == OMAP_DSS_COLOR_UYVY ||
color_mode == OMAP_DSS_COLOR_NV12)
cconv = 1;
if (ilace && !fieldmode) {
/*
* when downscaling the bottom field may have to start several
* source lines below the top field. Unfortunately ACCUI
* registers will only hold the fractional part of the offset
* so the integer part must be added to the base address of the
* bottom field.
*/
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
if (!in_height || in_height == out_height)
field_offset = 0;
else
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
field_offset = in_height / out_height / 2;
}
/* Fields are independent but interleaved in memory. */
if (fieldmode)
field_offset = 1;
offset0 = 0;
offset1 = 0;
row_inc = 0;
pix_inc = 0;
if (rotation_type == OMAP_DSS_ROT_TILER)
calc_tiler_rotation_offset(screen_width, in_width,
color_mode, fieldmode, field_offset,
OMAPDSS: DISPC: Support rotation through TILER TILER is a block in OMAP4's DMM which lets DSS fetch frames in a rotated manner. Physical memory can be mapped to a portion of OMAP's system address space called TILER address space. The TILER address space is split into 8 views. Each view represents a rotated or mirrored form of the mapped physical memory. When a DISPC overlay's base address is programmed to one of these views, the TILER fetches the pixels according to the orientation of the view. A view is further split into 4 containers, each container holds elements of a particular size. Rotation can be achieved at the granularity of elements in the container. For more information on TILER, refer to the Memory Subsytem section in OMAP4 TRM. Rotation type TILER has been added which is used to exploit the capabilities of these 8 views for performing various rotations. When fetching from addresses mapped to TILER space, the DISPC DMA can fetch pixels in either 1D or 2D bursts. The fetch depends on which TILER container we are accessing. Accessing 8, 16 and 32 bit sized containers requires 2D bursts, and page mode sized containers require 1D bursts. The DSS2 user is expected to provide the Tiler address of the view that it is interested in. This is passed to the paddr and p_uv_addr parameters in omap_overlay_info. It is also expected to provide the stride value based on the view's orientation and container type, this should be passed to the screen_width parameter of omap_overlay_info. In calc_tiler_rotation_offset screen_width is used to calculate the required row_inc for DISPC. x_predecim and y_predecim are also used to calculate row_inc and pix_inc thereby adding predecimation support for TILER. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-11 20:49:55 +07:00
&offset0, &offset1, &row_inc, &pix_inc,
x_predecim, y_predecim);
else if (rotation_type == OMAP_DSS_ROT_DMA)
calc_dma_rotation_offset(rotation, mirror,
screen_width, in_width, frame_height,
color_mode, fieldmode, field_offset,
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
&offset0, &offset1, &row_inc, &pix_inc,
x_predecim, y_predecim);
else
calc_vrfb_rotation_offset(rotation, mirror,
screen_width, in_width, frame_height,
color_mode, fieldmode, field_offset,
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
&offset0, &offset1, &row_inc, &pix_inc,
x_predecim, y_predecim);
DSSDBG("offset0 %u, offset1 %u, row_inc %d, pix_inc %d\n",
offset0, offset1, row_inc, pix_inc);
dispc_ovl_set_color_mode(plane, color_mode);
dispc_ovl_configure_burst_type(plane, rotation_type);
OMAPDSS: DISPC: Support rotation through TILER TILER is a block in OMAP4's DMM which lets DSS fetch frames in a rotated manner. Physical memory can be mapped to a portion of OMAP's system address space called TILER address space. The TILER address space is split into 8 views. Each view represents a rotated or mirrored form of the mapped physical memory. When a DISPC overlay's base address is programmed to one of these views, the TILER fetches the pixels according to the orientation of the view. A view is further split into 4 containers, each container holds elements of a particular size. Rotation can be achieved at the granularity of elements in the container. For more information on TILER, refer to the Memory Subsytem section in OMAP4 TRM. Rotation type TILER has been added which is used to exploit the capabilities of these 8 views for performing various rotations. When fetching from addresses mapped to TILER space, the DISPC DMA can fetch pixels in either 1D or 2D bursts. The fetch depends on which TILER container we are accessing. Accessing 8, 16 and 32 bit sized containers requires 2D bursts, and page mode sized containers require 1D bursts. The DSS2 user is expected to provide the Tiler address of the view that it is interested in. This is passed to the paddr and p_uv_addr parameters in omap_overlay_info. It is also expected to provide the stride value based on the view's orientation and container type, this should be passed to the screen_width parameter of omap_overlay_info. In calc_tiler_rotation_offset screen_width is used to calculate the required row_inc for DISPC. x_predecim and y_predecim are also used to calculate row_inc and pix_inc thereby adding predecimation support for TILER. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-11 20:49:55 +07:00
dispc_ovl_set_ba0(plane, paddr + offset0);
dispc_ovl_set_ba1(plane, paddr + offset1);
if (OMAP_DSS_COLOR_NV12 == color_mode) {
dispc_ovl_set_ba0_uv(plane, p_uv_addr + offset0);
dispc_ovl_set_ba1_uv(plane, p_uv_addr + offset1);
}
dispc_ovl_set_row_inc(plane, row_inc);
dispc_ovl_set_pix_inc(plane, pix_inc);
DSSDBG("%d,%d %dx%d -> %dx%d\n", pos_x, pos_y, in_width,
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
in_height, out_width, out_height);
dispc_ovl_set_pos(plane, caps, pos_x, pos_y);
dispc_ovl_set_input_size(plane, in_width, in_height);
if (caps & OMAP_DSS_OVL_CAP_SCALE) {
OMAPDSS: DISPC: Enable predecimation In OMAP3 and OMAP4, the DISPC Scaler can downscale an image up to 4 times, and up to 2 times in OMAP2. However, with predecimation, the image can be reduced to 16 times by fetching only the necessary pixels in memory. Then this predecimated image can be downscaled further by the DISPC scaler. The pipeline is configured to use a burst of size 8 * 128 bits which consists of 8 mini bursts of 16 bytes each. So, horizontal predecimation more than 16 can lead to complete discarding of such mini bursts. L3 interconnect may handover the bus to some other initiator and inturn delay the fetching of pixels leading to underflows. So, maximum predecimation limit is fixed at 16. Based on the downscaling required, a prior calculation of predecimation values for width and height of an image is done. Since, Predecimation reduces quality of an image higher priorty is given to DISPC Scaler for downscaling. This code was successfully tested on OMAP2, OMAP3 and OMAP4. Horizontal and vertical predecimation worked fine except for some synclost errors due to undocumented errata in OMAP3 which are fixed later and skewed images were seen on OMAP2 and OMAP3 during horizontal predecimation which will be addressed in the future patches. This code is based on code written by Lajos Molnar <lajos@ti.com> who had added predecimation support for NV12/YUV/rotated/SDMA buffers. Signed-off-by: Chandrabhanu Mahapatra <cmahapatra@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-04-02 22:13:16 +07:00
dispc_ovl_set_scaling(plane, in_width, in_height, out_width,
out_height, ilace, five_taps, fieldmode,
color_mode, rotation);
dispc_ovl_set_output_size(plane, out_width, out_height);
dispc_ovl_set_vid_color_conv(plane, cconv);
}
dispc_ovl_set_rotation_attrs(plane, rotation, mirror, color_mode);
dispc_ovl_set_zorder(plane, caps, zorder);
dispc_ovl_set_pre_mult_alpha(plane, caps, pre_mult_alpha);
dispc_ovl_setup_global_alpha(plane, caps, global_alpha);
dispc_ovl_enable_replication(plane, caps, replication);
return 0;
}
int dispc_ovl_setup(enum omap_plane plane, const struct omap_overlay_info *oi,
bool replication, const struct omap_video_timings *mgr_timings)
{
int r;
struct omap_overlay *ovl = omap_dss_get_overlay(plane);
enum omap_channel channel;
channel = dispc_ovl_get_channel_out(plane);
DSSDBG("dispc_ovl_setup %d, pa %x, pa_uv %x, sw %d, %d,%d, %dx%d -> "
"%dx%d, cmode %x, rot %d, mir %d, chan %d repl %d\n",
plane, oi->paddr, oi->p_uv_addr, oi->screen_width, oi->pos_x,
oi->pos_y, oi->width, oi->height, oi->out_width, oi->out_height,
oi->color_mode, oi->rotation, oi->mirror, channel, replication);
r = dispc_ovl_setup_common(plane, channel, ovl->caps, oi->paddr,
oi->p_uv_addr, oi->screen_width, oi->pos_x, oi->pos_y,
oi->width, oi->height, oi->out_width, oi->out_height,
oi->color_mode, oi->rotation, oi->mirror, oi->zorder,
oi->pre_mult_alpha, oi->global_alpha, oi->rotation_type,
replication, mgr_timings);
return r;
}
int dispc_ovl_enable(enum omap_plane plane, bool enable)
{
DSSDBG("dispc_enable_plane %d, %d\n", plane, enable);
REG_FLD_MOD(DISPC_OVL_ATTRIBUTES(plane), enable ? 1 : 0, 0, 0);
return 0;
}
static void dispc_disable_isr(void *data, u32 mask)
{
struct completion *compl = data;
complete(compl);
}
static void _enable_lcd_out(enum omap_channel channel, bool enable)
{
mgr_fld_write(channel, DISPC_MGR_FLD_ENABLE, enable);
/* flush posted write */
mgr_fld_read(channel, DISPC_MGR_FLD_ENABLE);
}
static void dispc_mgr_enable_lcd_out(enum omap_channel channel, bool enable)
{
struct completion frame_done_completion;
bool is_on;
int r;
u32 irq;
/* When we disable LCD output, we need to wait until frame is done.
* Otherwise the DSS is still working, and turning off the clocks
* prevents DSS from going to OFF mode */
is_on = mgr_fld_read(channel, DISPC_MGR_FLD_ENABLE);
irq = mgr_desc[channel].framedone_irq;
if (!enable && is_on) {
init_completion(&frame_done_completion);
r = omap_dispc_register_isr(dispc_disable_isr,
&frame_done_completion, irq);
if (r)
DSSERR("failed to register FRAMEDONE isr\n");
}
_enable_lcd_out(channel, enable);
if (!enable && is_on) {
if (!wait_for_completion_timeout(&frame_done_completion,
msecs_to_jiffies(100)))
DSSERR("timeout waiting for FRAME DONE\n");
r = omap_dispc_unregister_isr(dispc_disable_isr,
&frame_done_completion, irq);
if (r)
DSSERR("failed to unregister FRAMEDONE isr\n");
}
}
static void _enable_digit_out(bool enable)
{
REG_FLD_MOD(DISPC_CONTROL, enable ? 1 : 0, 1, 1);
/* flush posted write */
dispc_read_reg(DISPC_CONTROL);
}
static void dispc_mgr_enable_digit_out(bool enable)
{
struct completion frame_done_completion;
enum dss_hdmi_venc_clk_source_select src;
int r, i;
u32 irq_mask;
int num_irqs;
if (REG_GET(DISPC_CONTROL, 1, 1) == enable)
return;
src = dss_get_hdmi_venc_clk_source();
if (enable) {
unsigned long flags;
/* When we enable digit output, we'll get an extra digit
* sync lost interrupt, that we need to ignore */
spin_lock_irqsave(&dispc.irq_lock, flags);
dispc.irq_error_mask &= ~DISPC_IRQ_SYNC_LOST_DIGIT;
_omap_dispc_set_irqs();
spin_unlock_irqrestore(&dispc.irq_lock, flags);
}
/* When we disable digit output, we need to wait until fields are done.
* Otherwise the DSS is still working, and turning off the clocks
* prevents DSS from going to OFF mode. And when enabling, we need to
* wait for the extra sync losts */
init_completion(&frame_done_completion);
if (src == DSS_HDMI_M_PCLK && enable == false) {
irq_mask = DISPC_IRQ_FRAMEDONETV;
num_irqs = 1;
} else {
irq_mask = DISPC_IRQ_EVSYNC_EVEN | DISPC_IRQ_EVSYNC_ODD;
/* XXX I understand from TRM that we should only wait for the
* current field to complete. But it seems we have to wait for
* both fields */
num_irqs = 2;
}
r = omap_dispc_register_isr(dispc_disable_isr, &frame_done_completion,
irq_mask);
if (r)
DSSERR("failed to register %x isr\n", irq_mask);
_enable_digit_out(enable);
for (i = 0; i < num_irqs; ++i) {
if (!wait_for_completion_timeout(&frame_done_completion,
msecs_to_jiffies(100)))
DSSERR("timeout waiting for digit out to %s\n",
enable ? "start" : "stop");
}
r = omap_dispc_unregister_isr(dispc_disable_isr, &frame_done_completion,
irq_mask);
if (r)
DSSERR("failed to unregister %x isr\n", irq_mask);
if (enable) {
unsigned long flags;
spin_lock_irqsave(&dispc.irq_lock, flags);
dispc.irq_error_mask |= DISPC_IRQ_SYNC_LOST_DIGIT;
dispc_write_reg(DISPC_IRQSTATUS, DISPC_IRQ_SYNC_LOST_DIGIT);
_omap_dispc_set_irqs();
spin_unlock_irqrestore(&dispc.irq_lock, flags);
}
}
bool dispc_mgr_is_enabled(enum omap_channel channel)
{
return !!mgr_fld_read(channel, DISPC_MGR_FLD_ENABLE);
}
void dispc_mgr_enable(enum omap_channel channel, bool enable)
{
if (dss_mgr_is_lcd(channel))
dispc_mgr_enable_lcd_out(channel, enable);
else if (channel == OMAP_DSS_CHANNEL_DIGIT)
dispc_mgr_enable_digit_out(enable);
else
BUG();
}
void dispc_lcd_enable_signal_polarity(bool act_high)
{
if (!dss_has_feature(FEAT_LCDENABLEPOL))
return;
REG_FLD_MOD(DISPC_CONTROL, act_high ? 1 : 0, 29, 29);
}
void dispc_lcd_enable_signal(bool enable)
{
if (!dss_has_feature(FEAT_LCDENABLESIGNAL))
return;
REG_FLD_MOD(DISPC_CONTROL, enable ? 1 : 0, 28, 28);
}
void dispc_pck_free_enable(bool enable)
{
if (!dss_has_feature(FEAT_PCKFREEENABLE))
return;
REG_FLD_MOD(DISPC_CONTROL, enable ? 1 : 0, 27, 27);
}
void dispc_mgr_enable_fifohandcheck(enum omap_channel channel, bool enable)
{
mgr_fld_write(channel, DISPC_MGR_FLD_FIFOHANDCHECK, enable);
}
void dispc_mgr_set_lcd_type_tft(enum omap_channel channel)
{
mgr_fld_write(channel, DISPC_MGR_FLD_STNTFT, 1);
}
void dispc_set_loadmode(enum omap_dss_load_mode mode)
{
REG_FLD_MOD(DISPC_CONFIG, mode, 2, 1);
}
static void dispc_mgr_set_default_color(enum omap_channel channel, u32 color)
{
dispc_write_reg(DISPC_DEFAULT_COLOR(channel), color);
}
static void dispc_mgr_set_trans_key(enum omap_channel ch,
enum omap_dss_trans_key_type type,
u32 trans_key)
{
mgr_fld_write(ch, DISPC_MGR_FLD_TCKSELECTION, type);
dispc_write_reg(DISPC_TRANS_COLOR(ch), trans_key);
}
static void dispc_mgr_enable_trans_key(enum omap_channel ch, bool enable)
{
mgr_fld_write(ch, DISPC_MGR_FLD_TCKENABLE, enable);
}
OMAPDSS/OMAP_VOUT: Fix incorrect OMAP3-alpha compatibility setting On OMAP3, in order to enable alpha blending for LCD and TV managers, we needed to set LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits in DISPC_CONFIG. On OMAP4, alpha blending is always enabled by default, if the above bits are set, we switch to an OMAP3 compatibility mode where the zorder values in the pipeline attribute registers are ignored and a fixed priority is configured. Rename the manager_info member "alpha_enabled" to "partial_alpha_enabled" for more clarity. Introduce two dss_features FEAT_ALPHA_FIXED_ZORDER and FEAT_ALPHA_FREE_ZORDER which represent OMAP3-alpha compatibility mode and OMAP4 alpha mode respectively. Introduce an overlay cap for ZORDER. The DSS2 user is expected to check for the ZORDER cap, if an overlay doesn't have this cap, the user is expected to set the parameter partial_alpha_enabled. If the overlay has ZORDER cap, the DSS2 user can assume that alpha blending is already enabled. Don't support OMAP3 compatibility mode for now. Trying to read/write to alpha_blending_enabled sysfs attribute issues a warning for OMAP4 and does not set the LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits. Change alpha_enabled to partial_alpha_enabled in the omap_vout driver. Use overlay cap "OMAP_DSS_OVL_CAP_GLOBAL_ALPHA" to check if overlay supports alpha blending or not. Replace this with checks for VIDEO1 pipeline. Cc: linux-media@vger.kernel.org Cc: Lajos Molnar <molnar@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Acked-by: Vaibhav Hiremath <hvaibhav@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-09-26 13:17:29 +07:00
static void dispc_mgr_enable_alpha_fixed_zorder(enum omap_channel ch,
bool enable)
{
OMAPDSS/OMAP_VOUT: Fix incorrect OMAP3-alpha compatibility setting On OMAP3, in order to enable alpha blending for LCD and TV managers, we needed to set LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits in DISPC_CONFIG. On OMAP4, alpha blending is always enabled by default, if the above bits are set, we switch to an OMAP3 compatibility mode where the zorder values in the pipeline attribute registers are ignored and a fixed priority is configured. Rename the manager_info member "alpha_enabled" to "partial_alpha_enabled" for more clarity. Introduce two dss_features FEAT_ALPHA_FIXED_ZORDER and FEAT_ALPHA_FREE_ZORDER which represent OMAP3-alpha compatibility mode and OMAP4 alpha mode respectively. Introduce an overlay cap for ZORDER. The DSS2 user is expected to check for the ZORDER cap, if an overlay doesn't have this cap, the user is expected to set the parameter partial_alpha_enabled. If the overlay has ZORDER cap, the DSS2 user can assume that alpha blending is already enabled. Don't support OMAP3 compatibility mode for now. Trying to read/write to alpha_blending_enabled sysfs attribute issues a warning for OMAP4 and does not set the LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits. Change alpha_enabled to partial_alpha_enabled in the omap_vout driver. Use overlay cap "OMAP_DSS_OVL_CAP_GLOBAL_ALPHA" to check if overlay supports alpha blending or not. Replace this with checks for VIDEO1 pipeline. Cc: linux-media@vger.kernel.org Cc: Lajos Molnar <molnar@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Acked-by: Vaibhav Hiremath <hvaibhav@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-09-26 13:17:29 +07:00
if (!dss_has_feature(FEAT_ALPHA_FIXED_ZORDER))
return;
if (ch == OMAP_DSS_CHANNEL_LCD)
REG_FLD_MOD(DISPC_CONFIG, enable, 18, 18);
else if (ch == OMAP_DSS_CHANNEL_DIGIT)
REG_FLD_MOD(DISPC_CONFIG, enable, 19, 19);
}
OMAPDSS/OMAP_VOUT: Fix incorrect OMAP3-alpha compatibility setting On OMAP3, in order to enable alpha blending for LCD and TV managers, we needed to set LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits in DISPC_CONFIG. On OMAP4, alpha blending is always enabled by default, if the above bits are set, we switch to an OMAP3 compatibility mode where the zorder values in the pipeline attribute registers are ignored and a fixed priority is configured. Rename the manager_info member "alpha_enabled" to "partial_alpha_enabled" for more clarity. Introduce two dss_features FEAT_ALPHA_FIXED_ZORDER and FEAT_ALPHA_FREE_ZORDER which represent OMAP3-alpha compatibility mode and OMAP4 alpha mode respectively. Introduce an overlay cap for ZORDER. The DSS2 user is expected to check for the ZORDER cap, if an overlay doesn't have this cap, the user is expected to set the parameter partial_alpha_enabled. If the overlay has ZORDER cap, the DSS2 user can assume that alpha blending is already enabled. Don't support OMAP3 compatibility mode for now. Trying to read/write to alpha_blending_enabled sysfs attribute issues a warning for OMAP4 and does not set the LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits. Change alpha_enabled to partial_alpha_enabled in the omap_vout driver. Use overlay cap "OMAP_DSS_OVL_CAP_GLOBAL_ALPHA" to check if overlay supports alpha blending or not. Replace this with checks for VIDEO1 pipeline. Cc: linux-media@vger.kernel.org Cc: Lajos Molnar <molnar@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Acked-by: Vaibhav Hiremath <hvaibhav@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-09-26 13:17:29 +07:00
void dispc_mgr_setup(enum omap_channel channel,
struct omap_overlay_manager_info *info)
{
dispc_mgr_set_default_color(channel, info->default_color);
dispc_mgr_set_trans_key(channel, info->trans_key_type, info->trans_key);
dispc_mgr_enable_trans_key(channel, info->trans_enabled);
dispc_mgr_enable_alpha_fixed_zorder(channel,
info->partial_alpha_enabled);
if (dss_has_feature(FEAT_CPR)) {
dispc_mgr_enable_cpr(channel, info->cpr_enable);
dispc_mgr_set_cpr_coef(channel, &info->cpr_coefs);
}
}
void dispc_mgr_set_tft_data_lines(enum omap_channel channel, u8 data_lines)
{
int code;
switch (data_lines) {
case 12:
code = 0;
break;
case 16:
code = 1;
break;
case 18:
code = 2;
break;
case 24:
code = 3;
break;
default:
BUG();
return;
}
mgr_fld_write(channel, DISPC_MGR_FLD_TFTDATALINES, code);
}
void dispc_mgr_set_io_pad_mode(enum dss_io_pad_mode mode)
{
u32 l;
int gpout0, gpout1;
switch (mode) {
case DSS_IO_PAD_MODE_RESET:
gpout0 = 0;
gpout1 = 0;
break;
case DSS_IO_PAD_MODE_RFBI:
gpout0 = 1;
gpout1 = 0;
break;
case DSS_IO_PAD_MODE_BYPASS:
gpout0 = 1;
gpout1 = 1;
break;
default:
BUG();
return;
}
l = dispc_read_reg(DISPC_CONTROL);
l = FLD_MOD(l, gpout0, 15, 15);
l = FLD_MOD(l, gpout1, 16, 16);
dispc_write_reg(DISPC_CONTROL, l);
}
void dispc_mgr_enable_stallmode(enum omap_channel channel, bool enable)
{
mgr_fld_write(channel, DISPC_MGR_FLD_STALLMODE, enable);
}
static bool _dispc_mgr_size_ok(u16 width, u16 height)
{
return width <= dss_feat_get_param_max(FEAT_PARAM_MGR_WIDTH) &&
height <= dss_feat_get_param_max(FEAT_PARAM_MGR_HEIGHT);
}
static bool _dispc_lcd_timings_ok(int hsw, int hfp, int hbp,
int vsw, int vfp, int vbp)
{
if (hsw < 1 || hsw > dispc.feat->sw_max ||
hfp < 1 || hfp > dispc.feat->hp_max ||
hbp < 1 || hbp > dispc.feat->hp_max ||
vsw < 1 || vsw > dispc.feat->sw_max ||
vfp < 0 || vfp > dispc.feat->vp_max ||
vbp < 0 || vbp > dispc.feat->vp_max)
return false;
return true;
}
bool dispc_mgr_timings_ok(enum omap_channel channel,
const struct omap_video_timings *timings)
{
bool timings_ok;
timings_ok = _dispc_mgr_size_ok(timings->x_res, timings->y_res);
if (dss_mgr_is_lcd(channel))
timings_ok = timings_ok && _dispc_lcd_timings_ok(timings->hsw,
timings->hfp, timings->hbp,
timings->vsw, timings->vfp,
timings->vbp);
return timings_ok;
}
static void _dispc_mgr_set_lcd_timings(enum omap_channel channel, int hsw,
int hfp, int hbp, int vsw, int vfp, int vbp,
enum omap_dss_signal_level vsync_level,
enum omap_dss_signal_level hsync_level,
enum omap_dss_signal_edge data_pclk_edge,
enum omap_dss_signal_level de_level,
enum omap_dss_signal_edge sync_pclk_edge)
{
u32 timing_h, timing_v, l;
bool onoff, rf, ipc;
timing_h = FLD_VAL(hsw-1, dispc.feat->sw_start, 0) |
FLD_VAL(hfp-1, dispc.feat->fp_start, 8) |
FLD_VAL(hbp-1, dispc.feat->bp_start, 20);
timing_v = FLD_VAL(vsw-1, dispc.feat->sw_start, 0) |
FLD_VAL(vfp, dispc.feat->fp_start, 8) |
FLD_VAL(vbp, dispc.feat->bp_start, 20);
dispc_write_reg(DISPC_TIMING_H(channel), timing_h);
dispc_write_reg(DISPC_TIMING_V(channel), timing_v);
switch (data_pclk_edge) {
case OMAPDSS_DRIVE_SIG_RISING_EDGE:
ipc = false;
break;
case OMAPDSS_DRIVE_SIG_FALLING_EDGE:
ipc = true;
break;
case OMAPDSS_DRIVE_SIG_OPPOSITE_EDGES:
default:
BUG();
}
switch (sync_pclk_edge) {
case OMAPDSS_DRIVE_SIG_OPPOSITE_EDGES:
onoff = false;
rf = false;
break;
case OMAPDSS_DRIVE_SIG_FALLING_EDGE:
onoff = true;
rf = false;
break;
case OMAPDSS_DRIVE_SIG_RISING_EDGE:
onoff = true;
rf = true;
break;
default:
BUG();
};
l = dispc_read_reg(DISPC_POL_FREQ(channel));
l |= FLD_VAL(onoff, 17, 17);
l |= FLD_VAL(rf, 16, 16);
l |= FLD_VAL(de_level, 15, 15);
l |= FLD_VAL(ipc, 14, 14);
l |= FLD_VAL(hsync_level, 13, 13);
l |= FLD_VAL(vsync_level, 12, 12);
dispc_write_reg(DISPC_POL_FREQ(channel), l);
}
/* change name to mode? */
void dispc_mgr_set_timings(enum omap_channel channel,
struct omap_video_timings *timings)
{
unsigned xtot, ytot;
unsigned long ht, vt;
struct omap_video_timings t = *timings;
DSSDBG("channel %d xres %u yres %u\n", channel, t.x_res, t.y_res);
if (!dispc_mgr_timings_ok(channel, &t)) {
BUG();
return;
}
if (dss_mgr_is_lcd(channel)) {
_dispc_mgr_set_lcd_timings(channel, t.hsw, t.hfp, t.hbp, t.vsw,
t.vfp, t.vbp, t.vsync_level, t.hsync_level,
t.data_pclk_edge, t.de_level, t.sync_pclk_edge);
xtot = t.x_res + t.hfp + t.hsw + t.hbp;
ytot = t.y_res + t.vfp + t.vsw + t.vbp;
ht = (timings->pixel_clock * 1000) / xtot;
vt = (timings->pixel_clock * 1000) / xtot / ytot;
DSSDBG("pck %u\n", timings->pixel_clock);
DSSDBG("hsw %d hfp %d hbp %d vsw %d vfp %d vbp %d\n",
t.hsw, t.hfp, t.hbp, t.vsw, t.vfp, t.vbp);
DSSDBG("vsync_level %d hsync_level %d data_pclk_edge %d de_level %d sync_pclk_edge %d\n",
t.vsync_level, t.hsync_level, t.data_pclk_edge,
t.de_level, t.sync_pclk_edge);
DSSDBG("hsync %luHz, vsync %luHz\n", ht, vt);
} else {
if (t.interlace == true)
t.y_res /= 2;
}
dispc_mgr_set_size(channel, t.x_res, t.y_res);
}
static void dispc_mgr_set_lcd_divisor(enum omap_channel channel, u16 lck_div,
u16 pck_div)
{
BUG_ON(lck_div < 1);
BUG_ON(pck_div < 1);
dispc_write_reg(DISPC_DIVISORo(channel),
FLD_VAL(lck_div, 23, 16) | FLD_VAL(pck_div, 7, 0));
}
static void dispc_mgr_get_lcd_divisor(enum omap_channel channel, int *lck_div,
int *pck_div)
{
u32 l;
l = dispc_read_reg(DISPC_DIVISORo(channel));
*lck_div = FLD_GET(l, 23, 16);
*pck_div = FLD_GET(l, 7, 0);
}
unsigned long dispc_fclk_rate(void)
{
struct platform_device *dsidev;
unsigned long r = 0;
switch (dss_get_dispc_clk_source()) {
case OMAP_DSS_CLK_SRC_FCK:
r = clk_get_rate(dispc.dss_clk);
break;
case OMAP_DSS_CLK_SRC_DSI_PLL_HSDIV_DISPC:
dsidev = dsi_get_dsidev_from_id(0);
r = dsi_get_pll_hsdiv_dispc_rate(dsidev);
break;
case OMAP_DSS_CLK_SRC_DSI2_PLL_HSDIV_DISPC:
dsidev = dsi_get_dsidev_from_id(1);
r = dsi_get_pll_hsdiv_dispc_rate(dsidev);
break;
default:
BUG();
return 0;
}
return r;
}
unsigned long dispc_mgr_lclk_rate(enum omap_channel channel)
{
struct platform_device *dsidev;
int lcd;
unsigned long r;
u32 l;
l = dispc_read_reg(DISPC_DIVISORo(channel));
lcd = FLD_GET(l, 23, 16);
switch (dss_get_lcd_clk_source(channel)) {
case OMAP_DSS_CLK_SRC_FCK:
r = clk_get_rate(dispc.dss_clk);
break;
case OMAP_DSS_CLK_SRC_DSI_PLL_HSDIV_DISPC:
dsidev = dsi_get_dsidev_from_id(0);
r = dsi_get_pll_hsdiv_dispc_rate(dsidev);
break;
case OMAP_DSS_CLK_SRC_DSI2_PLL_HSDIV_DISPC:
dsidev = dsi_get_dsidev_from_id(1);
r = dsi_get_pll_hsdiv_dispc_rate(dsidev);
break;
default:
BUG();
return 0;
}
return r / lcd;
}
unsigned long dispc_mgr_pclk_rate(enum omap_channel channel)
{
unsigned long r;
if (dss_mgr_is_lcd(channel)) {
int pcd;
u32 l;
l = dispc_read_reg(DISPC_DIVISORo(channel));
pcd = FLD_GET(l, 7, 0);
r = dispc_mgr_lclk_rate(channel);
return r / pcd;
} else {
enum dss_hdmi_venc_clk_source_select source;
source = dss_get_hdmi_venc_clk_source();
switch (source) {
case DSS_VENC_TV_CLK:
return venc_get_pixel_clock();
case DSS_HDMI_M_PCLK:
return hdmi_get_pixel_clock();
default:
BUG();
return 0;
}
}
}
unsigned long dispc_core_clk_rate(void)
{
int lcd;
unsigned long fclk = dispc_fclk_rate();
if (dss_has_feature(FEAT_CORE_CLK_DIV))
lcd = REG_GET(DISPC_DIVISOR, 23, 16);
else
lcd = REG_GET(DISPC_DIVISORo(OMAP_DSS_CHANNEL_LCD), 23, 16);
return fclk / lcd;
}
static void dispc_dump_clocks_channel(struct seq_file *s, enum omap_channel channel)
{
int lcd, pcd;
enum omap_dss_clk_source lcd_clk_src;
seq_printf(s, "- %s -\n", mgr_desc[channel].name);
lcd_clk_src = dss_get_lcd_clk_source(channel);
seq_printf(s, "%s clk source = %s (%s)\n", mgr_desc[channel].name,
dss_get_generic_clk_source_name(lcd_clk_src),
dss_feat_get_clk_source_name(lcd_clk_src));
dispc_mgr_get_lcd_divisor(channel, &lcd, &pcd);
seq_printf(s, "lck\t\t%-16lulck div\t%u\n",
dispc_mgr_lclk_rate(channel), lcd);
seq_printf(s, "pck\t\t%-16lupck div\t%u\n",
dispc_mgr_pclk_rate(channel), pcd);
}
void dispc_dump_clocks(struct seq_file *s)
{
int lcd;
u32 l;
enum omap_dss_clk_source dispc_clk_src = dss_get_dispc_clk_source();
if (dispc_runtime_get())
return;
seq_printf(s, "- DISPC -\n");
seq_printf(s, "dispc fclk source = %s (%s)\n",
dss_get_generic_clk_source_name(dispc_clk_src),
dss_feat_get_clk_source_name(dispc_clk_src));
seq_printf(s, "fck\t\t%-16lu\n", dispc_fclk_rate());
if (dss_has_feature(FEAT_CORE_CLK_DIV)) {
seq_printf(s, "- DISPC-CORE-CLK -\n");
l = dispc_read_reg(DISPC_DIVISOR);
lcd = FLD_GET(l, 23, 16);
seq_printf(s, "lck\t\t%-16lulck div\t%u\n",
(dispc_fclk_rate()/lcd), lcd);
}
dispc_dump_clocks_channel(s, OMAP_DSS_CHANNEL_LCD);
if (dss_has_feature(FEAT_MGR_LCD2))
dispc_dump_clocks_channel(s, OMAP_DSS_CHANNEL_LCD2);
if (dss_has_feature(FEAT_MGR_LCD3))
dispc_dump_clocks_channel(s, OMAP_DSS_CHANNEL_LCD3);
dispc_runtime_put();
}
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
void dispc_dump_irqs(struct seq_file *s)
{
unsigned long flags;
struct dispc_irq_stats stats;
spin_lock_irqsave(&dispc.irq_stats_lock, flags);
stats = dispc.irq_stats;
memset(&dispc.irq_stats, 0, sizeof(dispc.irq_stats));
dispc.irq_stats.last_reset = jiffies;
spin_unlock_irqrestore(&dispc.irq_stats_lock, flags);
seq_printf(s, "period %u ms\n",
jiffies_to_msecs(jiffies - stats.last_reset));
seq_printf(s, "irqs %d\n", stats.irq_count);
#define PIS(x) \
seq_printf(s, "%-20s %10d\n", #x, stats.irqs[ffs(DISPC_IRQ_##x)-1]);
PIS(FRAMEDONE);
PIS(VSYNC);
PIS(EVSYNC_EVEN);
PIS(EVSYNC_ODD);
PIS(ACBIAS_COUNT_STAT);
PIS(PROG_LINE_NUM);
PIS(GFX_FIFO_UNDERFLOW);
PIS(GFX_END_WIN);
PIS(PAL_GAMMA_MASK);
PIS(OCP_ERR);
PIS(VID1_FIFO_UNDERFLOW);
PIS(VID1_END_WIN);
PIS(VID2_FIFO_UNDERFLOW);
PIS(VID2_END_WIN);
if (dss_feat_get_num_ovls() > 3) {
PIS(VID3_FIFO_UNDERFLOW);
PIS(VID3_END_WIN);
}
PIS(SYNC_LOST);
PIS(SYNC_LOST_DIGIT);
PIS(WAKEUP);
if (dss_has_feature(FEAT_MGR_LCD2)) {
PIS(FRAMEDONE2);
PIS(VSYNC2);
PIS(ACBIAS_COUNT_STAT2);
PIS(SYNC_LOST2);
}
if (dss_has_feature(FEAT_MGR_LCD3)) {
PIS(FRAMEDONE3);
PIS(VSYNC3);
PIS(ACBIAS_COUNT_STAT3);
PIS(SYNC_LOST3);
}
#undef PIS
}
#endif
static void dispc_dump_regs(struct seq_file *s)
{
int i, j;
const char *mgr_names[] = {
[OMAP_DSS_CHANNEL_LCD] = "LCD",
[OMAP_DSS_CHANNEL_DIGIT] = "TV",
[OMAP_DSS_CHANNEL_LCD2] = "LCD2",
[OMAP_DSS_CHANNEL_LCD3] = "LCD3",
};
const char *ovl_names[] = {
[OMAP_DSS_GFX] = "GFX",
[OMAP_DSS_VIDEO1] = "VID1",
[OMAP_DSS_VIDEO2] = "VID2",
[OMAP_DSS_VIDEO3] = "VID3",
};
const char **p_names;
#define DUMPREG(r) seq_printf(s, "%-50s %08x\n", #r, dispc_read_reg(r))
if (dispc_runtime_get())
return;
/* DISPC common registers */
DUMPREG(DISPC_REVISION);
DUMPREG(DISPC_SYSCONFIG);
DUMPREG(DISPC_SYSSTATUS);
DUMPREG(DISPC_IRQSTATUS);
DUMPREG(DISPC_IRQENABLE);
DUMPREG(DISPC_CONTROL);
DUMPREG(DISPC_CONFIG);
DUMPREG(DISPC_CAPABLE);
DUMPREG(DISPC_LINE_STATUS);
DUMPREG(DISPC_LINE_NUMBER);
OMAPDSS/OMAP_VOUT: Fix incorrect OMAP3-alpha compatibility setting On OMAP3, in order to enable alpha blending for LCD and TV managers, we needed to set LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits in DISPC_CONFIG. On OMAP4, alpha blending is always enabled by default, if the above bits are set, we switch to an OMAP3 compatibility mode where the zorder values in the pipeline attribute registers are ignored and a fixed priority is configured. Rename the manager_info member "alpha_enabled" to "partial_alpha_enabled" for more clarity. Introduce two dss_features FEAT_ALPHA_FIXED_ZORDER and FEAT_ALPHA_FREE_ZORDER which represent OMAP3-alpha compatibility mode and OMAP4 alpha mode respectively. Introduce an overlay cap for ZORDER. The DSS2 user is expected to check for the ZORDER cap, if an overlay doesn't have this cap, the user is expected to set the parameter partial_alpha_enabled. If the overlay has ZORDER cap, the DSS2 user can assume that alpha blending is already enabled. Don't support OMAP3 compatibility mode for now. Trying to read/write to alpha_blending_enabled sysfs attribute issues a warning for OMAP4 and does not set the LCDALPHABLENDERENABLE/TVALPHABLENDERENABLE bits. Change alpha_enabled to partial_alpha_enabled in the omap_vout driver. Use overlay cap "OMAP_DSS_OVL_CAP_GLOBAL_ALPHA" to check if overlay supports alpha blending or not. Replace this with checks for VIDEO1 pipeline. Cc: linux-media@vger.kernel.org Cc: Lajos Molnar <molnar@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Acked-by: Vaibhav Hiremath <hvaibhav@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-09-26 13:17:29 +07:00
if (dss_has_feature(FEAT_ALPHA_FIXED_ZORDER) ||
dss_has_feature(FEAT_ALPHA_FREE_ZORDER))
DUMPREG(DISPC_GLOBAL_ALPHA);
if (dss_has_feature(FEAT_MGR_LCD2)) {
DUMPREG(DISPC_CONTROL2);
DUMPREG(DISPC_CONFIG2);
}
if (dss_has_feature(FEAT_MGR_LCD3)) {
DUMPREG(DISPC_CONTROL3);
DUMPREG(DISPC_CONFIG3);
}
#undef DUMPREG
#define DISPC_REG(i, name) name(i)
#define DUMPREG(i, r) seq_printf(s, "%s(%s)%*s %08x\n", #r, p_names[i], \
48 - strlen(#r) - strlen(p_names[i]), " ", \
dispc_read_reg(DISPC_REG(i, r)))
p_names = mgr_names;
/* DISPC channel specific registers */
for (i = 0; i < dss_feat_get_num_mgrs(); i++) {
DUMPREG(i, DISPC_DEFAULT_COLOR);
DUMPREG(i, DISPC_TRANS_COLOR);
DUMPREG(i, DISPC_SIZE_MGR);
if (i == OMAP_DSS_CHANNEL_DIGIT)
continue;
DUMPREG(i, DISPC_DEFAULT_COLOR);
DUMPREG(i, DISPC_TRANS_COLOR);
DUMPREG(i, DISPC_TIMING_H);
DUMPREG(i, DISPC_TIMING_V);
DUMPREG(i, DISPC_POL_FREQ);
DUMPREG(i, DISPC_DIVISORo);
DUMPREG(i, DISPC_SIZE_MGR);
DUMPREG(i, DISPC_DATA_CYCLE1);
DUMPREG(i, DISPC_DATA_CYCLE2);
DUMPREG(i, DISPC_DATA_CYCLE3);
if (dss_has_feature(FEAT_CPR)) {
DUMPREG(i, DISPC_CPR_COEF_R);
DUMPREG(i, DISPC_CPR_COEF_G);
DUMPREG(i, DISPC_CPR_COEF_B);
}
}
p_names = ovl_names;
for (i = 0; i < dss_feat_get_num_ovls(); i++) {
DUMPREG(i, DISPC_OVL_BA0);
DUMPREG(i, DISPC_OVL_BA1);
DUMPREG(i, DISPC_OVL_POSITION);
DUMPREG(i, DISPC_OVL_SIZE);
DUMPREG(i, DISPC_OVL_ATTRIBUTES);
DUMPREG(i, DISPC_OVL_FIFO_THRESHOLD);
DUMPREG(i, DISPC_OVL_FIFO_SIZE_STATUS);
DUMPREG(i, DISPC_OVL_ROW_INC);
DUMPREG(i, DISPC_OVL_PIXEL_INC);
if (dss_has_feature(FEAT_PRELOAD))
DUMPREG(i, DISPC_OVL_PRELOAD);
if (i == OMAP_DSS_GFX) {
DUMPREG(i, DISPC_OVL_WINDOW_SKIP);
DUMPREG(i, DISPC_OVL_TABLE_BA);
continue;
}
DUMPREG(i, DISPC_OVL_FIR);
DUMPREG(i, DISPC_OVL_PICTURE_SIZE);
DUMPREG(i, DISPC_OVL_ACCU0);
DUMPREG(i, DISPC_OVL_ACCU1);
if (dss_has_feature(FEAT_HANDLE_UV_SEPARATE)) {
DUMPREG(i, DISPC_OVL_BA0_UV);
DUMPREG(i, DISPC_OVL_BA1_UV);
DUMPREG(i, DISPC_OVL_FIR2);
DUMPREG(i, DISPC_OVL_ACCU2_0);
DUMPREG(i, DISPC_OVL_ACCU2_1);
}
if (dss_has_feature(FEAT_ATTR2))
DUMPREG(i, DISPC_OVL_ATTRIBUTES2);
if (dss_has_feature(FEAT_PRELOAD))
DUMPREG(i, DISPC_OVL_PRELOAD);
}
#undef DISPC_REG
#undef DUMPREG
#define DISPC_REG(plane, name, i) name(plane, i)
#define DUMPREG(plane, name, i) \
seq_printf(s, "%s_%d(%s)%*s %08x\n", #name, i, p_names[plane], \
46 - strlen(#name) - strlen(p_names[plane]), " ", \
dispc_read_reg(DISPC_REG(plane, name, i)))
/* Video pipeline coefficient registers */
/* start from OMAP_DSS_VIDEO1 */
for (i = 1; i < dss_feat_get_num_ovls(); i++) {
for (j = 0; j < 8; j++)
DUMPREG(i, DISPC_OVL_FIR_COEF_H, j);
for (j = 0; j < 8; j++)
DUMPREG(i, DISPC_OVL_FIR_COEF_HV, j);
for (j = 0; j < 5; j++)
DUMPREG(i, DISPC_OVL_CONV_COEF, j);
if (dss_has_feature(FEAT_FIR_COEF_V)) {
for (j = 0; j < 8; j++)
DUMPREG(i, DISPC_OVL_FIR_COEF_V, j);
}
if (dss_has_feature(FEAT_HANDLE_UV_SEPARATE)) {
for (j = 0; j < 8; j++)
DUMPREG(i, DISPC_OVL_FIR_COEF_H2, j);
for (j = 0; j < 8; j++)
DUMPREG(i, DISPC_OVL_FIR_COEF_HV2, j);
for (j = 0; j < 8; j++)
DUMPREG(i, DISPC_OVL_FIR_COEF_V2, j);
}
}
dispc_runtime_put();
#undef DISPC_REG
#undef DUMPREG
}
/* with fck as input clock rate, find dispc dividers that produce req_pck */
void dispc_find_clk_divs(unsigned long req_pck, unsigned long fck,
struct dispc_clock_info *cinfo)
{
u16 pcd_min, pcd_max;
unsigned long best_pck;
u16 best_ld, cur_ld;
u16 best_pd, cur_pd;
pcd_min = dss_feat_get_param_min(FEAT_PARAM_DSS_PCD);
pcd_max = dss_feat_get_param_max(FEAT_PARAM_DSS_PCD);
best_pck = 0;
best_ld = 0;
best_pd = 0;
for (cur_ld = 1; cur_ld <= 255; ++cur_ld) {
unsigned long lck = fck / cur_ld;
for (cur_pd = pcd_min; cur_pd <= pcd_max; ++cur_pd) {
unsigned long pck = lck / cur_pd;
long old_delta = abs(best_pck - req_pck);
long new_delta = abs(pck - req_pck);
if (best_pck == 0 || new_delta < old_delta) {
best_pck = pck;
best_ld = cur_ld;
best_pd = cur_pd;
if (pck == req_pck)
goto found;
}
if (pck < req_pck)
break;
}
if (lck / pcd_min < req_pck)
break;
}
found:
cinfo->lck_div = best_ld;
cinfo->pck_div = best_pd;
cinfo->lck = fck / cinfo->lck_div;
cinfo->pck = cinfo->lck / cinfo->pck_div;
}
/* calculate clock rates using dividers in cinfo */
int dispc_calc_clock_rates(unsigned long dispc_fclk_rate,
struct dispc_clock_info *cinfo)
{
if (cinfo->lck_div > 255 || cinfo->lck_div == 0)
return -EINVAL;
if (cinfo->pck_div < 1 || cinfo->pck_div > 255)
return -EINVAL;
cinfo->lck = dispc_fclk_rate / cinfo->lck_div;
cinfo->pck = cinfo->lck / cinfo->pck_div;
return 0;
}
void dispc_mgr_set_clock_div(enum omap_channel channel,
struct dispc_clock_info *cinfo)
{
DSSDBG("lck = %lu (%u)\n", cinfo->lck, cinfo->lck_div);
DSSDBG("pck = %lu (%u)\n", cinfo->pck, cinfo->pck_div);
dispc_mgr_set_lcd_divisor(channel, cinfo->lck_div, cinfo->pck_div);
}
int dispc_mgr_get_clock_div(enum omap_channel channel,
struct dispc_clock_info *cinfo)
{
unsigned long fck;
fck = dispc_fclk_rate();
cinfo->lck_div = REG_GET(DISPC_DIVISORo(channel), 23, 16);
cinfo->pck_div = REG_GET(DISPC_DIVISORo(channel), 7, 0);
cinfo->lck = fck / cinfo->lck_div;
cinfo->pck = cinfo->lck / cinfo->pck_div;
return 0;
}
/* dispc.irq_lock has to be locked by the caller */
static void _omap_dispc_set_irqs(void)
{
u32 mask;
u32 old_mask;
int i;
struct omap_dispc_isr_data *isr_data;
mask = dispc.irq_error_mask;
for (i = 0; i < DISPC_MAX_NR_ISRS; i++) {
isr_data = &dispc.registered_isr[i];
if (isr_data->isr == NULL)
continue;
mask |= isr_data->mask;
}
old_mask = dispc_read_reg(DISPC_IRQENABLE);
/* clear the irqstatus for newly enabled irqs */
dispc_write_reg(DISPC_IRQSTATUS, (mask ^ old_mask) & mask);
dispc_write_reg(DISPC_IRQENABLE, mask);
}
int omap_dispc_register_isr(omap_dispc_isr_t isr, void *arg, u32 mask)
{
int i;
int ret;
unsigned long flags;
struct omap_dispc_isr_data *isr_data;
if (isr == NULL)
return -EINVAL;
spin_lock_irqsave(&dispc.irq_lock, flags);
/* check for duplicate entry */
for (i = 0; i < DISPC_MAX_NR_ISRS; i++) {
isr_data = &dispc.registered_isr[i];
if (isr_data->isr == isr && isr_data->arg == arg &&
isr_data->mask == mask) {
ret = -EINVAL;
goto err;
}
}
isr_data = NULL;
ret = -EBUSY;
for (i = 0; i < DISPC_MAX_NR_ISRS; i++) {
isr_data = &dispc.registered_isr[i];
if (isr_data->isr != NULL)
continue;
isr_data->isr = isr;
isr_data->arg = arg;
isr_data->mask = mask;
ret = 0;
break;
}
if (ret)
goto err;
_omap_dispc_set_irqs();
spin_unlock_irqrestore(&dispc.irq_lock, flags);
return 0;
err:
spin_unlock_irqrestore(&dispc.irq_lock, flags);
return ret;
}
EXPORT_SYMBOL(omap_dispc_register_isr);
int omap_dispc_unregister_isr(omap_dispc_isr_t isr, void *arg, u32 mask)
{
int i;
unsigned long flags;
int ret = -EINVAL;
struct omap_dispc_isr_data *isr_data;
spin_lock_irqsave(&dispc.irq_lock, flags);
for (i = 0; i < DISPC_MAX_NR_ISRS; i++) {
isr_data = &dispc.registered_isr[i];
if (isr_data->isr != isr || isr_data->arg != arg ||
isr_data->mask != mask)
continue;
/* found the correct isr */
isr_data->isr = NULL;
isr_data->arg = NULL;
isr_data->mask = 0;
ret = 0;
break;
}
if (ret == 0)
_omap_dispc_set_irqs();
spin_unlock_irqrestore(&dispc.irq_lock, flags);
return ret;
}
EXPORT_SYMBOL(omap_dispc_unregister_isr);
#ifdef DEBUG
static void print_irq_status(u32 status)
{
if ((status & dispc.irq_error_mask) == 0)
return;
printk(KERN_DEBUG "DISPC IRQ: 0x%x: ", status);
#define PIS(x) \
if (status & DISPC_IRQ_##x) \
printk(#x " ");
PIS(GFX_FIFO_UNDERFLOW);
PIS(OCP_ERR);
PIS(VID1_FIFO_UNDERFLOW);
PIS(VID2_FIFO_UNDERFLOW);
if (dss_feat_get_num_ovls() > 3)
PIS(VID3_FIFO_UNDERFLOW);
PIS(SYNC_LOST);
PIS(SYNC_LOST_DIGIT);
if (dss_has_feature(FEAT_MGR_LCD2))
PIS(SYNC_LOST2);
if (dss_has_feature(FEAT_MGR_LCD3))
PIS(SYNC_LOST3);
#undef PIS
printk("\n");
}
#endif
/* Called from dss.c. Note that we don't touch clocks here,
* but we presume they are on because we got an IRQ. However,
* an irq handler may turn the clocks off, so we may not have
* clock later in the function. */
static irqreturn_t omap_dispc_irq_handler(int irq, void *arg)
{
int i;
u32 irqstatus, irqenable;
u32 handledirqs = 0;
u32 unhandled_errors;
struct omap_dispc_isr_data *isr_data;
struct omap_dispc_isr_data registered_isr[DISPC_MAX_NR_ISRS];
spin_lock(&dispc.irq_lock);
irqstatus = dispc_read_reg(DISPC_IRQSTATUS);
irqenable = dispc_read_reg(DISPC_IRQENABLE);
/* IRQ is not for us */
if (!(irqstatus & irqenable)) {
spin_unlock(&dispc.irq_lock);
return IRQ_NONE;
}
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
spin_lock(&dispc.irq_stats_lock);
dispc.irq_stats.irq_count++;
dss_collect_irq_stats(irqstatus, dispc.irq_stats.irqs);
spin_unlock(&dispc.irq_stats_lock);
#endif
#ifdef DEBUG
if (dss_debug)
print_irq_status(irqstatus);
#endif
/* Ack the interrupt. Do it here before clocks are possibly turned
* off */
dispc_write_reg(DISPC_IRQSTATUS, irqstatus);
/* flush posted write */
dispc_read_reg(DISPC_IRQSTATUS);
/* make a copy and unlock, so that isrs can unregister
* themselves */
memcpy(registered_isr, dispc.registered_isr,
sizeof(registered_isr));
spin_unlock(&dispc.irq_lock);
for (i = 0; i < DISPC_MAX_NR_ISRS; i++) {
isr_data = &registered_isr[i];
if (!isr_data->isr)
continue;
if (isr_data->mask & irqstatus) {
isr_data->isr(isr_data->arg, irqstatus);
handledirqs |= isr_data->mask;
}
}
spin_lock(&dispc.irq_lock);
unhandled_errors = irqstatus & ~handledirqs & dispc.irq_error_mask;
if (unhandled_errors) {
dispc.error_irqs |= unhandled_errors;
dispc.irq_error_mask &= ~unhandled_errors;
_omap_dispc_set_irqs();
schedule_work(&dispc.error_work);
}
spin_unlock(&dispc.irq_lock);
return IRQ_HANDLED;
}
static void dispc_error_worker(struct work_struct *work)
{
int i;
u32 errors;
unsigned long flags;
static const unsigned fifo_underflow_bits[] = {
DISPC_IRQ_GFX_FIFO_UNDERFLOW,
DISPC_IRQ_VID1_FIFO_UNDERFLOW,
DISPC_IRQ_VID2_FIFO_UNDERFLOW,
DISPC_IRQ_VID3_FIFO_UNDERFLOW,
};
spin_lock_irqsave(&dispc.irq_lock, flags);
errors = dispc.error_irqs;
dispc.error_irqs = 0;
spin_unlock_irqrestore(&dispc.irq_lock, flags);
dispc_runtime_get();
for (i = 0; i < omap_dss_get_num_overlays(); ++i) {
struct omap_overlay *ovl;
unsigned bit;
ovl = omap_dss_get_overlay(i);
bit = fifo_underflow_bits[i];
if (bit & errors) {
DSSERR("FIFO UNDERFLOW on %s, disabling the overlay\n",
ovl->name);
dispc_ovl_enable(ovl->id, false);
dispc_mgr_go(ovl->manager->id);
msleep(50);
}
}
for (i = 0; i < omap_dss_get_num_overlay_managers(); ++i) {
struct omap_overlay_manager *mgr;
unsigned bit;
mgr = omap_dss_get_overlay_manager(i);
bit = mgr_desc[i].sync_lost_irq;
if (bit & errors) {
struct omap_dss_device *dssdev = mgr->get_device(mgr);
bool enable;
DSSERR("SYNC_LOST on channel %s, restarting the output "
"with video overlays disabled\n",
mgr->name);
enable = dssdev->state == OMAP_DSS_DISPLAY_ACTIVE;
dssdev->driver->disable(dssdev);
for (i = 0; i < omap_dss_get_num_overlays(); ++i) {
struct omap_overlay *ovl;
ovl = omap_dss_get_overlay(i);
if (ovl->id != OMAP_DSS_GFX &&
ovl->manager == mgr)
dispc_ovl_enable(ovl->id, false);
}
dispc_mgr_go(mgr->id);
msleep(50);
if (enable)
dssdev->driver->enable(dssdev);
}
}
if (errors & DISPC_IRQ_OCP_ERR) {
DSSERR("OCP_ERR\n");
for (i = 0; i < omap_dss_get_num_overlay_managers(); ++i) {
struct omap_overlay_manager *mgr;
struct omap_dss_device *dssdev;
mgr = omap_dss_get_overlay_manager(i);
dssdev = mgr->get_device(mgr);
if (dssdev && dssdev->driver)
dssdev->driver->disable(dssdev);
}
}
spin_lock_irqsave(&dispc.irq_lock, flags);
dispc.irq_error_mask |= errors;
_omap_dispc_set_irqs();
spin_unlock_irqrestore(&dispc.irq_lock, flags);
dispc_runtime_put();
}
int omap_dispc_wait_for_irq_timeout(u32 irqmask, unsigned long timeout)
{
void dispc_irq_wait_handler(void *data, u32 mask)
{
complete((struct completion *)data);
}
int r;
DECLARE_COMPLETION_ONSTACK(completion);
r = omap_dispc_register_isr(dispc_irq_wait_handler, &completion,
irqmask);
if (r)
return r;
timeout = wait_for_completion_timeout(&completion, timeout);
omap_dispc_unregister_isr(dispc_irq_wait_handler, &completion, irqmask);
if (timeout == 0)
return -ETIMEDOUT;
if (timeout == -ERESTARTSYS)
return -ERESTARTSYS;
return 0;
}
int omap_dispc_wait_for_irq_interruptible_timeout(u32 irqmask,
unsigned long timeout)
{
void dispc_irq_wait_handler(void *data, u32 mask)
{
complete((struct completion *)data);
}
int r;
DECLARE_COMPLETION_ONSTACK(completion);
r = omap_dispc_register_isr(dispc_irq_wait_handler, &completion,
irqmask);
if (r)
return r;
timeout = wait_for_completion_interruptible_timeout(&completion,
timeout);
omap_dispc_unregister_isr(dispc_irq_wait_handler, &completion, irqmask);
if (timeout == 0)
return -ETIMEDOUT;
if (timeout == -ERESTARTSYS)
return -ERESTARTSYS;
return 0;
}
static void _omap_dispc_initialize_irq(void)
{
unsigned long flags;
spin_lock_irqsave(&dispc.irq_lock, flags);
memset(dispc.registered_isr, 0, sizeof(dispc.registered_isr));
dispc.irq_error_mask = DISPC_IRQ_MASK_ERROR;
if (dss_has_feature(FEAT_MGR_LCD2))
dispc.irq_error_mask |= DISPC_IRQ_SYNC_LOST2;
if (dss_has_feature(FEAT_MGR_LCD3))
dispc.irq_error_mask |= DISPC_IRQ_SYNC_LOST3;
if (dss_feat_get_num_ovls() > 3)
dispc.irq_error_mask |= DISPC_IRQ_VID3_FIFO_UNDERFLOW;
/* there's SYNC_LOST_DIGIT waiting after enabling the DSS,
* so clear it */
dispc_write_reg(DISPC_IRQSTATUS, dispc_read_reg(DISPC_IRQSTATUS));
_omap_dispc_set_irqs();
spin_unlock_irqrestore(&dispc.irq_lock, flags);
}
void dispc_enable_sidle(void)
{
REG_FLD_MOD(DISPC_SYSCONFIG, 2, 4, 3); /* SIDLEMODE: smart idle */
}
void dispc_disable_sidle(void)
{
REG_FLD_MOD(DISPC_SYSCONFIG, 1, 4, 3); /* SIDLEMODE: no idle */
}
static void _omap_dispc_initial_config(void)
{
u32 l;
/* Exclusively enable DISPC_CORE_CLK and set divider to 1 */
if (dss_has_feature(FEAT_CORE_CLK_DIV)) {
l = dispc_read_reg(DISPC_DIVISOR);
/* Use DISPC_DIVISOR.LCD, instead of DISPC_DIVISOR1.LCD */
l = FLD_MOD(l, 1, 0, 0);
l = FLD_MOD(l, 1, 23, 16);
dispc_write_reg(DISPC_DIVISOR, l);
}
/* FUNCGATED */
if (dss_has_feature(FEAT_FUNCGATED))
REG_FLD_MOD(DISPC_CONFIG, 1, 9, 9);
_dispc_setup_color_conv_coef();
dispc_set_loadmode(OMAP_DSS_LOAD_FRAME_ONLY);
dispc_init_fifos();
OMAP: DSS2: Fix FIFO threshold and burst size for OMAP4 The DMA FIFO threshold registers and burst size registers have changed for OMAP4. The current code only handles OMAP2/3 case, and so the values are a bit off for OMAP4. A summary of the differences between OMAP2/3 and OMAP4: Burst size: OMAP2/3: 4 x 32 bits / 8 x 32 bits / 16 x 32 bits OMAP4: 2 x 128 bits / 4 x 128 bits / 8 x 128 bits Threshold size: OMAP2/3: in bytes (8 bit units) OMAP4: in 128bit units This patch fixes the issue by creating two new helper functions in dss_features: dss_feat_get_buffer_size_unit() and dss_feat_get_burst_size_unit(). These return (in bytes) the unit size for threshold registers and unit size for burst size register, respectively, and are used to calculate correct values. For the threshold size the usage is straightforward. However, the burst size register has different multipliers for OMAP2/3 and OMAP4. This patch solves the problem by defining the multipliers for the burst size as 2x, 4x and 8x, which fit fine for the OMAP4 burst size definition (i.e. burst size unit for OMAP4 is 128bits), but requires a slight twist on OMAP2/3 by defining the burst size unit as 64bit. As the driver in practice always uses the maximum burst size, and no use case currently exists where we would want to use a smaller burst size, this patch changes the driver to hardcode the burst size when initializing DISPC. This makes the threshold configuration code somewhat simpler. Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-06-21 13:35:36 +07:00
dispc_configure_burst_sizes();
dispc_ovl_enable_zorder_planes();
}
static const struct dispc_features omap24xx_dispc_feats __initconst = {
.sw_start = 5,
.fp_start = 15,
.bp_start = 27,
.sw_max = 64,
.vp_max = 255,
.hp_max = 256,
.calc_scaling = dispc_ovl_calc_scaling_24xx,
.calc_core_clk = calc_core_clk_24xx,
.num_fifos = 3,
};
static const struct dispc_features omap34xx_rev1_0_dispc_feats __initconst = {
.sw_start = 5,
.fp_start = 15,
.bp_start = 27,
.sw_max = 64,
.vp_max = 255,
.hp_max = 256,
.calc_scaling = dispc_ovl_calc_scaling_34xx,
.calc_core_clk = calc_core_clk_34xx,
.num_fifos = 3,
};
static const struct dispc_features omap34xx_rev3_0_dispc_feats __initconst = {
.sw_start = 7,
.fp_start = 19,
.bp_start = 31,
.sw_max = 256,
.vp_max = 4095,
.hp_max = 4096,
.calc_scaling = dispc_ovl_calc_scaling_34xx,
.calc_core_clk = calc_core_clk_34xx,
.num_fifos = 3,
};
static const struct dispc_features omap44xx_dispc_feats __initconst = {
.sw_start = 7,
.fp_start = 19,
.bp_start = 31,
.sw_max = 256,
.vp_max = 4095,
.hp_max = 4096,
.calc_scaling = dispc_ovl_calc_scaling_44xx,
.calc_core_clk = calc_core_clk_44xx,
.num_fifos = 5,
.gfx_fifo_workaround = true,
};
static int __init dispc_init_features(struct device *dev)
{
const struct dispc_features *src;
struct dispc_features *dst;
dst = devm_kzalloc(dev, sizeof(*dst), GFP_KERNEL);
if (!dst) {
dev_err(dev, "Failed to allocate DISPC Features\n");
return -ENOMEM;
}
if (cpu_is_omap24xx()) {
src = &omap24xx_dispc_feats;
} else if (cpu_is_omap34xx()) {
if (omap_rev() < OMAP3430_REV_ES3_0)
src = &omap34xx_rev1_0_dispc_feats;
else
src = &omap34xx_rev3_0_dispc_feats;
} else if (cpu_is_omap44xx()) {
src = &omap44xx_dispc_feats;
} else if (soc_is_omap54xx()) {
src = &omap44xx_dispc_feats;
} else {
return -ENODEV;
}
memcpy(dst, src, sizeof(*dst));
dispc.feat = dst;
return 0;
}
/* DISPC HW IP initialisation */
static int __init omap_dispchw_probe(struct platform_device *pdev)
{
u32 rev;
int r = 0;
struct resource *dispc_mem;
struct clk *clk;
dispc.pdev = pdev;
r = dispc_init_features(&dispc.pdev->dev);
if (r)
return r;
spin_lock_init(&dispc.irq_lock);
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
spin_lock_init(&dispc.irq_stats_lock);
dispc.irq_stats.last_reset = jiffies;
#endif
INIT_WORK(&dispc.error_work, dispc_error_worker);
dispc_mem = platform_get_resource(dispc.pdev, IORESOURCE_MEM, 0);
if (!dispc_mem) {
DSSERR("can't get IORESOURCE_MEM DISPC\n");
return -EINVAL;
}
dispc.base = devm_ioremap(&pdev->dev, dispc_mem->start,
resource_size(dispc_mem));
if (!dispc.base) {
DSSERR("can't ioremap DISPC\n");
return -ENOMEM;
}
dispc.irq = platform_get_irq(dispc.pdev, 0);
if (dispc.irq < 0) {
DSSERR("platform_get_irq failed\n");
return -ENODEV;
}
r = devm_request_irq(&pdev->dev, dispc.irq, omap_dispc_irq_handler,
IRQF_SHARED, "OMAP DISPC", dispc.pdev);
if (r < 0) {
DSSERR("request_irq failed\n");
return r;
}
clk = clk_get(&pdev->dev, "fck");
if (IS_ERR(clk)) {
DSSERR("can't get fck\n");
r = PTR_ERR(clk);
return r;
}
dispc.dss_clk = clk;
pm_runtime_enable(&pdev->dev);
r = dispc_runtime_get();
if (r)
goto err_runtime_get;
_omap_dispc_initial_config();
_omap_dispc_initialize_irq();
rev = dispc_read_reg(DISPC_REVISION);
dev_dbg(&pdev->dev, "OMAP DISPC rev %d.%d\n",
FLD_GET(rev, 7, 4), FLD_GET(rev, 3, 0));
dispc_runtime_put();
dss_debugfs_create_file("dispc", dispc_dump_regs);
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
dss_debugfs_create_file("dispc_irq", dispc_dump_irqs);
#endif
return 0;
err_runtime_get:
pm_runtime_disable(&pdev->dev);
clk_put(dispc.dss_clk);
return r;
}
static int __exit omap_dispchw_remove(struct platform_device *pdev)
{
pm_runtime_disable(&pdev->dev);
clk_put(dispc.dss_clk);
return 0;
}
static int dispc_runtime_suspend(struct device *dev)
{
dispc_save_context();
return 0;
}
static int dispc_runtime_resume(struct device *dev)
{
dispc_restore_context();
return 0;
}
static const struct dev_pm_ops dispc_pm_ops = {
.runtime_suspend = dispc_runtime_suspend,
.runtime_resume = dispc_runtime_resume,
};
static struct platform_driver omap_dispchw_driver = {
.remove = __exit_p(omap_dispchw_remove),
.driver = {
.name = "omapdss_dispc",
.owner = THIS_MODULE,
.pm = &dispc_pm_ops,
},
};
int __init dispc_init_platform_driver(void)
{
return platform_driver_probe(&omap_dispchw_driver, omap_dispchw_probe);
}
void __exit dispc_uninit_platform_driver(void)
{
platform_driver_unregister(&omap_dispchw_driver);
}