linux_dsm_epyc7002/drivers/gpu/drm/tidss/tidss_dispc.c
Tomi Valkeinen a8d9d7da15 drm/tidss: remove AM65x PG1 YUV erratum code
AM65x PG1 has a HW issue with YUV pixel formats, resulting in wrong
colors on the screen. This issue is fixed in PG2 hardware.

The driver currently has code to hide YUV pixel formats from the
userspace. To support PG2, we would need to add code to detect the SoC
version and hide the YUV formats based on that.

However, as PG1 will be phased out and PG2 will be the main platform, a
much simpler solution is just to drop the code in question. The downside
is that the users will be able to use YUV formats on PG1, getting wrong
colors on the screen. On the other hand, that may also be a plus, as the
same applications will now work on PG1 and PG2, even if the colors are
wrong on PG1.

Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
Link: https://patchwork.freedesktop.org/patch/msgid/20200429121022.3871-1-tomi.valkeinen@ti.com
Reviewed-by: Jyri Sarha <jsarha@ti.com>
2020-05-05 10:00:07 +03:00

2747 lines
70 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2016-2018 Texas Instruments Incorporated - http://www.ti.com/
* Author: Jyri Sarha <jsarha@ti.com>
*/
#include <linux/clk.h>
#include <linux/delay.h>
#include <linux/dma-mapping.h>
#include <linux/err.h>
#include <linux/interrupt.h>
#include <linux/io.h>
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/mfd/syscon.h>
#include <linux/of.h>
#include <linux/of_graph.h>
#include <linux/of_device.h>
#include <linux/platform_device.h>
#include <linux/pm_runtime.h>
#include <linux/regmap.h>
#include <drm/drm_fourcc.h>
#include <drm/drm_fb_cma_helper.h>
#include <drm/drm_gem_cma_helper.h>
#include <drm/drm_panel.h>
#include "tidss_crtc.h"
#include "tidss_dispc.h"
#include "tidss_drv.h"
#include "tidss_irq.h"
#include "tidss_plane.h"
#include "tidss_dispc_regs.h"
#include "tidss_scale_coefs.h"
static const u16 tidss_k2g_common_regs[DISPC_COMMON_REG_TABLE_LEN] = {
[DSS_REVISION_OFF] = 0x00,
[DSS_SYSCONFIG_OFF] = 0x04,
[DSS_SYSSTATUS_OFF] = 0x08,
[DISPC_IRQ_EOI_OFF] = 0x20,
[DISPC_IRQSTATUS_RAW_OFF] = 0x24,
[DISPC_IRQSTATUS_OFF] = 0x28,
[DISPC_IRQENABLE_SET_OFF] = 0x2c,
[DISPC_IRQENABLE_CLR_OFF] = 0x30,
[DISPC_GLOBAL_MFLAG_ATTRIBUTE_OFF] = 0x40,
[DISPC_GLOBAL_BUFFER_OFF] = 0x44,
[DISPC_DBG_CONTROL_OFF] = 0x4c,
[DISPC_DBG_STATUS_OFF] = 0x50,
[DISPC_CLKGATING_DISABLE_OFF] = 0x54,
};
const struct dispc_features dispc_k2g_feats = {
.min_pclk_khz = 4375,
.max_pclk_khz = {
[DISPC_VP_DPI] = 150000,
},
/*
* XXX According TRM the RGB input buffer width up to 2560 should
* work on 3 taps, but in practice it only works up to 1280.
*/
.scaling = {
.in_width_max_5tap_rgb = 1280,
.in_width_max_3tap_rgb = 1280,
.in_width_max_5tap_yuv = 2560,
.in_width_max_3tap_yuv = 2560,
.upscale_limit = 16,
.downscale_limit_5tap = 4,
.downscale_limit_3tap = 2,
/*
* The max supported pixel inc value is 255. The value
* of pixel inc is calculated like this: 1+(xinc-1)*bpp.
* The maximum bpp of all formats supported by the HW
* is 8. So the maximum supported xinc value is 32,
* because 1+(32-1)*8 < 255 < 1+(33-1)*4.
*/
.xinc_max = 32,
},
.subrev = DISPC_K2G,
.common = "common",
.common_regs = tidss_k2g_common_regs,
.num_vps = 1,
.vp_name = { "vp1" },
.ovr_name = { "ovr1" },
.vpclk_name = { "vp1" },
.vp_bus_type = { DISPC_VP_DPI },
.vp_feat = { .color = {
.has_ctm = true,
.gamma_size = 256,
.gamma_type = TIDSS_GAMMA_8BIT,
},
},
.num_planes = 1,
.vid_name = { "vid1" },
.vid_lite = { false },
.vid_order = { 0 },
};
static const u16 tidss_am65x_common_regs[DISPC_COMMON_REG_TABLE_LEN] = {
[DSS_REVISION_OFF] = 0x4,
[DSS_SYSCONFIG_OFF] = 0x8,
[DSS_SYSSTATUS_OFF] = 0x20,
[DISPC_IRQ_EOI_OFF] = 0x24,
[DISPC_IRQSTATUS_RAW_OFF] = 0x28,
[DISPC_IRQSTATUS_OFF] = 0x2c,
[DISPC_IRQENABLE_SET_OFF] = 0x30,
[DISPC_IRQENABLE_CLR_OFF] = 0x40,
[DISPC_VID_IRQENABLE_OFF] = 0x44,
[DISPC_VID_IRQSTATUS_OFF] = 0x58,
[DISPC_VP_IRQENABLE_OFF] = 0x70,
[DISPC_VP_IRQSTATUS_OFF] = 0x7c,
[WB_IRQENABLE_OFF] = 0x88,
[WB_IRQSTATUS_OFF] = 0x8c,
[DISPC_GLOBAL_MFLAG_ATTRIBUTE_OFF] = 0x90,
[DISPC_GLOBAL_OUTPUT_ENABLE_OFF] = 0x94,
[DISPC_GLOBAL_BUFFER_OFF] = 0x98,
[DSS_CBA_CFG_OFF] = 0x9c,
[DISPC_DBG_CONTROL_OFF] = 0xa0,
[DISPC_DBG_STATUS_OFF] = 0xa4,
[DISPC_CLKGATING_DISABLE_OFF] = 0xa8,
[DISPC_SECURE_DISABLE_OFF] = 0xac,
};
const struct dispc_features dispc_am65x_feats = {
.max_pclk_khz = {
[DISPC_VP_DPI] = 165000,
[DISPC_VP_OLDI] = 165000,
},
.scaling = {
.in_width_max_5tap_rgb = 1280,
.in_width_max_3tap_rgb = 2560,
.in_width_max_5tap_yuv = 2560,
.in_width_max_3tap_yuv = 4096,
.upscale_limit = 16,
.downscale_limit_5tap = 4,
.downscale_limit_3tap = 2,
/*
* The max supported pixel inc value is 255. The value
* of pixel inc is calculated like this: 1+(xinc-1)*bpp.
* The maximum bpp of all formats supported by the HW
* is 8. So the maximum supported xinc value is 32,
* because 1+(32-1)*8 < 255 < 1+(33-1)*4.
*/
.xinc_max = 32,
},
.subrev = DISPC_AM65X,
.common = "common",
.common_regs = tidss_am65x_common_regs,
.num_vps = 2,
.vp_name = { "vp1", "vp2" },
.ovr_name = { "ovr1", "ovr2" },
.vpclk_name = { "vp1", "vp2" },
.vp_bus_type = { DISPC_VP_OLDI, DISPC_VP_DPI },
.vp_feat = { .color = {
.has_ctm = true,
.gamma_size = 256,
.gamma_type = TIDSS_GAMMA_8BIT,
},
},
.num_planes = 2,
/* note: vid is plane_id 0 and vidl1 is plane_id 1 */
.vid_name = { "vid", "vidl1" },
.vid_lite = { false, true, },
.vid_order = { 1, 0 },
};
static const u16 tidss_j721e_common_regs[DISPC_COMMON_REG_TABLE_LEN] = {
[DSS_REVISION_OFF] = 0x4,
[DSS_SYSCONFIG_OFF] = 0x8,
[DSS_SYSSTATUS_OFF] = 0x20,
[DISPC_IRQ_EOI_OFF] = 0x80,
[DISPC_IRQSTATUS_RAW_OFF] = 0x28,
[DISPC_IRQSTATUS_OFF] = 0x2c,
[DISPC_IRQENABLE_SET_OFF] = 0x30,
[DISPC_IRQENABLE_CLR_OFF] = 0x34,
[DISPC_VID_IRQENABLE_OFF] = 0x38,
[DISPC_VID_IRQSTATUS_OFF] = 0x48,
[DISPC_VP_IRQENABLE_OFF] = 0x58,
[DISPC_VP_IRQSTATUS_OFF] = 0x68,
[WB_IRQENABLE_OFF] = 0x78,
[WB_IRQSTATUS_OFF] = 0x7c,
[DISPC_GLOBAL_MFLAG_ATTRIBUTE_OFF] = 0x98,
[DISPC_GLOBAL_OUTPUT_ENABLE_OFF] = 0x9c,
[DISPC_GLOBAL_BUFFER_OFF] = 0xa0,
[DSS_CBA_CFG_OFF] = 0xa4,
[DISPC_DBG_CONTROL_OFF] = 0xa8,
[DISPC_DBG_STATUS_OFF] = 0xac,
[DISPC_CLKGATING_DISABLE_OFF] = 0xb0,
[DISPC_SECURE_DISABLE_OFF] = 0x90,
[FBDC_REVISION_1_OFF] = 0xb8,
[FBDC_REVISION_2_OFF] = 0xbc,
[FBDC_REVISION_3_OFF] = 0xc0,
[FBDC_REVISION_4_OFF] = 0xc4,
[FBDC_REVISION_5_OFF] = 0xc8,
[FBDC_REVISION_6_OFF] = 0xcc,
[FBDC_COMMON_CONTROL_OFF] = 0xd0,
[FBDC_CONSTANT_COLOR_0_OFF] = 0xd4,
[FBDC_CONSTANT_COLOR_1_OFF] = 0xd8,
[DISPC_CONNECTIONS_OFF] = 0xe4,
[DISPC_MSS_VP1_OFF] = 0xe8,
[DISPC_MSS_VP3_OFF] = 0xec,
};
const struct dispc_features dispc_j721e_feats = {
.max_pclk_khz = {
[DISPC_VP_DPI] = 170000,
[DISPC_VP_INTERNAL] = 600000,
},
.scaling = {
.in_width_max_5tap_rgb = 2048,
.in_width_max_3tap_rgb = 4096,
.in_width_max_5tap_yuv = 4096,
.in_width_max_3tap_yuv = 4096,
.upscale_limit = 16,
.downscale_limit_5tap = 4,
.downscale_limit_3tap = 2,
/*
* The max supported pixel inc value is 255. The value
* of pixel inc is calculated like this: 1+(xinc-1)*bpp.
* The maximum bpp of all formats supported by the HW
* is 8. So the maximum supported xinc value is 32,
* because 1+(32-1)*8 < 255 < 1+(33-1)*4.
*/
.xinc_max = 32,
},
.subrev = DISPC_J721E,
.common = "common_m",
.common_regs = tidss_j721e_common_regs,
.num_vps = 4,
.vp_name = { "vp1", "vp2", "vp3", "vp4" },
.ovr_name = { "ovr1", "ovr2", "ovr3", "ovr4" },
.vpclk_name = { "vp1", "vp2", "vp3", "vp4" },
/* Currently hard coded VP routing (see dispc_initial_config()) */
.vp_bus_type = { DISPC_VP_INTERNAL, DISPC_VP_DPI,
DISPC_VP_INTERNAL, DISPC_VP_DPI, },
.vp_feat = { .color = {
.has_ctm = true,
.gamma_size = 1024,
.gamma_type = TIDSS_GAMMA_10BIT,
},
},
.num_planes = 4,
.vid_name = { "vid1", "vidl1", "vid2", "vidl2" },
.vid_lite = { 0, 1, 0, 1, },
.vid_order = { 1, 3, 0, 2 },
};
static const u16 *dispc_common_regmap;
struct dss_vp_data {
u32 *gamma_table;
};
struct dispc_device {
struct tidss_device *tidss;
struct device *dev;
void __iomem *base_common;
void __iomem *base_vid[TIDSS_MAX_PLANES];
void __iomem *base_ovr[TIDSS_MAX_PORTS];
void __iomem *base_vp[TIDSS_MAX_PORTS];
struct regmap *oldi_io_ctrl;
struct clk *vp_clk[TIDSS_MAX_PORTS];
const struct dispc_features *feat;
struct clk *fclk;
bool is_enabled;
struct dss_vp_data vp_data[TIDSS_MAX_PORTS];
u32 *fourccs;
u32 num_fourccs;
u32 memory_bandwidth_limit;
};
static void dispc_write(struct dispc_device *dispc, u16 reg, u32 val)
{
iowrite32(val, dispc->base_common + reg);
}
static u32 dispc_read(struct dispc_device *dispc, u16 reg)
{
return ioread32(dispc->base_common + reg);
}
static
void dispc_vid_write(struct dispc_device *dispc, u32 hw_plane, u16 reg, u32 val)
{
void __iomem *base = dispc->base_vid[hw_plane];
iowrite32(val, base + reg);
}
static u32 dispc_vid_read(struct dispc_device *dispc, u32 hw_plane, u16 reg)
{
void __iomem *base = dispc->base_vid[hw_plane];
return ioread32(base + reg);
}
static void dispc_ovr_write(struct dispc_device *dispc, u32 hw_videoport,
u16 reg, u32 val)
{
void __iomem *base = dispc->base_ovr[hw_videoport];
iowrite32(val, base + reg);
}
static u32 dispc_ovr_read(struct dispc_device *dispc, u32 hw_videoport, u16 reg)
{
void __iomem *base = dispc->base_ovr[hw_videoport];
return ioread32(base + reg);
}
static void dispc_vp_write(struct dispc_device *dispc, u32 hw_videoport,
u16 reg, u32 val)
{
void __iomem *base = dispc->base_vp[hw_videoport];
iowrite32(val, base + reg);
}
static u32 dispc_vp_read(struct dispc_device *dispc, u32 hw_videoport, u16 reg)
{
void __iomem *base = dispc->base_vp[hw_videoport];
return ioread32(base + reg);
}
/*
* TRM gives bitfields as start:end, where start is the higher bit
* number. For example 7:0
*/
static u32 FLD_MASK(u32 start, u32 end)
{
return ((1 << (start - end + 1)) - 1) << end;
}
static u32 FLD_VAL(u32 val, u32 start, u32 end)
{
return (val << end) & FLD_MASK(start, end);
}
static u32 FLD_GET(u32 val, u32 start, u32 end)
{
return (val & FLD_MASK(start, end)) >> end;
}
static u32 FLD_MOD(u32 orig, u32 val, u32 start, u32 end)
{
return (orig & ~FLD_MASK(start, end)) | FLD_VAL(val, start, end);
}
static u32 REG_GET(struct dispc_device *dispc, u32 idx, u32 start, u32 end)
{
return FLD_GET(dispc_read(dispc, idx), start, end);
}
static void REG_FLD_MOD(struct dispc_device *dispc, u32 idx, u32 val,
u32 start, u32 end)
{
dispc_write(dispc, idx, FLD_MOD(dispc_read(dispc, idx), val,
start, end));
}
static u32 VID_REG_GET(struct dispc_device *dispc, u32 hw_plane, u32 idx,
u32 start, u32 end)
{
return FLD_GET(dispc_vid_read(dispc, hw_plane, idx), start, end);
}
static void VID_REG_FLD_MOD(struct dispc_device *dispc, u32 hw_plane, u32 idx,
u32 val, u32 start, u32 end)
{
dispc_vid_write(dispc, hw_plane, idx,
FLD_MOD(dispc_vid_read(dispc, hw_plane, idx),
val, start, end));
}
static u32 VP_REG_GET(struct dispc_device *dispc, u32 vp, u32 idx,
u32 start, u32 end)
{
return FLD_GET(dispc_vp_read(dispc, vp, idx), start, end);
}
static void VP_REG_FLD_MOD(struct dispc_device *dispc, u32 vp, u32 idx, u32 val,
u32 start, u32 end)
{
dispc_vp_write(dispc, vp, idx, FLD_MOD(dispc_vp_read(dispc, vp, idx),
val, start, end));
}
__maybe_unused
static u32 OVR_REG_GET(struct dispc_device *dispc, u32 ovr, u32 idx,
u32 start, u32 end)
{
return FLD_GET(dispc_ovr_read(dispc, ovr, idx), start, end);
}
static void OVR_REG_FLD_MOD(struct dispc_device *dispc, u32 ovr, u32 idx,
u32 val, u32 start, u32 end)
{
dispc_ovr_write(dispc, ovr, idx,
FLD_MOD(dispc_ovr_read(dispc, ovr, idx),
val, start, end));
}
static dispc_irq_t dispc_vp_irq_from_raw(u32 stat, u32 hw_videoport)
{
dispc_irq_t vp_stat = 0;
if (stat & BIT(0))
vp_stat |= DSS_IRQ_VP_FRAME_DONE(hw_videoport);
if (stat & BIT(1))
vp_stat |= DSS_IRQ_VP_VSYNC_EVEN(hw_videoport);
if (stat & BIT(2))
vp_stat |= DSS_IRQ_VP_VSYNC_ODD(hw_videoport);
if (stat & BIT(4))
vp_stat |= DSS_IRQ_VP_SYNC_LOST(hw_videoport);
return vp_stat;
}
static u32 dispc_vp_irq_to_raw(dispc_irq_t vpstat, u32 hw_videoport)
{
u32 stat = 0;
if (vpstat & DSS_IRQ_VP_FRAME_DONE(hw_videoport))
stat |= BIT(0);
if (vpstat & DSS_IRQ_VP_VSYNC_EVEN(hw_videoport))
stat |= BIT(1);
if (vpstat & DSS_IRQ_VP_VSYNC_ODD(hw_videoport))
stat |= BIT(2);
if (vpstat & DSS_IRQ_VP_SYNC_LOST(hw_videoport))
stat |= BIT(4);
return stat;
}
static dispc_irq_t dispc_vid_irq_from_raw(u32 stat, u32 hw_plane)
{
dispc_irq_t vid_stat = 0;
if (stat & BIT(0))
vid_stat |= DSS_IRQ_PLANE_FIFO_UNDERFLOW(hw_plane);
return vid_stat;
}
static u32 dispc_vid_irq_to_raw(dispc_irq_t vidstat, u32 hw_plane)
{
u32 stat = 0;
if (vidstat & DSS_IRQ_PLANE_FIFO_UNDERFLOW(hw_plane))
stat |= BIT(0);
return stat;
}
static dispc_irq_t dispc_k2g_vp_read_irqstatus(struct dispc_device *dispc,
u32 hw_videoport)
{
u32 stat = dispc_vp_read(dispc, hw_videoport, DISPC_VP_K2G_IRQSTATUS);
return dispc_vp_irq_from_raw(stat, hw_videoport);
}
static void dispc_k2g_vp_write_irqstatus(struct dispc_device *dispc,
u32 hw_videoport, dispc_irq_t vpstat)
{
u32 stat = dispc_vp_irq_to_raw(vpstat, hw_videoport);
dispc_vp_write(dispc, hw_videoport, DISPC_VP_K2G_IRQSTATUS, stat);
}
static dispc_irq_t dispc_k2g_vid_read_irqstatus(struct dispc_device *dispc,
u32 hw_plane)
{
u32 stat = dispc_vid_read(dispc, hw_plane, DISPC_VID_K2G_IRQSTATUS);
return dispc_vid_irq_from_raw(stat, hw_plane);
}
static void dispc_k2g_vid_write_irqstatus(struct dispc_device *dispc,
u32 hw_plane, dispc_irq_t vidstat)
{
u32 stat = dispc_vid_irq_to_raw(vidstat, hw_plane);
dispc_vid_write(dispc, hw_plane, DISPC_VID_K2G_IRQSTATUS, stat);
}
static dispc_irq_t dispc_k2g_vp_read_irqenable(struct dispc_device *dispc,
u32 hw_videoport)
{
u32 stat = dispc_vp_read(dispc, hw_videoport, DISPC_VP_K2G_IRQENABLE);
return dispc_vp_irq_from_raw(stat, hw_videoport);
}
static void dispc_k2g_vp_set_irqenable(struct dispc_device *dispc,
u32 hw_videoport, dispc_irq_t vpstat)
{
u32 stat = dispc_vp_irq_to_raw(vpstat, hw_videoport);
dispc_vp_write(dispc, hw_videoport, DISPC_VP_K2G_IRQENABLE, stat);
}
static dispc_irq_t dispc_k2g_vid_read_irqenable(struct dispc_device *dispc,
u32 hw_plane)
{
u32 stat = dispc_vid_read(dispc, hw_plane, DISPC_VID_K2G_IRQENABLE);
return dispc_vid_irq_from_raw(stat, hw_plane);
}
static void dispc_k2g_vid_set_irqenable(struct dispc_device *dispc,
u32 hw_plane, dispc_irq_t vidstat)
{
u32 stat = dispc_vid_irq_to_raw(vidstat, hw_plane);
dispc_vid_write(dispc, hw_plane, DISPC_VID_K2G_IRQENABLE, stat);
}
static void dispc_k2g_clear_irqstatus(struct dispc_device *dispc,
dispc_irq_t mask)
{
dispc_k2g_vp_write_irqstatus(dispc, 0, mask);
dispc_k2g_vid_write_irqstatus(dispc, 0, mask);
}
static
dispc_irq_t dispc_k2g_read_and_clear_irqstatus(struct dispc_device *dispc)
{
dispc_irq_t stat = 0;
/* always clear the top level irqstatus */
dispc_write(dispc, DISPC_IRQSTATUS,
dispc_read(dispc, DISPC_IRQSTATUS));
stat |= dispc_k2g_vp_read_irqstatus(dispc, 0);
stat |= dispc_k2g_vid_read_irqstatus(dispc, 0);
dispc_k2g_clear_irqstatus(dispc, stat);
return stat;
}
static dispc_irq_t dispc_k2g_read_irqenable(struct dispc_device *dispc)
{
dispc_irq_t stat = 0;
stat |= dispc_k2g_vp_read_irqenable(dispc, 0);
stat |= dispc_k2g_vid_read_irqenable(dispc, 0);
return stat;
}
static
void dispc_k2g_set_irqenable(struct dispc_device *dispc, dispc_irq_t mask)
{
dispc_irq_t old_mask = dispc_k2g_read_irqenable(dispc);
/* clear the irqstatus for newly enabled irqs */
dispc_k2g_clear_irqstatus(dispc, (mask ^ old_mask) & mask);
dispc_k2g_vp_set_irqenable(dispc, 0, mask);
dispc_k2g_vid_set_irqenable(dispc, 0, mask);
dispc_write(dispc, DISPC_IRQENABLE_SET, (1 << 0) | (1 << 7));
/* flush posted write */
dispc_k2g_read_irqenable(dispc);
}
static dispc_irq_t dispc_k3_vp_read_irqstatus(struct dispc_device *dispc,
u32 hw_videoport)
{
u32 stat = dispc_read(dispc, DISPC_VP_IRQSTATUS(hw_videoport));
return dispc_vp_irq_from_raw(stat, hw_videoport);
}
static void dispc_k3_vp_write_irqstatus(struct dispc_device *dispc,
u32 hw_videoport, dispc_irq_t vpstat)
{
u32 stat = dispc_vp_irq_to_raw(vpstat, hw_videoport);
dispc_write(dispc, DISPC_VP_IRQSTATUS(hw_videoport), stat);
}
static dispc_irq_t dispc_k3_vid_read_irqstatus(struct dispc_device *dispc,
u32 hw_plane)
{
u32 stat = dispc_read(dispc, DISPC_VID_IRQSTATUS(hw_plane));
return dispc_vid_irq_from_raw(stat, hw_plane);
}
static void dispc_k3_vid_write_irqstatus(struct dispc_device *dispc,
u32 hw_plane, dispc_irq_t vidstat)
{
u32 stat = dispc_vid_irq_to_raw(vidstat, hw_plane);
dispc_write(dispc, DISPC_VID_IRQSTATUS(hw_plane), stat);
}
static dispc_irq_t dispc_k3_vp_read_irqenable(struct dispc_device *dispc,
u32 hw_videoport)
{
u32 stat = dispc_read(dispc, DISPC_VP_IRQENABLE(hw_videoport));
return dispc_vp_irq_from_raw(stat, hw_videoport);
}
static void dispc_k3_vp_set_irqenable(struct dispc_device *dispc,
u32 hw_videoport, dispc_irq_t vpstat)
{
u32 stat = dispc_vp_irq_to_raw(vpstat, hw_videoport);
dispc_write(dispc, DISPC_VP_IRQENABLE(hw_videoport), stat);
}
static dispc_irq_t dispc_k3_vid_read_irqenable(struct dispc_device *dispc,
u32 hw_plane)
{
u32 stat = dispc_read(dispc, DISPC_VID_IRQENABLE(hw_plane));
return dispc_vid_irq_from_raw(stat, hw_plane);
}
static void dispc_k3_vid_set_irqenable(struct dispc_device *dispc,
u32 hw_plane, dispc_irq_t vidstat)
{
u32 stat = dispc_vid_irq_to_raw(vidstat, hw_plane);
dispc_write(dispc, DISPC_VID_IRQENABLE(hw_plane), stat);
}
static
void dispc_k3_clear_irqstatus(struct dispc_device *dispc, dispc_irq_t clearmask)
{
unsigned int i;
u32 top_clear = 0;
for (i = 0; i < dispc->feat->num_vps; ++i) {
if (clearmask & DSS_IRQ_VP_MASK(i)) {
dispc_k3_vp_write_irqstatus(dispc, i, clearmask);
top_clear |= BIT(i);
}
}
for (i = 0; i < dispc->feat->num_planes; ++i) {
if (clearmask & DSS_IRQ_PLANE_MASK(i)) {
dispc_k3_vid_write_irqstatus(dispc, i, clearmask);
top_clear |= BIT(4 + i);
}
}
if (dispc->feat->subrev == DISPC_K2G)
return;
dispc_write(dispc, DISPC_IRQSTATUS, top_clear);
/* Flush posted writes */
dispc_read(dispc, DISPC_IRQSTATUS);
}
static
dispc_irq_t dispc_k3_read_and_clear_irqstatus(struct dispc_device *dispc)
{
dispc_irq_t status = 0;
unsigned int i;
for (i = 0; i < dispc->feat->num_vps; ++i)
status |= dispc_k3_vp_read_irqstatus(dispc, i);
for (i = 0; i < dispc->feat->num_planes; ++i)
status |= dispc_k3_vid_read_irqstatus(dispc, i);
dispc_k3_clear_irqstatus(dispc, status);
return status;
}
static dispc_irq_t dispc_k3_read_irqenable(struct dispc_device *dispc)
{
dispc_irq_t enable = 0;
unsigned int i;
for (i = 0; i < dispc->feat->num_vps; ++i)
enable |= dispc_k3_vp_read_irqenable(dispc, i);
for (i = 0; i < dispc->feat->num_planes; ++i)
enable |= dispc_k3_vid_read_irqenable(dispc, i);
return enable;
}
static void dispc_k3_set_irqenable(struct dispc_device *dispc,
dispc_irq_t mask)
{
unsigned int i;
u32 main_enable = 0, main_disable = 0;
dispc_irq_t old_mask;
old_mask = dispc_k3_read_irqenable(dispc);
/* clear the irqstatus for newly enabled irqs */
dispc_k3_clear_irqstatus(dispc, (old_mask ^ mask) & mask);
for (i = 0; i < dispc->feat->num_vps; ++i) {
dispc_k3_vp_set_irqenable(dispc, i, mask);
if (mask & DSS_IRQ_VP_MASK(i))
main_enable |= BIT(i); /* VP IRQ */
else
main_disable |= BIT(i); /* VP IRQ */
}
for (i = 0; i < dispc->feat->num_planes; ++i) {
dispc_k3_vid_set_irqenable(dispc, i, mask);
if (mask & DSS_IRQ_PLANE_MASK(i))
main_enable |= BIT(i + 4); /* VID IRQ */
else
main_disable |= BIT(i + 4); /* VID IRQ */
}
if (main_enable)
dispc_write(dispc, DISPC_IRQENABLE_SET, main_enable);
if (main_disable)
dispc_write(dispc, DISPC_IRQENABLE_CLR, main_disable);
/* Flush posted writes */
dispc_read(dispc, DISPC_IRQENABLE_SET);
}
dispc_irq_t dispc_read_and_clear_irqstatus(struct dispc_device *dispc)
{
switch (dispc->feat->subrev) {
case DISPC_K2G:
return dispc_k2g_read_and_clear_irqstatus(dispc);
case DISPC_AM65X:
case DISPC_J721E:
return dispc_k3_read_and_clear_irqstatus(dispc);
default:
WARN_ON(1);
return 0;
}
}
void dispc_set_irqenable(struct dispc_device *dispc, dispc_irq_t mask)
{
switch (dispc->feat->subrev) {
case DISPC_K2G:
dispc_k2g_set_irqenable(dispc, mask);
break;
case DISPC_AM65X:
case DISPC_J721E:
dispc_k3_set_irqenable(dispc, mask);
break;
default:
WARN_ON(1);
break;
}
}
enum dispc_oldi_mode_reg_val { SPWG_18 = 0, JEIDA_24 = 1, SPWG_24 = 2 };
struct dispc_bus_format {
u32 bus_fmt;
u32 data_width;
bool is_oldi_fmt;
enum dispc_oldi_mode_reg_val oldi_mode_reg_val;
};
static const struct dispc_bus_format dispc_bus_formats[] = {
{ MEDIA_BUS_FMT_RGB444_1X12, 12, false, 0 },
{ MEDIA_BUS_FMT_RGB565_1X16, 16, false, 0 },
{ MEDIA_BUS_FMT_RGB666_1X18, 18, false, 0 },
{ MEDIA_BUS_FMT_RGB888_1X24, 24, false, 0 },
{ MEDIA_BUS_FMT_RGB101010_1X30, 30, false, 0 },
{ MEDIA_BUS_FMT_RGB121212_1X36, 36, false, 0 },
{ MEDIA_BUS_FMT_RGB666_1X7X3_SPWG, 18, true, SPWG_18 },
{ MEDIA_BUS_FMT_RGB888_1X7X4_SPWG, 24, true, SPWG_24 },
{ MEDIA_BUS_FMT_RGB888_1X7X4_JEIDA, 24, true, JEIDA_24 },
};
static const
struct dispc_bus_format *dispc_vp_find_bus_fmt(struct dispc_device *dispc,
u32 hw_videoport,
u32 bus_fmt, u32 bus_flags)
{
unsigned int i;
for (i = 0; i < ARRAY_SIZE(dispc_bus_formats); ++i) {
if (dispc_bus_formats[i].bus_fmt == bus_fmt)
return &dispc_bus_formats[i];
}
return NULL;
}
int dispc_vp_bus_check(struct dispc_device *dispc, u32 hw_videoport,
const struct drm_crtc_state *state)
{
const struct tidss_crtc_state *tstate = to_tidss_crtc_state(state);
const struct dispc_bus_format *fmt;
fmt = dispc_vp_find_bus_fmt(dispc, hw_videoport, tstate->bus_format,
tstate->bus_flags);
if (!fmt) {
dev_dbg(dispc->dev, "%s: Unsupported bus format: %u\n",
__func__, tstate->bus_format);
return -EINVAL;
}
if (dispc->feat->vp_bus_type[hw_videoport] != DISPC_VP_OLDI &&
fmt->is_oldi_fmt) {
dev_dbg(dispc->dev, "%s: %s is not OLDI-port\n",
__func__, dispc->feat->vp_name[hw_videoport]);
return -EINVAL;
}
return 0;
}
static void dispc_oldi_tx_power(struct dispc_device *dispc, bool power)
{
u32 val = power ? 0 : OLDI_PWRDN_TX;
if (WARN_ON(!dispc->oldi_io_ctrl))
return;
regmap_update_bits(dispc->oldi_io_ctrl, OLDI_DAT0_IO_CTRL,
OLDI_PWRDN_TX, val);
regmap_update_bits(dispc->oldi_io_ctrl, OLDI_DAT1_IO_CTRL,
OLDI_PWRDN_TX, val);
regmap_update_bits(dispc->oldi_io_ctrl, OLDI_DAT2_IO_CTRL,
OLDI_PWRDN_TX, val);
regmap_update_bits(dispc->oldi_io_ctrl, OLDI_DAT3_IO_CTRL,
OLDI_PWRDN_TX, val);
regmap_update_bits(dispc->oldi_io_ctrl, OLDI_CLK_IO_CTRL,
OLDI_PWRDN_TX, val);
}
static void dispc_set_num_datalines(struct dispc_device *dispc,
u32 hw_videoport, int num_lines)
{
int v;
switch (num_lines) {
case 12:
v = 0; break;
case 16:
v = 1; break;
case 18:
v = 2; break;
case 24:
v = 3; break;
case 30:
v = 4; break;
case 36:
v = 5; break;
default:
WARN_ON(1);
v = 3;
}
VP_REG_FLD_MOD(dispc, hw_videoport, DISPC_VP_CONTROL, v, 10, 8);
}
static void dispc_enable_oldi(struct dispc_device *dispc, u32 hw_videoport,
const struct dispc_bus_format *fmt)
{
u32 oldi_cfg = 0;
u32 oldi_reset_bit = BIT(5 + hw_videoport);
int count = 0;
/*
* For the moment DUALMODESYNC, MASTERSLAVE, MODE, and SRC
* bits of DISPC_VP_DSS_OLDI_CFG are set statically to 0.
*/
if (fmt->data_width == 24)
oldi_cfg |= BIT(8); /* MSB */
else if (fmt->data_width != 18)
dev_warn(dispc->dev, "%s: %d port width not supported\n",
__func__, fmt->data_width);
oldi_cfg |= BIT(7); /* DEPOL */
oldi_cfg = FLD_MOD(oldi_cfg, fmt->oldi_mode_reg_val, 3, 1);
oldi_cfg |= BIT(12); /* SOFTRST */
oldi_cfg |= BIT(0); /* ENABLE */
dispc_vp_write(dispc, hw_videoport, DISPC_VP_DSS_OLDI_CFG, oldi_cfg);
while (!(oldi_reset_bit & dispc_read(dispc, DSS_SYSSTATUS)) &&
count < 10000)
count++;
if (!(oldi_reset_bit & dispc_read(dispc, DSS_SYSSTATUS)))
dev_warn(dispc->dev, "%s: timeout waiting OLDI reset done\n",
__func__);
}
void dispc_vp_prepare(struct dispc_device *dispc, u32 hw_videoport,
const struct drm_crtc_state *state)
{
const struct tidss_crtc_state *tstate = to_tidss_crtc_state(state);
const struct dispc_bus_format *fmt;
fmt = dispc_vp_find_bus_fmt(dispc, hw_videoport, tstate->bus_format,
tstate->bus_flags);
if (WARN_ON(!fmt))
return;
if (dispc->feat->vp_bus_type[hw_videoport] == DISPC_VP_OLDI) {
dispc_oldi_tx_power(dispc, true);
dispc_enable_oldi(dispc, hw_videoport, fmt);
}
}
void dispc_vp_enable(struct dispc_device *dispc, u32 hw_videoport,
const struct drm_crtc_state *state)
{
const struct drm_display_mode *mode = &state->adjusted_mode;
const struct tidss_crtc_state *tstate = to_tidss_crtc_state(state);
bool align, onoff, rf, ieo, ipc, ihs, ivs;
const struct dispc_bus_format *fmt;
u32 hsw, hfp, hbp, vsw, vfp, vbp;
fmt = dispc_vp_find_bus_fmt(dispc, hw_videoport, tstate->bus_format,
tstate->bus_flags);
if (WARN_ON(!fmt))
return;
dispc_set_num_datalines(dispc, hw_videoport, fmt->data_width);
hfp = mode->hsync_start - mode->hdisplay;
hsw = mode->hsync_end - mode->hsync_start;
hbp = mode->htotal - mode->hsync_end;
vfp = mode->vsync_start - mode->vdisplay;
vsw = mode->vsync_end - mode->vsync_start;
vbp = mode->vtotal - mode->vsync_end;
dispc_vp_write(dispc, hw_videoport, DISPC_VP_TIMING_H,
FLD_VAL(hsw - 1, 7, 0) |
FLD_VAL(hfp - 1, 19, 8) |
FLD_VAL(hbp - 1, 31, 20));
dispc_vp_write(dispc, hw_videoport, DISPC_VP_TIMING_V,
FLD_VAL(vsw - 1, 7, 0) |
FLD_VAL(vfp, 19, 8) |
FLD_VAL(vbp, 31, 20));
ivs = !!(mode->flags & DRM_MODE_FLAG_NVSYNC);
ihs = !!(mode->flags & DRM_MODE_FLAG_NHSYNC);
ieo = !!(tstate->bus_flags & DRM_BUS_FLAG_DE_LOW);
ipc = !!(tstate->bus_flags & DRM_BUS_FLAG_PIXDATA_NEGEDGE);
/* always use the 'rf' setting */
onoff = true;
rf = !!(tstate->bus_flags & DRM_BUS_FLAG_SYNC_POSEDGE);
/* always use aligned syncs */
align = true;
/* always use DE_HIGH for OLDI */
if (dispc->feat->vp_bus_type[hw_videoport] == DISPC_VP_OLDI)
ieo = false;
dispc_vp_write(dispc, hw_videoport, DISPC_VP_POL_FREQ,
FLD_VAL(align, 18, 18) |
FLD_VAL(onoff, 17, 17) |
FLD_VAL(rf, 16, 16) |
FLD_VAL(ieo, 15, 15) |
FLD_VAL(ipc, 14, 14) |
FLD_VAL(ihs, 13, 13) |
FLD_VAL(ivs, 12, 12));
dispc_vp_write(dispc, hw_videoport, DISPC_VP_SIZE_SCREEN,
FLD_VAL(mode->hdisplay - 1, 11, 0) |
FLD_VAL(mode->vdisplay - 1, 27, 16));
VP_REG_FLD_MOD(dispc, hw_videoport, DISPC_VP_CONTROL, 1, 0, 0);
}
void dispc_vp_disable(struct dispc_device *dispc, u32 hw_videoport)
{
VP_REG_FLD_MOD(dispc, hw_videoport, DISPC_VP_CONTROL, 0, 0, 0);
}
void dispc_vp_unprepare(struct dispc_device *dispc, u32 hw_videoport)
{
if (dispc->feat->vp_bus_type[hw_videoport] == DISPC_VP_OLDI) {
dispc_vp_write(dispc, hw_videoport, DISPC_VP_DSS_OLDI_CFG, 0);
dispc_oldi_tx_power(dispc, false);
}
}
bool dispc_vp_go_busy(struct dispc_device *dispc, u32 hw_videoport)
{
return VP_REG_GET(dispc, hw_videoport, DISPC_VP_CONTROL, 5, 5);
}
void dispc_vp_go(struct dispc_device *dispc, u32 hw_videoport)
{
WARN_ON(VP_REG_GET(dispc, hw_videoport, DISPC_VP_CONTROL, 5, 5));
VP_REG_FLD_MOD(dispc, hw_videoport, DISPC_VP_CONTROL, 1, 5, 5);
}
enum c8_to_c12_mode { C8_TO_C12_REPLICATE, C8_TO_C12_MAX, C8_TO_C12_MIN };
static u16 c8_to_c12(u8 c8, enum c8_to_c12_mode mode)
{
u16 c12;
c12 = c8 << 4;
switch (mode) {
case C8_TO_C12_REPLICATE:
/* Copy c8 4 MSB to 4 LSB for full scale c12 */
c12 |= c8 >> 4;
break;
case C8_TO_C12_MAX:
c12 |= 0xF;
break;
default:
case C8_TO_C12_MIN:
break;
}
return c12;
}
static u64 argb8888_to_argb12121212(u32 argb8888, enum c8_to_c12_mode m)
{
u8 a, r, g, b;
u64 v;
a = (argb8888 >> 24) & 0xff;
r = (argb8888 >> 16) & 0xff;
g = (argb8888 >> 8) & 0xff;
b = (argb8888 >> 0) & 0xff;
v = ((u64)c8_to_c12(a, m) << 36) | ((u64)c8_to_c12(r, m) << 24) |
((u64)c8_to_c12(g, m) << 12) | (u64)c8_to_c12(b, m);
return v;
}
static void dispc_vp_set_default_color(struct dispc_device *dispc,
u32 hw_videoport, u32 default_color)
{
u64 v;
v = argb8888_to_argb12121212(default_color, C8_TO_C12_REPLICATE);
dispc_ovr_write(dispc, hw_videoport,
DISPC_OVR_DEFAULT_COLOR, v & 0xffffffff);
dispc_ovr_write(dispc, hw_videoport,
DISPC_OVR_DEFAULT_COLOR2, (v >> 32) & 0xffff);
}
enum drm_mode_status dispc_vp_mode_valid(struct dispc_device *dispc,
u32 hw_videoport,
const struct drm_display_mode *mode)
{
u32 hsw, hfp, hbp, vsw, vfp, vbp;
enum dispc_vp_bus_type bus_type;
int max_pclk;
bus_type = dispc->feat->vp_bus_type[hw_videoport];
max_pclk = dispc->feat->max_pclk_khz[bus_type];
if (WARN_ON(max_pclk == 0))
return MODE_BAD;
if (mode->clock < dispc->feat->min_pclk_khz)
return MODE_CLOCK_LOW;
if (mode->clock > max_pclk)
return MODE_CLOCK_HIGH;
if (mode->hdisplay > 4096)
return MODE_BAD;
if (mode->vdisplay > 4096)
return MODE_BAD;
/* TODO: add interlace support */
if (mode->flags & DRM_MODE_FLAG_INTERLACE)
return MODE_NO_INTERLACE;
/*
* Enforce the output width is divisible by 2. Actually this
* is only needed in following cases:
* - YUV output selected (BT656, BT1120)
* - Dithering enabled
* - TDM with TDMCycleFormat == 3
* But for simplicity we enforce that always.
*/
if ((mode->hdisplay % 2) != 0)
return MODE_BAD_HVALUE;
hfp = mode->hsync_start - mode->hdisplay;
hsw = mode->hsync_end - mode->hsync_start;
hbp = mode->htotal - mode->hsync_end;
vfp = mode->vsync_start - mode->vdisplay;
vsw = mode->vsync_end - mode->vsync_start;
vbp = mode->vtotal - mode->vsync_end;
if (hsw < 1 || hsw > 256 ||
hfp < 1 || hfp > 4096 ||
hbp < 1 || hbp > 4096)
return MODE_BAD_HVALUE;
if (vsw < 1 || vsw > 256 ||
vfp > 4095 || vbp > 4095)
return MODE_BAD_VVALUE;
if (dispc->memory_bandwidth_limit) {
const unsigned int bpp = 4;
u64 bandwidth;
bandwidth = 1000 * mode->clock;
bandwidth = bandwidth * mode->hdisplay * mode->vdisplay * bpp;
bandwidth = div_u64(bandwidth, mode->htotal * mode->vtotal);
if (dispc->memory_bandwidth_limit < bandwidth)
return MODE_BAD;
}
return MODE_OK;
}
int dispc_vp_enable_clk(struct dispc_device *dispc, u32 hw_videoport)
{
int ret = clk_prepare_enable(dispc->vp_clk[hw_videoport]);
if (ret)
dev_err(dispc->dev, "%s: enabling clk failed: %d\n", __func__,
ret);
return ret;
}
void dispc_vp_disable_clk(struct dispc_device *dispc, u32 hw_videoport)
{
clk_disable_unprepare(dispc->vp_clk[hw_videoport]);
}
/*
* Calculate the percentage difference between the requested pixel clock rate
* and the effective rate resulting from calculating the clock divider value.
*/
static
unsigned int dispc_pclk_diff(unsigned long rate, unsigned long real_rate)
{
int r = rate / 100, rr = real_rate / 100;
return (unsigned int)(abs(((rr - r) * 100) / r));
}
int dispc_vp_set_clk_rate(struct dispc_device *dispc, u32 hw_videoport,
unsigned long rate)
{
int r;
unsigned long new_rate;
r = clk_set_rate(dispc->vp_clk[hw_videoport], rate);
if (r) {
dev_err(dispc->dev, "vp%d: failed to set clk rate to %lu\n",
hw_videoport, rate);
return r;
}
new_rate = clk_get_rate(dispc->vp_clk[hw_videoport]);
if (dispc_pclk_diff(rate, new_rate) > 5)
dev_warn(dispc->dev,
"vp%d: Clock rate %lu differs over 5%% from requested %lu\n",
hw_videoport, new_rate, rate);
dev_dbg(dispc->dev, "vp%d: new rate %lu Hz (requested %lu Hz)\n",
hw_videoport, clk_get_rate(dispc->vp_clk[hw_videoport]), rate);
return 0;
}
/* OVR */
static void dispc_k2g_ovr_set_plane(struct dispc_device *dispc,
u32 hw_plane, u32 hw_videoport,
u32 x, u32 y, u32 layer)
{
/* On k2g there is only one plane and no need for ovr */
dispc_vid_write(dispc, hw_plane, DISPC_VID_K2G_POSITION,
x | (y << 16));
}
static void dispc_am65x_ovr_set_plane(struct dispc_device *dispc,
u32 hw_plane, u32 hw_videoport,
u32 x, u32 y, u32 layer)
{
OVR_REG_FLD_MOD(dispc, hw_videoport, DISPC_OVR_ATTRIBUTES(layer),
hw_plane, 4, 1);
OVR_REG_FLD_MOD(dispc, hw_videoport, DISPC_OVR_ATTRIBUTES(layer),
x, 17, 6);
OVR_REG_FLD_MOD(dispc, hw_videoport, DISPC_OVR_ATTRIBUTES(layer),
y, 30, 19);
}
static void dispc_j721e_ovr_set_plane(struct dispc_device *dispc,
u32 hw_plane, u32 hw_videoport,
u32 x, u32 y, u32 layer)
{
OVR_REG_FLD_MOD(dispc, hw_videoport, DISPC_OVR_ATTRIBUTES(layer),
hw_plane, 4, 1);
OVR_REG_FLD_MOD(dispc, hw_videoport, DISPC_OVR_ATTRIBUTES2(layer),
x, 13, 0);
OVR_REG_FLD_MOD(dispc, hw_videoport, DISPC_OVR_ATTRIBUTES2(layer),
y, 29, 16);
}
void dispc_ovr_set_plane(struct dispc_device *dispc, u32 hw_plane,
u32 hw_videoport, u32 x, u32 y, u32 layer)
{
switch (dispc->feat->subrev) {
case DISPC_K2G:
dispc_k2g_ovr_set_plane(dispc, hw_plane, hw_videoport,
x, y, layer);
break;
case DISPC_AM65X:
dispc_am65x_ovr_set_plane(dispc, hw_plane, hw_videoport,
x, y, layer);
break;
case DISPC_J721E:
dispc_j721e_ovr_set_plane(dispc, hw_plane, hw_videoport,
x, y, layer);
break;
default:
WARN_ON(1);
break;
}
}
void dispc_ovr_enable_layer(struct dispc_device *dispc,
u32 hw_videoport, u32 layer, bool enable)
{
if (dispc->feat->subrev == DISPC_K2G)
return;
OVR_REG_FLD_MOD(dispc, hw_videoport, DISPC_OVR_ATTRIBUTES(layer),
!!enable, 0, 0);
}
/* CSC */
enum csc_ctm {
CSC_RR, CSC_RG, CSC_RB,
CSC_GR, CSC_GG, CSC_GB,
CSC_BR, CSC_BG, CSC_BB,
};
enum csc_yuv2rgb {
CSC_RY, CSC_RCB, CSC_RCR,
CSC_GY, CSC_GCB, CSC_GCR,
CSC_BY, CSC_BCB, CSC_BCR,
};
enum csc_rgb2yuv {
CSC_YR, CSC_YG, CSC_YB,
CSC_CBR, CSC_CBG, CSC_CBB,
CSC_CRR, CSC_CRG, CSC_CRB,
};
struct dispc_csc_coef {
void (*to_regval)(const struct dispc_csc_coef *csc, u32 *regval);
int m[9];
int preoffset[3];
int postoffset[3];
enum { CLIP_LIMITED_RANGE = 0, CLIP_FULL_RANGE = 1, } cliping;
const char *name;
};
#define DISPC_CSC_REGVAL_LEN 8
static
void dispc_csc_offset_regval(const struct dispc_csc_coef *csc, u32 *regval)
{
#define OVAL(x, y) (FLD_VAL(x, 15, 3) | FLD_VAL(y, 31, 19))
regval[5] = OVAL(csc->preoffset[0], csc->preoffset[1]);
regval[6] = OVAL(csc->preoffset[2], csc->postoffset[0]);
regval[7] = OVAL(csc->postoffset[1], csc->postoffset[2]);
#undef OVAL
}
#define CVAL(x, y) (FLD_VAL(x, 10, 0) | FLD_VAL(y, 26, 16))
static
void dispc_csc_yuv2rgb_regval(const struct dispc_csc_coef *csc, u32 *regval)
{
regval[0] = CVAL(csc->m[CSC_RY], csc->m[CSC_RCR]);
regval[1] = CVAL(csc->m[CSC_RCB], csc->m[CSC_GY]);
regval[2] = CVAL(csc->m[CSC_GCR], csc->m[CSC_GCB]);
regval[3] = CVAL(csc->m[CSC_BY], csc->m[CSC_BCR]);
regval[4] = CVAL(csc->m[CSC_BCB], 0);
dispc_csc_offset_regval(csc, regval);
}
__maybe_unused static
void dispc_csc_rgb2yuv_regval(const struct dispc_csc_coef *csc, u32 *regval)
{
regval[0] = CVAL(csc->m[CSC_YR], csc->m[CSC_YG]);
regval[1] = CVAL(csc->m[CSC_YB], csc->m[CSC_CRR]);
regval[2] = CVAL(csc->m[CSC_CRG], csc->m[CSC_CRB]);
regval[3] = CVAL(csc->m[CSC_CBR], csc->m[CSC_CBG]);
regval[4] = CVAL(csc->m[CSC_CBB], 0);
dispc_csc_offset_regval(csc, regval);
}
static void dispc_csc_cpr_regval(const struct dispc_csc_coef *csc,
u32 *regval)
{
regval[0] = CVAL(csc->m[CSC_RR], csc->m[CSC_RG]);
regval[1] = CVAL(csc->m[CSC_RB], csc->m[CSC_GR]);
regval[2] = CVAL(csc->m[CSC_GG], csc->m[CSC_GB]);
regval[3] = CVAL(csc->m[CSC_BR], csc->m[CSC_BG]);
regval[4] = CVAL(csc->m[CSC_BB], 0);
dispc_csc_offset_regval(csc, regval);
}
#undef CVAL
static void dispc_k2g_vid_write_csc(struct dispc_device *dispc, u32 hw_plane,
const struct dispc_csc_coef *csc)
{
static const u16 dispc_vid_csc_coef_reg[] = {
DISPC_VID_CSC_COEF(0), DISPC_VID_CSC_COEF(1),
DISPC_VID_CSC_COEF(2), DISPC_VID_CSC_COEF(3),
DISPC_VID_CSC_COEF(4), DISPC_VID_CSC_COEF(5),
DISPC_VID_CSC_COEF(6), /* K2G has no post offset support */
};
u32 regval[DISPC_CSC_REGVAL_LEN];
unsigned int i;
csc->to_regval(csc, regval);
if (regval[7] != 0)
dev_warn(dispc->dev, "%s: No post offset support for %s\n",
__func__, csc->name);
for (i = 0; i < ARRAY_SIZE(dispc_vid_csc_coef_reg); i++)
dispc_vid_write(dispc, hw_plane, dispc_vid_csc_coef_reg[i],
regval[i]);
}
static void dispc_k3_vid_write_csc(struct dispc_device *dispc, u32 hw_plane,
const struct dispc_csc_coef *csc)
{
static const u16 dispc_vid_csc_coef_reg[DISPC_CSC_REGVAL_LEN] = {
DISPC_VID_CSC_COEF(0), DISPC_VID_CSC_COEF(1),
DISPC_VID_CSC_COEF(2), DISPC_VID_CSC_COEF(3),
DISPC_VID_CSC_COEF(4), DISPC_VID_CSC_COEF(5),
DISPC_VID_CSC_COEF(6), DISPC_VID_CSC_COEF7,
};
u32 regval[DISPC_CSC_REGVAL_LEN];
unsigned int i;
csc->to_regval(csc, regval);
for (i = 0; i < ARRAY_SIZE(dispc_vid_csc_coef_reg); i++)
dispc_vid_write(dispc, hw_plane, dispc_vid_csc_coef_reg[i],
regval[i]);
}
/* YUV -> RGB, ITU-R BT.601, full range */
static const struct dispc_csc_coef csc_yuv2rgb_bt601_full = {
dispc_csc_yuv2rgb_regval,
{ 256, 0, 358, /* ry, rcb, rcr |1.000 0.000 1.402|*/
256, -88, -182, /* gy, gcb, gcr |1.000 -0.344 -0.714|*/
256, 452, 0, }, /* by, bcb, bcr |1.000 1.772 0.000|*/
{ 0, -2048, -2048, }, /* full range */
{ 0, 0, 0, },
CLIP_FULL_RANGE,
"BT.601 Full",
};
/* YUV -> RGB, ITU-R BT.601, limited range */
static const struct dispc_csc_coef csc_yuv2rgb_bt601_lim = {
dispc_csc_yuv2rgb_regval,
{ 298, 0, 409, /* ry, rcb, rcr |1.164 0.000 1.596|*/
298, -100, -208, /* gy, gcb, gcr |1.164 -0.392 -0.813|*/
298, 516, 0, }, /* by, bcb, bcr |1.164 2.017 0.000|*/
{ -256, -2048, -2048, }, /* limited range */
{ 0, 0, 0, },
CLIP_FULL_RANGE,
"BT.601 Limited",
};
/* YUV -> RGB, ITU-R BT.709, full range */
static const struct dispc_csc_coef csc_yuv2rgb_bt709_full = {
dispc_csc_yuv2rgb_regval,
{ 256, 0, 402, /* ry, rcb, rcr |1.000 0.000 1.570|*/
256, -48, -120, /* gy, gcb, gcr |1.000 -0.187 -0.467|*/
256, 475, 0, }, /* by, bcb, bcr |1.000 1.856 0.000|*/
{ 0, -2048, -2048, }, /* full range */
{ 0, 0, 0, },
CLIP_FULL_RANGE,
"BT.709 Full",
};
/* YUV -> RGB, ITU-R BT.709, limited range */
static const struct dispc_csc_coef csc_yuv2rgb_bt709_lim = {
dispc_csc_yuv2rgb_regval,
{ 298, 0, 459, /* ry, rcb, rcr |1.164 0.000 1.793|*/
298, -55, -136, /* gy, gcb, gcr |1.164 -0.213 -0.533|*/
298, 541, 0, }, /* by, bcb, bcr |1.164 2.112 0.000|*/
{ -256, -2048, -2048, }, /* limited range */
{ 0, 0, 0, },
CLIP_FULL_RANGE,
"BT.709 Limited",
};
static const struct {
enum drm_color_encoding encoding;
enum drm_color_range range;
const struct dispc_csc_coef *csc;
} dispc_csc_table[] = {
{ DRM_COLOR_YCBCR_BT601, DRM_COLOR_YCBCR_FULL_RANGE,
&csc_yuv2rgb_bt601_full, },
{ DRM_COLOR_YCBCR_BT601, DRM_COLOR_YCBCR_LIMITED_RANGE,
&csc_yuv2rgb_bt601_lim, },
{ DRM_COLOR_YCBCR_BT709, DRM_COLOR_YCBCR_FULL_RANGE,
&csc_yuv2rgb_bt709_full, },
{ DRM_COLOR_YCBCR_BT709, DRM_COLOR_YCBCR_LIMITED_RANGE,
&csc_yuv2rgb_bt709_lim, },
};
static const
struct dispc_csc_coef *dispc_find_csc(enum drm_color_encoding encoding,
enum drm_color_range range)
{
unsigned int i;
for (i = 0; i < ARRAY_SIZE(dispc_csc_table); i++) {
if (dispc_csc_table[i].encoding == encoding &&
dispc_csc_table[i].range == range) {
return dispc_csc_table[i].csc;
}
}
return NULL;
}
static void dispc_vid_csc_setup(struct dispc_device *dispc, u32 hw_plane,
const struct drm_plane_state *state)
{
const struct dispc_csc_coef *coef;
coef = dispc_find_csc(state->color_encoding, state->color_range);
if (!coef) {
dev_err(dispc->dev, "%s: CSC (%u,%u) not found\n",
__func__, state->color_encoding, state->color_range);
return;
}
if (dispc->feat->subrev == DISPC_K2G)
dispc_k2g_vid_write_csc(dispc, hw_plane, coef);
else
dispc_k3_vid_write_csc(dispc, hw_plane, coef);
}
static void dispc_vid_csc_enable(struct dispc_device *dispc, u32 hw_plane,
bool enable)
{
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES, !!enable, 9, 9);
}
/* SCALER */
static u32 dispc_calc_fir_inc(u32 in, u32 out)
{
return (u32)div_u64(0x200000ull * in, out);
}
enum dispc_vid_fir_coef_set {
DISPC_VID_FIR_COEF_HORIZ,
DISPC_VID_FIR_COEF_HORIZ_UV,
DISPC_VID_FIR_COEF_VERT,
DISPC_VID_FIR_COEF_VERT_UV,
};
static void dispc_vid_write_fir_coefs(struct dispc_device *dispc,
u32 hw_plane,
enum dispc_vid_fir_coef_set coef_set,
const struct tidss_scale_coefs *coefs)
{
static const u16 c0_regs[] = {
[DISPC_VID_FIR_COEF_HORIZ] = DISPC_VID_FIR_COEFS_H0,
[DISPC_VID_FIR_COEF_HORIZ_UV] = DISPC_VID_FIR_COEFS_H0_C,
[DISPC_VID_FIR_COEF_VERT] = DISPC_VID_FIR_COEFS_V0,
[DISPC_VID_FIR_COEF_VERT_UV] = DISPC_VID_FIR_COEFS_V0_C,
};
static const u16 c12_regs[] = {
[DISPC_VID_FIR_COEF_HORIZ] = DISPC_VID_FIR_COEFS_H12,
[DISPC_VID_FIR_COEF_HORIZ_UV] = DISPC_VID_FIR_COEFS_H12_C,
[DISPC_VID_FIR_COEF_VERT] = DISPC_VID_FIR_COEFS_V12,
[DISPC_VID_FIR_COEF_VERT_UV] = DISPC_VID_FIR_COEFS_V12_C,
};
const u16 c0_base = c0_regs[coef_set];
const u16 c12_base = c12_regs[coef_set];
int phase;
if (!coefs) {
dev_err(dispc->dev, "%s: No coefficients given.\n", __func__);
return;
}
for (phase = 0; phase <= 8; ++phase) {
u16 reg = c0_base + phase * 4;
u16 c0 = coefs->c0[phase];
dispc_vid_write(dispc, hw_plane, reg, c0);
}
for (phase = 0; phase <= 15; ++phase) {
u16 reg = c12_base + phase * 4;
s16 c1, c2;
u32 c12;
c1 = coefs->c1[phase];
c2 = coefs->c2[phase];
c12 = FLD_VAL(c1, 19, 10) | FLD_VAL(c2, 29, 20);
dispc_vid_write(dispc, hw_plane, reg, c12);
}
}
static bool dispc_fourcc_is_yuv(u32 fourcc)
{
switch (fourcc) {
case DRM_FORMAT_YUYV:
case DRM_FORMAT_UYVY:
case DRM_FORMAT_NV12:
return true;
default:
return false;
}
}
struct dispc_scaling_params {
int xinc, yinc;
u32 in_w, in_h, in_w_uv, in_h_uv;
u32 fir_xinc, fir_yinc, fir_xinc_uv, fir_yinc_uv;
bool scale_x, scale_y;
const struct tidss_scale_coefs *xcoef, *ycoef, *xcoef_uv, *ycoef_uv;
bool five_taps;
};
static int dispc_vid_calc_scaling(struct dispc_device *dispc,
const struct drm_plane_state *state,
struct dispc_scaling_params *sp,
bool lite_plane)
{
const struct dispc_features_scaling *f = &dispc->feat->scaling;
u32 fourcc = state->fb->format->format;
u32 in_width_max_5tap = f->in_width_max_5tap_rgb;
u32 in_width_max_3tap = f->in_width_max_3tap_rgb;
u32 downscale_limit;
u32 in_width_max;
memset(sp, 0, sizeof(*sp));
sp->xinc = 1;
sp->yinc = 1;
sp->in_w = state->src_w >> 16;
sp->in_w_uv = sp->in_w;
sp->in_h = state->src_h >> 16;
sp->in_h_uv = sp->in_h;
sp->scale_x = sp->in_w != state->crtc_w;
sp->scale_y = sp->in_h != state->crtc_h;
if (dispc_fourcc_is_yuv(fourcc)) {
in_width_max_5tap = f->in_width_max_5tap_yuv;
in_width_max_3tap = f->in_width_max_3tap_yuv;
sp->in_w_uv >>= 1;
sp->scale_x = true;
if (fourcc == DRM_FORMAT_NV12) {
sp->in_h_uv >>= 1;
sp->scale_y = true;
}
}
/* Skip the rest if no scaling is used */
if ((!sp->scale_x && !sp->scale_y) || lite_plane)
return 0;
if (sp->in_w > in_width_max_5tap) {
sp->five_taps = false;
in_width_max = in_width_max_3tap;
downscale_limit = f->downscale_limit_3tap;
} else {
sp->five_taps = true;
in_width_max = in_width_max_5tap;
downscale_limit = f->downscale_limit_5tap;
}
if (sp->scale_x) {
sp->fir_xinc = dispc_calc_fir_inc(sp->in_w, state->crtc_w);
if (sp->fir_xinc < dispc_calc_fir_inc(1, f->upscale_limit)) {
dev_dbg(dispc->dev,
"%s: X-scaling factor %u/%u > %u\n",
__func__, state->crtc_w, state->src_w >> 16,
f->upscale_limit);
return -EINVAL;
}
if (sp->fir_xinc >= dispc_calc_fir_inc(downscale_limit, 1)) {
sp->xinc = DIV_ROUND_UP(DIV_ROUND_UP(sp->in_w,
state->crtc_w),
downscale_limit);
if (sp->xinc > f->xinc_max) {
dev_dbg(dispc->dev,
"%s: X-scaling factor %u/%u < 1/%u\n",
__func__, state->crtc_w,
state->src_w >> 16,
downscale_limit * f->xinc_max);
return -EINVAL;
}
sp->in_w = (state->src_w >> 16) / sp->xinc;
}
while (sp->in_w > in_width_max) {
sp->xinc++;
sp->in_w = (state->src_w >> 16) / sp->xinc;
}
if (sp->xinc > f->xinc_max) {
dev_dbg(dispc->dev,
"%s: Too wide input buffer %u > %u\n", __func__,
state->src_w >> 16, in_width_max * f->xinc_max);
return -EINVAL;
}
/*
* We need even line length for YUV formats. Decimation
* can lead to odd length, so we need to make it even
* again.
*/
if (dispc_fourcc_is_yuv(fourcc))
sp->in_w &= ~1;
sp->fir_xinc = dispc_calc_fir_inc(sp->in_w, state->crtc_w);
}
if (sp->scale_y) {
sp->fir_yinc = dispc_calc_fir_inc(sp->in_h, state->crtc_h);
if (sp->fir_yinc < dispc_calc_fir_inc(1, f->upscale_limit)) {
dev_dbg(dispc->dev,
"%s: Y-scaling factor %u/%u > %u\n",
__func__, state->crtc_h, state->src_h >> 16,
f->upscale_limit);
return -EINVAL;
}
if (sp->fir_yinc >= dispc_calc_fir_inc(downscale_limit, 1)) {
sp->yinc = DIV_ROUND_UP(DIV_ROUND_UP(sp->in_h,
state->crtc_h),
downscale_limit);
sp->in_h /= sp->yinc;
sp->fir_yinc = dispc_calc_fir_inc(sp->in_h,
state->crtc_h);
}
}
dev_dbg(dispc->dev,
"%s: %ux%u decim %ux%u -> %ux%u firinc %u.%03ux%u.%03u taps %u -> %ux%u\n",
__func__, state->src_w >> 16, state->src_h >> 16,
sp->xinc, sp->yinc, sp->in_w, sp->in_h,
sp->fir_xinc / 0x200000u,
((sp->fir_xinc & 0x1FFFFFu) * 999u) / 0x1FFFFFu,
sp->fir_yinc / 0x200000u,
((sp->fir_yinc & 0x1FFFFFu) * 999u) / 0x1FFFFFu,
sp->five_taps ? 5 : 3,
state->crtc_w, state->crtc_h);
if (dispc_fourcc_is_yuv(fourcc)) {
if (sp->scale_x) {
sp->in_w_uv /= sp->xinc;
sp->fir_xinc_uv = dispc_calc_fir_inc(sp->in_w_uv,
state->crtc_w);
sp->xcoef_uv = tidss_get_scale_coefs(dispc->dev,
sp->fir_xinc_uv,
true);
}
if (sp->scale_y) {
sp->in_h_uv /= sp->yinc;
sp->fir_yinc_uv = dispc_calc_fir_inc(sp->in_h_uv,
state->crtc_h);
sp->ycoef_uv = tidss_get_scale_coefs(dispc->dev,
sp->fir_yinc_uv,
sp->five_taps);
}
}
if (sp->scale_x)
sp->xcoef = tidss_get_scale_coefs(dispc->dev, sp->fir_xinc,
true);
if (sp->scale_y)
sp->ycoef = tidss_get_scale_coefs(dispc->dev, sp->fir_yinc,
sp->five_taps);
return 0;
}
static void dispc_vid_set_scaling(struct dispc_device *dispc,
u32 hw_plane,
struct dispc_scaling_params *sp,
u32 fourcc)
{
/* HORIZONTAL RESIZE ENABLE */
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES,
sp->scale_x, 7, 7);
/* VERTICAL RESIZE ENABLE */
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES,
sp->scale_y, 8, 8);
/* Skip the rest if no scaling is used */
if (!sp->scale_x && !sp->scale_y)
return;
/* VERTICAL 5-TAPS */
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES,
sp->five_taps, 21, 21);
if (dispc_fourcc_is_yuv(fourcc)) {
if (sp->scale_x) {
dispc_vid_write(dispc, hw_plane, DISPC_VID_FIRH2,
sp->fir_xinc_uv);
dispc_vid_write_fir_coefs(dispc, hw_plane,
DISPC_VID_FIR_COEF_HORIZ_UV,
sp->xcoef_uv);
}
if (sp->scale_y) {
dispc_vid_write(dispc, hw_plane, DISPC_VID_FIRV2,
sp->fir_yinc_uv);
dispc_vid_write_fir_coefs(dispc, hw_plane,
DISPC_VID_FIR_COEF_VERT_UV,
sp->ycoef_uv);
}
}
if (sp->scale_x) {
dispc_vid_write(dispc, hw_plane, DISPC_VID_FIRH, sp->fir_xinc);
dispc_vid_write_fir_coefs(dispc, hw_plane,
DISPC_VID_FIR_COEF_HORIZ,
sp->xcoef);
}
if (sp->scale_y) {
dispc_vid_write(dispc, hw_plane, DISPC_VID_FIRV, sp->fir_yinc);
dispc_vid_write_fir_coefs(dispc, hw_plane,
DISPC_VID_FIR_COEF_VERT, sp->ycoef);
}
}
/* OTHER */
static const struct {
u32 fourcc;
u8 dss_code;
} dispc_color_formats[] = {
{ DRM_FORMAT_ARGB4444, 0x0, },
{ DRM_FORMAT_ABGR4444, 0x1, },
{ DRM_FORMAT_RGBA4444, 0x2, },
{ DRM_FORMAT_RGB565, 0x3, },
{ DRM_FORMAT_BGR565, 0x4, },
{ DRM_FORMAT_ARGB1555, 0x5, },
{ DRM_FORMAT_ABGR1555, 0x6, },
{ DRM_FORMAT_ARGB8888, 0x7, },
{ DRM_FORMAT_ABGR8888, 0x8, },
{ DRM_FORMAT_RGBA8888, 0x9, },
{ DRM_FORMAT_BGRA8888, 0xa, },
{ DRM_FORMAT_RGB888, 0xb, },
{ DRM_FORMAT_BGR888, 0xc, },
{ DRM_FORMAT_ARGB2101010, 0xe, },
{ DRM_FORMAT_ABGR2101010, 0xf, },
{ DRM_FORMAT_XRGB4444, 0x20, },
{ DRM_FORMAT_XBGR4444, 0x21, },
{ DRM_FORMAT_RGBX4444, 0x22, },
{ DRM_FORMAT_ARGB1555, 0x25, },
{ DRM_FORMAT_ABGR1555, 0x26, },
{ DRM_FORMAT_XRGB8888, 0x27, },
{ DRM_FORMAT_XBGR8888, 0x28, },
{ DRM_FORMAT_RGBX8888, 0x29, },
{ DRM_FORMAT_BGRX8888, 0x2a, },
{ DRM_FORMAT_XRGB2101010, 0x2e, },
{ DRM_FORMAT_XBGR2101010, 0x2f, },
{ DRM_FORMAT_YUYV, 0x3e, },
{ DRM_FORMAT_UYVY, 0x3f, },
{ DRM_FORMAT_NV12, 0x3d, },
};
static void dispc_plane_set_pixel_format(struct dispc_device *dispc,
u32 hw_plane, u32 fourcc)
{
unsigned int i;
for (i = 0; i < ARRAY_SIZE(dispc_color_formats); ++i) {
if (dispc_color_formats[i].fourcc == fourcc) {
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES,
dispc_color_formats[i].dss_code,
6, 1);
return;
}
}
WARN_ON(1);
}
const u32 *dispc_plane_formats(struct dispc_device *dispc, unsigned int *len)
{
WARN_ON(!dispc->fourccs);
*len = dispc->num_fourccs;
return dispc->fourccs;
}
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;
WARN_ON(1);
return 0;
}
int dispc_plane_check(struct dispc_device *dispc, u32 hw_plane,
const struct drm_plane_state *state,
u32 hw_videoport)
{
bool lite = dispc->feat->vid_lite[hw_plane];
u32 fourcc = state->fb->format->format;
bool need_scaling = state->src_w >> 16 != state->crtc_w ||
state->src_h >> 16 != state->crtc_h;
struct dispc_scaling_params scaling;
int ret;
if (dispc_fourcc_is_yuv(fourcc)) {
if (!dispc_find_csc(state->color_encoding,
state->color_range)) {
dev_dbg(dispc->dev,
"%s: Unsupported CSC (%u,%u) for HW plane %u\n",
__func__, state->color_encoding,
state->color_range, hw_plane);
return -EINVAL;
}
}
if (need_scaling) {
if (lite) {
dev_dbg(dispc->dev,
"%s: Lite plane %u can't scale %ux%u!=%ux%u\n",
__func__, hw_plane,
state->src_w >> 16, state->src_h >> 16,
state->crtc_w, state->crtc_h);
return -EINVAL;
}
ret = dispc_vid_calc_scaling(dispc, state, &scaling, false);
if (ret)
return ret;
}
return 0;
}
static
dma_addr_t dispc_plane_state_paddr(const struct drm_plane_state *state)
{
struct drm_framebuffer *fb = state->fb;
struct drm_gem_cma_object *gem;
u32 x = state->src_x >> 16;
u32 y = state->src_y >> 16;
gem = drm_fb_cma_get_gem_obj(state->fb, 0);
return gem->paddr + fb->offsets[0] + x * fb->format->cpp[0] +
y * fb->pitches[0];
}
static
dma_addr_t dispc_plane_state_p_uv_addr(const struct drm_plane_state *state)
{
struct drm_framebuffer *fb = state->fb;
struct drm_gem_cma_object *gem;
u32 x = state->src_x >> 16;
u32 y = state->src_y >> 16;
if (WARN_ON(state->fb->format->num_planes != 2))
return 0;
gem = drm_fb_cma_get_gem_obj(fb, 1);
return gem->paddr + fb->offsets[1] +
(x * fb->format->cpp[1] / fb->format->hsub) +
(y * fb->pitches[1] / fb->format->vsub);
}
int dispc_plane_setup(struct dispc_device *dispc, u32 hw_plane,
const struct drm_plane_state *state,
u32 hw_videoport)
{
bool lite = dispc->feat->vid_lite[hw_plane];
u32 fourcc = state->fb->format->format;
u16 cpp = state->fb->format->cpp[0];
u32 fb_width = state->fb->pitches[0] / cpp;
dma_addr_t paddr = dispc_plane_state_paddr(state);
struct dispc_scaling_params scale;
dispc_vid_calc_scaling(dispc, state, &scale, lite);
dispc_plane_set_pixel_format(dispc, hw_plane, fourcc);
dispc_vid_write(dispc, hw_plane, DISPC_VID_BA_0, paddr & 0xffffffff);
dispc_vid_write(dispc, hw_plane, DISPC_VID_BA_EXT_0, (u64)paddr >> 32);
dispc_vid_write(dispc, hw_plane, DISPC_VID_BA_1, paddr & 0xffffffff);
dispc_vid_write(dispc, hw_plane, DISPC_VID_BA_EXT_1, (u64)paddr >> 32);
dispc_vid_write(dispc, hw_plane, DISPC_VID_PICTURE_SIZE,
(scale.in_w - 1) | ((scale.in_h - 1) << 16));
/* For YUV422 format we use the macropixel size for pixel inc */
if (fourcc == DRM_FORMAT_YUYV || fourcc == DRM_FORMAT_UYVY)
dispc_vid_write(dispc, hw_plane, DISPC_VID_PIXEL_INC,
pixinc(scale.xinc, cpp * 2));
else
dispc_vid_write(dispc, hw_plane, DISPC_VID_PIXEL_INC,
pixinc(scale.xinc, cpp));
dispc_vid_write(dispc, hw_plane, DISPC_VID_ROW_INC,
pixinc(1 + (scale.yinc * fb_width -
scale.xinc * scale.in_w),
cpp));
if (state->fb->format->num_planes == 2) {
u16 cpp_uv = state->fb->format->cpp[1];
u32 fb_width_uv = state->fb->pitches[1] / cpp_uv;
dma_addr_t p_uv_addr = dispc_plane_state_p_uv_addr(state);
dispc_vid_write(dispc, hw_plane,
DISPC_VID_BA_UV_0, p_uv_addr & 0xffffffff);
dispc_vid_write(dispc, hw_plane,
DISPC_VID_BA_UV_EXT_0, (u64)p_uv_addr >> 32);
dispc_vid_write(dispc, hw_plane,
DISPC_VID_BA_UV_1, p_uv_addr & 0xffffffff);
dispc_vid_write(dispc, hw_plane,
DISPC_VID_BA_UV_EXT_1, (u64)p_uv_addr >> 32);
dispc_vid_write(dispc, hw_plane, DISPC_VID_ROW_INC_UV,
pixinc(1 + (scale.yinc * fb_width_uv -
scale.xinc * scale.in_w_uv),
cpp_uv));
}
if (!lite) {
dispc_vid_write(dispc, hw_plane, DISPC_VID_SIZE,
(state->crtc_w - 1) |
((state->crtc_h - 1) << 16));
dispc_vid_set_scaling(dispc, hw_plane, &scale, fourcc);
}
/* enable YUV->RGB color conversion */
if (dispc_fourcc_is_yuv(fourcc)) {
dispc_vid_csc_setup(dispc, hw_plane, state);
dispc_vid_csc_enable(dispc, hw_plane, true);
} else {
dispc_vid_csc_enable(dispc, hw_plane, false);
}
dispc_vid_write(dispc, hw_plane, DISPC_VID_GLOBAL_ALPHA,
0xFF & (state->alpha >> 8));
if (state->pixel_blend_mode == DRM_MODE_BLEND_PREMULTI)
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES, 1,
28, 28);
else
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES, 0,
28, 28);
return 0;
}
int dispc_plane_enable(struct dispc_device *dispc, u32 hw_plane, bool enable)
{
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES, !!enable, 0, 0);
return 0;
}
static u32 dispc_vid_get_fifo_size(struct dispc_device *dispc, u32 hw_plane)
{
return VID_REG_GET(dispc, hw_plane, DISPC_VID_BUF_SIZE_STATUS, 15, 0);
}
static void dispc_vid_set_mflag_threshold(struct dispc_device *dispc,
u32 hw_plane, u32 low, u32 high)
{
dispc_vid_write(dispc, hw_plane, DISPC_VID_MFLAG_THRESHOLD,
FLD_VAL(high, 31, 16) | FLD_VAL(low, 15, 0));
}
static void dispc_vid_set_buf_threshold(struct dispc_device *dispc,
u32 hw_plane, u32 low, u32 high)
{
dispc_vid_write(dispc, hw_plane, DISPC_VID_BUF_THRESHOLD,
FLD_VAL(high, 31, 16) | FLD_VAL(low, 15, 0));
}
static void dispc_k2g_plane_init(struct dispc_device *dispc)
{
unsigned int hw_plane;
dev_dbg(dispc->dev, "%s()\n", __func__);
/* MFLAG_CTRL = ENABLED */
REG_FLD_MOD(dispc, DISPC_GLOBAL_MFLAG_ATTRIBUTE, 2, 1, 0);
/* MFLAG_START = MFLAGNORMALSTARTMODE */
REG_FLD_MOD(dispc, DISPC_GLOBAL_MFLAG_ATTRIBUTE, 0, 6, 6);
for (hw_plane = 0; hw_plane < dispc->feat->num_planes; hw_plane++) {
u32 size = dispc_vid_get_fifo_size(dispc, hw_plane);
u32 thr_low, thr_high;
u32 mflag_low, mflag_high;
u32 preload;
thr_high = size - 1;
thr_low = size / 2;
mflag_high = size * 2 / 3;
mflag_low = size / 3;
preload = thr_low;
dev_dbg(dispc->dev,
"%s: bufsize %u, buf_threshold %u/%u, mflag threshold %u/%u preload %u\n",
dispc->feat->vid_name[hw_plane],
size,
thr_high, thr_low,
mflag_high, mflag_low,
preload);
dispc_vid_set_buf_threshold(dispc, hw_plane,
thr_low, thr_high);
dispc_vid_set_mflag_threshold(dispc, hw_plane,
mflag_low, mflag_high);
dispc_vid_write(dispc, hw_plane, DISPC_VID_PRELOAD, preload);
/*
* Prefetch up to fifo high-threshold value to minimize the
* possibility of underflows. Note that this means the PRELOAD
* register is ignored.
*/
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES, 1,
19, 19);
}
}
static void dispc_k3_plane_init(struct dispc_device *dispc)
{
unsigned int hw_plane;
u32 cba_lo_pri = 1;
u32 cba_hi_pri = 0;
dev_dbg(dispc->dev, "%s()\n", __func__);
REG_FLD_MOD(dispc, DSS_CBA_CFG, cba_lo_pri, 2, 0);
REG_FLD_MOD(dispc, DSS_CBA_CFG, cba_hi_pri, 5, 3);
/* MFLAG_CTRL = ENABLED */
REG_FLD_MOD(dispc, DISPC_GLOBAL_MFLAG_ATTRIBUTE, 2, 1, 0);
/* MFLAG_START = MFLAGNORMALSTARTMODE */
REG_FLD_MOD(dispc, DISPC_GLOBAL_MFLAG_ATTRIBUTE, 0, 6, 6);
for (hw_plane = 0; hw_plane < dispc->feat->num_planes; hw_plane++) {
u32 size = dispc_vid_get_fifo_size(dispc, hw_plane);
u32 thr_low, thr_high;
u32 mflag_low, mflag_high;
u32 preload;
thr_high = size - 1;
thr_low = size / 2;
mflag_high = size * 2 / 3;
mflag_low = size / 3;
preload = thr_low;
dev_dbg(dispc->dev,
"%s: bufsize %u, buf_threshold %u/%u, mflag threshold %u/%u preload %u\n",
dispc->feat->vid_name[hw_plane],
size,
thr_high, thr_low,
mflag_high, mflag_low,
preload);
dispc_vid_set_buf_threshold(dispc, hw_plane,
thr_low, thr_high);
dispc_vid_set_mflag_threshold(dispc, hw_plane,
mflag_low, mflag_high);
dispc_vid_write(dispc, hw_plane, DISPC_VID_PRELOAD, preload);
/* Prefech up to PRELOAD value */
VID_REG_FLD_MOD(dispc, hw_plane, DISPC_VID_ATTRIBUTES, 0,
19, 19);
}
}
static void dispc_plane_init(struct dispc_device *dispc)
{
switch (dispc->feat->subrev) {
case DISPC_K2G:
dispc_k2g_plane_init(dispc);
break;
case DISPC_AM65X:
case DISPC_J721E:
dispc_k3_plane_init(dispc);
break;
default:
WARN_ON(1);
}
}
static void dispc_vp_init(struct dispc_device *dispc)
{
unsigned int i;
dev_dbg(dispc->dev, "%s()\n", __func__);
/* Enable the gamma Shadow bit-field for all VPs*/
for (i = 0; i < dispc->feat->num_vps; i++)
VP_REG_FLD_MOD(dispc, i, DISPC_VP_CONFIG, 1, 2, 2);
}
static void dispc_initial_config(struct dispc_device *dispc)
{
dispc_plane_init(dispc);
dispc_vp_init(dispc);
/* Note: Hardcoded DPI routing on J721E for now */
if (dispc->feat->subrev == DISPC_J721E) {
dispc_write(dispc, DISPC_CONNECTIONS,
FLD_VAL(2, 3, 0) | /* VP1 to DPI0 */
FLD_VAL(8, 7, 4) /* VP3 to DPI1 */
);
}
}
static void dispc_k2g_vp_write_gamma_table(struct dispc_device *dispc,
u32 hw_videoport)
{
u32 *table = dispc->vp_data[hw_videoport].gamma_table;
u32 hwlen = dispc->feat->vp_feat.color.gamma_size;
unsigned int i;
dev_dbg(dispc->dev, "%s: hw_videoport %d\n", __func__, hw_videoport);
if (WARN_ON(dispc->feat->vp_feat.color.gamma_type != TIDSS_GAMMA_8BIT))
return;
for (i = 0; i < hwlen; ++i) {
u32 v = table[i];
v |= i << 24;
dispc_vp_write(dispc, hw_videoport, DISPC_VP_K2G_GAMMA_TABLE,
v);
}
}
static void dispc_am65x_vp_write_gamma_table(struct dispc_device *dispc,
u32 hw_videoport)
{
u32 *table = dispc->vp_data[hw_videoport].gamma_table;
u32 hwlen = dispc->feat->vp_feat.color.gamma_size;
unsigned int i;
dev_dbg(dispc->dev, "%s: hw_videoport %d\n", __func__, hw_videoport);
if (WARN_ON(dispc->feat->vp_feat.color.gamma_type != TIDSS_GAMMA_8BIT))
return;
for (i = 0; i < hwlen; ++i) {
u32 v = table[i];
v |= i << 24;
dispc_vp_write(dispc, hw_videoport, DISPC_VP_GAMMA_TABLE, v);
}
}
static void dispc_j721e_vp_write_gamma_table(struct dispc_device *dispc,
u32 hw_videoport)
{
u32 *table = dispc->vp_data[hw_videoport].gamma_table;
u32 hwlen = dispc->feat->vp_feat.color.gamma_size;
unsigned int i;
dev_dbg(dispc->dev, "%s: hw_videoport %d\n", __func__, hw_videoport);
if (WARN_ON(dispc->feat->vp_feat.color.gamma_type != TIDSS_GAMMA_10BIT))
return;
for (i = 0; i < hwlen; ++i) {
u32 v = table[i];
if (i == 0)
v |= 1 << 31;
dispc_vp_write(dispc, hw_videoport, DISPC_VP_GAMMA_TABLE, v);
}
}
static void dispc_vp_write_gamma_table(struct dispc_device *dispc,
u32 hw_videoport)
{
switch (dispc->feat->subrev) {
case DISPC_K2G:
dispc_k2g_vp_write_gamma_table(dispc, hw_videoport);
break;
case DISPC_AM65X:
dispc_am65x_vp_write_gamma_table(dispc, hw_videoport);
break;
case DISPC_J721E:
dispc_j721e_vp_write_gamma_table(dispc, hw_videoport);
break;
default:
WARN_ON(1);
break;
}
}
static const struct drm_color_lut dispc_vp_gamma_default_lut[] = {
{ .red = 0, .green = 0, .blue = 0, },
{ .red = U16_MAX, .green = U16_MAX, .blue = U16_MAX, },
};
static void dispc_vp_set_gamma(struct dispc_device *dispc,
u32 hw_videoport,
const struct drm_color_lut *lut,
unsigned int length)
{
u32 *table = dispc->vp_data[hw_videoport].gamma_table;
u32 hwlen = dispc->feat->vp_feat.color.gamma_size;
u32 hwbits;
unsigned int i;
dev_dbg(dispc->dev, "%s: hw_videoport %d, lut len %u, hw len %u\n",
__func__, hw_videoport, length, hwlen);
if (dispc->feat->vp_feat.color.gamma_type == TIDSS_GAMMA_10BIT)
hwbits = 10;
else
hwbits = 8;
if (!lut || length < 2) {
lut = dispc_vp_gamma_default_lut;
length = ARRAY_SIZE(dispc_vp_gamma_default_lut);
}
for (i = 0; i < length - 1; ++i) {
unsigned int first = i * (hwlen - 1) / (length - 1);
unsigned int last = (i + 1) * (hwlen - 1) / (length - 1);
unsigned int w = last - first;
u16 r, g, b;
unsigned int j;
if (w == 0)
continue;
for (j = 0; j <= w; j++) {
r = (lut[i].red * (w - j) + lut[i + 1].red * j) / w;
g = (lut[i].green * (w - j) + lut[i + 1].green * j) / w;
b = (lut[i].blue * (w - j) + lut[i + 1].blue * j) / w;
r >>= 16 - hwbits;
g >>= 16 - hwbits;
b >>= 16 - hwbits;
table[first + j] = (r << (hwbits * 2)) |
(g << hwbits) | b;
}
}
dispc_vp_write_gamma_table(dispc, hw_videoport);
}
static s16 dispc_S31_32_to_s2_8(s64 coef)
{
u64 sign_bit = 1ULL << 63;
u64 cbits = (u64)coef;
s16 ret;
if (cbits & sign_bit)
ret = -clamp_val(((cbits & ~sign_bit) >> 24), 0, 0x200);
else
ret = clamp_val(((cbits & ~sign_bit) >> 24), 0, 0x1FF);
return ret;
}
static void dispc_k2g_cpr_from_ctm(const struct drm_color_ctm *ctm,
struct dispc_csc_coef *cpr)
{
memset(cpr, 0, sizeof(*cpr));
cpr->to_regval = dispc_csc_cpr_regval;
cpr->m[CSC_RR] = dispc_S31_32_to_s2_8(ctm->matrix[0]);
cpr->m[CSC_RG] = dispc_S31_32_to_s2_8(ctm->matrix[1]);
cpr->m[CSC_RB] = dispc_S31_32_to_s2_8(ctm->matrix[2]);
cpr->m[CSC_GR] = dispc_S31_32_to_s2_8(ctm->matrix[3]);
cpr->m[CSC_GG] = dispc_S31_32_to_s2_8(ctm->matrix[4]);
cpr->m[CSC_GB] = dispc_S31_32_to_s2_8(ctm->matrix[5]);
cpr->m[CSC_BR] = dispc_S31_32_to_s2_8(ctm->matrix[6]);
cpr->m[CSC_BG] = dispc_S31_32_to_s2_8(ctm->matrix[7]);
cpr->m[CSC_BB] = dispc_S31_32_to_s2_8(ctm->matrix[8]);
}
#define CVAL(xR, xG, xB) (FLD_VAL(xR, 9, 0) | FLD_VAL(xG, 20, 11) | \
FLD_VAL(xB, 31, 22))
static void dispc_k2g_vp_csc_cpr_regval(const struct dispc_csc_coef *csc,
u32 *regval)
{
regval[0] = CVAL(csc->m[CSC_BB], csc->m[CSC_BG], csc->m[CSC_BR]);
regval[1] = CVAL(csc->m[CSC_GB], csc->m[CSC_GG], csc->m[CSC_GR]);
regval[2] = CVAL(csc->m[CSC_RB], csc->m[CSC_RG], csc->m[CSC_RR]);
}
#undef CVAL
static void dispc_k2g_vp_write_csc(struct dispc_device *dispc, u32 hw_videoport,
const struct dispc_csc_coef *csc)
{
static const u16 dispc_vp_cpr_coef_reg[] = {
DISPC_VP_CSC_COEF0, DISPC_VP_CSC_COEF1, DISPC_VP_CSC_COEF2,
/* K2G CPR is packed to three registers. */
};
u32 regval[DISPC_CSC_REGVAL_LEN];
unsigned int i;
dispc_k2g_vp_csc_cpr_regval(csc, regval);
for (i = 0; i < ARRAY_SIZE(dispc_vp_cpr_coef_reg); i++)
dispc_vp_write(dispc, hw_videoport, dispc_vp_cpr_coef_reg[i],
regval[i]);
}
static void dispc_k2g_vp_set_ctm(struct dispc_device *dispc, u32 hw_videoport,
struct drm_color_ctm *ctm)
{
u32 cprenable = 0;
if (ctm) {
struct dispc_csc_coef cpr;
dispc_k2g_cpr_from_ctm(ctm, &cpr);
dispc_k2g_vp_write_csc(dispc, hw_videoport, &cpr);
cprenable = 1;
}
VP_REG_FLD_MOD(dispc, hw_videoport, DISPC_VP_CONFIG,
cprenable, 15, 15);
}
static s16 dispc_S31_32_to_s3_8(s64 coef)
{
u64 sign_bit = 1ULL << 63;
u64 cbits = (u64)coef;
s16 ret;
if (cbits & sign_bit)
ret = -clamp_val(((cbits & ~sign_bit) >> 24), 0, 0x400);
else
ret = clamp_val(((cbits & ~sign_bit) >> 24), 0, 0x3FF);
return ret;
}
static void dispc_csc_from_ctm(const struct drm_color_ctm *ctm,
struct dispc_csc_coef *cpr)
{
memset(cpr, 0, sizeof(*cpr));
cpr->to_regval = dispc_csc_cpr_regval;
cpr->m[CSC_RR] = dispc_S31_32_to_s3_8(ctm->matrix[0]);
cpr->m[CSC_RG] = dispc_S31_32_to_s3_8(ctm->matrix[1]);
cpr->m[CSC_RB] = dispc_S31_32_to_s3_8(ctm->matrix[2]);
cpr->m[CSC_GR] = dispc_S31_32_to_s3_8(ctm->matrix[3]);
cpr->m[CSC_GG] = dispc_S31_32_to_s3_8(ctm->matrix[4]);
cpr->m[CSC_GB] = dispc_S31_32_to_s3_8(ctm->matrix[5]);
cpr->m[CSC_BR] = dispc_S31_32_to_s3_8(ctm->matrix[6]);
cpr->m[CSC_BG] = dispc_S31_32_to_s3_8(ctm->matrix[7]);
cpr->m[CSC_BB] = dispc_S31_32_to_s3_8(ctm->matrix[8]);
}
static void dispc_k3_vp_write_csc(struct dispc_device *dispc, u32 hw_videoport,
const struct dispc_csc_coef *csc)
{
static const u16 dispc_vp_csc_coef_reg[DISPC_CSC_REGVAL_LEN] = {
DISPC_VP_CSC_COEF0, DISPC_VP_CSC_COEF1, DISPC_VP_CSC_COEF2,
DISPC_VP_CSC_COEF3, DISPC_VP_CSC_COEF4, DISPC_VP_CSC_COEF5,
DISPC_VP_CSC_COEF6, DISPC_VP_CSC_COEF7,
};
u32 regval[DISPC_CSC_REGVAL_LEN];
unsigned int i;
csc->to_regval(csc, regval);
for (i = 0; i < ARRAY_SIZE(regval); i++)
dispc_vp_write(dispc, hw_videoport, dispc_vp_csc_coef_reg[i],
regval[i]);
}
static void dispc_k3_vp_set_ctm(struct dispc_device *dispc, u32 hw_videoport,
struct drm_color_ctm *ctm)
{
u32 colorconvenable = 0;
if (ctm) {
struct dispc_csc_coef csc;
dispc_csc_from_ctm(ctm, &csc);
dispc_k3_vp_write_csc(dispc, hw_videoport, &csc);
colorconvenable = 1;
}
VP_REG_FLD_MOD(dispc, hw_videoport, DISPC_VP_CONFIG,
colorconvenable, 24, 24);
}
static void dispc_vp_set_color_mgmt(struct dispc_device *dispc,
u32 hw_videoport,
const struct drm_crtc_state *state,
bool newmodeset)
{
struct drm_color_lut *lut = NULL;
struct drm_color_ctm *ctm = NULL;
unsigned int length = 0;
if (!(state->color_mgmt_changed || newmodeset))
return;
if (state->gamma_lut) {
lut = (struct drm_color_lut *)state->gamma_lut->data;
length = state->gamma_lut->length / sizeof(*lut);
}
dispc_vp_set_gamma(dispc, hw_videoport, lut, length);
if (state->ctm)
ctm = (struct drm_color_ctm *)state->ctm->data;
if (dispc->feat->subrev == DISPC_K2G)
dispc_k2g_vp_set_ctm(dispc, hw_videoport, ctm);
else
dispc_k3_vp_set_ctm(dispc, hw_videoport, ctm);
}
void dispc_vp_setup(struct dispc_device *dispc, u32 hw_videoport,
const struct drm_crtc_state *state, bool newmodeset)
{
dispc_vp_set_default_color(dispc, hw_videoport, 0);
dispc_vp_set_color_mgmt(dispc, hw_videoport, state, newmodeset);
}
int dispc_runtime_suspend(struct dispc_device *dispc)
{
dev_dbg(dispc->dev, "suspend\n");
dispc->is_enabled = false;
clk_disable_unprepare(dispc->fclk);
return 0;
}
int dispc_runtime_resume(struct dispc_device *dispc)
{
dev_dbg(dispc->dev, "resume\n");
clk_prepare_enable(dispc->fclk);
if (REG_GET(dispc, DSS_SYSSTATUS, 0, 0) == 0)
dev_warn(dispc->dev, "DSS FUNC RESET not done!\n");
dev_dbg(dispc->dev, "OMAP DSS7 rev 0x%x\n",
dispc_read(dispc, DSS_REVISION));
dev_dbg(dispc->dev, "VP RESETDONE %d,%d,%d\n",
REG_GET(dispc, DSS_SYSSTATUS, 1, 1),
REG_GET(dispc, DSS_SYSSTATUS, 2, 2),
REG_GET(dispc, DSS_SYSSTATUS, 3, 3));
if (dispc->feat->subrev == DISPC_AM65X)
dev_dbg(dispc->dev, "OLDI RESETDONE %d,%d,%d\n",
REG_GET(dispc, DSS_SYSSTATUS, 5, 5),
REG_GET(dispc, DSS_SYSSTATUS, 6, 6),
REG_GET(dispc, DSS_SYSSTATUS, 7, 7));
dev_dbg(dispc->dev, "DISPC IDLE %d\n",
REG_GET(dispc, DSS_SYSSTATUS, 9, 9));
dispc_initial_config(dispc);
dispc->is_enabled = true;
tidss_irq_resume(dispc->tidss);
return 0;
}
void dispc_remove(struct tidss_device *tidss)
{
dev_dbg(tidss->dev, "%s\n", __func__);
tidss->dispc = NULL;
}
static int dispc_iomap_resource(struct platform_device *pdev, const char *name,
void __iomem **base)
{
struct resource *res;
void __iomem *b;
res = platform_get_resource_byname(pdev, IORESOURCE_MEM, name);
if (!res) {
dev_err(&pdev->dev, "cannot get mem resource '%s'\n", name);
return -EINVAL;
}
b = devm_ioremap_resource(&pdev->dev, res);
if (IS_ERR(b)) {
dev_err(&pdev->dev, "cannot ioremap resource '%s'\n", name);
return PTR_ERR(b);
}
*base = b;
return 0;
}
static int dispc_init_am65x_oldi_io_ctrl(struct device *dev,
struct dispc_device *dispc)
{
dispc->oldi_io_ctrl =
syscon_regmap_lookup_by_phandle(dev->of_node,
"ti,am65x-oldi-io-ctrl");
if (PTR_ERR(dispc->oldi_io_ctrl) == -ENODEV) {
dispc->oldi_io_ctrl = NULL;
} else if (IS_ERR(dispc->oldi_io_ctrl)) {
dev_err(dev, "%s: syscon_regmap_lookup_by_phandle failed %ld\n",
__func__, PTR_ERR(dispc->oldi_io_ctrl));
return PTR_ERR(dispc->oldi_io_ctrl);
}
return 0;
}
int dispc_init(struct tidss_device *tidss)
{
struct device *dev = tidss->dev;
struct platform_device *pdev = to_platform_device(dev);
struct dispc_device *dispc;
const struct dispc_features *feat;
unsigned int i, num_fourccs;
int r = 0;
dev_dbg(dev, "%s\n", __func__);
feat = tidss->feat;
if (feat->subrev != DISPC_K2G) {
r = dma_set_mask_and_coherent(dev, DMA_BIT_MASK(48));
if (r)
dev_warn(dev, "cannot set DMA masks to 48-bit\n");
}
dispc = devm_kzalloc(dev, sizeof(*dispc), GFP_KERNEL);
if (!dispc)
return -ENOMEM;
dispc->fourccs = devm_kcalloc(dev, ARRAY_SIZE(dispc_color_formats),
sizeof(*dispc->fourccs), GFP_KERNEL);
if (!dispc->fourccs)
return -ENOMEM;
num_fourccs = 0;
for (i = 0; i < ARRAY_SIZE(dispc_color_formats); ++i)
dispc->fourccs[num_fourccs++] = dispc_color_formats[i].fourcc;
dispc->num_fourccs = num_fourccs;
dispc->tidss = tidss;
dispc->dev = dev;
dispc->feat = feat;
dispc_common_regmap = dispc->feat->common_regs;
r = dispc_iomap_resource(pdev, dispc->feat->common,
&dispc->base_common);
if (r)
return r;
for (i = 0; i < dispc->feat->num_planes; i++) {
r = dispc_iomap_resource(pdev, dispc->feat->vid_name[i],
&dispc->base_vid[i]);
if (r)
return r;
}
for (i = 0; i < dispc->feat->num_vps; i++) {
u32 gamma_size = dispc->feat->vp_feat.color.gamma_size;
u32 *gamma_table;
struct clk *clk;
r = dispc_iomap_resource(pdev, dispc->feat->ovr_name[i],
&dispc->base_ovr[i]);
if (r)
return r;
r = dispc_iomap_resource(pdev, dispc->feat->vp_name[i],
&dispc->base_vp[i]);
if (r)
return r;
clk = devm_clk_get(dev, dispc->feat->vpclk_name[i]);
if (IS_ERR(clk)) {
dev_err(dev, "%s: Failed to get clk %s:%ld\n", __func__,
dispc->feat->vpclk_name[i], PTR_ERR(clk));
return PTR_ERR(clk);
}
dispc->vp_clk[i] = clk;
gamma_table = devm_kmalloc_array(dev, gamma_size,
sizeof(*gamma_table),
GFP_KERNEL);
if (!gamma_table)
return -ENOMEM;
dispc->vp_data[i].gamma_table = gamma_table;
}
if (feat->subrev == DISPC_AM65X) {
r = dispc_init_am65x_oldi_io_ctrl(dev, dispc);
if (r)
return r;
}
dispc->fclk = devm_clk_get(dev, "fck");
if (IS_ERR(dispc->fclk)) {
dev_err(dev, "%s: Failed to get fclk: %ld\n",
__func__, PTR_ERR(dispc->fclk));
return PTR_ERR(dispc->fclk);
}
dev_dbg(dev, "DSS fclk %lu Hz\n", clk_get_rate(dispc->fclk));
of_property_read_u32(dispc->dev->of_node, "max-memory-bandwidth",
&dispc->memory_bandwidth_limit);
tidss->dispc = dispc;
return 0;
}