linux_dsm_epyc7002/drivers/gpu/drm/omapdrm/dss/dsi.c

5494 lines
132 KiB
C
Raw Normal View History

/*
* Copyright (C) 2009 Nokia Corporation
* Author: Tomi Valkeinen <tomi.valkeinen@ti.com>
*
* 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 "DSI"
#include <linux/kernel.h>
#include <linux/mfd/syscon.h>
#include <linux/regmap.h>
#include <linux/io.h>
#include <linux/clk.h>
#include <linux/device.h>
#include <linux/err.h>
#include <linux/interrupt.h>
#include <linux/delay.h>
#include <linux/mutex.h>
#include <linux/module.h>
#include <linux/semaphore.h>
#include <linux/seq_file.h>
#include <linux/platform_device.h>
#include <linux/regulator/consumer.h>
#include <linux/wait.h>
#include <linux/workqueue.h>
#include <linux/sched.h>
#include <linux/slab.h>
#include <linux/debugfs.h>
#include <linux/pm_runtime.h>
#include <linux/of.h>
#include <linux/of_graph.h>
#include <linux/of_platform.h>
#include <linux/component.h>
#include <linux/sys_soc.h>
#include <video/mipi_display.h>
#include "omapdss.h"
#include "dss.h"
#define DSI_CATCH_MISSING_TE
struct dsi_reg { u16 module; u16 idx; };
#define DSI_REG(mod, idx) ((const struct dsi_reg) { mod, idx })
/* DSI Protocol Engine */
#define DSI_PROTO 0
#define DSI_PROTO_SZ 0x200
#define DSI_REVISION DSI_REG(DSI_PROTO, 0x0000)
#define DSI_SYSCONFIG DSI_REG(DSI_PROTO, 0x0010)
#define DSI_SYSSTATUS DSI_REG(DSI_PROTO, 0x0014)
#define DSI_IRQSTATUS DSI_REG(DSI_PROTO, 0x0018)
#define DSI_IRQENABLE DSI_REG(DSI_PROTO, 0x001C)
#define DSI_CTRL DSI_REG(DSI_PROTO, 0x0040)
#define DSI_GNQ DSI_REG(DSI_PROTO, 0x0044)
#define DSI_COMPLEXIO_CFG1 DSI_REG(DSI_PROTO, 0x0048)
#define DSI_COMPLEXIO_IRQ_STATUS DSI_REG(DSI_PROTO, 0x004C)
#define DSI_COMPLEXIO_IRQ_ENABLE DSI_REG(DSI_PROTO, 0x0050)
#define DSI_CLK_CTRL DSI_REG(DSI_PROTO, 0x0054)
#define DSI_TIMING1 DSI_REG(DSI_PROTO, 0x0058)
#define DSI_TIMING2 DSI_REG(DSI_PROTO, 0x005C)
#define DSI_VM_TIMING1 DSI_REG(DSI_PROTO, 0x0060)
#define DSI_VM_TIMING2 DSI_REG(DSI_PROTO, 0x0064)
#define DSI_VM_TIMING3 DSI_REG(DSI_PROTO, 0x0068)
#define DSI_CLK_TIMING DSI_REG(DSI_PROTO, 0x006C)
#define DSI_TX_FIFO_VC_SIZE DSI_REG(DSI_PROTO, 0x0070)
#define DSI_RX_FIFO_VC_SIZE DSI_REG(DSI_PROTO, 0x0074)
#define DSI_COMPLEXIO_CFG2 DSI_REG(DSI_PROTO, 0x0078)
#define DSI_RX_FIFO_VC_FULLNESS DSI_REG(DSI_PROTO, 0x007C)
#define DSI_VM_TIMING4 DSI_REG(DSI_PROTO, 0x0080)
#define DSI_TX_FIFO_VC_EMPTINESS DSI_REG(DSI_PROTO, 0x0084)
#define DSI_VM_TIMING5 DSI_REG(DSI_PROTO, 0x0088)
#define DSI_VM_TIMING6 DSI_REG(DSI_PROTO, 0x008C)
#define DSI_VM_TIMING7 DSI_REG(DSI_PROTO, 0x0090)
#define DSI_STOPCLK_TIMING DSI_REG(DSI_PROTO, 0x0094)
#define DSI_VC_CTRL(n) DSI_REG(DSI_PROTO, 0x0100 + (n * 0x20))
#define DSI_VC_TE(n) DSI_REG(DSI_PROTO, 0x0104 + (n * 0x20))
#define DSI_VC_LONG_PACKET_HEADER(n) DSI_REG(DSI_PROTO, 0x0108 + (n * 0x20))
#define DSI_VC_LONG_PACKET_PAYLOAD(n) DSI_REG(DSI_PROTO, 0x010C + (n * 0x20))
#define DSI_VC_SHORT_PACKET_HEADER(n) DSI_REG(DSI_PROTO, 0x0110 + (n * 0x20))
#define DSI_VC_IRQSTATUS(n) DSI_REG(DSI_PROTO, 0x0118 + (n * 0x20))
#define DSI_VC_IRQENABLE(n) DSI_REG(DSI_PROTO, 0x011C + (n * 0x20))
/* DSIPHY_SCP */
#define DSI_PHY 1
#define DSI_PHY_OFFSET 0x200
#define DSI_PHY_SZ 0x40
#define DSI_DSIPHY_CFG0 DSI_REG(DSI_PHY, 0x0000)
#define DSI_DSIPHY_CFG1 DSI_REG(DSI_PHY, 0x0004)
#define DSI_DSIPHY_CFG2 DSI_REG(DSI_PHY, 0x0008)
#define DSI_DSIPHY_CFG5 DSI_REG(DSI_PHY, 0x0014)
#define DSI_DSIPHY_CFG10 DSI_REG(DSI_PHY, 0x0028)
/* DSI_PLL_CTRL_SCP */
#define DSI_PLL 2
#define DSI_PLL_OFFSET 0x300
#define DSI_PLL_SZ 0x20
#define DSI_PLL_CONTROL DSI_REG(DSI_PLL, 0x0000)
#define DSI_PLL_STATUS DSI_REG(DSI_PLL, 0x0004)
#define DSI_PLL_GO DSI_REG(DSI_PLL, 0x0008)
#define DSI_PLL_CONFIGURATION1 DSI_REG(DSI_PLL, 0x000C)
#define DSI_PLL_CONFIGURATION2 DSI_REG(DSI_PLL, 0x0010)
#define REG_GET(dsi, idx, start, end) \
FLD_GET(dsi_read_reg(dsi, idx), start, end)
#define REG_FLD_MOD(dsi, idx, val, start, end) \
dsi_write_reg(dsi, idx, FLD_MOD(dsi_read_reg(dsi, idx), val, start, end))
/* Global interrupts */
#define DSI_IRQ_VC0 (1 << 0)
#define DSI_IRQ_VC1 (1 << 1)
#define DSI_IRQ_VC2 (1 << 2)
#define DSI_IRQ_VC3 (1 << 3)
#define DSI_IRQ_WAKEUP (1 << 4)
#define DSI_IRQ_RESYNC (1 << 5)
#define DSI_IRQ_PLL_LOCK (1 << 7)
#define DSI_IRQ_PLL_UNLOCK (1 << 8)
#define DSI_IRQ_PLL_RECALL (1 << 9)
#define DSI_IRQ_COMPLEXIO_ERR (1 << 10)
#define DSI_IRQ_HS_TX_TIMEOUT (1 << 14)
#define DSI_IRQ_LP_RX_TIMEOUT (1 << 15)
#define DSI_IRQ_TE_TRIGGER (1 << 16)
#define DSI_IRQ_ACK_TRIGGER (1 << 17)
#define DSI_IRQ_SYNC_LOST (1 << 18)
#define DSI_IRQ_LDO_POWER_GOOD (1 << 19)
#define DSI_IRQ_TA_TIMEOUT (1 << 20)
#define DSI_IRQ_ERROR_MASK \
(DSI_IRQ_HS_TX_TIMEOUT | DSI_IRQ_LP_RX_TIMEOUT | DSI_IRQ_SYNC_LOST | \
DSI_IRQ_TA_TIMEOUT)
#define DSI_IRQ_CHANNEL_MASK 0xf
/* Virtual channel interrupts */
#define DSI_VC_IRQ_CS (1 << 0)
#define DSI_VC_IRQ_ECC_CORR (1 << 1)
#define DSI_VC_IRQ_PACKET_SENT (1 << 2)
#define DSI_VC_IRQ_FIFO_TX_OVF (1 << 3)
#define DSI_VC_IRQ_FIFO_RX_OVF (1 << 4)
#define DSI_VC_IRQ_BTA (1 << 5)
#define DSI_VC_IRQ_ECC_NO_CORR (1 << 6)
#define DSI_VC_IRQ_FIFO_TX_UDF (1 << 7)
#define DSI_VC_IRQ_PP_BUSY_CHANGE (1 << 8)
#define DSI_VC_IRQ_ERROR_MASK \
(DSI_VC_IRQ_CS | DSI_VC_IRQ_ECC_CORR | DSI_VC_IRQ_FIFO_TX_OVF | \
DSI_VC_IRQ_FIFO_RX_OVF | DSI_VC_IRQ_ECC_NO_CORR | \
DSI_VC_IRQ_FIFO_TX_UDF)
/* ComplexIO interrupts */
#define DSI_CIO_IRQ_ERRSYNCESC1 (1 << 0)
#define DSI_CIO_IRQ_ERRSYNCESC2 (1 << 1)
#define DSI_CIO_IRQ_ERRSYNCESC3 (1 << 2)
#define DSI_CIO_IRQ_ERRSYNCESC4 (1 << 3)
#define DSI_CIO_IRQ_ERRSYNCESC5 (1 << 4)
#define DSI_CIO_IRQ_ERRESC1 (1 << 5)
#define DSI_CIO_IRQ_ERRESC2 (1 << 6)
#define DSI_CIO_IRQ_ERRESC3 (1 << 7)
#define DSI_CIO_IRQ_ERRESC4 (1 << 8)
#define DSI_CIO_IRQ_ERRESC5 (1 << 9)
#define DSI_CIO_IRQ_ERRCONTROL1 (1 << 10)
#define DSI_CIO_IRQ_ERRCONTROL2 (1 << 11)
#define DSI_CIO_IRQ_ERRCONTROL3 (1 << 12)
#define DSI_CIO_IRQ_ERRCONTROL4 (1 << 13)
#define DSI_CIO_IRQ_ERRCONTROL5 (1 << 14)
#define DSI_CIO_IRQ_STATEULPS1 (1 << 15)
#define DSI_CIO_IRQ_STATEULPS2 (1 << 16)
#define DSI_CIO_IRQ_STATEULPS3 (1 << 17)
#define DSI_CIO_IRQ_STATEULPS4 (1 << 18)
#define DSI_CIO_IRQ_STATEULPS5 (1 << 19)
#define DSI_CIO_IRQ_ERRCONTENTIONLP0_1 (1 << 20)
#define DSI_CIO_IRQ_ERRCONTENTIONLP1_1 (1 << 21)
#define DSI_CIO_IRQ_ERRCONTENTIONLP0_2 (1 << 22)
#define DSI_CIO_IRQ_ERRCONTENTIONLP1_2 (1 << 23)
#define DSI_CIO_IRQ_ERRCONTENTIONLP0_3 (1 << 24)
#define DSI_CIO_IRQ_ERRCONTENTIONLP1_3 (1 << 25)
#define DSI_CIO_IRQ_ERRCONTENTIONLP0_4 (1 << 26)
#define DSI_CIO_IRQ_ERRCONTENTIONLP1_4 (1 << 27)
#define DSI_CIO_IRQ_ERRCONTENTIONLP0_5 (1 << 28)
#define DSI_CIO_IRQ_ERRCONTENTIONLP1_5 (1 << 29)
#define DSI_CIO_IRQ_ULPSACTIVENOT_ALL0 (1 << 30)
#define DSI_CIO_IRQ_ULPSACTIVENOT_ALL1 (1 << 31)
#define DSI_CIO_IRQ_ERROR_MASK \
(DSI_CIO_IRQ_ERRSYNCESC1 | DSI_CIO_IRQ_ERRSYNCESC2 | \
DSI_CIO_IRQ_ERRSYNCESC3 | DSI_CIO_IRQ_ERRSYNCESC4 | \
DSI_CIO_IRQ_ERRSYNCESC5 | \
DSI_CIO_IRQ_ERRESC1 | DSI_CIO_IRQ_ERRESC2 | \
DSI_CIO_IRQ_ERRESC3 | DSI_CIO_IRQ_ERRESC4 | \
DSI_CIO_IRQ_ERRESC5 | \
DSI_CIO_IRQ_ERRCONTROL1 | DSI_CIO_IRQ_ERRCONTROL2 | \
DSI_CIO_IRQ_ERRCONTROL3 | DSI_CIO_IRQ_ERRCONTROL4 | \
DSI_CIO_IRQ_ERRCONTROL5 | \
DSI_CIO_IRQ_ERRCONTENTIONLP0_1 | DSI_CIO_IRQ_ERRCONTENTIONLP1_1 | \
DSI_CIO_IRQ_ERRCONTENTIONLP0_2 | DSI_CIO_IRQ_ERRCONTENTIONLP1_2 | \
DSI_CIO_IRQ_ERRCONTENTIONLP0_3 | DSI_CIO_IRQ_ERRCONTENTIONLP1_3 | \
DSI_CIO_IRQ_ERRCONTENTIONLP0_4 | DSI_CIO_IRQ_ERRCONTENTIONLP1_4 | \
DSI_CIO_IRQ_ERRCONTENTIONLP0_5 | DSI_CIO_IRQ_ERRCONTENTIONLP1_5)
typedef void (*omap_dsi_isr_t) (void *arg, u32 mask);
struct dsi_data;
static int dsi_display_init_dispc(struct dsi_data *dsi);
static void dsi_display_uninit_dispc(struct dsi_data *dsi);
static int dsi_vc_send_null(struct dsi_data *dsi, int channel);
/* DSI PLL HSDIV indices */
#define HSDIV_DISPC 0
#define HSDIV_DSI 1
#define DSI_MAX_NR_ISRS 2
#define DSI_MAX_NR_LANES 5
enum dsi_model {
DSI_MODEL_OMAP3,
DSI_MODEL_OMAP4,
DSI_MODEL_OMAP5,
};
enum dsi_lane_function {
DSI_LANE_UNUSED = 0,
DSI_LANE_CLK,
DSI_LANE_DATA1,
DSI_LANE_DATA2,
DSI_LANE_DATA3,
DSI_LANE_DATA4,
};
struct dsi_lane_config {
enum dsi_lane_function function;
u8 polarity;
};
struct dsi_isr_data {
omap_dsi_isr_t isr;
void *arg;
u32 mask;
};
enum fifo_size {
DSI_FIFO_SIZE_0 = 0,
DSI_FIFO_SIZE_32 = 1,
DSI_FIFO_SIZE_64 = 2,
DSI_FIFO_SIZE_96 = 3,
DSI_FIFO_SIZE_128 = 4,
};
enum dsi_vc_source {
DSI_VC_SOURCE_L4 = 0,
DSI_VC_SOURCE_VP,
};
struct dsi_irq_stats {
unsigned long last_reset;
unsigned int irq_count;
unsigned int dsi_irqs[32];
unsigned int vc_irqs[4][32];
unsigned int cio_irqs[32];
};
struct dsi_isr_tables {
struct dsi_isr_data isr_table[DSI_MAX_NR_ISRS];
struct dsi_isr_data isr_table_vc[4][DSI_MAX_NR_ISRS];
struct dsi_isr_data isr_table_cio[DSI_MAX_NR_ISRS];
};
struct dsi_clk_calc_ctx {
struct dsi_data *dsi;
struct dss_pll *pll;
/* inputs */
const struct omap_dss_dsi_config *config;
unsigned long req_pck_min, req_pck_nom, req_pck_max;
/* outputs */
struct dss_pll_clock_info dsi_cinfo;
struct dispc_clock_info dispc_cinfo;
struct videomode vm;
struct omap_dss_dsi_videomode_timings dsi_vm;
};
struct dsi_lp_clock_info {
unsigned long lp_clk;
u16 lp_clk_div;
};
struct dsi_module_id_data {
u32 address;
int id;
};
enum dsi_quirks {
DSI_QUIRK_PLL_PWR_BUG = (1 << 0), /* DSI-PLL power command 0x3 is not working */
DSI_QUIRK_DCS_CMD_CONFIG_VC = (1 << 1),
DSI_QUIRK_VC_OCP_WIDTH = (1 << 2),
DSI_QUIRK_REVERSE_TXCLKESC = (1 << 3),
DSI_QUIRK_GNQ = (1 << 4),
DSI_QUIRK_PHY_DCC = (1 << 5),
};
struct dsi_of_data {
enum dsi_model model;
const struct dss_pll_hw *pll_hw;
const struct dsi_module_id_data *modules;
unsigned int max_fck_freq;
unsigned int max_pll_lpdiv;
enum dsi_quirks quirks;
};
struct dsi_data {
struct device *dev;
void __iomem *proto_base;
void __iomem *phy_base;
void __iomem *pll_base;
const struct dsi_of_data *data;
int module_id;
int irq;
bool is_enabled;
struct clk *dss_clk;
struct regmap *syscon;
struct dss_device *dss;
struct dispc_clock_info user_dispc_cinfo;
struct dss_pll_clock_info user_dsi_cinfo;
struct dsi_lp_clock_info user_lp_cinfo;
struct dsi_lp_clock_info current_lp_cinfo;
struct dss_pll pll;
bool vdds_dsi_enabled;
struct regulator *vdds_dsi_reg;
struct {
enum dsi_vc_source source;
struct omap_dss_device *dssdev;
enum fifo_size tx_fifo_size;
enum fifo_size rx_fifo_size;
int vc_id;
} vc[4];
struct mutex lock;
struct semaphore bus_lock;
spinlock_t irq_lock;
struct dsi_isr_tables isr_tables;
/* space for a copy used by the interrupt handler */
struct dsi_isr_tables isr_tables_copy;
int update_channel;
#ifdef DSI_PERF_MEASURE
unsigned int update_bytes;
#endif
bool te_enabled;
bool ulps_enabled;
void (*framedone_callback)(int, void *);
void *framedone_data;
struct delayed_work framedone_timeout_work;
#ifdef DSI_CATCH_MISSING_TE
struct timer_list te_timer;
#endif
unsigned long cache_req_pck;
unsigned long cache_clk_freq;
struct dss_pll_clock_info cache_cinfo;
u32 errors;
spinlock_t errors_lock;
#ifdef DSI_PERF_MEASURE
ktime_t perf_setup_time;
ktime_t perf_start_time;
#endif
int debug_read;
int debug_write;
struct {
struct dss_debugfs_entry *irqs;
struct dss_debugfs_entry *regs;
struct dss_debugfs_entry *clks;
} debugfs;
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
spinlock_t irq_stats_lock;
struct dsi_irq_stats irq_stats;
#endif
unsigned int num_lanes_supported;
unsigned int line_buffer_size;
struct dsi_lane_config lanes[DSI_MAX_NR_LANES];
unsigned int num_lanes_used;
unsigned int scp_clk_refcount;
struct dss_lcd_mgr_config mgr_config;
struct videomode vm;
enum omap_dss_dsi_pixel_format pix_fmt;
enum omap_dss_dsi_mode mode;
struct omap_dss_dsi_videomode_timings vm_timings;
struct omap_dss_device output;
};
struct dsi_packet_sent_handler_data {
struct dsi_data *dsi;
struct completion *completion;
};
#ifdef DSI_PERF_MEASURE
static bool dsi_perf;
module_param(dsi_perf, bool, 0644);
#endif
static inline struct dsi_data *to_dsi_data(struct omap_dss_device *dssdev)
{
return dev_get_drvdata(dssdev->dev);
}
static inline void dsi_write_reg(struct dsi_data *dsi,
const struct dsi_reg idx, u32 val)
{
void __iomem *base;
switch(idx.module) {
case DSI_PROTO: base = dsi->proto_base; break;
case DSI_PHY: base = dsi->phy_base; break;
case DSI_PLL: base = dsi->pll_base; break;
default: return;
}
__raw_writel(val, base + idx.idx);
}
static inline u32 dsi_read_reg(struct dsi_data *dsi, const struct dsi_reg idx)
{
void __iomem *base;
switch(idx.module) {
case DSI_PROTO: base = dsi->proto_base; break;
case DSI_PHY: base = dsi->phy_base; break;
case DSI_PLL: base = dsi->pll_base; break;
default: return 0;
}
return __raw_readl(base + idx.idx);
}
static void dsi_bus_lock(struct omap_dss_device *dssdev)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
down(&dsi->bus_lock);
}
static void dsi_bus_unlock(struct omap_dss_device *dssdev)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
up(&dsi->bus_lock);
}
static bool dsi_bus_is_locked(struct dsi_data *dsi)
{
return dsi->bus_lock.count == 0;
}
static void dsi_completion_handler(void *data, u32 mask)
{
complete((struct completion *)data);
}
static inline bool wait_for_bit_change(struct dsi_data *dsi,
const struct dsi_reg idx,
int bitnum, int value)
{
unsigned long timeout;
ktime_t wait;
int t;
/* first busyloop to see if the bit changes right away */
t = 100;
while (t-- > 0) {
if (REG_GET(dsi, idx, bitnum, bitnum) == value)
return true;
}
/* then loop for 500ms, sleeping for 1ms in between */
timeout = jiffies + msecs_to_jiffies(500);
while (time_before(jiffies, timeout)) {
if (REG_GET(dsi, idx, bitnum, bitnum) == value)
return true;
wait = ns_to_ktime(1000 * 1000);
set_current_state(TASK_UNINTERRUPTIBLE);
schedule_hrtimeout(&wait, HRTIMER_MODE_REL);
}
return false;
}
static u8 dsi_get_pixel_size(enum omap_dss_dsi_pixel_format fmt)
{
switch (fmt) {
case OMAP_DSS_DSI_FMT_RGB888:
case OMAP_DSS_DSI_FMT_RGB666:
return 24;
case OMAP_DSS_DSI_FMT_RGB666_PACKED:
return 18;
case OMAP_DSS_DSI_FMT_RGB565:
return 16;
default:
BUG();
return 0;
}
}
#ifdef DSI_PERF_MEASURE
static void dsi_perf_mark_setup(struct dsi_data *dsi)
{
dsi->perf_setup_time = ktime_get();
}
static void dsi_perf_mark_start(struct dsi_data *dsi)
{
dsi->perf_start_time = ktime_get();
}
static void dsi_perf_show(struct dsi_data *dsi, const char *name)
{
ktime_t t, setup_time, trans_time;
u32 total_bytes;
u32 setup_us, trans_us, total_us;
if (!dsi_perf)
return;
t = ktime_get();
setup_time = ktime_sub(dsi->perf_start_time, dsi->perf_setup_time);
setup_us = (u32)ktime_to_us(setup_time);
if (setup_us == 0)
setup_us = 1;
trans_time = ktime_sub(t, dsi->perf_start_time);
trans_us = (u32)ktime_to_us(trans_time);
if (trans_us == 0)
trans_us = 1;
total_us = setup_us + trans_us;
total_bytes = dsi->update_bytes;
pr_info("DSI(%s): %u us + %u us = %u us (%uHz), %u bytes, %u kbytes/sec\n",
name,
setup_us,
trans_us,
total_us,
1000 * 1000 / total_us,
total_bytes,
total_bytes * 1000 / total_us);
}
#else
static inline void dsi_perf_mark_setup(struct dsi_data *dsi)
{
}
static inline void dsi_perf_mark_start(struct dsi_data *dsi)
{
}
static inline void dsi_perf_show(struct dsi_data *dsi, const char *name)
{
}
#endif
static int verbose_irq;
static void print_irq_status(u32 status)
{
if (status == 0)
return;
if (!verbose_irq && (status & ~DSI_IRQ_CHANNEL_MASK) == 0)
return;
#define PIS(x) (status & DSI_IRQ_##x) ? (#x " ") : ""
pr_debug("DSI IRQ: 0x%x: %s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s\n",
status,
verbose_irq ? PIS(VC0) : "",
verbose_irq ? PIS(VC1) : "",
verbose_irq ? PIS(VC2) : "",
verbose_irq ? PIS(VC3) : "",
PIS(WAKEUP),
PIS(RESYNC),
PIS(PLL_LOCK),
PIS(PLL_UNLOCK),
PIS(PLL_RECALL),
PIS(COMPLEXIO_ERR),
PIS(HS_TX_TIMEOUT),
PIS(LP_RX_TIMEOUT),
PIS(TE_TRIGGER),
PIS(ACK_TRIGGER),
PIS(SYNC_LOST),
PIS(LDO_POWER_GOOD),
PIS(TA_TIMEOUT));
#undef PIS
}
static void print_irq_status_vc(int channel, u32 status)
{
if (status == 0)
return;
if (!verbose_irq && (status & ~DSI_VC_IRQ_PACKET_SENT) == 0)
return;
#define PIS(x) (status & DSI_VC_IRQ_##x) ? (#x " ") : ""
pr_debug("DSI VC(%d) IRQ 0x%x: %s%s%s%s%s%s%s%s%s\n",
channel,
status,
PIS(CS),
PIS(ECC_CORR),
PIS(ECC_NO_CORR),
verbose_irq ? PIS(PACKET_SENT) : "",
PIS(BTA),
PIS(FIFO_TX_OVF),
PIS(FIFO_RX_OVF),
PIS(FIFO_TX_UDF),
PIS(PP_BUSY_CHANGE));
#undef PIS
}
static void print_irq_status_cio(u32 status)
{
if (status == 0)
return;
#define PIS(x) (status & DSI_CIO_IRQ_##x) ? (#x " ") : ""
pr_debug("DSI CIO IRQ 0x%x: %s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s\n",
status,
PIS(ERRSYNCESC1),
PIS(ERRSYNCESC2),
PIS(ERRSYNCESC3),
PIS(ERRESC1),
PIS(ERRESC2),
PIS(ERRESC3),
PIS(ERRCONTROL1),
PIS(ERRCONTROL2),
PIS(ERRCONTROL3),
PIS(STATEULPS1),
PIS(STATEULPS2),
PIS(STATEULPS3),
PIS(ERRCONTENTIONLP0_1),
PIS(ERRCONTENTIONLP1_1),
PIS(ERRCONTENTIONLP0_2),
PIS(ERRCONTENTIONLP1_2),
PIS(ERRCONTENTIONLP0_3),
PIS(ERRCONTENTIONLP1_3),
PIS(ULPSACTIVENOT_ALL0),
PIS(ULPSACTIVENOT_ALL1));
#undef PIS
}
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
static void dsi_collect_irq_stats(struct dsi_data *dsi, u32 irqstatus,
u32 *vcstatus, u32 ciostatus)
{
int i;
spin_lock(&dsi->irq_stats_lock);
dsi->irq_stats.irq_count++;
dss_collect_irq_stats(irqstatus, dsi->irq_stats.dsi_irqs);
for (i = 0; i < 4; ++i)
dss_collect_irq_stats(vcstatus[i], dsi->irq_stats.vc_irqs[i]);
dss_collect_irq_stats(ciostatus, dsi->irq_stats.cio_irqs);
spin_unlock(&dsi->irq_stats_lock);
}
#else
#define dsi_collect_irq_stats(dsi, irqstatus, vcstatus, ciostatus)
#endif
static int debug_irq;
static void dsi_handle_irq_errors(struct dsi_data *dsi, u32 irqstatus,
u32 *vcstatus, u32 ciostatus)
{
int i;
if (irqstatus & DSI_IRQ_ERROR_MASK) {
DSSERR("DSI error, irqstatus %x\n", irqstatus);
print_irq_status(irqstatus);
spin_lock(&dsi->errors_lock);
dsi->errors |= irqstatus & DSI_IRQ_ERROR_MASK;
spin_unlock(&dsi->errors_lock);
} else if (debug_irq) {
print_irq_status(irqstatus);
}
for (i = 0; i < 4; ++i) {
if (vcstatus[i] & DSI_VC_IRQ_ERROR_MASK) {
DSSERR("DSI VC(%d) error, vc irqstatus %x\n",
i, vcstatus[i]);
print_irq_status_vc(i, vcstatus[i]);
} else if (debug_irq) {
print_irq_status_vc(i, vcstatus[i]);
}
}
if (ciostatus & DSI_CIO_IRQ_ERROR_MASK) {
DSSERR("DSI CIO error, cio irqstatus %x\n", ciostatus);
print_irq_status_cio(ciostatus);
} else if (debug_irq) {
print_irq_status_cio(ciostatus);
}
}
static void dsi_call_isrs(struct dsi_isr_data *isr_array,
unsigned int isr_array_size, u32 irqstatus)
{
struct dsi_isr_data *isr_data;
int i;
for (i = 0; i < isr_array_size; i++) {
isr_data = &isr_array[i];
if (isr_data->isr && isr_data->mask & irqstatus)
isr_data->isr(isr_data->arg, irqstatus);
}
}
static void dsi_handle_isrs(struct dsi_isr_tables *isr_tables,
u32 irqstatus, u32 *vcstatus, u32 ciostatus)
{
int i;
dsi_call_isrs(isr_tables->isr_table,
ARRAY_SIZE(isr_tables->isr_table),
irqstatus);
for (i = 0; i < 4; ++i) {
if (vcstatus[i] == 0)
continue;
dsi_call_isrs(isr_tables->isr_table_vc[i],
ARRAY_SIZE(isr_tables->isr_table_vc[i]),
vcstatus[i]);
}
if (ciostatus != 0)
dsi_call_isrs(isr_tables->isr_table_cio,
ARRAY_SIZE(isr_tables->isr_table_cio),
ciostatus);
}
static irqreturn_t omap_dsi_irq_handler(int irq, void *arg)
{
struct dsi_data *dsi = arg;
u32 irqstatus, vcstatus[4], ciostatus;
int i;
if (!dsi->is_enabled)
return IRQ_NONE;
spin_lock(&dsi->irq_lock);
irqstatus = dsi_read_reg(dsi, DSI_IRQSTATUS);
/* IRQ is not for us */
if (!irqstatus) {
spin_unlock(&dsi->irq_lock);
return IRQ_NONE;
}
dsi_write_reg(dsi, DSI_IRQSTATUS, irqstatus & ~DSI_IRQ_CHANNEL_MASK);
/* flush posted write */
dsi_read_reg(dsi, DSI_IRQSTATUS);
for (i = 0; i < 4; ++i) {
if ((irqstatus & (1 << i)) == 0) {
vcstatus[i] = 0;
continue;
}
vcstatus[i] = dsi_read_reg(dsi, DSI_VC_IRQSTATUS(i));
dsi_write_reg(dsi, DSI_VC_IRQSTATUS(i), vcstatus[i]);
/* flush posted write */
dsi_read_reg(dsi, DSI_VC_IRQSTATUS(i));
}
if (irqstatus & DSI_IRQ_COMPLEXIO_ERR) {
ciostatus = dsi_read_reg(dsi, DSI_COMPLEXIO_IRQ_STATUS);
dsi_write_reg(dsi, DSI_COMPLEXIO_IRQ_STATUS, ciostatus);
/* flush posted write */
dsi_read_reg(dsi, DSI_COMPLEXIO_IRQ_STATUS);
} else {
ciostatus = 0;
}
#ifdef DSI_CATCH_MISSING_TE
if (irqstatus & DSI_IRQ_TE_TRIGGER)
del_timer(&dsi->te_timer);
#endif
/* make a copy and unlock, so that isrs can unregister
* themselves */
memcpy(&dsi->isr_tables_copy, &dsi->isr_tables,
sizeof(dsi->isr_tables));
spin_unlock(&dsi->irq_lock);
dsi_handle_isrs(&dsi->isr_tables_copy, irqstatus, vcstatus, ciostatus);
dsi_handle_irq_errors(dsi, irqstatus, vcstatus, ciostatus);
dsi_collect_irq_stats(dsi, irqstatus, vcstatus, ciostatus);
return IRQ_HANDLED;
}
/* dsi->irq_lock has to be locked by the caller */
static void _omap_dsi_configure_irqs(struct dsi_data *dsi,
struct dsi_isr_data *isr_array,
unsigned int isr_array_size,
u32 default_mask,
const struct dsi_reg enable_reg,
const struct dsi_reg status_reg)
{
struct dsi_isr_data *isr_data;
u32 mask;
u32 old_mask;
int i;
mask = default_mask;
for (i = 0; i < isr_array_size; i++) {
isr_data = &isr_array[i];
if (isr_data->isr == NULL)
continue;
mask |= isr_data->mask;
}
old_mask = dsi_read_reg(dsi, enable_reg);
/* clear the irqstatus for newly enabled irqs */
dsi_write_reg(dsi, status_reg, (mask ^ old_mask) & mask);
dsi_write_reg(dsi, enable_reg, mask);
/* flush posted writes */
dsi_read_reg(dsi, enable_reg);
dsi_read_reg(dsi, status_reg);
}
/* dsi->irq_lock has to be locked by the caller */
static void _omap_dsi_set_irqs(struct dsi_data *dsi)
{
u32 mask = DSI_IRQ_ERROR_MASK;
#ifdef DSI_CATCH_MISSING_TE
mask |= DSI_IRQ_TE_TRIGGER;
#endif
_omap_dsi_configure_irqs(dsi, dsi->isr_tables.isr_table,
ARRAY_SIZE(dsi->isr_tables.isr_table), mask,
DSI_IRQENABLE, DSI_IRQSTATUS);
}
/* dsi->irq_lock has to be locked by the caller */
static void _omap_dsi_set_irqs_vc(struct dsi_data *dsi, int vc)
{
_omap_dsi_configure_irqs(dsi, dsi->isr_tables.isr_table_vc[vc],
ARRAY_SIZE(dsi->isr_tables.isr_table_vc[vc]),
DSI_VC_IRQ_ERROR_MASK,
DSI_VC_IRQENABLE(vc), DSI_VC_IRQSTATUS(vc));
}
/* dsi->irq_lock has to be locked by the caller */
static void _omap_dsi_set_irqs_cio(struct dsi_data *dsi)
{
_omap_dsi_configure_irqs(dsi, dsi->isr_tables.isr_table_cio,
ARRAY_SIZE(dsi->isr_tables.isr_table_cio),
DSI_CIO_IRQ_ERROR_MASK,
DSI_COMPLEXIO_IRQ_ENABLE, DSI_COMPLEXIO_IRQ_STATUS);
}
static void _dsi_initialize_irq(struct dsi_data *dsi)
{
unsigned long flags;
int vc;
spin_lock_irqsave(&dsi->irq_lock, flags);
memset(&dsi->isr_tables, 0, sizeof(dsi->isr_tables));
_omap_dsi_set_irqs(dsi);
for (vc = 0; vc < 4; ++vc)
_omap_dsi_set_irqs_vc(dsi, vc);
_omap_dsi_set_irqs_cio(dsi);
spin_unlock_irqrestore(&dsi->irq_lock, flags);
}
static int _dsi_register_isr(omap_dsi_isr_t isr, void *arg, u32 mask,
struct dsi_isr_data *isr_array, unsigned int isr_array_size)
{
struct dsi_isr_data *isr_data;
int free_idx;
int i;
BUG_ON(isr == NULL);
/* check for duplicate entry and find a free slot */
free_idx = -1;
for (i = 0; i < isr_array_size; i++) {
isr_data = &isr_array[i];
if (isr_data->isr == isr && isr_data->arg == arg &&
isr_data->mask == mask) {
return -EINVAL;
}
if (isr_data->isr == NULL && free_idx == -1)
free_idx = i;
}
if (free_idx == -1)
return -EBUSY;
isr_data = &isr_array[free_idx];
isr_data->isr = isr;
isr_data->arg = arg;
isr_data->mask = mask;
return 0;
}
static int _dsi_unregister_isr(omap_dsi_isr_t isr, void *arg, u32 mask,
struct dsi_isr_data *isr_array, unsigned int isr_array_size)
{
struct dsi_isr_data *isr_data;
int i;
for (i = 0; i < isr_array_size; i++) {
isr_data = &isr_array[i];
if (isr_data->isr != isr || isr_data->arg != arg ||
isr_data->mask != mask)
continue;
isr_data->isr = NULL;
isr_data->arg = NULL;
isr_data->mask = 0;
return 0;
}
return -EINVAL;
}
static int dsi_register_isr(struct dsi_data *dsi, omap_dsi_isr_t isr,
void *arg, u32 mask)
{
unsigned long flags;
int r;
spin_lock_irqsave(&dsi->irq_lock, flags);
r = _dsi_register_isr(isr, arg, mask, dsi->isr_tables.isr_table,
ARRAY_SIZE(dsi->isr_tables.isr_table));
if (r == 0)
_omap_dsi_set_irqs(dsi);
spin_unlock_irqrestore(&dsi->irq_lock, flags);
return r;
}
static int dsi_unregister_isr(struct dsi_data *dsi, omap_dsi_isr_t isr,
void *arg, u32 mask)
{
unsigned long flags;
int r;
spin_lock_irqsave(&dsi->irq_lock, flags);
r = _dsi_unregister_isr(isr, arg, mask, dsi->isr_tables.isr_table,
ARRAY_SIZE(dsi->isr_tables.isr_table));
if (r == 0)
_omap_dsi_set_irqs(dsi);
spin_unlock_irqrestore(&dsi->irq_lock, flags);
return r;
}
static int dsi_register_isr_vc(struct dsi_data *dsi, int channel,
omap_dsi_isr_t isr, void *arg, u32 mask)
{
unsigned long flags;
int r;
spin_lock_irqsave(&dsi->irq_lock, flags);
r = _dsi_register_isr(isr, arg, mask,
dsi->isr_tables.isr_table_vc[channel],
ARRAY_SIZE(dsi->isr_tables.isr_table_vc[channel]));
if (r == 0)
_omap_dsi_set_irqs_vc(dsi, channel);
spin_unlock_irqrestore(&dsi->irq_lock, flags);
return r;
}
static int dsi_unregister_isr_vc(struct dsi_data *dsi, int channel,
omap_dsi_isr_t isr, void *arg, u32 mask)
{
unsigned long flags;
int r;
spin_lock_irqsave(&dsi->irq_lock, flags);
r = _dsi_unregister_isr(isr, arg, mask,
dsi->isr_tables.isr_table_vc[channel],
ARRAY_SIZE(dsi->isr_tables.isr_table_vc[channel]));
if (r == 0)
_omap_dsi_set_irqs_vc(dsi, channel);
spin_unlock_irqrestore(&dsi->irq_lock, flags);
return r;
}
static int dsi_register_isr_cio(struct dsi_data *dsi, omap_dsi_isr_t isr,
void *arg, u32 mask)
{
unsigned long flags;
int r;
spin_lock_irqsave(&dsi->irq_lock, flags);
r = _dsi_register_isr(isr, arg, mask, dsi->isr_tables.isr_table_cio,
ARRAY_SIZE(dsi->isr_tables.isr_table_cio));
if (r == 0)
_omap_dsi_set_irqs_cio(dsi);
spin_unlock_irqrestore(&dsi->irq_lock, flags);
return r;
}
static int dsi_unregister_isr_cio(struct dsi_data *dsi, omap_dsi_isr_t isr,
void *arg, u32 mask)
{
unsigned long flags;
int r;
spin_lock_irqsave(&dsi->irq_lock, flags);
r = _dsi_unregister_isr(isr, arg, mask, dsi->isr_tables.isr_table_cio,
ARRAY_SIZE(dsi->isr_tables.isr_table_cio));
if (r == 0)
_omap_dsi_set_irqs_cio(dsi);
spin_unlock_irqrestore(&dsi->irq_lock, flags);
return r;
}
static u32 dsi_get_errors(struct dsi_data *dsi)
{
unsigned long flags;
u32 e;
spin_lock_irqsave(&dsi->errors_lock, flags);
e = dsi->errors;
dsi->errors = 0;
spin_unlock_irqrestore(&dsi->errors_lock, flags);
return e;
}
static int dsi_runtime_get(struct dsi_data *dsi)
{
int r;
DSSDBG("dsi_runtime_get\n");
r = pm_runtime_get_sync(dsi->dev);
WARN_ON(r < 0);
return r < 0 ? r : 0;
}
static void dsi_runtime_put(struct dsi_data *dsi)
{
int r;
DSSDBG("dsi_runtime_put\n");
r = pm_runtime_put_sync(dsi->dev);
WARN_ON(r < 0 && r != -ENOSYS);
}
static void _dsi_print_reset_status(struct dsi_data *dsi)
{
u32 l;
int b0, b1, b2;
/* A dummy read using the SCP interface to any DSIPHY register is
* required after DSIPHY reset to complete the reset of the DSI complex
* I/O. */
l = dsi_read_reg(dsi, DSI_DSIPHY_CFG5);
if (dsi->data->quirks & DSI_QUIRK_REVERSE_TXCLKESC) {
b0 = 28;
b1 = 27;
b2 = 26;
} else {
b0 = 24;
b1 = 25;
b2 = 26;
}
#define DSI_FLD_GET(fld, start, end)\
FLD_GET(dsi_read_reg(dsi, DSI_##fld), start, end)
pr_debug("DSI resets: PLL (%d) CIO (%d) PHY (%x%x%x, %d, %d, %d)\n",
DSI_FLD_GET(PLL_STATUS, 0, 0),
DSI_FLD_GET(COMPLEXIO_CFG1, 29, 29),
DSI_FLD_GET(DSIPHY_CFG5, b0, b0),
DSI_FLD_GET(DSIPHY_CFG5, b1, b1),
DSI_FLD_GET(DSIPHY_CFG5, b2, b2),
DSI_FLD_GET(DSIPHY_CFG5, 29, 29),
DSI_FLD_GET(DSIPHY_CFG5, 30, 30),
DSI_FLD_GET(DSIPHY_CFG5, 31, 31));
#undef DSI_FLD_GET
}
static inline int dsi_if_enable(struct dsi_data *dsi, bool enable)
{
DSSDBG("dsi_if_enable(%d)\n", enable);
enable = enable ? 1 : 0;
REG_FLD_MOD(dsi, DSI_CTRL, enable, 0, 0); /* IF_EN */
if (!wait_for_bit_change(dsi, DSI_CTRL, 0, enable)) {
DSSERR("Failed to set dsi_if_enable to %d\n", enable);
return -EIO;
}
return 0;
}
static unsigned long dsi_get_pll_hsdiv_dispc_rate(struct dsi_data *dsi)
{
return dsi->pll.cinfo.clkout[HSDIV_DISPC];
}
static unsigned long dsi_get_pll_hsdiv_dsi_rate(struct dsi_data *dsi)
{
return dsi->pll.cinfo.clkout[HSDIV_DSI];
}
static unsigned long dsi_get_txbyteclkhs(struct dsi_data *dsi)
{
return dsi->pll.cinfo.clkdco / 16;
}
static unsigned long dsi_fclk_rate(struct dsi_data *dsi)
{
unsigned long r;
enum dss_clk_source source;
source = dss_get_dsi_clk_source(dsi->dss, dsi->module_id);
if (source == DSS_CLK_SRC_FCK) {
/* DSI FCLK source is DSS_CLK_FCK */
r = clk_get_rate(dsi->dss_clk);
} else {
/* DSI FCLK source is dsi_pll_hsdiv_dsi_clk */
r = dsi_get_pll_hsdiv_dsi_rate(dsi);
}
return r;
}
static int dsi_lp_clock_calc(unsigned long dsi_fclk,
unsigned long lp_clk_min, unsigned long lp_clk_max,
struct dsi_lp_clock_info *lp_cinfo)
{
unsigned int lp_clk_div;
unsigned long lp_clk;
lp_clk_div = DIV_ROUND_UP(dsi_fclk, lp_clk_max * 2);
lp_clk = dsi_fclk / 2 / lp_clk_div;
if (lp_clk < lp_clk_min || lp_clk > lp_clk_max)
return -EINVAL;
lp_cinfo->lp_clk_div = lp_clk_div;
lp_cinfo->lp_clk = lp_clk;
return 0;
}
static int dsi_set_lp_clk_divisor(struct dsi_data *dsi)
{
unsigned long dsi_fclk;
unsigned int lp_clk_div;
unsigned long lp_clk;
unsigned int lpdiv_max = dsi->data->max_pll_lpdiv;
lp_clk_div = dsi->user_lp_cinfo.lp_clk_div;
if (lp_clk_div == 0 || lp_clk_div > lpdiv_max)
return -EINVAL;
dsi_fclk = dsi_fclk_rate(dsi);
lp_clk = dsi_fclk / 2 / lp_clk_div;
DSSDBG("LP_CLK_DIV %u, LP_CLK %lu\n", lp_clk_div, lp_clk);
dsi->current_lp_cinfo.lp_clk = lp_clk;
dsi->current_lp_cinfo.lp_clk_div = lp_clk_div;
/* LP_CLK_DIVISOR */
REG_FLD_MOD(dsi, DSI_CLK_CTRL, lp_clk_div, 12, 0);
/* LP_RX_SYNCHRO_ENABLE */
REG_FLD_MOD(dsi, DSI_CLK_CTRL, dsi_fclk > 30000000 ? 1 : 0, 21, 21);
return 0;
}
static void dsi_enable_scp_clk(struct dsi_data *dsi)
{
if (dsi->scp_clk_refcount++ == 0)
REG_FLD_MOD(dsi, DSI_CLK_CTRL, 1, 14, 14); /* CIO_CLK_ICG */
}
static void dsi_disable_scp_clk(struct dsi_data *dsi)
{
WARN_ON(dsi->scp_clk_refcount == 0);
if (--dsi->scp_clk_refcount == 0)
REG_FLD_MOD(dsi, DSI_CLK_CTRL, 0, 14, 14); /* CIO_CLK_ICG */
}
enum dsi_pll_power_state {
DSI_PLL_POWER_OFF = 0x0,
DSI_PLL_POWER_ON_HSCLK = 0x1,
DSI_PLL_POWER_ON_ALL = 0x2,
DSI_PLL_POWER_ON_DIV = 0x3,
};
static int dsi_pll_power(struct dsi_data *dsi, enum dsi_pll_power_state state)
{
int t = 0;
/* DSI-PLL power command 0x3 is not working */
if ((dsi->data->quirks & DSI_QUIRK_PLL_PWR_BUG) &&
state == DSI_PLL_POWER_ON_DIV)
state = DSI_PLL_POWER_ON_ALL;
/* PLL_PWR_CMD */
REG_FLD_MOD(dsi, DSI_CLK_CTRL, state, 31, 30);
/* PLL_PWR_STATUS */
while (FLD_GET(dsi_read_reg(dsi, DSI_CLK_CTRL), 29, 28) != state) {
if (++t > 1000) {
DSSERR("Failed to set DSI PLL power mode to %d\n",
state);
return -ENODEV;
}
udelay(1);
}
return 0;
}
static void dsi_pll_calc_dsi_fck(struct dsi_data *dsi,
struct dss_pll_clock_info *cinfo)
{
unsigned long max_dsi_fck;
max_dsi_fck = dsi->data->max_fck_freq;
cinfo->mX[HSDIV_DSI] = DIV_ROUND_UP(cinfo->clkdco, max_dsi_fck);
cinfo->clkout[HSDIV_DSI] = cinfo->clkdco / cinfo->mX[HSDIV_DSI];
}
static int dsi_pll_enable(struct dss_pll *pll)
{
struct dsi_data *dsi = container_of(pll, struct dsi_data, pll);
int r = 0;
DSSDBG("PLL init\n");
r = dsi_runtime_get(dsi);
if (r)
return r;
/*
* Note: SCP CLK is not required on OMAP3, but it is required on OMAP4.
*/
dsi_enable_scp_clk(dsi);
2019-02-07 22:45:16 +07:00
r = regulator_enable(dsi->vdds_dsi_reg);
if (r)
goto err0;
/* XXX PLL does not come out of reset without this... */
dispc_pck_free_enable(dsi->dss->dispc, 1);
if (!wait_for_bit_change(dsi, DSI_PLL_STATUS, 0, 1)) {
DSSERR("PLL not coming out of reset.\n");
r = -ENODEV;
dispc_pck_free_enable(dsi->dss->dispc, 0);
goto err1;
}
/* XXX ... but if left on, we get problems when planes do not
* fill the whole display. No idea about this */
dispc_pck_free_enable(dsi->dss->dispc, 0);
r = dsi_pll_power(dsi, DSI_PLL_POWER_ON_ALL);
if (r)
goto err1;
DSSDBG("PLL init done\n");
return 0;
err1:
2019-02-07 22:45:16 +07:00
regulator_disable(dsi->vdds_dsi_reg);
err0:
dsi_disable_scp_clk(dsi);
dsi_runtime_put(dsi);
return r;
}
2019-02-07 22:45:16 +07:00
static void dsi_pll_disable(struct dss_pll *pll)
{
2019-02-07 22:45:16 +07:00
struct dsi_data *dsi = container_of(pll, struct dsi_data, pll);
dsi_pll_power(dsi, DSI_PLL_POWER_OFF);
2019-02-07 22:45:16 +07:00
regulator_disable(dsi->vdds_dsi_reg);
dsi_disable_scp_clk(dsi);
dsi_runtime_put(dsi);
2019-02-07 22:45:16 +07:00
DSSDBG("PLL disable done\n");
}
static int dsi_dump_dsi_clocks(struct seq_file *s, void *p)
{
struct dsi_data *dsi = s->private;
struct dss_pll_clock_info *cinfo = &dsi->pll.cinfo;
enum dss_clk_source dispc_clk_src, dsi_clk_src;
int dsi_module = dsi->module_id;
struct dss_pll *pll = &dsi->pll;
dispc_clk_src = dss_get_dispc_clk_source(dsi->dss);
dsi_clk_src = dss_get_dsi_clk_source(dsi->dss, dsi_module);
if (dsi_runtime_get(dsi))
return 0;
seq_printf(s, "- DSI%d PLL -\n", dsi_module + 1);
seq_printf(s, "dsi pll clkin\t%lu\n", clk_get_rate(pll->clkin));
seq_printf(s, "Fint\t\t%-16lun %u\n", cinfo->fint, cinfo->n);
seq_printf(s, "CLKIN4DDR\t%-16lum %u\n",
cinfo->clkdco, cinfo->m);
seq_printf(s, "DSI_PLL_HSDIV_DISPC (%s)\t%-16lum_dispc %u\t(%s)\n",
dss_get_clk_source_name(dsi_module == 0 ?
DSS_CLK_SRC_PLL1_1 :
DSS_CLK_SRC_PLL2_1),
cinfo->clkout[HSDIV_DISPC],
cinfo->mX[HSDIV_DISPC],
dispc_clk_src == DSS_CLK_SRC_FCK ?
"off" : "on");
seq_printf(s, "DSI_PLL_HSDIV_DSI (%s)\t%-16lum_dsi %u\t(%s)\n",
dss_get_clk_source_name(dsi_module == 0 ?
DSS_CLK_SRC_PLL1_2 :
DSS_CLK_SRC_PLL2_2),
cinfo->clkout[HSDIV_DSI],
cinfo->mX[HSDIV_DSI],
dsi_clk_src == DSS_CLK_SRC_FCK ?
"off" : "on");
seq_printf(s, "- DSI%d -\n", dsi_module + 1);
seq_printf(s, "dsi fclk source = %s\n",
dss_get_clk_source_name(dsi_clk_src));
seq_printf(s, "DSI_FCLK\t%lu\n", dsi_fclk_rate(dsi));
seq_printf(s, "DDR_CLK\t\t%lu\n",
cinfo->clkdco / 4);
seq_printf(s, "TxByteClkHS\t%lu\n", dsi_get_txbyteclkhs(dsi));
seq_printf(s, "LP_CLK\t\t%lu\n", dsi->current_lp_cinfo.lp_clk);
dsi_runtime_put(dsi);
return 0;
}
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
static int dsi_dump_dsi_irqs(struct seq_file *s, void *p)
{
struct dsi_data *dsi = s->private;
unsigned long flags;
struct dsi_irq_stats stats;
spin_lock_irqsave(&dsi->irq_stats_lock, flags);
stats = dsi->irq_stats;
memset(&dsi->irq_stats, 0, sizeof(dsi->irq_stats));
dsi->irq_stats.last_reset = jiffies;
spin_unlock_irqrestore(&dsi->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.dsi_irqs[ffs(DSI_IRQ_##x)-1]);
seq_printf(s, "-- DSI%d interrupts --\n", dsi->module_id + 1);
PIS(VC0);
PIS(VC1);
PIS(VC2);
PIS(VC3);
PIS(WAKEUP);
PIS(RESYNC);
PIS(PLL_LOCK);
PIS(PLL_UNLOCK);
PIS(PLL_RECALL);
PIS(COMPLEXIO_ERR);
PIS(HS_TX_TIMEOUT);
PIS(LP_RX_TIMEOUT);
PIS(TE_TRIGGER);
PIS(ACK_TRIGGER);
PIS(SYNC_LOST);
PIS(LDO_POWER_GOOD);
PIS(TA_TIMEOUT);
#undef PIS
#define PIS(x) \
seq_printf(s, "%-20s %10d %10d %10d %10d\n", #x, \
stats.vc_irqs[0][ffs(DSI_VC_IRQ_##x)-1], \
stats.vc_irqs[1][ffs(DSI_VC_IRQ_##x)-1], \
stats.vc_irqs[2][ffs(DSI_VC_IRQ_##x)-1], \
stats.vc_irqs[3][ffs(DSI_VC_IRQ_##x)-1]);
seq_printf(s, "-- VC interrupts --\n");
PIS(CS);
PIS(ECC_CORR);
PIS(PACKET_SENT);
PIS(FIFO_TX_OVF);
PIS(FIFO_RX_OVF);
PIS(BTA);
PIS(ECC_NO_CORR);
PIS(FIFO_TX_UDF);
PIS(PP_BUSY_CHANGE);
#undef PIS
#define PIS(x) \
seq_printf(s, "%-20s %10d\n", #x, \
stats.cio_irqs[ffs(DSI_CIO_IRQ_##x)-1]);
seq_printf(s, "-- CIO interrupts --\n");
PIS(ERRSYNCESC1);
PIS(ERRSYNCESC2);
PIS(ERRSYNCESC3);
PIS(ERRESC1);
PIS(ERRESC2);
PIS(ERRESC3);
PIS(ERRCONTROL1);
PIS(ERRCONTROL2);
PIS(ERRCONTROL3);
PIS(STATEULPS1);
PIS(STATEULPS2);
PIS(STATEULPS3);
PIS(ERRCONTENTIONLP0_1);
PIS(ERRCONTENTIONLP1_1);
PIS(ERRCONTENTIONLP0_2);
PIS(ERRCONTENTIONLP1_2);
PIS(ERRCONTENTIONLP0_3);
PIS(ERRCONTENTIONLP1_3);
PIS(ULPSACTIVENOT_ALL0);
PIS(ULPSACTIVENOT_ALL1);
#undef PIS
return 0;
}
#endif
static int dsi_dump_dsi_regs(struct seq_file *s, void *p)
{
struct dsi_data *dsi = s->private;
if (dsi_runtime_get(dsi))
return 0;
dsi_enable_scp_clk(dsi);
#define DUMPREG(r) seq_printf(s, "%-35s %08x\n", #r, dsi_read_reg(dsi, r))
DUMPREG(DSI_REVISION);
DUMPREG(DSI_SYSCONFIG);
DUMPREG(DSI_SYSSTATUS);
DUMPREG(DSI_IRQSTATUS);
DUMPREG(DSI_IRQENABLE);
DUMPREG(DSI_CTRL);
DUMPREG(DSI_COMPLEXIO_CFG1);
DUMPREG(DSI_COMPLEXIO_IRQ_STATUS);
DUMPREG(DSI_COMPLEXIO_IRQ_ENABLE);
DUMPREG(DSI_CLK_CTRL);
DUMPREG(DSI_TIMING1);
DUMPREG(DSI_TIMING2);
DUMPREG(DSI_VM_TIMING1);
DUMPREG(DSI_VM_TIMING2);
DUMPREG(DSI_VM_TIMING3);
DUMPREG(DSI_CLK_TIMING);
DUMPREG(DSI_TX_FIFO_VC_SIZE);
DUMPREG(DSI_RX_FIFO_VC_SIZE);
DUMPREG(DSI_COMPLEXIO_CFG2);
DUMPREG(DSI_RX_FIFO_VC_FULLNESS);
DUMPREG(DSI_VM_TIMING4);
DUMPREG(DSI_TX_FIFO_VC_EMPTINESS);
DUMPREG(DSI_VM_TIMING5);
DUMPREG(DSI_VM_TIMING6);
DUMPREG(DSI_VM_TIMING7);
DUMPREG(DSI_STOPCLK_TIMING);
DUMPREG(DSI_VC_CTRL(0));
DUMPREG(DSI_VC_TE(0));
DUMPREG(DSI_VC_LONG_PACKET_HEADER(0));
DUMPREG(DSI_VC_LONG_PACKET_PAYLOAD(0));
DUMPREG(DSI_VC_SHORT_PACKET_HEADER(0));
DUMPREG(DSI_VC_IRQSTATUS(0));
DUMPREG(DSI_VC_IRQENABLE(0));
DUMPREG(DSI_VC_CTRL(1));
DUMPREG(DSI_VC_TE(1));
DUMPREG(DSI_VC_LONG_PACKET_HEADER(1));
DUMPREG(DSI_VC_LONG_PACKET_PAYLOAD(1));
DUMPREG(DSI_VC_SHORT_PACKET_HEADER(1));
DUMPREG(DSI_VC_IRQSTATUS(1));
DUMPREG(DSI_VC_IRQENABLE(1));
DUMPREG(DSI_VC_CTRL(2));
DUMPREG(DSI_VC_TE(2));
DUMPREG(DSI_VC_LONG_PACKET_HEADER(2));
DUMPREG(DSI_VC_LONG_PACKET_PAYLOAD(2));
DUMPREG(DSI_VC_SHORT_PACKET_HEADER(2));
DUMPREG(DSI_VC_IRQSTATUS(2));
DUMPREG(DSI_VC_IRQENABLE(2));
DUMPREG(DSI_VC_CTRL(3));
DUMPREG(DSI_VC_TE(3));
DUMPREG(DSI_VC_LONG_PACKET_HEADER(3));
DUMPREG(DSI_VC_LONG_PACKET_PAYLOAD(3));
DUMPREG(DSI_VC_SHORT_PACKET_HEADER(3));
DUMPREG(DSI_VC_IRQSTATUS(3));
DUMPREG(DSI_VC_IRQENABLE(3));
DUMPREG(DSI_DSIPHY_CFG0);
DUMPREG(DSI_DSIPHY_CFG1);
DUMPREG(DSI_DSIPHY_CFG2);
DUMPREG(DSI_DSIPHY_CFG5);
DUMPREG(DSI_PLL_CONTROL);
DUMPREG(DSI_PLL_STATUS);
DUMPREG(DSI_PLL_GO);
DUMPREG(DSI_PLL_CONFIGURATION1);
DUMPREG(DSI_PLL_CONFIGURATION2);
#undef DUMPREG
dsi_disable_scp_clk(dsi);
dsi_runtime_put(dsi);
return 0;
}
enum dsi_cio_power_state {
DSI_COMPLEXIO_POWER_OFF = 0x0,
DSI_COMPLEXIO_POWER_ON = 0x1,
DSI_COMPLEXIO_POWER_ULPS = 0x2,
};
static int dsi_cio_power(struct dsi_data *dsi, enum dsi_cio_power_state state)
{
int t = 0;
/* PWR_CMD */
REG_FLD_MOD(dsi, DSI_COMPLEXIO_CFG1, state, 28, 27);
/* PWR_STATUS */
while (FLD_GET(dsi_read_reg(dsi, DSI_COMPLEXIO_CFG1),
26, 25) != state) {
if (++t > 1000) {
DSSERR("failed to set complexio power state to "
"%d\n", state);
return -ENODEV;
}
udelay(1);
}
return 0;
}
static unsigned int dsi_get_line_buf_size(struct dsi_data *dsi)
{
int val;
/* line buffer on OMAP3 is 1024 x 24bits */
/* XXX: for some reason using full buffer size causes
* considerable TX slowdown with update sizes that fill the
* whole buffer */
if (!(dsi->data->quirks & DSI_QUIRK_GNQ))
return 1023 * 3;
val = REG_GET(dsi, DSI_GNQ, 14, 12); /* VP1_LINE_BUFFER_SIZE */
switch (val) {
case 1:
return 512 * 3; /* 512x24 bits */
case 2:
return 682 * 3; /* 682x24 bits */
case 3:
return 853 * 3; /* 853x24 bits */
case 4:
return 1024 * 3; /* 1024x24 bits */
case 5:
return 1194 * 3; /* 1194x24 bits */
case 6:
return 1365 * 3; /* 1365x24 bits */
case 7:
return 1920 * 3; /* 1920x24 bits */
default:
BUG();
return 0;
}
}
static int dsi_set_lane_config(struct dsi_data *dsi)
{
static const u8 offsets[] = { 0, 4, 8, 12, 16 };
static const enum dsi_lane_function functions[] = {
DSI_LANE_CLK,
DSI_LANE_DATA1,
DSI_LANE_DATA2,
DSI_LANE_DATA3,
DSI_LANE_DATA4,
};
u32 r;
int i;
r = dsi_read_reg(dsi, DSI_COMPLEXIO_CFG1);
for (i = 0; i < dsi->num_lanes_used; ++i) {
unsigned int offset = offsets[i];
unsigned int polarity, lane_number;
unsigned int t;
for (t = 0; t < dsi->num_lanes_supported; ++t)
if (dsi->lanes[t].function == functions[i])
break;
if (t == dsi->num_lanes_supported)
return -EINVAL;
lane_number = t;
polarity = dsi->lanes[t].polarity;
r = FLD_MOD(r, lane_number + 1, offset + 2, offset);
r = FLD_MOD(r, polarity, offset + 3, offset + 3);
}
/* clear the unused lanes */
for (; i < dsi->num_lanes_supported; ++i) {
unsigned int offset = offsets[i];
r = FLD_MOD(r, 0, offset + 2, offset);
r = FLD_MOD(r, 0, offset + 3, offset + 3);
}
dsi_write_reg(dsi, DSI_COMPLEXIO_CFG1, r);
return 0;
}
static inline unsigned int ns2ddr(struct dsi_data *dsi, unsigned int ns)
{
/* convert time in ns to ddr ticks, rounding up */
unsigned long ddr_clk = dsi->pll.cinfo.clkdco / 4;
return (ns * (ddr_clk / 1000 / 1000) + 999) / 1000;
}
static inline unsigned int ddr2ns(struct dsi_data *dsi, unsigned int ddr)
{
unsigned long ddr_clk = dsi->pll.cinfo.clkdco / 4;
return ddr * 1000 * 1000 / (ddr_clk / 1000);
}
static void dsi_cio_timings(struct dsi_data *dsi)
{
u32 r;
u32 ths_prepare, ths_prepare_ths_zero, ths_trail, ths_exit;
u32 tlpx_half, tclk_trail, tclk_zero;
u32 tclk_prepare;
/* calculate timings */
/* 1 * DDR_CLK = 2 * UI */
/* min 40ns + 4*UI max 85ns + 6*UI */
ths_prepare = ns2ddr(dsi, 70) + 2;
/* min 145ns + 10*UI */
ths_prepare_ths_zero = ns2ddr(dsi, 175) + 2;
/* min max(8*UI, 60ns+4*UI) */
ths_trail = ns2ddr(dsi, 60) + 5;
/* min 100ns */
ths_exit = ns2ddr(dsi, 145);
/* tlpx min 50n */
tlpx_half = ns2ddr(dsi, 25);
/* min 60ns */
tclk_trail = ns2ddr(dsi, 60) + 2;
/* min 38ns, max 95ns */
tclk_prepare = ns2ddr(dsi, 65);
/* min tclk-prepare + tclk-zero = 300ns */
tclk_zero = ns2ddr(dsi, 260);
DSSDBG("ths_prepare %u (%uns), ths_prepare_ths_zero %u (%uns)\n",
ths_prepare, ddr2ns(dsi, ths_prepare),
ths_prepare_ths_zero, ddr2ns(dsi, ths_prepare_ths_zero));
DSSDBG("ths_trail %u (%uns), ths_exit %u (%uns)\n",
ths_trail, ddr2ns(dsi, ths_trail),
ths_exit, ddr2ns(dsi, ths_exit));
DSSDBG("tlpx_half %u (%uns), tclk_trail %u (%uns), "
"tclk_zero %u (%uns)\n",
tlpx_half, ddr2ns(dsi, tlpx_half),
tclk_trail, ddr2ns(dsi, tclk_trail),
tclk_zero, ddr2ns(dsi, tclk_zero));
DSSDBG("tclk_prepare %u (%uns)\n",
tclk_prepare, ddr2ns(dsi, tclk_prepare));
/* program timings */
r = dsi_read_reg(dsi, DSI_DSIPHY_CFG0);
r = FLD_MOD(r, ths_prepare, 31, 24);
r = FLD_MOD(r, ths_prepare_ths_zero, 23, 16);
r = FLD_MOD(r, ths_trail, 15, 8);
r = FLD_MOD(r, ths_exit, 7, 0);
dsi_write_reg(dsi, DSI_DSIPHY_CFG0, r);
r = dsi_read_reg(dsi, DSI_DSIPHY_CFG1);
r = FLD_MOD(r, tlpx_half, 20, 16);
r = FLD_MOD(r, tclk_trail, 15, 8);
r = FLD_MOD(r, tclk_zero, 7, 0);
if (dsi->data->quirks & DSI_QUIRK_PHY_DCC) {
r = FLD_MOD(r, 0, 21, 21); /* DCCEN = disable */
r = FLD_MOD(r, 1, 22, 22); /* CLKINP_DIVBY2EN = enable */
r = FLD_MOD(r, 1, 23, 23); /* CLKINP_SEL = enable */
}
dsi_write_reg(dsi, DSI_DSIPHY_CFG1, r);
r = dsi_read_reg(dsi, DSI_DSIPHY_CFG2);
r = FLD_MOD(r, tclk_prepare, 7, 0);
dsi_write_reg(dsi, DSI_DSIPHY_CFG2, r);
}
/* lane masks have lane 0 at lsb. mask_p for positive lines, n for negative */
static void dsi_cio_enable_lane_override(struct dsi_data *dsi,
unsigned int mask_p,
unsigned int mask_n)
{
int i;
u32 l;
u8 lptxscp_start = dsi->num_lanes_supported == 3 ? 22 : 26;
l = 0;
for (i = 0; i < dsi->num_lanes_supported; ++i) {
unsigned int p = dsi->lanes[i].polarity;
if (mask_p & (1 << i))
l |= 1 << (i * 2 + (p ? 0 : 1));
if (mask_n & (1 << i))
l |= 1 << (i * 2 + (p ? 1 : 0));
}
/*
* Bits in REGLPTXSCPDAT4TO0DXDY:
* 17: DY0 18: DX0
* 19: DY1 20: DX1
* 21: DY2 22: DX2
* 23: DY3 24: DX3
* 25: DY4 26: DX4
*/
/* Set the lane override configuration */
/* REGLPTXSCPDAT4TO0DXDY */
REG_FLD_MOD(dsi, DSI_DSIPHY_CFG10, l, lptxscp_start, 17);
/* Enable lane override */
/* ENLPTXSCPDAT */
REG_FLD_MOD(dsi, DSI_DSIPHY_CFG10, 1, 27, 27);
}
static void dsi_cio_disable_lane_override(struct dsi_data *dsi)
{
/* Disable lane override */
REG_FLD_MOD(dsi, DSI_DSIPHY_CFG10, 0, 27, 27); /* ENLPTXSCPDAT */
/* Reset the lane override configuration */
/* REGLPTXSCPDAT4TO0DXDY */
REG_FLD_MOD(dsi, DSI_DSIPHY_CFG10, 0, 22, 17);
}
static int dsi_cio_wait_tx_clk_esc_reset(struct dsi_data *dsi)
{
int t, i;
bool in_use[DSI_MAX_NR_LANES];
static const u8 offsets_old[] = { 28, 27, 26 };
static const u8 offsets_new[] = { 24, 25, 26, 27, 28 };
const u8 *offsets;
if (dsi->data->quirks & DSI_QUIRK_REVERSE_TXCLKESC)
offsets = offsets_old;
else
offsets = offsets_new;
for (i = 0; i < dsi->num_lanes_supported; ++i)
in_use[i] = dsi->lanes[i].function != DSI_LANE_UNUSED;
t = 100000;
while (true) {
u32 l;
int ok;
l = dsi_read_reg(dsi, DSI_DSIPHY_CFG5);
ok = 0;
for (i = 0; i < dsi->num_lanes_supported; ++i) {
if (!in_use[i] || (l & (1 << offsets[i])))
ok++;
}
if (ok == dsi->num_lanes_supported)
break;
if (--t == 0) {
for (i = 0; i < dsi->num_lanes_supported; ++i) {
if (!in_use[i] || (l & (1 << offsets[i])))
continue;
DSSERR("CIO TXCLKESC%d domain not coming " \
"out of reset\n", i);
}
return -EIO;
}
}
return 0;
}
/* return bitmask of enabled lanes, lane0 being the lsb */
static unsigned int dsi_get_lane_mask(struct dsi_data *dsi)
{
unsigned int mask = 0;
int i;
for (i = 0; i < dsi->num_lanes_supported; ++i) {
if (dsi->lanes[i].function != DSI_LANE_UNUSED)
mask |= 1 << i;
}
return mask;
}
/* OMAP4 CONTROL_DSIPHY */
#define OMAP4_DSIPHY_SYSCON_OFFSET 0x78
#define OMAP4_DSI2_LANEENABLE_SHIFT 29
#define OMAP4_DSI2_LANEENABLE_MASK (0x7 << 29)
#define OMAP4_DSI1_LANEENABLE_SHIFT 24
#define OMAP4_DSI1_LANEENABLE_MASK (0x1f << 24)
#define OMAP4_DSI1_PIPD_SHIFT 19
#define OMAP4_DSI1_PIPD_MASK (0x1f << 19)
#define OMAP4_DSI2_PIPD_SHIFT 14
#define OMAP4_DSI2_PIPD_MASK (0x1f << 14)
static int dsi_omap4_mux_pads(struct dsi_data *dsi, unsigned int lanes)
{
u32 enable_mask, enable_shift;
u32 pipd_mask, pipd_shift;
if (dsi->module_id == 0) {
enable_mask = OMAP4_DSI1_LANEENABLE_MASK;
enable_shift = OMAP4_DSI1_LANEENABLE_SHIFT;
pipd_mask = OMAP4_DSI1_PIPD_MASK;
pipd_shift = OMAP4_DSI1_PIPD_SHIFT;
} else if (dsi->module_id == 1) {
enable_mask = OMAP4_DSI2_LANEENABLE_MASK;
enable_shift = OMAP4_DSI2_LANEENABLE_SHIFT;
pipd_mask = OMAP4_DSI2_PIPD_MASK;
pipd_shift = OMAP4_DSI2_PIPD_SHIFT;
} else {
return -ENODEV;
}
return regmap_update_bits(dsi->syscon, OMAP4_DSIPHY_SYSCON_OFFSET,
enable_mask | pipd_mask,
(lanes << enable_shift) | (lanes << pipd_shift));
}
/* OMAP5 CONTROL_DSIPHY */
#define OMAP5_DSIPHY_SYSCON_OFFSET 0x74
#define OMAP5_DSI1_LANEENABLE_SHIFT 24
#define OMAP5_DSI2_LANEENABLE_SHIFT 19
#define OMAP5_DSI_LANEENABLE_MASK 0x1f
static int dsi_omap5_mux_pads(struct dsi_data *dsi, unsigned int lanes)
{
u32 enable_shift;
if (dsi->module_id == 0)
enable_shift = OMAP5_DSI1_LANEENABLE_SHIFT;
else if (dsi->module_id == 1)
enable_shift = OMAP5_DSI2_LANEENABLE_SHIFT;
else
return -ENODEV;
return regmap_update_bits(dsi->syscon, OMAP5_DSIPHY_SYSCON_OFFSET,
OMAP5_DSI_LANEENABLE_MASK << enable_shift,
lanes << enable_shift);
}
static int dsi_enable_pads(struct dsi_data *dsi, unsigned int lane_mask)
{
if (dsi->data->model == DSI_MODEL_OMAP4)
return dsi_omap4_mux_pads(dsi, lane_mask);
if (dsi->data->model == DSI_MODEL_OMAP5)
return dsi_omap5_mux_pads(dsi, lane_mask);
return 0;
}
static void dsi_disable_pads(struct dsi_data *dsi)
{
if (dsi->data->model == DSI_MODEL_OMAP4)
dsi_omap4_mux_pads(dsi, 0);
else if (dsi->data->model == DSI_MODEL_OMAP5)
dsi_omap5_mux_pads(dsi, 0);
}
static int dsi_cio_init(struct dsi_data *dsi)
{
int r;
u32 l;
DSSDBG("DSI CIO init starts");
r = dsi_enable_pads(dsi, dsi_get_lane_mask(dsi));
if (r)
return r;
dsi_enable_scp_clk(dsi);
/* A dummy read using the SCP interface to any DSIPHY register is
* required after DSIPHY reset to complete the reset of the DSI complex
* I/O. */
dsi_read_reg(dsi, DSI_DSIPHY_CFG5);
if (!wait_for_bit_change(dsi, DSI_DSIPHY_CFG5, 30, 1)) {
DSSERR("CIO SCP Clock domain not coming out of reset.\n");
r = -EIO;
goto err_scp_clk_dom;
}
r = dsi_set_lane_config(dsi);
if (r)
goto err_scp_clk_dom;
/* set TX STOP MODE timer to maximum for this operation */
l = dsi_read_reg(dsi, DSI_TIMING1);
l = FLD_MOD(l, 1, 15, 15); /* FORCE_TX_STOP_MODE_IO */
l = FLD_MOD(l, 1, 14, 14); /* STOP_STATE_X16_IO */
l = FLD_MOD(l, 1, 13, 13); /* STOP_STATE_X4_IO */
l = FLD_MOD(l, 0x1fff, 12, 0); /* STOP_STATE_COUNTER_IO */
dsi_write_reg(dsi, DSI_TIMING1, l);
if (dsi->ulps_enabled) {
unsigned int mask_p;
int i;
DSSDBG("manual ulps exit\n");
/* ULPS is exited by Mark-1 state for 1ms, followed by
* stop state. DSS HW cannot do this via the normal
* ULPS exit sequence, as after reset the DSS HW thinks
* that we are not in ULPS mode, and refuses to send the
* sequence. So we need to send the ULPS exit sequence
* manually by setting positive lines high and negative lines
* low for 1ms.
*/
mask_p = 0;
for (i = 0; i < dsi->num_lanes_supported; ++i) {
if (dsi->lanes[i].function == DSI_LANE_UNUSED)
continue;
mask_p |= 1 << i;
}
dsi_cio_enable_lane_override(dsi, mask_p, 0);
}
r = dsi_cio_power(dsi, DSI_COMPLEXIO_POWER_ON);
if (r)
goto err_cio_pwr;
if (!wait_for_bit_change(dsi, DSI_COMPLEXIO_CFG1, 29, 1)) {
DSSERR("CIO PWR clock domain not coming out of reset.\n");
r = -ENODEV;
goto err_cio_pwr_dom;
}
dsi_if_enable(dsi, true);
dsi_if_enable(dsi, false);
REG_FLD_MOD(dsi, DSI_CLK_CTRL, 1, 20, 20); /* LP_CLK_ENABLE */
r = dsi_cio_wait_tx_clk_esc_reset(dsi);
if (r)
goto err_tx_clk_esc_rst;
if (dsi->ulps_enabled) {
/* Keep Mark-1 state for 1ms (as per DSI spec) */
ktime_t wait = ns_to_ktime(1000 * 1000);
set_current_state(TASK_UNINTERRUPTIBLE);
schedule_hrtimeout(&wait, HRTIMER_MODE_REL);
/* Disable the override. The lanes should be set to Mark-11
* state by the HW */
dsi_cio_disable_lane_override(dsi);
}
/* FORCE_TX_STOP_MODE_IO */
REG_FLD_MOD(dsi, DSI_TIMING1, 0, 15, 15);
dsi_cio_timings(dsi);
if (dsi->mode == OMAP_DSS_DSI_VIDEO_MODE) {
/* DDR_CLK_ALWAYS_ON */
REG_FLD_MOD(dsi, DSI_CLK_CTRL,
dsi->vm_timings.ddr_clk_always_on, 13, 13);
}
dsi->ulps_enabled = false;
DSSDBG("CIO init done\n");
return 0;
err_tx_clk_esc_rst:
REG_FLD_MOD(dsi, DSI_CLK_CTRL, 0, 20, 20); /* LP_CLK_ENABLE */
err_cio_pwr_dom:
dsi_cio_power(dsi, DSI_COMPLEXIO_POWER_OFF);
err_cio_pwr:
if (dsi->ulps_enabled)
dsi_cio_disable_lane_override(dsi);
err_scp_clk_dom:
dsi_disable_scp_clk(dsi);
dsi_disable_pads(dsi);
return r;
}
static void dsi_cio_uninit(struct dsi_data *dsi)
{
/* DDR_CLK_ALWAYS_ON */
REG_FLD_MOD(dsi, DSI_CLK_CTRL, 0, 13, 13);
dsi_cio_power(dsi, DSI_COMPLEXIO_POWER_OFF);
dsi_disable_scp_clk(dsi);
dsi_disable_pads(dsi);
}
static void dsi_config_tx_fifo(struct dsi_data *dsi,
enum fifo_size size1, enum fifo_size size2,
enum fifo_size size3, enum fifo_size size4)
{
u32 r = 0;
int add = 0;
int i;
dsi->vc[0].tx_fifo_size = size1;
dsi->vc[1].tx_fifo_size = size2;
dsi->vc[2].tx_fifo_size = size3;
dsi->vc[3].tx_fifo_size = size4;
for (i = 0; i < 4; i++) {
u8 v;
int size = dsi->vc[i].tx_fifo_size;
if (add + size > 4) {
DSSERR("Illegal FIFO configuration\n");
BUG();
return;
}
v = FLD_VAL(add, 2, 0) | FLD_VAL(size, 7, 4);
r |= v << (8 * i);
/*DSSDBG("TX FIFO vc %d: size %d, add %d\n", i, size, add); */
add += size;
}
dsi_write_reg(dsi, DSI_TX_FIFO_VC_SIZE, r);
}
static void dsi_config_rx_fifo(struct dsi_data *dsi,
enum fifo_size size1, enum fifo_size size2,
enum fifo_size size3, enum fifo_size size4)
{
u32 r = 0;
int add = 0;
int i;
dsi->vc[0].rx_fifo_size = size1;
dsi->vc[1].rx_fifo_size = size2;
dsi->vc[2].rx_fifo_size = size3;
dsi->vc[3].rx_fifo_size = size4;
for (i = 0; i < 4; i++) {
u8 v;
int size = dsi->vc[i].rx_fifo_size;
if (add + size > 4) {
DSSERR("Illegal FIFO configuration\n");
BUG();
return;
}
v = FLD_VAL(add, 2, 0) | FLD_VAL(size, 7, 4);
r |= v << (8 * i);
/*DSSDBG("RX FIFO vc %d: size %d, add %d\n", i, size, add); */
add += size;
}
dsi_write_reg(dsi, DSI_RX_FIFO_VC_SIZE, r);
}
static int dsi_force_tx_stop_mode_io(struct dsi_data *dsi)
{
u32 r;
r = dsi_read_reg(dsi, DSI_TIMING1);
r = FLD_MOD(r, 1, 15, 15); /* FORCE_TX_STOP_MODE_IO */
dsi_write_reg(dsi, DSI_TIMING1, r);
if (!wait_for_bit_change(dsi, DSI_TIMING1, 15, 0)) {
DSSERR("TX_STOP bit not going down\n");
return -EIO;
}
return 0;
}
static bool dsi_vc_is_enabled(struct dsi_data *dsi, int channel)
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
{
return REG_GET(dsi, DSI_VC_CTRL(channel), 0, 0);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
}
static void dsi_packet_sent_handler_vp(void *data, u32 mask)
{
struct dsi_packet_sent_handler_data *vp_data =
(struct dsi_packet_sent_handler_data *) data;
struct dsi_data *dsi = vp_data->dsi;
const int channel = dsi->update_channel;
u8 bit = dsi->te_enabled ? 30 : 31;
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
if (REG_GET(dsi, DSI_VC_TE(channel), bit, bit) == 0)
complete(vp_data->completion);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
}
static int dsi_sync_vc_vp(struct dsi_data *dsi, int channel)
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
{
DECLARE_COMPLETION_ONSTACK(completion);
struct dsi_packet_sent_handler_data vp_data = {
.dsi = dsi,
.completion = &completion
};
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
int r = 0;
u8 bit;
bit = dsi->te_enabled ? 30 : 31;
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
r = dsi_register_isr_vc(dsi, channel, dsi_packet_sent_handler_vp,
&vp_data, DSI_VC_IRQ_PACKET_SENT);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
if (r)
goto err0;
/* Wait for completion only if TE_EN/TE_START is still set */
if (REG_GET(dsi, DSI_VC_TE(channel), bit, bit)) {
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
if (wait_for_completion_timeout(&completion,
msecs_to_jiffies(10)) == 0) {
DSSERR("Failed to complete previous frame transfer\n");
r = -EIO;
goto err1;
}
}
dsi_unregister_isr_vc(dsi, channel, dsi_packet_sent_handler_vp,
&vp_data, DSI_VC_IRQ_PACKET_SENT);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
return 0;
err1:
dsi_unregister_isr_vc(dsi, channel, dsi_packet_sent_handler_vp,
&vp_data, DSI_VC_IRQ_PACKET_SENT);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
err0:
return r;
}
static void dsi_packet_sent_handler_l4(void *data, u32 mask)
{
struct dsi_packet_sent_handler_data *l4_data =
(struct dsi_packet_sent_handler_data *) data;
struct dsi_data *dsi = l4_data->dsi;
const int channel = dsi->update_channel;
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
if (REG_GET(dsi, DSI_VC_CTRL(channel), 5, 5) == 0)
complete(l4_data->completion);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
}
static int dsi_sync_vc_l4(struct dsi_data *dsi, int channel)
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
{
DECLARE_COMPLETION_ONSTACK(completion);
struct dsi_packet_sent_handler_data l4_data = {
.dsi = dsi,
.completion = &completion
};
int r = 0;
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
r = dsi_register_isr_vc(dsi, channel, dsi_packet_sent_handler_l4,
&l4_data, DSI_VC_IRQ_PACKET_SENT);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
if (r)
goto err0;
/* Wait for completion only if TX_FIFO_NOT_EMPTY is still set */
if (REG_GET(dsi, DSI_VC_CTRL(channel), 5, 5)) {
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
if (wait_for_completion_timeout(&completion,
msecs_to_jiffies(10)) == 0) {
DSSERR("Failed to complete previous l4 transfer\n");
r = -EIO;
goto err1;
}
}
dsi_unregister_isr_vc(dsi, channel, dsi_packet_sent_handler_l4,
&l4_data, DSI_VC_IRQ_PACKET_SENT);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
return 0;
err1:
dsi_unregister_isr_vc(dsi, channel, dsi_packet_sent_handler_l4,
&l4_data, DSI_VC_IRQ_PACKET_SENT);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
err0:
return r;
}
static int dsi_sync_vc(struct dsi_data *dsi, int channel)
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
{
WARN_ON(!dsi_bus_is_locked(dsi));
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
WARN_ON(in_interrupt());
if (!dsi_vc_is_enabled(dsi, channel))
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
return 0;
switch (dsi->vc[channel].source) {
case DSI_VC_SOURCE_VP:
return dsi_sync_vc_vp(dsi, channel);
case DSI_VC_SOURCE_L4:
return dsi_sync_vc_l4(dsi, channel);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
default:
BUG();
return -EINVAL;
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
}
}
static int dsi_vc_enable(struct dsi_data *dsi, int channel, bool enable)
{
DSSDBG("dsi_vc_enable channel %d, enable %d\n",
channel, enable);
enable = enable ? 1 : 0;
REG_FLD_MOD(dsi, DSI_VC_CTRL(channel), enable, 0, 0);
if (!wait_for_bit_change(dsi, DSI_VC_CTRL(channel), 0, enable)) {
DSSERR("Failed to set dsi_vc_enable to %d\n", enable);
return -EIO;
}
return 0;
}
static void dsi_vc_initial_config(struct dsi_data *dsi, int channel)
{
u32 r;
DSSDBG("Initial config of virtual channel %d", channel);
r = dsi_read_reg(dsi, DSI_VC_CTRL(channel));
if (FLD_GET(r, 15, 15)) /* VC_BUSY */
DSSERR("VC(%d) busy when trying to configure it!\n",
channel);
r = FLD_MOD(r, 0, 1, 1); /* SOURCE, 0 = L4 */
r = FLD_MOD(r, 0, 2, 2); /* BTA_SHORT_EN */
r = FLD_MOD(r, 0, 3, 3); /* BTA_LONG_EN */
r = FLD_MOD(r, 0, 4, 4); /* MODE, 0 = command */
r = FLD_MOD(r, 1, 7, 7); /* CS_TX_EN */
r = FLD_MOD(r, 1, 8, 8); /* ECC_TX_EN */
r = FLD_MOD(r, 0, 9, 9); /* MODE_SPEED, high speed on/off */
if (dsi->data->quirks & DSI_QUIRK_VC_OCP_WIDTH)
r = FLD_MOD(r, 3, 11, 10); /* OCP_WIDTH = 32 bit */
r = FLD_MOD(r, 4, 29, 27); /* DMA_RX_REQ_NB = no dma */
r = FLD_MOD(r, 4, 23, 21); /* DMA_TX_REQ_NB = no dma */
dsi_write_reg(dsi, DSI_VC_CTRL(channel), r);
dsi->vc[channel].source = DSI_VC_SOURCE_L4;
}
static int dsi_vc_config_source(struct dsi_data *dsi, int channel,
enum dsi_vc_source source)
{
if (dsi->vc[channel].source == source)
return 0;
DSSDBG("Source config of virtual channel %d", channel);
dsi_sync_vc(dsi, channel);
OMAP: DSS2: DSI: Introduce sync_vc functions The DSI protocol engine has no interrupt for signalling the end of a Frame transfer. The present approach is to send a BTA after DISPC generates a FRAMEDONE interrupt, and unlock the dsi bus only when the BTA Ack is received. The assumption made with this approach was that OMAP will send a BTA only after the long packet corresponding to the last line is sent. However, it is possible that on the DISPC FRAMEDONE interrupt there are 2 (or more) lines of pixel data in the DSI line buffer. Hence, the BTA Ack could be received for the long packet corresponding to the second last line (or the third last and so on..). Therefore, the current method doesn't ensure that the complete frame data is sent before we start a new transfer. A similar explanation holds valid if we send a BTA in between multiple short/long command packets from the slave port. Introduce dsi_sync_vc functions, based on Tomi Valkeinen's idea, which ensure that the DSI Virtual Channel in use(update_channel) completes its previous work before proceeding to the next Frame/Command. For a frame update, the DSI driver now sends a callback to the Panel Driver on the FRAMEDONE interrupt itself. The callback in the panel driver then unlocks the bus. dsi_sync_vc() functions are placed in dsi_vc_config_l4() and dsi_vc_config_vp() to ensure that the previous task of the Virtual Channel is completed. Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2011-03-23 16:59:34 +07:00
dsi_vc_enable(dsi, channel, 0);
/* VC_BUSY */
if (!wait_for_bit_change(dsi, DSI_VC_CTRL(channel), 15, 0)) {
DSSERR("vc(%d) busy when trying to config for VP\n", channel);
return -EIO;
}
/* SOURCE, 0 = L4, 1 = video port */
REG_FLD_MOD(dsi, DSI_VC_CTRL(channel), source, 1, 1);
/* DCS_CMD_ENABLE */
if (dsi->data->quirks & DSI_QUIRK_DCS_CMD_CONFIG_VC) {
bool enable = source == DSI_VC_SOURCE_VP;
REG_FLD_MOD(dsi, DSI_VC_CTRL(channel), enable, 30, 30);
}
dsi_vc_enable(dsi, channel, 1);
dsi->vc[channel].source = source;
return 0;
}
static void dsi_vc_enable_hs(struct omap_dss_device *dssdev, int channel,
bool enable)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
DSSDBG("dsi_vc_enable_hs(%d, %d)\n", channel, enable);
WARN_ON(!dsi_bus_is_locked(dsi));
dsi_vc_enable(dsi, channel, 0);
dsi_if_enable(dsi, 0);
REG_FLD_MOD(dsi, DSI_VC_CTRL(channel), enable, 9, 9);
dsi_vc_enable(dsi, channel, 1);
dsi_if_enable(dsi, 1);
dsi_force_tx_stop_mode_io(dsi);
/* start the DDR clock by sending a NULL packet */
if (dsi->vm_timings.ddr_clk_always_on && enable)
dsi_vc_send_null(dsi, channel);
}
static void dsi_vc_flush_long_data(struct dsi_data *dsi, int channel)
{
while (REG_GET(dsi, DSI_VC_CTRL(channel), 20, 20)) {
u32 val;
val = dsi_read_reg(dsi, DSI_VC_SHORT_PACKET_HEADER(channel));
DSSDBG("\t\tb1 %#02x b2 %#02x b3 %#02x b4 %#02x\n",
(val >> 0) & 0xff,
(val >> 8) & 0xff,
(val >> 16) & 0xff,
(val >> 24) & 0xff);
}
}
static void dsi_show_rx_ack_with_err(u16 err)
{
DSSERR("\tACK with ERROR (%#x):\n", err);
if (err & (1 << 0))
DSSERR("\t\tSoT Error\n");
if (err & (1 << 1))
DSSERR("\t\tSoT Sync Error\n");
if (err & (1 << 2))
DSSERR("\t\tEoT Sync Error\n");
if (err & (1 << 3))
DSSERR("\t\tEscape Mode Entry Command Error\n");
if (err & (1 << 4))
DSSERR("\t\tLP Transmit Sync Error\n");
if (err & (1 << 5))
DSSERR("\t\tHS Receive Timeout Error\n");
if (err & (1 << 6))
DSSERR("\t\tFalse Control Error\n");
if (err & (1 << 7))
DSSERR("\t\t(reserved7)\n");
if (err & (1 << 8))
DSSERR("\t\tECC Error, single-bit (corrected)\n");
if (err & (1 << 9))
DSSERR("\t\tECC Error, multi-bit (not corrected)\n");
if (err & (1 << 10))
DSSERR("\t\tChecksum Error\n");
if (err & (1 << 11))
DSSERR("\t\tData type not recognized\n");
if (err & (1 << 12))
DSSERR("\t\tInvalid VC ID\n");
if (err & (1 << 13))
DSSERR("\t\tInvalid Transmission Length\n");
if (err & (1 << 14))
DSSERR("\t\t(reserved14)\n");
if (err & (1 << 15))
DSSERR("\t\tDSI Protocol Violation\n");
}
static u16 dsi_vc_flush_receive_data(struct dsi_data *dsi, int channel)
{
/* RX_FIFO_NOT_EMPTY */
while (REG_GET(dsi, DSI_VC_CTRL(channel), 20, 20)) {
u32 val;
u8 dt;
val = dsi_read_reg(dsi, DSI_VC_SHORT_PACKET_HEADER(channel));
DSSERR("\trawval %#08x\n", val);
dt = FLD_GET(val, 5, 0);
if (dt == MIPI_DSI_RX_ACKNOWLEDGE_AND_ERROR_REPORT) {
u16 err = FLD_GET(val, 23, 8);
dsi_show_rx_ack_with_err(err);
} else if (dt == MIPI_DSI_RX_DCS_SHORT_READ_RESPONSE_1BYTE) {
DSSERR("\tDCS short response, 1 byte: %#x\n",
FLD_GET(val, 23, 8));
} else if (dt == MIPI_DSI_RX_DCS_SHORT_READ_RESPONSE_2BYTE) {
DSSERR("\tDCS short response, 2 byte: %#x\n",
FLD_GET(val, 23, 8));
} else if (dt == MIPI_DSI_RX_DCS_LONG_READ_RESPONSE) {
DSSERR("\tDCS long response, len %d\n",
FLD_GET(val, 23, 8));
dsi_vc_flush_long_data(dsi, channel);
} else {
DSSERR("\tunknown datatype 0x%02x\n", dt);
}
}
return 0;
}
static int dsi_vc_send_bta(struct dsi_data *dsi, int channel)
{
if (dsi->debug_write || dsi->debug_read)
DSSDBG("dsi_vc_send_bta %d\n", channel);
WARN_ON(!dsi_bus_is_locked(dsi));
/* RX_FIFO_NOT_EMPTY */
if (REG_GET(dsi, DSI_VC_CTRL(channel), 20, 20)) {
DSSERR("rx fifo not empty when sending BTA, dumping data:\n");
dsi_vc_flush_receive_data(dsi, channel);
}
REG_FLD_MOD(dsi, DSI_VC_CTRL(channel), 1, 6, 6); /* BTA_EN */
/* flush posted write */
dsi_read_reg(dsi, DSI_VC_CTRL(channel));
return 0;
}
static int dsi_vc_send_bta_sync(struct omap_dss_device *dssdev, int channel)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
DECLARE_COMPLETION_ONSTACK(completion);
int r = 0;
u32 err;
r = dsi_register_isr_vc(dsi, channel, dsi_completion_handler,
&completion, DSI_VC_IRQ_BTA);
if (r)
goto err0;
r = dsi_register_isr(dsi, dsi_completion_handler, &completion,
DSI_IRQ_ERROR_MASK);
if (r)
goto err1;
r = dsi_vc_send_bta(dsi, channel);
if (r)
goto err2;
if (wait_for_completion_timeout(&completion,
msecs_to_jiffies(500)) == 0) {
DSSERR("Failed to receive BTA\n");
r = -EIO;
goto err2;
}
err = dsi_get_errors(dsi);
if (err) {
DSSERR("Error while sending BTA: %x\n", err);
r = -EIO;
goto err2;
}
err2:
dsi_unregister_isr(dsi, dsi_completion_handler, &completion,
DSI_IRQ_ERROR_MASK);
err1:
dsi_unregister_isr_vc(dsi, channel, dsi_completion_handler,
&completion, DSI_VC_IRQ_BTA);
err0:
return r;
}
static inline void dsi_vc_write_long_header(struct dsi_data *dsi, int channel,
u8 data_type, u16 len, u8 ecc)
{
u32 val;
u8 data_id;
WARN_ON(!dsi_bus_is_locked(dsi));
data_id = data_type | dsi->vc[channel].vc_id << 6;
val = FLD_VAL(data_id, 7, 0) | FLD_VAL(len, 23, 8) |
FLD_VAL(ecc, 31, 24);
dsi_write_reg(dsi, DSI_VC_LONG_PACKET_HEADER(channel), val);
}
static inline void dsi_vc_write_long_payload(struct dsi_data *dsi, int channel,
u8 b1, u8 b2, u8 b3, u8 b4)
{
u32 val;
val = b4 << 24 | b3 << 16 | b2 << 8 | b1 << 0;
/* DSSDBG("\twriting %02x, %02x, %02x, %02x (%#010x)\n",
b1, b2, b3, b4, val); */
dsi_write_reg(dsi, DSI_VC_LONG_PACKET_PAYLOAD(channel), val);
}
static int dsi_vc_send_long(struct dsi_data *dsi, int channel, u8 data_type,
u8 *data, u16 len, u8 ecc)
{
/*u32 val; */
int i;
u8 *p;
int r = 0;
u8 b1, b2, b3, b4;
if (dsi->debug_write)
DSSDBG("dsi_vc_send_long, %d bytes\n", len);
/* len + header */
if (dsi->vc[channel].tx_fifo_size * 32 * 4 < len + 4) {
DSSERR("unable to send long packet: packet too long.\n");
return -EINVAL;
}
dsi_vc_config_source(dsi, channel, DSI_VC_SOURCE_L4);
dsi_vc_write_long_header(dsi, channel, data_type, len, ecc);
p = data;
for (i = 0; i < len >> 2; i++) {
if (dsi->debug_write)
DSSDBG("\tsending full packet %d\n", i);
b1 = *p++;
b2 = *p++;
b3 = *p++;
b4 = *p++;
dsi_vc_write_long_payload(dsi, channel, b1, b2, b3, b4);
}
i = len % 4;
if (i) {
b1 = 0; b2 = 0; b3 = 0;
if (dsi->debug_write)
DSSDBG("\tsending remainder bytes %d\n", i);
switch (i) {
case 3:
b1 = *p++;
b2 = *p++;
b3 = *p++;
break;
case 2:
b1 = *p++;
b2 = *p++;
break;
case 1:
b1 = *p++;
break;
}
dsi_vc_write_long_payload(dsi, channel, b1, b2, b3, 0);
}
return r;
}
static int dsi_vc_send_short(struct dsi_data *dsi, int channel, u8 data_type,
u16 data, u8 ecc)
{
u32 r;
u8 data_id;
WARN_ON(!dsi_bus_is_locked(dsi));
if (dsi->debug_write)
DSSDBG("dsi_vc_send_short(ch%d, dt %#x, b1 %#x, b2 %#x)\n",
channel,
data_type, data & 0xff, (data >> 8) & 0xff);
dsi_vc_config_source(dsi, channel, DSI_VC_SOURCE_L4);
if (FLD_GET(dsi_read_reg(dsi, DSI_VC_CTRL(channel)), 16, 16)) {
DSSERR("ERROR FIFO FULL, aborting transfer\n");
return -EINVAL;
}
data_id = data_type | dsi->vc[channel].vc_id << 6;
r = (data_id << 0) | (data << 8) | (ecc << 24);
dsi_write_reg(dsi, DSI_VC_SHORT_PACKET_HEADER(channel), r);
return 0;
}
static int dsi_vc_send_null(struct dsi_data *dsi, int channel)
{
return dsi_vc_send_long(dsi, channel, MIPI_DSI_NULL_PACKET, NULL, 0, 0);
}
static int dsi_vc_write_nosync_common(struct dsi_data *dsi, int channel,
u8 *data, int len,
enum dss_dsi_content_type type)
{
int r;
if (len == 0) {
BUG_ON(type == DSS_DSI_CONTENT_DCS);
r = dsi_vc_send_short(dsi, channel,
MIPI_DSI_GENERIC_SHORT_WRITE_0_PARAM, 0, 0);
} else if (len == 1) {
r = dsi_vc_send_short(dsi, channel,
type == DSS_DSI_CONTENT_GENERIC ?
MIPI_DSI_GENERIC_SHORT_WRITE_1_PARAM :
MIPI_DSI_DCS_SHORT_WRITE, data[0], 0);
} else if (len == 2) {
r = dsi_vc_send_short(dsi, channel,
type == DSS_DSI_CONTENT_GENERIC ?
MIPI_DSI_GENERIC_SHORT_WRITE_2_PARAM :
MIPI_DSI_DCS_SHORT_WRITE_PARAM,
data[0] | (data[1] << 8), 0);
} else {
r = dsi_vc_send_long(dsi, channel,
type == DSS_DSI_CONTENT_GENERIC ?
MIPI_DSI_GENERIC_LONG_WRITE :
MIPI_DSI_DCS_LONG_WRITE, data, len, 0);
}
return r;
}
static int dsi_vc_dcs_write_nosync(struct omap_dss_device *dssdev, int channel,
u8 *data, int len)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
return dsi_vc_write_nosync_common(dsi, channel, data, len,
DSS_DSI_CONTENT_DCS);
}
static int dsi_vc_generic_write_nosync(struct omap_dss_device *dssdev, int channel,
u8 *data, int len)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
return dsi_vc_write_nosync_common(dsi, channel, data, len,
DSS_DSI_CONTENT_GENERIC);
}
static int dsi_vc_write_common(struct omap_dss_device *dssdev,
int channel, u8 *data, int len,
enum dss_dsi_content_type type)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
int r;
r = dsi_vc_write_nosync_common(dsi, channel, data, len, type);
if (r)
goto err;
r = dsi_vc_send_bta_sync(dssdev, channel);
if (r)
goto err;
/* RX_FIFO_NOT_EMPTY */
if (REG_GET(dsi, DSI_VC_CTRL(channel), 20, 20)) {
DSSERR("rx fifo not empty after write, dumping data:\n");
dsi_vc_flush_receive_data(dsi, channel);
r = -EIO;
goto err;
}
return 0;
err:
DSSERR("dsi_vc_write_common(ch %d, cmd 0x%02x, len %d) failed\n",
channel, data[0], len);
return r;
}
static int dsi_vc_dcs_write(struct omap_dss_device *dssdev, int channel, u8 *data,
int len)
{
return dsi_vc_write_common(dssdev, channel, data, len,
DSS_DSI_CONTENT_DCS);
}
static int dsi_vc_generic_write(struct omap_dss_device *dssdev, int channel, u8 *data,
int len)
{
return dsi_vc_write_common(dssdev, channel, data, len,
DSS_DSI_CONTENT_GENERIC);
}
static int dsi_vc_dcs_send_read_request(struct dsi_data *dsi, int channel,
u8 dcs_cmd)
{
int r;
if (dsi->debug_read)
DSSDBG("dsi_vc_dcs_send_read_request(ch%d, dcs_cmd %x)\n",
channel, dcs_cmd);
r = dsi_vc_send_short(dsi, channel, MIPI_DSI_DCS_READ, dcs_cmd, 0);
if (r) {
DSSERR("dsi_vc_dcs_send_read_request(ch %d, cmd 0x%02x)"
" failed\n", channel, dcs_cmd);
return r;
}
return 0;
}
static int dsi_vc_generic_send_read_request(struct dsi_data *dsi, int channel,
u8 *reqdata, int reqlen)
{
u16 data;
u8 data_type;
int r;
if (dsi->debug_read)
DSSDBG("dsi_vc_generic_send_read_request(ch %d, reqlen %d)\n",
channel, reqlen);
if (reqlen == 0) {
data_type = MIPI_DSI_GENERIC_READ_REQUEST_0_PARAM;
data = 0;
} else if (reqlen == 1) {
data_type = MIPI_DSI_GENERIC_READ_REQUEST_1_PARAM;
data = reqdata[0];
} else if (reqlen == 2) {
data_type = MIPI_DSI_GENERIC_READ_REQUEST_2_PARAM;
data = reqdata[0] | (reqdata[1] << 8);
} else {
BUG();
return -EINVAL;
}
r = dsi_vc_send_short(dsi, channel, data_type, data, 0);
if (r) {
DSSERR("dsi_vc_generic_send_read_request(ch %d, reqlen %d)"
" failed\n", channel, reqlen);
return r;
}
return 0;
}
static int dsi_vc_read_rx_fifo(struct dsi_data *dsi, int channel, u8 *buf,
int buflen, enum dss_dsi_content_type type)
{
u32 val;
u8 dt;
int r;
/* RX_FIFO_NOT_EMPTY */
if (REG_GET(dsi, DSI_VC_CTRL(channel), 20, 20) == 0) {
DSSERR("RX fifo empty when trying to read.\n");
r = -EIO;
goto err;
}
val = dsi_read_reg(dsi, DSI_VC_SHORT_PACKET_HEADER(channel));
if (dsi->debug_read)
DSSDBG("\theader: %08x\n", val);
dt = FLD_GET(val, 5, 0);
if (dt == MIPI_DSI_RX_ACKNOWLEDGE_AND_ERROR_REPORT) {
u16 err = FLD_GET(val, 23, 8);
dsi_show_rx_ack_with_err(err);
r = -EIO;
goto err;
} else if (dt == (type == DSS_DSI_CONTENT_GENERIC ?
MIPI_DSI_RX_GENERIC_SHORT_READ_RESPONSE_1BYTE :
MIPI_DSI_RX_DCS_SHORT_READ_RESPONSE_1BYTE)) {
u8 data = FLD_GET(val, 15, 8);
if (dsi->debug_read)
DSSDBG("\t%s short response, 1 byte: %02x\n",
type == DSS_DSI_CONTENT_GENERIC ? "GENERIC" :
"DCS", data);
if (buflen < 1) {
r = -EIO;
goto err;
}
buf[0] = data;
return 1;
} else if (dt == (type == DSS_DSI_CONTENT_GENERIC ?
MIPI_DSI_RX_GENERIC_SHORT_READ_RESPONSE_2BYTE :
MIPI_DSI_RX_DCS_SHORT_READ_RESPONSE_2BYTE)) {
u16 data = FLD_GET(val, 23, 8);
if (dsi->debug_read)
DSSDBG("\t%s short response, 2 byte: %04x\n",
type == DSS_DSI_CONTENT_GENERIC ? "GENERIC" :
"DCS", data);
if (buflen < 2) {
r = -EIO;
goto err;
}
buf[0] = data & 0xff;
buf[1] = (data >> 8) & 0xff;
return 2;
} else if (dt == (type == DSS_DSI_CONTENT_GENERIC ?
MIPI_DSI_RX_GENERIC_LONG_READ_RESPONSE :
MIPI_DSI_RX_DCS_LONG_READ_RESPONSE)) {
int w;
int len = FLD_GET(val, 23, 8);
if (dsi->debug_read)
DSSDBG("\t%s long response, len %d\n",
type == DSS_DSI_CONTENT_GENERIC ? "GENERIC" :
"DCS", len);
if (len > buflen) {
r = -EIO;
goto err;
}
/* two byte checksum ends the packet, not included in len */
for (w = 0; w < len + 2;) {
int b;
val = dsi_read_reg(dsi,
DSI_VC_SHORT_PACKET_HEADER(channel));
if (dsi->debug_read)
DSSDBG("\t\t%02x %02x %02x %02x\n",
(val >> 0) & 0xff,
(val >> 8) & 0xff,
(val >> 16) & 0xff,
(val >> 24) & 0xff);
for (b = 0; b < 4; ++b) {
if (w < len)
buf[w] = (val >> (b * 8)) & 0xff;
/* we discard the 2 byte checksum */
++w;
}
}
return len;
} else {
DSSERR("\tunknown datatype 0x%02x\n", dt);
r = -EIO;
goto err;
}
err:
DSSERR("dsi_vc_read_rx_fifo(ch %d type %s) failed\n", channel,
type == DSS_DSI_CONTENT_GENERIC ? "GENERIC" : "DCS");
return r;
}
static int dsi_vc_dcs_read(struct omap_dss_device *dssdev, int channel, u8 dcs_cmd,
u8 *buf, int buflen)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
int r;
r = dsi_vc_dcs_send_read_request(dsi, channel, dcs_cmd);
if (r)
goto err;
r = dsi_vc_send_bta_sync(dssdev, channel);
if (r)
goto err;
r = dsi_vc_read_rx_fifo(dsi, channel, buf, buflen,
DSS_DSI_CONTENT_DCS);
if (r < 0)
goto err;
if (r != buflen) {
r = -EIO;
goto err;
}
return 0;
err:
DSSERR("dsi_vc_dcs_read(ch %d, cmd 0x%02x) failed\n", channel, dcs_cmd);
return r;
}
static int dsi_vc_generic_read(struct omap_dss_device *dssdev, int channel,
u8 *reqdata, int reqlen, u8 *buf, int buflen)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
int r;
r = dsi_vc_generic_send_read_request(dsi, channel, reqdata, reqlen);
if (r)
return r;
r = dsi_vc_send_bta_sync(dssdev, channel);
if (r)
return r;
r = dsi_vc_read_rx_fifo(dsi, channel, buf, buflen,
DSS_DSI_CONTENT_GENERIC);
if (r < 0)
return r;
if (r != buflen) {
r = -EIO;
return r;
}
return 0;
}
static int dsi_vc_set_max_rx_packet_size(struct omap_dss_device *dssdev, int channel,
u16 len)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
return dsi_vc_send_short(dsi, channel,
MIPI_DSI_SET_MAXIMUM_RETURN_PACKET_SIZE, len, 0);
}
static int dsi_enter_ulps(struct dsi_data *dsi)
{
DECLARE_COMPLETION_ONSTACK(completion);
int r, i;
unsigned int mask;
DSSDBG("Entering ULPS");
WARN_ON(!dsi_bus_is_locked(dsi));
WARN_ON(dsi->ulps_enabled);
if (dsi->ulps_enabled)
return 0;
/* DDR_CLK_ALWAYS_ON */
if (REG_GET(dsi, DSI_CLK_CTRL, 13, 13)) {
dsi_if_enable(dsi, 0);
REG_FLD_MOD(dsi, DSI_CLK_CTRL, 0, 13, 13);
dsi_if_enable(dsi, 1);
}
dsi_sync_vc(dsi, 0);
dsi_sync_vc(dsi, 1);
dsi_sync_vc(dsi, 2);
dsi_sync_vc(dsi, 3);
dsi_force_tx_stop_mode_io(dsi);
dsi_vc_enable(dsi, 0, false);
dsi_vc_enable(dsi, 1, false);
dsi_vc_enable(dsi, 2, false);
dsi_vc_enable(dsi, 3, false);
if (REG_GET(dsi, DSI_COMPLEXIO_CFG2, 16, 16)) { /* HS_BUSY */
DSSERR("HS busy when enabling ULPS\n");
return -EIO;
}
if (REG_GET(dsi, DSI_COMPLEXIO_CFG2, 17, 17)) { /* LP_BUSY */
DSSERR("LP busy when enabling ULPS\n");
return -EIO;
}
r = dsi_register_isr_cio(dsi, dsi_completion_handler, &completion,
DSI_CIO_IRQ_ULPSACTIVENOT_ALL0);
if (r)
return r;
mask = 0;
for (i = 0; i < dsi->num_lanes_supported; ++i) {
if (dsi->lanes[i].function == DSI_LANE_UNUSED)
continue;
mask |= 1 << i;
}
/* Assert TxRequestEsc for data lanes and TxUlpsClk for clk lane */
/* LANEx_ULPS_SIG2 */
REG_FLD_MOD(dsi, DSI_COMPLEXIO_CFG2, mask, 9, 5);
/* flush posted write and wait for SCP interface to finish the write */
dsi_read_reg(dsi, DSI_COMPLEXIO_CFG2);
if (wait_for_completion_timeout(&completion,
msecs_to_jiffies(1000)) == 0) {
DSSERR("ULPS enable timeout\n");
r = -EIO;
goto err;
}
dsi_unregister_isr_cio(dsi, dsi_completion_handler, &completion,
DSI_CIO_IRQ_ULPSACTIVENOT_ALL0);
/* Reset LANEx_ULPS_SIG2 */
REG_FLD_MOD(dsi, DSI_COMPLEXIO_CFG2, 0, 9, 5);
/* flush posted write and wait for SCP interface to finish the write */
dsi_read_reg(dsi, DSI_COMPLEXIO_CFG2);
dsi_cio_power(dsi, DSI_COMPLEXIO_POWER_ULPS);
dsi_if_enable(dsi, false);
dsi->ulps_enabled = true;
return 0;
err:
dsi_unregister_isr_cio(dsi, dsi_completion_handler, &completion,
DSI_CIO_IRQ_ULPSACTIVENOT_ALL0);
return r;
}
static void dsi_set_lp_rx_timeout(struct dsi_data *dsi, unsigned int ticks,
bool x4, bool x16)
{
unsigned long fck;
unsigned long total_ticks;
u32 r;
BUG_ON(ticks > 0x1fff);
/* ticks in DSI_FCK */
fck = dsi_fclk_rate(dsi);
r = dsi_read_reg(dsi, DSI_TIMING2);
r = FLD_MOD(r, 1, 15, 15); /* LP_RX_TO */
r = FLD_MOD(r, x16 ? 1 : 0, 14, 14); /* LP_RX_TO_X16 */
r = FLD_MOD(r, x4 ? 1 : 0, 13, 13); /* LP_RX_TO_X4 */
r = FLD_MOD(r, ticks, 12, 0); /* LP_RX_COUNTER */
dsi_write_reg(dsi, DSI_TIMING2, r);
total_ticks = ticks * (x16 ? 16 : 1) * (x4 ? 4 : 1);
DSSDBG("LP_RX_TO %lu ticks (%#x%s%s) = %lu ns\n",
total_ticks,
ticks, x4 ? " x4" : "", x16 ? " x16" : "",
(total_ticks * 1000) / (fck / 1000 / 1000));
}
static void dsi_set_ta_timeout(struct dsi_data *dsi, unsigned int ticks,
bool x8, bool x16)
{
unsigned long fck;
unsigned long total_ticks;
u32 r;
BUG_ON(ticks > 0x1fff);
/* ticks in DSI_FCK */
fck = dsi_fclk_rate(dsi);
r = dsi_read_reg(dsi, DSI_TIMING1);
r = FLD_MOD(r, 1, 31, 31); /* TA_TO */
r = FLD_MOD(r, x16 ? 1 : 0, 30, 30); /* TA_TO_X16 */
r = FLD_MOD(r, x8 ? 1 : 0, 29, 29); /* TA_TO_X8 */
r = FLD_MOD(r, ticks, 28, 16); /* TA_TO_COUNTER */
dsi_write_reg(dsi, DSI_TIMING1, r);
total_ticks = ticks * (x16 ? 16 : 1) * (x8 ? 8 : 1);
DSSDBG("TA_TO %lu ticks (%#x%s%s) = %lu ns\n",
total_ticks,
ticks, x8 ? " x8" : "", x16 ? " x16" : "",
(total_ticks * 1000) / (fck / 1000 / 1000));
}
static void dsi_set_stop_state_counter(struct dsi_data *dsi, unsigned int ticks,
bool x4, bool x16)
{
unsigned long fck;
unsigned long total_ticks;
u32 r;
BUG_ON(ticks > 0x1fff);
/* ticks in DSI_FCK */
fck = dsi_fclk_rate(dsi);
r = dsi_read_reg(dsi, DSI_TIMING1);
r = FLD_MOD(r, 1, 15, 15); /* FORCE_TX_STOP_MODE_IO */
r = FLD_MOD(r, x16 ? 1 : 0, 14, 14); /* STOP_STATE_X16_IO */
r = FLD_MOD(r, x4 ? 1 : 0, 13, 13); /* STOP_STATE_X4_IO */
r = FLD_MOD(r, ticks, 12, 0); /* STOP_STATE_COUNTER_IO */
dsi_write_reg(dsi, DSI_TIMING1, r);
total_ticks = ticks * (x16 ? 16 : 1) * (x4 ? 4 : 1);
DSSDBG("STOP_STATE_COUNTER %lu ticks (%#x%s%s) = %lu ns\n",
total_ticks,
ticks, x4 ? " x4" : "", x16 ? " x16" : "",
(total_ticks * 1000) / (fck / 1000 / 1000));
}
static void dsi_set_hs_tx_timeout(struct dsi_data *dsi, unsigned int ticks,
bool x4, bool x16)
{
unsigned long fck;
unsigned long total_ticks;
u32 r;
BUG_ON(ticks > 0x1fff);
/* ticks in TxByteClkHS */
fck = dsi_get_txbyteclkhs(dsi);
r = dsi_read_reg(dsi, DSI_TIMING2);
r = FLD_MOD(r, 1, 31, 31); /* HS_TX_TO */
r = FLD_MOD(r, x16 ? 1 : 0, 30, 30); /* HS_TX_TO_X16 */
r = FLD_MOD(r, x4 ? 1 : 0, 29, 29); /* HS_TX_TO_X8 (4 really) */
r = FLD_MOD(r, ticks, 28, 16); /* HS_TX_TO_COUNTER */
dsi_write_reg(dsi, DSI_TIMING2, r);
total_ticks = ticks * (x16 ? 16 : 1) * (x4 ? 4 : 1);
DSSDBG("HS_TX_TO %lu ticks (%#x%s%s) = %lu ns\n",
total_ticks,
ticks, x4 ? " x4" : "", x16 ? " x16" : "",
(total_ticks * 1000) / (fck / 1000 / 1000));
}
static void dsi_config_vp_num_line_buffers(struct dsi_data *dsi)
{
int num_line_buffers;
if (dsi->mode == OMAP_DSS_DSI_VIDEO_MODE) {
int bpp = dsi_get_pixel_size(dsi->pix_fmt);
const struct videomode *vm = &dsi->vm;
/*
* Don't use line buffers if width is greater than the video
* port's line buffer size
*/
if (dsi->line_buffer_size <= vm->hactive * bpp / 8)
num_line_buffers = 0;
else
num_line_buffers = 2;
} else {
/* Use maximum number of line buffers in command mode */
num_line_buffers = 2;
}
/* LINE_BUFFER */
REG_FLD_MOD(dsi, DSI_CTRL, num_line_buffers, 13, 12);
}
static void dsi_config_vp_sync_events(struct dsi_data *dsi)
{
bool sync_end;
u32 r;
if (dsi->vm_timings.trans_mode == OMAP_DSS_DSI_PULSE_MODE)
sync_end = true;
else
sync_end = false;
r = dsi_read_reg(dsi, DSI_CTRL);
r = FLD_MOD(r, 1, 9, 9); /* VP_DE_POL */
r = FLD_MOD(r, 1, 10, 10); /* VP_HSYNC_POL */
r = FLD_MOD(r, 1, 11, 11); /* VP_VSYNC_POL */
r = FLD_MOD(r, 1, 15, 15); /* VP_VSYNC_START */
r = FLD_MOD(r, sync_end, 16, 16); /* VP_VSYNC_END */
r = FLD_MOD(r, 1, 17, 17); /* VP_HSYNC_START */
r = FLD_MOD(r, sync_end, 18, 18); /* VP_HSYNC_END */
dsi_write_reg(dsi, DSI_CTRL, r);
}
static void dsi_config_blanking_modes(struct dsi_data *dsi)
{
int blanking_mode = dsi->vm_timings.blanking_mode;
int hfp_blanking_mode = dsi->vm_timings.hfp_blanking_mode;
int hbp_blanking_mode = dsi->vm_timings.hbp_blanking_mode;
int hsa_blanking_mode = dsi->vm_timings.hsa_blanking_mode;
u32 r;
/*
* 0 = TX FIFO packets sent or LPS in corresponding blanking periods
* 1 = Long blanking packets are sent in corresponding blanking periods
*/
r = dsi_read_reg(dsi, DSI_CTRL);
r = FLD_MOD(r, blanking_mode, 20, 20); /* BLANKING_MODE */
r = FLD_MOD(r, hfp_blanking_mode, 21, 21); /* HFP_BLANKING */
r = FLD_MOD(r, hbp_blanking_mode, 22, 22); /* HBP_BLANKING */
r = FLD_MOD(r, hsa_blanking_mode, 23, 23); /* HSA_BLANKING */
dsi_write_reg(dsi, DSI_CTRL, r);
}
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
/*
* According to section 'HS Command Mode Interleaving' in OMAP TRM, Scenario 3
* results in maximum transition time for data and clock lanes to enter and
* exit HS mode. Hence, this is the scenario where the least amount of command
* mode data can be interleaved. We program the minimum amount of TXBYTECLKHS
* clock cycles that can be used to interleave command mode data in HS so that
* all scenarios are satisfied.
*/
static int dsi_compute_interleave_hs(int blank, bool ddr_alwon, int enter_hs,
int exit_hs, int exiths_clk, int ddr_pre, int ddr_post)
{
int transition;
/*
* If DDR_CLK_ALWAYS_ON is set, we need to consider HS mode transition
* time of data lanes only, if it isn't set, we need to consider HS
* transition time of both data and clock lanes. HS transition time
* of Scenario 3 is considered.
*/
if (ddr_alwon) {
transition = enter_hs + exit_hs + max(enter_hs, 2) + 1;
} else {
int trans1, trans2;
trans1 = ddr_pre + enter_hs + exit_hs + max(enter_hs, 2) + 1;
trans2 = ddr_pre + enter_hs + exiths_clk + ddr_post + ddr_pre +
enter_hs + 1;
transition = max(trans1, trans2);
}
return blank > transition ? blank - transition : 0;
}
/*
* According to section 'LP Command Mode Interleaving' in OMAP TRM, Scenario 1
* results in maximum transition time for data lanes to enter and exit LP mode.
* Hence, this is the scenario where the least amount of command mode data can
* be interleaved. We program the minimum amount of bytes that can be
* interleaved in LP so that all scenarios are satisfied.
*/
static int dsi_compute_interleave_lp(int blank, int enter_hs, int exit_hs,
int lp_clk_div, int tdsi_fclk)
{
int trans_lp; /* time required for a LP transition, in TXBYTECLKHS */
int tlp_avail; /* time left for interleaving commands, in CLKIN4DDR */
int ttxclkesc; /* period of LP transmit escape clock, in CLKIN4DDR */
int thsbyte_clk = 16; /* Period of TXBYTECLKHS clock, in CLKIN4DDR */
int lp_inter; /* cmd mode data that can be interleaved, in bytes */
/* maximum LP transition time according to Scenario 1 */
trans_lp = exit_hs + max(enter_hs, 2) + 1;
/* CLKIN4DDR = 16 * TXBYTECLKHS */
tlp_avail = thsbyte_clk * (blank - trans_lp);
ttxclkesc = tdsi_fclk * lp_clk_div;
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
lp_inter = ((tlp_avail - 8 * thsbyte_clk - 5 * tdsi_fclk) / ttxclkesc -
26) / 16;
return max(lp_inter, 0);
}
static void dsi_config_cmd_mode_interleaving(struct dsi_data *dsi)
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
{
int blanking_mode;
int hfp_blanking_mode, hbp_blanking_mode, hsa_blanking_mode;
int hsa, hfp, hbp, width_bytes, bllp, lp_clk_div;
int ddr_clk_pre, ddr_clk_post, enter_hs_mode_lat, exit_hs_mode_lat;
int tclk_trail, ths_exit, exiths_clk;
bool ddr_alwon;
const struct videomode *vm = &dsi->vm;
int bpp = dsi_get_pixel_size(dsi->pix_fmt);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
int ndl = dsi->num_lanes_used - 1;
int dsi_fclk_hsdiv = dsi->user_dsi_cinfo.mX[HSDIV_DSI] + 1;
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
int hsa_interleave_hs = 0, hsa_interleave_lp = 0;
int hfp_interleave_hs = 0, hfp_interleave_lp = 0;
int hbp_interleave_hs = 0, hbp_interleave_lp = 0;
int bl_interleave_hs = 0, bl_interleave_lp = 0;
u32 r;
r = dsi_read_reg(dsi, DSI_CTRL);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
blanking_mode = FLD_GET(r, 20, 20);
hfp_blanking_mode = FLD_GET(r, 21, 21);
hbp_blanking_mode = FLD_GET(r, 22, 22);
hsa_blanking_mode = FLD_GET(r, 23, 23);
r = dsi_read_reg(dsi, DSI_VM_TIMING1);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
hbp = FLD_GET(r, 11, 0);
hfp = FLD_GET(r, 23, 12);
hsa = FLD_GET(r, 31, 24);
r = dsi_read_reg(dsi, DSI_CLK_TIMING);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
ddr_clk_post = FLD_GET(r, 7, 0);
ddr_clk_pre = FLD_GET(r, 15, 8);
r = dsi_read_reg(dsi, DSI_VM_TIMING7);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
exit_hs_mode_lat = FLD_GET(r, 15, 0);
enter_hs_mode_lat = FLD_GET(r, 31, 16);
r = dsi_read_reg(dsi, DSI_CLK_CTRL);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
lp_clk_div = FLD_GET(r, 12, 0);
ddr_alwon = FLD_GET(r, 13, 13);
r = dsi_read_reg(dsi, DSI_DSIPHY_CFG0);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
ths_exit = FLD_GET(r, 7, 0);
r = dsi_read_reg(dsi, DSI_DSIPHY_CFG1);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
tclk_trail = FLD_GET(r, 15, 8);
exiths_clk = ths_exit + tclk_trail;
width_bytes = DIV_ROUND_UP(vm->hactive * bpp, 8);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
bllp = hbp + hfp + hsa + DIV_ROUND_UP(width_bytes + 6, ndl);
if (!hsa_blanking_mode) {
hsa_interleave_hs = dsi_compute_interleave_hs(hsa, ddr_alwon,
enter_hs_mode_lat, exit_hs_mode_lat,
exiths_clk, ddr_clk_pre, ddr_clk_post);
hsa_interleave_lp = dsi_compute_interleave_lp(hsa,
enter_hs_mode_lat, exit_hs_mode_lat,
lp_clk_div, dsi_fclk_hsdiv);
}
if (!hfp_blanking_mode) {
hfp_interleave_hs = dsi_compute_interleave_hs(hfp, ddr_alwon,
enter_hs_mode_lat, exit_hs_mode_lat,
exiths_clk, ddr_clk_pre, ddr_clk_post);
hfp_interleave_lp = dsi_compute_interleave_lp(hfp,
enter_hs_mode_lat, exit_hs_mode_lat,
lp_clk_div, dsi_fclk_hsdiv);
}
if (!hbp_blanking_mode) {
hbp_interleave_hs = dsi_compute_interleave_hs(hbp, ddr_alwon,
enter_hs_mode_lat, exit_hs_mode_lat,
exiths_clk, ddr_clk_pre, ddr_clk_post);
hbp_interleave_lp = dsi_compute_interleave_lp(hbp,
enter_hs_mode_lat, exit_hs_mode_lat,
lp_clk_div, dsi_fclk_hsdiv);
}
if (!blanking_mode) {
bl_interleave_hs = dsi_compute_interleave_hs(bllp, ddr_alwon,
enter_hs_mode_lat, exit_hs_mode_lat,
exiths_clk, ddr_clk_pre, ddr_clk_post);
bl_interleave_lp = dsi_compute_interleave_lp(bllp,
enter_hs_mode_lat, exit_hs_mode_lat,
lp_clk_div, dsi_fclk_hsdiv);
}
DSSDBG("DSI HS interleaving(TXBYTECLKHS) HSA %d, HFP %d, HBP %d, BLLP %d\n",
hsa_interleave_hs, hfp_interleave_hs, hbp_interleave_hs,
bl_interleave_hs);
DSSDBG("DSI LP interleaving(bytes) HSA %d, HFP %d, HBP %d, BLLP %d\n",
hsa_interleave_lp, hfp_interleave_lp, hbp_interleave_lp,
bl_interleave_lp);
r = dsi_read_reg(dsi, DSI_VM_TIMING4);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
r = FLD_MOD(r, hsa_interleave_hs, 23, 16);
r = FLD_MOD(r, hfp_interleave_hs, 15, 8);
r = FLD_MOD(r, hbp_interleave_hs, 7, 0);
dsi_write_reg(dsi, DSI_VM_TIMING4, r);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
r = dsi_read_reg(dsi, DSI_VM_TIMING5);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
r = FLD_MOD(r, hsa_interleave_lp, 23, 16);
r = FLD_MOD(r, hfp_interleave_lp, 15, 8);
r = FLD_MOD(r, hbp_interleave_lp, 7, 0);
dsi_write_reg(dsi, DSI_VM_TIMING5, r);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
r = dsi_read_reg(dsi, DSI_VM_TIMING6);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
r = FLD_MOD(r, bl_interleave_hs, 31, 15);
r = FLD_MOD(r, bl_interleave_lp, 16, 0);
dsi_write_reg(dsi, DSI_VM_TIMING6, r);
OMAPDSS: DSI: Support command mode interleaving during video mode blanking periods DSI supports interleaving of command mode packets during the HSA, HFP, HBP and BLLP blanking intervals in a video mode stream. This is useful as a user may want to read or change the configuration of a panel without stopping the video stream. On OMAP DSI, we can queue HS or LP command mode packets in the TX FIFO, and the DSI HW takes care of interleaving this data during the one of the blanking intervals. The DSI HW needs to be programmed with the maximum amount of data that can be interleaved in a particular blanking period. A blanking period cannot be used to send command mode data for it's complete duration, there is some amount of time required for the DSI data and clock lanes to transition to the desired LP or HS state. Based on the state of the lanes at the beginning and end of the blanking period, we have different scenarios, with each scenario having a different value of time required to transition to HS or LP. Refer to the section 'Interleaving Mode' in OMAP TRM for more info on the scenarios and the equations to calculate the time required for HS or LP transitions. We use the scenarios which takes the maximum time for HS or LP transition, this gives us the minimum amount of time that can be used to interleave command mode data. The amount of data that can be sent during this minimum time is calculated for command mode packets both in LP and HS. These are written to the registers DSI_VM_TIMING4 to DSI_VM_TIMING6. The calculations don't take into account the time required of transmitting BTA when doing a DSI read, or verifying if a DSI write went through correctly. Until these latencies aren't considered, the behaviour of DSI is unpredictable when a BTA is interleaved during a blanking period. Enhancement of these calculations is a TODO item. The calculations are derived from DSI parameter calculation tools written by Sebastien Fagard <s-fagard@ti.com> Signed-off-by: Archit Taneja <archit@ti.com> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2012-05-15 13:02:18 +07:00
}
static int dsi_proto_config(struct dsi_data *dsi)
{
u32 r;
int buswidth = 0;
dsi_config_tx_fifo(dsi, DSI_FIFO_SIZE_32,
DSI_FIFO_SIZE_32,
DSI_FIFO_SIZE_32,
DSI_FIFO_SIZE_32);
dsi_config_rx_fifo(dsi, DSI_FIFO_SIZE_32,
DSI_FIFO_SIZE_32,
DSI_FIFO_SIZE_32,
DSI_FIFO_SIZE_32);
/* XXX what values for the timeouts? */
dsi_set_stop_state_counter(dsi, 0x1000, false, false);
dsi_set_ta_timeout(dsi, 0x1fff, true, true);
dsi_set_lp_rx_timeout(dsi, 0x1fff, true, true);
dsi_set_hs_tx_timeout(dsi, 0x1fff, true, true);
switch (dsi_get_pixel_size(dsi->pix_fmt)) {
case 16:
buswidth = 0;
break;
case 18:
buswidth = 1;
break;
case 24:
buswidth = 2;
break;
default:
BUG();
return -EINVAL;
}
r = dsi_read_reg(dsi, DSI_CTRL);
r = FLD_MOD(r, 1, 1, 1); /* CS_RX_EN */
r = FLD_MOD(r, 1, 2, 2); /* ECC_RX_EN */
r = FLD_MOD(r, 1, 3, 3); /* TX_FIFO_ARBITRATION */
r = FLD_MOD(r, 1, 4, 4); /* VP_CLK_RATIO, always 1, see errata*/
r = FLD_MOD(r, buswidth, 7, 6); /* VP_DATA_BUS_WIDTH */
r = FLD_MOD(r, 0, 8, 8); /* VP_CLK_POL */
r = FLD_MOD(r, 1, 14, 14); /* TRIGGER_RESET_MODE */
r = FLD_MOD(r, 1, 19, 19); /* EOT_ENABLE */
if (!(dsi->data->quirks & DSI_QUIRK_DCS_CMD_CONFIG_VC)) {
r = FLD_MOD(r, 1, 24, 24); /* DCS_CMD_ENABLE */
/* DCS_CMD_CODE, 1=start, 0=continue */
r = FLD_MOD(r, 0, 25, 25);
}
dsi_write_reg(dsi, DSI_CTRL, r);
dsi_config_vp_num_line_buffers(dsi);
if (dsi->mode == OMAP_DSS_DSI_VIDEO_MODE) {
dsi_config_vp_sync_events(dsi);
dsi_config_blanking_modes(dsi);
dsi_config_cmd_mode_interleaving(dsi);
}
dsi_vc_initial_config(dsi, 0);
dsi_vc_initial_config(dsi, 1);
dsi_vc_initial_config(dsi, 2);
dsi_vc_initial_config(dsi, 3);
return 0;
}
static void dsi_proto_timings(struct dsi_data *dsi)
{
unsigned int tlpx, tclk_zero, tclk_prepare, tclk_trail;
unsigned int tclk_pre, tclk_post;
unsigned int ths_prepare, ths_prepare_ths_zero, ths_zero;
unsigned int ths_trail, ths_exit;
unsigned int ddr_clk_pre, ddr_clk_post;
unsigned int enter_hs_mode_lat, exit_hs_mode_lat;
unsigned int ths_eot;
int ndl = dsi->num_lanes_used - 1;
u32 r;
r = dsi_read_reg(dsi, DSI_DSIPHY_CFG0);
ths_prepare = FLD_GET(r, 31, 24);
ths_prepare_ths_zero = FLD_GET(r, 23, 16);
ths_zero = ths_prepare_ths_zero - ths_prepare;
ths_trail = FLD_GET(r, 15, 8);
ths_exit = FLD_GET(r, 7, 0);
r = dsi_read_reg(dsi, DSI_DSIPHY_CFG1);
tlpx = FLD_GET(r, 20, 16) * 2;
tclk_trail = FLD_GET(r, 15, 8);
tclk_zero = FLD_GET(r, 7, 0);
r = dsi_read_reg(dsi, DSI_DSIPHY_CFG2);
tclk_prepare = FLD_GET(r, 7, 0);
/* min 8*UI */
tclk_pre = 20;
/* min 60ns + 52*UI */
tclk_post = ns2ddr(dsi, 60) + 26;
ths_eot = DIV_ROUND_UP(4, ndl);
ddr_clk_pre = DIV_ROUND_UP(tclk_pre + tlpx + tclk_zero + tclk_prepare,
4);
ddr_clk_post = DIV_ROUND_UP(tclk_post + ths_trail, 4) + ths_eot;
BUG_ON(ddr_clk_pre == 0 || ddr_clk_pre > 255);
BUG_ON(ddr_clk_post == 0 || ddr_clk_post > 255);
r = dsi_read_reg(dsi, DSI_CLK_TIMING);
r = FLD_MOD(r, ddr_clk_pre, 15, 8);
r = FLD_MOD(r, ddr_clk_post, 7, 0);
dsi_write_reg(dsi, DSI_CLK_TIMING, r);
DSSDBG("ddr_clk_pre %u, ddr_clk_post %u\n",
ddr_clk_pre,
ddr_clk_post);
enter_hs_mode_lat = 1 + DIV_ROUND_UP(tlpx, 4) +
DIV_ROUND_UP(ths_prepare, 4) +
DIV_ROUND_UP(ths_zero + 3, 4);
exit_hs_mode_lat = DIV_ROUND_UP(ths_trail + ths_exit, 4) + 1 + ths_eot;
r = FLD_VAL(enter_hs_mode_lat, 31, 16) |
FLD_VAL(exit_hs_mode_lat, 15, 0);
dsi_write_reg(dsi, DSI_VM_TIMING7, r);
DSSDBG("enter_hs_mode_lat %u, exit_hs_mode_lat %u\n",
enter_hs_mode_lat, exit_hs_mode_lat);
if (dsi->mode == OMAP_DSS_DSI_VIDEO_MODE) {
/* TODO: Implement a video mode check_timings function */
int hsa = dsi->vm_timings.hsa;
int hfp = dsi->vm_timings.hfp;
int hbp = dsi->vm_timings.hbp;
int vsa = dsi->vm_timings.vsa;
int vfp = dsi->vm_timings.vfp;
int vbp = dsi->vm_timings.vbp;
int window_sync = dsi->vm_timings.window_sync;
bool hsync_end;
const struct videomode *vm = &dsi->vm;
int bpp = dsi_get_pixel_size(dsi->pix_fmt);
int tl, t_he, width_bytes;
hsync_end = dsi->vm_timings.trans_mode == OMAP_DSS_DSI_PULSE_MODE;
t_he = hsync_end ?
((hsa == 0 && ndl == 3) ? 1 : DIV_ROUND_UP(4, ndl)) : 0;
width_bytes = DIV_ROUND_UP(vm->hactive * bpp, 8);
/* TL = t_HS + HSA + t_HE + HFP + ceil((WC + 6) / NDL) + HBP */
tl = DIV_ROUND_UP(4, ndl) + (hsync_end ? hsa : 0) + t_he + hfp +
DIV_ROUND_UP(width_bytes + 6, ndl) + hbp;
DSSDBG("HBP: %d, HFP: %d, HSA: %d, TL: %d TXBYTECLKHS\n", hbp,
hfp, hsync_end ? hsa : 0, tl);
DSSDBG("VBP: %d, VFP: %d, VSA: %d, VACT: %d lines\n", vbp, vfp,
vsa, vm->vactive);
r = dsi_read_reg(dsi, DSI_VM_TIMING1);
r = FLD_MOD(r, hbp, 11, 0); /* HBP */
r = FLD_MOD(r, hfp, 23, 12); /* HFP */
r = FLD_MOD(r, hsync_end ? hsa : 0, 31, 24); /* HSA */
dsi_write_reg(dsi, DSI_VM_TIMING1, r);
r = dsi_read_reg(dsi, DSI_VM_TIMING2);
r = FLD_MOD(r, vbp, 7, 0); /* VBP */
r = FLD_MOD(r, vfp, 15, 8); /* VFP */
r = FLD_MOD(r, vsa, 23, 16); /* VSA */
r = FLD_MOD(r, window_sync, 27, 24); /* WINDOW_SYNC */
dsi_write_reg(dsi, DSI_VM_TIMING2, r);
r = dsi_read_reg(dsi, DSI_VM_TIMING3);
r = FLD_MOD(r, vm->vactive, 14, 0); /* VACT */
r = FLD_MOD(r, tl, 31, 16); /* TL */
dsi_write_reg(dsi, DSI_VM_TIMING3, r);
}
}
static int dsi_configure_pins(struct omap_dss_device *dssdev,
const struct omap_dsi_pin_config *pin_cfg)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
int num_pins;
const int *pins;
struct dsi_lane_config lanes[DSI_MAX_NR_LANES];
int num_lanes;
int i;
static const enum dsi_lane_function functions[] = {
DSI_LANE_CLK,
DSI_LANE_DATA1,
DSI_LANE_DATA2,
DSI_LANE_DATA3,
DSI_LANE_DATA4,
};
num_pins = pin_cfg->num_pins;
pins = pin_cfg->pins;
if (num_pins < 4 || num_pins > dsi->num_lanes_supported * 2
|| num_pins % 2 != 0)
return -EINVAL;
for (i = 0; i < DSI_MAX_NR_LANES; ++i)
lanes[i].function = DSI_LANE_UNUSED;
num_lanes = 0;
for (i = 0; i < num_pins; i += 2) {
u8 lane, pol;
int dx, dy;
dx = pins[i];
dy = pins[i + 1];
if (dx < 0 || dx >= dsi->num_lanes_supported * 2)
return -EINVAL;
if (dy < 0 || dy >= dsi->num_lanes_supported * 2)
return -EINVAL;
if (dx & 1) {
if (dy != dx - 1)
return -EINVAL;
pol = 1;
} else {
if (dy != dx + 1)
return -EINVAL;
pol = 0;
}
lane = dx / 2;
lanes[lane].function = functions[i / 2];
lanes[lane].polarity = pol;
num_lanes++;
}
memcpy(dsi->lanes, lanes, sizeof(dsi->lanes));
dsi->num_lanes_used = num_lanes;
return 0;
}
static int dsi_enable_video_output(struct omap_dss_device *dssdev, int channel)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
int bpp = dsi_get_pixel_size(dsi->pix_fmt);
u8 data_type;
u16 word_count;
int r;
r = dsi_display_init_dispc(dsi);
if (r)
return r;
if (dsi->mode == OMAP_DSS_DSI_VIDEO_MODE) {
switch (dsi->pix_fmt) {
case OMAP_DSS_DSI_FMT_RGB888:
data_type = MIPI_DSI_PACKED_PIXEL_STREAM_24;
break;
case OMAP_DSS_DSI_FMT_RGB666:
data_type = MIPI_DSI_PIXEL_STREAM_3BYTE_18;
break;
case OMAP_DSS_DSI_FMT_RGB666_PACKED:
data_type = MIPI_DSI_PACKED_PIXEL_STREAM_18;
break;
case OMAP_DSS_DSI_FMT_RGB565:
data_type = MIPI_DSI_PACKED_PIXEL_STREAM_16;
break;
default:
r = -EINVAL;
goto err_pix_fmt;
}
dsi_if_enable(dsi, false);
dsi_vc_enable(dsi, channel, false);
/* MODE, 1 = video mode */
REG_FLD_MOD(dsi, DSI_VC_CTRL(channel), 1, 4, 4);
word_count = DIV_ROUND_UP(dsi->vm.hactive * bpp, 8);
dsi_vc_write_long_header(dsi, channel, data_type,
word_count, 0);
dsi_vc_enable(dsi, channel, true);
dsi_if_enable(dsi, true);
}
r = dss_mgr_enable(&dsi->output);
if (r)
goto err_mgr_enable;
return 0;
err_mgr_enable:
if (dsi->mode == OMAP_DSS_DSI_VIDEO_MODE) {
dsi_if_enable(dsi, false);
dsi_vc_enable(dsi, channel, false);
}
err_pix_fmt:
dsi_display_uninit_dispc(dsi);
return r;
}
static void dsi_disable_video_output(struct omap_dss_device *dssdev, int channel)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
if (dsi->mode == OMAP_DSS_DSI_VIDEO_MODE) {
dsi_if_enable(dsi, false);
dsi_vc_enable(dsi, channel, false);
/* MODE, 0 = command mode */
REG_FLD_MOD(dsi, DSI_VC_CTRL(channel), 0, 4, 4);
dsi_vc_enable(dsi, channel, true);
dsi_if_enable(dsi, true);
}
dss_mgr_disable(&dsi->output);
dsi_display_uninit_dispc(dsi);
}
static void dsi_update_screen_dispc(struct dsi_data *dsi)
{
unsigned int bytespp;
unsigned int bytespl;
unsigned int bytespf;
unsigned int total_len;
unsigned int packet_payload;
unsigned int packet_len;
u32 l;
int r;
const unsigned channel = dsi->update_channel;
const unsigned int line_buf_size = dsi->line_buffer_size;
u16 w = dsi->vm.hactive;
u16 h = dsi->vm.vactive;
DSSDBG("dsi_update_screen_dispc(%dx%d)\n", w, h);
dsi_vc_config_source(dsi, channel, DSI_VC_SOURCE_VP);
bytespp = dsi_get_pixel_size(dsi->pix_fmt) / 8;
bytespl = w * bytespp;
bytespf = bytespl * h;
/* NOTE: packet_payload has to be equal to N * bytespl, where N is
* number of lines in a packet. See errata about VP_CLK_RATIO */
if (bytespf < line_buf_size)
packet_payload = bytespf;
else
packet_payload = (line_buf_size) / bytespl * bytespl;
packet_len = packet_payload + 1; /* 1 byte for DCS cmd */
total_len = (bytespf / packet_payload) * packet_len;
if (bytespf % packet_payload)
total_len += (bytespf % packet_payload) + 1;
l = FLD_VAL(total_len, 23, 0); /* TE_SIZE */
dsi_write_reg(dsi, DSI_VC_TE(channel), l);
dsi_vc_write_long_header(dsi, channel, MIPI_DSI_DCS_LONG_WRITE,
packet_len, 0);
if (dsi->te_enabled)
l = FLD_MOD(l, 1, 30, 30); /* TE_EN */
else
l = FLD_MOD(l, 1, 31, 31); /* TE_START */
dsi_write_reg(dsi, DSI_VC_TE(channel), l);
/* We put SIDLEMODE to no-idle for the duration of the transfer,
* because DSS interrupts are not capable of waking up the CPU and the
* framedone interrupt could be delayed for quite a long time. I think
* the same goes for any DSS interrupts, but for some reason I have not
* seen the problem anywhere else than here.
*/
dispc_disable_sidle(dsi->dss->dispc);
dsi_perf_mark_start(dsi);
r = schedule_delayed_work(&dsi->framedone_timeout_work,
msecs_to_jiffies(250));
BUG_ON(r == 0);
dss_mgr_start_update(&dsi->output);
if (dsi->te_enabled) {
/* disable LP_RX_TO, so that we can receive TE. Time to wait
* for TE is longer than the timer allows */
REG_FLD_MOD(dsi, DSI_TIMING2, 0, 15, 15); /* LP_RX_TO */
dsi_vc_send_bta(dsi, channel);
#ifdef DSI_CATCH_MISSING_TE
mod_timer(&dsi->te_timer, jiffies + msecs_to_jiffies(250));
#endif
}
}
#ifdef DSI_CATCH_MISSING_TE
treewide: setup_timer() -> timer_setup() This converts all remaining cases of the old setup_timer() API into using timer_setup(), where the callback argument is the structure already holding the struct timer_list. These should have no behavioral changes, since they just change which pointer is passed into the callback with the same available pointers after conversion. It handles the following examples, in addition to some other variations. Casting from unsigned long: void my_callback(unsigned long data) { struct something *ptr = (struct something *)data; ... } ... setup_timer(&ptr->my_timer, my_callback, ptr); and forced object casts: void my_callback(struct something *ptr) { ... } ... setup_timer(&ptr->my_timer, my_callback, (unsigned long)ptr); become: void my_callback(struct timer_list *t) { struct something *ptr = from_timer(ptr, t, my_timer); ... } ... timer_setup(&ptr->my_timer, my_callback, 0); Direct function assignments: void my_callback(unsigned long data) { struct something *ptr = (struct something *)data; ... } ... ptr->my_timer.function = my_callback; have a temporary cast added, along with converting the args: void my_callback(struct timer_list *t) { struct something *ptr = from_timer(ptr, t, my_timer); ... } ... ptr->my_timer.function = (TIMER_FUNC_TYPE)my_callback; And finally, callbacks without a data assignment: void my_callback(unsigned long data) { ... } ... setup_timer(&ptr->my_timer, my_callback, 0); have their argument renamed to verify they're unused during conversion: void my_callback(struct timer_list *unused) { ... } ... timer_setup(&ptr->my_timer, my_callback, 0); The conversion is done with the following Coccinelle script: spatch --very-quiet --all-includes --include-headers \ -I ./arch/x86/include -I ./arch/x86/include/generated \ -I ./include -I ./arch/x86/include/uapi \ -I ./arch/x86/include/generated/uapi -I ./include/uapi \ -I ./include/generated/uapi --include ./include/linux/kconfig.h \ --dir . \ --cocci-file ~/src/data/timer_setup.cocci @fix_address_of@ expression e; @@ setup_timer( -&(e) +&e , ...) // Update any raw setup_timer() usages that have a NULL callback, but // would otherwise match change_timer_function_usage, since the latter // will update all function assignments done in the face of a NULL // function initialization in setup_timer(). @change_timer_function_usage_NULL@ expression _E; identifier _timer; type _cast_data; @@ ( -setup_timer(&_E->_timer, NULL, _E); +timer_setup(&_E->_timer, NULL, 0); | -setup_timer(&_E->_timer, NULL, (_cast_data)_E); +timer_setup(&_E->_timer, NULL, 0); | -setup_timer(&_E._timer, NULL, &_E); +timer_setup(&_E._timer, NULL, 0); | -setup_timer(&_E._timer, NULL, (_cast_data)&_E); +timer_setup(&_E._timer, NULL, 0); ) @change_timer_function_usage@ expression _E; identifier _timer; struct timer_list _stl; identifier _callback; type _cast_func, _cast_data; @@ ( -setup_timer(&_E->_timer, _callback, _E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, &_callback, _E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, _callback, (_cast_data)_E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, &_callback, (_cast_data)_E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, (_cast_func)_callback, _E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, (_cast_func)&_callback, _E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, (_cast_func)_callback, (_cast_data)_E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, (_cast_func)&_callback, (_cast_data)_E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E._timer, _callback, (_cast_data)_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, _callback, (_cast_data)&_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, &_callback, (_cast_data)_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, &_callback, (_cast_data)&_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, (_cast_func)_callback, (_cast_data)_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, (_cast_func)_callback, (_cast_data)&_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, (_cast_func)&_callback, (_cast_data)_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, (_cast_func)&_callback, (_cast_data)&_E); +timer_setup(&_E._timer, _callback, 0); | _E->_timer@_stl.function = _callback; | _E->_timer@_stl.function = &_callback; | _E->_timer@_stl.function = (_cast_func)_callback; | _E->_timer@_stl.function = (_cast_func)&_callback; | _E._timer@_stl.function = _callback; | _E._timer@_stl.function = &_callback; | _E._timer@_stl.function = (_cast_func)_callback; | _E._timer@_stl.function = (_cast_func)&_callback; ) // callback(unsigned long arg) @change_callback_handle_cast depends on change_timer_function_usage@ identifier change_timer_function_usage._callback; identifier change_timer_function_usage._timer; type _origtype; identifier _origarg; type _handletype; identifier _handle; @@ void _callback( -_origtype _origarg +struct timer_list *t ) { ( ... when != _origarg _handletype *_handle = -(_handletype *)_origarg; +from_timer(_handle, t, _timer); ... when != _origarg | ... when != _origarg _handletype *_handle = -(void *)_origarg; +from_timer(_handle, t, _timer); ... when != _origarg | ... when != _origarg _handletype *_handle; ... when != _handle _handle = -(_handletype *)_origarg; +from_timer(_handle, t, _timer); ... when != _origarg | ... when != _origarg _handletype *_handle; ... when != _handle _handle = -(void *)_origarg; +from_timer(_handle, t, _timer); ... when != _origarg ) } // callback(unsigned long arg) without existing variable @change_callback_handle_cast_no_arg depends on change_timer_function_usage && !change_callback_handle_cast@ identifier change_timer_function_usage._callback; identifier change_timer_function_usage._timer; type _origtype; identifier _origarg; type _handletype; @@ void _callback( -_origtype _origarg +struct timer_list *t ) { + _handletype *_origarg = from_timer(_origarg, t, _timer); + ... when != _origarg - (_handletype *)_origarg + _origarg ... when != _origarg } // Avoid already converted callbacks. @match_callback_converted depends on change_timer_function_usage && !change_callback_handle_cast && !change_callback_handle_cast_no_arg@ identifier change_timer_function_usage._callback; identifier t; @@ void _callback(struct timer_list *t) { ... } // callback(struct something *handle) @change_callback_handle_arg depends on change_timer_function_usage && !match_callback_converted && !change_callback_handle_cast && !change_callback_handle_cast_no_arg@ identifier change_timer_function_usage._callback; identifier change_timer_function_usage._timer; type _handletype; identifier _handle; @@ void _callback( -_handletype *_handle +struct timer_list *t ) { + _handletype *_handle = from_timer(_handle, t, _timer); ... } // If change_callback_handle_arg ran on an empty function, remove // the added handler. @unchange_callback_handle_arg depends on change_timer_function_usage && change_callback_handle_arg@ identifier change_timer_function_usage._callback; identifier change_timer_function_usage._timer; type _handletype; identifier _handle; identifier t; @@ void _callback(struct timer_list *t) { - _handletype *_handle = from_timer(_handle, t, _timer); } // We only want to refactor the setup_timer() data argument if we've found // the matching callback. This undoes changes in change_timer_function_usage. @unchange_timer_function_usage depends on change_timer_function_usage && !change_callback_handle_cast && !change_callback_handle_cast_no_arg && !change_callback_handle_arg@ expression change_timer_function_usage._E; identifier change_timer_function_usage._timer; identifier change_timer_function_usage._callback; type change_timer_function_usage._cast_data; @@ ( -timer_setup(&_E->_timer, _callback, 0); +setup_timer(&_E->_timer, _callback, (_cast_data)_E); | -timer_setup(&_E._timer, _callback, 0); +setup_timer(&_E._timer, _callback, (_cast_data)&_E); ) // If we fixed a callback from a .function assignment, fix the // assignment cast now. @change_timer_function_assignment depends on change_timer_function_usage && (change_callback_handle_cast || change_callback_handle_cast_no_arg || change_callback_handle_arg)@ expression change_timer_function_usage._E; identifier change_timer_function_usage._timer; identifier change_timer_function_usage._callback; type _cast_func; typedef TIMER_FUNC_TYPE; @@ ( _E->_timer.function = -_callback +(TIMER_FUNC_TYPE)_callback ; | _E->_timer.function = -&_callback +(TIMER_FUNC_TYPE)_callback ; | _E->_timer.function = -(_cast_func)_callback; +(TIMER_FUNC_TYPE)_callback ; | _E->_timer.function = -(_cast_func)&_callback +(TIMER_FUNC_TYPE)_callback ; | _E._timer.function = -_callback +(TIMER_FUNC_TYPE)_callback ; | _E._timer.function = -&_callback; +(TIMER_FUNC_TYPE)_callback ; | _E._timer.function = -(_cast_func)_callback +(TIMER_FUNC_TYPE)_callback ; | _E._timer.function = -(_cast_func)&_callback +(TIMER_FUNC_TYPE)_callback ; ) // Sometimes timer functions are called directly. Replace matched args. @change_timer_function_calls depends on change_timer_function_usage && (change_callback_handle_cast || change_callback_handle_cast_no_arg || change_callback_handle_arg)@ expression _E; identifier change_timer_function_usage._timer; identifier change_timer_function_usage._callback; type _cast_data; @@ _callback( ( -(_cast_data)_E +&_E->_timer | -(_cast_data)&_E +&_E._timer | -_E +&_E->_timer ) ) // If a timer has been configured without a data argument, it can be // converted without regard to the callback argument, since it is unused. @match_timer_function_unused_data@ expression _E; identifier _timer; identifier _callback; @@ ( -setup_timer(&_E->_timer, _callback, 0); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, _callback, 0L); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, _callback, 0UL); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E._timer, _callback, 0); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, _callback, 0L); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, _callback, 0UL); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_timer, _callback, 0); +timer_setup(&_timer, _callback, 0); | -setup_timer(&_timer, _callback, 0L); +timer_setup(&_timer, _callback, 0); | -setup_timer(&_timer, _callback, 0UL); +timer_setup(&_timer, _callback, 0); | -setup_timer(_timer, _callback, 0); +timer_setup(_timer, _callback, 0); | -setup_timer(_timer, _callback, 0L); +timer_setup(_timer, _callback, 0); | -setup_timer(_timer, _callback, 0UL); +timer_setup(_timer, _callback, 0); ) @change_callback_unused_data depends on match_timer_function_unused_data@ identifier match_timer_function_unused_data._callback; type _origtype; identifier _origarg; @@ void _callback( -_origtype _origarg +struct timer_list *unused ) { ... when != _origarg } Signed-off-by: Kees Cook <keescook@chromium.org>
2017-10-17 04:43:17 +07:00
static void dsi_te_timeout(struct timer_list *unused)
{
DSSERR("TE not received for 250ms!\n");
}
#endif
static void dsi_handle_framedone(struct dsi_data *dsi, int error)
{
/* SIDLEMODE back to smart-idle */
dispc_enable_sidle(dsi->dss->dispc);
if (dsi->te_enabled) {
/* enable LP_RX_TO again after the TE */
REG_FLD_MOD(dsi, DSI_TIMING2, 1, 15, 15); /* LP_RX_TO */
}
dsi->framedone_callback(error, dsi->framedone_data);
if (!error)
dsi_perf_show(dsi, "DISPC");
}
static void dsi_framedone_timeout_work_callback(struct work_struct *work)
{
struct dsi_data *dsi = container_of(work, struct dsi_data,
framedone_timeout_work.work);
/* XXX While extremely unlikely, we could get FRAMEDONE interrupt after
* 250ms which would conflict with this timeout work. What should be
* done is first cancel the transfer on the HW, and then cancel the
* possibly scheduled framedone work. However, cancelling the transfer
* on the HW is buggy, and would probably require resetting the whole
* DSI */
DSSERR("Framedone not received for 250ms!\n");
dsi_handle_framedone(dsi, -ETIMEDOUT);
}
static void dsi_framedone_irq_callback(void *data)
{
struct dsi_data *dsi = data;
/* Note: We get FRAMEDONE when DISPC has finished sending pixels and
* turns itself off. However, DSI still has the pixels in its buffers,
* and is sending the data.
*/
cancel_delayed_work(&dsi->framedone_timeout_work);
dsi_handle_framedone(dsi, 0);
}
static int dsi_update(struct omap_dss_device *dssdev, int channel,
void (*callback)(int, void *), void *data)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
u16 dw, dh;
dsi_perf_mark_setup(dsi);
dsi->update_channel = channel;
dsi->framedone_callback = callback;
dsi->framedone_data = data;
dw = dsi->vm.hactive;
dh = dsi->vm.vactive;
#ifdef DSI_PERF_MEASURE
dsi->update_bytes = dw * dh *
dsi_get_pixel_size(dsi->pix_fmt) / 8;
#endif
dsi_update_screen_dispc(dsi);
return 0;
}
/* Display funcs */
static int dsi_configure_dispc_clocks(struct dsi_data *dsi)
{
struct dispc_clock_info dispc_cinfo;
int r;
unsigned long fck;
fck = dsi_get_pll_hsdiv_dispc_rate(dsi);
dispc_cinfo.lck_div = dsi->user_dispc_cinfo.lck_div;
dispc_cinfo.pck_div = dsi->user_dispc_cinfo.pck_div;
r = dispc_calc_clock_rates(dsi->dss->dispc, fck, &dispc_cinfo);
if (r) {
DSSERR("Failed to calc dispc clocks\n");
return r;
}
dsi->mgr_config.clock_info = dispc_cinfo;
return 0;
}
static int dsi_display_init_dispc(struct dsi_data *dsi)
{
enum omap_channel channel = dsi->output.dispc_channel;
int r;
dss_select_lcd_clk_source(dsi->dss, channel, dsi->module_id == 0 ?
DSS_CLK_SRC_PLL1_1 :
DSS_CLK_SRC_PLL2_1);
if (dsi->mode == OMAP_DSS_DSI_CMD_MODE) {
r = dss_mgr_register_framedone_handler(&dsi->output,
dsi_framedone_irq_callback, dsi);
if (r) {
DSSERR("can't register FRAMEDONE handler\n");
goto err;
}
dsi->mgr_config.stallmode = true;
dsi->mgr_config.fifohandcheck = true;
} else {
dsi->mgr_config.stallmode = false;
dsi->mgr_config.fifohandcheck = false;
}
r = dsi_configure_dispc_clocks(dsi);
if (r)
goto err1;
dsi->mgr_config.io_pad_mode = DSS_IO_PAD_MODE_BYPASS;
dsi->mgr_config.video_port_width =
dsi_get_pixel_size(dsi->pix_fmt);
dsi->mgr_config.lcden_sig_polarity = 0;
dss_mgr_set_lcd_config(&dsi->output, &dsi->mgr_config);
return 0;
err1:
if (dsi->mode == OMAP_DSS_DSI_CMD_MODE)
dss_mgr_unregister_framedone_handler(&dsi->output,
dsi_framedone_irq_callback, dsi);
err:
dss_select_lcd_clk_source(dsi->dss, channel, DSS_CLK_SRC_FCK);
return r;
}
static void dsi_display_uninit_dispc(struct dsi_data *dsi)
{
enum omap_channel channel = dsi->output.dispc_channel;
if (dsi->mode == OMAP_DSS_DSI_CMD_MODE)
dss_mgr_unregister_framedone_handler(&dsi->output,
dsi_framedone_irq_callback, dsi);
dss_select_lcd_clk_source(dsi->dss, channel, DSS_CLK_SRC_FCK);
}
static int dsi_configure_dsi_clocks(struct dsi_data *dsi)
{
struct dss_pll_clock_info cinfo;
int r;
cinfo = dsi->user_dsi_cinfo;
r = dss_pll_set_config(&dsi->pll, &cinfo);
if (r) {
DSSERR("Failed to set dsi clocks\n");
return r;
}
return 0;
}
static int dsi_display_init_dsi(struct dsi_data *dsi)
{
int r;
r = dss_pll_enable(&dsi->pll);
if (r)
2019-02-07 22:45:16 +07:00
return r;
r = dsi_configure_dsi_clocks(dsi);
if (r)
2019-02-07 22:45:16 +07:00
goto err0;
dss_select_dsi_clk_source(dsi->dss, dsi->module_id,
dsi->module_id == 0 ?
DSS_CLK_SRC_PLL1_2 : DSS_CLK_SRC_PLL2_2);
DSSDBG("PLL OK\n");
2019-02-07 22:45:16 +07:00
if (!dsi->vdds_dsi_enabled) {
r = regulator_enable(dsi->vdds_dsi_reg);
if (r)
goto err1;
dsi->vdds_dsi_enabled = true;
}
r = dsi_cio_init(dsi);
if (r)
goto err2;
_dsi_print_reset_status(dsi);
dsi_proto_timings(dsi);
dsi_set_lp_clk_divisor(dsi);
if (1)
_dsi_print_reset_status(dsi);
r = dsi_proto_config(dsi);
if (r)
goto err3;
/* enable interface */
dsi_vc_enable(dsi, 0, 1);
dsi_vc_enable(dsi, 1, 1);
dsi_vc_enable(dsi, 2, 1);
dsi_vc_enable(dsi, 3, 1);
dsi_if_enable(dsi, 1);
dsi_force_tx_stop_mode_io(dsi);
return 0;
err3:
dsi_cio_uninit(dsi);
err2:
2019-02-07 22:45:16 +07:00
regulator_disable(dsi->vdds_dsi_reg);
dsi->vdds_dsi_enabled = false;
err1:
2019-02-07 22:45:16 +07:00
dss_select_dsi_clk_source(dsi->dss, dsi->module_id, DSS_CLK_SRC_FCK);
err0:
2019-02-07 22:45:16 +07:00
dss_pll_disable(&dsi->pll);
return r;
}
static void dsi_display_uninit_dsi(struct dsi_data *dsi, bool disconnect_lanes,
bool enter_ulps)
{
if (enter_ulps && !dsi->ulps_enabled)
dsi_enter_ulps(dsi);
/* disable interface */
dsi_if_enable(dsi, 0);
dsi_vc_enable(dsi, 0, 0);
dsi_vc_enable(dsi, 1, 0);
dsi_vc_enable(dsi, 2, 0);
dsi_vc_enable(dsi, 3, 0);
dss_select_dsi_clk_source(dsi->dss, dsi->module_id, DSS_CLK_SRC_FCK);
dsi_cio_uninit(dsi);
2019-02-07 22:45:16 +07:00
dss_pll_disable(&dsi->pll);
if (disconnect_lanes) {
regulator_disable(dsi->vdds_dsi_reg);
dsi->vdds_dsi_enabled = false;
}
}
static void dsi_display_enable(struct omap_dss_device *dssdev)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
int r;
DSSDBG("dsi_display_enable\n");
WARN_ON(!dsi_bus_is_locked(dsi));
mutex_lock(&dsi->lock);
r = dsi_runtime_get(dsi);
if (r)
goto err_get_dsi;
_dsi_initialize_irq(dsi);
r = dsi_display_init_dsi(dsi);
if (r)
goto err_init_dsi;
mutex_unlock(&dsi->lock);
return;
err_init_dsi:
dsi_runtime_put(dsi);
err_get_dsi:
mutex_unlock(&dsi->lock);
DSSDBG("dsi_display_enable FAILED\n");
}
static void dsi_display_disable(struct omap_dss_device *dssdev,
bool disconnect_lanes, bool enter_ulps)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
DSSDBG("dsi_display_disable\n");
WARN_ON(!dsi_bus_is_locked(dsi));
mutex_lock(&dsi->lock);
dsi_sync_vc(dsi, 0);
dsi_sync_vc(dsi, 1);
dsi_sync_vc(dsi, 2);
dsi_sync_vc(dsi, 3);
dsi_display_uninit_dsi(dsi, disconnect_lanes, enter_ulps);
dsi_runtime_put(dsi);
mutex_unlock(&dsi->lock);
}
static int dsi_enable_te(struct omap_dss_device *dssdev, bool enable)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
dsi->te_enabled = enable;
return 0;
}
#ifdef PRINT_VERBOSE_VM_TIMINGS
static void print_dsi_vm(const char *str,
const struct omap_dss_dsi_videomode_timings *t)
{
unsigned long byteclk = t->hsclk / 4;
int bl, wc, pps, tot;
wc = DIV_ROUND_UP(t->hact * t->bitspp, 8);
pps = DIV_ROUND_UP(wc + 6, t->ndl); /* pixel packet size */
bl = t->hss + t->hsa + t->hse + t->hbp + t->hfp;
tot = bl + pps;
#define TO_DSI_T(x) ((u32)div64_u64((u64)x * 1000000000llu, byteclk))
pr_debug("%s bck %lu, %u/%u/%u/%u/%u/%u = %u+%u = %u, "
"%u/%u/%u/%u/%u/%u = %u + %u = %u\n",
str,
byteclk,
t->hss, t->hsa, t->hse, t->hbp, pps, t->hfp,
bl, pps, tot,
TO_DSI_T(t->hss),
TO_DSI_T(t->hsa),
TO_DSI_T(t->hse),
TO_DSI_T(t->hbp),
TO_DSI_T(pps),
TO_DSI_T(t->hfp),
TO_DSI_T(bl),
TO_DSI_T(pps),
TO_DSI_T(tot));
#undef TO_DSI_T
}
static void print_dispc_vm(const char *str, const struct videomode *vm)
{
unsigned long pck = vm->pixelclock;
int hact, bl, tot;
hact = vm->hactive;
bl = vm->hsync_len + vm->hback_porch + vm->hfront_porch;
tot = hact + bl;
#define TO_DISPC_T(x) ((u32)div64_u64((u64)x * 1000000000llu, pck))
pr_debug("%s pck %lu, %u/%u/%u/%u = %u+%u = %u, "
"%u/%u/%u/%u = %u + %u = %u\n",
str,
pck,
vm->hsync_len, vm->hback_porch, hact, vm->hfront_porch,
bl, hact, tot,
TO_DISPC_T(vm->hsync_len),
TO_DISPC_T(vm->hback_porch),
TO_DISPC_T(hact),
TO_DISPC_T(vm->hfront_porch),
TO_DISPC_T(bl),
TO_DISPC_T(hact),
TO_DISPC_T(tot));
#undef TO_DISPC_T
}
/* note: this is not quite accurate */
static void print_dsi_dispc_vm(const char *str,
const struct omap_dss_dsi_videomode_timings *t)
{
struct videomode vm = { 0 };
unsigned long byteclk = t->hsclk / 4;
unsigned long pck;
u64 dsi_tput;
int dsi_hact, dsi_htot;
dsi_tput = (u64)byteclk * t->ndl * 8;
pck = (u32)div64_u64(dsi_tput, t->bitspp);
dsi_hact = DIV_ROUND_UP(DIV_ROUND_UP(t->hact * t->bitspp, 8) + 6, t->ndl);
dsi_htot = t->hss + t->hsa + t->hse + t->hbp + dsi_hact + t->hfp;
vm.pixelclock = pck;
vm.hsync_len = div64_u64((u64)(t->hsa + t->hse) * pck, byteclk);
vm.hback_porch = div64_u64((u64)t->hbp * pck, byteclk);
vm.hfront_porch = div64_u64((u64)t->hfp * pck, byteclk);
vm.hactive = t->hact;
print_dispc_vm(str, &vm);
}
#endif /* PRINT_VERBOSE_VM_TIMINGS */
static bool dsi_cm_calc_dispc_cb(int lckd, int pckd, unsigned long lck,
unsigned long pck, void *data)
{
struct dsi_clk_calc_ctx *ctx = data;
struct videomode *vm = &ctx->vm;
ctx->dispc_cinfo.lck_div = lckd;
ctx->dispc_cinfo.pck_div = pckd;
ctx->dispc_cinfo.lck = lck;
ctx->dispc_cinfo.pck = pck;
*vm = *ctx->config->vm;
vm->pixelclock = pck;
vm->hactive = ctx->config->vm->hactive;
vm->vactive = ctx->config->vm->vactive;
vm->hsync_len = vm->hfront_porch = vm->hback_porch = vm->vsync_len = 1;
vm->vfront_porch = vm->vback_porch = 0;
return true;
}
static bool dsi_cm_calc_hsdiv_cb(int m_dispc, unsigned long dispc,
void *data)
{
struct dsi_clk_calc_ctx *ctx = data;
ctx->dsi_cinfo.mX[HSDIV_DISPC] = m_dispc;
ctx->dsi_cinfo.clkout[HSDIV_DISPC] = dispc;
return dispc_div_calc(ctx->dsi->dss->dispc, dispc,
ctx->req_pck_min, ctx->req_pck_max,
dsi_cm_calc_dispc_cb, ctx);
}
static bool dsi_cm_calc_pll_cb(int n, int m, unsigned long fint,
unsigned long clkdco, void *data)
{
struct dsi_clk_calc_ctx *ctx = data;
struct dsi_data *dsi = ctx->dsi;
ctx->dsi_cinfo.n = n;
ctx->dsi_cinfo.m = m;
ctx->dsi_cinfo.fint = fint;
ctx->dsi_cinfo.clkdco = clkdco;
return dss_pll_hsdiv_calc_a(ctx->pll, clkdco, ctx->req_pck_min,
dsi->data->max_fck_freq,
dsi_cm_calc_hsdiv_cb, ctx);
}
static bool dsi_cm_calc(struct dsi_data *dsi,
const struct omap_dss_dsi_config *cfg,
struct dsi_clk_calc_ctx *ctx)
{
unsigned long clkin;
int bitspp, ndl;
unsigned long pll_min, pll_max;
unsigned long pck, txbyteclk;
clkin = clk_get_rate(dsi->pll.clkin);
bitspp = dsi_get_pixel_size(cfg->pixel_format);
ndl = dsi->num_lanes_used - 1;
/*
* Here we should calculate minimum txbyteclk to be able to send the
* frame in time, and also to handle TE. That's not very simple, though,
* especially as we go to LP between each pixel packet due to HW
* "feature". So let's just estimate very roughly and multiply by 1.5.
*/
pck = cfg->vm->pixelclock;
pck = pck * 3 / 2;
txbyteclk = pck * bitspp / 8 / ndl;
memset(ctx, 0, sizeof(*ctx));
ctx->dsi = dsi;
ctx->pll = &dsi->pll;
ctx->config = cfg;
ctx->req_pck_min = pck;
ctx->req_pck_nom = pck;
ctx->req_pck_max = pck * 3 / 2;
pll_min = max(cfg->hs_clk_min * 4, txbyteclk * 4 * 4);
pll_max = cfg->hs_clk_max * 4;
return dss_pll_calc_a(ctx->pll, clkin,
pll_min, pll_max,
dsi_cm_calc_pll_cb, ctx);
}
static bool dsi_vm_calc_blanking(struct dsi_clk_calc_ctx *ctx)
{
struct dsi_data *dsi = ctx->dsi;
const struct omap_dss_dsi_config *cfg = ctx->config;
int bitspp = dsi_get_pixel_size(cfg->pixel_format);
int ndl = dsi->num_lanes_used - 1;
unsigned long hsclk = ctx->dsi_cinfo.clkdco / 4;
unsigned long byteclk = hsclk / 4;
unsigned long dispc_pck, req_pck_min, req_pck_nom, req_pck_max;
int xres;
int panel_htot, panel_hbl; /* pixels */
int dispc_htot, dispc_hbl; /* pixels */
int dsi_htot, dsi_hact, dsi_hbl, hss, hse; /* byteclks */
int hfp, hsa, hbp;
const struct videomode *req_vm;
struct videomode *dispc_vm;
struct omap_dss_dsi_videomode_timings *dsi_vm;
u64 dsi_tput, dispc_tput;
dsi_tput = (u64)byteclk * ndl * 8;
req_vm = cfg->vm;
req_pck_min = ctx->req_pck_min;
req_pck_max = ctx->req_pck_max;
req_pck_nom = ctx->req_pck_nom;
dispc_pck = ctx->dispc_cinfo.pck;
dispc_tput = (u64)dispc_pck * bitspp;
xres = req_vm->hactive;
panel_hbl = req_vm->hfront_porch + req_vm->hback_porch +
req_vm->hsync_len;
panel_htot = xres + panel_hbl;
dsi_hact = DIV_ROUND_UP(DIV_ROUND_UP(xres * bitspp, 8) + 6, ndl);
/*
* When there are no line buffers, DISPC and DSI must have the
* same tput. Otherwise DISPC tput needs to be higher than DSI's.
*/
if (dsi->line_buffer_size < xres * bitspp / 8) {
if (dispc_tput != dsi_tput)
return false;
} else {
if (dispc_tput < dsi_tput)
return false;
}
/* DSI tput must be over the min requirement */
if (dsi_tput < (u64)bitspp * req_pck_min)
return false;
/* When non-burst mode, DSI tput must be below max requirement. */
if (cfg->trans_mode != OMAP_DSS_DSI_BURST_MODE) {
if (dsi_tput > (u64)bitspp * req_pck_max)
return false;
}
hss = DIV_ROUND_UP(4, ndl);
if (cfg->trans_mode == OMAP_DSS_DSI_PULSE_MODE) {
if (ndl == 3 && req_vm->hsync_len == 0)
hse = 1;
else
hse = DIV_ROUND_UP(4, ndl);
} else {
hse = 0;
}
/* DSI htot to match the panel's nominal pck */
dsi_htot = div64_u64((u64)panel_htot * byteclk, req_pck_nom);
/* fail if there would be no time for blanking */
if (dsi_htot < hss + hse + dsi_hact)
return false;
/* total DSI blanking needed to achieve panel's TL */
dsi_hbl = dsi_htot - dsi_hact;
/* DISPC htot to match the DSI TL */
dispc_htot = div64_u64((u64)dsi_htot * dispc_pck, byteclk);
/* verify that the DSI and DISPC TLs are the same */
if ((u64)dsi_htot * dispc_pck != (u64)dispc_htot * byteclk)
return false;
dispc_hbl = dispc_htot - xres;
/* setup DSI videomode */
dsi_vm = &ctx->dsi_vm;
memset(dsi_vm, 0, sizeof(*dsi_vm));
dsi_vm->hsclk = hsclk;
dsi_vm->ndl = ndl;
dsi_vm->bitspp = bitspp;
if (cfg->trans_mode != OMAP_DSS_DSI_PULSE_MODE) {
hsa = 0;
} else if (ndl == 3 && req_vm->hsync_len == 0) {
hsa = 0;
} else {
hsa = div64_u64((u64)req_vm->hsync_len * byteclk, req_pck_nom);
hsa = max(hsa - hse, 1);
}
hbp = div64_u64((u64)req_vm->hback_porch * byteclk, req_pck_nom);
hbp = max(hbp, 1);
hfp = dsi_hbl - (hss + hsa + hse + hbp);
if (hfp < 1) {
int t;
/* we need to take cycles from hbp */
t = 1 - hfp;
hbp = max(hbp - t, 1);
hfp = dsi_hbl - (hss + hsa + hse + hbp);
if (hfp < 1 && hsa > 0) {
/* we need to take cycles from hsa */
t = 1 - hfp;
hsa = max(hsa - t, 1);
hfp = dsi_hbl - (hss + hsa + hse + hbp);
}
}
if (hfp < 1)
return false;
dsi_vm->hss = hss;
dsi_vm->hsa = hsa;
dsi_vm->hse = hse;
dsi_vm->hbp = hbp;
dsi_vm->hact = xres;
dsi_vm->hfp = hfp;
dsi_vm->vsa = req_vm->vsync_len;
dsi_vm->vbp = req_vm->vback_porch;
dsi_vm->vact = req_vm->vactive;
dsi_vm->vfp = req_vm->vfront_porch;
dsi_vm->trans_mode = cfg->trans_mode;
dsi_vm->blanking_mode = 0;
dsi_vm->hsa_blanking_mode = 1;
dsi_vm->hfp_blanking_mode = 1;
dsi_vm->hbp_blanking_mode = 1;
dsi_vm->ddr_clk_always_on = cfg->ddr_clk_always_on;
dsi_vm->window_sync = 4;
/* setup DISPC videomode */
dispc_vm = &ctx->vm;
*dispc_vm = *req_vm;
dispc_vm->pixelclock = dispc_pck;
if (cfg->trans_mode == OMAP_DSS_DSI_PULSE_MODE) {
hsa = div64_u64((u64)req_vm->hsync_len * dispc_pck,
req_pck_nom);
hsa = max(hsa, 1);
} else {
hsa = 1;
}
hbp = div64_u64((u64)req_vm->hback_porch * dispc_pck, req_pck_nom);
hbp = max(hbp, 1);
hfp = dispc_hbl - hsa - hbp;
if (hfp < 1) {
int t;
/* we need to take cycles from hbp */
t = 1 - hfp;
hbp = max(hbp - t, 1);
hfp = dispc_hbl - hsa - hbp;
if (hfp < 1) {
/* we need to take cycles from hsa */
t = 1 - hfp;
hsa = max(hsa - t, 1);
hfp = dispc_hbl - hsa - hbp;
}
}
if (hfp < 1)
return false;
dispc_vm->hfront_porch = hfp;
dispc_vm->hsync_len = hsa;
dispc_vm->hback_porch = hbp;
return true;
}
static bool dsi_vm_calc_dispc_cb(int lckd, int pckd, unsigned long lck,
unsigned long pck, void *data)
{
struct dsi_clk_calc_ctx *ctx = data;
ctx->dispc_cinfo.lck_div = lckd;
ctx->dispc_cinfo.pck_div = pckd;
ctx->dispc_cinfo.lck = lck;
ctx->dispc_cinfo.pck = pck;
if (dsi_vm_calc_blanking(ctx) == false)
return false;
#ifdef PRINT_VERBOSE_VM_TIMINGS
print_dispc_vm("dispc", &ctx->vm);
print_dsi_vm("dsi ", &ctx->dsi_vm);
print_dispc_vm("req ", ctx->config->vm);
print_dsi_dispc_vm("act ", &ctx->dsi_vm);
#endif
return true;
}
static bool dsi_vm_calc_hsdiv_cb(int m_dispc, unsigned long dispc,
void *data)
{
struct dsi_clk_calc_ctx *ctx = data;
unsigned long pck_max;
ctx->dsi_cinfo.mX[HSDIV_DISPC] = m_dispc;
ctx->dsi_cinfo.clkout[HSDIV_DISPC] = dispc;
/*
* In burst mode we can let the dispc pck be arbitrarily high, but it
* limits our scaling abilities. So for now, don't aim too high.
*/
if (ctx->config->trans_mode == OMAP_DSS_DSI_BURST_MODE)
pck_max = ctx->req_pck_max + 10000000;
else
pck_max = ctx->req_pck_max;
return dispc_div_calc(ctx->dsi->dss->dispc, dispc,
ctx->req_pck_min, pck_max,
dsi_vm_calc_dispc_cb, ctx);
}
static bool dsi_vm_calc_pll_cb(int n, int m, unsigned long fint,
unsigned long clkdco, void *data)
{
struct dsi_clk_calc_ctx *ctx = data;
struct dsi_data *dsi = ctx->dsi;
ctx->dsi_cinfo.n = n;
ctx->dsi_cinfo.m = m;
ctx->dsi_cinfo.fint = fint;
ctx->dsi_cinfo.clkdco = clkdco;
return dss_pll_hsdiv_calc_a(ctx->pll, clkdco, ctx->req_pck_min,
dsi->data->max_fck_freq,
dsi_vm_calc_hsdiv_cb, ctx);
}
static bool dsi_vm_calc(struct dsi_data *dsi,
const struct omap_dss_dsi_config *cfg,
struct dsi_clk_calc_ctx *ctx)
{
const struct videomode *vm = cfg->vm;
unsigned long clkin;
unsigned long pll_min;
unsigned long pll_max;
int ndl = dsi->num_lanes_used - 1;
int bitspp = dsi_get_pixel_size(cfg->pixel_format);
unsigned long byteclk_min;
clkin = clk_get_rate(dsi->pll.clkin);
memset(ctx, 0, sizeof(*ctx));
ctx->dsi = dsi;
ctx->pll = &dsi->pll;
ctx->config = cfg;
/* these limits should come from the panel driver */
ctx->req_pck_min = vm->pixelclock - 1000;
ctx->req_pck_nom = vm->pixelclock;
ctx->req_pck_max = vm->pixelclock + 1000;
byteclk_min = div64_u64((u64)ctx->req_pck_min * bitspp, ndl * 8);
pll_min = max(cfg->hs_clk_min * 4, byteclk_min * 4 * 4);
if (cfg->trans_mode == OMAP_DSS_DSI_BURST_MODE) {
pll_max = cfg->hs_clk_max * 4;
} else {
unsigned long byteclk_max;
byteclk_max = div64_u64((u64)ctx->req_pck_max * bitspp,
ndl * 8);
pll_max = byteclk_max * 4 * 4;
}
return dss_pll_calc_a(ctx->pll, clkin,
pll_min, pll_max,
dsi_vm_calc_pll_cb, ctx);
}
static int dsi_set_config(struct omap_dss_device *dssdev,
const struct omap_dss_dsi_config *config)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
struct dsi_clk_calc_ctx ctx;
bool ok;
int r;
mutex_lock(&dsi->lock);
dsi->pix_fmt = config->pixel_format;
dsi->mode = config->mode;
if (config->mode == OMAP_DSS_DSI_VIDEO_MODE)
ok = dsi_vm_calc(dsi, config, &ctx);
else
ok = dsi_cm_calc(dsi, config, &ctx);
if (!ok) {
DSSERR("failed to find suitable DSI clock settings\n");
r = -EINVAL;
goto err;
}
dsi_pll_calc_dsi_fck(dsi, &ctx.dsi_cinfo);
r = dsi_lp_clock_calc(ctx.dsi_cinfo.clkout[HSDIV_DSI],
config->lp_clk_min, config->lp_clk_max, &dsi->user_lp_cinfo);
if (r) {
DSSERR("failed to find suitable DSI LP clock settings\n");
goto err;
}
dsi->user_dsi_cinfo = ctx.dsi_cinfo;
dsi->user_dispc_cinfo = ctx.dispc_cinfo;
dsi->vm = ctx.vm;
/*
* override interlace, logic level and edge related parameters in
* videomode with default values
*/
dsi->vm.flags &= ~DISPLAY_FLAGS_INTERLACED;
dsi->vm.flags &= ~DISPLAY_FLAGS_HSYNC_LOW;
dsi->vm.flags |= DISPLAY_FLAGS_HSYNC_HIGH;
dsi->vm.flags &= ~DISPLAY_FLAGS_VSYNC_LOW;
dsi->vm.flags |= DISPLAY_FLAGS_VSYNC_HIGH;
/*
* HACK: These flags should be handled through the omap_dss_device bus
* flags, but this will only be possible when the DSI encoder will be
* converted to the omapdrm-managed encoder model.
*/
dsi->vm.flags &= ~DISPLAY_FLAGS_PIXDATA_NEGEDGE;
dsi->vm.flags |= DISPLAY_FLAGS_PIXDATA_POSEDGE;
dsi->vm.flags &= ~DISPLAY_FLAGS_DE_LOW;
dsi->vm.flags |= DISPLAY_FLAGS_DE_HIGH;
dsi->vm.flags &= ~DISPLAY_FLAGS_SYNC_POSEDGE;
dsi->vm.flags |= DISPLAY_FLAGS_SYNC_NEGEDGE;
dss_mgr_set_timings(&dsi->output, &dsi->vm);
dsi->vm_timings = ctx.dsi_vm;
mutex_unlock(&dsi->lock);
return 0;
err:
mutex_unlock(&dsi->lock);
return r;
}
/*
* Return a hardcoded channel for the DSI output. This should work for
* current use cases, but this can be later expanded to either resolve
* the channel in some more dynamic manner, or get the channel as a user
* parameter.
*/
static enum omap_channel dsi_get_channel(struct dsi_data *dsi)
{
switch (dsi->data->model) {
case DSI_MODEL_OMAP3:
return OMAP_DSS_CHANNEL_LCD;
case DSI_MODEL_OMAP4:
switch (dsi->module_id) {
case 0:
return OMAP_DSS_CHANNEL_LCD;
case 1:
return OMAP_DSS_CHANNEL_LCD2;
default:
DSSWARN("unsupported module id\n");
return OMAP_DSS_CHANNEL_LCD;
}
case DSI_MODEL_OMAP5:
switch (dsi->module_id) {
case 0:
return OMAP_DSS_CHANNEL_LCD;
case 1:
return OMAP_DSS_CHANNEL_LCD3;
default:
DSSWARN("unsupported module id\n");
return OMAP_DSS_CHANNEL_LCD;
}
default:
DSSWARN("unsupported DSS version\n");
return OMAP_DSS_CHANNEL_LCD;
}
}
static int dsi_request_vc(struct omap_dss_device *dssdev, int *channel)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
int i;
for (i = 0; i < ARRAY_SIZE(dsi->vc); i++) {
if (!dsi->vc[i].dssdev) {
dsi->vc[i].dssdev = dssdev;
*channel = i;
return 0;
}
}
DSSERR("cannot get VC for display %s", dssdev->name);
return -ENOSPC;
}
static int dsi_set_vc_id(struct omap_dss_device *dssdev, int channel, int vc_id)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
if (vc_id < 0 || vc_id > 3) {
DSSERR("VC ID out of range\n");
return -EINVAL;
}
if (channel < 0 || channel > 3) {
DSSERR("Virtual Channel out of range\n");
return -EINVAL;
}
if (dsi->vc[channel].dssdev != dssdev) {
DSSERR("Virtual Channel not allocated to display %s\n",
dssdev->name);
return -EINVAL;
}
dsi->vc[channel].vc_id = vc_id;
return 0;
}
static void dsi_release_vc(struct omap_dss_device *dssdev, int channel)
{
struct dsi_data *dsi = to_dsi_data(dssdev);
if ((channel >= 0 && channel <= 3) &&
dsi->vc[channel].dssdev == dssdev) {
dsi->vc[channel].dssdev = NULL;
dsi->vc[channel].vc_id = 0;
}
}
static int dsi_get_clocks(struct dsi_data *dsi)
{
struct clk *clk;
clk = devm_clk_get(dsi->dev, "fck");
if (IS_ERR(clk)) {
DSSERR("can't get fck\n");
return PTR_ERR(clk);
}
dsi->dss_clk = clk;
return 0;
}
static int dsi_connect(struct omap_dss_device *src,
struct omap_dss_device *dst)
{
return omapdss_device_connect(dst->dss, dst, dst->next);
}
static void dsi_disconnect(struct omap_dss_device *src,
struct omap_dss_device *dst)
{
omapdss_device_disconnect(dst, dst->next);
}
static const struct omap_dss_device_ops dsi_ops = {
.connect = dsi_connect,
.disconnect = dsi_disconnect,
.enable = dsi_display_enable,
.dsi = {
.bus_lock = dsi_bus_lock,
.bus_unlock = dsi_bus_unlock,
.disable = dsi_display_disable,
.enable_hs = dsi_vc_enable_hs,
.configure_pins = dsi_configure_pins,
.set_config = dsi_set_config,
.enable_video_output = dsi_enable_video_output,
.disable_video_output = dsi_disable_video_output,
.update = dsi_update,
.enable_te = dsi_enable_te,
.request_vc = dsi_request_vc,
.set_vc_id = dsi_set_vc_id,
.release_vc = dsi_release_vc,
.dcs_write = dsi_vc_dcs_write,
.dcs_write_nosync = dsi_vc_dcs_write_nosync,
.dcs_read = dsi_vc_dcs_read,
.gen_write = dsi_vc_generic_write,
.gen_write_nosync = dsi_vc_generic_write_nosync,
.gen_read = dsi_vc_generic_read,
.bta_sync = dsi_vc_send_bta_sync,
.set_max_rx_packet_size = dsi_vc_set_max_rx_packet_size,
},
};
/* -----------------------------------------------------------------------------
* PLL
*/
static const struct dss_pll_ops dsi_pll_ops = {
.enable = dsi_pll_enable,
.disable = dsi_pll_disable,
.set_config = dss_pll_write_config_type_a,
};
static const struct dss_pll_hw dss_omap3_dsi_pll_hw = {
.type = DSS_PLL_TYPE_A,
.n_max = (1 << 7) - 1,
.m_max = (1 << 11) - 1,
.mX_max = (1 << 4) - 1,
.fint_min = 750000,
.fint_max = 2100000,
.clkdco_low = 1000000000,
.clkdco_max = 1800000000,
.n_msb = 7,
.n_lsb = 1,
.m_msb = 18,
.m_lsb = 8,
.mX_msb[0] = 22,
.mX_lsb[0] = 19,
.mX_msb[1] = 26,
.mX_lsb[1] = 23,
.has_stopmode = true,
.has_freqsel = true,
.has_selfreqdco = false,
.has_refsel = false,
};
static const struct dss_pll_hw dss_omap4_dsi_pll_hw = {
.type = DSS_PLL_TYPE_A,
.n_max = (1 << 8) - 1,
.m_max = (1 << 12) - 1,
.mX_max = (1 << 5) - 1,
.fint_min = 500000,
.fint_max = 2500000,
.clkdco_low = 1000000000,
.clkdco_max = 1800000000,
.n_msb = 8,
.n_lsb = 1,
.m_msb = 20,
.m_lsb = 9,
.mX_msb[0] = 25,
.mX_lsb[0] = 21,
.mX_msb[1] = 30,
.mX_lsb[1] = 26,
.has_stopmode = true,
.has_freqsel = false,
.has_selfreqdco = false,
.has_refsel = false,
};
static const struct dss_pll_hw dss_omap5_dsi_pll_hw = {
.type = DSS_PLL_TYPE_A,
.n_max = (1 << 8) - 1,
.m_max = (1 << 12) - 1,
.mX_max = (1 << 5) - 1,
.fint_min = 150000,
.fint_max = 52000000,
.clkdco_low = 1000000000,
.clkdco_max = 1800000000,
.n_msb = 8,
.n_lsb = 1,
.m_msb = 20,
.m_lsb = 9,
.mX_msb[0] = 25,
.mX_lsb[0] = 21,
.mX_msb[1] = 30,
.mX_lsb[1] = 26,
.has_stopmode = true,
.has_freqsel = false,
.has_selfreqdco = true,
.has_refsel = true,
};
static int dsi_init_pll_data(struct dss_device *dss, struct dsi_data *dsi)
{
struct dss_pll *pll = &dsi->pll;
struct clk *clk;
int r;
clk = devm_clk_get(dsi->dev, "sys_clk");
if (IS_ERR(clk)) {
DSSERR("can't get sys_clk\n");
return PTR_ERR(clk);
}
pll->name = dsi->module_id == 0 ? "dsi0" : "dsi1";
pll->id = dsi->module_id == 0 ? DSS_PLL_DSI1 : DSS_PLL_DSI2;
pll->clkin = clk;
pll->base = dsi->pll_base;
pll->hw = dsi->data->pll_hw;
pll->ops = &dsi_pll_ops;
r = dss_pll_register(dss, pll);
if (r)
return r;
return 0;
}
/* -----------------------------------------------------------------------------
* Component Bind & Unbind
*/
static int dsi_bind(struct device *dev, struct device *master, void *data)
{
struct dss_device *dss = dss_get_device(master);
struct dsi_data *dsi = dev_get_drvdata(dev);
char name[10];
u32 rev;
int r;
dsi->dss = dss;
dsi_init_pll_data(dss, dsi);
r = dsi_runtime_get(dsi);
if (r)
return r;
rev = dsi_read_reg(dsi, DSI_REVISION);
dev_dbg(dev, "OMAP DSI rev %d.%d\n",
FLD_GET(rev, 7, 4), FLD_GET(rev, 3, 0));
dsi->line_buffer_size = dsi_get_line_buf_size(dsi);
dsi_runtime_put(dsi);
snprintf(name, sizeof(name), "dsi%u_regs", dsi->module_id + 1);
dsi->debugfs.regs = dss_debugfs_create_file(dss, name,
dsi_dump_dsi_regs, dsi);
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
snprintf(name, sizeof(name), "dsi%u_irqs", dsi->module_id + 1);
dsi->debugfs.irqs = dss_debugfs_create_file(dss, name,
dsi_dump_dsi_irqs, dsi);
#endif
snprintf(name, sizeof(name), "dsi%u_clks", dsi->module_id + 1);
dsi->debugfs.clks = dss_debugfs_create_file(dss, name,
dsi_dump_dsi_clocks, dsi);
return 0;
}
static void dsi_unbind(struct device *dev, struct device *master, void *data)
{
struct dsi_data *dsi = dev_get_drvdata(dev);
dss_debugfs_remove_file(dsi->debugfs.clks);
dss_debugfs_remove_file(dsi->debugfs.irqs);
dss_debugfs_remove_file(dsi->debugfs.regs);
WARN_ON(dsi->scp_clk_refcount > 0);
dss_pll_unregister(&dsi->pll);
}
static const struct component_ops dsi_component_ops = {
.bind = dsi_bind,
.unbind = dsi_unbind,
};
/* -----------------------------------------------------------------------------
* Probe & Remove, Suspend & Resume
*/
static int dsi_init_output(struct dsi_data *dsi)
{
struct omap_dss_device *out = &dsi->output;
int r;
out->dev = dsi->dev;
out->id = dsi->module_id == 0 ?
OMAP_DSS_OUTPUT_DSI1 : OMAP_DSS_OUTPUT_DSI2;
out->type = OMAP_DISPLAY_TYPE_DSI;
out->name = dsi->module_id == 0 ? "dsi.0" : "dsi.1";
out->dispc_channel = dsi_get_channel(dsi);
out->ops = &dsi_ops;
out->owner = THIS_MODULE;
out->of_ports = BIT(0);
out->bus_flags = DRM_BUS_FLAG_PIXDATA_DRIVE_POSEDGE
drm/omap: Store bus flags in the omap_dss_device structure Source components in the display pipeline need to configure their output signals polarities and clock driving edge based on the requirements of the sink component. Those requirements are currently shared across the whole pipeline in the flags of a videomode structure, instead of being local to each bus. This both prevents multiple buses from having different configurations (when the hardware supports it), and makes it difficult to move from videomode to drm_display_mode as the latter doesn't contain bus polarities and clock edge flags. Add a bus_flags field to the omap_dss_device structure and move the DISPLAY_FLAGS_DE_(LOW|HIGH), DISPLAY_FLAGS_PIXDATA_(POS|NEG)EDGE and DISPLAY_FLAGS_SYNC_(POS|NEG)EDGE videomode flags to bus_flags in all external encoders, connectors and panels. The videomode flags are still used internally for internal encoders, this will be addressed in a second step. The related videomode flags in the default mode of the DVI connector can simply be dropped, as they are always overridden by the TFP410 driver. Note that this results in both the DISPLAY_FLAGS_SYNC_POSEDGE and DISPLAY_FLAGS_SYNC_NEGEDGE flags being set, which is invalid, but only the former is tested for when programming the DISPC, so the DVI connector flags are effectively overridden by the TFP410 flags. Signed-off-by: Laurent Pinchart <laurent.pinchart@ideasonboard.com> Reviewed-by: Sebastian Reichel <sebastian.reichel@collabora.co.uk> Signed-off-by: Tomi Valkeinen <tomi.valkeinen@ti.com>
2018-06-06 19:20:01 +07:00
| DRM_BUS_FLAG_DE_HIGH
| DRM_BUS_FLAG_SYNC_DRIVE_NEGEDGE;
r = omapdss_device_init_output(out);
if (r < 0)
return r;
omapdss_device_register(out);
return 0;
}
static void dsi_uninit_output(struct dsi_data *dsi)
{
struct omap_dss_device *out = &dsi->output;
omapdss_device_unregister(out);
omapdss_device_cleanup_output(out);
}
static int dsi_probe_of(struct dsi_data *dsi)
{
struct device_node *node = dsi->dev->of_node;
struct property *prop;
u32 lane_arr[10];
int len, num_pins;
int r, i;
struct device_node *ep;
struct omap_dsi_pin_config pin_cfg;
ep = of_graph_get_endpoint_by_regs(node, 0, 0);
if (!ep)
return 0;
prop = of_find_property(ep, "lanes", &len);
if (prop == NULL) {
dev_err(dsi->dev, "failed to find lane data\n");
r = -EINVAL;
goto err;
}
num_pins = len / sizeof(u32);
if (num_pins < 4 || num_pins % 2 != 0 ||
num_pins > dsi->num_lanes_supported * 2) {
dev_err(dsi->dev, "bad number of lanes\n");
r = -EINVAL;
goto err;
}
r = of_property_read_u32_array(ep, "lanes", lane_arr, num_pins);
if (r) {
dev_err(dsi->dev, "failed to read lane data\n");
goto err;
}
pin_cfg.num_pins = num_pins;
for (i = 0; i < num_pins; ++i)
pin_cfg.pins[i] = (int)lane_arr[i];
r = dsi_configure_pins(&dsi->output, &pin_cfg);
if (r) {
dev_err(dsi->dev, "failed to configure pins");
goto err;
}
of_node_put(ep);
return 0;
err:
of_node_put(ep);
return r;
}
static const struct dsi_of_data dsi_of_data_omap34xx = {
.model = DSI_MODEL_OMAP3,
.pll_hw = &dss_omap3_dsi_pll_hw,
.modules = (const struct dsi_module_id_data[]) {
{ .address = 0x4804fc00, .id = 0, },
{ },
},
.max_fck_freq = 173000000,
.max_pll_lpdiv = (1 << 13) - 1,
.quirks = DSI_QUIRK_REVERSE_TXCLKESC,
};
static const struct dsi_of_data dsi_of_data_omap36xx = {
.model = DSI_MODEL_OMAP3,
.pll_hw = &dss_omap3_dsi_pll_hw,
.modules = (const struct dsi_module_id_data[]) {
{ .address = 0x4804fc00, .id = 0, },
{ },
},
.max_fck_freq = 173000000,
.max_pll_lpdiv = (1 << 13) - 1,
.quirks = DSI_QUIRK_PLL_PWR_BUG,
};
static const struct dsi_of_data dsi_of_data_omap4 = {
.model = DSI_MODEL_OMAP4,
.pll_hw = &dss_omap4_dsi_pll_hw,
.modules = (const struct dsi_module_id_data[]) {
{ .address = 0x58004000, .id = 0, },
{ .address = 0x58005000, .id = 1, },
{ },
},
.max_fck_freq = 170000000,
.max_pll_lpdiv = (1 << 13) - 1,
.quirks = DSI_QUIRK_DCS_CMD_CONFIG_VC | DSI_QUIRK_VC_OCP_WIDTH
| DSI_QUIRK_GNQ,
};
static const struct dsi_of_data dsi_of_data_omap5 = {
.model = DSI_MODEL_OMAP5,
.pll_hw = &dss_omap5_dsi_pll_hw,
.modules = (const struct dsi_module_id_data[]) {
{ .address = 0x58004000, .id = 0, },
{ .address = 0x58009000, .id = 1, },
{ },
},
.max_fck_freq = 209250000,
.max_pll_lpdiv = (1 << 13) - 1,
.quirks = DSI_QUIRK_DCS_CMD_CONFIG_VC | DSI_QUIRK_VC_OCP_WIDTH
| DSI_QUIRK_GNQ | DSI_QUIRK_PHY_DCC,
};
static const struct of_device_id dsi_of_match[] = {
{ .compatible = "ti,omap3-dsi", .data = &dsi_of_data_omap36xx, },
{ .compatible = "ti,omap4-dsi", .data = &dsi_of_data_omap4, },
{ .compatible = "ti,omap5-dsi", .data = &dsi_of_data_omap5, },
{},
};
static const struct soc_device_attribute dsi_soc_devices[] = {
{ .machine = "OMAP3[45]*", .data = &dsi_of_data_omap34xx },
{ .machine = "AM35*", .data = &dsi_of_data_omap34xx },
{ /* sentinel */ }
};
static int dsi_probe(struct platform_device *pdev)
{
const struct soc_device_attribute *soc;
const struct dsi_module_id_data *d;
struct device *dev = &pdev->dev;
struct dsi_data *dsi;
struct resource *dsi_mem;
struct resource *res;
unsigned int i;
int r;
dsi = devm_kzalloc(dev, sizeof(*dsi), GFP_KERNEL);
if (!dsi)
return -ENOMEM;
dsi->dev = dev;
dev_set_drvdata(dev, dsi);
spin_lock_init(&dsi->irq_lock);
spin_lock_init(&dsi->errors_lock);
dsi->errors = 0;
#ifdef CONFIG_OMAP2_DSS_COLLECT_IRQ_STATS
spin_lock_init(&dsi->irq_stats_lock);
dsi->irq_stats.last_reset = jiffies;
#endif
mutex_init(&dsi->lock);
sema_init(&dsi->bus_lock, 1);
INIT_DEFERRABLE_WORK(&dsi->framedone_timeout_work,
dsi_framedone_timeout_work_callback);
#ifdef DSI_CATCH_MISSING_TE
treewide: setup_timer() -> timer_setup() This converts all remaining cases of the old setup_timer() API into using timer_setup(), where the callback argument is the structure already holding the struct timer_list. These should have no behavioral changes, since they just change which pointer is passed into the callback with the same available pointers after conversion. It handles the following examples, in addition to some other variations. Casting from unsigned long: void my_callback(unsigned long data) { struct something *ptr = (struct something *)data; ... } ... setup_timer(&ptr->my_timer, my_callback, ptr); and forced object casts: void my_callback(struct something *ptr) { ... } ... setup_timer(&ptr->my_timer, my_callback, (unsigned long)ptr); become: void my_callback(struct timer_list *t) { struct something *ptr = from_timer(ptr, t, my_timer); ... } ... timer_setup(&ptr->my_timer, my_callback, 0); Direct function assignments: void my_callback(unsigned long data) { struct something *ptr = (struct something *)data; ... } ... ptr->my_timer.function = my_callback; have a temporary cast added, along with converting the args: void my_callback(struct timer_list *t) { struct something *ptr = from_timer(ptr, t, my_timer); ... } ... ptr->my_timer.function = (TIMER_FUNC_TYPE)my_callback; And finally, callbacks without a data assignment: void my_callback(unsigned long data) { ... } ... setup_timer(&ptr->my_timer, my_callback, 0); have their argument renamed to verify they're unused during conversion: void my_callback(struct timer_list *unused) { ... } ... timer_setup(&ptr->my_timer, my_callback, 0); The conversion is done with the following Coccinelle script: spatch --very-quiet --all-includes --include-headers \ -I ./arch/x86/include -I ./arch/x86/include/generated \ -I ./include -I ./arch/x86/include/uapi \ -I ./arch/x86/include/generated/uapi -I ./include/uapi \ -I ./include/generated/uapi --include ./include/linux/kconfig.h \ --dir . \ --cocci-file ~/src/data/timer_setup.cocci @fix_address_of@ expression e; @@ setup_timer( -&(e) +&e , ...) // Update any raw setup_timer() usages that have a NULL callback, but // would otherwise match change_timer_function_usage, since the latter // will update all function assignments done in the face of a NULL // function initialization in setup_timer(). @change_timer_function_usage_NULL@ expression _E; identifier _timer; type _cast_data; @@ ( -setup_timer(&_E->_timer, NULL, _E); +timer_setup(&_E->_timer, NULL, 0); | -setup_timer(&_E->_timer, NULL, (_cast_data)_E); +timer_setup(&_E->_timer, NULL, 0); | -setup_timer(&_E._timer, NULL, &_E); +timer_setup(&_E._timer, NULL, 0); | -setup_timer(&_E._timer, NULL, (_cast_data)&_E); +timer_setup(&_E._timer, NULL, 0); ) @change_timer_function_usage@ expression _E; identifier _timer; struct timer_list _stl; identifier _callback; type _cast_func, _cast_data; @@ ( -setup_timer(&_E->_timer, _callback, _E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, &_callback, _E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, _callback, (_cast_data)_E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, &_callback, (_cast_data)_E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, (_cast_func)_callback, _E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, (_cast_func)&_callback, _E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, (_cast_func)_callback, (_cast_data)_E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, (_cast_func)&_callback, (_cast_data)_E); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E._timer, _callback, (_cast_data)_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, _callback, (_cast_data)&_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, &_callback, (_cast_data)_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, &_callback, (_cast_data)&_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, (_cast_func)_callback, (_cast_data)_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, (_cast_func)_callback, (_cast_data)&_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, (_cast_func)&_callback, (_cast_data)_E); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, (_cast_func)&_callback, (_cast_data)&_E); +timer_setup(&_E._timer, _callback, 0); | _E->_timer@_stl.function = _callback; | _E->_timer@_stl.function = &_callback; | _E->_timer@_stl.function = (_cast_func)_callback; | _E->_timer@_stl.function = (_cast_func)&_callback; | _E._timer@_stl.function = _callback; | _E._timer@_stl.function = &_callback; | _E._timer@_stl.function = (_cast_func)_callback; | _E._timer@_stl.function = (_cast_func)&_callback; ) // callback(unsigned long arg) @change_callback_handle_cast depends on change_timer_function_usage@ identifier change_timer_function_usage._callback; identifier change_timer_function_usage._timer; type _origtype; identifier _origarg; type _handletype; identifier _handle; @@ void _callback( -_origtype _origarg +struct timer_list *t ) { ( ... when != _origarg _handletype *_handle = -(_handletype *)_origarg; +from_timer(_handle, t, _timer); ... when != _origarg | ... when != _origarg _handletype *_handle = -(void *)_origarg; +from_timer(_handle, t, _timer); ... when != _origarg | ... when != _origarg _handletype *_handle; ... when != _handle _handle = -(_handletype *)_origarg; +from_timer(_handle, t, _timer); ... when != _origarg | ... when != _origarg _handletype *_handle; ... when != _handle _handle = -(void *)_origarg; +from_timer(_handle, t, _timer); ... when != _origarg ) } // callback(unsigned long arg) without existing variable @change_callback_handle_cast_no_arg depends on change_timer_function_usage && !change_callback_handle_cast@ identifier change_timer_function_usage._callback; identifier change_timer_function_usage._timer; type _origtype; identifier _origarg; type _handletype; @@ void _callback( -_origtype _origarg +struct timer_list *t ) { + _handletype *_origarg = from_timer(_origarg, t, _timer); + ... when != _origarg - (_handletype *)_origarg + _origarg ... when != _origarg } // Avoid already converted callbacks. @match_callback_converted depends on change_timer_function_usage && !change_callback_handle_cast && !change_callback_handle_cast_no_arg@ identifier change_timer_function_usage._callback; identifier t; @@ void _callback(struct timer_list *t) { ... } // callback(struct something *handle) @change_callback_handle_arg depends on change_timer_function_usage && !match_callback_converted && !change_callback_handle_cast && !change_callback_handle_cast_no_arg@ identifier change_timer_function_usage._callback; identifier change_timer_function_usage._timer; type _handletype; identifier _handle; @@ void _callback( -_handletype *_handle +struct timer_list *t ) { + _handletype *_handle = from_timer(_handle, t, _timer); ... } // If change_callback_handle_arg ran on an empty function, remove // the added handler. @unchange_callback_handle_arg depends on change_timer_function_usage && change_callback_handle_arg@ identifier change_timer_function_usage._callback; identifier change_timer_function_usage._timer; type _handletype; identifier _handle; identifier t; @@ void _callback(struct timer_list *t) { - _handletype *_handle = from_timer(_handle, t, _timer); } // We only want to refactor the setup_timer() data argument if we've found // the matching callback. This undoes changes in change_timer_function_usage. @unchange_timer_function_usage depends on change_timer_function_usage && !change_callback_handle_cast && !change_callback_handle_cast_no_arg && !change_callback_handle_arg@ expression change_timer_function_usage._E; identifier change_timer_function_usage._timer; identifier change_timer_function_usage._callback; type change_timer_function_usage._cast_data; @@ ( -timer_setup(&_E->_timer, _callback, 0); +setup_timer(&_E->_timer, _callback, (_cast_data)_E); | -timer_setup(&_E._timer, _callback, 0); +setup_timer(&_E._timer, _callback, (_cast_data)&_E); ) // If we fixed a callback from a .function assignment, fix the // assignment cast now. @change_timer_function_assignment depends on change_timer_function_usage && (change_callback_handle_cast || change_callback_handle_cast_no_arg || change_callback_handle_arg)@ expression change_timer_function_usage._E; identifier change_timer_function_usage._timer; identifier change_timer_function_usage._callback; type _cast_func; typedef TIMER_FUNC_TYPE; @@ ( _E->_timer.function = -_callback +(TIMER_FUNC_TYPE)_callback ; | _E->_timer.function = -&_callback +(TIMER_FUNC_TYPE)_callback ; | _E->_timer.function = -(_cast_func)_callback; +(TIMER_FUNC_TYPE)_callback ; | _E->_timer.function = -(_cast_func)&_callback +(TIMER_FUNC_TYPE)_callback ; | _E._timer.function = -_callback +(TIMER_FUNC_TYPE)_callback ; | _E._timer.function = -&_callback; +(TIMER_FUNC_TYPE)_callback ; | _E._timer.function = -(_cast_func)_callback +(TIMER_FUNC_TYPE)_callback ; | _E._timer.function = -(_cast_func)&_callback +(TIMER_FUNC_TYPE)_callback ; ) // Sometimes timer functions are called directly. Replace matched args. @change_timer_function_calls depends on change_timer_function_usage && (change_callback_handle_cast || change_callback_handle_cast_no_arg || change_callback_handle_arg)@ expression _E; identifier change_timer_function_usage._timer; identifier change_timer_function_usage._callback; type _cast_data; @@ _callback( ( -(_cast_data)_E +&_E->_timer | -(_cast_data)&_E +&_E._timer | -_E +&_E->_timer ) ) // If a timer has been configured without a data argument, it can be // converted without regard to the callback argument, since it is unused. @match_timer_function_unused_data@ expression _E; identifier _timer; identifier _callback; @@ ( -setup_timer(&_E->_timer, _callback, 0); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, _callback, 0L); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E->_timer, _callback, 0UL); +timer_setup(&_E->_timer, _callback, 0); | -setup_timer(&_E._timer, _callback, 0); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, _callback, 0L); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_E._timer, _callback, 0UL); +timer_setup(&_E._timer, _callback, 0); | -setup_timer(&_timer, _callback, 0); +timer_setup(&_timer, _callback, 0); | -setup_timer(&_timer, _callback, 0L); +timer_setup(&_timer, _callback, 0); | -setup_timer(&_timer, _callback, 0UL); +timer_setup(&_timer, _callback, 0); | -setup_timer(_timer, _callback, 0); +timer_setup(_timer, _callback, 0); | -setup_timer(_timer, _callback, 0L); +timer_setup(_timer, _callback, 0); | -setup_timer(_timer, _callback, 0UL); +timer_setup(_timer, _callback, 0); ) @change_callback_unused_data depends on match_timer_function_unused_data@ identifier match_timer_function_unused_data._callback; type _origtype; identifier _origarg; @@ void _callback( -_origtype _origarg +struct timer_list *unused ) { ... when != _origarg } Signed-off-by: Kees Cook <keescook@chromium.org>
2017-10-17 04:43:17 +07:00
timer_setup(&dsi->te_timer, dsi_te_timeout, 0);
#endif
dsi_mem = platform_get_resource_byname(pdev, IORESOURCE_MEM, "proto");
dsi->proto_base = devm_ioremap_resource(dev, dsi_mem);
if (IS_ERR(dsi->proto_base))
return PTR_ERR(dsi->proto_base);
res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "phy");
dsi->phy_base = devm_ioremap_resource(dev, res);
if (IS_ERR(dsi->phy_base))
return PTR_ERR(dsi->phy_base);
res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "pll");
dsi->pll_base = devm_ioremap_resource(dev, res);
if (IS_ERR(dsi->pll_base))
return PTR_ERR(dsi->pll_base);
dsi->irq = platform_get_irq(pdev, 0);
if (dsi->irq < 0) {
DSSERR("platform_get_irq failed\n");
return -ENODEV;
}
r = devm_request_irq(dev, dsi->irq, omap_dsi_irq_handler,
IRQF_SHARED, dev_name(dev), dsi);
if (r < 0) {
DSSERR("request_irq failed\n");
return r;
}
dsi->vdds_dsi_reg = devm_regulator_get(dev, "vdd");
if (IS_ERR(dsi->vdds_dsi_reg)) {
if (PTR_ERR(dsi->vdds_dsi_reg) != -EPROBE_DEFER)
DSSERR("can't get DSI VDD regulator\n");
return PTR_ERR(dsi->vdds_dsi_reg);
}
soc = soc_device_match(dsi_soc_devices);
if (soc)
dsi->data = soc->data;
else
dsi->data = of_match_node(dsi_of_match, dev->of_node)->data;
d = dsi->data->modules;
while (d->address != 0 && d->address != dsi_mem->start)
d++;
if (d->address == 0) {
DSSERR("unsupported DSI module\n");
return -ENODEV;
}
dsi->module_id = d->id;
if (dsi->data->model == DSI_MODEL_OMAP4 ||
dsi->data->model == DSI_MODEL_OMAP5) {
struct device_node *np;
/*
* The OMAP4/5 display DT bindings don't reference the padconf
* syscon. Our only option to retrieve it is to find it by name.
*/
np = of_find_node_by_name(NULL,
dsi->data->model == DSI_MODEL_OMAP4 ?
"omap4_padconf_global" : "omap5_padconf_global");
if (!np)
return -ENODEV;
dsi->syscon = syscon_node_to_regmap(np);
of_node_put(np);
}
/* DSI VCs initialization */
for (i = 0; i < ARRAY_SIZE(dsi->vc); i++) {
dsi->vc[i].source = DSI_VC_SOURCE_L4;
dsi->vc[i].dssdev = NULL;
dsi->vc[i].vc_id = 0;
}
r = dsi_get_clocks(dsi);
if (r)
return r;
pm_runtime_enable(dev);
/* DSI on OMAP3 doesn't have register DSI_GNQ, set number
* of data to 3 by default */
if (dsi->data->quirks & DSI_QUIRK_GNQ) {
dsi_runtime_get(dsi);
/* NB_DATA_LANES */
dsi->num_lanes_supported = 1 + REG_GET(dsi, DSI_GNQ, 11, 9);
dsi_runtime_put(dsi);
} else {
dsi->num_lanes_supported = 3;
}
r = of_platform_populate(dev->of_node, NULL, NULL, dev);
if (r) {
DSSERR("Failed to populate DSI child devices: %d\n", r);
goto err_pm_disable;
}
r = dsi_init_output(dsi);
if (r)
goto err_of_depopulate;
r = dsi_probe_of(dsi);
if (r) {
DSSERR("Invalid DSI DT data\n");
goto err_uninit_output;
}
r = component_add(&pdev->dev, &dsi_component_ops);
if (r)
goto err_uninit_output;
return 0;
err_uninit_output:
dsi_uninit_output(dsi);
err_of_depopulate:
of_platform_depopulate(dev);
err_pm_disable:
pm_runtime_disable(dev);
return r;
}
static int dsi_remove(struct platform_device *pdev)
{
struct dsi_data *dsi = platform_get_drvdata(pdev);
component_del(&pdev->dev, &dsi_component_ops);
dsi_uninit_output(dsi);
of_platform_depopulate(&pdev->dev);
pm_runtime_disable(&pdev->dev);
if (dsi->vdds_dsi_reg != NULL && dsi->vdds_dsi_enabled) {
regulator_disable(dsi->vdds_dsi_reg);
dsi->vdds_dsi_enabled = false;
}
return 0;
}
static int dsi_runtime_suspend(struct device *dev)
{
struct dsi_data *dsi = dev_get_drvdata(dev);
dsi->is_enabled = false;
/* ensure the irq handler sees the is_enabled value */
smp_wmb();
/* wait for current handler to finish before turning the DSI off */
synchronize_irq(dsi->irq);
return 0;
}
static int dsi_runtime_resume(struct device *dev)
{
struct dsi_data *dsi = dev_get_drvdata(dev);
dsi->is_enabled = true;
/* ensure the irq handler sees the is_enabled value */
smp_wmb();
return 0;
}
static const struct dev_pm_ops dsi_pm_ops = {
.runtime_suspend = dsi_runtime_suspend,
.runtime_resume = dsi_runtime_resume,
};
struct platform_driver omap_dsihw_driver = {
.probe = dsi_probe,
.remove = dsi_remove,
.driver = {
.name = "omapdss_dsi",
.pm = &dsi_pm_ops,
.of_match_table = dsi_of_match,
.suppress_bind_attrs = true,
},
};