kernel-fxtec-pro1x/drivers/gpu/ipu-v3/ipu-di.c
Philipp Zabel 39b9004d1f gpu: ipu-v3: Move i.MX IPUv3 core driver out of staging
The i.MX Image Processing Unit (IPU) contains a number of image processing
blocks that sit right in the middle between DRM and V4L2. Some of the modules,
such as Display Controller, Processor, and Interface (DC, DP, DI) or CMOS
Sensor Interface (CSI) and their FIFOs could be assigned to either framework,
but others, such as the dma controller (IDMAC) and image converter (IC) can
be used by both.
The IPUv3 core driver provides an internal API to access the modules, to be
used by both DRM and V4L2 IPUv3 drivers.

Signed-off-by: Lucas Stach <l.stach@pengutronix.de>
Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
Acked-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-06-04 11:06:52 +02:00

730 lines
18 KiB
C

/*
* Copyright (c) 2010 Sascha Hauer <s.hauer@pengutronix.de>
* Copyright (C) 2005-2009 Freescale Semiconductor, Inc.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 2 of the License, or (at your
* option) any later version.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
* or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* for more details.
*/
#include <linux/export.h>
#include <linux/module.h>
#include <linux/types.h>
#include <linux/errno.h>
#include <linux/io.h>
#include <linux/err.h>
#include <linux/platform_device.h>
#include <video/imx-ipu-v3.h>
#include "ipu-prv.h"
struct ipu_di {
void __iomem *base;
int id;
u32 module;
struct clk *clk_di; /* display input clock */
struct clk *clk_ipu; /* IPU bus clock */
struct clk *clk_di_pixel; /* resulting pixel clock */
bool inuse;
struct ipu_soc *ipu;
};
static DEFINE_MUTEX(di_mutex);
struct di_sync_config {
int run_count;
int run_src;
int offset_count;
int offset_src;
int repeat_count;
int cnt_clr_src;
int cnt_polarity_gen_en;
int cnt_polarity_clr_src;
int cnt_polarity_trigger_src;
int cnt_up;
int cnt_down;
};
enum di_pins {
DI_PIN11 = 0,
DI_PIN12 = 1,
DI_PIN13 = 2,
DI_PIN14 = 3,
DI_PIN15 = 4,
DI_PIN16 = 5,
DI_PIN17 = 6,
DI_PIN_CS = 7,
DI_PIN_SER_CLK = 0,
DI_PIN_SER_RS = 1,
};
enum di_sync_wave {
DI_SYNC_NONE = 0,
DI_SYNC_CLK = 1,
DI_SYNC_INT_HSYNC = 2,
DI_SYNC_HSYNC = 3,
DI_SYNC_VSYNC = 4,
DI_SYNC_DE = 6,
};
#define SYNC_WAVE 0
#define DI_GENERAL 0x0000
#define DI_BS_CLKGEN0 0x0004
#define DI_BS_CLKGEN1 0x0008
#define DI_SW_GEN0(gen) (0x000c + 4 * ((gen) - 1))
#define DI_SW_GEN1(gen) (0x0030 + 4 * ((gen) - 1))
#define DI_STP_REP(gen) (0x0148 + 4 * (((gen) - 1)/2))
#define DI_SYNC_AS_GEN 0x0054
#define DI_DW_GEN(gen) (0x0058 + 4 * (gen))
#define DI_DW_SET(gen, set) (0x0088 + 4 * ((gen) + 0xc * (set)))
#define DI_SER_CONF 0x015c
#define DI_SSC 0x0160
#define DI_POL 0x0164
#define DI_AW0 0x0168
#define DI_AW1 0x016c
#define DI_SCR_CONF 0x0170
#define DI_STAT 0x0174
#define DI_SW_GEN0_RUN_COUNT(x) ((x) << 19)
#define DI_SW_GEN0_RUN_SRC(x) ((x) << 16)
#define DI_SW_GEN0_OFFSET_COUNT(x) ((x) << 3)
#define DI_SW_GEN0_OFFSET_SRC(x) ((x) << 0)
#define DI_SW_GEN1_CNT_POL_GEN_EN(x) ((x) << 29)
#define DI_SW_GEN1_CNT_CLR_SRC(x) ((x) << 25)
#define DI_SW_GEN1_CNT_POL_TRIGGER_SRC(x) ((x) << 12)
#define DI_SW_GEN1_CNT_POL_CLR_SRC(x) ((x) << 9)
#define DI_SW_GEN1_CNT_DOWN(x) ((x) << 16)
#define DI_SW_GEN1_CNT_UP(x) (x)
#define DI_SW_GEN1_AUTO_RELOAD (0x10000000)
#define DI_DW_GEN_ACCESS_SIZE_OFFSET 24
#define DI_DW_GEN_COMPONENT_SIZE_OFFSET 16
#define DI_GEN_POLARITY_1 (1 << 0)
#define DI_GEN_POLARITY_2 (1 << 1)
#define DI_GEN_POLARITY_3 (1 << 2)
#define DI_GEN_POLARITY_4 (1 << 3)
#define DI_GEN_POLARITY_5 (1 << 4)
#define DI_GEN_POLARITY_6 (1 << 5)
#define DI_GEN_POLARITY_7 (1 << 6)
#define DI_GEN_POLARITY_8 (1 << 7)
#define DI_GEN_POLARITY_DISP_CLK (1 << 17)
#define DI_GEN_DI_CLK_EXT (1 << 20)
#define DI_GEN_DI_VSYNC_EXT (1 << 21)
#define DI_POL_DRDY_DATA_POLARITY (1 << 7)
#define DI_POL_DRDY_POLARITY_15 (1 << 4)
#define DI_VSYNC_SEL_OFFSET 13
static inline u32 ipu_di_read(struct ipu_di *di, unsigned offset)
{
return readl(di->base + offset);
}
static inline void ipu_di_write(struct ipu_di *di, u32 value, unsigned offset)
{
writel(value, di->base + offset);
}
static void ipu_di_data_wave_config(struct ipu_di *di,
int wave_gen,
int access_size, int component_size)
{
u32 reg;
reg = (access_size << DI_DW_GEN_ACCESS_SIZE_OFFSET) |
(component_size << DI_DW_GEN_COMPONENT_SIZE_OFFSET);
ipu_di_write(di, reg, DI_DW_GEN(wave_gen));
}
static void ipu_di_data_pin_config(struct ipu_di *di, int wave_gen, int di_pin,
int set, int up, int down)
{
u32 reg;
reg = ipu_di_read(di, DI_DW_GEN(wave_gen));
reg &= ~(0x3 << (di_pin * 2));
reg |= set << (di_pin * 2);
ipu_di_write(di, reg, DI_DW_GEN(wave_gen));
ipu_di_write(di, (down << 16) | up, DI_DW_SET(wave_gen, set));
}
static void ipu_di_sync_config(struct ipu_di *di, struct di_sync_config *config,
int start, int count)
{
u32 reg;
int i;
for (i = 0; i < count; i++) {
struct di_sync_config *c = &config[i];
int wave_gen = start + i + 1;
if ((c->run_count >= 0x1000) || (c->offset_count >= 0x1000) ||
(c->repeat_count >= 0x1000) ||
(c->cnt_up >= 0x400) ||
(c->cnt_down >= 0x400)) {
dev_err(di->ipu->dev, "DI%d counters out of range.\n",
di->id);
return;
}
reg = DI_SW_GEN0_RUN_COUNT(c->run_count) |
DI_SW_GEN0_RUN_SRC(c->run_src) |
DI_SW_GEN0_OFFSET_COUNT(c->offset_count) |
DI_SW_GEN0_OFFSET_SRC(c->offset_src);
ipu_di_write(di, reg, DI_SW_GEN0(wave_gen));
reg = DI_SW_GEN1_CNT_POL_GEN_EN(c->cnt_polarity_gen_en) |
DI_SW_GEN1_CNT_CLR_SRC(c->cnt_clr_src) |
DI_SW_GEN1_CNT_POL_TRIGGER_SRC(
c->cnt_polarity_trigger_src) |
DI_SW_GEN1_CNT_POL_CLR_SRC(c->cnt_polarity_clr_src) |
DI_SW_GEN1_CNT_DOWN(c->cnt_down) |
DI_SW_GEN1_CNT_UP(c->cnt_up);
/* Enable auto reload */
if (c->repeat_count == 0)
reg |= DI_SW_GEN1_AUTO_RELOAD;
ipu_di_write(di, reg, DI_SW_GEN1(wave_gen));
reg = ipu_di_read(di, DI_STP_REP(wave_gen));
reg &= ~(0xffff << (16 * ((wave_gen - 1) & 0x1)));
reg |= c->repeat_count << (16 * ((wave_gen - 1) & 0x1));
ipu_di_write(di, reg, DI_STP_REP(wave_gen));
}
}
static void ipu_di_sync_config_interlaced(struct ipu_di *di,
struct ipu_di_signal_cfg *sig)
{
u32 h_total = sig->width + sig->h_sync_width +
sig->h_start_width + sig->h_end_width;
u32 v_total = sig->height + sig->v_sync_width +
sig->v_start_width + sig->v_end_width;
u32 reg;
struct di_sync_config cfg[] = {
{
.run_count = h_total / 2 - 1,
.run_src = DI_SYNC_CLK,
}, {
.run_count = h_total - 11,
.run_src = DI_SYNC_CLK,
.cnt_down = 4,
}, {
.run_count = v_total * 2 - 1,
.run_src = DI_SYNC_INT_HSYNC,
.offset_count = 1,
.offset_src = DI_SYNC_INT_HSYNC,
.cnt_down = 4,
}, {
.run_count = v_total / 2 - 1,
.run_src = DI_SYNC_HSYNC,
.offset_count = sig->v_start_width,
.offset_src = DI_SYNC_HSYNC,
.repeat_count = 2,
.cnt_clr_src = DI_SYNC_VSYNC,
}, {
.run_src = DI_SYNC_HSYNC,
.repeat_count = sig->height / 2,
.cnt_clr_src = 4,
}, {
.run_count = v_total - 1,
.run_src = DI_SYNC_HSYNC,
}, {
.run_count = v_total / 2 - 1,
.run_src = DI_SYNC_HSYNC,
.offset_count = 9,
.offset_src = DI_SYNC_HSYNC,
.repeat_count = 2,
.cnt_clr_src = DI_SYNC_VSYNC,
}, {
.run_src = DI_SYNC_CLK,
.offset_count = sig->h_start_width,
.offset_src = DI_SYNC_CLK,
.repeat_count = sig->width,
.cnt_clr_src = 5,
}, {
.run_count = v_total - 1,
.run_src = DI_SYNC_INT_HSYNC,
.offset_count = v_total / 2,
.offset_src = DI_SYNC_INT_HSYNC,
.cnt_clr_src = DI_SYNC_HSYNC,
.cnt_down = 4,
}
};
ipu_di_sync_config(di, cfg, 0, ARRAY_SIZE(cfg));
/* set gentime select and tag sel */
reg = ipu_di_read(di, DI_SW_GEN1(9));
reg &= 0x1FFFFFFF;
reg |= (3 - 1) << 29 | 0x00008000;
ipu_di_write(di, reg, DI_SW_GEN1(9));
ipu_di_write(di, v_total / 2 - 1, DI_SCR_CONF);
}
static void ipu_di_sync_config_noninterlaced(struct ipu_di *di,
struct ipu_di_signal_cfg *sig, int div)
{
u32 h_total = sig->width + sig->h_sync_width + sig->h_start_width +
sig->h_end_width;
u32 v_total = sig->height + sig->v_sync_width + sig->v_start_width +
sig->v_end_width;
struct di_sync_config cfg[] = {
{
/* 1: INT_HSYNC */
.run_count = h_total - 1,
.run_src = DI_SYNC_CLK,
} , {
/* PIN2: HSYNC */
.run_count = h_total - 1,
.run_src = DI_SYNC_CLK,
.offset_count = div * sig->v_to_h_sync,
.offset_src = DI_SYNC_CLK,
.cnt_polarity_gen_en = 1,
.cnt_polarity_trigger_src = DI_SYNC_CLK,
.cnt_down = sig->h_sync_width * 2,
} , {
/* PIN3: VSYNC */
.run_count = v_total - 1,
.run_src = DI_SYNC_INT_HSYNC,
.cnt_polarity_gen_en = 1,
.cnt_polarity_trigger_src = DI_SYNC_INT_HSYNC,
.cnt_down = sig->v_sync_width * 2,
} , {
/* 4: Line Active */
.run_src = DI_SYNC_HSYNC,
.offset_count = sig->v_sync_width + sig->v_start_width,
.offset_src = DI_SYNC_HSYNC,
.repeat_count = sig->height,
.cnt_clr_src = DI_SYNC_VSYNC,
} , {
/* 5: Pixel Active, referenced by DC */
.run_src = DI_SYNC_CLK,
.offset_count = sig->h_sync_width + sig->h_start_width,
.offset_src = DI_SYNC_CLK,
.repeat_count = sig->width,
.cnt_clr_src = 5, /* Line Active */
} , {
/* unused */
} , {
/* unused */
} , {
/* unused */
} , {
/* unused */
},
};
/* can't use #7 and #8 for line active and pixel active counters */
struct di_sync_config cfg_vga[] = {
{
/* 1: INT_HSYNC */
.run_count = h_total - 1,
.run_src = DI_SYNC_CLK,
} , {
/* 2: VSYNC */
.run_count = v_total - 1,
.run_src = DI_SYNC_INT_HSYNC,
} , {
/* 3: Line Active */
.run_src = DI_SYNC_INT_HSYNC,
.offset_count = sig->v_sync_width + sig->v_start_width,
.offset_src = DI_SYNC_INT_HSYNC,
.repeat_count = sig->height,
.cnt_clr_src = 3 /* VSYNC */,
} , {
/* PIN4: HSYNC for VGA via TVEv2 on TQ MBa53 */
.run_count = h_total - 1,
.run_src = DI_SYNC_CLK,
.offset_count = div * sig->v_to_h_sync + 18, /* magic value from Freescale TVE driver */
.offset_src = DI_SYNC_CLK,
.cnt_polarity_gen_en = 1,
.cnt_polarity_trigger_src = DI_SYNC_CLK,
.cnt_down = sig->h_sync_width * 2,
} , {
/* 5: Pixel Active signal to DC */
.run_src = DI_SYNC_CLK,
.offset_count = sig->h_sync_width + sig->h_start_width,
.offset_src = DI_SYNC_CLK,
.repeat_count = sig->width,
.cnt_clr_src = 4, /* Line Active */
} , {
/* PIN6: VSYNC for VGA via TVEv2 on TQ MBa53 */
.run_count = v_total - 1,
.run_src = DI_SYNC_INT_HSYNC,
.offset_count = 1, /* magic value from Freescale TVE driver */
.offset_src = DI_SYNC_INT_HSYNC,
.cnt_polarity_gen_en = 1,
.cnt_polarity_trigger_src = DI_SYNC_INT_HSYNC,
.cnt_down = sig->v_sync_width * 2,
} , {
/* PIN4: HSYNC for VGA via TVEv2 on i.MX53-QSB */
.run_count = h_total - 1,
.run_src = DI_SYNC_CLK,
.offset_count = div * sig->v_to_h_sync + 18, /* magic value from Freescale TVE driver */
.offset_src = DI_SYNC_CLK,
.cnt_polarity_gen_en = 1,
.cnt_polarity_trigger_src = DI_SYNC_CLK,
.cnt_down = sig->h_sync_width * 2,
} , {
/* PIN6: VSYNC for VGA via TVEv2 on i.MX53-QSB */
.run_count = v_total - 1,
.run_src = DI_SYNC_INT_HSYNC,
.offset_count = 1, /* magic value from Freescale TVE driver */
.offset_src = DI_SYNC_INT_HSYNC,
.cnt_polarity_gen_en = 1,
.cnt_polarity_trigger_src = DI_SYNC_INT_HSYNC,
.cnt_down = sig->v_sync_width * 2,
} , {
/* unused */
},
};
ipu_di_write(di, v_total - 1, DI_SCR_CONF);
if (sig->hsync_pin == 2 && sig->vsync_pin == 3)
ipu_di_sync_config(di, cfg, 0, ARRAY_SIZE(cfg));
else
ipu_di_sync_config(di, cfg_vga, 0, ARRAY_SIZE(cfg_vga));
}
static void ipu_di_config_clock(struct ipu_di *di,
const struct ipu_di_signal_cfg *sig)
{
struct clk *clk;
unsigned clkgen0;
uint32_t val;
if (sig->clkflags & IPU_DI_CLKMODE_EXT) {
/*
* CLKMODE_EXT means we must use the DI clock: this is
* needed for things like LVDS which needs to feed the
* DI and LDB with the same pixel clock.
*/
clk = di->clk_di;
if (sig->clkflags & IPU_DI_CLKMODE_SYNC) {
/*
* CLKMODE_SYNC means that we want the DI to be
* clocked at the same rate as the parent clock.
* This is needed (eg) for LDB which needs to be
* fed with the same pixel clock. We assume that
* the LDB clock has already been set correctly.
*/
clkgen0 = 1 << 4;
} else {
/*
* We can use the divider. We should really have
* a flag here indicating whether the bridge can
* cope with a fractional divider or not. For the
* time being, let's go for simplicitly and
* reliability.
*/
unsigned long in_rate;
unsigned div;
clk_set_rate(clk, sig->pixelclock);
in_rate = clk_get_rate(clk);
div = (in_rate + sig->pixelclock / 2) / sig->pixelclock;
if (div == 0)
div = 1;
clkgen0 = div << 4;
}
} else {
/*
* For other interfaces, we can arbitarily select between
* the DI specific clock and the internal IPU clock. See
* DI_GENERAL bit 20. We select the IPU clock if it can
* give us a clock rate within 1% of the requested frequency,
* otherwise we use the DI clock.
*/
unsigned long rate, clkrate;
unsigned div, error;
clkrate = clk_get_rate(di->clk_ipu);
div = (clkrate + sig->pixelclock / 2) / sig->pixelclock;
rate = clkrate / div;
error = rate / (sig->pixelclock / 1000);
dev_dbg(di->ipu->dev, " IPU clock can give %lu with divider %u, error %d.%u%%\n",
rate, div, (signed)(error - 1000) / 10, error % 10);
/* Allow a 1% error */
if (error < 1010 && error >= 990) {
clk = di->clk_ipu;
clkgen0 = div << 4;
} else {
unsigned long in_rate;
unsigned div;
clk = di->clk_di;
clk_set_rate(clk, sig->pixelclock);
in_rate = clk_get_rate(clk);
div = (in_rate + sig->pixelclock / 2) / sig->pixelclock;
if (div == 0)
div = 1;
clkgen0 = div << 4;
}
}
di->clk_di_pixel = clk;
/* Set the divider */
ipu_di_write(di, clkgen0, DI_BS_CLKGEN0);
/*
* Set the high/low periods. Bits 24:16 give us the falling edge,
* and bits 8:0 give the rising edge. LSB is fraction, and is
* based on the divider above. We want a 50% duty cycle, so set
* the falling edge to be half the divider.
*/
ipu_di_write(di, (clkgen0 >> 4) << 16, DI_BS_CLKGEN1);
/* Finally select the input clock */
val = ipu_di_read(di, DI_GENERAL) & ~DI_GEN_DI_CLK_EXT;
if (clk == di->clk_di)
val |= DI_GEN_DI_CLK_EXT;
ipu_di_write(di, val, DI_GENERAL);
dev_dbg(di->ipu->dev, "Want %luHz IPU %luHz DI %luHz using %s, %luHz\n",
sig->pixelclock,
clk_get_rate(di->clk_ipu),
clk_get_rate(di->clk_di),
clk == di->clk_di ? "DI" : "IPU",
clk_get_rate(di->clk_di_pixel) / (clkgen0 >> 4));
}
int ipu_di_init_sync_panel(struct ipu_di *di, struct ipu_di_signal_cfg *sig)
{
u32 reg;
u32 di_gen, vsync_cnt;
u32 div;
u32 h_total, v_total;
dev_dbg(di->ipu->dev, "disp %d: panel size = %d x %d\n",
di->id, sig->width, sig->height);
if ((sig->v_sync_width == 0) || (sig->h_sync_width == 0))
return -EINVAL;
h_total = sig->width + sig->h_sync_width + sig->h_start_width +
sig->h_end_width;
v_total = sig->height + sig->v_sync_width + sig->v_start_width +
sig->v_end_width;
dev_dbg(di->ipu->dev, "Clocks: IPU %luHz DI %luHz Needed %luHz\n",
clk_get_rate(di->clk_ipu),
clk_get_rate(di->clk_di),
sig->pixelclock);
mutex_lock(&di_mutex);
ipu_di_config_clock(di, sig);
div = ipu_di_read(di, DI_BS_CLKGEN0) & 0xfff;
div = div / 16; /* Now divider is integer portion */
/* Setup pixel clock timing */
/* Down time is half of period */
ipu_di_write(di, (div << 16), DI_BS_CLKGEN1);
ipu_di_data_wave_config(di, SYNC_WAVE, div - 1, div - 1);
ipu_di_data_pin_config(di, SYNC_WAVE, DI_PIN15, 3, 0, div * 2);
di_gen = ipu_di_read(di, DI_GENERAL) & DI_GEN_DI_CLK_EXT;
di_gen |= DI_GEN_DI_VSYNC_EXT;
if (sig->interlaced) {
ipu_di_sync_config_interlaced(di, sig);
/* set y_sel = 1 */
di_gen |= 0x10000000;
di_gen |= DI_GEN_POLARITY_5;
di_gen |= DI_GEN_POLARITY_8;
vsync_cnt = 7;
if (sig->Hsync_pol)
di_gen |= DI_GEN_POLARITY_3;
if (sig->Vsync_pol)
di_gen |= DI_GEN_POLARITY_2;
} else {
ipu_di_sync_config_noninterlaced(di, sig, div);
vsync_cnt = 3;
if (di->id == 1)
/*
* TODO: change only for TVEv2, parallel display
* uses pin 2 / 3
*/
if (!(sig->hsync_pin == 2 && sig->vsync_pin == 3))
vsync_cnt = 6;
if (sig->Hsync_pol) {
if (sig->hsync_pin == 2)
di_gen |= DI_GEN_POLARITY_2;
else if (sig->hsync_pin == 4)
di_gen |= DI_GEN_POLARITY_4;
else if (sig->hsync_pin == 7)
di_gen |= DI_GEN_POLARITY_7;
}
if (sig->Vsync_pol) {
if (sig->vsync_pin == 3)
di_gen |= DI_GEN_POLARITY_3;
else if (sig->vsync_pin == 6)
di_gen |= DI_GEN_POLARITY_6;
else if (sig->vsync_pin == 8)
di_gen |= DI_GEN_POLARITY_8;
}
}
if (!sig->clk_pol)
di_gen |= DI_GEN_POLARITY_DISP_CLK;
ipu_di_write(di, di_gen, DI_GENERAL);
ipu_di_write(di, (--vsync_cnt << DI_VSYNC_SEL_OFFSET) | 0x00000002,
DI_SYNC_AS_GEN);
reg = ipu_di_read(di, DI_POL);
reg &= ~(DI_POL_DRDY_DATA_POLARITY | DI_POL_DRDY_POLARITY_15);
if (sig->enable_pol)
reg |= DI_POL_DRDY_POLARITY_15;
if (sig->data_pol)
reg |= DI_POL_DRDY_DATA_POLARITY;
ipu_di_write(di, reg, DI_POL);
mutex_unlock(&di_mutex);
return 0;
}
EXPORT_SYMBOL_GPL(ipu_di_init_sync_panel);
int ipu_di_enable(struct ipu_di *di)
{
int ret;
WARN_ON(IS_ERR(di->clk_di_pixel));
ret = clk_prepare_enable(di->clk_di_pixel);
if (ret)
return ret;
ipu_module_enable(di->ipu, di->module);
return 0;
}
EXPORT_SYMBOL_GPL(ipu_di_enable);
int ipu_di_disable(struct ipu_di *di)
{
WARN_ON(IS_ERR(di->clk_di_pixel));
ipu_module_disable(di->ipu, di->module);
clk_disable_unprepare(di->clk_di_pixel);
return 0;
}
EXPORT_SYMBOL_GPL(ipu_di_disable);
int ipu_di_get_num(struct ipu_di *di)
{
return di->id;
}
EXPORT_SYMBOL_GPL(ipu_di_get_num);
static DEFINE_MUTEX(ipu_di_lock);
struct ipu_di *ipu_di_get(struct ipu_soc *ipu, int disp)
{
struct ipu_di *di;
if (disp > 1)
return ERR_PTR(-EINVAL);
di = ipu->di_priv[disp];
mutex_lock(&ipu_di_lock);
if (di->inuse) {
di = ERR_PTR(-EBUSY);
goto out;
}
di->inuse = true;
out:
mutex_unlock(&ipu_di_lock);
return di;
}
EXPORT_SYMBOL_GPL(ipu_di_get);
void ipu_di_put(struct ipu_di *di)
{
mutex_lock(&ipu_di_lock);
di->inuse = false;
mutex_unlock(&ipu_di_lock);
}
EXPORT_SYMBOL_GPL(ipu_di_put);
int ipu_di_init(struct ipu_soc *ipu, struct device *dev, int id,
unsigned long base,
u32 module, struct clk *clk_ipu)
{
struct ipu_di *di;
if (id > 1)
return -ENODEV;
di = devm_kzalloc(dev, sizeof(*di), GFP_KERNEL);
if (!di)
return -ENOMEM;
ipu->di_priv[id] = di;
di->clk_di = devm_clk_get(dev, id ? "di1" : "di0");
if (IS_ERR(di->clk_di))
return PTR_ERR(di->clk_di);
di->module = module;
di->id = id;
di->clk_ipu = clk_ipu;
di->base = devm_ioremap(dev, base, PAGE_SIZE);
if (!di->base)
return -ENOMEM;
ipu_di_write(di, 0x10, DI_BS_CLKGEN0);
dev_dbg(dev, "DI%d base: 0x%08lx remapped to %p\n",
id, base, di->base);
di->inuse = false;
di->ipu = ipu;
return 0;
}
void ipu_di_exit(struct ipu_soc *ipu, int id)
{
}