linux_old1/drivers/gpu/drm/i915/dvo_ns2501.c

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/*
*
* Copyright (c) 2012 Gilles Dartiguelongue, Thomas Richter
*
* All Rights Reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sub license, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice (including the
* next paragraph) shall be included in all copies or substantial portions
* of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
*/
#include "dvo.h"
#include "i915_reg.h"
#include "i915_drv.h"
#define NS2501_VID 0x1305
#define NS2501_DID 0x6726
#define NS2501_VID_LO 0x00
#define NS2501_VID_HI 0x01
#define NS2501_DID_LO 0x02
#define NS2501_DID_HI 0x03
#define NS2501_REV 0x04
#define NS2501_RSVD 0x05
#define NS2501_FREQ_LO 0x06
#define NS2501_FREQ_HI 0x07
#define NS2501_REG8 0x08
#define NS2501_8_VEN (1<<5)
#define NS2501_8_HEN (1<<4)
#define NS2501_8_DSEL (1<<3)
#define NS2501_8_BPAS (1<<2)
#define NS2501_8_RSVD (1<<1)
#define NS2501_8_PD (1<<0)
#define NS2501_REG9 0x09
#define NS2501_9_VLOW (1<<7)
#define NS2501_9_MSEL_MASK (0x7<<4)
#define NS2501_9_TSEL (1<<3)
#define NS2501_9_RSEN (1<<2)
#define NS2501_9_RSVD (1<<1)
#define NS2501_9_MDI (1<<0)
#define NS2501_REGC 0x0c
/*
* The following registers are not part of the official datasheet
* and are the result of reverse engineering.
*/
/*
* Register c0 controls how the DVO synchronizes with
* its input.
*/
#define NS2501_REGC0 0xc0
#define NS2501_C0_ENABLE (1<<0) /* enable the DVO sync in general */
#define NS2501_C0_HSYNC (1<<1) /* synchronize horizontal with input */
#define NS2501_C0_VSYNC (1<<2) /* synchronize vertical with input */
#define NS2501_C0_RESET (1<<7) /* reset the synchronization flip/flops */
/*
* Register 41 is somehow related to the sync register and sync
* configuration. It should be 0x32 whenever regC0 is 0x05 (hsync off)
* and 0x00 otherwise.
*/
#define NS2501_REG41 0x41
/*
* this register controls the dithering of the DVO
* One bit enables it, the other define the dithering depth.
* The higher the value, the lower the dithering depth.
*/
#define NS2501_F9_REG 0xf9
#define NS2501_F9_ENABLE (1<<0) /* if set, dithering is enabled */
#define NS2501_F9_DITHER_MASK (0x7f<<1) /* controls the dither depth */
#define NS2501_F9_DITHER_SHIFT 1 /* shifts the dither mask */
/*
* PLL configuration register. This is a pair of registers,
* one single byte register at 1B, and a pair at 1C,1D.
* These registers are counters/dividers.
*/
#define NS2501_REG1B 0x1b /* one byte PLL control register */
#define NS2501_REG1C 0x1c /* low-part of the second register */
#define NS2501_REG1D 0x1d /* high-part of the second register */
/*
* Scaler control registers. Horizontal at b8,b9,
* vertical at 10,11. The scale factor is computed as
* 2^16/control-value. The low-byte comes first.
*/
#define NS2501_REG10 0x10 /* low-byte vertical scaler */
#define NS2501_REG11 0x11 /* high-byte vertical scaler */
#define NS2501_REGB8 0xb8 /* low-byte horizontal scaler */
#define NS2501_REGB9 0xb9 /* high-byte horizontal scaler */
/*
* Display window definition. This consists of four registers
* per dimension. One register pair defines the start of the
* display, one the end.
* As far as I understand, this defines the window within which
* the scaler samples the input.
*/
#define NS2501_REGC1 0xc1 /* low-byte horizontal display start */
#define NS2501_REGC2 0xc2 /* high-byte horizontal display start */
#define NS2501_REGC3 0xc3 /* low-byte horizontal display stop */
#define NS2501_REGC4 0xc4 /* high-byte horizontal display stop */
#define NS2501_REGC5 0xc5 /* low-byte vertical display start */
#define NS2501_REGC6 0xc6 /* high-byte vertical display start */
#define NS2501_REGC7 0xc7 /* low-byte vertical display stop */
#define NS2501_REGC8 0xc8 /* high-byte vertical display stop */
/*
* The following register pair seems to define the start of
* the vertical sync. If automatic syncing is enabled, and the
* register value defines a sync pulse that is later than the
* incoming sync, then the register value is ignored and the
* external hsync triggers the synchronization.
*/
#define NS2501_REG80 0x80 /* low-byte vsync-start */
#define NS2501_REG81 0x81 /* high-byte vsync-start */
/*
* The following register pair seems to define the total number
* of lines created at the output side of the scaler.
* This is again a low-high register pair.
*/
#define NS2501_REG82 0x82 /* output display height, low byte */
#define NS2501_REG83 0x83 /* output display height, high byte */
/*
* The following registers define the end of the front-porch
* in horizontal and vertical position and hence allow to shift
* the image left/right or up/down.
*/
#define NS2501_REG98 0x98 /* horizontal start of display + 256, low */
#define NS2501_REG99 0x99 /* horizontal start of display + 256, high */
#define NS2501_REG8E 0x8e /* vertical start of the display, low byte */
#define NS2501_REG8F 0x8f /* vertical start of the display, high byte */
/*
* The following register pair control the function of the
* backlight and the DVO output. To enable the corresponding
* function, the corresponding bit must be set in both registers.
*/
#define NS2501_REG34 0x34 /* DVO enable functions, first register */
#define NS2501_REG35 0x35 /* DVO enable functions, second register */
#define NS2501_34_ENABLE_OUTPUT (1<<0) /* enable DVO output */
#define NS2501_34_ENABLE_BACKLIGHT (1<<1) /* enable backlight */
/*
* Registers 9C and 9D define the vertical output offset
* of the visible region.
*/
#define NS2501_REG9C 0x9c
#define NS2501_REG9D 0x9d
/*
* The register 9F defines the dithering. This requires the
* scaler to be ON. Bit 0 enables dithering, the remaining
* bits control the depth of the dither. The higher the value,
* the LOWER the dithering amplitude. A good value seems to be
* 15 (total register value).
*/
#define NS2501_REGF9 0xf9
#define NS2501_F9_ENABLE_DITHER (1<<0) /* enable dithering */
#define NS2501_F9_DITHER_MASK (0x7f<<1) /* dither masking */
#define NS2501_F9_DITHER_SHIFT 1 /* upshift of the dither mask */
enum {
MODE_640x480,
MODE_800x600,
MODE_1024x768,
};
struct ns2501_reg {
uint8_t offset;
uint8_t value;
};
/*
* The following structure keeps the complete configuration of
* the DVO, given a specific output configuration.
* This is pretty much guess-work from reverse-engineering, so
* read all this with a grain of salt.
*/
struct ns2501_configuration {
uint8_t sync; /* configuration of the C0 register */
uint8_t conf; /* configuration register 8 */
uint8_t syncb; /* configuration register 41 */
uint8_t dither; /* configuration of the dithering */
uint8_t pll_a; /* PLL configuration, register A, 1B */
uint16_t pll_b; /* PLL configuration, register B, 1C/1D */
uint16_t hstart; /* horizontal start, registers C1/C2 */
uint16_t hstop; /* horizontal total, registers C3/C4 */
uint16_t vstart; /* vertical start, registers C5/C6 */
uint16_t vstop; /* vertical total, registers C7/C8 */
uint16_t vsync; /* manual vertical sync start, 80/81 */
uint16_t vtotal; /* number of lines generated, 82/83 */
uint16_t hpos; /* horizontal position + 256, 98/99 */
uint16_t vpos; /* vertical position, 8e/8f */
uint16_t voffs; /* vertical output offset, 9c/9d */
uint16_t hscale; /* horizontal scaling factor, b8/b9 */
uint16_t vscale; /* vertical scaling factor, 10/11 */
};
/*
* DVO configuration values, partially based on what the BIOS
* of the Fujitsu Lifebook S6010 writes into registers,
* partially found by manual tweaking. These configurations assume
* a 1024x768 panel.
*/
static const struct ns2501_configuration ns2501_modes[] = {
[MODE_640x480] = {
.sync = NS2501_C0_ENABLE | NS2501_C0_VSYNC,
.conf = NS2501_8_VEN | NS2501_8_HEN | NS2501_8_PD,
.syncb = 0x32,
.dither = 0x0f,
.pll_a = 17,
.pll_b = 852,
.hstart = 144,
.hstop = 783,
.vstart = 22,
.vstop = 514,
.vsync = 2047, /* actually, ignored with this config */
.vtotal = 1341,
.hpos = 0,
.vpos = 16,
.voffs = 36,
.hscale = 40960,
.vscale = 40960
},
[MODE_800x600] = {
.sync = NS2501_C0_ENABLE |
NS2501_C0_HSYNC | NS2501_C0_VSYNC,
.conf = NS2501_8_VEN | NS2501_8_HEN | NS2501_8_PD,
.syncb = 0x00,
.dither = 0x0f,
.pll_a = 25,
.pll_b = 612,
.hstart = 215,
.hstop = 1016,
.vstart = 26,
.vstop = 627,
.vsync = 807,
.vtotal = 1341,
.hpos = 0,
.vpos = 4,
.voffs = 35,
.hscale = 51248,
.vscale = 51232
},
[MODE_1024x768] = {
.sync = NS2501_C0_ENABLE | NS2501_C0_VSYNC,
.conf = NS2501_8_VEN | NS2501_8_HEN | NS2501_8_PD,
.syncb = 0x32,
.dither = 0x0f,
.pll_a = 11,
.pll_b = 1350,
.hstart = 276,
.hstop = 1299,
.vstart = 15,
.vstop = 1056,
.vsync = 2047,
.vtotal = 1341,
.hpos = 0,
.vpos = 7,
.voffs = 27,
.hscale = 65535,
.vscale = 65535
}
};
/*
* Other configuration values left by the BIOS of the
* Fujitsu S6010 in the DVO control registers. Their
* value does not depend on the BIOS and their meaning
* is unknown.
*/
static const struct ns2501_reg mode_agnostic_values[] = {
/* 08 is mode specific */
[0] = { .offset = 0x0a, .value = 0x81, },
/* 10,11 are part of the mode specific configuration */
[1] = { .offset = 0x12, .value = 0x02, },
[2] = { .offset = 0x18, .value = 0x07, },
[3] = { .offset = 0x19, .value = 0x00, },
[4] = { .offset = 0x1a, .value = 0x00, }, /* PLL?, ignored */
/* 1b,1c,1d are part of the mode specific configuration */
[5] = { .offset = 0x1e, .value = 0x02, },
[6] = { .offset = 0x1f, .value = 0x40, },
[7] = { .offset = 0x20, .value = 0x00, },
[8] = { .offset = 0x21, .value = 0x00, },
[9] = { .offset = 0x22, .value = 0x00, },
[10] = { .offset = 0x23, .value = 0x00, },
[11] = { .offset = 0x24, .value = 0x00, },
[12] = { .offset = 0x25, .value = 0x00, },
[13] = { .offset = 0x26, .value = 0x00, },
[14] = { .offset = 0x27, .value = 0x00, },
[15] = { .offset = 0x7e, .value = 0x18, },
/* 80-84 are part of the mode-specific configuration */
[16] = { .offset = 0x84, .value = 0x00, },
[17] = { .offset = 0x85, .value = 0x00, },
[18] = { .offset = 0x86, .value = 0x00, },
[19] = { .offset = 0x87, .value = 0x00, },
[20] = { .offset = 0x88, .value = 0x00, },
[21] = { .offset = 0x89, .value = 0x00, },
[22] = { .offset = 0x8a, .value = 0x00, },
[23] = { .offset = 0x8b, .value = 0x00, },
[24] = { .offset = 0x8c, .value = 0x10, },
[25] = { .offset = 0x8d, .value = 0x02, },
/* 8e,8f are part of the mode-specific configuration */
[26] = { .offset = 0x90, .value = 0xff, },
[27] = { .offset = 0x91, .value = 0x07, },
[28] = { .offset = 0x92, .value = 0xa0, },
[29] = { .offset = 0x93, .value = 0x02, },
[30] = { .offset = 0x94, .value = 0x00, },
[31] = { .offset = 0x95, .value = 0x00, },
[32] = { .offset = 0x96, .value = 0x05, },
[33] = { .offset = 0x97, .value = 0x00, },
/* 98,99 are part of the mode-specific configuration */
[34] = { .offset = 0x9a, .value = 0x88, },
[35] = { .offset = 0x9b, .value = 0x00, },
/* 9c,9d are part of the mode-specific configuration */
[36] = { .offset = 0x9e, .value = 0x25, },
[37] = { .offset = 0x9f, .value = 0x03, },
[38] = { .offset = 0xa0, .value = 0x28, },
[39] = { .offset = 0xa1, .value = 0x01, },
[40] = { .offset = 0xa2, .value = 0x28, },
[41] = { .offset = 0xa3, .value = 0x05, },
/* register 0xa4 is mode specific, but 0x80..0x84 works always */
[42] = { .offset = 0xa4, .value = 0x84, },
[43] = { .offset = 0xa5, .value = 0x00, },
[44] = { .offset = 0xa6, .value = 0x00, },
[45] = { .offset = 0xa7, .value = 0x00, },
[46] = { .offset = 0xa8, .value = 0x00, },
/* 0xa9 to 0xab are mode specific, but have no visible effect */
[47] = { .offset = 0xa9, .value = 0x04, },
[48] = { .offset = 0xaa, .value = 0x70, },
[49] = { .offset = 0xab, .value = 0x4f, },
[50] = { .offset = 0xac, .value = 0x00, },
[51] = { .offset = 0xad, .value = 0x00, },
[52] = { .offset = 0xb6, .value = 0x09, },
[53] = { .offset = 0xb7, .value = 0x03, },
/* b8,b9 are part of the mode-specific configuration */
[54] = { .offset = 0xba, .value = 0x00, },
[55] = { .offset = 0xbb, .value = 0x20, },
[56] = { .offset = 0xf3, .value = 0x90, },
[57] = { .offset = 0xf4, .value = 0x00, },
[58] = { .offset = 0xf7, .value = 0x88, },
/* f8 is mode specific, but the value does not matter */
[59] = { .offset = 0xf8, .value = 0x0a, },
[60] = { .offset = 0xf9, .value = 0x00, }
};
static const struct ns2501_reg regs_init[] = {
[0] = { .offset = 0x35, .value = 0xff, },
[1] = { .offset = 0x34, .value = 0x00, },
[2] = { .offset = 0x08, .value = 0x30, },
};
struct ns2501_priv {
bool quiet;
const struct ns2501_configuration *conf;
};
#define NSPTR(d) ((NS2501Ptr)(d->DriverPrivate.ptr))
/*
** Read a register from the ns2501.
** Returns true if successful, false otherwise.
** If it returns false, it might be wise to enable the
** DVO with the above function.
*/
static bool ns2501_readb(struct intel_dvo_device *dvo, int addr, uint8_t * ch)
{
struct ns2501_priv *ns = dvo->dev_priv;
struct i2c_adapter *adapter = dvo->i2c_bus;
u8 out_buf[2];
u8 in_buf[2];
struct i2c_msg msgs[] = {
{
.addr = dvo->slave_addr,
.flags = 0,
.len = 1,
.buf = out_buf,
},
{
.addr = dvo->slave_addr,
.flags = I2C_M_RD,
.len = 1,
.buf = in_buf,
}
};
out_buf[0] = addr;
out_buf[1] = 0;
if (i2c_transfer(adapter, msgs, 2) == 2) {
*ch = in_buf[0];
return true;
}
if (!ns->quiet) {
DRM_DEBUG_KMS
("Unable to read register 0x%02x from %s:0x%02x.\n", addr,
adapter->name, dvo->slave_addr);
}
return false;
}
/*
** Write a register to the ns2501.
** Returns true if successful, false otherwise.
** If it returns false, it might be wise to enable the
** DVO with the above function.
*/
static bool ns2501_writeb(struct intel_dvo_device *dvo, int addr, uint8_t ch)
{
struct ns2501_priv *ns = dvo->dev_priv;
struct i2c_adapter *adapter = dvo->i2c_bus;
uint8_t out_buf[2];
struct i2c_msg msg = {
.addr = dvo->slave_addr,
.flags = 0,
.len = 2,
.buf = out_buf,
};
out_buf[0] = addr;
out_buf[1] = ch;
if (i2c_transfer(adapter, &msg, 1) == 1) {
return true;
}
if (!ns->quiet) {
DRM_DEBUG_KMS("Unable to write register 0x%02x to %s:%d\n",
addr, adapter->name, dvo->slave_addr);
}
return false;
}
/* National Semiconductor 2501 driver for chip on i2c bus
* scan for the chip on the bus.
* Hope the VBIOS initialized the PLL correctly so we can
* talk to it. If not, it will not be seen and not detected.
* Bummer!
*/
static bool ns2501_init(struct intel_dvo_device *dvo,
struct i2c_adapter *adapter)
{
/* this will detect the NS2501 chip on the specified i2c bus */
struct ns2501_priv *ns;
unsigned char ch;
ns = kzalloc(sizeof(struct ns2501_priv), GFP_KERNEL);
if (ns == NULL)
return false;
dvo->i2c_bus = adapter;
dvo->dev_priv = ns;
ns->quiet = true;
if (!ns2501_readb(dvo, NS2501_VID_LO, &ch))
goto out;
if (ch != (NS2501_VID & 0xff)) {
DRM_DEBUG_KMS("ns2501 not detected got %d: from %s Slave %d.\n",
ch, adapter->name, dvo->slave_addr);
goto out;
}
if (!ns2501_readb(dvo, NS2501_DID_LO, &ch))
goto out;
if (ch != (NS2501_DID & 0xff)) {
DRM_DEBUG_KMS("ns2501 not detected got %d: from %s Slave %d.\n",
ch, adapter->name, dvo->slave_addr);
goto out;
}
ns->quiet = false;
DRM_DEBUG_KMS("init ns2501 dvo controller successfully!\n");
return true;
out:
kfree(ns);
return false;
}
static enum drm_connector_status ns2501_detect(struct intel_dvo_device *dvo)
{
/*
* This is a Laptop display, it doesn't have hotplugging.
* Even if not, the detection bit of the 2501 is unreliable as
* it only works for some display types.
* It is even more unreliable as the PLL must be active for
* allowing reading from the chiop.
*/
return connector_status_connected;
}
static enum drm_mode_status ns2501_mode_valid(struct intel_dvo_device *dvo,
struct drm_display_mode *mode)
{
DRM_DEBUG_KMS
("is mode valid (hdisplay=%d,htotal=%d,vdisplay=%d,vtotal=%d)\n",
mode->hdisplay, mode->htotal, mode->vdisplay, mode->vtotal);
/*
* Currently, these are all the modes I have data from.
* More might exist. Unclear how to find the native resolution
* of the panel in here so we could always accept it
* by disabling the scaler.
*/
if ((mode->hdisplay == 640 && mode->vdisplay == 480 && mode->clock == 25175) ||
(mode->hdisplay == 800 && mode->vdisplay == 600 && mode->clock == 40000) ||
(mode->hdisplay == 1024 && mode->vdisplay == 768 && mode->clock == 65000)) {
return MODE_OK;
} else {
return MODE_ONE_SIZE; /* Is this a reasonable error? */
}
}
static void ns2501_mode_set(struct intel_dvo_device *dvo,
const struct drm_display_mode *mode,
const struct drm_display_mode *adjusted_mode)
{
const struct ns2501_configuration *conf;
struct ns2501_priv *ns = (struct ns2501_priv *)(dvo->dev_priv);
int mode_idx, i;
DRM_DEBUG_KMS
("set mode (hdisplay=%d,htotal=%d,vdisplay=%d,vtotal=%d).\n",
mode->hdisplay, mode->htotal, mode->vdisplay, mode->vtotal);
DRM_DEBUG_KMS("Detailed requested mode settings are:\n"
"clock : %d kHz\n"
"hdisplay : %d\n"
"hblank start : %d\n"
"hblank end : %d\n"
"hsync start : %d\n"
"hsync end : %d\n"
"htotal : %d\n"
"hskew : %d\n"
"vdisplay : %d\n"
"vblank start : %d\n"
"hblank end : %d\n"
"vsync start : %d\n"
"vsync end : %d\n"
"vtotal : %d\n",
adjusted_mode->crtc_clock,
adjusted_mode->crtc_hdisplay,
adjusted_mode->crtc_hblank_start,
adjusted_mode->crtc_hblank_end,
adjusted_mode->crtc_hsync_start,
adjusted_mode->crtc_hsync_end,
adjusted_mode->crtc_htotal,
adjusted_mode->crtc_hskew,
adjusted_mode->crtc_vdisplay,
adjusted_mode->crtc_vblank_start,
adjusted_mode->crtc_vblank_end,
adjusted_mode->crtc_vsync_start,
adjusted_mode->crtc_vsync_end,
adjusted_mode->crtc_vtotal);
if (mode->hdisplay == 640 && mode->vdisplay == 480)
mode_idx = MODE_640x480;
else if (mode->hdisplay == 800 && mode->vdisplay == 600)
mode_idx = MODE_800x600;
else if (mode->hdisplay == 1024 && mode->vdisplay == 768)
mode_idx = MODE_1024x768;
else
return;
/* Hopefully doing it every time won't hurt... */
for (i = 0; i < ARRAY_SIZE(regs_init); i++)
ns2501_writeb(dvo, regs_init[i].offset, regs_init[i].value);
/* Write the mode-agnostic values */
for (i = 0; i < ARRAY_SIZE(mode_agnostic_values); i++)
ns2501_writeb(dvo, mode_agnostic_values[i].offset,
mode_agnostic_values[i].value);
/* Write now the mode-specific configuration */
conf = ns2501_modes + mode_idx;
ns->conf = conf;
ns2501_writeb(dvo, NS2501_REG8, conf->conf);
ns2501_writeb(dvo, NS2501_REG1B, conf->pll_a);
ns2501_writeb(dvo, NS2501_REG1C, conf->pll_b & 0xff);
ns2501_writeb(dvo, NS2501_REG1D, conf->pll_b >> 8);
ns2501_writeb(dvo, NS2501_REGC1, conf->hstart & 0xff);
ns2501_writeb(dvo, NS2501_REGC2, conf->hstart >> 8);
ns2501_writeb(dvo, NS2501_REGC3, conf->hstop & 0xff);
ns2501_writeb(dvo, NS2501_REGC4, conf->hstop >> 8);
ns2501_writeb(dvo, NS2501_REGC5, conf->vstart & 0xff);
ns2501_writeb(dvo, NS2501_REGC6, conf->vstart >> 8);
ns2501_writeb(dvo, NS2501_REGC7, conf->vstop & 0xff);
ns2501_writeb(dvo, NS2501_REGC8, conf->vstop >> 8);
ns2501_writeb(dvo, NS2501_REG80, conf->vsync & 0xff);
ns2501_writeb(dvo, NS2501_REG81, conf->vsync >> 8);
ns2501_writeb(dvo, NS2501_REG82, conf->vtotal & 0xff);
ns2501_writeb(dvo, NS2501_REG83, conf->vtotal >> 8);
ns2501_writeb(dvo, NS2501_REG98, conf->hpos & 0xff);
ns2501_writeb(dvo, NS2501_REG99, conf->hpos >> 8);
ns2501_writeb(dvo, NS2501_REG8E, conf->vpos & 0xff);
ns2501_writeb(dvo, NS2501_REG8F, conf->vpos >> 8);
ns2501_writeb(dvo, NS2501_REG9C, conf->voffs & 0xff);
ns2501_writeb(dvo, NS2501_REG9D, conf->voffs >> 8);
ns2501_writeb(dvo, NS2501_REGB8, conf->hscale & 0xff);
ns2501_writeb(dvo, NS2501_REGB9, conf->hscale >> 8);
ns2501_writeb(dvo, NS2501_REG10, conf->vscale & 0xff);
ns2501_writeb(dvo, NS2501_REG11, conf->vscale >> 8);
ns2501_writeb(dvo, NS2501_REGF9, conf->dither);
ns2501_writeb(dvo, NS2501_REG41, conf->syncb);
ns2501_writeb(dvo, NS2501_REGC0, conf->sync);
}
/* set the NS2501 power state */
static bool ns2501_get_hw_state(struct intel_dvo_device *dvo)
{
unsigned char ch;
if (!ns2501_readb(dvo, NS2501_REG8, &ch))
return false;
return ch & NS2501_8_PD;
}
/* set the NS2501 power state */
static void ns2501_dpms(struct intel_dvo_device *dvo, bool enable)
{
struct ns2501_priv *ns = (struct ns2501_priv *)(dvo->dev_priv);
DRM_DEBUG_KMS("Trying set the dpms of the DVO to %i\n", enable);
if (enable) {
ns2501_writeb(dvo, NS2501_REGC0, ns->conf->sync | 0x08);
ns2501_writeb(dvo, NS2501_REG41, ns->conf->syncb);
ns2501_writeb(dvo, NS2501_REG34, NS2501_34_ENABLE_OUTPUT);
msleep(15);
ns2501_writeb(dvo, NS2501_REG8,
ns->conf->conf | NS2501_8_BPAS);
if (!(ns->conf->conf & NS2501_8_BPAS))
ns2501_writeb(dvo, NS2501_REG8, ns->conf->conf);
msleep(200);
ns2501_writeb(dvo, NS2501_REG34,
NS2501_34_ENABLE_OUTPUT | NS2501_34_ENABLE_BACKLIGHT);
ns2501_writeb(dvo, NS2501_REGC0, ns->conf->sync);
} else {
ns2501_writeb(dvo, NS2501_REG34, NS2501_34_ENABLE_OUTPUT);
msleep(200);
ns2501_writeb(dvo, NS2501_REG8, NS2501_8_VEN | NS2501_8_HEN |
NS2501_8_BPAS);
msleep(15);
ns2501_writeb(dvo, NS2501_REG34, 0x00);
}
}
static void ns2501_destroy(struct intel_dvo_device *dvo)
{
struct ns2501_priv *ns = dvo->dev_priv;
if (ns) {
kfree(ns);
dvo->dev_priv = NULL;
}
}
struct intel_dvo_dev_ops ns2501_ops = {
.init = ns2501_init,
.detect = ns2501_detect,
.mode_valid = ns2501_mode_valid,
.mode_set = ns2501_mode_set,
.dpms = ns2501_dpms,
.get_hw_state = ns2501_get_hw_state,
.destroy = ns2501_destroy,
};