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linux-pinenote/drivers/gpu/drm/ast/ast_post.c

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drm: Initial KMS driver for AST (ASpeed Technologies) 2000 series (v2) This is the initial driver for the Aspeed Technologies chips found in servers. This driver supports the AST 2000, 2100, 2200, 2150 and 2300. It doesn't support the AST11xx due to lack of hw to test it on, and them requiring different codepaths. This driver is intended to be used with xf86-video-modesetting in userspace. This driver has a slightly different design than other KMS drivers, but future server chips will probably share similiar setup. As these GPUs commonly have low video RAM, it doesn't make sense to put the kms console in VRAM always. This driver places the kms console into system RAM, and does dirty updates to a copy in video RAM. When userspace sets a new scanout buffer, it forcefully evicts the video RAM console, and X can create a framebuffer that can use all of of video RAM. This driver uses TTM but in a very simple fashion to control the eviction to system RAM of the console, and multiple servers. v2: add s/r support, fix Kconfig. Signed-off-by: Dave Airlie <airlied@redhat.com>
2012-02-29 13:40:04 +00:00
/*
* Copyright 2012 Red Hat Inc.
*
* 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 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 COPYRIGHT HOLDERS, AUTHORS AND/OR ITS SUPPLIERS 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.
*
* The above copyright notice and this permission notice (including the
* next paragraph) shall be included in all copies or substantial portions
* of the Software.
*
*/
/*
* Authors: Dave Airlie <airlied@redhat.com>
*/
UAPI: (Scripted) Convert #include "..." to #include <path/...> in drivers/gpu/ Convert #include "..." to #include <path/...> in drivers/gpu/. Signed-off-by: David Howells <dhowells@redhat.com> Acked-by: Dave Airlie <airlied@redhat.com> Acked-by: Arnd Bergmann <arnd@arndb.de> Acked-by: Thomas Gleixner <tglx@linutronix.de> Acked-by: Paul E. McKenney <paulmck@linux.vnet.ibm.com> Acked-by: Dave Jones <davej@redhat.com>
2012-10-02 18:01:07 +01:00
#include <drm/drmP.h>
drm: Initial KMS driver for AST (ASpeed Technologies) 2000 series (v2) This is the initial driver for the Aspeed Technologies chips found in servers. This driver supports the AST 2000, 2100, 2200, 2150 and 2300. It doesn't support the AST11xx due to lack of hw to test it on, and them requiring different codepaths. This driver is intended to be used with xf86-video-modesetting in userspace. This driver has a slightly different design than other KMS drivers, but future server chips will probably share similiar setup. As these GPUs commonly have low video RAM, it doesn't make sense to put the kms console in VRAM always. This driver places the kms console into system RAM, and does dirty updates to a copy in video RAM. When userspace sets a new scanout buffer, it forcefully evicts the video RAM console, and X can create a framebuffer that can use all of of video RAM. This driver uses TTM but in a very simple fashion to control the eviction to system RAM of the console, and multiple servers. v2: add s/r support, fix Kconfig. Signed-off-by: Dave Airlie <airlied@redhat.com>
2012-02-29 13:40:04 +00:00
#include "ast_drv.h"
#include "ast_dram_tables.h"
static void ast_init_dram_2300(struct drm_device *dev);
static void
ast_enable_vga(struct drm_device *dev)
{
struct ast_private *ast = dev->dev_private;
ast_io_write8(ast, 0x43, 0x01);
ast_io_write8(ast, 0x42, 0x01);
}
#if 0 /* will use later */
static bool
ast_is_vga_enabled(struct drm_device *dev)
{
struct ast_private *ast = dev->dev_private;
u8 ch;
if (ast->chip == AST1180) {
/* TODO 1180 */
} else {
ch = ast_io_read8(ast, 0x43);
if (ch) {
ast_open_key(ast);
ch = ast_get_index_reg_mask(ast, AST_IO_CRTC_PORT, 0xb6, 0xff);
return ch & 0x04;
}
}
return 0;
}
#endif
static const u8 extreginfo[] = { 0x0f, 0x04, 0x1c, 0xff };
static const u8 extreginfo_ast2300a0[] = { 0x0f, 0x04, 0x1c, 0xff };
static const u8 extreginfo_ast2300[] = { 0x0f, 0x04, 0x1f, 0xff };
static void
ast_set_def_ext_reg(struct drm_device *dev)
{
struct ast_private *ast = dev->dev_private;
u8 i, index, reg;
const u8 *ext_reg_info;
/* reset scratch */
for (i = 0x81; i <= 0x8f; i++)
ast_set_index_reg(ast, AST_IO_CRTC_PORT, i, 0x00);
if (ast->chip == AST2300) {
if (dev->pdev->revision >= 0x20)
ext_reg_info = extreginfo_ast2300;
else
ext_reg_info = extreginfo_ast2300a0;
} else
ext_reg_info = extreginfo;
index = 0xa0;
while (*ext_reg_info != 0xff) {
ast_set_index_reg_mask(ast, AST_IO_CRTC_PORT, index, 0x00, *ext_reg_info);
index++;
ext_reg_info++;
}
/* disable standard IO/MEM decode if secondary */
/* ast_set_index_reg-mask(ast, AST_IO_CRTC_PORT, 0xa1, 0xff, 0x3); */
/* Set Ext. Default */
ast_set_index_reg_mask(ast, AST_IO_CRTC_PORT, 0x8c, 0x00, 0x01);
ast_set_index_reg_mask(ast, AST_IO_CRTC_PORT, 0xb7, 0x00, 0x00);
/* Enable RAMDAC for A1 */
reg = 0x04;
if (ast->chip == AST2300)
reg |= 0x20;
ast_set_index_reg_mask(ast, AST_IO_CRTC_PORT, 0xb6, 0xff, reg);
}
static inline u32 mindwm(struct ast_private *ast, u32 r)
{
ast_write32(ast, 0xf004, r & 0xffff0000);
ast_write32(ast, 0xf000, 0x1);
return ast_read32(ast, 0x10000 + (r & 0x0000ffff));
}
static inline void moutdwm(struct ast_private *ast, u32 r, u32 v)
{
ast_write32(ast, 0xf004, r & 0xffff0000);
ast_write32(ast, 0xf000, 0x1);
ast_write32(ast, 0x10000 + (r & 0x0000ffff), v);
}
/*
* AST2100/2150 DLL CBR Setting
*/
#define CBR_SIZE_AST2150 ((16 << 10) - 1)
#define CBR_PASSNUM_AST2150 5
#define CBR_THRESHOLD_AST2150 10
#define CBR_THRESHOLD2_AST2150 10
#define TIMEOUT_AST2150 5000000
#define CBR_PATNUM_AST2150 8
static const u32 pattern_AST2150[14] = {
0xFF00FF00,
0xCC33CC33,
0xAA55AA55,
0xFFFE0001,
0x683501FE,
0x0F1929B0,
0x2D0B4346,
0x60767F02,
0x6FBE36A6,
0x3A253035,
0x3019686D,
0x41C6167E,
0x620152BF,
0x20F050E0
};
static u32 mmctestburst2_ast2150(struct ast_private *ast, u32 datagen)
{
u32 data, timeout;
moutdwm(ast, 0x1e6e0070, 0x00000000);
moutdwm(ast, 0x1e6e0070, 0x00000001 | (datagen << 3));
timeout = 0;
do {
data = mindwm(ast, 0x1e6e0070) & 0x40;
if (++timeout > TIMEOUT_AST2150) {
moutdwm(ast, 0x1e6e0070, 0x00000000);
return 0xffffffff;
}
} while (!data);
moutdwm(ast, 0x1e6e0070, 0x00000000);
moutdwm(ast, 0x1e6e0070, 0x00000003 | (datagen << 3));
timeout = 0;
do {
data = mindwm(ast, 0x1e6e0070) & 0x40;
if (++timeout > TIMEOUT_AST2150) {
moutdwm(ast, 0x1e6e0070, 0x00000000);
return 0xffffffff;
}
} while (!data);
data = (mindwm(ast, 0x1e6e0070) & 0x80) >> 7;
moutdwm(ast, 0x1e6e0070, 0x00000000);
return data;
}
#if 0 /* unused in DDX driver - here for completeness */
static u32 mmctestsingle2_ast2150(struct ast_private *ast, u32 datagen)
{
u32 data, timeout;
moutdwm(ast, 0x1e6e0070, 0x00000000);
moutdwm(ast, 0x1e6e0070, 0x00000005 | (datagen << 3));
timeout = 0;
do {
data = mindwm(ast, 0x1e6e0070) & 0x40;
if (++timeout > TIMEOUT_AST2150) {
moutdwm(ast, 0x1e6e0070, 0x00000000);
return 0xffffffff;
}
} while (!data);
data = (mindwm(ast, 0x1e6e0070) & 0x80) >> 7;
moutdwm(ast, 0x1e6e0070, 0x00000000);
return data;
}
#endif
static int cbrtest_ast2150(struct ast_private *ast)
{
int i;
for (i = 0; i < 8; i++)
if (mmctestburst2_ast2150(ast, i))
return 0;
return 1;
}
static int cbrscan_ast2150(struct ast_private *ast, int busw)
{
u32 patcnt, loop;
for (patcnt = 0; patcnt < CBR_PATNUM_AST2150; patcnt++) {
moutdwm(ast, 0x1e6e007c, pattern_AST2150[patcnt]);
for (loop = 0; loop < CBR_PASSNUM_AST2150; loop++) {
if (cbrtest_ast2150(ast))
break;
}
if (loop == CBR_PASSNUM_AST2150)
return 0;
}
return 1;
}
static void cbrdlli_ast2150(struct ast_private *ast, int busw)
{
u32 dll_min[4], dll_max[4], dlli, data, passcnt;
cbr_start:
dll_min[0] = dll_min[1] = dll_min[2] = dll_min[3] = 0xff;
dll_max[0] = dll_max[1] = dll_max[2] = dll_max[3] = 0x0;
passcnt = 0;
for (dlli = 0; dlli < 100; dlli++) {
moutdwm(ast, 0x1e6e0068, dlli | (dlli << 8) | (dlli << 16) | (dlli << 24));
data = cbrscan_ast2150(ast, busw);
if (data != 0) {
if (data & 0x1) {
if (dll_min[0] > dlli)
dll_min[0] = dlli;
if (dll_max[0] < dlli)
dll_max[0] = dlli;
}
passcnt++;
} else if (passcnt >= CBR_THRESHOLD_AST2150)
goto cbr_start;
}
if (dll_max[0] == 0 || (dll_max[0]-dll_min[0]) < CBR_THRESHOLD_AST2150)
goto cbr_start;
dlli = dll_min[0] + (((dll_max[0] - dll_min[0]) * 7) >> 4);
moutdwm(ast, 0x1e6e0068, dlli | (dlli << 8) | (dlli << 16) | (dlli << 24));
}
static void ast_init_dram_reg(struct drm_device *dev)
{
struct ast_private *ast = dev->dev_private;
u8 j;
u32 data, temp, i;
const struct ast_dramstruct *dram_reg_info;
j = ast_get_index_reg_mask(ast, AST_IO_CRTC_PORT, 0xd0, 0xff);
if ((j & 0x80) == 0) { /* VGA only */
if (ast->chip == AST2000) {
dram_reg_info = ast2000_dram_table_data;
ast_write32(ast, 0xf004, 0x1e6e0000);
ast_write32(ast, 0xf000, 0x1);
ast_write32(ast, 0x10100, 0xa8);
do {
;
} while (ast_read32(ast, 0x10100) != 0xa8);
} else {/* AST2100/1100 */
if (ast->chip == AST2100 || ast->chip == 2200)
dram_reg_info = ast2100_dram_table_data;
else
dram_reg_info = ast1100_dram_table_data;
ast_write32(ast, 0xf004, 0x1e6e0000);
ast_write32(ast, 0xf000, 0x1);
ast_write32(ast, 0x12000, 0x1688A8A8);
do {
;
} while (ast_read32(ast, 0x12000) != 0x01);
ast_write32(ast, 0x10000, 0xfc600309);
do {
;
} while (ast_read32(ast, 0x10000) != 0x01);
}
while (dram_reg_info->index != 0xffff) {
if (dram_reg_info->index == 0xff00) {/* delay fn */
for (i = 0; i < 15; i++)
udelay(dram_reg_info->data);
} else if (dram_reg_info->index == 0x4 && ast->chip != AST2000) {
data = dram_reg_info->data;
if (ast->dram_type == AST_DRAM_1Gx16)
data = 0x00000d89;
else if (ast->dram_type == AST_DRAM_1Gx32)
data = 0x00000c8d;
temp = ast_read32(ast, 0x12070);
temp &= 0xc;
temp <<= 2;
ast_write32(ast, 0x10000 + dram_reg_info->index, data | temp);
} else
ast_write32(ast, 0x10000 + dram_reg_info->index, dram_reg_info->data);
dram_reg_info++;
}
/* AST 2100/2150 DRAM calibration */
data = ast_read32(ast, 0x10120);
if (data == 0x5061) { /* 266Mhz */
data = ast_read32(ast, 0x10004);
if (data & 0x40)
cbrdlli_ast2150(ast, 16); /* 16 bits */
else
cbrdlli_ast2150(ast, 32); /* 32 bits */
}
switch (ast->chip) {
case AST2000:
temp = ast_read32(ast, 0x10140);
ast_write32(ast, 0x10140, temp | 0x40);
break;
case AST1100:
case AST2100:
case AST2200:
case AST2150:
temp = ast_read32(ast, 0x1200c);
ast_write32(ast, 0x1200c, temp & 0xfffffffd);
temp = ast_read32(ast, 0x12040);
ast_write32(ast, 0x12040, temp | 0x40);
break;
default:
break;
}
}
/* wait ready */
do {
j = ast_get_index_reg_mask(ast, AST_IO_CRTC_PORT, 0xd0, 0xff);
} while ((j & 0x40) == 0);
}
void ast_post_gpu(struct drm_device *dev)
{
u32 reg;
struct ast_private *ast = dev->dev_private;
pci_read_config_dword(ast->dev->pdev, 0x04, &reg);
reg |= 0x3;
pci_write_config_dword(ast->dev->pdev, 0x04, reg);
ast_enable_vga(dev);
ast_open_key(ast);
ast_set_def_ext_reg(dev);
if (ast->chip == AST2300)
ast_init_dram_2300(dev);
else
ast_init_dram_reg(dev);
}
/* AST 2300 DRAM settings */
#define AST_DDR3 0
#define AST_DDR2 1
struct ast2300_dram_param {
u32 dram_type;
u32 dram_chipid;
u32 dram_freq;
u32 vram_size;
u32 odt;
u32 wodt;
u32 rodt;
u32 dram_config;
u32 reg_PERIOD;
u32 reg_MADJ;
u32 reg_SADJ;
u32 reg_MRS;
u32 reg_EMRS;
u32 reg_AC1;
u32 reg_AC2;
u32 reg_DQSIC;
u32 reg_DRV;
u32 reg_IOZ;
u32 reg_DQIDLY;
u32 reg_FREQ;
u32 madj_max;
u32 dll2_finetune_step;
};
/*
* DQSI DLL CBR Setting
*/
#define CBR_SIZE1 ((4 << 10) - 1)
#define CBR_SIZE2 ((64 << 10) - 1)
#define CBR_PASSNUM 5
#define CBR_PASSNUM2 5
#define CBR_THRESHOLD 10
#define CBR_THRESHOLD2 10
#define TIMEOUT 5000000
#define CBR_PATNUM 8
static const u32 pattern[8] = {
0xFF00FF00,
0xCC33CC33,
0xAA55AA55,
0x88778877,
0x92CC4D6E,
0x543D3CDE,
0xF1E843C7,
0x7C61D253
};
#if 0 /* unused in DDX, included for completeness */
static int mmc_test_burst(struct ast_private *ast, u32 datagen)
{
u32 data, timeout;
moutdwm(ast, 0x1e6e0070, 0x00000000);
moutdwm(ast, 0x1e6e0070, 0x000000c1 | (datagen << 3));
timeout = 0;
do {
data = mindwm(ast, 0x1e6e0070) & 0x3000;
if (data & 0x2000) {
return 0;
}
if (++timeout > TIMEOUT) {
moutdwm(ast, 0x1e6e0070, 0x00000000);
return 0;
}
} while (!data);
moutdwm(ast, 0x1e6e0070, 0x00000000);
return 1;
}
#endif
static int mmc_test_burst2(struct ast_private *ast, u32 datagen)
{
u32 data, timeout;
moutdwm(ast, 0x1e6e0070, 0x00000000);
moutdwm(ast, 0x1e6e0070, 0x00000041 | (datagen << 3));
timeout = 0;
do {
data = mindwm(ast, 0x1e6e0070) & 0x1000;
if (++timeout > TIMEOUT) {
moutdwm(ast, 0x1e6e0070, 0x0);
return -1;
}
} while (!data);
data = mindwm(ast, 0x1e6e0078);
data = (data | (data >> 16)) & 0xffff;
moutdwm(ast, 0x1e6e0070, 0x0);
return data;
}
#if 0 /* Unused in DDX here for completeness */
static int mmc_test_single(struct ast_private *ast, u32 datagen)
{
u32 data, timeout;
moutdwm(ast, 0x1e6e0070, 0x00000000);
moutdwm(ast, 0x1e6e0070, 0x000000c5 | (datagen << 3));
timeout = 0;
do {
data = mindwm(ast, 0x1e6e0070) & 0x3000;
if (data & 0x2000)
return 0;
if (++timeout > TIMEOUT) {
moutdwm(ast, 0x1e6e0070, 0x0);
return 0;
}
} while (!data);
moutdwm(ast, 0x1e6e0070, 0x0);
return 1;
}
#endif
static int mmc_test_single2(struct ast_private *ast, u32 datagen)
{
u32 data, timeout;
moutdwm(ast, 0x1e6e0070, 0x00000000);
moutdwm(ast, 0x1e6e0070, 0x00000005 | (datagen << 3));
timeout = 0;
do {
data = mindwm(ast, 0x1e6e0070) & 0x1000;
if (++timeout > TIMEOUT) {
moutdwm(ast, 0x1e6e0070, 0x0);
return -1;
}
} while (!data);
data = mindwm(ast, 0x1e6e0078);
data = (data | (data >> 16)) & 0xffff;
moutdwm(ast, 0x1e6e0070, 0x0);
return data;
}
static int cbr_test(struct ast_private *ast)
{
u32 data;
int i;
data = mmc_test_single2(ast, 0);
if ((data & 0xff) && (data & 0xff00))
return 0;
for (i = 0; i < 8; i++) {
data = mmc_test_burst2(ast, i);
if ((data & 0xff) && (data & 0xff00))
return 0;
}
if (!data)
return 3;
else if (data & 0xff)
return 2;
return 1;
}
static int cbr_scan(struct ast_private *ast)
{
u32 data, data2, patcnt, loop;
data2 = 3;
for (patcnt = 0; patcnt < CBR_PATNUM; patcnt++) {
moutdwm(ast, 0x1e6e007c, pattern[patcnt]);
for (loop = 0; loop < CBR_PASSNUM2; loop++) {
if ((data = cbr_test(ast)) != 0) {
data2 &= data;
if (!data2)
return 0;
break;
}
}
if (loop == CBR_PASSNUM2)
return 0;
}
return data2;
}
static u32 cbr_test2(struct ast_private *ast)
{
u32 data;
data = mmc_test_burst2(ast, 0);
if (data == 0xffff)
return 0;
data |= mmc_test_single2(ast, 0);
if (data == 0xffff)
return 0;
return ~data & 0xffff;
}
static u32 cbr_scan2(struct ast_private *ast)
{
u32 data, data2, patcnt, loop;
data2 = 0xffff;
for (patcnt = 0; patcnt < CBR_PATNUM; patcnt++) {
moutdwm(ast, 0x1e6e007c, pattern[patcnt]);
for (loop = 0; loop < CBR_PASSNUM2; loop++) {
if ((data = cbr_test2(ast)) != 0) {
data2 &= data;
if (!data)
return 0;
break;
}
}
if (loop == CBR_PASSNUM2)
return 0;
}
return data2;
}
#if 0 /* unused in DDX - added for completeness */
static void finetuneDQI(struct ast_private *ast, struct ast2300_dram_param *param)
{
u32 gold_sadj[2], dllmin[16], dllmax[16], dlli, data, cnt, mask, passcnt;
gold_sadj[0] = (mindwm(ast, 0x1E6E0024) >> 16) & 0xffff;
gold_sadj[1] = gold_sadj[0] >> 8;
gold_sadj[0] = gold_sadj[0] & 0xff;
gold_sadj[0] = (gold_sadj[0] + gold_sadj[1]) >> 1;
gold_sadj[1] = gold_sadj[0];
for (cnt = 0; cnt < 16; cnt++) {
dllmin[cnt] = 0xff;
dllmax[cnt] = 0x0;
}
passcnt = 0;
for (dlli = 0; dlli < 76; dlli++) {
moutdwm(ast, 0x1E6E0068, 0x00001400 | (dlli << 16) | (dlli << 24));
/* Wait DQSI latch phase calibration */
moutdwm(ast, 0x1E6E0074, 0x00000010);
moutdwm(ast, 0x1E6E0070, 0x00000003);
do {
data = mindwm(ast, 0x1E6E0070);
} while (!(data & 0x00001000));
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0074, CBR_SIZE1);
data = cbr_scan2(ast);
if (data != 0) {
mask = 0x00010001;
for (cnt = 0; cnt < 16; cnt++) {
if (data & mask) {
if (dllmin[cnt] > dlli) {
dllmin[cnt] = dlli;
}
if (dllmax[cnt] < dlli) {
dllmax[cnt] = dlli;
}
}
mask <<= 1;
}
passcnt++;
} else if (passcnt >= CBR_THRESHOLD) {
break;
}
}
data = 0;
for (cnt = 0; cnt < 8; cnt++) {
data >>= 3;
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD)) {
dlli = (dllmin[cnt] + dllmax[cnt]) >> 1;
if (gold_sadj[0] >= dlli) {
dlli = (gold_sadj[0] - dlli) >> 1;
if (dlli > 3) {
dlli = 3;
}
} else {
dlli = (dlli - gold_sadj[0]) >> 1;
if (dlli > 4) {
dlli = 4;
}
dlli = (8 - dlli) & 0x7;
}
data |= dlli << 21;
}
}
moutdwm(ast, 0x1E6E0080, data);
data = 0;
for (cnt = 8; cnt < 16; cnt++) {
data >>= 3;
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD)) {
dlli = (dllmin[cnt] + dllmax[cnt]) >> 1;
if (gold_sadj[1] >= dlli) {
dlli = (gold_sadj[1] - dlli) >> 1;
if (dlli > 3) {
dlli = 3;
} else {
dlli = (dlli - 1) & 0x7;
}
} else {
dlli = (dlli - gold_sadj[1]) >> 1;
dlli += 1;
if (dlli > 4) {
dlli = 4;
}
dlli = (8 - dlli) & 0x7;
}
data |= dlli << 21;
}
}
moutdwm(ast, 0x1E6E0084, data);
} /* finetuneDQI */
#endif
static void finetuneDQI_L(struct ast_private *ast, struct ast2300_dram_param *param)
{
u32 gold_sadj[2], dllmin[16], dllmax[16], dlli, data, cnt, mask, passcnt;
FINETUNE_START:
for (cnt = 0; cnt < 16; cnt++) {
dllmin[cnt] = 0xff;
dllmax[cnt] = 0x0;
}
passcnt = 0;
for (dlli = 0; dlli < 76; dlli++) {
moutdwm(ast, 0x1E6E0068, 0x00001400 | (dlli << 16) | (dlli << 24));
/* Wait DQSI latch phase calibration */
moutdwm(ast, 0x1E6E0074, 0x00000010);
moutdwm(ast, 0x1E6E0070, 0x00000003);
do {
data = mindwm(ast, 0x1E6E0070);
} while (!(data & 0x00001000));
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0074, CBR_SIZE1);
data = cbr_scan2(ast);
if (data != 0) {
mask = 0x00010001;
for (cnt = 0; cnt < 16; cnt++) {
if (data & mask) {
if (dllmin[cnt] > dlli) {
dllmin[cnt] = dlli;
}
if (dllmax[cnt] < dlli) {
dllmax[cnt] = dlli;
}
}
mask <<= 1;
}
passcnt++;
} else if (passcnt >= CBR_THRESHOLD2) {
break;
}
}
gold_sadj[0] = 0x0;
passcnt = 0;
for (cnt = 0; cnt < 16; cnt++) {
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD2)) {
gold_sadj[0] += dllmin[cnt];
passcnt++;
}
}
if (passcnt != 16) {
goto FINETUNE_START;
}
gold_sadj[0] = gold_sadj[0] >> 4;
gold_sadj[1] = gold_sadj[0];
data = 0;
for (cnt = 0; cnt < 8; cnt++) {
data >>= 3;
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD2)) {
dlli = dllmin[cnt];
if (gold_sadj[0] >= dlli) {
dlli = ((gold_sadj[0] - dlli) * 19) >> 5;
if (dlli > 3) {
dlli = 3;
}
} else {
dlli = ((dlli - gold_sadj[0]) * 19) >> 5;
if (dlli > 4) {
dlli = 4;
}
dlli = (8 - dlli) & 0x7;
}
data |= dlli << 21;
}
}
moutdwm(ast, 0x1E6E0080, data);
data = 0;
for (cnt = 8; cnt < 16; cnt++) {
data >>= 3;
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD2)) {
dlli = dllmin[cnt];
if (gold_sadj[1] >= dlli) {
dlli = ((gold_sadj[1] - dlli) * 19) >> 5;
if (dlli > 3) {
dlli = 3;
} else {
dlli = (dlli - 1) & 0x7;
}
} else {
dlli = ((dlli - gold_sadj[1]) * 19) >> 5;
dlli += 1;
if (dlli > 4) {
dlli = 4;
}
dlli = (8 - dlli) & 0x7;
}
data |= dlli << 21;
}
}
moutdwm(ast, 0x1E6E0084, data);
} /* finetuneDQI_L */
static void finetuneDQI_L2(struct ast_private *ast, struct ast2300_dram_param *param)
{
u32 gold_sadj[2], dllmin[16], dllmax[16], dlli, data, cnt, mask, passcnt, data2;
for (cnt = 0; cnt < 16; cnt++) {
dllmin[cnt] = 0xff;
dllmax[cnt] = 0x0;
}
passcnt = 0;
for (dlli = 0; dlli < 76; dlli++) {
moutdwm(ast, 0x1E6E0068, 0x00001400 | (dlli << 16) | (dlli << 24));
/* Wait DQSI latch phase calibration */
moutdwm(ast, 0x1E6E0074, 0x00000010);
moutdwm(ast, 0x1E6E0070, 0x00000003);
do {
data = mindwm(ast, 0x1E6E0070);
} while (!(data & 0x00001000));
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0074, CBR_SIZE2);
data = cbr_scan2(ast);
if (data != 0) {
mask = 0x00010001;
for (cnt = 0; cnt < 16; cnt++) {
if (data & mask) {
if (dllmin[cnt] > dlli) {
dllmin[cnt] = dlli;
}
if (dllmax[cnt] < dlli) {
dllmax[cnt] = dlli;
}
}
mask <<= 1;
}
passcnt++;
} else if (passcnt >= CBR_THRESHOLD2) {
break;
}
}
gold_sadj[0] = 0x0;
gold_sadj[1] = 0xFF;
for (cnt = 0; cnt < 8; cnt++) {
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD2)) {
if (gold_sadj[0] < dllmin[cnt]) {
gold_sadj[0] = dllmin[cnt];
}
if (gold_sadj[1] > dllmax[cnt]) {
gold_sadj[1] = dllmax[cnt];
}
}
}
gold_sadj[0] = (gold_sadj[1] + gold_sadj[0]) >> 1;
gold_sadj[1] = mindwm(ast, 0x1E6E0080);
data = 0;
for (cnt = 0; cnt < 8; cnt++) {
data >>= 3;
data2 = gold_sadj[1] & 0x7;
gold_sadj[1] >>= 3;
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD2)) {
dlli = (dllmin[cnt] + dllmax[cnt]) >> 1;
if (gold_sadj[0] >= dlli) {
dlli = (gold_sadj[0] - dlli) >> 1;
if (dlli > 0) {
dlli = 1;
}
if (data2 != 3) {
data2 = (data2 + dlli) & 0x7;
}
} else {
dlli = (dlli - gold_sadj[0]) >> 1;
if (dlli > 0) {
dlli = 1;
}
if (data2 != 4) {
data2 = (data2 - dlli) & 0x7;
}
}
}
data |= data2 << 21;
}
moutdwm(ast, 0x1E6E0080, data);
gold_sadj[0] = 0x0;
gold_sadj[1] = 0xFF;
for (cnt = 8; cnt < 16; cnt++) {
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD2)) {
if (gold_sadj[0] < dllmin[cnt]) {
gold_sadj[0] = dllmin[cnt];
}
if (gold_sadj[1] > dllmax[cnt]) {
gold_sadj[1] = dllmax[cnt];
}
}
}
gold_sadj[0] = (gold_sadj[1] + gold_sadj[0]) >> 1;
gold_sadj[1] = mindwm(ast, 0x1E6E0084);
data = 0;
for (cnt = 8; cnt < 16; cnt++) {
data >>= 3;
data2 = gold_sadj[1] & 0x7;
gold_sadj[1] >>= 3;
if ((dllmax[cnt] > dllmin[cnt]) && ((dllmax[cnt] - dllmin[cnt]) >= CBR_THRESHOLD2)) {
dlli = (dllmin[cnt] + dllmax[cnt]) >> 1;
if (gold_sadj[0] >= dlli) {
dlli = (gold_sadj[0] - dlli) >> 1;
if (dlli > 0) {
dlli = 1;
}
if (data2 != 3) {
data2 = (data2 + dlli) & 0x7;
}
} else {
dlli = (dlli - gold_sadj[0]) >> 1;
if (dlli > 0) {
dlli = 1;
}
if (data2 != 4) {
data2 = (data2 - dlli) & 0x7;
}
}
}
data |= data2 << 21;
}
moutdwm(ast, 0x1E6E0084, data);
} /* finetuneDQI_L2 */
static void cbr_dll2(struct ast_private *ast, struct ast2300_dram_param *param)
{
u32 dllmin[2], dllmax[2], dlli, data, data2, passcnt;
finetuneDQI_L(ast, param);
finetuneDQI_L2(ast, param);
CBR_START2:
dllmin[0] = dllmin[1] = 0xff;
dllmax[0] = dllmax[1] = 0x0;
passcnt = 0;
for (dlli = 0; dlli < 76; dlli++) {
moutdwm(ast, 0x1E6E0068, 0x00001300 | (dlli << 16) | (dlli << 24));
/* Wait DQSI latch phase calibration */
moutdwm(ast, 0x1E6E0074, 0x00000010);
moutdwm(ast, 0x1E6E0070, 0x00000003);
do {
data = mindwm(ast, 0x1E6E0070);
} while (!(data & 0x00001000));
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0074, CBR_SIZE2);
data = cbr_scan(ast);
if (data != 0) {
if (data & 0x1) {
if (dllmin[0] > dlli) {
dllmin[0] = dlli;
}
if (dllmax[0] < dlli) {
dllmax[0] = dlli;
}
}
if (data & 0x2) {
if (dllmin[1] > dlli) {
dllmin[1] = dlli;
}
if (dllmax[1] < dlli) {
dllmax[1] = dlli;
}
}
passcnt++;
} else if (passcnt >= CBR_THRESHOLD) {
break;
}
}
if (dllmax[0] == 0 || (dllmax[0]-dllmin[0]) < CBR_THRESHOLD) {
goto CBR_START2;
}
if (dllmax[1] == 0 || (dllmax[1]-dllmin[1]) < CBR_THRESHOLD) {
goto CBR_START2;
}
dlli = (dllmin[1] + dllmax[1]) >> 1;
dlli <<= 8;
dlli += (dllmin[0] + dllmax[0]) >> 1;
moutdwm(ast, 0x1E6E0068, (mindwm(ast, 0x1E6E0068) & 0xFFFF) | (dlli << 16));
data = (mindwm(ast, 0x1E6E0080) >> 24) & 0x1F;
data2 = (mindwm(ast, 0x1E6E0018) & 0xff80ffff) | (data << 16);
moutdwm(ast, 0x1E6E0018, data2);
moutdwm(ast, 0x1E6E0024, 0x8001 | (data << 1) | (param->dll2_finetune_step << 8));
/* Wait DQSI latch phase calibration */
moutdwm(ast, 0x1E6E0074, 0x00000010);
moutdwm(ast, 0x1E6E0070, 0x00000003);
do {
data = mindwm(ast, 0x1E6E0070);
} while (!(data & 0x00001000));
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0070, 0x00000003);
do {
data = mindwm(ast, 0x1E6E0070);
} while (!(data & 0x00001000));
moutdwm(ast, 0x1E6E0070, 0x00000000);
} /* CBRDLL2 */
static void get_ddr3_info(struct ast_private *ast, struct ast2300_dram_param *param)
{
u32 trap, trap_AC2, trap_MRS;
moutdwm(ast, 0x1E6E2000, 0x1688A8A8);
/* Ger trap info */
trap = (mindwm(ast, 0x1E6E2070) >> 25) & 0x3;
trap_AC2 = 0x00020000 + (trap << 16);
trap_AC2 |= 0x00300000 + ((trap & 0x2) << 19);
trap_MRS = 0x00000010 + (trap << 4);
trap_MRS |= ((trap & 0x2) << 18);
param->reg_MADJ = 0x00034C4C;
param->reg_SADJ = 0x00001800;
param->reg_DRV = 0x000000F0;
param->reg_PERIOD = param->dram_freq;
param->rodt = 0;
switch (param->dram_freq) {
case 336:
moutdwm(ast, 0x1E6E2020, 0x0190);
param->wodt = 0;
param->reg_AC1 = 0x22202725;
param->reg_AC2 = 0xAA007613 | trap_AC2;
param->reg_DQSIC = 0x000000BA;
param->reg_MRS = 0x04001400 | trap_MRS;
param->reg_EMRS = 0x00000000;
param->reg_IOZ = 0x00000034;
param->reg_DQIDLY = 0x00000074;
param->reg_FREQ = 0x00004DC0;
param->madj_max = 96;
param->dll2_finetune_step = 3;
break;
default:
case 396:
moutdwm(ast, 0x1E6E2020, 0x03F1);
param->wodt = 1;
param->reg_AC1 = 0x33302825;
param->reg_AC2 = 0xCC009617 | trap_AC2;
param->reg_DQSIC = 0x000000E2;
param->reg_MRS = 0x04001600 | trap_MRS;
param->reg_EMRS = 0x00000000;
param->reg_IOZ = 0x00000034;
param->reg_DRV = 0x000000FA;
param->reg_DQIDLY = 0x00000089;
param->reg_FREQ = 0x000050C0;
param->madj_max = 96;
param->dll2_finetune_step = 4;
switch (param->dram_chipid) {
default:
case AST_DRAM_512Mx16:
case AST_DRAM_1Gx16:
param->reg_AC2 = 0xCC009617 | trap_AC2;
break;
case AST_DRAM_2Gx16:
param->reg_AC2 = 0xCC009622 | trap_AC2;
break;
case AST_DRAM_4Gx16:
param->reg_AC2 = 0xCC00963F | trap_AC2;
break;
}
break;
case 408:
moutdwm(ast, 0x1E6E2020, 0x01F0);
param->wodt = 1;
param->reg_AC1 = 0x33302825;
param->reg_AC2 = 0xCC009617 | trap_AC2;
param->reg_DQSIC = 0x000000E2;
param->reg_MRS = 0x04001600 | trap_MRS;
param->reg_EMRS = 0x00000000;
param->reg_IOZ = 0x00000034;
param->reg_DRV = 0x000000FA;
param->reg_DQIDLY = 0x00000089;
param->reg_FREQ = 0x000050C0;
param->madj_max = 96;
param->dll2_finetune_step = 4;
switch (param->dram_chipid) {
default:
case AST_DRAM_512Mx16:
case AST_DRAM_1Gx16:
param->reg_AC2 = 0xCC009617 | trap_AC2;
break;
case AST_DRAM_2Gx16:
param->reg_AC2 = 0xCC009622 | trap_AC2;
break;
case AST_DRAM_4Gx16:
param->reg_AC2 = 0xCC00963F | trap_AC2;
break;
}
break;
case 456:
moutdwm(ast, 0x1E6E2020, 0x0230);
param->wodt = 0;
param->reg_AC1 = 0x33302926;
param->reg_AC2 = 0xCD44961A;
param->reg_DQSIC = 0x000000FC;
param->reg_MRS = 0x00081830;
param->reg_EMRS = 0x00000000;
param->reg_IOZ = 0x00000045;
param->reg_DQIDLY = 0x00000097;
param->reg_FREQ = 0x000052C0;
param->madj_max = 88;
param->dll2_finetune_step = 4;
break;
case 504:
moutdwm(ast, 0x1E6E2020, 0x0270);
param->wodt = 1;
param->reg_AC1 = 0x33302926;
param->reg_AC2 = 0xDE44A61D;
param->reg_DQSIC = 0x00000117;
param->reg_MRS = 0x00081A30;
param->reg_EMRS = 0x00000000;
param->reg_IOZ = 0x070000BB;
param->reg_DQIDLY = 0x000000A0;
param->reg_FREQ = 0x000054C0;
param->madj_max = 79;
param->dll2_finetune_step = 4;
break;
case 528:
moutdwm(ast, 0x1E6E2020, 0x0290);
param->wodt = 1;
param->rodt = 1;
param->reg_AC1 = 0x33302926;
param->reg_AC2 = 0xEF44B61E;
param->reg_DQSIC = 0x00000125;
param->reg_MRS = 0x00081A30;
param->reg_EMRS = 0x00000040;
param->reg_DRV = 0x000000F5;
param->reg_IOZ = 0x00000023;
param->reg_DQIDLY = 0x00000088;
param->reg_FREQ = 0x000055C0;
param->madj_max = 76;
param->dll2_finetune_step = 3;
break;
case 576:
moutdwm(ast, 0x1E6E2020, 0x0140);
param->reg_MADJ = 0x00136868;
param->reg_SADJ = 0x00004534;
param->wodt = 1;
param->rodt = 1;
param->reg_AC1 = 0x33302A37;
param->reg_AC2 = 0xEF56B61E;
param->reg_DQSIC = 0x0000013F;
param->reg_MRS = 0x00101A50;
param->reg_EMRS = 0x00000040;
param->reg_DRV = 0x000000FA;
param->reg_IOZ = 0x00000023;
param->reg_DQIDLY = 0x00000078;
param->reg_FREQ = 0x000057C0;
param->madj_max = 136;
param->dll2_finetune_step = 3;
break;
case 600:
moutdwm(ast, 0x1E6E2020, 0x02E1);
param->reg_MADJ = 0x00136868;
param->reg_SADJ = 0x00004534;
param->wodt = 1;
param->rodt = 1;
param->reg_AC1 = 0x32302A37;
param->reg_AC2 = 0xDF56B61F;
param->reg_DQSIC = 0x0000014D;
param->reg_MRS = 0x00101A50;
param->reg_EMRS = 0x00000004;
param->reg_DRV = 0x000000F5;
param->reg_IOZ = 0x00000023;
param->reg_DQIDLY = 0x00000078;
param->reg_FREQ = 0x000058C0;
param->madj_max = 132;
param->dll2_finetune_step = 3;
break;
case 624:
moutdwm(ast, 0x1E6E2020, 0x0160);
param->reg_MADJ = 0x00136868;
param->reg_SADJ = 0x00004534;
param->wodt = 1;
param->rodt = 1;
param->reg_AC1 = 0x32302A37;
param->reg_AC2 = 0xEF56B621;
param->reg_DQSIC = 0x0000015A;
param->reg_MRS = 0x02101A50;
param->reg_EMRS = 0x00000004;
param->reg_DRV = 0x000000F5;
param->reg_IOZ = 0x00000034;
param->reg_DQIDLY = 0x00000078;
param->reg_FREQ = 0x000059C0;
param->madj_max = 128;
param->dll2_finetune_step = 3;
break;
} /* switch freq */
switch (param->dram_chipid) {
case AST_DRAM_512Mx16:
param->dram_config = 0x130;
break;
default:
case AST_DRAM_1Gx16:
param->dram_config = 0x131;
break;
case AST_DRAM_2Gx16:
param->dram_config = 0x132;
break;
case AST_DRAM_4Gx16:
param->dram_config = 0x133;
break;
}; /* switch size */
switch (param->vram_size) {
default:
case AST_VIDMEM_SIZE_8M:
param->dram_config |= 0x00;
break;
case AST_VIDMEM_SIZE_16M:
param->dram_config |= 0x04;
break;
case AST_VIDMEM_SIZE_32M:
param->dram_config |= 0x08;
break;
case AST_VIDMEM_SIZE_64M:
param->dram_config |= 0x0c;
break;
}
}
static void ddr3_init(struct ast_private *ast, struct ast2300_dram_param *param)
{
u32 data, data2;
moutdwm(ast, 0x1E6E0000, 0xFC600309);
moutdwm(ast, 0x1E6E0018, 0x00000100);
moutdwm(ast, 0x1E6E0024, 0x00000000);
moutdwm(ast, 0x1E6E0034, 0x00000000);
udelay(10);
moutdwm(ast, 0x1E6E0064, param->reg_MADJ);
moutdwm(ast, 0x1E6E0068, param->reg_SADJ);
udelay(10);
moutdwm(ast, 0x1E6E0064, param->reg_MADJ | 0xC0000);
udelay(10);
moutdwm(ast, 0x1E6E0004, param->dram_config);
moutdwm(ast, 0x1E6E0008, 0x90040f);
moutdwm(ast, 0x1E6E0010, param->reg_AC1);
moutdwm(ast, 0x1E6E0014, param->reg_AC2);
moutdwm(ast, 0x1E6E0020, param->reg_DQSIC);
moutdwm(ast, 0x1E6E0080, 0x00000000);
moutdwm(ast, 0x1E6E0084, 0x00000000);
moutdwm(ast, 0x1E6E0088, param->reg_DQIDLY);
moutdwm(ast, 0x1E6E0018, 0x4040A170);
moutdwm(ast, 0x1E6E0018, 0x20402370);
moutdwm(ast, 0x1E6E0038, 0x00000000);
moutdwm(ast, 0x1E6E0040, 0xFF444444);
moutdwm(ast, 0x1E6E0044, 0x22222222);
moutdwm(ast, 0x1E6E0048, 0x22222222);
moutdwm(ast, 0x1E6E004C, 0x00000002);
moutdwm(ast, 0x1E6E0050, 0x80000000);
moutdwm(ast, 0x1E6E0050, 0x00000000);
moutdwm(ast, 0x1E6E0054, 0);
moutdwm(ast, 0x1E6E0060, param->reg_DRV);
moutdwm(ast, 0x1E6E006C, param->reg_IOZ);
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0074, 0x00000000);
moutdwm(ast, 0x1E6E0078, 0x00000000);
moutdwm(ast, 0x1E6E007C, 0x00000000);
/* Wait MCLK2X lock to MCLK */
do {
data = mindwm(ast, 0x1E6E001C);
} while (!(data & 0x08000000));
moutdwm(ast, 0x1E6E0034, 0x00000001);
moutdwm(ast, 0x1E6E000C, 0x00005C04);
udelay(10);
moutdwm(ast, 0x1E6E000C, 0x00000000);
moutdwm(ast, 0x1E6E0034, 0x00000000);
data = mindwm(ast, 0x1E6E001C);
data = (data >> 8) & 0xff;
while ((data & 0x08) || ((data & 0x7) < 2) || (data < 4)) {
data2 = (mindwm(ast, 0x1E6E0064) & 0xfff3ffff) + 4;
if ((data2 & 0xff) > param->madj_max) {
break;
}
moutdwm(ast, 0x1E6E0064, data2);
if (data2 & 0x00100000) {
data2 = ((data2 & 0xff) >> 3) + 3;
} else {
data2 = ((data2 & 0xff) >> 2) + 5;
}
data = mindwm(ast, 0x1E6E0068) & 0xffff00ff;
data2 += data & 0xff;
data = data | (data2 << 8);
moutdwm(ast, 0x1E6E0068, data);
udelay(10);
moutdwm(ast, 0x1E6E0064, mindwm(ast, 0x1E6E0064) | 0xC0000);
udelay(10);
data = mindwm(ast, 0x1E6E0018) & 0xfffff1ff;
moutdwm(ast, 0x1E6E0018, data);
data = data | 0x200;
moutdwm(ast, 0x1E6E0018, data);
do {
data = mindwm(ast, 0x1E6E001C);
} while (!(data & 0x08000000));
moutdwm(ast, 0x1E6E0034, 0x00000001);
moutdwm(ast, 0x1E6E000C, 0x00005C04);
udelay(10);
moutdwm(ast, 0x1E6E000C, 0x00000000);
moutdwm(ast, 0x1E6E0034, 0x00000000);
data = mindwm(ast, 0x1E6E001C);
data = (data >> 8) & 0xff;
}
data = mindwm(ast, 0x1E6E0018) | 0xC00;
moutdwm(ast, 0x1E6E0018, data);
moutdwm(ast, 0x1E6E0034, 0x00000001);
moutdwm(ast, 0x1E6E000C, 0x00000040);
udelay(50);
/* Mode Register Setting */
moutdwm(ast, 0x1E6E002C, param->reg_MRS | 0x100);
moutdwm(ast, 0x1E6E0030, param->reg_EMRS);
moutdwm(ast, 0x1E6E0028, 0x00000005);
moutdwm(ast, 0x1E6E0028, 0x00000007);
moutdwm(ast, 0x1E6E0028, 0x00000003);
moutdwm(ast, 0x1E6E0028, 0x00000001);
moutdwm(ast, 0x1E6E002C, param->reg_MRS);
moutdwm(ast, 0x1E6E000C, 0x00005C08);
moutdwm(ast, 0x1E6E0028, 0x00000001);
moutdwm(ast, 0x1E6E000C, 0x7FFF5C01);
data = 0;
if (param->wodt) {
data = 0x300;
}
if (param->rodt) {
data = data | 0x3000 | ((param->reg_AC2 & 0x60000) >> 3);
}
moutdwm(ast, 0x1E6E0034, data | 0x3);
/* Wait DQI delay lock */
do {
data = mindwm(ast, 0x1E6E0080);
} while (!(data & 0x40000000));
/* Wait DQSI delay lock */
do {
data = mindwm(ast, 0x1E6E0020);
} while (!(data & 0x00000800));
/* Calibrate the DQSI delay */
cbr_dll2(ast, param);
moutdwm(ast, 0x1E6E0120, param->reg_FREQ);
/* ECC Memory Initialization */
#ifdef ECC
moutdwm(ast, 0x1E6E007C, 0x00000000);
moutdwm(ast, 0x1E6E0070, 0x221);
do {
data = mindwm(ast, 0x1E6E0070);
} while (!(data & 0x00001000));
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0050, 0x80000000);
moutdwm(ast, 0x1E6E0050, 0x00000000);
#endif
}
static void get_ddr2_info(struct ast_private *ast, struct ast2300_dram_param *param)
{
u32 trap, trap_AC2, trap_MRS;
moutdwm(ast, 0x1E6E2000, 0x1688A8A8);
/* Ger trap info */
trap = (mindwm(ast, 0x1E6E2070) >> 25) & 0x3;
trap_AC2 = (trap << 20) | (trap << 16);
trap_AC2 += 0x00110000;
trap_MRS = 0x00000040 | (trap << 4);
param->reg_MADJ = 0x00034C4C;
param->reg_SADJ = 0x00001800;
param->reg_DRV = 0x000000F0;
param->reg_PERIOD = param->dram_freq;
param->rodt = 0;
switch (param->dram_freq) {
case 264:
moutdwm(ast, 0x1E6E2020, 0x0130);
param->wodt = 0;
param->reg_AC1 = 0x11101513;
param->reg_AC2 = 0x78117011;
param->reg_DQSIC = 0x00000092;
param->reg_MRS = 0x00000842;
param->reg_EMRS = 0x00000000;
param->reg_DRV = 0x000000F0;
param->reg_IOZ = 0x00000034;
param->reg_DQIDLY = 0x0000005A;
param->reg_FREQ = 0x00004AC0;
param->madj_max = 138;
param->dll2_finetune_step = 3;
break;
case 336:
moutdwm(ast, 0x1E6E2020, 0x0190);
param->wodt = 1;
param->reg_AC1 = 0x22202613;
param->reg_AC2 = 0xAA009016 | trap_AC2;
param->reg_DQSIC = 0x000000BA;
param->reg_MRS = 0x00000A02 | trap_MRS;
param->reg_EMRS = 0x00000040;
param->reg_DRV = 0x000000FA;
param->reg_IOZ = 0x00000034;
param->reg_DQIDLY = 0x00000074;
param->reg_FREQ = 0x00004DC0;
param->madj_max = 96;
param->dll2_finetune_step = 3;
break;
default:
case 396:
moutdwm(ast, 0x1E6E2020, 0x03F1);
param->wodt = 1;
param->rodt = 0;
param->reg_AC1 = 0x33302714;
param->reg_AC2 = 0xCC00B01B | trap_AC2;
param->reg_DQSIC = 0x000000E2;
param->reg_MRS = 0x00000C02 | trap_MRS;
param->reg_EMRS = 0x00000040;
param->reg_DRV = 0x000000FA;
param->reg_IOZ = 0x00000034;
param->reg_DQIDLY = 0x00000089;
param->reg_FREQ = 0x000050C0;
param->madj_max = 96;
param->dll2_finetune_step = 4;
switch (param->dram_chipid) {
case AST_DRAM_512Mx16:
param->reg_AC2 = 0xCC00B016 | trap_AC2;
break;
default:
case AST_DRAM_1Gx16:
param->reg_AC2 = 0xCC00B01B | trap_AC2;
break;
case AST_DRAM_2Gx16:
param->reg_AC2 = 0xCC00B02B | trap_AC2;
break;
case AST_DRAM_4Gx16:
param->reg_AC2 = 0xCC00B03F | trap_AC2;
break;
}
break;
case 408:
moutdwm(ast, 0x1E6E2020, 0x01F0);
param->wodt = 1;
param->rodt = 0;
param->reg_AC1 = 0x33302714;
param->reg_AC2 = 0xCC00B01B | trap_AC2;
param->reg_DQSIC = 0x000000E2;
param->reg_MRS = 0x00000C02 | trap_MRS;
param->reg_EMRS = 0x00000040;
param->reg_DRV = 0x000000FA;
param->reg_IOZ = 0x00000034;
param->reg_DQIDLY = 0x00000089;
param->reg_FREQ = 0x000050C0;
param->madj_max = 96;
param->dll2_finetune_step = 4;
switch (param->dram_chipid) {
case AST_DRAM_512Mx16:
param->reg_AC2 = 0xCC00B016 | trap_AC2;
break;
default:
case AST_DRAM_1Gx16:
param->reg_AC2 = 0xCC00B01B | trap_AC2;
break;
case AST_DRAM_2Gx16:
param->reg_AC2 = 0xCC00B02B | trap_AC2;
break;
case AST_DRAM_4Gx16:
param->reg_AC2 = 0xCC00B03F | trap_AC2;
break;
}
break;
case 456:
moutdwm(ast, 0x1E6E2020, 0x0230);
param->wodt = 0;
param->reg_AC1 = 0x33302815;
param->reg_AC2 = 0xCD44B01E;
param->reg_DQSIC = 0x000000FC;
param->reg_MRS = 0x00000E72;
param->reg_EMRS = 0x00000000;
param->reg_DRV = 0x00000000;
param->reg_IOZ = 0x00000034;
param->reg_DQIDLY = 0x00000097;
param->reg_FREQ = 0x000052C0;
param->madj_max = 88;
param->dll2_finetune_step = 3;
break;
case 504:
moutdwm(ast, 0x1E6E2020, 0x0261);
param->wodt = 1;
param->rodt = 1;
param->reg_AC1 = 0x33302815;
param->reg_AC2 = 0xDE44C022;
param->reg_DQSIC = 0x00000117;
param->reg_MRS = 0x00000E72;
param->reg_EMRS = 0x00000040;
param->reg_DRV = 0x0000000A;
param->reg_IOZ = 0x00000045;
param->reg_DQIDLY = 0x000000A0;
param->reg_FREQ = 0x000054C0;
param->madj_max = 79;
param->dll2_finetune_step = 3;
break;
case 528:
moutdwm(ast, 0x1E6E2020, 0x0120);
param->wodt = 1;
param->rodt = 1;
param->reg_AC1 = 0x33302815;
param->reg_AC2 = 0xEF44D024;
param->reg_DQSIC = 0x00000125;
param->reg_MRS = 0x00000E72;
param->reg_EMRS = 0x00000004;
param->reg_DRV = 0x000000F9;
param->reg_IOZ = 0x00000045;
param->reg_DQIDLY = 0x000000A7;
param->reg_FREQ = 0x000055C0;
param->madj_max = 76;
param->dll2_finetune_step = 3;
break;
case 552:
moutdwm(ast, 0x1E6E2020, 0x02A1);
param->wodt = 1;
param->rodt = 1;
param->reg_AC1 = 0x43402915;
param->reg_AC2 = 0xFF44E025;
param->reg_DQSIC = 0x00000132;
param->reg_MRS = 0x00000E72;
param->reg_EMRS = 0x00000040;
param->reg_DRV = 0x0000000A;
param->reg_IOZ = 0x00000045;
param->reg_DQIDLY = 0x000000AD;
param->reg_FREQ = 0x000056C0;
param->madj_max = 76;
param->dll2_finetune_step = 3;
break;
case 576:
moutdwm(ast, 0x1E6E2020, 0x0140);
param->wodt = 1;
param->rodt = 1;
param->reg_AC1 = 0x43402915;
param->reg_AC2 = 0xFF44E027;
param->reg_DQSIC = 0x0000013F;
param->reg_MRS = 0x00000E72;
param->reg_EMRS = 0x00000004;
param->reg_DRV = 0x000000F5;
param->reg_IOZ = 0x00000045;
param->reg_DQIDLY = 0x000000B3;
param->reg_FREQ = 0x000057C0;
param->madj_max = 76;
param->dll2_finetune_step = 3;
break;
}
switch (param->dram_chipid) {
case AST_DRAM_512Mx16:
param->dram_config = 0x100;
break;
default:
case AST_DRAM_1Gx16:
param->dram_config = 0x121;
break;
case AST_DRAM_2Gx16:
param->dram_config = 0x122;
break;
case AST_DRAM_4Gx16:
param->dram_config = 0x123;
break;
}; /* switch size */
switch (param->vram_size) {
default:
case AST_VIDMEM_SIZE_8M:
param->dram_config |= 0x00;
break;
case AST_VIDMEM_SIZE_16M:
param->dram_config |= 0x04;
break;
case AST_VIDMEM_SIZE_32M:
param->dram_config |= 0x08;
break;
case AST_VIDMEM_SIZE_64M:
param->dram_config |= 0x0c;
break;
}
}
static void ddr2_init(struct ast_private *ast, struct ast2300_dram_param *param)
{
u32 data, data2;
moutdwm(ast, 0x1E6E0000, 0xFC600309);
moutdwm(ast, 0x1E6E0018, 0x00000100);
moutdwm(ast, 0x1E6E0024, 0x00000000);
moutdwm(ast, 0x1E6E0064, param->reg_MADJ);
moutdwm(ast, 0x1E6E0068, param->reg_SADJ);
udelay(10);
moutdwm(ast, 0x1E6E0064, param->reg_MADJ | 0xC0000);
udelay(10);
moutdwm(ast, 0x1E6E0004, param->dram_config);
moutdwm(ast, 0x1E6E0008, 0x90040f);
moutdwm(ast, 0x1E6E0010, param->reg_AC1);
moutdwm(ast, 0x1E6E0014, param->reg_AC2);
moutdwm(ast, 0x1E6E0020, param->reg_DQSIC);
moutdwm(ast, 0x1E6E0080, 0x00000000);
moutdwm(ast, 0x1E6E0084, 0x00000000);
moutdwm(ast, 0x1E6E0088, param->reg_DQIDLY);
moutdwm(ast, 0x1E6E0018, 0x4040A130);
moutdwm(ast, 0x1E6E0018, 0x20402330);
moutdwm(ast, 0x1E6E0038, 0x00000000);
moutdwm(ast, 0x1E6E0040, 0xFF808000);
moutdwm(ast, 0x1E6E0044, 0x88848466);
moutdwm(ast, 0x1E6E0048, 0x44440008);
moutdwm(ast, 0x1E6E004C, 0x00000000);
moutdwm(ast, 0x1E6E0050, 0x80000000);
moutdwm(ast, 0x1E6E0050, 0x00000000);
moutdwm(ast, 0x1E6E0054, 0);
moutdwm(ast, 0x1E6E0060, param->reg_DRV);
moutdwm(ast, 0x1E6E006C, param->reg_IOZ);
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0074, 0x00000000);
moutdwm(ast, 0x1E6E0078, 0x00000000);
moutdwm(ast, 0x1E6E007C, 0x00000000);
/* Wait MCLK2X lock to MCLK */
do {
data = mindwm(ast, 0x1E6E001C);
} while (!(data & 0x08000000));
moutdwm(ast, 0x1E6E0034, 0x00000001);
moutdwm(ast, 0x1E6E000C, 0x00005C04);
udelay(10);
moutdwm(ast, 0x1E6E000C, 0x00000000);
moutdwm(ast, 0x1E6E0034, 0x00000000);
data = mindwm(ast, 0x1E6E001C);
data = (data >> 8) & 0xff;
while ((data & 0x08) || ((data & 0x7) < 2) || (data < 4)) {
data2 = (mindwm(ast, 0x1E6E0064) & 0xfff3ffff) + 4;
if ((data2 & 0xff) > param->madj_max) {
break;
}
moutdwm(ast, 0x1E6E0064, data2);
if (data2 & 0x00100000) {
data2 = ((data2 & 0xff) >> 3) + 3;
} else {
data2 = ((data2 & 0xff) >> 2) + 5;
}
data = mindwm(ast, 0x1E6E0068) & 0xffff00ff;
data2 += data & 0xff;
data = data | (data2 << 8);
moutdwm(ast, 0x1E6E0068, data);
udelay(10);
moutdwm(ast, 0x1E6E0064, mindwm(ast, 0x1E6E0064) | 0xC0000);
udelay(10);
data = mindwm(ast, 0x1E6E0018) & 0xfffff1ff;
moutdwm(ast, 0x1E6E0018, data);
data = data | 0x200;
moutdwm(ast, 0x1E6E0018, data);
do {
data = mindwm(ast, 0x1E6E001C);
} while (!(data & 0x08000000));
moutdwm(ast, 0x1E6E0034, 0x00000001);
moutdwm(ast, 0x1E6E000C, 0x00005C04);
udelay(10);
moutdwm(ast, 0x1E6E000C, 0x00000000);
moutdwm(ast, 0x1E6E0034, 0x00000000);
data = mindwm(ast, 0x1E6E001C);
data = (data >> 8) & 0xff;
}
data = mindwm(ast, 0x1E6E0018) | 0xC00;
moutdwm(ast, 0x1E6E0018, data);
moutdwm(ast, 0x1E6E0034, 0x00000001);
moutdwm(ast, 0x1E6E000C, 0x00000000);
udelay(50);
/* Mode Register Setting */
moutdwm(ast, 0x1E6E002C, param->reg_MRS | 0x100);
moutdwm(ast, 0x1E6E0030, param->reg_EMRS);
moutdwm(ast, 0x1E6E0028, 0x00000005);
moutdwm(ast, 0x1E6E0028, 0x00000007);
moutdwm(ast, 0x1E6E0028, 0x00000003);
moutdwm(ast, 0x1E6E0028, 0x00000001);
moutdwm(ast, 0x1E6E000C, 0x00005C08);
moutdwm(ast, 0x1E6E002C, param->reg_MRS);
moutdwm(ast, 0x1E6E0028, 0x00000001);
moutdwm(ast, 0x1E6E0030, param->reg_EMRS | 0x380);
moutdwm(ast, 0x1E6E0028, 0x00000003);
moutdwm(ast, 0x1E6E0030, param->reg_EMRS);
moutdwm(ast, 0x1E6E0028, 0x00000003);
moutdwm(ast, 0x1E6E000C, 0x7FFF5C01);
data = 0;
if (param->wodt) {
data = 0x500;
}
if (param->rodt) {
data = data | 0x3000 | ((param->reg_AC2 & 0x60000) >> 3);
}
moutdwm(ast, 0x1E6E0034, data | 0x3);
moutdwm(ast, 0x1E6E0120, param->reg_FREQ);
/* Wait DQI delay lock */
do {
data = mindwm(ast, 0x1E6E0080);
} while (!(data & 0x40000000));
/* Wait DQSI delay lock */
do {
data = mindwm(ast, 0x1E6E0020);
} while (!(data & 0x00000800));
/* Calibrate the DQSI delay */
cbr_dll2(ast, param);
/* ECC Memory Initialization */
#ifdef ECC
moutdwm(ast, 0x1E6E007C, 0x00000000);
moutdwm(ast, 0x1E6E0070, 0x221);
do {
data = mindwm(ast, 0x1E6E0070);
} while (!(data & 0x00001000));
moutdwm(ast, 0x1E6E0070, 0x00000000);
moutdwm(ast, 0x1E6E0050, 0x80000000);
moutdwm(ast, 0x1E6E0050, 0x00000000);
#endif
}
static void ast_init_dram_2300(struct drm_device *dev)
{
struct ast_private *ast = dev->dev_private;
struct ast2300_dram_param param;
u32 temp;
u8 reg;
reg = ast_get_index_reg_mask(ast, AST_IO_CRTC_PORT, 0xd0, 0xff);
if ((reg & 0x80) == 0) {/* vga only */
ast_write32(ast, 0xf004, 0x1e6e0000);
ast_write32(ast, 0xf000, 0x1);
ast_write32(ast, 0x12000, 0x1688a8a8);
do {
;
} while (ast_read32(ast, 0x12000) != 0x1);
ast_write32(ast, 0x10000, 0xfc600309);
do {
;
} while (ast_read32(ast, 0x10000) != 0x1);
/* Slow down CPU/AHB CLK in VGA only mode */
temp = ast_read32(ast, 0x12008);
temp |= 0x73;
ast_write32(ast, 0x12008, temp);
param.dram_type = AST_DDR3;
if (temp & 0x01000000)
param.dram_type = AST_DDR2;
param.dram_chipid = ast->dram_type;
param.dram_freq = ast->mclk;
param.vram_size = ast->vram_size;
if (param.dram_type == AST_DDR3) {
get_ddr3_info(ast, &param);
ddr3_init(ast, &param);
} else {
get_ddr2_info(ast, &param);
ddr2_init(ast, &param);
}
temp = mindwm(ast, 0x1e6e2040);
moutdwm(ast, 0x1e6e2040, temp | 0x40);
}
/* wait ready */
do {
reg = ast_get_index_reg_mask(ast, AST_IO_CRTC_PORT, 0xd0, 0xff);
} while ((reg & 0x40) == 0);
}
Reference in a new issue Copy permalink