linux/drivers/gpu/drm/nouveau/nouveau_bios.c
Ben Skeggs 02a841d434 drm/nouveau: restructure source tree, split core from drm implementation
Future work will be headed in the way of separating the policy supplied by
the nouveau drm module from the mechanisms provided by the driver core.

There will be a couple of major classes (subdev, engine) of driver modules
that have clearly defined tasks, and the further directory structure change
is to reflect this.

No code changes here whatsoever, aside from fixing up a couple of include
file pathnames.

Signed-off-by: Ben Skeggs <bskeggs@redhat.com>
2012-10-03 13:12:43 +10:00

6570 lines
176 KiB
C

/*
* Copyright 2005-2006 Erik Waling
* Copyright 2006 Stephane Marchesin
* Copyright 2007-2009 Stuart Bennett
*
* 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, sublicense,
* 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 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 NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS 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 "drmP.h"
#define NV_DEBUG_NOTRACE
#include "nouveau_drv.h"
#include "nouveau_hw.h"
#include "nouveau_encoder.h"
#include <subdev/gpio.h>
#include <linux/io-mapping.h>
#include <linux/firmware.h>
/* these defines are made up */
#define NV_CIO_CRE_44_HEADA 0x0
#define NV_CIO_CRE_44_HEADB 0x3
#define FEATURE_MOBILE 0x10 /* also FEATURE_QUADRO for BMP */
#define EDID1_LEN 128
#define BIOSLOG(sip, fmt, arg...) NV_DEBUG(sip->dev, fmt, ##arg)
#define LOG_OLD_VALUE(x)
struct init_exec {
bool execute;
bool repeat;
};
static bool nv_cksum(const uint8_t *data, unsigned int length)
{
/*
* There's a few checksums in the BIOS, so here's a generic checking
* function.
*/
int i;
uint8_t sum = 0;
for (i = 0; i < length; i++)
sum += data[i];
if (sum)
return true;
return false;
}
static int
score_vbios(struct nvbios *bios, const bool writeable)
{
if (!bios->data || bios->data[0] != 0x55 || bios->data[1] != 0xAA) {
NV_TRACEWARN(bios->dev, "... BIOS signature not found\n");
return 0;
}
if (nv_cksum(bios->data, bios->data[2] * 512)) {
NV_TRACEWARN(bios->dev, "... BIOS checksum invalid\n");
/* if a ro image is somewhat bad, it's probably all rubbish */
return writeable ? 2 : 1;
}
NV_TRACE(bios->dev, "... appears to be valid\n");
return 3;
}
static void
bios_shadow_prom(struct nvbios *bios)
{
struct drm_device *dev = bios->dev;
struct drm_nouveau_private *dev_priv = dev->dev_private;
u32 pcireg, access;
u16 pcir;
int i;
/* enable access to rom */
if (dev_priv->card_type >= NV_50)
pcireg = 0x088050;
else
pcireg = NV_PBUS_PCI_NV_20;
access = nv_mask(dev, pcireg, 0x00000001, 0x00000000);
/* bail if no rom signature, with a workaround for a PROM reading
* issue on some chipsets. the first read after a period of
* inactivity returns the wrong result, so retry the first header
* byte a few times before giving up as a workaround
*/
i = 16;
do {
if (nv_rd08(dev, NV_PROM_OFFSET + 0) == 0x55)
break;
} while (i--);
if (!i || nv_rd08(dev, NV_PROM_OFFSET + 1) != 0xaa)
goto out;
/* additional check (see note below) - read PCI record header */
pcir = nv_rd08(dev, NV_PROM_OFFSET + 0x18) |
nv_rd08(dev, NV_PROM_OFFSET + 0x19) << 8;
if (nv_rd08(dev, NV_PROM_OFFSET + pcir + 0) != 'P' ||
nv_rd08(dev, NV_PROM_OFFSET + pcir + 1) != 'C' ||
nv_rd08(dev, NV_PROM_OFFSET + pcir + 2) != 'I' ||
nv_rd08(dev, NV_PROM_OFFSET + pcir + 3) != 'R')
goto out;
/* read entire bios image to system memory */
bios->length = nv_rd08(dev, NV_PROM_OFFSET + 2) * 512;
bios->data = kmalloc(bios->length, GFP_KERNEL);
if (bios->data) {
for (i = 0; i < bios->length; i++)
bios->data[i] = nv_rd08(dev, NV_PROM_OFFSET + i);
}
out:
/* disable access to rom */
nv_wr32(dev, pcireg, access);
}
static void
bios_shadow_pramin(struct nvbios *bios)
{
struct drm_device *dev = bios->dev;
struct drm_nouveau_private *dev_priv = dev->dev_private;
u32 bar0 = 0;
int i;
if (dev_priv->card_type >= NV_50) {
u64 addr = (u64)(nv_rd32(dev, 0x619f04) & 0xffffff00) << 8;
if (!addr) {
addr = (u64)nv_rd32(dev, 0x001700) << 16;
addr += 0xf0000;
}
bar0 = nv_mask(dev, 0x001700, 0xffffffff, addr >> 16);
}
/* bail if no rom signature */
if (nv_rd08(dev, NV_PRAMIN_OFFSET + 0) != 0x55 ||
nv_rd08(dev, NV_PRAMIN_OFFSET + 1) != 0xaa)
goto out;
bios->length = nv_rd08(dev, NV_PRAMIN_OFFSET + 2) * 512;
bios->data = kmalloc(bios->length, GFP_KERNEL);
if (bios->data) {
for (i = 0; i < bios->length; i++)
bios->data[i] = nv_rd08(dev, NV_PRAMIN_OFFSET + i);
}
out:
if (dev_priv->card_type >= NV_50)
nv_wr32(dev, 0x001700, bar0);
}
static void
bios_shadow_pci(struct nvbios *bios)
{
struct pci_dev *pdev = bios->dev->pdev;
size_t length;
if (!pci_enable_rom(pdev)) {
void __iomem *rom = pci_map_rom(pdev, &length);
if (rom && length) {
bios->data = kmalloc(length, GFP_KERNEL);
if (bios->data) {
memcpy_fromio(bios->data, rom, length);
bios->length = length;
}
}
if (rom)
pci_unmap_rom(pdev, rom);
pci_disable_rom(pdev);
}
}
static void
bios_shadow_acpi(struct nvbios *bios)
{
struct pci_dev *pdev = bios->dev->pdev;
int cnt = 65536 / ROM_BIOS_PAGE;
int ret;
if (!nouveau_acpi_rom_supported(pdev))
return;
bios->data = kmalloc(cnt * ROM_BIOS_PAGE, GFP_KERNEL);
if (!bios->data)
return;
bios->length = 0;
while (cnt--) {
ret = nouveau_acpi_get_bios_chunk(bios->data, bios->length,
ROM_BIOS_PAGE);
if (ret != ROM_BIOS_PAGE)
return;
bios->length += ROM_BIOS_PAGE;
}
}
struct methods {
const char desc[8];
void (*shadow)(struct nvbios *);
const bool rw;
int score;
u32 size;
u8 *data;
};
static bool
bios_shadow(struct drm_device *dev)
{
struct methods shadow_methods[] = {
{ "PRAMIN", bios_shadow_pramin, true, 0, 0, NULL },
{ "PROM", bios_shadow_prom, false, 0, 0, NULL },
{ "ACPI", bios_shadow_acpi, true, 0, 0, NULL },
{ "PCIROM", bios_shadow_pci, true, 0, 0, NULL },
{}
};
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
struct methods *mthd, *best;
const struct firmware *fw;
char fname[32];
int ret;
if (nouveau_vbios) {
/* try to match one of the built-in methods */
mthd = shadow_methods;
do {
if (strcasecmp(nouveau_vbios, mthd->desc))
continue;
NV_INFO(dev, "VBIOS source: %s\n", mthd->desc);
mthd->shadow(bios);
mthd->score = score_vbios(bios, mthd->rw);
if (mthd->score)
return true;
} while ((++mthd)->shadow);
/* attempt to load firmware image */
snprintf(fname, sizeof(fname), "nouveau/%s", nouveau_vbios);
ret = request_firmware(&fw, fname, &dev->pdev->dev);
if (ret == 0) {
bios->length = fw->size;
bios->data = kmemdup(fw->data, fw->size, GFP_KERNEL);
release_firmware(fw);
NV_INFO(dev, "VBIOS image: %s\n", nouveau_vbios);
if (score_vbios(bios, 1))
return true;
kfree(bios->data);
bios->data = NULL;
}
NV_ERROR(dev, "VBIOS source \'%s\' invalid\n", nouveau_vbios);
}
mthd = shadow_methods;
do {
NV_TRACE(dev, "Checking %s for VBIOS\n", mthd->desc);
mthd->shadow(bios);
mthd->score = score_vbios(bios, mthd->rw);
mthd->size = bios->length;
mthd->data = bios->data;
bios->data = NULL;
} while (mthd->score != 3 && (++mthd)->shadow);
mthd = shadow_methods;
best = mthd;
do {
if (mthd->score > best->score) {
kfree(best->data);
best = mthd;
}
} while ((++mthd)->shadow);
if (best->score) {
NV_TRACE(dev, "Using VBIOS from %s\n", best->desc);
bios->length = best->size;
bios->data = best->data;
return true;
}
NV_ERROR(dev, "No valid VBIOS image found\n");
return false;
}
struct init_tbl_entry {
char *name;
uint8_t id;
/* Return:
* > 0: success, length of opcode
* 0: success, but abort further parsing of table (INIT_DONE etc)
* < 0: failure, table parsing will be aborted
*/
int (*handler)(struct nvbios *, uint16_t, struct init_exec *);
};
static int parse_init_table(struct nvbios *, uint16_t, struct init_exec *);
#define MACRO_INDEX_SIZE 2
#define MACRO_SIZE 8
#define CONDITION_SIZE 12
#define IO_FLAG_CONDITION_SIZE 9
#define IO_CONDITION_SIZE 5
#define MEM_INIT_SIZE 66
static void still_alive(void)
{
#if 0
sync();
mdelay(2);
#endif
}
static uint32_t
munge_reg(struct nvbios *bios, uint32_t reg)
{
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
struct dcb_entry *dcbent = bios->display.output;
if (dev_priv->card_type < NV_50)
return reg;
if (reg & 0x80000000) {
BUG_ON(bios->display.crtc < 0);
reg += bios->display.crtc * 0x800;
}
if (reg & 0x40000000) {
BUG_ON(!dcbent);
reg += (ffs(dcbent->or) - 1) * 0x800;
if ((reg & 0x20000000) && !(dcbent->sorconf.link & 1))
reg += 0x00000080;
}
reg &= ~0xe0000000;
return reg;
}
static int
valid_reg(struct nvbios *bios, uint32_t reg)
{
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
struct drm_device *dev = bios->dev;
/* C51 has misaligned regs on purpose. Marvellous */
if (reg & 0x2 ||
(reg & 0x1 && dev_priv->vbios.chip_version != 0x51))
NV_ERROR(dev, "======= misaligned reg 0x%08X =======\n", reg);
/* warn on C51 regs that haven't been verified accessible in tracing */
if (reg & 0x1 && dev_priv->vbios.chip_version == 0x51 &&
reg != 0x130d && reg != 0x1311 && reg != 0x60081d)
NV_WARN(dev, "=== C51 misaligned reg 0x%08X not verified ===\n",
reg);
if (reg >= (8*1024*1024)) {
NV_ERROR(dev, "=== reg 0x%08x out of mapped bounds ===\n", reg);
return 0;
}
return 1;
}
static bool
valid_idx_port(struct nvbios *bios, uint16_t port)
{
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
struct drm_device *dev = bios->dev;
/*
* If adding more ports here, the read/write functions below will need
* updating so that the correct mmio range (PRMCIO, PRMDIO, PRMVIO) is
* used for the port in question
*/
if (dev_priv->card_type < NV_50) {
if (port == NV_CIO_CRX__COLOR)
return true;
if (port == NV_VIO_SRX)
return true;
} else {
if (port == NV_CIO_CRX__COLOR)
return true;
}
NV_ERROR(dev, "========== unknown indexed io port 0x%04X ==========\n",
port);
return false;
}
static bool
valid_port(struct nvbios *bios, uint16_t port)
{
struct drm_device *dev = bios->dev;
/*
* If adding more ports here, the read/write functions below will need
* updating so that the correct mmio range (PRMCIO, PRMDIO, PRMVIO) is
* used for the port in question
*/
if (port == NV_VIO_VSE2)
return true;
NV_ERROR(dev, "========== unknown io port 0x%04X ==========\n", port);
return false;
}
static uint32_t
bios_rd32(struct nvbios *bios, uint32_t reg)
{
uint32_t data;
reg = munge_reg(bios, reg);
if (!valid_reg(bios, reg))
return 0;
/*
* C51 sometimes uses regs with bit0 set in the address. For these
* cases there should exist a translation in a BIOS table to an IO
* port address which the BIOS uses for accessing the reg
*
* These only seem to appear for the power control regs to a flat panel,
* and the GPIO regs at 0x60081*. In C51 mmio traces the normal regs
* for 0x1308 and 0x1310 are used - hence the mask below. An S3
* suspend-resume mmio trace from a C51 will be required to see if this
* is true for the power microcode in 0x14.., or whether the direct IO
* port access method is needed
*/
if (reg & 0x1)
reg &= ~0x1;
data = nv_rd32(bios->dev, reg);
BIOSLOG(bios, " Read: Reg: 0x%08X, Data: 0x%08X\n", reg, data);
return data;
}
static void
bios_wr32(struct nvbios *bios, uint32_t reg, uint32_t data)
{
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
reg = munge_reg(bios, reg);
if (!valid_reg(bios, reg))
return;
/* see note in bios_rd32 */
if (reg & 0x1)
reg &= 0xfffffffe;
LOG_OLD_VALUE(bios_rd32(bios, reg));
BIOSLOG(bios, " Write: Reg: 0x%08X, Data: 0x%08X\n", reg, data);
if (dev_priv->vbios.execute) {
still_alive();
nv_wr32(bios->dev, reg, data);
}
}
static uint8_t
bios_idxprt_rd(struct nvbios *bios, uint16_t port, uint8_t index)
{
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
struct drm_device *dev = bios->dev;
uint8_t data;
if (!valid_idx_port(bios, port))
return 0;
if (dev_priv->card_type < NV_50) {
if (port == NV_VIO_SRX)
data = NVReadVgaSeq(dev, bios->state.crtchead, index);
else /* assume NV_CIO_CRX__COLOR */
data = NVReadVgaCrtc(dev, bios->state.crtchead, index);
} else {
uint32_t data32;
data32 = bios_rd32(bios, NV50_PDISPLAY_VGACRTC(index & ~3));
data = (data32 >> ((index & 3) << 3)) & 0xff;
}
BIOSLOG(bios, " Indexed IO read: Port: 0x%04X, Index: 0x%02X, "
"Head: 0x%02X, Data: 0x%02X\n",
port, index, bios->state.crtchead, data);
return data;
}
static void
bios_idxprt_wr(struct nvbios *bios, uint16_t port, uint8_t index, uint8_t data)
{
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
struct drm_device *dev = bios->dev;
if (!valid_idx_port(bios, port))
return;
/*
* The current head is maintained in the nvbios member state.crtchead.
* We trap changes to CR44 and update the head variable and hence the
* register set written.
* As CR44 only exists on CRTC0, we update crtchead to head0 in advance
* of the write, and to head1 after the write
*/
if (port == NV_CIO_CRX__COLOR && index == NV_CIO_CRE_44 &&
data != NV_CIO_CRE_44_HEADB)
bios->state.crtchead = 0;
LOG_OLD_VALUE(bios_idxprt_rd(bios, port, index));
BIOSLOG(bios, " Indexed IO write: Port: 0x%04X, Index: 0x%02X, "
"Head: 0x%02X, Data: 0x%02X\n",
port, index, bios->state.crtchead, data);
if (bios->execute && dev_priv->card_type < NV_50) {
still_alive();
if (port == NV_VIO_SRX)
NVWriteVgaSeq(dev, bios->state.crtchead, index, data);
else /* assume NV_CIO_CRX__COLOR */
NVWriteVgaCrtc(dev, bios->state.crtchead, index, data);
} else
if (bios->execute) {
uint32_t data32, shift = (index & 3) << 3;
still_alive();
data32 = bios_rd32(bios, NV50_PDISPLAY_VGACRTC(index & ~3));
data32 &= ~(0xff << shift);
data32 |= (data << shift);
bios_wr32(bios, NV50_PDISPLAY_VGACRTC(index & ~3), data32);
}
if (port == NV_CIO_CRX__COLOR &&
index == NV_CIO_CRE_44 && data == NV_CIO_CRE_44_HEADB)
bios->state.crtchead = 1;
}
static uint8_t
bios_port_rd(struct nvbios *bios, uint16_t port)
{
uint8_t data, head = bios->state.crtchead;
if (!valid_port(bios, port))
return 0;
data = NVReadPRMVIO(bios->dev, head, NV_PRMVIO0_OFFSET + port);
BIOSLOG(bios, " IO read: Port: 0x%04X, Head: 0x%02X, Data: 0x%02X\n",
port, head, data);
return data;
}
static void
bios_port_wr(struct nvbios *bios, uint16_t port, uint8_t data)
{
int head = bios->state.crtchead;
if (!valid_port(bios, port))
return;
LOG_OLD_VALUE(bios_port_rd(bios, port));
BIOSLOG(bios, " IO write: Port: 0x%04X, Head: 0x%02X, Data: 0x%02X\n",
port, head, data);
if (!bios->execute)
return;
still_alive();
NVWritePRMVIO(bios->dev, head, NV_PRMVIO0_OFFSET + port, data);
}
static bool
io_flag_condition_met(struct nvbios *bios, uint16_t offset, uint8_t cond)
{
/*
* The IO flag condition entry has 2 bytes for the CRTC port; 1 byte
* for the CRTC index; 1 byte for the mask to apply to the value
* retrieved from the CRTC; 1 byte for the shift right to apply to the
* masked CRTC value; 2 bytes for the offset to the flag array, to
* which the shifted value is added; 1 byte for the mask applied to the
* value read from the flag array; and 1 byte for the value to compare
* against the masked byte from the flag table.
*/
uint16_t condptr = bios->io_flag_condition_tbl_ptr + cond * IO_FLAG_CONDITION_SIZE;
uint16_t crtcport = ROM16(bios->data[condptr]);
uint8_t crtcindex = bios->data[condptr + 2];
uint8_t mask = bios->data[condptr + 3];
uint8_t shift = bios->data[condptr + 4];
uint16_t flagarray = ROM16(bios->data[condptr + 5]);
uint8_t flagarraymask = bios->data[condptr + 7];
uint8_t cmpval = bios->data[condptr + 8];
uint8_t data;
BIOSLOG(bios, "0x%04X: Port: 0x%04X, Index: 0x%02X, Mask: 0x%02X, "
"Shift: 0x%02X, FlagArray: 0x%04X, FAMask: 0x%02X, "
"Cmpval: 0x%02X\n",
offset, crtcport, crtcindex, mask, shift, flagarray, flagarraymask, cmpval);
data = bios_idxprt_rd(bios, crtcport, crtcindex);
data = bios->data[flagarray + ((data & mask) >> shift)];
data &= flagarraymask;
BIOSLOG(bios, "0x%04X: Checking if 0x%02X equals 0x%02X\n",
offset, data, cmpval);
return (data == cmpval);
}
static bool
bios_condition_met(struct nvbios *bios, uint16_t offset, uint8_t cond)
{
/*
* The condition table entry has 4 bytes for the address of the
* register to check, 4 bytes for a mask to apply to the register and
* 4 for a test comparison value
*/
uint16_t condptr = bios->condition_tbl_ptr + cond * CONDITION_SIZE;
uint32_t reg = ROM32(bios->data[condptr]);
uint32_t mask = ROM32(bios->data[condptr + 4]);
uint32_t cmpval = ROM32(bios->data[condptr + 8]);
uint32_t data;
BIOSLOG(bios, "0x%04X: Cond: 0x%02X, Reg: 0x%08X, Mask: 0x%08X\n",
offset, cond, reg, mask);
data = bios_rd32(bios, reg) & mask;
BIOSLOG(bios, "0x%04X: Checking if 0x%08X equals 0x%08X\n",
offset, data, cmpval);
return (data == cmpval);
}
static bool
io_condition_met(struct nvbios *bios, uint16_t offset, uint8_t cond)
{
/*
* The IO condition entry has 2 bytes for the IO port address; 1 byte
* for the index to write to io_port; 1 byte for the mask to apply to
* the byte read from io_port+1; and 1 byte for the value to compare
* against the masked byte.
*/
uint16_t condptr = bios->io_condition_tbl_ptr + cond * IO_CONDITION_SIZE;
uint16_t io_port = ROM16(bios->data[condptr]);
uint8_t port_index = bios->data[condptr + 2];
uint8_t mask = bios->data[condptr + 3];
uint8_t cmpval = bios->data[condptr + 4];
uint8_t data = bios_idxprt_rd(bios, io_port, port_index) & mask;
BIOSLOG(bios, "0x%04X: Checking if 0x%02X equals 0x%02X\n",
offset, data, cmpval);
return (data == cmpval);
}
static int
nv50_pll_set(struct drm_device *dev, uint32_t reg, uint32_t clk)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nouveau_pll_vals pll;
struct pll_lims pll_limits;
u32 ctrl, mask, coef;
int ret;
ret = get_pll_limits(dev, reg, &pll_limits);
if (ret)
return ret;
clk = nouveau_calc_pll_mnp(dev, &pll_limits, clk, &pll);
if (!clk)
return -ERANGE;
coef = pll.N1 << 8 | pll.M1;
ctrl = pll.log2P << 16;
mask = 0x00070000;
if (reg == 0x004008) {
mask |= 0x01f80000;
ctrl |= (pll_limits.log2p_bias << 19);
ctrl |= (pll.log2P << 22);
}
if (!dev_priv->vbios.execute)
return 0;
nv_mask(dev, reg + 0, mask, ctrl);
nv_wr32(dev, reg + 4, coef);
return 0;
}
static int
setPLL(struct nvbios *bios, uint32_t reg, uint32_t clk)
{
struct drm_device *dev = bios->dev;
struct drm_nouveau_private *dev_priv = dev->dev_private;
/* clk in kHz */
struct pll_lims pll_lim;
struct nouveau_pll_vals pllvals;
int ret;
if (dev_priv->card_type >= NV_50)
return nv50_pll_set(dev, reg, clk);
/* high regs (such as in the mac g5 table) are not -= 4 */
ret = get_pll_limits(dev, reg > 0x405c ? reg : reg - 4, &pll_lim);
if (ret)
return ret;
clk = nouveau_calc_pll_mnp(dev, &pll_lim, clk, &pllvals);
if (!clk)
return -ERANGE;
if (bios->execute) {
still_alive();
nouveau_hw_setpll(dev, reg, &pllvals);
}
return 0;
}
static int dcb_entry_idx_from_crtchead(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
/*
* For the results of this function to be correct, CR44 must have been
* set (using bios_idxprt_wr to set crtchead), CR58 set for CR57 = 0,
* and the DCB table parsed, before the script calling the function is
* run. run_digital_op_script is example of how to do such setup
*/
uint8_t dcb_entry = NVReadVgaCrtc5758(dev, bios->state.crtchead, 0);
if (dcb_entry > bios->dcb.entries) {
NV_ERROR(dev, "CR58 doesn't have a valid DCB entry currently "
"(%02X)\n", dcb_entry);
dcb_entry = 0x7f; /* unused / invalid marker */
}
return dcb_entry;
}
static struct nouveau_i2c_chan *
init_i2c_device_find(struct drm_device *dev, int i2c_index)
{
if (i2c_index == 0xff) {
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct dcb_table *dcb = &dev_priv->vbios.dcb;
/* note: dcb_entry_idx_from_crtchead needs pre-script set-up */
int idx = dcb_entry_idx_from_crtchead(dev);
i2c_index = NV_I2C_DEFAULT(0);
if (idx != 0x7f && dcb->entry[idx].i2c_upper_default)
i2c_index = NV_I2C_DEFAULT(1);
}
return nouveau_i2c_find(dev, i2c_index);
}
static uint32_t
get_tmds_index_reg(struct drm_device *dev, uint8_t mlv)
{
/*
* For mlv < 0x80, it is an index into a table of TMDS base addresses.
* For mlv == 0x80 use the "or" value of the dcb_entry indexed by
* CR58 for CR57 = 0 to index a table of offsets to the basic
* 0x6808b0 address.
* For mlv == 0x81 use the "or" value of the dcb_entry indexed by
* CR58 for CR57 = 0 to index a table of offsets to the basic
* 0x6808b0 address, and then flip the offset by 8.
*/
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
const int pramdac_offset[13] = {
0, 0, 0x8, 0, 0x2000, 0, 0, 0, 0x2008, 0, 0, 0, 0x2000 };
const uint32_t pramdac_table[4] = {
0x6808b0, 0x6808b8, 0x6828b0, 0x6828b8 };
if (mlv >= 0x80) {
int dcb_entry, dacoffset;
/* note: dcb_entry_idx_from_crtchead needs pre-script set-up */
dcb_entry = dcb_entry_idx_from_crtchead(dev);
if (dcb_entry == 0x7f)
return 0;
dacoffset = pramdac_offset[bios->dcb.entry[dcb_entry].or];
if (mlv == 0x81)
dacoffset ^= 8;
return 0x6808b0 + dacoffset;
} else {
if (mlv >= ARRAY_SIZE(pramdac_table)) {
NV_ERROR(dev, "Magic Lookup Value too big (%02X)\n",
mlv);
return 0;
}
return pramdac_table[mlv];
}
}
static int
init_io_restrict_prog(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_IO_RESTRICT_PROG opcode: 0x32 ('2')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): CRTC port
* offset + 3 (8 bit): CRTC index
* offset + 4 (8 bit): mask
* offset + 5 (8 bit): shift
* offset + 6 (8 bit): count
* offset + 7 (32 bit): register
* offset + 11 (32 bit): configuration 1
* ...
*
* Starting at offset + 11 there are "count" 32 bit values.
* To find out which value to use read index "CRTC index" on "CRTC
* port", AND this value with "mask" and then bit shift right "shift"
* bits. Read the appropriate value using this index and write to
* "register"
*/
uint16_t crtcport = ROM16(bios->data[offset + 1]);
uint8_t crtcindex = bios->data[offset + 3];
uint8_t mask = bios->data[offset + 4];
uint8_t shift = bios->data[offset + 5];
uint8_t count = bios->data[offset + 6];
uint32_t reg = ROM32(bios->data[offset + 7]);
uint8_t config;
uint32_t configval;
int len = 11 + count * 4;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: Port: 0x%04X, Index: 0x%02X, Mask: 0x%02X, "
"Shift: 0x%02X, Count: 0x%02X, Reg: 0x%08X\n",
offset, crtcport, crtcindex, mask, shift, count, reg);
config = (bios_idxprt_rd(bios, crtcport, crtcindex) & mask) >> shift;
if (config > count) {
NV_ERROR(bios->dev,
"0x%04X: Config 0x%02X exceeds maximal bound 0x%02X\n",
offset, config, count);
return len;
}
configval = ROM32(bios->data[offset + 11 + config * 4]);
BIOSLOG(bios, "0x%04X: Writing config %02X\n", offset, config);
bios_wr32(bios, reg, configval);
return len;
}
static int
init_repeat(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_REPEAT opcode: 0x33 ('3')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): count
*
* Execute script following this opcode up to INIT_REPEAT_END
* "count" times
*/
uint8_t count = bios->data[offset + 1];
uint8_t i;
/* no iexec->execute check by design */
BIOSLOG(bios, "0x%04X: Repeating following segment %d times\n",
offset, count);
iexec->repeat = true;
/*
* count - 1, as the script block will execute once when we leave this
* opcode -- this is compatible with bios behaviour as:
* a) the block is always executed at least once, even if count == 0
* b) the bios interpreter skips to the op following INIT_END_REPEAT,
* while we don't
*/
for (i = 0; i < count - 1; i++)
parse_init_table(bios, offset + 2, iexec);
iexec->repeat = false;
return 2;
}
static int
init_io_restrict_pll(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_IO_RESTRICT_PLL opcode: 0x34 ('4')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): CRTC port
* offset + 3 (8 bit): CRTC index
* offset + 4 (8 bit): mask
* offset + 5 (8 bit): shift
* offset + 6 (8 bit): IO flag condition index
* offset + 7 (8 bit): count
* offset + 8 (32 bit): register
* offset + 12 (16 bit): frequency 1
* ...
*
* Starting at offset + 12 there are "count" 16 bit frequencies (10kHz).
* Set PLL register "register" to coefficients for frequency n,
* selected by reading index "CRTC index" of "CRTC port" ANDed with
* "mask" and shifted right by "shift".
*
* If "IO flag condition index" > 0, and condition met, double
* frequency before setting it.
*/
uint16_t crtcport = ROM16(bios->data[offset + 1]);
uint8_t crtcindex = bios->data[offset + 3];
uint8_t mask = bios->data[offset + 4];
uint8_t shift = bios->data[offset + 5];
int8_t io_flag_condition_idx = bios->data[offset + 6];
uint8_t count = bios->data[offset + 7];
uint32_t reg = ROM32(bios->data[offset + 8]);
uint8_t config;
uint16_t freq;
int len = 12 + count * 2;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: Port: 0x%04X, Index: 0x%02X, Mask: 0x%02X, "
"Shift: 0x%02X, IO Flag Condition: 0x%02X, "
"Count: 0x%02X, Reg: 0x%08X\n",
offset, crtcport, crtcindex, mask, shift,
io_flag_condition_idx, count, reg);
config = (bios_idxprt_rd(bios, crtcport, crtcindex) & mask) >> shift;
if (config > count) {
NV_ERROR(bios->dev,
"0x%04X: Config 0x%02X exceeds maximal bound 0x%02X\n",
offset, config, count);
return len;
}
freq = ROM16(bios->data[offset + 12 + config * 2]);
if (io_flag_condition_idx > 0) {
if (io_flag_condition_met(bios, offset, io_flag_condition_idx)) {
BIOSLOG(bios, "0x%04X: Condition fulfilled -- "
"frequency doubled\n", offset);
freq *= 2;
} else
BIOSLOG(bios, "0x%04X: Condition not fulfilled -- "
"frequency unchanged\n", offset);
}
BIOSLOG(bios, "0x%04X: Reg: 0x%08X, Config: 0x%02X, Freq: %d0kHz\n",
offset, reg, config, freq);
setPLL(bios, reg, freq * 10);
return len;
}
static int
init_end_repeat(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_END_REPEAT opcode: 0x36 ('6')
*
* offset (8 bit): opcode
*
* Marks the end of the block for INIT_REPEAT to repeat
*/
/* no iexec->execute check by design */
/*
* iexec->repeat flag necessary to go past INIT_END_REPEAT opcode when
* we're not in repeat mode
*/
if (iexec->repeat)
return 0;
return 1;
}
static int
init_copy(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_COPY opcode: 0x37 ('7')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): register
* offset + 5 (8 bit): shift
* offset + 6 (8 bit): srcmask
* offset + 7 (16 bit): CRTC port
* offset + 9 (8 bit): CRTC index
* offset + 10 (8 bit): mask
*
* Read index "CRTC index" on "CRTC port", AND with "mask", OR with
* (REGVAL("register") >> "shift" & "srcmask") and write-back to CRTC
* port
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint8_t shift = bios->data[offset + 5];
uint8_t srcmask = bios->data[offset + 6];
uint16_t crtcport = ROM16(bios->data[offset + 7]);
uint8_t crtcindex = bios->data[offset + 9];
uint8_t mask = bios->data[offset + 10];
uint32_t data;
uint8_t crtcdata;
if (!iexec->execute)
return 11;
BIOSLOG(bios, "0x%04X: Reg: 0x%08X, Shift: 0x%02X, SrcMask: 0x%02X, "
"Port: 0x%04X, Index: 0x%02X, Mask: 0x%02X\n",
offset, reg, shift, srcmask, crtcport, crtcindex, mask);
data = bios_rd32(bios, reg);
if (shift < 0x80)
data >>= shift;
else
data <<= (0x100 - shift);
data &= srcmask;
crtcdata = bios_idxprt_rd(bios, crtcport, crtcindex) & mask;
crtcdata |= (uint8_t)data;
bios_idxprt_wr(bios, crtcport, crtcindex, crtcdata);
return 11;
}
static int
init_not(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_NOT opcode: 0x38 ('8')
*
* offset (8 bit): opcode
*
* Invert the current execute / no-execute condition (i.e. "else")
*/
if (iexec->execute)
BIOSLOG(bios, "0x%04X: ------ Skipping following commands ------\n", offset);
else
BIOSLOG(bios, "0x%04X: ------ Executing following commands ------\n", offset);
iexec->execute = !iexec->execute;
return 1;
}
static int
init_io_flag_condition(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_IO_FLAG_CONDITION opcode: 0x39 ('9')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): condition number
*
* Check condition "condition number" in the IO flag condition table.
* If condition not met skip subsequent opcodes until condition is
* inverted (INIT_NOT), or we hit INIT_RESUME
*/
uint8_t cond = bios->data[offset + 1];
if (!iexec->execute)
return 2;
if (io_flag_condition_met(bios, offset, cond))
BIOSLOG(bios, "0x%04X: Condition fulfilled -- continuing to execute\n", offset);
else {
BIOSLOG(bios, "0x%04X: Condition not fulfilled -- skipping following commands\n", offset);
iexec->execute = false;
}
return 2;
}
static int
init_dp_condition(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_DP_CONDITION opcode: 0x3A ('')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): "sub" opcode
* offset + 2 (8 bit): unknown
*
*/
struct dcb_entry *dcb = bios->display.output;
struct drm_device *dev = bios->dev;
uint8_t cond = bios->data[offset + 1];
uint8_t *table, *entry;
BIOSLOG(bios, "0x%04X: subop 0x%02X\n", offset, cond);
if (!iexec->execute)
return 3;
table = nouveau_dp_bios_data(dev, dcb, &entry);
if (!table)
return 3;
switch (cond) {
case 0:
entry = dcb_conn(dev, dcb->connector);
if (!entry || entry[0] != DCB_CONNECTOR_eDP)
iexec->execute = false;
break;
case 1:
case 2:
if ((table[0] < 0x40 && !(entry[5] & cond)) ||
(table[0] == 0x40 && !(entry[4] & cond)))
iexec->execute = false;
break;
case 5:
{
struct nouveau_i2c_chan *auxch;
int ret;
auxch = nouveau_i2c_find(dev, bios->display.output->i2c_index);
if (!auxch) {
NV_ERROR(dev, "0x%04X: couldn't get auxch\n", offset);
return 3;
}
ret = nouveau_dp_auxch(auxch, 9, 0xd, &cond, 1);
if (ret) {
NV_ERROR(dev, "0x%04X: auxch rd fail: %d\n", offset, ret);
return 3;
}
if (!(cond & 1))
iexec->execute = false;
}
break;
default:
NV_WARN(dev, "0x%04X: unknown INIT_3A op: %d\n", offset, cond);
break;
}
if (iexec->execute)
BIOSLOG(bios, "0x%04X: continuing to execute\n", offset);
else
BIOSLOG(bios, "0x%04X: skipping following commands\n", offset);
return 3;
}
static int
init_op_3b(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_3B opcode: 0x3B ('')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): crtc index
*
*/
uint8_t or = ffs(bios->display.output->or) - 1;
uint8_t index = bios->data[offset + 1];
uint8_t data;
if (!iexec->execute)
return 2;
data = bios_idxprt_rd(bios, 0x3d4, index);
bios_idxprt_wr(bios, 0x3d4, index, data & ~(1 << or));
return 2;
}
static int
init_op_3c(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_3C opcode: 0x3C ('')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): crtc index
*
*/
uint8_t or = ffs(bios->display.output->or) - 1;
uint8_t index = bios->data[offset + 1];
uint8_t data;
if (!iexec->execute)
return 2;
data = bios_idxprt_rd(bios, 0x3d4, index);
bios_idxprt_wr(bios, 0x3d4, index, data | (1 << or));
return 2;
}
static int
init_idx_addr_latched(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_INDEX_ADDRESS_LATCHED opcode: 0x49 ('I')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): control register
* offset + 5 (32 bit): data register
* offset + 9 (32 bit): mask
* offset + 13 (32 bit): data
* offset + 17 (8 bit): count
* offset + 18 (8 bit): address 1
* offset + 19 (8 bit): data 1
* ...
*
* For each of "count" address and data pairs, write "data n" to
* "data register", read the current value of "control register",
* and write it back once ANDed with "mask", ORed with "data",
* and ORed with "address n"
*/
uint32_t controlreg = ROM32(bios->data[offset + 1]);
uint32_t datareg = ROM32(bios->data[offset + 5]);
uint32_t mask = ROM32(bios->data[offset + 9]);
uint32_t data = ROM32(bios->data[offset + 13]);
uint8_t count = bios->data[offset + 17];
int len = 18 + count * 2;
uint32_t value;
int i;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: ControlReg: 0x%08X, DataReg: 0x%08X, "
"Mask: 0x%08X, Data: 0x%08X, Count: 0x%02X\n",
offset, controlreg, datareg, mask, data, count);
for (i = 0; i < count; i++) {
uint8_t instaddress = bios->data[offset + 18 + i * 2];
uint8_t instdata = bios->data[offset + 19 + i * 2];
BIOSLOG(bios, "0x%04X: Address: 0x%02X, Data: 0x%02X\n",
offset, instaddress, instdata);
bios_wr32(bios, datareg, instdata);
value = bios_rd32(bios, controlreg) & mask;
value |= data;
value |= instaddress;
bios_wr32(bios, controlreg, value);
}
return len;
}
static int
init_io_restrict_pll2(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_IO_RESTRICT_PLL2 opcode: 0x4A ('J')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): CRTC port
* offset + 3 (8 bit): CRTC index
* offset + 4 (8 bit): mask
* offset + 5 (8 bit): shift
* offset + 6 (8 bit): count
* offset + 7 (32 bit): register
* offset + 11 (32 bit): frequency 1
* ...
*
* Starting at offset + 11 there are "count" 32 bit frequencies (kHz).
* Set PLL register "register" to coefficients for frequency n,
* selected by reading index "CRTC index" of "CRTC port" ANDed with
* "mask" and shifted right by "shift".
*/
uint16_t crtcport = ROM16(bios->data[offset + 1]);
uint8_t crtcindex = bios->data[offset + 3];
uint8_t mask = bios->data[offset + 4];
uint8_t shift = bios->data[offset + 5];
uint8_t count = bios->data[offset + 6];
uint32_t reg = ROM32(bios->data[offset + 7]);
int len = 11 + count * 4;
uint8_t config;
uint32_t freq;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: Port: 0x%04X, Index: 0x%02X, Mask: 0x%02X, "
"Shift: 0x%02X, Count: 0x%02X, Reg: 0x%08X\n",
offset, crtcport, crtcindex, mask, shift, count, reg);
if (!reg)
return len;
config = (bios_idxprt_rd(bios, crtcport, crtcindex) & mask) >> shift;
if (config > count) {
NV_ERROR(bios->dev,
"0x%04X: Config 0x%02X exceeds maximal bound 0x%02X\n",
offset, config, count);
return len;
}
freq = ROM32(bios->data[offset + 11 + config * 4]);
BIOSLOG(bios, "0x%04X: Reg: 0x%08X, Config: 0x%02X, Freq: %dkHz\n",
offset, reg, config, freq);
setPLL(bios, reg, freq);
return len;
}
static int
init_pll2(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_PLL2 opcode: 0x4B ('K')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): register
* offset + 5 (32 bit): freq
*
* Set PLL register "register" to coefficients for frequency "freq"
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint32_t freq = ROM32(bios->data[offset + 5]);
if (!iexec->execute)
return 9;
BIOSLOG(bios, "0x%04X: Reg: 0x%04X, Freq: %dkHz\n",
offset, reg, freq);
setPLL(bios, reg, freq);
return 9;
}
static int
init_i2c_byte(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_I2C_BYTE opcode: 0x4C ('L')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): DCB I2C table entry index
* offset + 2 (8 bit): I2C slave address
* offset + 3 (8 bit): count
* offset + 4 (8 bit): I2C register 1
* offset + 5 (8 bit): mask 1
* offset + 6 (8 bit): data 1
* ...
*
* For each of "count" registers given by "I2C register n" on the device
* addressed by "I2C slave address" on the I2C bus given by
* "DCB I2C table entry index", read the register, AND the result with
* "mask n" and OR it with "data n" before writing it back to the device
*/
struct drm_device *dev = bios->dev;
uint8_t i2c_index = bios->data[offset + 1];
uint8_t i2c_address = bios->data[offset + 2] >> 1;
uint8_t count = bios->data[offset + 3];
struct nouveau_i2c_chan *chan;
int len = 4 + count * 3;
int ret, i;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: DCBI2CIndex: 0x%02X, I2CAddress: 0x%02X, "
"Count: 0x%02X\n",
offset, i2c_index, i2c_address, count);
chan = init_i2c_device_find(dev, i2c_index);
if (!chan) {
NV_ERROR(dev, "0x%04X: i2c bus not found\n", offset);
return len;
}
for (i = 0; i < count; i++) {
uint8_t reg = bios->data[offset + 4 + i * 3];
uint8_t mask = bios->data[offset + 5 + i * 3];
uint8_t data = bios->data[offset + 6 + i * 3];
union i2c_smbus_data val;
ret = i2c_smbus_xfer(&chan->adapter, i2c_address, 0,
I2C_SMBUS_READ, reg,
I2C_SMBUS_BYTE_DATA, &val);
if (ret < 0) {
NV_ERROR(dev, "0x%04X: i2c rd fail: %d\n", offset, ret);
return len;
}
BIOSLOG(bios, "0x%04X: I2CReg: 0x%02X, Value: 0x%02X, "
"Mask: 0x%02X, Data: 0x%02X\n",
offset, reg, val.byte, mask, data);
if (!bios->execute)
continue;
val.byte &= mask;
val.byte |= data;
ret = i2c_smbus_xfer(&chan->adapter, i2c_address, 0,
I2C_SMBUS_WRITE, reg,
I2C_SMBUS_BYTE_DATA, &val);
if (ret < 0) {
NV_ERROR(dev, "0x%04X: i2c wr fail: %d\n", offset, ret);
return len;
}
}
return len;
}
static int
init_zm_i2c_byte(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_ZM_I2C_BYTE opcode: 0x4D ('M')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): DCB I2C table entry index
* offset + 2 (8 bit): I2C slave address
* offset + 3 (8 bit): count
* offset + 4 (8 bit): I2C register 1
* offset + 5 (8 bit): data 1
* ...
*
* For each of "count" registers given by "I2C register n" on the device
* addressed by "I2C slave address" on the I2C bus given by
* "DCB I2C table entry index", set the register to "data n"
*/
struct drm_device *dev = bios->dev;
uint8_t i2c_index = bios->data[offset + 1];
uint8_t i2c_address = bios->data[offset + 2] >> 1;
uint8_t count = bios->data[offset + 3];
struct nouveau_i2c_chan *chan;
int len = 4 + count * 2;
int ret, i;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: DCBI2CIndex: 0x%02X, I2CAddress: 0x%02X, "
"Count: 0x%02X\n",
offset, i2c_index, i2c_address, count);
chan = init_i2c_device_find(dev, i2c_index);
if (!chan) {
NV_ERROR(dev, "0x%04X: i2c bus not found\n", offset);
return len;
}
for (i = 0; i < count; i++) {
uint8_t reg = bios->data[offset + 4 + i * 2];
union i2c_smbus_data val;
val.byte = bios->data[offset + 5 + i * 2];
BIOSLOG(bios, "0x%04X: I2CReg: 0x%02X, Data: 0x%02X\n",
offset, reg, val.byte);
if (!bios->execute)
continue;
ret = i2c_smbus_xfer(&chan->adapter, i2c_address, 0,
I2C_SMBUS_WRITE, reg,
I2C_SMBUS_BYTE_DATA, &val);
if (ret < 0) {
NV_ERROR(dev, "0x%04X: i2c wr fail: %d\n", offset, ret);
return len;
}
}
return len;
}
static int
init_zm_i2c(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_ZM_I2C opcode: 0x4E ('N')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): DCB I2C table entry index
* offset + 2 (8 bit): I2C slave address
* offset + 3 (8 bit): count
* offset + 4 (8 bit): data 1
* ...
*
* Send "count" bytes ("data n") to the device addressed by "I2C slave
* address" on the I2C bus given by "DCB I2C table entry index"
*/
struct drm_device *dev = bios->dev;
uint8_t i2c_index = bios->data[offset + 1];
uint8_t i2c_address = bios->data[offset + 2] >> 1;
uint8_t count = bios->data[offset + 3];
int len = 4 + count;
struct nouveau_i2c_chan *chan;
struct i2c_msg msg;
uint8_t data[256];
int ret, i;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: DCBI2CIndex: 0x%02X, I2CAddress: 0x%02X, "
"Count: 0x%02X\n",
offset, i2c_index, i2c_address, count);
chan = init_i2c_device_find(dev, i2c_index);
if (!chan) {
NV_ERROR(dev, "0x%04X: i2c bus not found\n", offset);
return len;
}
for (i = 0; i < count; i++) {
data[i] = bios->data[offset + 4 + i];
BIOSLOG(bios, "0x%04X: Data: 0x%02X\n", offset, data[i]);
}
if (bios->execute) {
msg.addr = i2c_address;
msg.flags = 0;
msg.len = count;
msg.buf = data;
ret = i2c_transfer(&chan->adapter, &msg, 1);
if (ret != 1) {
NV_ERROR(dev, "0x%04X: i2c wr fail: %d\n", offset, ret);
return len;
}
}
return len;
}
static int
init_tmds(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_TMDS opcode: 0x4F ('O') (non-canon name)
*
* offset (8 bit): opcode
* offset + 1 (8 bit): magic lookup value
* offset + 2 (8 bit): TMDS address
* offset + 3 (8 bit): mask
* offset + 4 (8 bit): data
*
* Read the data reg for TMDS address "TMDS address", AND it with mask
* and OR it with data, then write it back
* "magic lookup value" determines which TMDS base address register is
* used -- see get_tmds_index_reg()
*/
struct drm_device *dev = bios->dev;
uint8_t mlv = bios->data[offset + 1];
uint32_t tmdsaddr = bios->data[offset + 2];
uint8_t mask = bios->data[offset + 3];
uint8_t data = bios->data[offset + 4];
uint32_t reg, value;
if (!iexec->execute)
return 5;
BIOSLOG(bios, "0x%04X: MagicLookupValue: 0x%02X, TMDSAddr: 0x%02X, "
"Mask: 0x%02X, Data: 0x%02X\n",
offset, mlv, tmdsaddr, mask, data);
reg = get_tmds_index_reg(bios->dev, mlv);
if (!reg) {
NV_ERROR(dev, "0x%04X: no tmds_index_reg\n", offset);
return 5;
}
bios_wr32(bios, reg,
tmdsaddr | NV_PRAMDAC_FP_TMDS_CONTROL_WRITE_DISABLE);
value = (bios_rd32(bios, reg + 4) & mask) | data;
bios_wr32(bios, reg + 4, value);
bios_wr32(bios, reg, tmdsaddr);
return 5;
}
static int
init_zm_tmds_group(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_ZM_TMDS_GROUP opcode: 0x50 ('P') (non-canon name)
*
* offset (8 bit): opcode
* offset + 1 (8 bit): magic lookup value
* offset + 2 (8 bit): count
* offset + 3 (8 bit): addr 1
* offset + 4 (8 bit): data 1
* ...
*
* For each of "count" TMDS address and data pairs write "data n" to
* "addr n". "magic lookup value" determines which TMDS base address
* register is used -- see get_tmds_index_reg()
*/
struct drm_device *dev = bios->dev;
uint8_t mlv = bios->data[offset + 1];
uint8_t count = bios->data[offset + 2];
int len = 3 + count * 2;
uint32_t reg;
int i;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: MagicLookupValue: 0x%02X, Count: 0x%02X\n",
offset, mlv, count);
reg = get_tmds_index_reg(bios->dev, mlv);
if (!reg) {
NV_ERROR(dev, "0x%04X: no tmds_index_reg\n", offset);
return len;
}
for (i = 0; i < count; i++) {
uint8_t tmdsaddr = bios->data[offset + 3 + i * 2];
uint8_t tmdsdata = bios->data[offset + 4 + i * 2];
bios_wr32(bios, reg + 4, tmdsdata);
bios_wr32(bios, reg, tmdsaddr);
}
return len;
}
static int
init_cr_idx_adr_latch(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_CR_INDEX_ADDRESS_LATCHED opcode: 0x51 ('Q')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): CRTC index1
* offset + 2 (8 bit): CRTC index2
* offset + 3 (8 bit): baseaddr
* offset + 4 (8 bit): count
* offset + 5 (8 bit): data 1
* ...
*
* For each of "count" address and data pairs, write "baseaddr + n" to
* "CRTC index1" and "data n" to "CRTC index2"
* Once complete, restore initial value read from "CRTC index1"
*/
uint8_t crtcindex1 = bios->data[offset + 1];
uint8_t crtcindex2 = bios->data[offset + 2];
uint8_t baseaddr = bios->data[offset + 3];
uint8_t count = bios->data[offset + 4];
int len = 5 + count;
uint8_t oldaddr, data;
int i;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: Index1: 0x%02X, Index2: 0x%02X, "
"BaseAddr: 0x%02X, Count: 0x%02X\n",
offset, crtcindex1, crtcindex2, baseaddr, count);
oldaddr = bios_idxprt_rd(bios, NV_CIO_CRX__COLOR, crtcindex1);
for (i = 0; i < count; i++) {
bios_idxprt_wr(bios, NV_CIO_CRX__COLOR, crtcindex1,
baseaddr + i);
data = bios->data[offset + 5 + i];
bios_idxprt_wr(bios, NV_CIO_CRX__COLOR, crtcindex2, data);
}
bios_idxprt_wr(bios, NV_CIO_CRX__COLOR, crtcindex1, oldaddr);
return len;
}
static int
init_cr(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_CR opcode: 0x52 ('R')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): CRTC index
* offset + 2 (8 bit): mask
* offset + 3 (8 bit): data
*
* Assign the value of at "CRTC index" ANDed with mask and ORed with
* data back to "CRTC index"
*/
uint8_t crtcindex = bios->data[offset + 1];
uint8_t mask = bios->data[offset + 2];
uint8_t data = bios->data[offset + 3];
uint8_t value;
if (!iexec->execute)
return 4;
BIOSLOG(bios, "0x%04X: Index: 0x%02X, Mask: 0x%02X, Data: 0x%02X\n",
offset, crtcindex, mask, data);
value = bios_idxprt_rd(bios, NV_CIO_CRX__COLOR, crtcindex) & mask;
value |= data;
bios_idxprt_wr(bios, NV_CIO_CRX__COLOR, crtcindex, value);
return 4;
}
static int
init_zm_cr(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_ZM_CR opcode: 0x53 ('S')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): CRTC index
* offset + 2 (8 bit): value
*
* Assign "value" to CRTC register with index "CRTC index".
*/
uint8_t crtcindex = ROM32(bios->data[offset + 1]);
uint8_t data = bios->data[offset + 2];
if (!iexec->execute)
return 3;
bios_idxprt_wr(bios, NV_CIO_CRX__COLOR, crtcindex, data);
return 3;
}
static int
init_zm_cr_group(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_ZM_CR_GROUP opcode: 0x54 ('T')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): count
* offset + 2 (8 bit): CRTC index 1
* offset + 3 (8 bit): value 1
* ...
*
* For "count", assign "value n" to CRTC register with index
* "CRTC index n".
*/
uint8_t count = bios->data[offset + 1];
int len = 2 + count * 2;
int i;
if (!iexec->execute)
return len;
for (i = 0; i < count; i++)
init_zm_cr(bios, offset + 2 + 2 * i - 1, iexec);
return len;
}
static int
init_condition_time(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_CONDITION_TIME opcode: 0x56 ('V')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): condition number
* offset + 2 (8 bit): retries / 50
*
* Check condition "condition number" in the condition table.
* Bios code then sleeps for 2ms if the condition is not met, and
* repeats up to "retries" times, but on one C51 this has proved
* insufficient. In mmiotraces the driver sleeps for 20ms, so we do
* this, and bail after "retries" times, or 2s, whichever is less.
* If still not met after retries, clear execution flag for this table.
*/
uint8_t cond = bios->data[offset + 1];
uint16_t retries = bios->data[offset + 2] * 50;
unsigned cnt;
if (!iexec->execute)
return 3;
if (retries > 100)
retries = 100;
BIOSLOG(bios, "0x%04X: Condition: 0x%02X, Retries: 0x%02X\n",
offset, cond, retries);
if (!bios->execute) /* avoid 2s delays when "faking" execution */
retries = 1;
for (cnt = 0; cnt < retries; cnt++) {
if (bios_condition_met(bios, offset, cond)) {
BIOSLOG(bios, "0x%04X: Condition met, continuing\n",
offset);
break;
} else {
BIOSLOG(bios, "0x%04X: "
"Condition not met, sleeping for 20ms\n",
offset);
mdelay(20);
}
}
if (!bios_condition_met(bios, offset, cond)) {
NV_WARN(bios->dev,
"0x%04X: Condition still not met after %dms, "
"skipping following opcodes\n", offset, 20 * retries);
iexec->execute = false;
}
return 3;
}
static int
init_ltime(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_LTIME opcode: 0x57 ('V')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): time
*
* Sleep for "time" milliseconds.
*/
unsigned time = ROM16(bios->data[offset + 1]);
if (!iexec->execute)
return 3;
BIOSLOG(bios, "0x%04X: Sleeping for 0x%04X milliseconds\n",
offset, time);
mdelay(time);
return 3;
}
static int
init_zm_reg_sequence(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_ZM_REG_SEQUENCE opcode: 0x58 ('X')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): base register
* offset + 5 (8 bit): count
* offset + 6 (32 bit): value 1
* ...
*
* Starting at offset + 6 there are "count" 32 bit values.
* For "count" iterations set "base register" + 4 * current_iteration
* to "value current_iteration"
*/
uint32_t basereg = ROM32(bios->data[offset + 1]);
uint32_t count = bios->data[offset + 5];
int len = 6 + count * 4;
int i;
if (!iexec->execute)
return len;
BIOSLOG(bios, "0x%04X: BaseReg: 0x%08X, Count: 0x%02X\n",
offset, basereg, count);
for (i = 0; i < count; i++) {
uint32_t reg = basereg + i * 4;
uint32_t data = ROM32(bios->data[offset + 6 + i * 4]);
bios_wr32(bios, reg, data);
}
return len;
}
static int
init_sub_direct(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_SUB_DIRECT opcode: 0x5B ('[')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): subroutine offset (in bios)
*
* Calls a subroutine that will execute commands until INIT_DONE
* is found.
*/
uint16_t sub_offset = ROM16(bios->data[offset + 1]);
if (!iexec->execute)
return 3;
BIOSLOG(bios, "0x%04X: Executing subroutine at 0x%04X\n",
offset, sub_offset);
parse_init_table(bios, sub_offset, iexec);
BIOSLOG(bios, "0x%04X: End of 0x%04X subroutine\n", offset, sub_offset);
return 3;
}
static int
init_jump(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_JUMP opcode: 0x5C ('\')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): offset (in bios)
*
* Continue execution of init table from 'offset'
*/
uint16_t jmp_offset = ROM16(bios->data[offset + 1]);
if (!iexec->execute)
return 3;
BIOSLOG(bios, "0x%04X: Jump to 0x%04X\n", offset, jmp_offset);
return jmp_offset - offset;
}
static int
init_i2c_if(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_I2C_IF opcode: 0x5E ('^')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): DCB I2C table entry index
* offset + 2 (8 bit): I2C slave address
* offset + 3 (8 bit): I2C register
* offset + 4 (8 bit): mask
* offset + 5 (8 bit): data
*
* Read the register given by "I2C register" on the device addressed
* by "I2C slave address" on the I2C bus given by "DCB I2C table
* entry index". Compare the result AND "mask" to "data".
* If they're not equal, skip subsequent opcodes until condition is
* inverted (INIT_NOT), or we hit INIT_RESUME
*/
uint8_t i2c_index = bios->data[offset + 1];
uint8_t i2c_address = bios->data[offset + 2] >> 1;
uint8_t reg = bios->data[offset + 3];
uint8_t mask = bios->data[offset + 4];
uint8_t data = bios->data[offset + 5];
struct nouveau_i2c_chan *chan;
union i2c_smbus_data val;
int ret;
/* no execute check by design */
BIOSLOG(bios, "0x%04X: DCBI2CIndex: 0x%02X, I2CAddress: 0x%02X\n",
offset, i2c_index, i2c_address);
chan = init_i2c_device_find(bios->dev, i2c_index);
if (!chan)
return -ENODEV;
ret = i2c_smbus_xfer(&chan->adapter, i2c_address, 0,
I2C_SMBUS_READ, reg,
I2C_SMBUS_BYTE_DATA, &val);
if (ret < 0) {
BIOSLOG(bios, "0x%04X: I2CReg: 0x%02X, Value: [no device], "
"Mask: 0x%02X, Data: 0x%02X\n",
offset, reg, mask, data);
iexec->execute = 0;
return 6;
}
BIOSLOG(bios, "0x%04X: I2CReg: 0x%02X, Value: 0x%02X, "
"Mask: 0x%02X, Data: 0x%02X\n",
offset, reg, val.byte, mask, data);
iexec->execute = ((val.byte & mask) == data);
return 6;
}
static int
init_copy_nv_reg(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_COPY_NV_REG opcode: 0x5F ('_')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): src reg
* offset + 5 (8 bit): shift
* offset + 6 (32 bit): src mask
* offset + 10 (32 bit): xor
* offset + 14 (32 bit): dst reg
* offset + 18 (32 bit): dst mask
*
* Shift REGVAL("src reg") right by (signed) "shift", AND result with
* "src mask", then XOR with "xor". Write this OR'd with
* (REGVAL("dst reg") AND'd with "dst mask") to "dst reg"
*/
uint32_t srcreg = *((uint32_t *)(&bios->data[offset + 1]));
uint8_t shift = bios->data[offset + 5];
uint32_t srcmask = *((uint32_t *)(&bios->data[offset + 6]));
uint32_t xor = *((uint32_t *)(&bios->data[offset + 10]));
uint32_t dstreg = *((uint32_t *)(&bios->data[offset + 14]));
uint32_t dstmask = *((uint32_t *)(&bios->data[offset + 18]));
uint32_t srcvalue, dstvalue;
if (!iexec->execute)
return 22;
BIOSLOG(bios, "0x%04X: SrcReg: 0x%08X, Shift: 0x%02X, SrcMask: 0x%08X, "
"Xor: 0x%08X, DstReg: 0x%08X, DstMask: 0x%08X\n",
offset, srcreg, shift, srcmask, xor, dstreg, dstmask);
srcvalue = bios_rd32(bios, srcreg);
if (shift < 0x80)
srcvalue >>= shift;
else
srcvalue <<= (0x100 - shift);
srcvalue = (srcvalue & srcmask) ^ xor;
dstvalue = bios_rd32(bios, dstreg) & dstmask;
bios_wr32(bios, dstreg, dstvalue | srcvalue);
return 22;
}
static int
init_zm_index_io(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_ZM_INDEX_IO opcode: 0x62 ('b')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): CRTC port
* offset + 3 (8 bit): CRTC index
* offset + 4 (8 bit): data
*
* Write "data" to index "CRTC index" of "CRTC port"
*/
uint16_t crtcport = ROM16(bios->data[offset + 1]);
uint8_t crtcindex = bios->data[offset + 3];
uint8_t data = bios->data[offset + 4];
if (!iexec->execute)
return 5;
bios_idxprt_wr(bios, crtcport, crtcindex, data);
return 5;
}
static inline void
bios_md32(struct nvbios *bios, uint32_t reg,
uint32_t mask, uint32_t val)
{
bios_wr32(bios, reg, (bios_rd32(bios, reg) & ~mask) | val);
}
static uint32_t
peek_fb(struct drm_device *dev, struct io_mapping *fb,
uint32_t off)
{
uint32_t val = 0;
if (off < pci_resource_len(dev->pdev, 1)) {
uint8_t __iomem *p =
io_mapping_map_atomic_wc(fb, off & PAGE_MASK);
val = ioread32(p + (off & ~PAGE_MASK));
io_mapping_unmap_atomic(p);
}
return val;
}
static void
poke_fb(struct drm_device *dev, struct io_mapping *fb,
uint32_t off, uint32_t val)
{
if (off < pci_resource_len(dev->pdev, 1)) {
uint8_t __iomem *p =
io_mapping_map_atomic_wc(fb, off & PAGE_MASK);
iowrite32(val, p + (off & ~PAGE_MASK));
wmb();
io_mapping_unmap_atomic(p);
}
}
static inline bool
read_back_fb(struct drm_device *dev, struct io_mapping *fb,
uint32_t off, uint32_t val)
{
poke_fb(dev, fb, off, val);
return val == peek_fb(dev, fb, off);
}
static int
nv04_init_compute_mem(struct nvbios *bios)
{
struct drm_device *dev = bios->dev;
uint32_t patt = 0xdeadbeef;
struct io_mapping *fb;
int i;
/* Map the framebuffer aperture */
fb = io_mapping_create_wc(pci_resource_start(dev->pdev, 1),
pci_resource_len(dev->pdev, 1));
if (!fb)
return -ENOMEM;
/* Sequencer and refresh off */
NVWriteVgaSeq(dev, 0, 1, NVReadVgaSeq(dev, 0, 1) | 0x20);
bios_md32(bios, NV04_PFB_DEBUG_0, 0, NV04_PFB_DEBUG_0_REFRESH_OFF);
bios_md32(bios, NV04_PFB_BOOT_0, ~0,
NV04_PFB_BOOT_0_RAM_AMOUNT_16MB |
NV04_PFB_BOOT_0_RAM_WIDTH_128 |
NV04_PFB_BOOT_0_RAM_TYPE_SGRAM_16MBIT);
for (i = 0; i < 4; i++)
poke_fb(dev, fb, 4 * i, patt);
poke_fb(dev, fb, 0x400000, patt + 1);
if (peek_fb(dev, fb, 0) == patt + 1) {
bios_md32(bios, NV04_PFB_BOOT_0, NV04_PFB_BOOT_0_RAM_TYPE,
NV04_PFB_BOOT_0_RAM_TYPE_SDRAM_16MBIT);
bios_md32(bios, NV04_PFB_DEBUG_0,
NV04_PFB_DEBUG_0_REFRESH_OFF, 0);
for (i = 0; i < 4; i++)
poke_fb(dev, fb, 4 * i, patt);
if ((peek_fb(dev, fb, 0xc) & 0xffff) != (patt & 0xffff))
bios_md32(bios, NV04_PFB_BOOT_0,
NV04_PFB_BOOT_0_RAM_WIDTH_128 |
NV04_PFB_BOOT_0_RAM_AMOUNT,
NV04_PFB_BOOT_0_RAM_AMOUNT_8MB);
} else if ((peek_fb(dev, fb, 0xc) & 0xffff0000) !=
(patt & 0xffff0000)) {
bios_md32(bios, NV04_PFB_BOOT_0,
NV04_PFB_BOOT_0_RAM_WIDTH_128 |
NV04_PFB_BOOT_0_RAM_AMOUNT,
NV04_PFB_BOOT_0_RAM_AMOUNT_4MB);
} else if (peek_fb(dev, fb, 0) != patt) {
if (read_back_fb(dev, fb, 0x800000, patt))
bios_md32(bios, NV04_PFB_BOOT_0,
NV04_PFB_BOOT_0_RAM_AMOUNT,
NV04_PFB_BOOT_0_RAM_AMOUNT_8MB);
else
bios_md32(bios, NV04_PFB_BOOT_0,
NV04_PFB_BOOT_0_RAM_AMOUNT,
NV04_PFB_BOOT_0_RAM_AMOUNT_4MB);
bios_md32(bios, NV04_PFB_BOOT_0, NV04_PFB_BOOT_0_RAM_TYPE,
NV04_PFB_BOOT_0_RAM_TYPE_SGRAM_8MBIT);
} else if (!read_back_fb(dev, fb, 0x800000, patt)) {
bios_md32(bios, NV04_PFB_BOOT_0, NV04_PFB_BOOT_0_RAM_AMOUNT,
NV04_PFB_BOOT_0_RAM_AMOUNT_8MB);
}
/* Refresh on, sequencer on */
bios_md32(bios, NV04_PFB_DEBUG_0, NV04_PFB_DEBUG_0_REFRESH_OFF, 0);
NVWriteVgaSeq(dev, 0, 1, NVReadVgaSeq(dev, 0, 1) & ~0x20);
io_mapping_free(fb);
return 0;
}
static const uint8_t *
nv05_memory_config(struct nvbios *bios)
{
/* Defaults for BIOSes lacking a memory config table */
static const uint8_t default_config_tab[][2] = {
{ 0x24, 0x00 },
{ 0x28, 0x00 },
{ 0x24, 0x01 },
{ 0x1f, 0x00 },
{ 0x0f, 0x00 },
{ 0x17, 0x00 },
{ 0x06, 0x00 },
{ 0x00, 0x00 }
};
int i = (bios_rd32(bios, NV_PEXTDEV_BOOT_0) &
NV_PEXTDEV_BOOT_0_RAMCFG) >> 2;
if (bios->legacy.mem_init_tbl_ptr)
return &bios->data[bios->legacy.mem_init_tbl_ptr + 2 * i];
else
return default_config_tab[i];
}
static int
nv05_init_compute_mem(struct nvbios *bios)
{
struct drm_device *dev = bios->dev;
const uint8_t *ramcfg = nv05_memory_config(bios);
uint32_t patt = 0xdeadbeef;
struct io_mapping *fb;
int i, v;
/* Map the framebuffer aperture */
fb = io_mapping_create_wc(pci_resource_start(dev->pdev, 1),
pci_resource_len(dev->pdev, 1));
if (!fb)
return -ENOMEM;
/* Sequencer off */
NVWriteVgaSeq(dev, 0, 1, NVReadVgaSeq(dev, 0, 1) | 0x20);
if (bios_rd32(bios, NV04_PFB_BOOT_0) & NV04_PFB_BOOT_0_UMA_ENABLE)
goto out;
bios_md32(bios, NV04_PFB_DEBUG_0, NV04_PFB_DEBUG_0_REFRESH_OFF, 0);
/* If present load the hardcoded scrambling table */
if (bios->legacy.mem_init_tbl_ptr) {
uint32_t *scramble_tab = (uint32_t *)&bios->data[
bios->legacy.mem_init_tbl_ptr + 0x10];
for (i = 0; i < 8; i++)
bios_wr32(bios, NV04_PFB_SCRAMBLE(i),
ROM32(scramble_tab[i]));
}
/* Set memory type/width/length defaults depending on the straps */
bios_md32(bios, NV04_PFB_BOOT_0, 0x3f, ramcfg[0]);
if (ramcfg[1] & 0x80)
bios_md32(bios, NV04_PFB_CFG0, 0, NV04_PFB_CFG0_SCRAMBLE);
bios_md32(bios, NV04_PFB_CFG1, 0x700001, (ramcfg[1] & 1) << 20);
bios_md32(bios, NV04_PFB_CFG1, 0, 1);
/* Probe memory bus width */
for (i = 0; i < 4; i++)
poke_fb(dev, fb, 4 * i, patt);
if (peek_fb(dev, fb, 0xc) != patt)
bios_md32(bios, NV04_PFB_BOOT_0,
NV04_PFB_BOOT_0_RAM_WIDTH_128, 0);
/* Probe memory length */
v = bios_rd32(bios, NV04_PFB_BOOT_0) & NV04_PFB_BOOT_0_RAM_AMOUNT;
if (v == NV04_PFB_BOOT_0_RAM_AMOUNT_32MB &&
(!read_back_fb(dev, fb, 0x1000000, ++patt) ||
!read_back_fb(dev, fb, 0, ++patt)))
bios_md32(bios, NV04_PFB_BOOT_0, NV04_PFB_BOOT_0_RAM_AMOUNT,
NV04_PFB_BOOT_0_RAM_AMOUNT_16MB);
if (v == NV04_PFB_BOOT_0_RAM_AMOUNT_16MB &&
!read_back_fb(dev, fb, 0x800000, ++patt))
bios_md32(bios, NV04_PFB_BOOT_0, NV04_PFB_BOOT_0_RAM_AMOUNT,
NV04_PFB_BOOT_0_RAM_AMOUNT_8MB);
if (!read_back_fb(dev, fb, 0x400000, ++patt))
bios_md32(bios, NV04_PFB_BOOT_0, NV04_PFB_BOOT_0_RAM_AMOUNT,
NV04_PFB_BOOT_0_RAM_AMOUNT_4MB);
out:
/* Sequencer on */
NVWriteVgaSeq(dev, 0, 1, NVReadVgaSeq(dev, 0, 1) & ~0x20);
io_mapping_free(fb);
return 0;
}
static int
nv10_init_compute_mem(struct nvbios *bios)
{
struct drm_device *dev = bios->dev;
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
const int mem_width[] = { 0x10, 0x00, 0x20 };
const int mem_width_count = (dev_priv->chipset >= 0x17 ? 3 : 2);
uint32_t patt = 0xdeadbeef;
struct io_mapping *fb;
int i, j, k;
/* Map the framebuffer aperture */
fb = io_mapping_create_wc(pci_resource_start(dev->pdev, 1),
pci_resource_len(dev->pdev, 1));
if (!fb)
return -ENOMEM;
bios_wr32(bios, NV10_PFB_REFCTRL, NV10_PFB_REFCTRL_VALID_1);
/* Probe memory bus width */
for (i = 0; i < mem_width_count; i++) {
bios_md32(bios, NV04_PFB_CFG0, 0x30, mem_width[i]);
for (j = 0; j < 4; j++) {
for (k = 0; k < 4; k++)
poke_fb(dev, fb, 0x1c, 0);
poke_fb(dev, fb, 0x1c, patt);
poke_fb(dev, fb, 0x3c, 0);
if (peek_fb(dev, fb, 0x1c) == patt)
goto mem_width_found;
}
}
mem_width_found:
patt <<= 1;
/* Probe amount of installed memory */
for (i = 0; i < 4; i++) {
int off = bios_rd32(bios, NV04_PFB_FIFO_DATA) - 0x100000;
poke_fb(dev, fb, off, patt);
poke_fb(dev, fb, 0, 0);
peek_fb(dev, fb, 0);
peek_fb(dev, fb, 0);
peek_fb(dev, fb, 0);
peek_fb(dev, fb, 0);
if (peek_fb(dev, fb, off) == patt)
goto amount_found;
}
/* IC missing - disable the upper half memory space. */
bios_md32(bios, NV04_PFB_CFG0, 0x1000, 0);
amount_found:
io_mapping_free(fb);
return 0;
}
static int
nv20_init_compute_mem(struct nvbios *bios)
{
struct drm_device *dev = bios->dev;
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
uint32_t mask = (dev_priv->chipset >= 0x25 ? 0x300 : 0x900);
uint32_t amount, off;
struct io_mapping *fb;
/* Map the framebuffer aperture */
fb = io_mapping_create_wc(pci_resource_start(dev->pdev, 1),
pci_resource_len(dev->pdev, 1));
if (!fb)
return -ENOMEM;
bios_wr32(bios, NV10_PFB_REFCTRL, NV10_PFB_REFCTRL_VALID_1);
/* Allow full addressing */
bios_md32(bios, NV04_PFB_CFG0, 0, mask);
amount = bios_rd32(bios, NV04_PFB_FIFO_DATA);
for (off = amount; off > 0x2000000; off -= 0x2000000)
poke_fb(dev, fb, off - 4, off);
amount = bios_rd32(bios, NV04_PFB_FIFO_DATA);
if (amount != peek_fb(dev, fb, amount - 4))
/* IC missing - disable the upper half memory space. */
bios_md32(bios, NV04_PFB_CFG0, mask, 0);
io_mapping_free(fb);
return 0;
}
static int
init_compute_mem(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_COMPUTE_MEM opcode: 0x63 ('c')
*
* offset (8 bit): opcode
*
* This opcode is meant to set the PFB memory config registers
* appropriately so that we can correctly calculate how much VRAM it
* has (on nv10 and better chipsets the amount of installed VRAM is
* subsequently reported in NV_PFB_CSTATUS (0x10020C)).
*
* The implementation of this opcode in general consists of several
* parts:
*
* 1) Determination of memory type and density. Only necessary for
* really old chipsets, the memory type reported by the strap bits
* (0x101000) is assumed to be accurate on nv05 and newer.
*
* 2) Determination of the memory bus width. Usually done by a cunning
* combination of writes to offsets 0x1c and 0x3c in the fb, and
* seeing whether the written values are read back correctly.
*
* Only necessary on nv0x-nv1x and nv34, on the other cards we can
* trust the straps.
*
* 3) Determination of how many of the card's RAM pads have ICs
* attached, usually done by a cunning combination of writes to an
* offset slightly less than the maximum memory reported by
* NV_PFB_CSTATUS, then seeing if the test pattern can be read back.
*
* This appears to be a NOP on IGPs and NV4x or newer chipsets, both io
* logs of the VBIOS and kmmio traces of the binary driver POSTing the
* card show nothing being done for this opcode. Why is it still listed
* in the table?!
*/
/* no iexec->execute check by design */
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
int ret;
if (dev_priv->chipset >= 0x40 ||
dev_priv->chipset == 0x1a ||
dev_priv->chipset == 0x1f)
ret = 0;
else if (dev_priv->chipset >= 0x20 &&
dev_priv->chipset != 0x34)
ret = nv20_init_compute_mem(bios);
else if (dev_priv->chipset >= 0x10)
ret = nv10_init_compute_mem(bios);
else if (dev_priv->chipset >= 0x5)
ret = nv05_init_compute_mem(bios);
else
ret = nv04_init_compute_mem(bios);
if (ret)
return ret;
return 1;
}
static int
init_reset(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_RESET opcode: 0x65 ('e')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): register
* offset + 5 (32 bit): value1
* offset + 9 (32 bit): value2
*
* Assign "value1" to "register", then assign "value2" to "register"
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint32_t value1 = ROM32(bios->data[offset + 5]);
uint32_t value2 = ROM32(bios->data[offset + 9]);
uint32_t pci_nv_19, pci_nv_20;
/* no iexec->execute check by design */
pci_nv_19 = bios_rd32(bios, NV_PBUS_PCI_NV_19);
bios_wr32(bios, NV_PBUS_PCI_NV_19, pci_nv_19 & ~0xf00);
bios_wr32(bios, reg, value1);
udelay(10);
bios_wr32(bios, reg, value2);
bios_wr32(bios, NV_PBUS_PCI_NV_19, pci_nv_19);
pci_nv_20 = bios_rd32(bios, NV_PBUS_PCI_NV_20);
pci_nv_20 &= ~NV_PBUS_PCI_NV_20_ROM_SHADOW_ENABLED; /* 0xfffffffe */
bios_wr32(bios, NV_PBUS_PCI_NV_20, pci_nv_20);
return 13;
}
static int
init_configure_mem(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_CONFIGURE_MEM opcode: 0x66 ('f')
*
* offset (8 bit): opcode
*
* Equivalent to INIT_DONE on bios version 3 or greater.
* For early bios versions, sets up the memory registers, using values
* taken from the memory init table
*/
/* no iexec->execute check by design */
uint16_t meminitoffs = bios->legacy.mem_init_tbl_ptr + MEM_INIT_SIZE * (bios_idxprt_rd(bios, NV_CIO_CRX__COLOR, NV_CIO_CRE_SCRATCH4__INDEX) >> 4);
uint16_t seqtbloffs = bios->legacy.sdr_seq_tbl_ptr, meminitdata = meminitoffs + 6;
uint32_t reg, data;
if (bios->major_version > 2)
return 0;
bios_idxprt_wr(bios, NV_VIO_SRX, NV_VIO_SR_CLOCK_INDEX, bios_idxprt_rd(
bios, NV_VIO_SRX, NV_VIO_SR_CLOCK_INDEX) | 0x20);
if (bios->data[meminitoffs] & 1)
seqtbloffs = bios->legacy.ddr_seq_tbl_ptr;
for (reg = ROM32(bios->data[seqtbloffs]);
reg != 0xffffffff;
reg = ROM32(bios->data[seqtbloffs += 4])) {
switch (reg) {
case NV04_PFB_PRE:
data = NV04_PFB_PRE_CMD_PRECHARGE;
break;
case NV04_PFB_PAD:
data = NV04_PFB_PAD_CKE_NORMAL;
break;
case NV04_PFB_REF:
data = NV04_PFB_REF_CMD_REFRESH;
break;
default:
data = ROM32(bios->data[meminitdata]);
meminitdata += 4;
if (data == 0xffffffff)
continue;
}
bios_wr32(bios, reg, data);
}
return 1;
}
static int
init_configure_clk(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_CONFIGURE_CLK opcode: 0x67 ('g')
*
* offset (8 bit): opcode
*
* Equivalent to INIT_DONE on bios version 3 or greater.
* For early bios versions, sets up the NVClk and MClk PLLs, using
* values taken from the memory init table
*/
/* no iexec->execute check by design */
uint16_t meminitoffs = bios->legacy.mem_init_tbl_ptr + MEM_INIT_SIZE * (bios_idxprt_rd(bios, NV_CIO_CRX__COLOR, NV_CIO_CRE_SCRATCH4__INDEX) >> 4);
int clock;
if (bios->major_version > 2)
return 0;
clock = ROM16(bios->data[meminitoffs + 4]) * 10;
setPLL(bios, NV_PRAMDAC_NVPLL_COEFF, clock);
clock = ROM16(bios->data[meminitoffs + 2]) * 10;
if (bios->data[meminitoffs] & 1) /* DDR */
clock *= 2;
setPLL(bios, NV_PRAMDAC_MPLL_COEFF, clock);
return 1;
}
static int
init_configure_preinit(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_CONFIGURE_PREINIT opcode: 0x68 ('h')
*
* offset (8 bit): opcode
*
* Equivalent to INIT_DONE on bios version 3 or greater.
* For early bios versions, does early init, loading ram and crystal
* configuration from straps into CR3C
*/
/* no iexec->execute check by design */
uint32_t straps = bios_rd32(bios, NV_PEXTDEV_BOOT_0);
uint8_t cr3c = ((straps << 2) & 0xf0) | (straps & 0x40) >> 6;
if (bios->major_version > 2)
return 0;
bios_idxprt_wr(bios, NV_CIO_CRX__COLOR,
NV_CIO_CRE_SCRATCH4__INDEX, cr3c);
return 1;
}
static int
init_io(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_IO opcode: 0x69 ('i')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): CRTC port
* offset + 3 (8 bit): mask
* offset + 4 (8 bit): data
*
* Assign ((IOVAL("crtc port") & "mask") | "data") to "crtc port"
*/
struct drm_nouveau_private *dev_priv = bios->dev->dev_private;
uint16_t crtcport = ROM16(bios->data[offset + 1]);
uint8_t mask = bios->data[offset + 3];
uint8_t data = bios->data[offset + 4];
if (!iexec->execute)
return 5;
BIOSLOG(bios, "0x%04X: Port: 0x%04X, Mask: 0x%02X, Data: 0x%02X\n",
offset, crtcport, mask, data);
/*
* I have no idea what this does, but NVIDIA do this magic sequence
* in the places where this INIT_IO happens..
*/
if (dev_priv->card_type >= NV_50 && crtcport == 0x3c3 && data == 1) {
int i;
bios_wr32(bios, 0x614100, (bios_rd32(
bios, 0x614100) & 0x0fffffff) | 0x00800000);
bios_wr32(bios, 0x00e18c, bios_rd32(
bios, 0x00e18c) | 0x00020000);
bios_wr32(bios, 0x614900, (bios_rd32(
bios, 0x614900) & 0x0fffffff) | 0x00800000);
bios_wr32(bios, 0x000200, bios_rd32(
bios, 0x000200) & ~0x40000000);
mdelay(10);
bios_wr32(bios, 0x00e18c, bios_rd32(
bios, 0x00e18c) & ~0x00020000);
bios_wr32(bios, 0x000200, bios_rd32(
bios, 0x000200) | 0x40000000);
bios_wr32(bios, 0x614100, 0x00800018);
bios_wr32(bios, 0x614900, 0x00800018);
mdelay(10);
bios_wr32(bios, 0x614100, 0x10000018);
bios_wr32(bios, 0x614900, 0x10000018);
for (i = 0; i < 3; i++)
bios_wr32(bios, 0x614280 + (i*0x800), bios_rd32(
bios, 0x614280 + (i*0x800)) & 0xf0f0f0f0);
for (i = 0; i < 2; i++)
bios_wr32(bios, 0x614300 + (i*0x800), bios_rd32(
bios, 0x614300 + (i*0x800)) & 0xfffff0f0);
for (i = 0; i < 3; i++)
bios_wr32(bios, 0x614380 + (i*0x800), bios_rd32(
bios, 0x614380 + (i*0x800)) & 0xfffff0f0);
for (i = 0; i < 2; i++)
bios_wr32(bios, 0x614200 + (i*0x800), bios_rd32(
bios, 0x614200 + (i*0x800)) & 0xfffffff0);
for (i = 0; i < 2; i++)
bios_wr32(bios, 0x614108 + (i*0x800), bios_rd32(
bios, 0x614108 + (i*0x800)) & 0x0fffffff);
return 5;
}
bios_port_wr(bios, crtcport, (bios_port_rd(bios, crtcport) & mask) |
data);
return 5;
}
static int
init_sub(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_SUB opcode: 0x6B ('k')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): script number
*
* Execute script number "script number", as a subroutine
*/
uint8_t sub = bios->data[offset + 1];
if (!iexec->execute)
return 2;
BIOSLOG(bios, "0x%04X: Calling script %d\n", offset, sub);
parse_init_table(bios,
ROM16(bios->data[bios->init_script_tbls_ptr + sub * 2]),
iexec);
BIOSLOG(bios, "0x%04X: End of script %d\n", offset, sub);
return 2;
}
static int
init_ram_condition(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_RAM_CONDITION opcode: 0x6D ('m')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): mask
* offset + 2 (8 bit): cmpval
*
* Test if (NV04_PFB_BOOT_0 & "mask") equals "cmpval".
* If condition not met skip subsequent opcodes until condition is
* inverted (INIT_NOT), or we hit INIT_RESUME
*/
uint8_t mask = bios->data[offset + 1];
uint8_t cmpval = bios->data[offset + 2];
uint8_t data;
if (!iexec->execute)
return 3;
data = bios_rd32(bios, NV04_PFB_BOOT_0) & mask;
BIOSLOG(bios, "0x%04X: Checking if 0x%08X equals 0x%08X\n",
offset, data, cmpval);
if (data == cmpval)
BIOSLOG(bios, "0x%04X: Condition fulfilled -- continuing to execute\n", offset);
else {
BIOSLOG(bios, "0x%04X: Condition not fulfilled -- skipping following commands\n", offset);
iexec->execute = false;
}
return 3;
}
static int
init_nv_reg(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_NV_REG opcode: 0x6E ('n')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): register
* offset + 5 (32 bit): mask
* offset + 9 (32 bit): data
*
* Assign ((REGVAL("register") & "mask") | "data") to "register"
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint32_t mask = ROM32(bios->data[offset + 5]);
uint32_t data = ROM32(bios->data[offset + 9]);
if (!iexec->execute)
return 13;
BIOSLOG(bios, "0x%04X: Reg: 0x%08X, Mask: 0x%08X, Data: 0x%08X\n",
offset, reg, mask, data);
bios_wr32(bios, reg, (bios_rd32(bios, reg) & mask) | data);
return 13;
}
static int
init_macro(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_MACRO opcode: 0x6F ('o')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): macro number
*
* Look up macro index "macro number" in the macro index table.
* The macro index table entry has 1 byte for the index in the macro
* table, and 1 byte for the number of times to repeat the macro.
* The macro table entry has 4 bytes for the register address and
* 4 bytes for the value to write to that register
*/
uint8_t macro_index_tbl_idx = bios->data[offset + 1];
uint16_t tmp = bios->macro_index_tbl_ptr + (macro_index_tbl_idx * MACRO_INDEX_SIZE);
uint8_t macro_tbl_idx = bios->data[tmp];
uint8_t count = bios->data[tmp + 1];
uint32_t reg, data;
int i;
if (!iexec->execute)
return 2;
BIOSLOG(bios, "0x%04X: Macro: 0x%02X, MacroTableIndex: 0x%02X, "
"Count: 0x%02X\n",
offset, macro_index_tbl_idx, macro_tbl_idx, count);
for (i = 0; i < count; i++) {
uint16_t macroentryptr = bios->macro_tbl_ptr + (macro_tbl_idx + i) * MACRO_SIZE;
reg = ROM32(bios->data[macroentryptr]);
data = ROM32(bios->data[macroentryptr + 4]);
bios_wr32(bios, reg, data);
}
return 2;
}
static int
init_done(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_DONE opcode: 0x71 ('q')
*
* offset (8 bit): opcode
*
* End the current script
*/
/* mild retval abuse to stop parsing this table */
return 0;
}
static int
init_resume(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_RESUME opcode: 0x72 ('r')
*
* offset (8 bit): opcode
*
* End the current execute / no-execute condition
*/
if (iexec->execute)
return 1;
iexec->execute = true;
BIOSLOG(bios, "0x%04X: ---- Executing following commands ----\n", offset);
return 1;
}
static int
init_time(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_TIME opcode: 0x74 ('t')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): time
*
* Sleep for "time" microseconds.
*/
unsigned time = ROM16(bios->data[offset + 1]);
if (!iexec->execute)
return 3;
BIOSLOG(bios, "0x%04X: Sleeping for 0x%04X microseconds\n",
offset, time);
if (time < 1000)
udelay(time);
else
mdelay((time + 900) / 1000);
return 3;
}
static int
init_condition(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_CONDITION opcode: 0x75 ('u')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): condition number
*
* Check condition "condition number" in the condition table.
* If condition not met skip subsequent opcodes until condition is
* inverted (INIT_NOT), or we hit INIT_RESUME
*/
uint8_t cond = bios->data[offset + 1];
if (!iexec->execute)
return 2;
BIOSLOG(bios, "0x%04X: Condition: 0x%02X\n", offset, cond);
if (bios_condition_met(bios, offset, cond))
BIOSLOG(bios, "0x%04X: Condition fulfilled -- continuing to execute\n", offset);
else {
BIOSLOG(bios, "0x%04X: Condition not fulfilled -- skipping following commands\n", offset);
iexec->execute = false;
}
return 2;
}
static int
init_io_condition(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_IO_CONDITION opcode: 0x76
*
* offset (8 bit): opcode
* offset + 1 (8 bit): condition number
*
* Check condition "condition number" in the io condition table.
* If condition not met skip subsequent opcodes until condition is
* inverted (INIT_NOT), or we hit INIT_RESUME
*/
uint8_t cond = bios->data[offset + 1];
if (!iexec->execute)
return 2;
BIOSLOG(bios, "0x%04X: IO condition: 0x%02X\n", offset, cond);
if (io_condition_met(bios, offset, cond))
BIOSLOG(bios, "0x%04X: Condition fulfilled -- continuing to execute\n", offset);
else {
BIOSLOG(bios, "0x%04X: Condition not fulfilled -- skipping following commands\n", offset);
iexec->execute = false;
}
return 2;
}
static int
init_index_io(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_INDEX_IO opcode: 0x78 ('x')
*
* offset (8 bit): opcode
* offset + 1 (16 bit): CRTC port
* offset + 3 (8 bit): CRTC index
* offset + 4 (8 bit): mask
* offset + 5 (8 bit): data
*
* Read value at index "CRTC index" on "CRTC port", AND with "mask",
* OR with "data", write-back
*/
uint16_t crtcport = ROM16(bios->data[offset + 1]);
uint8_t crtcindex = bios->data[offset + 3];
uint8_t mask = bios->data[offset + 4];
uint8_t data = bios->data[offset + 5];
uint8_t value;
if (!iexec->execute)
return 6;
BIOSLOG(bios, "0x%04X: Port: 0x%04X, Index: 0x%02X, Mask: 0x%02X, "
"Data: 0x%02X\n",
offset, crtcport, crtcindex, mask, data);
value = (bios_idxprt_rd(bios, crtcport, crtcindex) & mask) | data;
bios_idxprt_wr(bios, crtcport, crtcindex, value);
return 6;
}
static int
init_pll(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_PLL opcode: 0x79 ('y')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): register
* offset + 5 (16 bit): freq
*
* Set PLL register "register" to coefficients for frequency (10kHz)
* "freq"
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint16_t freq = ROM16(bios->data[offset + 5]);
if (!iexec->execute)
return 7;
BIOSLOG(bios, "0x%04X: Reg: 0x%08X, Freq: %d0kHz\n", offset, reg, freq);
setPLL(bios, reg, freq * 10);
return 7;
}
static int
init_zm_reg(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_ZM_REG opcode: 0x7A ('z')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): register
* offset + 5 (32 bit): value
*
* Assign "value" to "register"
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint32_t value = ROM32(bios->data[offset + 5]);
if (!iexec->execute)
return 9;
if (reg == 0x000200)
value |= 1;
bios_wr32(bios, reg, value);
return 9;
}
static int
init_ram_restrict_pll(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_RAM_RESTRICT_PLL opcode: 0x87 ('')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): PLL type
* offset + 2 (32 bit): frequency 0
*
* Uses the RAMCFG strap of PEXTDEV_BOOT as an index into the table at
* ram_restrict_table_ptr. The value read from there is used to select
* a frequency from the table starting at 'frequency 0' to be
* programmed into the PLL corresponding to 'type'.
*
* The PLL limits table on cards using this opcode has a mapping of
* 'type' to the relevant registers.
*/
struct drm_device *dev = bios->dev;
uint32_t strap = (bios_rd32(bios, NV_PEXTDEV_BOOT_0) & 0x0000003c) >> 2;
uint8_t index = bios->data[bios->ram_restrict_tbl_ptr + strap];
uint8_t type = bios->data[offset + 1];
uint32_t freq = ROM32(bios->data[offset + 2 + (index * 4)]);
uint8_t *pll_limits = &bios->data[bios->pll_limit_tbl_ptr], *entry;
int len = 2 + bios->ram_restrict_group_count * 4;
int i;
if (!iexec->execute)
return len;
if (!bios->pll_limit_tbl_ptr || (pll_limits[0] & 0xf0) != 0x30) {
NV_ERROR(dev, "PLL limits table not version 3.x\n");
return len; /* deliberate, allow default clocks to remain */
}
entry = pll_limits + pll_limits[1];
for (i = 0; i < pll_limits[3]; i++, entry += pll_limits[2]) {
if (entry[0] == type) {
uint32_t reg = ROM32(entry[3]);
BIOSLOG(bios, "0x%04X: "
"Type %02x Reg 0x%08x Freq %dKHz\n",
offset, type, reg, freq);
setPLL(bios, reg, freq);
return len;
}
}
NV_ERROR(dev, "PLL type 0x%02x not found in PLL limits table", type);
return len;
}
static int
init_8c(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_8C opcode: 0x8C ('')
*
* NOP so far....
*
*/
return 1;
}
static int
init_8d(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_8D opcode: 0x8D ('')
*
* NOP so far....
*
*/
return 1;
}
static int
init_gpio(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_GPIO opcode: 0x8E ('')
*
* offset (8 bit): opcode
*
* Loop over all entries in the DCB GPIO table, and initialise
* each GPIO according to various values listed in each entry
*/
if (iexec->execute && bios->execute)
nouveau_gpio_reset(bios->dev);
return 1;
}
static int
init_ram_restrict_zm_reg_group(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_RAM_RESTRICT_ZM_REG_GROUP opcode: 0x8F ('')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): reg
* offset + 5 (8 bit): regincrement
* offset + 6 (8 bit): count
* offset + 7 (32 bit): value 1,1
* ...
*
* Use the RAMCFG strap of PEXTDEV_BOOT as an index into the table at
* ram_restrict_table_ptr. The value read from here is 'n', and
* "value 1,n" gets written to "reg". This repeats "count" times and on
* each iteration 'm', "reg" increases by "regincrement" and
* "value m,n" is used. The extent of n is limited by a number read
* from the 'M' BIT table, herein called "blocklen"
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint8_t regincrement = bios->data[offset + 5];
uint8_t count = bios->data[offset + 6];
uint32_t strap_ramcfg, data;
/* previously set by 'M' BIT table */
uint16_t blocklen = bios->ram_restrict_group_count * 4;
int len = 7 + count * blocklen;
uint8_t index;
int i;
/* critical! to know the length of the opcode */;
if (!blocklen) {
NV_ERROR(bios->dev,
"0x%04X: Zero block length - has the M table "
"been parsed?\n", offset);
return -EINVAL;
}
if (!iexec->execute)
return len;
strap_ramcfg = (bios_rd32(bios, NV_PEXTDEV_BOOT_0) >> 2) & 0xf;
index = bios->data[bios->ram_restrict_tbl_ptr + strap_ramcfg];
BIOSLOG(bios, "0x%04X: Reg: 0x%08X, RegIncrement: 0x%02X, "
"Count: 0x%02X, StrapRamCfg: 0x%02X, Index: 0x%02X\n",
offset, reg, regincrement, count, strap_ramcfg, index);
for (i = 0; i < count; i++) {
data = ROM32(bios->data[offset + 7 + index * 4 + blocklen * i]);
bios_wr32(bios, reg, data);
reg += regincrement;
}
return len;
}
static int
init_copy_zm_reg(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_COPY_ZM_REG opcode: 0x90 ('')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): src reg
* offset + 5 (32 bit): dst reg
*
* Put contents of "src reg" into "dst reg"
*/
uint32_t srcreg = ROM32(bios->data[offset + 1]);
uint32_t dstreg = ROM32(bios->data[offset + 5]);
if (!iexec->execute)
return 9;
bios_wr32(bios, dstreg, bios_rd32(bios, srcreg));
return 9;
}
static int
init_zm_reg_group_addr_latched(struct nvbios *bios, uint16_t offset,
struct init_exec *iexec)
{
/*
* INIT_ZM_REG_GROUP_ADDRESS_LATCHED opcode: 0x91 ('')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): dst reg
* offset + 5 (8 bit): count
* offset + 6 (32 bit): data 1
* ...
*
* For each of "count" values write "data n" to "dst reg"
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint8_t count = bios->data[offset + 5];
int len = 6 + count * 4;
int i;
if (!iexec->execute)
return len;
for (i = 0; i < count; i++) {
uint32_t data = ROM32(bios->data[offset + 6 + 4 * i]);
bios_wr32(bios, reg, data);
}
return len;
}
static int
init_reserved(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_RESERVED opcode: 0x92 ('')
*
* offset (8 bit): opcode
*
* Seemingly does nothing
*/
return 1;
}
static int
init_96(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_96 opcode: 0x96 ('')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): sreg
* offset + 5 (8 bit): sshift
* offset + 6 (8 bit): smask
* offset + 7 (8 bit): index
* offset + 8 (32 bit): reg
* offset + 12 (32 bit): mask
* offset + 16 (8 bit): shift
*
*/
uint16_t xlatptr = bios->init96_tbl_ptr + (bios->data[offset + 7] * 2);
uint32_t reg = ROM32(bios->data[offset + 8]);
uint32_t mask = ROM32(bios->data[offset + 12]);
uint32_t val;
val = bios_rd32(bios, ROM32(bios->data[offset + 1]));
if (bios->data[offset + 5] < 0x80)
val >>= bios->data[offset + 5];
else
val <<= (0x100 - bios->data[offset + 5]);
val &= bios->data[offset + 6];
val = bios->data[ROM16(bios->data[xlatptr]) + val];
val <<= bios->data[offset + 16];
if (!iexec->execute)
return 17;
bios_wr32(bios, reg, (bios_rd32(bios, reg) & mask) | val);
return 17;
}
static int
init_97(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_97 opcode: 0x97 ('')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): register
* offset + 5 (32 bit): mask
* offset + 9 (32 bit): value
*
* Adds "value" to "register" preserving the fields specified
* by "mask"
*/
uint32_t reg = ROM32(bios->data[offset + 1]);
uint32_t mask = ROM32(bios->data[offset + 5]);
uint32_t add = ROM32(bios->data[offset + 9]);
uint32_t val;
val = bios_rd32(bios, reg);
val = (val & mask) | ((val + add) & ~mask);
if (!iexec->execute)
return 13;
bios_wr32(bios, reg, val);
return 13;
}
static int
init_auxch(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_AUXCH opcode: 0x98 ('')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): address
* offset + 5 (8 bit): count
* offset + 6 (8 bit): mask 0
* offset + 7 (8 bit): data 0
* ...
*
*/
struct drm_device *dev = bios->dev;
struct nouveau_i2c_chan *auxch;
uint32_t addr = ROM32(bios->data[offset + 1]);
uint8_t count = bios->data[offset + 5];
int len = 6 + count * 2;
int ret, i;
if (!bios->display.output) {
NV_ERROR(dev, "INIT_AUXCH: no active output\n");
return len;
}
auxch = init_i2c_device_find(dev, bios->display.output->i2c_index);
if (!auxch) {
NV_ERROR(dev, "INIT_AUXCH: couldn't get auxch %d\n",
bios->display.output->i2c_index);
return len;
}
if (!iexec->execute)
return len;
offset += 6;
for (i = 0; i < count; i++, offset += 2) {
uint8_t data;
ret = nouveau_dp_auxch(auxch, 9, addr, &data, 1);
if (ret) {
NV_ERROR(dev, "INIT_AUXCH: rd auxch fail %d\n", ret);
return len;
}
data &= bios->data[offset + 0];
data |= bios->data[offset + 1];
ret = nouveau_dp_auxch(auxch, 8, addr, &data, 1);
if (ret) {
NV_ERROR(dev, "INIT_AUXCH: wr auxch fail %d\n", ret);
return len;
}
}
return len;
}
static int
init_zm_auxch(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_ZM_AUXCH opcode: 0x99 ('')
*
* offset (8 bit): opcode
* offset + 1 (32 bit): address
* offset + 5 (8 bit): count
* offset + 6 (8 bit): data 0
* ...
*
*/
struct drm_device *dev = bios->dev;
struct nouveau_i2c_chan *auxch;
uint32_t addr = ROM32(bios->data[offset + 1]);
uint8_t count = bios->data[offset + 5];
int len = 6 + count;
int ret, i;
if (!bios->display.output) {
NV_ERROR(dev, "INIT_ZM_AUXCH: no active output\n");
return len;
}
auxch = init_i2c_device_find(dev, bios->display.output->i2c_index);
if (!auxch) {
NV_ERROR(dev, "INIT_ZM_AUXCH: couldn't get auxch %d\n",
bios->display.output->i2c_index);
return len;
}
if (!iexec->execute)
return len;
offset += 6;
for (i = 0; i < count; i++, offset++) {
ret = nouveau_dp_auxch(auxch, 8, addr, &bios->data[offset], 1);
if (ret) {
NV_ERROR(dev, "INIT_ZM_AUXCH: wr auxch fail %d\n", ret);
return len;
}
}
return len;
}
static int
init_i2c_long_if(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* INIT_I2C_LONG_IF opcode: 0x9A ('')
*
* offset (8 bit): opcode
* offset + 1 (8 bit): DCB I2C table entry index
* offset + 2 (8 bit): I2C slave address
* offset + 3 (16 bit): I2C register
* offset + 5 (8 bit): mask
* offset + 6 (8 bit): data
*
* Read the register given by "I2C register" on the device addressed
* by "I2C slave address" on the I2C bus given by "DCB I2C table
* entry index". Compare the result AND "mask" to "data".
* If they're not equal, skip subsequent opcodes until condition is
* inverted (INIT_NOT), or we hit INIT_RESUME
*/
uint8_t i2c_index = bios->data[offset + 1];
uint8_t i2c_address = bios->data[offset + 2] >> 1;
uint8_t reglo = bios->data[offset + 3];
uint8_t reghi = bios->data[offset + 4];
uint8_t mask = bios->data[offset + 5];
uint8_t data = bios->data[offset + 6];
struct nouveau_i2c_chan *chan;
uint8_t buf0[2] = { reghi, reglo };
uint8_t buf1[1];
struct i2c_msg msg[2] = {
{ i2c_address, 0, 1, buf0 },
{ i2c_address, I2C_M_RD, 1, buf1 },
};
int ret;
/* no execute check by design */
BIOSLOG(bios, "0x%04X: DCBI2CIndex: 0x%02X, I2CAddress: 0x%02X\n",
offset, i2c_index, i2c_address);
chan = init_i2c_device_find(bios->dev, i2c_index);
if (!chan)
return -ENODEV;
ret = i2c_transfer(&chan->adapter, msg, 2);
if (ret < 0) {
BIOSLOG(bios, "0x%04X: I2CReg: 0x%02X:0x%02X, Value: [no device], "
"Mask: 0x%02X, Data: 0x%02X\n",
offset, reghi, reglo, mask, data);
iexec->execute = 0;
return 7;
}
BIOSLOG(bios, "0x%04X: I2CReg: 0x%02X:0x%02X, Value: 0x%02X, "
"Mask: 0x%02X, Data: 0x%02X\n",
offset, reghi, reglo, buf1[0], mask, data);
iexec->execute = ((buf1[0] & mask) == data);
return 7;
}
static struct init_tbl_entry itbl_entry[] = {
/* command name , id , length , offset , mult , command handler */
/* INIT_PROG (0x31, 15, 10, 4) removed due to no example of use */
{ "INIT_IO_RESTRICT_PROG" , 0x32, init_io_restrict_prog },
{ "INIT_REPEAT" , 0x33, init_repeat },
{ "INIT_IO_RESTRICT_PLL" , 0x34, init_io_restrict_pll },
{ "INIT_END_REPEAT" , 0x36, init_end_repeat },
{ "INIT_COPY" , 0x37, init_copy },
{ "INIT_NOT" , 0x38, init_not },
{ "INIT_IO_FLAG_CONDITION" , 0x39, init_io_flag_condition },
{ "INIT_DP_CONDITION" , 0x3A, init_dp_condition },
{ "INIT_OP_3B" , 0x3B, init_op_3b },
{ "INIT_OP_3C" , 0x3C, init_op_3c },
{ "INIT_INDEX_ADDRESS_LATCHED" , 0x49, init_idx_addr_latched },
{ "INIT_IO_RESTRICT_PLL2" , 0x4A, init_io_restrict_pll2 },
{ "INIT_PLL2" , 0x4B, init_pll2 },
{ "INIT_I2C_BYTE" , 0x4C, init_i2c_byte },
{ "INIT_ZM_I2C_BYTE" , 0x4D, init_zm_i2c_byte },
{ "INIT_ZM_I2C" , 0x4E, init_zm_i2c },
{ "INIT_TMDS" , 0x4F, init_tmds },
{ "INIT_ZM_TMDS_GROUP" , 0x50, init_zm_tmds_group },
{ "INIT_CR_INDEX_ADDRESS_LATCHED" , 0x51, init_cr_idx_adr_latch },
{ "INIT_CR" , 0x52, init_cr },
{ "INIT_ZM_CR" , 0x53, init_zm_cr },
{ "INIT_ZM_CR_GROUP" , 0x54, init_zm_cr_group },
{ "INIT_CONDITION_TIME" , 0x56, init_condition_time },
{ "INIT_LTIME" , 0x57, init_ltime },
{ "INIT_ZM_REG_SEQUENCE" , 0x58, init_zm_reg_sequence },
/* INIT_INDIRECT_REG (0x5A, 7, 0, 0) removed due to no example of use */
{ "INIT_SUB_DIRECT" , 0x5B, init_sub_direct },
{ "INIT_JUMP" , 0x5C, init_jump },
{ "INIT_I2C_IF" , 0x5E, init_i2c_if },
{ "INIT_COPY_NV_REG" , 0x5F, init_copy_nv_reg },
{ "INIT_ZM_INDEX_IO" , 0x62, init_zm_index_io },
{ "INIT_COMPUTE_MEM" , 0x63, init_compute_mem },
{ "INIT_RESET" , 0x65, init_reset },
{ "INIT_CONFIGURE_MEM" , 0x66, init_configure_mem },
{ "INIT_CONFIGURE_CLK" , 0x67, init_configure_clk },
{ "INIT_CONFIGURE_PREINIT" , 0x68, init_configure_preinit },
{ "INIT_IO" , 0x69, init_io },
{ "INIT_SUB" , 0x6B, init_sub },
{ "INIT_RAM_CONDITION" , 0x6D, init_ram_condition },
{ "INIT_NV_REG" , 0x6E, init_nv_reg },
{ "INIT_MACRO" , 0x6F, init_macro },
{ "INIT_DONE" , 0x71, init_done },
{ "INIT_RESUME" , 0x72, init_resume },
/* INIT_RAM_CONDITION2 (0x73, 9, 0, 0) removed due to no example of use */
{ "INIT_TIME" , 0x74, init_time },
{ "INIT_CONDITION" , 0x75, init_condition },
{ "INIT_IO_CONDITION" , 0x76, init_io_condition },
{ "INIT_INDEX_IO" , 0x78, init_index_io },
{ "INIT_PLL" , 0x79, init_pll },
{ "INIT_ZM_REG" , 0x7A, init_zm_reg },
{ "INIT_RAM_RESTRICT_PLL" , 0x87, init_ram_restrict_pll },
{ "INIT_8C" , 0x8C, init_8c },
{ "INIT_8D" , 0x8D, init_8d },
{ "INIT_GPIO" , 0x8E, init_gpio },
{ "INIT_RAM_RESTRICT_ZM_REG_GROUP" , 0x8F, init_ram_restrict_zm_reg_group },
{ "INIT_COPY_ZM_REG" , 0x90, init_copy_zm_reg },
{ "INIT_ZM_REG_GROUP_ADDRESS_LATCHED" , 0x91, init_zm_reg_group_addr_latched },
{ "INIT_RESERVED" , 0x92, init_reserved },
{ "INIT_96" , 0x96, init_96 },
{ "INIT_97" , 0x97, init_97 },
{ "INIT_AUXCH" , 0x98, init_auxch },
{ "INIT_ZM_AUXCH" , 0x99, init_zm_auxch },
{ "INIT_I2C_LONG_IF" , 0x9A, init_i2c_long_if },
{ NULL , 0 , NULL }
};
#define MAX_TABLE_OPS 1000
static int
parse_init_table(struct nvbios *bios, uint16_t offset, struct init_exec *iexec)
{
/*
* Parses all commands in an init table.
*
* We start out executing all commands found in the init table. Some
* opcodes may change the status of iexec->execute to SKIP, which will
* cause the following opcodes to perform no operation until the value
* is changed back to EXECUTE.
*/
int count = 0, i, ret;
uint8_t id;
/* catch NULL script pointers */
if (offset == 0)
return 0;
/*
* Loop until INIT_DONE causes us to break out of the loop
* (or until offset > bios length just in case... )
* (and no more than MAX_TABLE_OPS iterations, just in case... )
*/
while ((offset < bios->length) && (count++ < MAX_TABLE_OPS)) {
id = bios->data[offset];
/* Find matching id in itbl_entry */
for (i = 0; itbl_entry[i].name && (itbl_entry[i].id != id); i++)
;
if (!itbl_entry[i].name) {
NV_ERROR(bios->dev,
"0x%04X: Init table command not found: "
"0x%02X\n", offset, id);
return -ENOENT;
}
BIOSLOG(bios, "0x%04X: [ (0x%02X) - %s ]\n", offset,
itbl_entry[i].id, itbl_entry[i].name);
/* execute eventual command handler */
ret = (*itbl_entry[i].handler)(bios, offset, iexec);
if (ret < 0) {
NV_ERROR(bios->dev, "0x%04X: Failed parsing init "
"table opcode: %s %d\n", offset,
itbl_entry[i].name, ret);
}
if (ret <= 0)
break;
/*
* Add the offset of the current command including all data
* of that command. The offset will then be pointing on the
* next op code.
*/
offset += ret;
}
if (offset >= bios->length)
NV_WARN(bios->dev,
"Offset 0x%04X greater than known bios image length. "
"Corrupt image?\n", offset);
if (count >= MAX_TABLE_OPS)
NV_WARN(bios->dev,
"More than %d opcodes to a table is unlikely, "
"is the bios image corrupt?\n", MAX_TABLE_OPS);
return 0;
}
static void
parse_init_tables(struct nvbios *bios)
{
/* Loops and calls parse_init_table() for each present table. */
int i = 0;
uint16_t table;
struct init_exec iexec = {true, false};
if (bios->old_style_init) {
if (bios->init_script_tbls_ptr)
parse_init_table(bios, bios->init_script_tbls_ptr, &iexec);
if (bios->extra_init_script_tbl_ptr)
parse_init_table(bios, bios->extra_init_script_tbl_ptr, &iexec);
return;
}
while ((table = ROM16(bios->data[bios->init_script_tbls_ptr + i]))) {
NV_INFO(bios->dev,
"Parsing VBIOS init table %d at offset 0x%04X\n",
i / 2, table);
BIOSLOG(bios, "0x%04X: ------ Executing following commands ------\n", table);
parse_init_table(bios, table, &iexec);
i += 2;
}
}
static uint16_t clkcmptable(struct nvbios *bios, uint16_t clktable, int pxclk)
{
int compare_record_len, i = 0;
uint16_t compareclk, scriptptr = 0;
if (bios->major_version < 5) /* pre BIT */
compare_record_len = 3;
else
compare_record_len = 4;
do {
compareclk = ROM16(bios->data[clktable + compare_record_len * i]);
if (pxclk >= compareclk * 10) {
if (bios->major_version < 5) {
uint8_t tmdssub = bios->data[clktable + 2 + compare_record_len * i];
scriptptr = ROM16(bios->data[bios->init_script_tbls_ptr + tmdssub * 2]);
} else
scriptptr = ROM16(bios->data[clktable + 2 + compare_record_len * i]);
break;
}
i++;
} while (compareclk);
return scriptptr;
}
static void
run_digital_op_script(struct drm_device *dev, uint16_t scriptptr,
struct dcb_entry *dcbent, int head, bool dl)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
struct init_exec iexec = {true, false};
NV_TRACE(dev, "0x%04X: Parsing digital output script table\n",
scriptptr);
bios_idxprt_wr(bios, NV_CIO_CRX__COLOR, NV_CIO_CRE_44,
head ? NV_CIO_CRE_44_HEADB : NV_CIO_CRE_44_HEADA);
/* note: if dcb entries have been merged, index may be misleading */
NVWriteVgaCrtc5758(dev, head, 0, dcbent->index);
parse_init_table(bios, scriptptr, &iexec);
nv04_dfp_bind_head(dev, dcbent, head, dl);
}
static int call_lvds_manufacturer_script(struct drm_device *dev, struct dcb_entry *dcbent, int head, enum LVDS_script script)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
uint8_t sub = bios->data[bios->fp.xlated_entry + script] + (bios->fp.link_c_increment && dcbent->or & OUTPUT_C ? 1 : 0);
uint16_t scriptofs = ROM16(bios->data[bios->init_script_tbls_ptr + sub * 2]);
if (!bios->fp.xlated_entry || !sub || !scriptofs)
return -EINVAL;
run_digital_op_script(dev, scriptofs, dcbent, head, bios->fp.dual_link);
if (script == LVDS_PANEL_OFF) {
/* off-on delay in ms */
mdelay(ROM16(bios->data[bios->fp.xlated_entry + 7]));
}
#ifdef __powerpc__
/* Powerbook specific quirks */
if (script == LVDS_RESET &&
(dev->pci_device == 0x0179 || dev->pci_device == 0x0189 ||
dev->pci_device == 0x0329))
nv_write_tmds(dev, dcbent->or, 0, 0x02, 0x72);
#endif
return 0;
}
static int run_lvds_table(struct drm_device *dev, struct dcb_entry *dcbent, int head, enum LVDS_script script, int pxclk)
{
/*
* The BIT LVDS table's header has the information to setup the
* necessary registers. Following the standard 4 byte header are:
* A bitmask byte and a dual-link transition pxclk value for use in
* selecting the init script when not using straps; 4 script pointers
* for panel power, selected by output and on/off; and 8 table pointers
* for panel init, the needed one determined by output, and bits in the
* conf byte. These tables are similar to the TMDS tables, consisting
* of a list of pxclks and script pointers.
*/
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
unsigned int outputset = (dcbent->or == 4) ? 1 : 0;
uint16_t scriptptr = 0, clktable;
/*
* For now we assume version 3.0 table - g80 support will need some
* changes
*/
switch (script) {
case LVDS_INIT:
return -ENOSYS;
case LVDS_BACKLIGHT_ON:
case LVDS_PANEL_ON:
scriptptr = ROM16(bios->data[bios->fp.lvdsmanufacturerpointer + 7 + outputset * 2]);
break;
case LVDS_BACKLIGHT_OFF:
case LVDS_PANEL_OFF:
scriptptr = ROM16(bios->data[bios->fp.lvdsmanufacturerpointer + 11 + outputset * 2]);
break;
case LVDS_RESET:
clktable = bios->fp.lvdsmanufacturerpointer + 15;
if (dcbent->or == 4)
clktable += 8;
if (dcbent->lvdsconf.use_straps_for_mode) {
if (bios->fp.dual_link)
clktable += 4;
if (bios->fp.if_is_24bit)
clktable += 2;
} else {
/* using EDID */
int cmpval_24bit = (dcbent->or == 4) ? 4 : 1;
if (bios->fp.dual_link) {
clktable += 4;
cmpval_24bit <<= 1;
}
if (bios->fp.strapless_is_24bit & cmpval_24bit)
clktable += 2;
}
clktable = ROM16(bios->data[clktable]);
if (!clktable) {
NV_ERROR(dev, "Pixel clock comparison table not found\n");
return -ENOENT;
}
scriptptr = clkcmptable(bios, clktable, pxclk);
}
if (!scriptptr) {
NV_ERROR(dev, "LVDS output init script not found\n");
return -ENOENT;
}
run_digital_op_script(dev, scriptptr, dcbent, head, bios->fp.dual_link);
return 0;
}
int call_lvds_script(struct drm_device *dev, struct dcb_entry *dcbent, int head, enum LVDS_script script, int pxclk)
{
/*
* LVDS operations are multiplexed in an effort to present a single API
* which works with two vastly differing underlying structures.
* This acts as the demux
*/
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
uint8_t lvds_ver = bios->data[bios->fp.lvdsmanufacturerpointer];
uint32_t sel_clk_binding, sel_clk;
int ret;
if (bios->fp.last_script_invoc == (script << 1 | head) || !lvds_ver ||
(lvds_ver >= 0x30 && script == LVDS_INIT))
return 0;
if (!bios->fp.lvds_init_run) {
bios->fp.lvds_init_run = true;
call_lvds_script(dev, dcbent, head, LVDS_INIT, pxclk);
}
if (script == LVDS_PANEL_ON && bios->fp.reset_after_pclk_change)
call_lvds_script(dev, dcbent, head, LVDS_RESET, pxclk);
if (script == LVDS_RESET && bios->fp.power_off_for_reset)
call_lvds_script(dev, dcbent, head, LVDS_PANEL_OFF, pxclk);
NV_TRACE(dev, "Calling LVDS script %d:\n", script);
/* don't let script change pll->head binding */
sel_clk_binding = bios_rd32(bios, NV_PRAMDAC_SEL_CLK) & 0x50000;
if (lvds_ver < 0x30)
ret = call_lvds_manufacturer_script(dev, dcbent, head, script);
else
ret = run_lvds_table(dev, dcbent, head, script, pxclk);
bios->fp.last_script_invoc = (script << 1 | head);
sel_clk = NVReadRAMDAC(dev, 0, NV_PRAMDAC_SEL_CLK) & ~0x50000;
NVWriteRAMDAC(dev, 0, NV_PRAMDAC_SEL_CLK, sel_clk | sel_clk_binding);
/* some scripts set a value in NV_PBUS_POWERCTRL_2 and break video overlay */
nvWriteMC(dev, NV_PBUS_POWERCTRL_2, 0);
return ret;
}
struct lvdstableheader {
uint8_t lvds_ver, headerlen, recordlen;
};
static int parse_lvds_manufacturer_table_header(struct drm_device *dev, struct nvbios *bios, struct lvdstableheader *lth)
{
/*
* BMP version (0xa) LVDS table has a simple header of version and
* record length. The BIT LVDS table has the typical BIT table header:
* version byte, header length byte, record length byte, and a byte for
* the maximum number of records that can be held in the table.
*/
uint8_t lvds_ver, headerlen, recordlen;
memset(lth, 0, sizeof(struct lvdstableheader));
if (bios->fp.lvdsmanufacturerpointer == 0x0) {
NV_ERROR(dev, "Pointer to LVDS manufacturer table invalid\n");
return -EINVAL;
}
lvds_ver = bios->data[bios->fp.lvdsmanufacturerpointer];
switch (lvds_ver) {
case 0x0a: /* pre NV40 */
headerlen = 2;
recordlen = bios->data[bios->fp.lvdsmanufacturerpointer + 1];
break;
case 0x30: /* NV4x */
headerlen = bios->data[bios->fp.lvdsmanufacturerpointer + 1];
if (headerlen < 0x1f) {
NV_ERROR(dev, "LVDS table header not understood\n");
return -EINVAL;
}
recordlen = bios->data[bios->fp.lvdsmanufacturerpointer + 2];
break;
case 0x40: /* G80/G90 */
headerlen = bios->data[bios->fp.lvdsmanufacturerpointer + 1];
if (headerlen < 0x7) {
NV_ERROR(dev, "LVDS table header not understood\n");
return -EINVAL;
}
recordlen = bios->data[bios->fp.lvdsmanufacturerpointer + 2];
break;
default:
NV_ERROR(dev,
"LVDS table revision %d.%d not currently supported\n",
lvds_ver >> 4, lvds_ver & 0xf);
return -ENOSYS;
}
lth->lvds_ver = lvds_ver;
lth->headerlen = headerlen;
lth->recordlen = recordlen;
return 0;
}
static int
get_fp_strap(struct drm_device *dev, struct nvbios *bios)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
/*
* The fp strap is normally dictated by the "User Strap" in
* PEXTDEV_BOOT_0[20:16], but on BMP cards when bit 2 of the
* Internal_Flags struct at 0x48 is set, the user strap gets overriden
* by the PCI subsystem ID during POST, but not before the previous user
* strap has been committed to CR58 for CR57=0xf on head A, which may be
* read and used instead
*/
if (bios->major_version < 5 && bios->data[0x48] & 0x4)
return NVReadVgaCrtc5758(dev, 0, 0xf) & 0xf;
if (dev_priv->card_type >= NV_50)
return (bios_rd32(bios, NV_PEXTDEV_BOOT_0) >> 24) & 0xf;
else
return (bios_rd32(bios, NV_PEXTDEV_BOOT_0) >> 16) & 0xf;
}
static int parse_fp_mode_table(struct drm_device *dev, struct nvbios *bios)
{
uint8_t *fptable;
uint8_t fptable_ver, headerlen = 0, recordlen, fpentries = 0xf, fpindex;
int ret, ofs, fpstrapping;
struct lvdstableheader lth;
if (bios->fp.fptablepointer == 0x0) {
/* Apple cards don't have the fp table; the laptops use DDC */
/* The table is also missing on some x86 IGPs */
#ifndef __powerpc__
NV_ERROR(dev, "Pointer to flat panel table invalid\n");
#endif
bios->digital_min_front_porch = 0x4b;
return 0;
}
fptable = &bios->data[bios->fp.fptablepointer];
fptable_ver = fptable[0];
switch (fptable_ver) {
/*
* BMP version 0x5.0x11 BIOSen have version 1 like tables, but no
* version field, and miss one of the spread spectrum/PWM bytes.
* This could affect early GF2Go parts (not seen any appropriate ROMs
* though). Here we assume that a version of 0x05 matches this case
* (combining with a BMP version check would be better), as the
* common case for the panel type field is 0x0005, and that is in
* fact what we are reading the first byte of.
*/
case 0x05: /* some NV10, 11, 15, 16 */
recordlen = 42;
ofs = -1;
break;
case 0x10: /* some NV15/16, and NV11+ */
recordlen = 44;
ofs = 0;
break;
case 0x20: /* NV40+ */
headerlen = fptable[1];
recordlen = fptable[2];
fpentries = fptable[3];
/*
* fptable[4] is the minimum
* RAMDAC_FP_HCRTC -> RAMDAC_FP_HSYNC_START gap
*/
bios->digital_min_front_porch = fptable[4];
ofs = -7;
break;
default:
NV_ERROR(dev,
"FP table revision %d.%d not currently supported\n",
fptable_ver >> 4, fptable_ver & 0xf);
return -ENOSYS;
}
if (!bios->is_mobile) /* !mobile only needs digital_min_front_porch */
return 0;
ret = parse_lvds_manufacturer_table_header(dev, bios, &lth);
if (ret)
return ret;
if (lth.lvds_ver == 0x30 || lth.lvds_ver == 0x40) {
bios->fp.fpxlatetableptr = bios->fp.lvdsmanufacturerpointer +
lth.headerlen + 1;
bios->fp.xlatwidth = lth.recordlen;
}
if (bios->fp.fpxlatetableptr == 0x0) {
NV_ERROR(dev, "Pointer to flat panel xlat table invalid\n");
return -EINVAL;
}
fpstrapping = get_fp_strap(dev, bios);
fpindex = bios->data[bios->fp.fpxlatetableptr +
fpstrapping * bios->fp.xlatwidth];
if (fpindex > fpentries) {
NV_ERROR(dev, "Bad flat panel table index\n");
return -ENOENT;
}
/* nv4x cards need both a strap value and fpindex of 0xf to use DDC */
if (lth.lvds_ver > 0x10)
bios->fp_no_ddc = fpstrapping != 0xf || fpindex != 0xf;
/*
* If either the strap or xlated fpindex value are 0xf there is no
* panel using a strap-derived bios mode present. this condition
* includes, but is different from, the DDC panel indicator above
*/
if (fpstrapping == 0xf || fpindex == 0xf)
return 0;
bios->fp.mode_ptr = bios->fp.fptablepointer + headerlen +
recordlen * fpindex + ofs;
NV_TRACE(dev, "BIOS FP mode: %dx%d (%dkHz pixel clock)\n",
ROM16(bios->data[bios->fp.mode_ptr + 11]) + 1,
ROM16(bios->data[bios->fp.mode_ptr + 25]) + 1,
ROM16(bios->data[bios->fp.mode_ptr + 7]) * 10);
return 0;
}
bool nouveau_bios_fp_mode(struct drm_device *dev, struct drm_display_mode *mode)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
uint8_t *mode_entry = &bios->data[bios->fp.mode_ptr];
if (!mode) /* just checking whether we can produce a mode */
return bios->fp.mode_ptr;
memset(mode, 0, sizeof(struct drm_display_mode));
/*
* For version 1.0 (version in byte 0):
* bytes 1-2 are "panel type", including bits on whether Colour/mono,
* single/dual link, and type (TFT etc.)
* bytes 3-6 are bits per colour in RGBX
*/
mode->clock = ROM16(mode_entry[7]) * 10;
/* bytes 9-10 is HActive */
mode->hdisplay = ROM16(mode_entry[11]) + 1;
/*
* bytes 13-14 is HValid Start
* bytes 15-16 is HValid End
*/
mode->hsync_start = ROM16(mode_entry[17]) + 1;
mode->hsync_end = ROM16(mode_entry[19]) + 1;
mode->htotal = ROM16(mode_entry[21]) + 1;
/* bytes 23-24, 27-30 similarly, but vertical */
mode->vdisplay = ROM16(mode_entry[25]) + 1;
mode->vsync_start = ROM16(mode_entry[31]) + 1;
mode->vsync_end = ROM16(mode_entry[33]) + 1;
mode->vtotal = ROM16(mode_entry[35]) + 1;
mode->flags |= (mode_entry[37] & 0x10) ?
DRM_MODE_FLAG_PHSYNC : DRM_MODE_FLAG_NHSYNC;
mode->flags |= (mode_entry[37] & 0x1) ?
DRM_MODE_FLAG_PVSYNC : DRM_MODE_FLAG_NVSYNC;
/*
* bytes 38-39 relate to spread spectrum settings
* bytes 40-43 are something to do with PWM
*/
mode->status = MODE_OK;
mode->type = DRM_MODE_TYPE_DRIVER | DRM_MODE_TYPE_PREFERRED;
drm_mode_set_name(mode);
return bios->fp.mode_ptr;
}
int nouveau_bios_parse_lvds_table(struct drm_device *dev, int pxclk, bool *dl, bool *if_is_24bit)
{
/*
* The LVDS table header is (mostly) described in
* parse_lvds_manufacturer_table_header(): the BIT header additionally
* contains the dual-link transition pxclk (in 10s kHz), at byte 5 - if
* straps are not being used for the panel, this specifies the frequency
* at which modes should be set up in the dual link style.
*
* Following the header, the BMP (ver 0xa) table has several records,
* indexed by a separate xlat table, indexed in turn by the fp strap in
* EXTDEV_BOOT. Each record had a config byte, followed by 6 script
* numbers for use by INIT_SUB which controlled panel init and power,
* and finally a dword of ms to sleep between power off and on
* operations.
*
* In the BIT versions, the table following the header serves as an
* integrated config and xlat table: the records in the table are
* indexed by the FP strap nibble in EXTDEV_BOOT, and each record has
* two bytes - the first as a config byte, the second for indexing the
* fp mode table pointed to by the BIT 'D' table
*
* DDC is not used until after card init, so selecting the correct table
* entry and setting the dual link flag for EDID equipped panels,
* requiring tests against the native-mode pixel clock, cannot be done
* until later, when this function should be called with non-zero pxclk
*/
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
int fpstrapping = get_fp_strap(dev, bios), lvdsmanufacturerindex = 0;
struct lvdstableheader lth;
uint16_t lvdsofs;
int ret, chip_version = bios->chip_version;
ret = parse_lvds_manufacturer_table_header(dev, bios, &lth);
if (ret)
return ret;
switch (lth.lvds_ver) {
case 0x0a: /* pre NV40 */
lvdsmanufacturerindex = bios->data[
bios->fp.fpxlatemanufacturertableptr +
fpstrapping];
/* we're done if this isn't the EDID panel case */
if (!pxclk)
break;
if (chip_version < 0x25) {
/* nv17 behaviour
*
* It seems the old style lvds script pointer is reused
* to select 18/24 bit colour depth for EDID panels.
*/
lvdsmanufacturerindex =
(bios->legacy.lvds_single_a_script_ptr & 1) ?
2 : 0;
if (pxclk >= bios->fp.duallink_transition_clk)
lvdsmanufacturerindex++;
} else if (chip_version < 0x30) {
/* nv28 behaviour (off-chip encoder)
*
* nv28 does a complex dance of first using byte 121 of
* the EDID to choose the lvdsmanufacturerindex, then
* later attempting to match the EDID manufacturer and
* product IDs in a table (signature 'pidt' (panel id
* table?)), setting an lvdsmanufacturerindex of 0 and
* an fp strap of the match index (or 0xf if none)
*/
lvdsmanufacturerindex = 0;
} else {
/* nv31, nv34 behaviour */
lvdsmanufacturerindex = 0;
if (pxclk >= bios->fp.duallink_transition_clk)
lvdsmanufacturerindex = 2;
if (pxclk >= 140000)
lvdsmanufacturerindex = 3;
}
/*
* nvidia set the high nibble of (cr57=f, cr58) to
* lvdsmanufacturerindex in this case; we don't
*/
break;
case 0x30: /* NV4x */
case 0x40: /* G80/G90 */
lvdsmanufacturerindex = fpstrapping;
break;
default:
NV_ERROR(dev, "LVDS table revision not currently supported\n");
return -ENOSYS;
}
lvdsofs = bios->fp.xlated_entry = bios->fp.lvdsmanufacturerpointer + lth.headerlen + lth.recordlen * lvdsmanufacturerindex;
switch (lth.lvds_ver) {
case 0x0a:
bios->fp.power_off_for_reset = bios->data[lvdsofs] & 1;
bios->fp.reset_after_pclk_change = bios->data[lvdsofs] & 2;
bios->fp.dual_link = bios->data[lvdsofs] & 4;
bios->fp.link_c_increment = bios->data[lvdsofs] & 8;
*if_is_24bit = bios->data[lvdsofs] & 16;
break;
case 0x30:
case 0x40:
/*
* No sign of the "power off for reset" or "reset for panel
* on" bits, but it's safer to assume we should
*/
bios->fp.power_off_for_reset = true;
bios->fp.reset_after_pclk_change = true;
/*
* It's ok lvdsofs is wrong for nv4x edid case; dual_link is
* over-written, and if_is_24bit isn't used
*/
bios->fp.dual_link = bios->data[lvdsofs] & 1;
bios->fp.if_is_24bit = bios->data[lvdsofs] & 2;
bios->fp.strapless_is_24bit = bios->data[bios->fp.lvdsmanufacturerpointer + 4];
bios->fp.duallink_transition_clk = ROM16(bios->data[bios->fp.lvdsmanufacturerpointer + 5]) * 10;
break;
}
/* set dual_link flag for EDID case */
if (pxclk && (chip_version < 0x25 || chip_version > 0x28))
bios->fp.dual_link = (pxclk >= bios->fp.duallink_transition_clk);
*dl = bios->fp.dual_link;
return 0;
}
/* BIT 'U'/'d' table encoder subtables have hashes matching them to
* a particular set of encoders.
*
* This function returns true if a particular DCB entry matches.
*/
bool
bios_encoder_match(struct dcb_entry *dcb, u32 hash)
{
if ((hash & 0x000000f0) != (dcb->location << 4))
return false;
if ((hash & 0x0000000f) != dcb->type)
return false;
if (!(hash & (dcb->or << 16)))
return false;
switch (dcb->type) {
case OUTPUT_TMDS:
case OUTPUT_LVDS:
case OUTPUT_DP:
if (hash & 0x00c00000) {
if (!(hash & (dcb->sorconf.link << 22)))
return false;
}
default:
return true;
}
}
int
nouveau_bios_run_display_table(struct drm_device *dev, u16 type, int pclk,
struct dcb_entry *dcbent, int crtc)
{
/*
* The display script table is located by the BIT 'U' table.
*
* It contains an array of pointers to various tables describing
* a particular output type. The first 32-bits of the output
* tables contains similar information to a DCB entry, and is
* used to decide whether that particular table is suitable for
* the output you want to access.
*
* The "record header length" field here seems to indicate the
* offset of the first configuration entry in the output tables.
* This is 10 on most cards I've seen, but 12 has been witnessed
* on DP cards, and there's another script pointer within the
* header.
*
* offset + 0 ( 8 bits): version
* offset + 1 ( 8 bits): header length
* offset + 2 ( 8 bits): record length
* offset + 3 ( 8 bits): number of records
* offset + 4 ( 8 bits): record header length
* offset + 5 (16 bits): pointer to first output script table
*/
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
uint8_t *table = &bios->data[bios->display.script_table_ptr];
uint8_t *otable = NULL;
uint16_t script;
int i;
if (!bios->display.script_table_ptr) {
NV_ERROR(dev, "No pointer to output script table\n");
return 1;
}
/*
* Nothing useful has been in any of the pre-2.0 tables I've seen,
* so until they are, we really don't need to care.
*/
if (table[0] < 0x20)
return 1;
if (table[0] != 0x20 && table[0] != 0x21) {
NV_ERROR(dev, "Output script table version 0x%02x unknown\n",
table[0]);
return 1;
}
/*
* The output script tables describing a particular output type
* look as follows:
*
* offset + 0 (32 bits): output this table matches (hash of DCB)
* offset + 4 ( 8 bits): unknown
* offset + 5 ( 8 bits): number of configurations
* offset + 6 (16 bits): pointer to some script
* offset + 8 (16 bits): pointer to some script
*
* headerlen == 10
* offset + 10 : configuration 0
*
* headerlen == 12
* offset + 10 : pointer to some script
* offset + 12 : configuration 0
*
* Each config entry is as follows:
*
* offset + 0 (16 bits): unknown, assumed to be a match value
* offset + 2 (16 bits): pointer to script table (clock set?)
* offset + 4 (16 bits): pointer to script table (reset?)
*
* There doesn't appear to be a count value to say how many
* entries exist in each script table, instead, a 0 value in
* the first 16-bit word seems to indicate both the end of the
* list and the default entry. The second 16-bit word in the
* script tables is a pointer to the script to execute.
*/
NV_DEBUG_KMS(dev, "Searching for output entry for %d %d %d\n",
dcbent->type, dcbent->location, dcbent->or);
for (i = 0; i < table[3]; i++) {
otable = ROMPTR(dev, table[table[1] + (i * table[2])]);
if (otable && bios_encoder_match(dcbent, ROM32(otable[0])))
break;
}
if (!otable) {
NV_DEBUG_KMS(dev, "failed to match any output table\n");
return 1;
}
if (pclk < -2 || pclk > 0) {
/* Try to find matching script table entry */
for (i = 0; i < otable[5]; i++) {
if (ROM16(otable[table[4] + i*6]) == type)
break;
}
if (i == otable[5]) {
NV_ERROR(dev, "Table 0x%04x not found for %d/%d, "
"using first\n",
type, dcbent->type, dcbent->or);
i = 0;
}
}
if (pclk == 0) {
script = ROM16(otable[6]);
if (!script) {
NV_DEBUG_KMS(dev, "output script 0 not found\n");
return 1;
}
NV_DEBUG_KMS(dev, "0x%04X: parsing output script 0\n", script);
nouveau_bios_run_init_table(dev, script, dcbent, crtc);
} else
if (pclk == -1) {
script = ROM16(otable[8]);
if (!script) {
NV_DEBUG_KMS(dev, "output script 1 not found\n");
return 1;
}
NV_DEBUG_KMS(dev, "0x%04X: parsing output script 1\n", script);
nouveau_bios_run_init_table(dev, script, dcbent, crtc);
} else
if (pclk == -2) {
if (table[4] >= 12)
script = ROM16(otable[10]);
else
script = 0;
if (!script) {
NV_DEBUG_KMS(dev, "output script 2 not found\n");
return 1;
}
NV_DEBUG_KMS(dev, "0x%04X: parsing output script 2\n", script);
nouveau_bios_run_init_table(dev, script, dcbent, crtc);
} else
if (pclk > 0) {
script = ROM16(otable[table[4] + i*6 + 2]);
if (script)
script = clkcmptable(bios, script, pclk);
if (!script) {
NV_DEBUG_KMS(dev, "clock script 0 not found\n");
return 1;
}
NV_DEBUG_KMS(dev, "0x%04X: parsing clock script 0\n", script);
nouveau_bios_run_init_table(dev, script, dcbent, crtc);
} else
if (pclk < 0) {
script = ROM16(otable[table[4] + i*6 + 4]);
if (script)
script = clkcmptable(bios, script, -pclk);
if (!script) {
NV_DEBUG_KMS(dev, "clock script 1 not found\n");
return 1;
}
NV_DEBUG_KMS(dev, "0x%04X: parsing clock script 1\n", script);
nouveau_bios_run_init_table(dev, script, dcbent, crtc);
}
return 0;
}
int run_tmds_table(struct drm_device *dev, struct dcb_entry *dcbent, int head, int pxclk)
{
/*
* the pxclk parameter is in kHz
*
* This runs the TMDS regs setting code found on BIT bios cards
*
* For ffs(or) == 1 use the first table, for ffs(or) == 2 and
* ffs(or) == 3, use the second.
*/
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
int cv = bios->chip_version;
uint16_t clktable = 0, scriptptr;
uint32_t sel_clk_binding, sel_clk;
/* pre-nv17 off-chip tmds uses scripts, post nv17 doesn't */
if (cv >= 0x17 && cv != 0x1a && cv != 0x20 &&
dcbent->location != DCB_LOC_ON_CHIP)
return 0;
switch (ffs(dcbent->or)) {
case 1:
clktable = bios->tmds.output0_script_ptr;
break;
case 2:
case 3:
clktable = bios->tmds.output1_script_ptr;
break;
}
if (!clktable) {
NV_ERROR(dev, "Pixel clock comparison table not found\n");
return -EINVAL;
}
scriptptr = clkcmptable(bios, clktable, pxclk);
if (!scriptptr) {
NV_ERROR(dev, "TMDS output init script not found\n");
return -ENOENT;
}
/* don't let script change pll->head binding */
sel_clk_binding = bios_rd32(bios, NV_PRAMDAC_SEL_CLK) & 0x50000;
run_digital_op_script(dev, scriptptr, dcbent, head, pxclk >= 165000);
sel_clk = NVReadRAMDAC(dev, 0, NV_PRAMDAC_SEL_CLK) & ~0x50000;
NVWriteRAMDAC(dev, 0, NV_PRAMDAC_SEL_CLK, sel_clk | sel_clk_binding);
return 0;
}
struct pll_mapping {
u8 type;
u32 reg;
};
static struct pll_mapping nv04_pll_mapping[] = {
{ PLL_CORE , NV_PRAMDAC_NVPLL_COEFF },
{ PLL_MEMORY, NV_PRAMDAC_MPLL_COEFF },
{ PLL_VPLL0 , NV_PRAMDAC_VPLL_COEFF },
{ PLL_VPLL1 , NV_RAMDAC_VPLL2 },
{}
};
static struct pll_mapping nv40_pll_mapping[] = {
{ PLL_CORE , 0x004000 },
{ PLL_MEMORY, 0x004020 },
{ PLL_VPLL0 , NV_PRAMDAC_VPLL_COEFF },
{ PLL_VPLL1 , NV_RAMDAC_VPLL2 },
{}
};
static struct pll_mapping nv50_pll_mapping[] = {
{ PLL_CORE , 0x004028 },
{ PLL_SHADER, 0x004020 },
{ PLL_UNK03 , 0x004000 },
{ PLL_MEMORY, 0x004008 },
{ PLL_UNK40 , 0x00e810 },
{ PLL_UNK41 , 0x00e818 },
{ PLL_UNK42 , 0x00e824 },
{ PLL_VPLL0 , 0x614100 },
{ PLL_VPLL1 , 0x614900 },
{}
};
static struct pll_mapping nv84_pll_mapping[] = {
{ PLL_CORE , 0x004028 },
{ PLL_SHADER, 0x004020 },
{ PLL_MEMORY, 0x004008 },
{ PLL_VDEC , 0x004030 },
{ PLL_UNK41 , 0x00e818 },
{ PLL_VPLL0 , 0x614100 },
{ PLL_VPLL1 , 0x614900 },
{}
};
u32
get_pll_register(struct drm_device *dev, enum pll_types type)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
struct pll_mapping *map;
int i;
if (dev_priv->card_type < NV_40)
map = nv04_pll_mapping;
else
if (dev_priv->card_type < NV_50)
map = nv40_pll_mapping;
else {
u8 *plim = &bios->data[bios->pll_limit_tbl_ptr];
if (plim[0] >= 0x30) {
u8 *entry = plim + plim[1];
for (i = 0; i < plim[3]; i++, entry += plim[2]) {
if (entry[0] == type)
return ROM32(entry[3]);
}
return 0;
}
if (dev_priv->chipset == 0x50)
map = nv50_pll_mapping;
else
map = nv84_pll_mapping;
}
while (map->reg) {
if (map->type == type)
return map->reg;
map++;
}
return 0;
}
int get_pll_limits(struct drm_device *dev, uint32_t limit_match, struct pll_lims *pll_lim)
{
/*
* PLL limits table
*
* Version 0x10: NV30, NV31
* One byte header (version), one record of 24 bytes
* Version 0x11: NV36 - Not implemented
* Seems to have same record style as 0x10, but 3 records rather than 1
* Version 0x20: Found on Geforce 6 cards
* Trivial 4 byte BIT header. 31 (0x1f) byte record length
* Version 0x21: Found on Geforce 7, 8 and some Geforce 6 cards
* 5 byte header, fifth byte of unknown purpose. 35 (0x23) byte record
* length in general, some (integrated) have an extra configuration byte
* Version 0x30: Found on Geforce 8, separates the register mapping
* from the limits tables.
*/
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
int cv = bios->chip_version, pllindex = 0;
uint8_t pll_lim_ver = 0, headerlen = 0, recordlen = 0, entries = 0;
uint32_t crystal_strap_mask, crystal_straps;
if (!bios->pll_limit_tbl_ptr) {
if (cv == 0x30 || cv == 0x31 || cv == 0x35 || cv == 0x36 ||
cv >= 0x40) {
NV_ERROR(dev, "Pointer to PLL limits table invalid\n");
return -EINVAL;
}
} else
pll_lim_ver = bios->data[bios->pll_limit_tbl_ptr];
crystal_strap_mask = 1 << 6;
/* open coded dev->twoHeads test */
if (cv > 0x10 && cv != 0x15 && cv != 0x1a && cv != 0x20)
crystal_strap_mask |= 1 << 22;
crystal_straps = nvReadEXTDEV(dev, NV_PEXTDEV_BOOT_0) &
crystal_strap_mask;
switch (pll_lim_ver) {
/*
* We use version 0 to indicate a pre limit table bios (single stage
* pll) and load the hard coded limits instead.
*/
case 0:
break;
case 0x10:
case 0x11:
/*
* Strictly v0x11 has 3 entries, but the last two don't seem
* to get used.
*/
headerlen = 1;
recordlen = 0x18;
entries = 1;
pllindex = 0;
break;
case 0x20:
case 0x21:
case 0x30:
case 0x40:
headerlen = bios->data[bios->pll_limit_tbl_ptr + 1];
recordlen = bios->data[bios->pll_limit_tbl_ptr + 2];
entries = bios->data[bios->pll_limit_tbl_ptr + 3];
break;
default:
NV_ERROR(dev, "PLL limits table revision 0x%X not currently "
"supported\n", pll_lim_ver);
return -ENOSYS;
}
/* initialize all members to zero */
memset(pll_lim, 0, sizeof(struct pll_lims));
/* if we were passed a type rather than a register, figure
* out the register and store it
*/
if (limit_match > PLL_MAX)
pll_lim->reg = limit_match;
else {
pll_lim->reg = get_pll_register(dev, limit_match);
if (!pll_lim->reg)
return -ENOENT;
}
if (pll_lim_ver == 0x10 || pll_lim_ver == 0x11) {
uint8_t *pll_rec = &bios->data[bios->pll_limit_tbl_ptr + headerlen + recordlen * pllindex];
pll_lim->vco1.minfreq = ROM32(pll_rec[0]);
pll_lim->vco1.maxfreq = ROM32(pll_rec[4]);
pll_lim->vco2.minfreq = ROM32(pll_rec[8]);
pll_lim->vco2.maxfreq = ROM32(pll_rec[12]);
pll_lim->vco1.min_inputfreq = ROM32(pll_rec[16]);
pll_lim->vco2.min_inputfreq = ROM32(pll_rec[20]);
pll_lim->vco1.max_inputfreq = pll_lim->vco2.max_inputfreq = INT_MAX;
/* these values taken from nv30/31/36 */
pll_lim->vco1.min_n = 0x1;
if (cv == 0x36)
pll_lim->vco1.min_n = 0x5;
pll_lim->vco1.max_n = 0xff;
pll_lim->vco1.min_m = 0x1;
pll_lim->vco1.max_m = 0xd;
pll_lim->vco2.min_n = 0x4;
/*
* On nv30, 31, 36 (i.e. all cards with two stage PLLs with this
* table version (apart from nv35)), N2 is compared to
* maxN2 (0x46) and 10 * maxM2 (0x4), so set maxN2 to 0x28 and
* save a comparison
*/
pll_lim->vco2.max_n = 0x28;
if (cv == 0x30 || cv == 0x35)
/* only 5 bits available for N2 on nv30/35 */
pll_lim->vco2.max_n = 0x1f;
pll_lim->vco2.min_m = 0x1;
pll_lim->vco2.max_m = 0x4;
pll_lim->max_log2p = 0x7;
pll_lim->max_usable_log2p = 0x6;
} else if (pll_lim_ver == 0x20 || pll_lim_ver == 0x21) {
uint16_t plloffs = bios->pll_limit_tbl_ptr + headerlen;
uint8_t *pll_rec;
int i;
/*
* First entry is default match, if nothing better. warn if
* reg field nonzero
*/
if (ROM32(bios->data[plloffs]))
NV_WARN(dev, "Default PLL limit entry has non-zero "
"register field\n");
for (i = 1; i < entries; i++)
if (ROM32(bios->data[plloffs + recordlen * i]) == pll_lim->reg) {
pllindex = i;
break;
}
if ((dev_priv->card_type >= NV_50) && (pllindex == 0)) {
NV_ERROR(dev, "Register 0x%08x not found in PLL "
"limits table", pll_lim->reg);
return -ENOENT;
}
pll_rec = &bios->data[plloffs + recordlen * pllindex];
BIOSLOG(bios, "Loading PLL limits for reg 0x%08x\n",
pllindex ? pll_lim->reg : 0);
/*
* Frequencies are stored in tables in MHz, kHz are more
* useful, so we convert.
*/
/* What output frequencies can each VCO generate? */
pll_lim->vco1.minfreq = ROM16(pll_rec[4]) * 1000;
pll_lim->vco1.maxfreq = ROM16(pll_rec[6]) * 1000;
pll_lim->vco2.minfreq = ROM16(pll_rec[8]) * 1000;
pll_lim->vco2.maxfreq = ROM16(pll_rec[10]) * 1000;
/* What input frequencies they accept (past the m-divider)? */
pll_lim->vco1.min_inputfreq = ROM16(pll_rec[12]) * 1000;
pll_lim->vco2.min_inputfreq = ROM16(pll_rec[14]) * 1000;
pll_lim->vco1.max_inputfreq = ROM16(pll_rec[16]) * 1000;
pll_lim->vco2.max_inputfreq = ROM16(pll_rec[18]) * 1000;
/* What values are accepted as multiplier and divider? */
pll_lim->vco1.min_n = pll_rec[20];
pll_lim->vco1.max_n = pll_rec[21];
pll_lim->vco1.min_m = pll_rec[22];
pll_lim->vco1.max_m = pll_rec[23];
pll_lim->vco2.min_n = pll_rec[24];
pll_lim->vco2.max_n = pll_rec[25];
pll_lim->vco2.min_m = pll_rec[26];
pll_lim->vco2.max_m = pll_rec[27];
pll_lim->max_usable_log2p = pll_lim->max_log2p = pll_rec[29];
if (pll_lim->max_log2p > 0x7)
/* pll decoding in nv_hw.c assumes never > 7 */
NV_WARN(dev, "Max log2 P value greater than 7 (%d)\n",
pll_lim->max_log2p);
if (cv < 0x60)
pll_lim->max_usable_log2p = 0x6;
pll_lim->log2p_bias = pll_rec[30];
if (recordlen > 0x22)
pll_lim->refclk = ROM32(pll_rec[31]);
if (recordlen > 0x23 && pll_rec[35])
NV_WARN(dev,
"Bits set in PLL configuration byte (%x)\n",
pll_rec[35]);
/* C51 special not seen elsewhere */
if (cv == 0x51 && !pll_lim->refclk) {
uint32_t sel_clk = bios_rd32(bios, NV_PRAMDAC_SEL_CLK);
if ((pll_lim->reg == NV_PRAMDAC_VPLL_COEFF && sel_clk & 0x20) ||
(pll_lim->reg == NV_RAMDAC_VPLL2 && sel_clk & 0x80)) {
if (bios_idxprt_rd(bios, NV_CIO_CRX__COLOR, NV_CIO_CRE_CHIP_ID_INDEX) < 0xa3)
pll_lim->refclk = 200000;
else
pll_lim->refclk = 25000;
}
}
} else if (pll_lim_ver == 0x30) { /* ver 0x30 */
uint8_t *entry = &bios->data[bios->pll_limit_tbl_ptr + headerlen];
uint8_t *record = NULL;
int i;
BIOSLOG(bios, "Loading PLL limits for register 0x%08x\n",
pll_lim->reg);
for (i = 0; i < entries; i++, entry += recordlen) {
if (ROM32(entry[3]) == pll_lim->reg) {
record = &bios->data[ROM16(entry[1])];
break;
}
}
if (!record) {
NV_ERROR(dev, "Register 0x%08x not found in PLL "
"limits table", pll_lim->reg);
return -ENOENT;
}
pll_lim->vco1.minfreq = ROM16(record[0]) * 1000;
pll_lim->vco1.maxfreq = ROM16(record[2]) * 1000;
pll_lim->vco2.minfreq = ROM16(record[4]) * 1000;
pll_lim->vco2.maxfreq = ROM16(record[6]) * 1000;
pll_lim->vco1.min_inputfreq = ROM16(record[8]) * 1000;
pll_lim->vco2.min_inputfreq = ROM16(record[10]) * 1000;
pll_lim->vco1.max_inputfreq = ROM16(record[12]) * 1000;
pll_lim->vco2.max_inputfreq = ROM16(record[14]) * 1000;
pll_lim->vco1.min_n = record[16];
pll_lim->vco1.max_n = record[17];
pll_lim->vco1.min_m = record[18];
pll_lim->vco1.max_m = record[19];
pll_lim->vco2.min_n = record[20];
pll_lim->vco2.max_n = record[21];
pll_lim->vco2.min_m = record[22];
pll_lim->vco2.max_m = record[23];
pll_lim->max_usable_log2p = pll_lim->max_log2p = record[25];
pll_lim->log2p_bias = record[27];
pll_lim->refclk = ROM32(record[28]);
} else if (pll_lim_ver) { /* ver 0x40 */
uint8_t *entry = &bios->data[bios->pll_limit_tbl_ptr + headerlen];
uint8_t *record = NULL;
int i;
BIOSLOG(bios, "Loading PLL limits for register 0x%08x\n",
pll_lim->reg);
for (i = 0; i < entries; i++, entry += recordlen) {
if (ROM32(entry[3]) == pll_lim->reg) {
record = &bios->data[ROM16(entry[1])];
break;
}
}
if (!record) {
NV_ERROR(dev, "Register 0x%08x not found in PLL "
"limits table", pll_lim->reg);
return -ENOENT;
}
pll_lim->vco1.minfreq = ROM16(record[0]) * 1000;
pll_lim->vco1.maxfreq = ROM16(record[2]) * 1000;
pll_lim->vco1.min_inputfreq = ROM16(record[4]) * 1000;
pll_lim->vco1.max_inputfreq = ROM16(record[6]) * 1000;
pll_lim->vco1.min_m = record[8];
pll_lim->vco1.max_m = record[9];
pll_lim->vco1.min_n = record[10];
pll_lim->vco1.max_n = record[11];
pll_lim->min_p = record[12];
pll_lim->max_p = record[13];
pll_lim->refclk = ROM16(entry[9]) * 1000;
}
/*
* By now any valid limit table ought to have set a max frequency for
* vco1, so if it's zero it's either a pre limit table bios, or one
* with an empty limit table (seen on nv18)
*/
if (!pll_lim->vco1.maxfreq) {
pll_lim->vco1.minfreq = bios->fminvco;
pll_lim->vco1.maxfreq = bios->fmaxvco;
pll_lim->vco1.min_inputfreq = 0;
pll_lim->vco1.max_inputfreq = INT_MAX;
pll_lim->vco1.min_n = 0x1;
pll_lim->vco1.max_n = 0xff;
pll_lim->vco1.min_m = 0x1;
if (crystal_straps == 0) {
/* nv05 does this, nv11 doesn't, nv10 unknown */
if (cv < 0x11)
pll_lim->vco1.min_m = 0x7;
pll_lim->vco1.max_m = 0xd;
} else {
if (cv < 0x11)
pll_lim->vco1.min_m = 0x8;
pll_lim->vco1.max_m = 0xe;
}
if (cv < 0x17 || cv == 0x1a || cv == 0x20)
pll_lim->max_log2p = 4;
else
pll_lim->max_log2p = 5;
pll_lim->max_usable_log2p = pll_lim->max_log2p;
}
if (!pll_lim->refclk)
switch (crystal_straps) {
case 0:
pll_lim->refclk = 13500;
break;
case (1 << 6):
pll_lim->refclk = 14318;
break;
case (1 << 22):
pll_lim->refclk = 27000;
break;
case (1 << 22 | 1 << 6):
pll_lim->refclk = 25000;
break;
}
NV_DEBUG(dev, "pll.vco1.minfreq: %d\n", pll_lim->vco1.minfreq);
NV_DEBUG(dev, "pll.vco1.maxfreq: %d\n", pll_lim->vco1.maxfreq);
NV_DEBUG(dev, "pll.vco1.min_inputfreq: %d\n", pll_lim->vco1.min_inputfreq);
NV_DEBUG(dev, "pll.vco1.max_inputfreq: %d\n", pll_lim->vco1.max_inputfreq);
NV_DEBUG(dev, "pll.vco1.min_n: %d\n", pll_lim->vco1.min_n);
NV_DEBUG(dev, "pll.vco1.max_n: %d\n", pll_lim->vco1.max_n);
NV_DEBUG(dev, "pll.vco1.min_m: %d\n", pll_lim->vco1.min_m);
NV_DEBUG(dev, "pll.vco1.max_m: %d\n", pll_lim->vco1.max_m);
if (pll_lim->vco2.maxfreq) {
NV_DEBUG(dev, "pll.vco2.minfreq: %d\n", pll_lim->vco2.minfreq);
NV_DEBUG(dev, "pll.vco2.maxfreq: %d\n", pll_lim->vco2.maxfreq);
NV_DEBUG(dev, "pll.vco2.min_inputfreq: %d\n", pll_lim->vco2.min_inputfreq);
NV_DEBUG(dev, "pll.vco2.max_inputfreq: %d\n", pll_lim->vco2.max_inputfreq);
NV_DEBUG(dev, "pll.vco2.min_n: %d\n", pll_lim->vco2.min_n);
NV_DEBUG(dev, "pll.vco2.max_n: %d\n", pll_lim->vco2.max_n);
NV_DEBUG(dev, "pll.vco2.min_m: %d\n", pll_lim->vco2.min_m);
NV_DEBUG(dev, "pll.vco2.max_m: %d\n", pll_lim->vco2.max_m);
}
if (!pll_lim->max_p) {
NV_DEBUG(dev, "pll.max_log2p: %d\n", pll_lim->max_log2p);
NV_DEBUG(dev, "pll.log2p_bias: %d\n", pll_lim->log2p_bias);
} else {
NV_DEBUG(dev, "pll.min_p: %d\n", pll_lim->min_p);
NV_DEBUG(dev, "pll.max_p: %d\n", pll_lim->max_p);
}
NV_DEBUG(dev, "pll.refclk: %d\n", pll_lim->refclk);
return 0;
}
static void parse_bios_version(struct drm_device *dev, struct nvbios *bios, uint16_t offset)
{
/*
* offset + 0 (8 bits): Micro version
* offset + 1 (8 bits): Minor version
* offset + 2 (8 bits): Chip version
* offset + 3 (8 bits): Major version
*/
bios->major_version = bios->data[offset + 3];
bios->chip_version = bios->data[offset + 2];
NV_TRACE(dev, "Bios version %02x.%02x.%02x.%02x\n",
bios->data[offset + 3], bios->data[offset + 2],
bios->data[offset + 1], bios->data[offset]);
}
static void parse_script_table_pointers(struct nvbios *bios, uint16_t offset)
{
/*
* Parses the init table segment for pointers used in script execution.
*
* offset + 0 (16 bits): init script tables pointer
* offset + 2 (16 bits): macro index table pointer
* offset + 4 (16 bits): macro table pointer
* offset + 6 (16 bits): condition table pointer
* offset + 8 (16 bits): io condition table pointer
* offset + 10 (16 bits): io flag condition table pointer
* offset + 12 (16 bits): init function table pointer
*/
bios->init_script_tbls_ptr = ROM16(bios->data[offset]);
bios->macro_index_tbl_ptr = ROM16(bios->data[offset + 2]);
bios->macro_tbl_ptr = ROM16(bios->data[offset + 4]);
bios->condition_tbl_ptr = ROM16(bios->data[offset + 6]);
bios->io_condition_tbl_ptr = ROM16(bios->data[offset + 8]);
bios->io_flag_condition_tbl_ptr = ROM16(bios->data[offset + 10]);
bios->init_function_tbl_ptr = ROM16(bios->data[offset + 12]);
}
static int parse_bit_A_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
{
/*
* Parses the load detect values for g80 cards.
*
* offset + 0 (16 bits): loadval table pointer
*/
uint16_t load_table_ptr;
uint8_t version, headerlen, entrylen, num_entries;
if (bitentry->length != 3) {
NV_ERROR(dev, "Do not understand BIT A table\n");
return -EINVAL;
}
load_table_ptr = ROM16(bios->data[bitentry->offset]);
if (load_table_ptr == 0x0) {
NV_DEBUG(dev, "Pointer to BIT loadval table invalid\n");
return -EINVAL;
}
version = bios->data[load_table_ptr];
if (version != 0x10) {
NV_ERROR(dev, "BIT loadval table version %d.%d not supported\n",
version >> 4, version & 0xF);
return -ENOSYS;
}
headerlen = bios->data[load_table_ptr + 1];
entrylen = bios->data[load_table_ptr + 2];
num_entries = bios->data[load_table_ptr + 3];
if (headerlen != 4 || entrylen != 4 || num_entries != 2) {
NV_ERROR(dev, "Do not understand BIT loadval table\n");
return -EINVAL;
}
/* First entry is normal dac, 2nd tv-out perhaps? */
bios->dactestval = ROM32(bios->data[load_table_ptr + headerlen]) & 0x3ff;
return 0;
}
static int parse_bit_C_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
{
/*
* offset + 8 (16 bits): PLL limits table pointer
*
* There's more in here, but that's unknown.
*/
if (bitentry->length < 10) {
NV_ERROR(dev, "Do not understand BIT C table\n");
return -EINVAL;
}
bios->pll_limit_tbl_ptr = ROM16(bios->data[bitentry->offset + 8]);
return 0;
}
static int parse_bit_display_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
{
/*
* Parses the flat panel table segment that the bit entry points to.
* Starting at bitentry->offset:
*
* offset + 0 (16 bits): ??? table pointer - seems to have 18 byte
* records beginning with a freq.
* offset + 2 (16 bits): mode table pointer
*/
if (bitentry->length != 4) {
NV_ERROR(dev, "Do not understand BIT display table\n");
return -EINVAL;
}
bios->fp.fptablepointer = ROM16(bios->data[bitentry->offset + 2]);
return 0;
}
static int parse_bit_init_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
{
/*
* Parses the init table segment that the bit entry points to.
*
* See parse_script_table_pointers for layout
*/
if (bitentry->length < 14) {
NV_ERROR(dev, "Do not understand init table\n");
return -EINVAL;
}
parse_script_table_pointers(bios, bitentry->offset);
if (bitentry->length >= 16)
bios->some_script_ptr = ROM16(bios->data[bitentry->offset + 14]);
if (bitentry->length >= 18)
bios->init96_tbl_ptr = ROM16(bios->data[bitentry->offset + 16]);
return 0;
}
static int parse_bit_i_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
{
/*
* BIT 'i' (info?) table
*
* offset + 0 (32 bits): BIOS version dword (as in B table)
* offset + 5 (8 bits): BIOS feature byte (same as for BMP?)
* offset + 13 (16 bits): pointer to table containing DAC load
* detection comparison values
*
* There's other things in the table, purpose unknown
*/
uint16_t daccmpoffset;
uint8_t dacver, dacheaderlen;
if (bitentry->length < 6) {
NV_ERROR(dev, "BIT i table too short for needed information\n");
return -EINVAL;
}
parse_bios_version(dev, bios, bitentry->offset);
/*
* bit 4 seems to indicate a mobile bios (doesn't suffer from BMP's
* Quadro identity crisis), other bits possibly as for BMP feature byte
*/
bios->feature_byte = bios->data[bitentry->offset + 5];
bios->is_mobile = bios->feature_byte & FEATURE_MOBILE;
if (bitentry->length < 15) {
NV_WARN(dev, "BIT i table not long enough for DAC load "
"detection comparison table\n");
return -EINVAL;
}
daccmpoffset = ROM16(bios->data[bitentry->offset + 13]);
/* doesn't exist on g80 */
if (!daccmpoffset)
return 0;
/*
* The first value in the table, following the header, is the
* comparison value, the second entry is a comparison value for
* TV load detection.
*/
dacver = bios->data[daccmpoffset];
dacheaderlen = bios->data[daccmpoffset + 1];
if (dacver != 0x00 && dacver != 0x10) {
NV_WARN(dev, "DAC load detection comparison table version "
"%d.%d not known\n", dacver >> 4, dacver & 0xf);
return -ENOSYS;
}
bios->dactestval = ROM32(bios->data[daccmpoffset + dacheaderlen]);
bios->tvdactestval = ROM32(bios->data[daccmpoffset + dacheaderlen + 4]);
return 0;
}
static int parse_bit_lvds_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
{
/*
* Parses the LVDS table segment that the bit entry points to.
* Starting at bitentry->offset:
*
* offset + 0 (16 bits): LVDS strap xlate table pointer
*/
if (bitentry->length != 2) {
NV_ERROR(dev, "Do not understand BIT LVDS table\n");
return -EINVAL;
}
/*
* No idea if it's still called the LVDS manufacturer table, but
* the concept's close enough.
*/
bios->fp.lvdsmanufacturerpointer = ROM16(bios->data[bitentry->offset]);
return 0;
}
static int
parse_bit_M_tbl_entry(struct drm_device *dev, struct nvbios *bios,
struct bit_entry *bitentry)
{
/*
* offset + 2 (8 bits): number of options in an
* INIT_RAM_RESTRICT_ZM_REG_GROUP opcode option set
* offset + 3 (16 bits): pointer to strap xlate table for RAM
* restrict option selection
*
* There's a bunch of bits in this table other than the RAM restrict
* stuff that we don't use - their use currently unknown
*/
/*
* Older bios versions don't have a sufficiently long table for
* what we want
*/
if (bitentry->length < 0x5)
return 0;
if (bitentry->version < 2) {
bios->ram_restrict_group_count = bios->data[bitentry->offset + 2];
bios->ram_restrict_tbl_ptr = ROM16(bios->data[bitentry->offset + 3]);
} else {
bios->ram_restrict_group_count = bios->data[bitentry->offset + 0];
bios->ram_restrict_tbl_ptr = ROM16(bios->data[bitentry->offset + 1]);
}
return 0;
}
static int parse_bit_tmds_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
{
/*
* Parses the pointer to the TMDS table
*
* Starting at bitentry->offset:
*
* offset + 0 (16 bits): TMDS table pointer
*
* The TMDS table is typically found just before the DCB table, with a
* characteristic signature of 0x11,0x13 (1.1 being version, 0x13 being
* length?)
*
* At offset +7 is a pointer to a script, which I don't know how to
* run yet.
* At offset +9 is a pointer to another script, likewise
* Offset +11 has a pointer to a table where the first word is a pxclk
* frequency and the second word a pointer to a script, which should be
* run if the comparison pxclk frequency is less than the pxclk desired.
* This repeats for decreasing comparison frequencies
* Offset +13 has a pointer to a similar table
* The selection of table (and possibly +7/+9 script) is dictated by
* "or" from the DCB.
*/
uint16_t tmdstableptr, script1, script2;
if (bitentry->length != 2) {
NV_ERROR(dev, "Do not understand BIT TMDS table\n");
return -EINVAL;
}
tmdstableptr = ROM16(bios->data[bitentry->offset]);
if (!tmdstableptr) {
NV_ERROR(dev, "Pointer to TMDS table invalid\n");
return -EINVAL;
}
NV_INFO(dev, "TMDS table version %d.%d\n",
bios->data[tmdstableptr] >> 4, bios->data[tmdstableptr] & 0xf);
/* nv50+ has v2.0, but we don't parse it atm */
if (bios->data[tmdstableptr] != 0x11)
return -ENOSYS;
/*
* These two scripts are odd: they don't seem to get run even when
* they are not stubbed.
*/
script1 = ROM16(bios->data[tmdstableptr + 7]);
script2 = ROM16(bios->data[tmdstableptr + 9]);
if (bios->data[script1] != 'q' || bios->data[script2] != 'q')
NV_WARN(dev, "TMDS table script pointers not stubbed\n");
bios->tmds.output0_script_ptr = ROM16(bios->data[tmdstableptr + 11]);
bios->tmds.output1_script_ptr = ROM16(bios->data[tmdstableptr + 13]);
return 0;
}
static int
parse_bit_U_tbl_entry(struct drm_device *dev, struct nvbios *bios,
struct bit_entry *bitentry)
{
/*
* Parses the pointer to the G80 output script tables
*
* Starting at bitentry->offset:
*
* offset + 0 (16 bits): output script table pointer
*/
uint16_t outputscripttableptr;
if (bitentry->length != 3) {
NV_ERROR(dev, "Do not understand BIT U table\n");
return -EINVAL;
}
outputscripttableptr = ROM16(bios->data[bitentry->offset]);
bios->display.script_table_ptr = outputscripttableptr;
return 0;
}
struct bit_table {
const char id;
int (* const parse_fn)(struct drm_device *, struct nvbios *, struct bit_entry *);
};
#define BIT_TABLE(id, funcid) ((struct bit_table){ id, parse_bit_##funcid##_tbl_entry })
int
bit_table(struct drm_device *dev, u8 id, struct bit_entry *bit)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
u8 entries, *entry;
if (bios->type != NVBIOS_BIT)
return -ENODEV;
entries = bios->data[bios->offset + 10];
entry = &bios->data[bios->offset + 12];
while (entries--) {
if (entry[0] == id) {
bit->id = entry[0];
bit->version = entry[1];
bit->length = ROM16(entry[2]);
bit->offset = ROM16(entry[4]);
bit->data = ROMPTR(dev, entry[4]);
return 0;
}
entry += bios->data[bios->offset + 9];
}
return -ENOENT;
}
static int
parse_bit_table(struct nvbios *bios, const uint16_t bitoffset,
struct bit_table *table)
{
struct drm_device *dev = bios->dev;
struct bit_entry bitentry;
if (bit_table(dev, table->id, &bitentry) == 0)
return table->parse_fn(dev, bios, &bitentry);
NV_INFO(dev, "BIT table '%c' not found\n", table->id);
return -ENOSYS;
}
static int
parse_bit_structure(struct nvbios *bios, const uint16_t bitoffset)
{
int ret;
/*
* The only restriction on parsing order currently is having 'i' first
* for use of bios->*_version or bios->feature_byte while parsing;
* functions shouldn't be actually *doing* anything apart from pulling
* data from the image into the bios struct, thus no interdependencies
*/
ret = parse_bit_table(bios, bitoffset, &BIT_TABLE('i', i));
if (ret) /* info? */
return ret;
if (bios->major_version >= 0x60) /* g80+ */
parse_bit_table(bios, bitoffset, &BIT_TABLE('A', A));
ret = parse_bit_table(bios, bitoffset, &BIT_TABLE('C', C));
if (ret)
return ret;
parse_bit_table(bios, bitoffset, &BIT_TABLE('D', display));
ret = parse_bit_table(bios, bitoffset, &BIT_TABLE('I', init));
if (ret)
return ret;
parse_bit_table(bios, bitoffset, &BIT_TABLE('M', M)); /* memory? */
parse_bit_table(bios, bitoffset, &BIT_TABLE('L', lvds));
parse_bit_table(bios, bitoffset, &BIT_TABLE('T', tmds));
parse_bit_table(bios, bitoffset, &BIT_TABLE('U', U));
return 0;
}
static int parse_bmp_structure(struct drm_device *dev, struct nvbios *bios, unsigned int offset)
{
/*
* Parses the BMP structure for useful things, but does not act on them
*
* offset + 5: BMP major version
* offset + 6: BMP minor version
* offset + 9: BMP feature byte
* offset + 10: BCD encoded BIOS version
*
* offset + 18: init script table pointer (for bios versions < 5.10h)
* offset + 20: extra init script table pointer (for bios
* versions < 5.10h)
*
* offset + 24: memory init table pointer (used on early bios versions)
* offset + 26: SDR memory sequencing setup data table
* offset + 28: DDR memory sequencing setup data table
*
* offset + 54: index of I2C CRTC pair to use for CRT output
* offset + 55: index of I2C CRTC pair to use for TV output
* offset + 56: index of I2C CRTC pair to use for flat panel output
* offset + 58: write CRTC index for I2C pair 0
* offset + 59: read CRTC index for I2C pair 0
* offset + 60: write CRTC index for I2C pair 1
* offset + 61: read CRTC index for I2C pair 1
*
* offset + 67: maximum internal PLL frequency (single stage PLL)
* offset + 71: minimum internal PLL frequency (single stage PLL)
*
* offset + 75: script table pointers, as described in
* parse_script_table_pointers
*
* offset + 89: TMDS single link output A table pointer
* offset + 91: TMDS single link output B table pointer
* offset + 95: LVDS single link output A table pointer
* offset + 105: flat panel timings table pointer
* offset + 107: flat panel strapping translation table pointer
* offset + 117: LVDS manufacturer panel config table pointer
* offset + 119: LVDS manufacturer strapping translation table pointer
*
* offset + 142: PLL limits table pointer
*
* offset + 156: minimum pixel clock for LVDS dual link
*/
uint8_t *bmp = &bios->data[offset], bmp_version_major, bmp_version_minor;
uint16_t bmplength;
uint16_t legacy_scripts_offset, legacy_i2c_offset;
/* load needed defaults in case we can't parse this info */
bios->digital_min_front_porch = 0x4b;
bios->fmaxvco = 256000;
bios->fminvco = 128000;
bios->fp.duallink_transition_clk = 90000;
bmp_version_major = bmp[5];
bmp_version_minor = bmp[6];
NV_TRACE(dev, "BMP version %d.%d\n",
bmp_version_major, bmp_version_minor);
/*
* Make sure that 0x36 is blank and can't be mistaken for a DCB
* pointer on early versions
*/
if (bmp_version_major < 5)
*(uint16_t *)&bios->data[0x36] = 0;
/*
* Seems that the minor version was 1 for all major versions prior
* to 5. Version 6 could theoretically exist, but I suspect BIT
* happened instead.
*/
if ((bmp_version_major < 5 && bmp_version_minor != 1) || bmp_version_major > 5) {
NV_ERROR(dev, "You have an unsupported BMP version. "
"Please send in your bios\n");
return -ENOSYS;
}
if (bmp_version_major == 0)
/* nothing that's currently useful in this version */
return 0;
else if (bmp_version_major == 1)
bmplength = 44; /* exact for 1.01 */
else if (bmp_version_major == 2)
bmplength = 48; /* exact for 2.01 */
else if (bmp_version_major == 3)
bmplength = 54;
/* guessed - mem init tables added in this version */
else if (bmp_version_major == 4 || bmp_version_minor < 0x1)
/* don't know if 5.0 exists... */
bmplength = 62;
/* guessed - BMP I2C indices added in version 4*/
else if (bmp_version_minor < 0x6)
bmplength = 67; /* exact for 5.01 */
else if (bmp_version_minor < 0x10)
bmplength = 75; /* exact for 5.06 */
else if (bmp_version_minor == 0x10)
bmplength = 89; /* exact for 5.10h */
else if (bmp_version_minor < 0x14)
bmplength = 118; /* exact for 5.11h */
else if (bmp_version_minor < 0x24)
/*
* Not sure of version where pll limits came in;
* certainly exist by 0x24 though.
*/
/* length not exact: this is long enough to get lvds members */
bmplength = 123;
else if (bmp_version_minor < 0x27)
/*
* Length not exact: this is long enough to get pll limit
* member
*/
bmplength = 144;
else
/*
* Length not exact: this is long enough to get dual link
* transition clock.
*/
bmplength = 158;
/* checksum */
if (nv_cksum(bmp, 8)) {
NV_ERROR(dev, "Bad BMP checksum\n");
return -EINVAL;
}
/*
* Bit 4 seems to indicate either a mobile bios or a quadro card --
* mobile behaviour consistent (nv11+), quadro only seen nv18gl-nv36gl
* (not nv10gl), bit 5 that the flat panel tables are present, and
* bit 6 a tv bios.
*/
bios->feature_byte = bmp[9];
parse_bios_version(dev, bios, offset + 10);
if (bmp_version_major < 5 || bmp_version_minor < 0x10)
bios->old_style_init = true;
legacy_scripts_offset = 18;
if (bmp_version_major < 2)
legacy_scripts_offset -= 4;
bios->init_script_tbls_ptr = ROM16(bmp[legacy_scripts_offset]);
bios->extra_init_script_tbl_ptr = ROM16(bmp[legacy_scripts_offset + 2]);
if (bmp_version_major > 2) { /* appears in BMP 3 */
bios->legacy.mem_init_tbl_ptr = ROM16(bmp[24]);
bios->legacy.sdr_seq_tbl_ptr = ROM16(bmp[26]);
bios->legacy.ddr_seq_tbl_ptr = ROM16(bmp[28]);
}
legacy_i2c_offset = 0x48; /* BMP version 2 & 3 */
if (bmplength > 61)
legacy_i2c_offset = offset + 54;
bios->legacy.i2c_indices.crt = bios->data[legacy_i2c_offset];
bios->legacy.i2c_indices.tv = bios->data[legacy_i2c_offset + 1];
bios->legacy.i2c_indices.panel = bios->data[legacy_i2c_offset + 2];
if (bmplength > 74) {
bios->fmaxvco = ROM32(bmp[67]);
bios->fminvco = ROM32(bmp[71]);
}
if (bmplength > 88)
parse_script_table_pointers(bios, offset + 75);
if (bmplength > 94) {
bios->tmds.output0_script_ptr = ROM16(bmp[89]);
bios->tmds.output1_script_ptr = ROM16(bmp[91]);
/*
* Never observed in use with lvds scripts, but is reused for
* 18/24 bit panel interface default for EDID equipped panels
* (if_is_24bit not set directly to avoid any oscillation).
*/
bios->legacy.lvds_single_a_script_ptr = ROM16(bmp[95]);
}
if (bmplength > 108) {
bios->fp.fptablepointer = ROM16(bmp[105]);
bios->fp.fpxlatetableptr = ROM16(bmp[107]);
bios->fp.xlatwidth = 1;
}
if (bmplength > 120) {
bios->fp.lvdsmanufacturerpointer = ROM16(bmp[117]);
bios->fp.fpxlatemanufacturertableptr = ROM16(bmp[119]);
}
if (bmplength > 143)
bios->pll_limit_tbl_ptr = ROM16(bmp[142]);
if (bmplength > 157)
bios->fp.duallink_transition_clk = ROM16(bmp[156]) * 10;
return 0;
}
static uint16_t findstr(uint8_t *data, int n, const uint8_t *str, int len)
{
int i, j;
for (i = 0; i <= (n - len); i++) {
for (j = 0; j < len; j++)
if (data[i + j] != str[j])
break;
if (j == len)
return i;
}
return 0;
}
void *
dcb_table(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
u8 *dcb = NULL;
if (dev_priv->card_type > NV_04)
dcb = ROMPTR(dev, dev_priv->vbios.data[0x36]);
if (!dcb) {
NV_WARNONCE(dev, "No DCB data found in VBIOS\n");
return NULL;
}
if (dcb[0] >= 0x41) {
NV_WARNONCE(dev, "DCB version 0x%02x unknown\n", dcb[0]);
return NULL;
} else
if (dcb[0] >= 0x30) {
if (ROM32(dcb[6]) == 0x4edcbdcb)
return dcb;
} else
if (dcb[0] >= 0x20) {
if (ROM32(dcb[4]) == 0x4edcbdcb)
return dcb;
} else
if (dcb[0] >= 0x15) {
if (!memcmp(&dcb[-7], "DEV_REC", 7))
return dcb;
} else {
/*
* v1.4 (some NV15/16, NV11+) seems the same as v1.5, but
* always has the same single (crt) entry, even when tv-out
* present, so the conclusion is this version cannot really
* be used.
*
* v1.2 tables (some NV6/10, and NV15+) normally have the
* same 5 entries, which are not specific to the card and so
* no use.
*
* v1.2 does have an I2C table that read_dcb_i2c_table can
* handle, but cards exist (nv11 in #14821) with a bad i2c
* table pointer, so use the indices parsed in
* parse_bmp_structure.
*
* v1.1 (NV5+, maybe some NV4) is entirely unhelpful
*/
NV_WARNONCE(dev, "No useful DCB data in VBIOS\n");
return NULL;
}
NV_WARNONCE(dev, "DCB header validation failed\n");
return NULL;
}
void *
dcb_outp(struct drm_device *dev, u8 idx)
{
u8 *dcb = dcb_table(dev);
if (dcb && dcb[0] >= 0x30) {
if (idx < dcb[2])
return dcb + dcb[1] + (idx * dcb[3]);
} else
if (dcb && dcb[0] >= 0x20) {
u8 *i2c = ROMPTR(dev, dcb[2]);
u8 *ent = dcb + 8 + (idx * 8);
if (i2c && ent < i2c)
return ent;
} else
if (dcb && dcb[0] >= 0x15) {
u8 *i2c = ROMPTR(dev, dcb[2]);
u8 *ent = dcb + 4 + (idx * 10);
if (i2c && ent < i2c)
return ent;
}
return NULL;
}
int
dcb_outp_foreach(struct drm_device *dev, void *data,
int (*exec)(struct drm_device *, void *, int idx, u8 *outp))
{
int ret, idx = -1;
u8 *outp = NULL;
while ((outp = dcb_outp(dev, ++idx))) {
if (ROM32(outp[0]) == 0x00000000)
break; /* seen on an NV11 with DCB v1.5 */
if (ROM32(outp[0]) == 0xffffffff)
break; /* seen on an NV17 with DCB v2.0 */
if ((outp[0] & 0x0f) == OUTPUT_UNUSED)
continue;
if ((outp[0] & 0x0f) == OUTPUT_EOL)
break;
ret = exec(dev, data, idx, outp);
if (ret)
return ret;
}
return 0;
}
u8 *
dcb_conntab(struct drm_device *dev)
{
u8 *dcb = dcb_table(dev);
if (dcb && dcb[0] >= 0x30 && dcb[1] >= 0x16) {
u8 *conntab = ROMPTR(dev, dcb[0x14]);
if (conntab && conntab[0] >= 0x30 && conntab[0] <= 0x40)
return conntab;
}
return NULL;
}
u8 *
dcb_conn(struct drm_device *dev, u8 idx)
{
u8 *conntab = dcb_conntab(dev);
if (conntab && idx < conntab[2])
return conntab + conntab[1] + (idx * conntab[3]);
return NULL;
}
static struct dcb_entry *new_dcb_entry(struct dcb_table *dcb)
{
struct dcb_entry *entry = &dcb->entry[dcb->entries];
memset(entry, 0, sizeof(struct dcb_entry));
entry->index = dcb->entries++;
return entry;
}
static void fabricate_dcb_output(struct dcb_table *dcb, int type, int i2c,
int heads, int or)
{
struct dcb_entry *entry = new_dcb_entry(dcb);
entry->type = type;
entry->i2c_index = i2c;
entry->heads = heads;
if (type != OUTPUT_ANALOG)
entry->location = !DCB_LOC_ON_CHIP; /* ie OFF CHIP */
entry->or = or;
}
static bool
parse_dcb20_entry(struct drm_device *dev, struct dcb_table *dcb,
uint32_t conn, uint32_t conf, struct dcb_entry *entry)
{
entry->type = conn & 0xf;
entry->i2c_index = (conn >> 4) & 0xf;
entry->heads = (conn >> 8) & 0xf;
entry->connector = (conn >> 12) & 0xf;
entry->bus = (conn >> 16) & 0xf;
entry->location = (conn >> 20) & 0x3;
entry->or = (conn >> 24) & 0xf;
switch (entry->type) {
case OUTPUT_ANALOG:
/*
* Although the rest of a CRT conf dword is usually
* zeros, mac biosen have stuff there so we must mask
*/
entry->crtconf.maxfreq = (dcb->version < 0x30) ?
(conf & 0xffff) * 10 :
(conf & 0xff) * 10000;
break;
case OUTPUT_LVDS:
{
uint32_t mask;
if (conf & 0x1)
entry->lvdsconf.use_straps_for_mode = true;
if (dcb->version < 0x22) {
mask = ~0xd;
/*
* The laptop in bug 14567 lies and claims to not use
* straps when it does, so assume all DCB 2.0 laptops
* use straps, until a broken EDID using one is produced
*/
entry->lvdsconf.use_straps_for_mode = true;
/*
* Both 0x4 and 0x8 show up in v2.0 tables; assume they
* mean the same thing (probably wrong, but might work)
*/
if (conf & 0x4 || conf & 0x8)
entry->lvdsconf.use_power_scripts = true;
} else {
mask = ~0x7;
if (conf & 0x2)
entry->lvdsconf.use_acpi_for_edid = true;
if (conf & 0x4)
entry->lvdsconf.use_power_scripts = true;
entry->lvdsconf.sor.link = (conf & 0x00000030) >> 4;
}
if (conf & mask) {
/*
* Until we even try to use these on G8x, it's
* useless reporting unknown bits. They all are.
*/
if (dcb->version >= 0x40)
break;
NV_ERROR(dev, "Unknown LVDS configuration bits, "
"please report\n");
}
break;
}
case OUTPUT_TV:
{
if (dcb->version >= 0x30)
entry->tvconf.has_component_output = conf & (0x8 << 4);
else
entry->tvconf.has_component_output = false;
break;
}
case OUTPUT_DP:
entry->dpconf.sor.link = (conf & 0x00000030) >> 4;
switch ((conf & 0x00e00000) >> 21) {
case 0:
entry->dpconf.link_bw = 162000;
break;
default:
entry->dpconf.link_bw = 270000;
break;
}
switch ((conf & 0x0f000000) >> 24) {
case 0xf:
entry->dpconf.link_nr = 4;
break;
case 0x3:
entry->dpconf.link_nr = 2;
break;
default:
entry->dpconf.link_nr = 1;
break;
}
break;
case OUTPUT_TMDS:
if (dcb->version >= 0x40)
entry->tmdsconf.sor.link = (conf & 0x00000030) >> 4;
else if (dcb->version >= 0x30)
entry->tmdsconf.slave_addr = (conf & 0x00000700) >> 8;
else if (dcb->version >= 0x22)
entry->tmdsconf.slave_addr = (conf & 0x00000070) >> 4;
break;
case OUTPUT_EOL:
/* weird g80 mobile type that "nv" treats as a terminator */
dcb->entries--;
return false;
default:
break;
}
if (dcb->version < 0x40) {
/* Normal entries consist of a single bit, but dual link has
* the next most significant bit set too
*/
entry->duallink_possible =
((1 << (ffs(entry->or) - 1)) * 3 == entry->or);
} else {
entry->duallink_possible = (entry->sorconf.link == 3);
}
/* unsure what DCB version introduces this, 3.0? */
if (conf & 0x100000)
entry->i2c_upper_default = true;
return true;
}
static bool
parse_dcb15_entry(struct drm_device *dev, struct dcb_table *dcb,
uint32_t conn, uint32_t conf, struct dcb_entry *entry)
{
switch (conn & 0x0000000f) {
case 0:
entry->type = OUTPUT_ANALOG;
break;
case 1:
entry->type = OUTPUT_TV;
break;
case 2:
case 4:
if (conn & 0x10)
entry->type = OUTPUT_LVDS;
else
entry->type = OUTPUT_TMDS;
break;
case 3:
entry->type = OUTPUT_LVDS;
break;
default:
NV_ERROR(dev, "Unknown DCB type %d\n", conn & 0x0000000f);
return false;
}
entry->i2c_index = (conn & 0x0003c000) >> 14;
entry->heads = ((conn & 0x001c0000) >> 18) + 1;
entry->or = entry->heads; /* same as heads, hopefully safe enough */
entry->location = (conn & 0x01e00000) >> 21;
entry->bus = (conn & 0x0e000000) >> 25;
entry->duallink_possible = false;
switch (entry->type) {
case OUTPUT_ANALOG:
entry->crtconf.maxfreq = (conf & 0xffff) * 10;
break;
case OUTPUT_TV:
entry->tvconf.has_component_output = false;
break;
case OUTPUT_LVDS:
if ((conn & 0x00003f00) >> 8 != 0x10)
entry->lvdsconf.use_straps_for_mode = true;
entry->lvdsconf.use_power_scripts = true;
break;
default:
break;
}
return true;
}
static
void merge_like_dcb_entries(struct drm_device *dev, struct dcb_table *dcb)
{
/*
* DCB v2.0 lists each output combination separately.
* Here we merge compatible entries to have fewer outputs, with
* more options
*/
int i, newentries = 0;
for (i = 0; i < dcb->entries; i++) {
struct dcb_entry *ient = &dcb->entry[i];
int j;
for (j = i + 1; j < dcb->entries; j++) {
struct dcb_entry *jent = &dcb->entry[j];
if (jent->type == 100) /* already merged entry */
continue;
/* merge heads field when all other fields the same */
if (jent->i2c_index == ient->i2c_index &&
jent->type == ient->type &&
jent->location == ient->location &&
jent->or == ient->or) {
NV_TRACE(dev, "Merging DCB entries %d and %d\n",
i, j);
ient->heads |= jent->heads;
jent->type = 100; /* dummy value */
}
}
}
/* Compact entries merged into others out of dcb */
for (i = 0; i < dcb->entries; i++) {
if (dcb->entry[i].type == 100)
continue;
if (newentries != i) {
dcb->entry[newentries] = dcb->entry[i];
dcb->entry[newentries].index = newentries;
}
newentries++;
}
dcb->entries = newentries;
}
static bool
apply_dcb_encoder_quirks(struct drm_device *dev, int idx, u32 *conn, u32 *conf)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct dcb_table *dcb = &dev_priv->vbios.dcb;
/* Dell Precision M6300
* DCB entry 2: 02025312 00000010
* DCB entry 3: 02026312 00000020
*
* Identical, except apparently a different connector on a
* different SOR link. Not a clue how we're supposed to know
* which one is in use if it even shares an i2c line...
*
* Ignore the connector on the second SOR link to prevent
* nasty problems until this is sorted (assuming it's not a
* VBIOS bug).
*/
if (nv_match_device(dev, 0x040d, 0x1028, 0x019b)) {
if (*conn == 0x02026312 && *conf == 0x00000020)
return false;
}
/* GeForce3 Ti 200
*
* DCB reports an LVDS output that should be TMDS:
* DCB entry 1: f2005014 ffffffff
*/
if (nv_match_device(dev, 0x0201, 0x1462, 0x8851)) {
if (*conn == 0xf2005014 && *conf == 0xffffffff) {
fabricate_dcb_output(dcb, OUTPUT_TMDS, 1, 1, 1);
return false;
}
}
/* XFX GT-240X-YA
*
* So many things wrong here, replace the entire encoder table..
*/
if (nv_match_device(dev, 0x0ca3, 0x1682, 0x3003)) {
if (idx == 0) {
*conn = 0x02001300; /* VGA, connector 1 */
*conf = 0x00000028;
} else
if (idx == 1) {
*conn = 0x01010312; /* DVI, connector 0 */
*conf = 0x00020030;
} else
if (idx == 2) {
*conn = 0x01010310; /* VGA, connector 0 */
*conf = 0x00000028;
} else
if (idx == 3) {
*conn = 0x02022362; /* HDMI, connector 2 */
*conf = 0x00020010;
} else {
*conn = 0x0000000e; /* EOL */
*conf = 0x00000000;
}
}
/* Some other twisted XFX board (rhbz#694914)
*
* The DVI/VGA encoder combo that's supposed to represent the
* DVI-I connector actually point at two different ones, and
* the HDMI connector ends up paired with the VGA instead.
*
* Connector table is missing anything for VGA at all, pointing it
* an invalid conntab entry 2 so we figure it out ourself.
*/
if (nv_match_device(dev, 0x0615, 0x1682, 0x2605)) {
if (idx == 0) {
*conn = 0x02002300; /* VGA, connector 2 */
*conf = 0x00000028;
} else
if (idx == 1) {
*conn = 0x01010312; /* DVI, connector 0 */
*conf = 0x00020030;
} else
if (idx == 2) {
*conn = 0x04020310; /* VGA, connector 0 */
*conf = 0x00000028;
} else
if (idx == 3) {
*conn = 0x02021322; /* HDMI, connector 1 */
*conf = 0x00020010;
} else {
*conn = 0x0000000e; /* EOL */
*conf = 0x00000000;
}
}
/* fdo#50830: connector indices for VGA and DVI-I are backwards */
if (nv_match_device(dev, 0x0421, 0x3842, 0xc793)) {
if (idx == 0 && *conn == 0x02000300)
*conn = 0x02011300;
else
if (idx == 1 && *conn == 0x04011310)
*conn = 0x04000310;
else
if (idx == 2 && *conn == 0x02011312)
*conn = 0x02000312;
}
return true;
}
static void
fabricate_dcb_encoder_table(struct drm_device *dev, struct nvbios *bios)
{
struct dcb_table *dcb = &bios->dcb;
int all_heads = (nv_two_heads(dev) ? 3 : 1);
#ifdef __powerpc__
/* Apple iMac G4 NV17 */
if (of_machine_is_compatible("PowerMac4,5")) {
fabricate_dcb_output(dcb, OUTPUT_TMDS, 0, all_heads, 1);
fabricate_dcb_output(dcb, OUTPUT_ANALOG, 1, all_heads, 2);
return;
}
#endif
/* Make up some sane defaults */
fabricate_dcb_output(dcb, OUTPUT_ANALOG,
bios->legacy.i2c_indices.crt, 1, 1);
if (nv04_tv_identify(dev, bios->legacy.i2c_indices.tv) >= 0)
fabricate_dcb_output(dcb, OUTPUT_TV,
bios->legacy.i2c_indices.tv,
all_heads, 0);
else if (bios->tmds.output0_script_ptr ||
bios->tmds.output1_script_ptr)
fabricate_dcb_output(dcb, OUTPUT_TMDS,
bios->legacy.i2c_indices.panel,
all_heads, 1);
}
static int
parse_dcb_entry(struct drm_device *dev, void *data, int idx, u8 *outp)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct dcb_table *dcb = &dev_priv->vbios.dcb;
u32 conf = (dcb->version >= 0x20) ? ROM32(outp[4]) : ROM32(outp[6]);
u32 conn = ROM32(outp[0]);
bool ret;
if (apply_dcb_encoder_quirks(dev, idx, &conn, &conf)) {
struct dcb_entry *entry = new_dcb_entry(dcb);
NV_TRACEWARN(dev, "DCB outp %02d: %08x %08x\n", idx, conn, conf);
if (dcb->version >= 0x20)
ret = parse_dcb20_entry(dev, dcb, conn, conf, entry);
else
ret = parse_dcb15_entry(dev, dcb, conn, conf, entry);
if (!ret)
return 1; /* stop parsing */
/* Ignore the I2C index for on-chip TV-out, as there
* are cards with bogus values (nv31m in bug 23212),
* and it's otherwise useless.
*/
if (entry->type == OUTPUT_TV &&
entry->location == DCB_LOC_ON_CHIP)
entry->i2c_index = 0x0f;
}
return 0;
}
static void
dcb_fake_connectors(struct nvbios *bios)
{
struct dcb_table *dcbt = &bios->dcb;
u8 map[16] = { };
int i, idx = 0;
/* heuristic: if we ever get a non-zero connector field, assume
* that all the indices are valid and we don't need fake them.
*
* and, as usual, a blacklist of boards with bad bios data..
*/
if (!nv_match_device(bios->dev, 0x0392, 0x107d, 0x20a2)) {
for (i = 0; i < dcbt->entries; i++) {
if (dcbt->entry[i].connector)
return;
}
}
/* no useful connector info available, we need to make it up
* ourselves. the rule here is: anything on the same i2c bus
* is considered to be on the same connector. any output
* without an associated i2c bus is assigned its own unique
* connector index.
*/
for (i = 0; i < dcbt->entries; i++) {
u8 i2c = dcbt->entry[i].i2c_index;
if (i2c == 0x0f) {
dcbt->entry[i].connector = idx++;
} else {
if (!map[i2c])
map[i2c] = ++idx;
dcbt->entry[i].connector = map[i2c] - 1;
}
}
/* if we created more than one connector, destroy the connector
* table - just in case it has random, rather than stub, entries.
*/
if (i > 1) {
u8 *conntab = dcb_conntab(bios->dev);
if (conntab)
conntab[0] = 0x00;
}
}
static int
parse_dcb_table(struct drm_device *dev, struct nvbios *bios)
{
struct dcb_table *dcb = &bios->dcb;
u8 *dcbt, *conn;
int idx;
dcbt = dcb_table(dev);
if (!dcbt) {
/* handle pre-DCB boards */
if (bios->type == NVBIOS_BMP) {
fabricate_dcb_encoder_table(dev, bios);
return 0;
}
return -EINVAL;
}
NV_TRACE(dev, "DCB version %d.%d\n", dcbt[0] >> 4, dcbt[0] & 0xf);
dcb->version = dcbt[0];
dcb_outp_foreach(dev, NULL, parse_dcb_entry);
/*
* apart for v2.1+ not being known for requiring merging, this
* guarantees dcbent->index is the index of the entry in the rom image
*/
if (dcb->version < 0x21)
merge_like_dcb_entries(dev, dcb);
if (!dcb->entries)
return -ENXIO;
/* dump connector table entries to log, if any exist */
idx = -1;
while ((conn = dcb_conn(dev, ++idx))) {
if (conn[0] != 0xff) {
NV_TRACE(dev, "DCB conn %02d: ", idx);
if (dcb_conntab(dev)[3] < 4)
printk("%04x\n", ROM16(conn[0]));
else
printk("%08x\n", ROM32(conn[0]));
}
}
dcb_fake_connectors(bios);
return 0;
}
static int load_nv17_hwsq_ucode_entry(struct drm_device *dev, struct nvbios *bios, uint16_t hwsq_offset, int entry)
{
/*
* The header following the "HWSQ" signature has the number of entries,
* and the entry size
*
* An entry consists of a dword to write to the sequencer control reg
* (0x00001304), followed by the ucode bytes, written sequentially,
* starting at reg 0x00001400
*/
uint8_t bytes_to_write;
uint16_t hwsq_entry_offset;
int i;
if (bios->data[hwsq_offset] <= entry) {
NV_ERROR(dev, "Too few entries in HW sequencer table for "
"requested entry\n");
return -ENOENT;
}
bytes_to_write = bios->data[hwsq_offset + 1];
if (bytes_to_write != 36) {
NV_ERROR(dev, "Unknown HW sequencer entry size\n");
return -EINVAL;
}
NV_TRACE(dev, "Loading NV17 power sequencing microcode\n");
hwsq_entry_offset = hwsq_offset + 2 + entry * bytes_to_write;
/* set sequencer control */
bios_wr32(bios, 0x00001304, ROM32(bios->data[hwsq_entry_offset]));
bytes_to_write -= 4;
/* write ucode */
for (i = 0; i < bytes_to_write; i += 4)
bios_wr32(bios, 0x00001400 + i, ROM32(bios->data[hwsq_entry_offset + i + 4]));
/* twiddle NV_PBUS_DEBUG_4 */
bios_wr32(bios, NV_PBUS_DEBUG_4, bios_rd32(bios, NV_PBUS_DEBUG_4) | 0x18);
return 0;
}
static int load_nv17_hw_sequencer_ucode(struct drm_device *dev,
struct nvbios *bios)
{
/*
* BMP based cards, from NV17, need a microcode loading to correctly
* control the GPIO etc for LVDS panels
*
* BIT based cards seem to do this directly in the init scripts
*
* The microcode entries are found by the "HWSQ" signature.
*/
const uint8_t hwsq_signature[] = { 'H', 'W', 'S', 'Q' };
const int sz = sizeof(hwsq_signature);
int hwsq_offset;
hwsq_offset = findstr(bios->data, bios->length, hwsq_signature, sz);
if (!hwsq_offset)
return 0;
/* always use entry 0? */
return load_nv17_hwsq_ucode_entry(dev, bios, hwsq_offset + sz, 0);
}
uint8_t *nouveau_bios_embedded_edid(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
const uint8_t edid_sig[] = {
0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x00 };
uint16_t offset = 0;
uint16_t newoffset;
int searchlen = NV_PROM_SIZE;
if (bios->fp.edid)
return bios->fp.edid;
while (searchlen) {
newoffset = findstr(&bios->data[offset], searchlen,
edid_sig, 8);
if (!newoffset)
return NULL;
offset += newoffset;
if (!nv_cksum(&bios->data[offset], EDID1_LEN))
break;
searchlen -= offset;
offset++;
}
NV_TRACE(dev, "Found EDID in BIOS\n");
return bios->fp.edid = &bios->data[offset];
}
void
nouveau_bios_run_init_table(struct drm_device *dev, uint16_t table,
struct dcb_entry *dcbent, int crtc)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
struct init_exec iexec = { true, false };
spin_lock_bh(&bios->lock);
bios->display.output = dcbent;
bios->display.crtc = crtc;
parse_init_table(bios, table, &iexec);
bios->display.output = NULL;
spin_unlock_bh(&bios->lock);
}
void
nouveau_bios_init_exec(struct drm_device *dev, uint16_t table)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
struct init_exec iexec = { true, false };
parse_init_table(bios, table, &iexec);
}
static bool NVInitVBIOS(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
memset(bios, 0, sizeof(struct nvbios));
spin_lock_init(&bios->lock);
bios->dev = dev;
return bios_shadow(dev);
}
static int nouveau_parse_vbios_struct(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
const uint8_t bit_signature[] = { 0xff, 0xb8, 'B', 'I', 'T' };
const uint8_t bmp_signature[] = { 0xff, 0x7f, 'N', 'V', 0x0 };
int offset;
offset = findstr(bios->data, bios->length,
bit_signature, sizeof(bit_signature));
if (offset) {
NV_TRACE(dev, "BIT BIOS found\n");
bios->type = NVBIOS_BIT;
bios->offset = offset;
return parse_bit_structure(bios, offset + 6);
}
offset = findstr(bios->data, bios->length,
bmp_signature, sizeof(bmp_signature));
if (offset) {
NV_TRACE(dev, "BMP BIOS found\n");
bios->type = NVBIOS_BMP;
bios->offset = offset;
return parse_bmp_structure(dev, bios, offset);
}
NV_ERROR(dev, "No known BIOS signature found\n");
return -ENODEV;
}
int
nouveau_run_vbios_init(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
int i, ret = 0;
/* Reset the BIOS head to 0. */
bios->state.crtchead = 0;
if (bios->major_version < 5) /* BMP only */
load_nv17_hw_sequencer_ucode(dev, bios);
if (bios->execute) {
bios->fp.last_script_invoc = 0;
bios->fp.lvds_init_run = false;
}
parse_init_tables(bios);
/*
* Runs some additional script seen on G8x VBIOSen. The VBIOS'
* parser will run this right after the init tables, the binary
* driver appears to run it at some point later.
*/
if (bios->some_script_ptr) {
struct init_exec iexec = {true, false};
NV_INFO(dev, "Parsing VBIOS init table at offset 0x%04X\n",
bios->some_script_ptr);
parse_init_table(bios, bios->some_script_ptr, &iexec);
}
if (dev_priv->card_type >= NV_50) {
for (i = 0; i < bios->dcb.entries; i++) {
nouveau_bios_run_display_table(dev, 0, 0,
&bios->dcb.entry[i], -1);
}
}
return ret;
}
static bool
nouveau_bios_posted(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
unsigned htotal;
if (dev_priv->card_type >= NV_50) {
if (NVReadVgaCrtc(dev, 0, 0x00) == 0 &&
NVReadVgaCrtc(dev, 0, 0x1a) == 0)
return false;
return true;
}
htotal = NVReadVgaCrtc(dev, 0, 0x06);
htotal |= (NVReadVgaCrtc(dev, 0, 0x07) & 0x01) << 8;
htotal |= (NVReadVgaCrtc(dev, 0, 0x07) & 0x20) << 4;
htotal |= (NVReadVgaCrtc(dev, 0, 0x25) & 0x01) << 10;
htotal |= (NVReadVgaCrtc(dev, 0, 0x41) & 0x01) << 11;
return (htotal != 0);
}
int
nouveau_bios_init(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
struct nvbios *bios = &dev_priv->vbios;
int ret;
if (!NVInitVBIOS(dev))
return -ENODEV;
ret = nouveau_parse_vbios_struct(dev);
if (ret)
return ret;
ret = nouveau_i2c_init(dev);
if (ret)
return ret;
ret = nouveau_mxm_init(dev);
if (ret)
return ret;
ret = parse_dcb_table(dev, bios);
if (ret)
return ret;
if (!bios->major_version) /* we don't run version 0 bios */
return 0;
/* init script execution disabled */
bios->execute = false;
/* ... unless card isn't POSTed already */
if (!nouveau_bios_posted(dev)) {
NV_INFO(dev, "Adaptor not initialised, "
"running VBIOS init tables.\n");
bios->execute = true;
}
if (nouveau_force_post)
bios->execute = true;
ret = nouveau_run_vbios_init(dev);
if (ret)
return ret;
/* feature_byte on BMP is poor, but init always sets CR4B */
if (bios->major_version < 5)
bios->is_mobile = NVReadVgaCrtc(dev, 0, NV_CIO_CRE_4B) & 0x40;
/* all BIT systems need p_f_m_t for digital_min_front_porch */
if (bios->is_mobile || bios->major_version >= 5)
ret = parse_fp_mode_table(dev, bios);
/* allow subsequent scripts to execute */
bios->execute = true;
return 0;
}
void
nouveau_bios_takedown(struct drm_device *dev)
{
struct drm_nouveau_private *dev_priv = dev->dev_private;
nouveau_mxm_fini(dev);
nouveau_i2c_fini(dev);
kfree(dev_priv->vbios.data);
}