kolibrios-gitea/drivers/video/radeonhd/rhd_crtc.c
Sergey Semyonov (Serge) fb8dc89b4d move drivers from programs/system/drivers into /drivers
git-svn-id: svn://kolibrios.org@1029 a494cfbc-eb01-0410-851d-a64ba20cac60
2009-02-11 06:52:01 +00:00

1501 lines
40 KiB
C

/*
* Copyright 2007, 2008 Luc Verhaegen <lverhaegen@novell.com>
* Copyright 2007, 2008 Matthias Hopf <mhopf@novell.com>
* Copyright 2007, 2008 Egbert Eich <eich@novell.com>
* Copyright 2007, 2008 Advanced Micro Devices, Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, 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 COPYRIGHT HOLDER(S) OR AUTHOR(S) 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.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include "xf86.h"
/* for usleep */
#if HAVE_XF86_ANSIC_H
# include "xf86_ansic.h"
#else
# include <unistd.h>
#endif
#include "rhd.h"
#include "rhd_crtc.h"
#include "rhd_pll.h"
#include "rhd_lut.h"
#include "rhd_regs.h"
#include "rhd_modes.h"
#include "rhd_mc.h"
#ifdef ATOM_BIOS
# include "rhd_atombios.h"
#endif
#define D1_REG_OFFSET 0x0000
#define D2_REG_OFFSET 0x0800
#define FMT1_REG_OFFSET 0x0000
#define FMT2_REG_OFFSET 0x800
struct rhdCrtcFMTPrivate {
CARD32 StoreControl;
CARD32 StoreBitDepthControl;
CARD32 StoreClampCntl;
};
struct rhdCrtcFBPrivate {
CARD32 StoreGrphEnable;
CARD32 StoreGrphControl;
CARD32 StoreGrphXStart;
CARD32 StoreGrphYStart;
CARD32 StoreGrphXEnd;
CARD32 StoreGrphYEnd;
CARD32 StoreGrphSwap;
CARD32 StoreGrphPrimarySurfaceAddress;
CARD32 StoreGrphSurfaceOffsetX;
CARD32 StoreGrphSurfaceOffsetY;
CARD32 StoreGrphPitch;
CARD32 StoreModeDesktopHeight;
};
struct rhdCrtcLUTPrivate {
CARD32 StoreGrphLutSel;
};
struct rhdCrtcScalePrivate {
CARD32 StoreModeViewPortSize;
CARD32 StoreModeOverScanH;
CARD32 StoreModeOverScanV;
CARD32 StoreModeViewPortStart;
CARD32 StoreScaleEnable;
CARD32 StoreScaleTapControl;
CARD32 StoreModeCenter;
CARD32 StoreScaleHV;
CARD32 StoreScaleHFilter;
CARD32 StoreScaleVFilter;
CARD32 StoreScaleDither;
};
struct rhdCrtcModePrivate {
CARD32 StoreCrtcControl;
CARD32 StoreCrtcHTotal;
CARD32 StoreCrtcHBlankStartEnd;
CARD32 StoreCrtcHSyncA;
CARD32 StoreCrtcHSyncACntl;
CARD32 StoreCrtcHSyncB;
CARD32 StoreCrtcHSyncBCntl;
CARD32 StoreCrtcVTotal;
CARD32 StoreCrtcVBlankStartEnd;
CARD32 StoreCrtcVSyncA;
CARD32 StoreCrtcVSyncACntl;
CARD32 StoreCrtcVSyncB;
CARD32 StoreCrtcVSyncBCntl;
CARD32 StoreCrtcCountControl;
CARD32 StoreModeDataFormat;
CARD32 StoreCrtcInterlaceControl;
CARD32 StoreCrtcBlackColor;
CARD32 StoreCrtcBlankControl;
};
/*
* Checks whether Width, Height are within boundaries.
* If MODE_OK is returned and pPitch is not NULL, it is set.
*/
static ModeStatus
DxFBValid(struct rhdCrtc *Crtc, CARD16 Width, CARD16 Height, int bpp,
CARD32 Offset, CARD32 Size, CARD32 *pPitch)
{
RHDPtr rhdPtr = RHDPTRI(Crtc);
ScrnInfoPtr pScrn = rhdPtr->pScrn;
CARD16 Pitch;
unsigned int BytesPerPixel;
CARD8 PitchMask = 0xFF;
RHDDebug(Crtc->scrnIndex, "FUNCTION: %s: %s\n", __func__, Crtc->Name);
/* If we hit this, then the memory claimed so far is not properly aligned */
if (Offset & 0xFFF) {
xf86DrvMsg(Crtc->scrnIndex, X_ERROR, "%s: Offset (0x%08X) is invalid!\n",
__func__, (int) Offset);
return MODE_ERROR;
}
switch (pScrn->bitsPerPixel) {
case 8:
BytesPerPixel = 1;
break;
case 15:
case 16:
BytesPerPixel = 2;
PitchMask /= BytesPerPixel;
break;
case 24:
case 32:
BytesPerPixel = 4;
PitchMask /= BytesPerPixel;
break;
default:
xf86DrvMsg(pScrn->scrnIndex, X_WARNING, "%s: %dbpp is not implemented!\n",
__func__, pScrn->bitsPerPixel);
return MODE_BAD;
}
if((Width==720)&&(Height==400)) //skip textmode
return MODE_BAD;
/* Be reasonable */
if (Width < 640)
return MODE_H_ILLEGAL;
if (Height < 480)
return MODE_V_ILLEGAL;
/* D1GRPH_X_START is 14bits while D1_MODE_VIEWPORT_X_START is only 13 bits.
* Since it is reasonable to assume that modes will be at least 1x1
* limit at 13bits + 1 */
if (Width > 0x2000)
return MODE_VIRTUAL_X;
/* D1GRPH_Y_START is 14bits while D1_MODE_VIEWPORT_Y_START is only 13 bits.
* Since it is reasonable to assume that modes will be at least 1x1
* limit at 13bits + 1 */
if (Height > 0x2000)
return MODE_VIRTUAL_Y;
Pitch = (Width + PitchMask) & ~PitchMask;
/* D1_PITCH limit: should never happen after clamping Width to 0x2000 */
if (Pitch >= 0x4000)
return MODE_VIRTUAL_X;
if ((Pitch * BytesPerPixel * Height) > Size)
return MODE_MEM_VIRT;
if (pPitch)
*pPitch = Pitch;
return MODE_OK;
}
/*
*
*/
static void
DxFBSet(struct rhdCrtc *Crtc, CARD16 Pitch, CARD16 Width, CARD16 Height,
int bpp, CARD32 Offset)
{
RHDPtr rhdPtr = RHDPTRI(Crtc);
CARD16 RegOff;
RHDDebug(Crtc->scrnIndex, "FUNCTION: %s: %s (%i[%i]x%i@%ibpp) +0x%x )\n",
__func__, Crtc->Name, Width, Pitch, Height, bpp, Offset);
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
RHDRegMask(Crtc, RegOff + D1GRPH_ENABLE, 1, 0x00000001);
/* disable R/B swap, disable tiling, disable 16bit alpha, etc. */
RHDRegWrite(Crtc, RegOff + D1GRPH_CONTROL, 0);
switch (bpp) {
case 8:
RHDRegMask(Crtc, RegOff + D1GRPH_CONTROL, 0, 0x00000703);
break;
case 15:
RHDRegMask(Crtc, RegOff + D1GRPH_CONTROL, 0x000001, 0x00000703);
break;
case 16:
RHDRegMask(Crtc, RegOff + D1GRPH_CONTROL, 0x000101, 0x00000703);
break;
case 24:
case 32:
default:
RHDRegMask(Crtc, RegOff + D1GRPH_CONTROL, 0x000002, 0x00000703);
break;
/* TODO: 64bpp ;p */
}
/* Make sure that we are not swapping colours around */
if (rhdPtr->ChipSet > RHD_R600)
RHDRegWrite(Crtc, RegOff + D1GRPH_SWAP_CNTL, 0);
/* R5xx - RS690 case is GRPH_CONTROL bit 16 */
RHDRegWrite(Crtc, RegOff + D1GRPH_PRIMARY_SURFACE_ADDRESS,
rhdPtr->FbIntAddress + Offset);
RHDRegWrite(Crtc, RegOff + D1GRPH_PITCH, Pitch);
RHDRegWrite(Crtc, RegOff + D1GRPH_SURFACE_OFFSET_X, 0);
RHDRegWrite(Crtc, RegOff + D1GRPH_SURFACE_OFFSET_Y, 0);
RHDRegWrite(Crtc, RegOff + D1GRPH_X_START, 0);
RHDRegWrite(Crtc, RegOff + D1GRPH_Y_START, 0);
RHDRegWrite(Crtc, RegOff + D1GRPH_X_END, Width);
RHDRegWrite(Crtc, RegOff + D1GRPH_Y_END, Height);
/* D1Mode registers */
RHDRegWrite(Crtc, RegOff + D1MODE_DESKTOP_HEIGHT, Height);
Crtc->Pitch = Pitch;
Crtc->Width = Width;
Crtc->Height = Height;
Crtc->bpp = bpp;
Crtc->Offset = Offset;
}
/*
*
*/
static void
DxFBSave(struct rhdCrtc *Crtc)
{
struct rhdCrtcFBPrivate *FBPriv;
CARD32 RegOff;
if (!Crtc->FBPriv)
FBPriv = xnfcalloc(1, sizeof(struct rhdCrtcFBPrivate));
else
FBPriv = Crtc->FBPriv;
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
FBPriv->StoreGrphEnable = RHDRegRead(Crtc, RegOff + D1GRPH_ENABLE);
FBPriv->StoreGrphControl = RHDRegRead(Crtc, RegOff + D1GRPH_CONTROL);
FBPriv->StoreGrphXStart = RHDRegRead(Crtc, RegOff + D1GRPH_X_START);
FBPriv->StoreGrphYStart = RHDRegRead(Crtc, RegOff + D1GRPH_Y_START);
FBPriv->StoreGrphXEnd = RHDRegRead(Crtc, RegOff + D1GRPH_X_END);
FBPriv->StoreGrphYEnd = RHDRegRead(Crtc, RegOff + D1GRPH_Y_END);
if (RHDPTRI(Crtc)->ChipSet >= RHD_R600)
FBPriv->StoreGrphSwap = RHDRegRead(Crtc, RegOff + D1GRPH_SWAP_CNTL);
FBPriv->StoreGrphPrimarySurfaceAddress =
RHDRegRead(Crtc, RegOff + D1GRPH_PRIMARY_SURFACE_ADDRESS);
FBPriv->StoreGrphSurfaceOffsetX =
RHDRegRead(Crtc, RegOff + D1GRPH_SURFACE_OFFSET_X);
FBPriv->StoreGrphSurfaceOffsetY =
RHDRegRead(Crtc, RegOff + D1GRPH_SURFACE_OFFSET_Y);
FBPriv->StoreGrphPitch = RHDRegRead(Crtc, RegOff + D1GRPH_PITCH);
FBPriv->StoreModeDesktopHeight = RHDRegRead(Crtc, RegOff + D1MODE_DESKTOP_HEIGHT);
Crtc->FBPriv = FBPriv;
}
/*
*
*/
static void
DxFBRestore(struct rhdCrtc *Crtc)
{
struct rhdCrtcFBPrivate *FBPriv = Crtc->FBPriv;
CARD32 RegOff;
if (!FBPriv) {
xf86DrvMsg(Crtc->scrnIndex, X_ERROR, "%s: no registers stored!\n",
__func__);
return;
}
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
/* FBSet */
RHDRegWrite(Crtc, RegOff + D1GRPH_CONTROL, FBPriv->StoreGrphControl);
RHDRegWrite(Crtc, RegOff + D1GRPH_X_START, FBPriv->StoreGrphXStart);
RHDRegWrite(Crtc, RegOff + D1GRPH_Y_START, FBPriv->StoreGrphYStart);
RHDRegWrite(Crtc, RegOff + D1GRPH_X_END, FBPriv->StoreGrphXEnd);
RHDRegWrite(Crtc, RegOff + D1GRPH_Y_END, FBPriv->StoreGrphYEnd);
if (RHDPTRI(Crtc)->ChipSet >= RHD_R600)
RHDRegWrite(Crtc, RegOff + D1GRPH_SWAP_CNTL, FBPriv->StoreGrphSwap);
/* disable read requests */
RHDRegMask(Crtc, RegOff + D1CRTC_CONTROL, 0x01000000, 0x01000000);
RHDRegMask(Crtc, RegOff + D1GRPH_ENABLE, 0, 0x00000001);
usleep (10);
RHDRegWrite(Crtc, RegOff + D1GRPH_PRIMARY_SURFACE_ADDRESS,
FBPriv->StoreGrphPrimarySurfaceAddress);
usleep(10);
RHDRegWrite(Crtc, RegOff + D1GRPH_ENABLE, FBPriv->StoreGrphEnable);
RHDRegWrite(Crtc, RegOff + D1GRPH_SURFACE_OFFSET_X,
FBPriv->StoreGrphSurfaceOffsetX);
RHDRegWrite(Crtc, RegOff + D1GRPH_SURFACE_OFFSET_Y,
FBPriv->StoreGrphSurfaceOffsetY);
RHDRegWrite(Crtc, RegOff + D1GRPH_PITCH, FBPriv->StoreGrphPitch);
RHDRegWrite(Crtc, RegOff + D1MODE_DESKTOP_HEIGHT, FBPriv->StoreModeDesktopHeight);
}
/*
*
*/
static void
DxFBDestroy(struct rhdCrtc *Crtc)
{
if (Crtc->FBPriv)
xfree(Crtc->FBPriv);
Crtc->FBPriv = NULL;
}
/*
*
*/
static ModeStatus
DxModeValid(struct rhdCrtc *Crtc, DisplayModePtr Mode)
{
CARD32 tmp;
RHDDebug(Crtc->scrnIndex, "%s: %s\n", __func__, Crtc->Name);
/* Work around HW bug: need at least 2 lines of front porch
for interlaced mode */
if ((Mode->Flags & V_INTERLACE)
&& (Mode->CrtcVSyncStart < (Mode->CrtcVDisplay + 2))) {
Mode->CrtcVSyncStart = Mode->CrtcVDisplay + 2;
Mode->CrtcVAdjusted = TRUE;
}
/* D1CRTC_H_TOTAL - 1 : 13bits */
if (Mode->CrtcHTotal > 0x2000)
return MODE_BAD_HVALUE;
tmp = Mode->CrtcHTotal + Mode->CrtcHBlankStart - Mode->CrtcHSyncStart;
/* D1CRTC_H_BLANK_START: 13bits */
if (tmp >= 0x2000)
return MODE_BAD_HVALUE;
tmp = Mode->CrtcHBlankEnd - Mode->CrtcHSyncStart;
/* D1CRTC_H_BLANK_END: 13bits */
if (tmp >= 0x2000)
return MODE_BAD_HVALUE;
tmp = Mode->CrtcHSyncEnd - Mode->CrtcHSyncStart;
/* D1CRTC_H_SYNC_A_END: 13bits */
if (tmp >= 0x2000)
return MODE_HSYNC_WIDE;
/* D1CRTC_V_TOTAL - 1 : 13bits */
if (Mode->CrtcVTotal > 0x2000)
return MODE_BAD_VVALUE;
tmp = Mode->CrtcVTotal + Mode->CrtcVBlankStart - Mode->CrtcVSyncStart;
/* D1CRTC_V_BLANK_START: 13bits */
if (tmp >= 0x2000)
return MODE_BAD_VVALUE;
tmp = Mode->CrtcVBlankEnd - Mode->CrtcVSyncStart;
/* D1CRTC_V_BLANK_END: 13bits */
if (tmp >= 0x2000)
return MODE_BAD_VVALUE;
tmp = Mode->CrtcVSyncEnd - Mode->CrtcVSyncStart;
/* D1CRTC_V_SYNC_A_END: 13bits */
if (tmp >= 0x2000)
return MODE_VSYNC_WIDE;
return MODE_OK;
}
/*
*
*/
static void
DxModeSet(struct rhdCrtc *Crtc, DisplayModePtr Mode)
{
RHDPtr rhdPtr = RHDPTRI(Crtc);
CARD16 BlankStart, BlankEnd;
CARD16 RegOff;
RHDDebug(Crtc->scrnIndex, "FUNCTION: %s: %s\n", __func__, Crtc->Name);
if (rhdPtr->verbosity > 6) {
xf86DrvMsg(Crtc->scrnIndex, X_INFO, "%s: Setting ",__func__);
RHDPrintModeline(Mode);
}
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
/* enable read requests */
RHDRegMask(Crtc, RegOff + D1CRTC_CONTROL, 0, 0x01000000);
/* Horizontal */
RHDRegWrite(Crtc, RegOff + D1CRTC_H_TOTAL, Mode->CrtcHTotal - 1);
BlankStart = Mode->CrtcHTotal + Mode->CrtcHBlankStart - Mode->CrtcHSyncStart;
BlankEnd = Mode->CrtcHBlankEnd - Mode->CrtcHSyncStart;
RHDRegWrite(Crtc, RegOff + D1CRTC_H_BLANK_START_END,
BlankStart | (BlankEnd << 16));
RHDRegWrite(Crtc, RegOff + D1CRTC_H_SYNC_A,
(Mode->CrtcHSyncEnd - Mode->CrtcHSyncStart) << 16);
RHDRegWrite(Crtc, RegOff + D1CRTC_H_SYNC_A_CNTL, Mode->Flags & V_NHSYNC);
/* Vertical */
RHDRegWrite(Crtc, RegOff + D1CRTC_V_TOTAL, Mode->CrtcVTotal - 1);
BlankStart = Mode->CrtcVTotal + Mode->CrtcVBlankStart - Mode->CrtcVSyncStart;
BlankEnd = Mode->CrtcVBlankEnd - Mode->CrtcVSyncStart;
RHDRegWrite(Crtc, RegOff + D1CRTC_V_BLANK_START_END,
BlankStart | (BlankEnd << 16));
/* set interlaced */
if (Mode->Flags & V_INTERLACE) {
RHDRegWrite(Crtc, RegOff + D1CRTC_INTERLACE_CONTROL, 0x1);
RHDRegWrite(Crtc, RegOff + D1MODE_DATA_FORMAT, 0x1);
} else {
RHDRegWrite(Crtc, RegOff + D1CRTC_INTERLACE_CONTROL, 0x0);
RHDRegWrite(Crtc, RegOff + D1MODE_DATA_FORMAT, 0x0);
}
RHDRegWrite(Crtc, RegOff + D1CRTC_V_SYNC_A,
(Mode->CrtcVSyncEnd - Mode->CrtcVSyncStart) << 16);
RHDRegWrite(Crtc, RegOff + D1CRTC_V_SYNC_A_CNTL, Mode->Flags & V_NVSYNC);
/* set D1CRTC_HORZ_COUNT_BY2_EN to 0; should only be set to 1 on 30bpp DVI modes */
RHDRegMask(Crtc, RegOff + D1CRTC_COUNT_CONTROL, 0x0, 0x1);
Crtc->CurrentMode = Mode;
}
/*
*
*/
static void
DxModeSave(struct rhdCrtc *Crtc)
{
struct rhdCrtcModePrivate *ModePriv;
CARD32 RegOff;
if (!Crtc->ModePriv)
ModePriv = xnfcalloc(1, sizeof(struct rhdCrtcModePrivate));
else
ModePriv = Crtc->ModePriv;
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
ModePriv->StoreCrtcControl = RHDRegRead(Crtc, RegOff + D1CRTC_CONTROL);
ModePriv->StoreCrtcHTotal = RHDRegRead(Crtc, RegOff + D1CRTC_H_TOTAL);
ModePriv->StoreCrtcHBlankStartEnd =
RHDRegRead(Crtc, RegOff + D1CRTC_H_BLANK_START_END);
ModePriv->StoreCrtcHSyncA = RHDRegRead(Crtc, RegOff + D1CRTC_H_SYNC_A);
ModePriv->StoreCrtcHSyncACntl = RHDRegRead(Crtc, RegOff + D1CRTC_H_SYNC_A_CNTL);
ModePriv->StoreCrtcHSyncB = RHDRegRead(Crtc, RegOff + D1CRTC_H_SYNC_B);
ModePriv->StoreCrtcHSyncBCntl = RHDRegRead(Crtc, RegOff + D1CRTC_H_SYNC_B_CNTL);
ModePriv->StoreModeDataFormat = RHDRegRead(Crtc, RegOff + D1MODE_DATA_FORMAT);
ModePriv->StoreCrtcInterlaceControl = RHDRegRead(Crtc, RegOff + D1CRTC_INTERLACE_CONTROL);
ModePriv->StoreCrtcVTotal = RHDRegRead(Crtc, RegOff + D1CRTC_V_TOTAL);
ModePriv->StoreCrtcVBlankStartEnd =
RHDRegRead(Crtc, RegOff + D1CRTC_V_BLANK_START_END);
ModePriv->StoreCrtcVSyncA = RHDRegRead(Crtc, RegOff + D1CRTC_V_SYNC_A);
ModePriv->StoreCrtcVSyncACntl = RHDRegRead(Crtc, RegOff + D1CRTC_V_SYNC_A_CNTL);
ModePriv->StoreCrtcVSyncB = RHDRegRead(Crtc, RegOff + D1CRTC_V_SYNC_B);
ModePriv->StoreCrtcVSyncBCntl = RHDRegRead(Crtc, RegOff + D1CRTC_V_SYNC_B_CNTL);
ModePriv->StoreCrtcBlackColor = RHDRegRead(Crtc, RegOff + D1CRTC_BLACK_COLOR);
ModePriv->StoreCrtcBlankControl = RHDRegRead(Crtc, RegOff + D1CRTC_BLANK_CONTROL);
ModePriv->StoreCrtcCountControl = RHDRegRead(Crtc, RegOff + D1CRTC_COUNT_CONTROL);
RHDDebug(Crtc->scrnIndex, "Saved CrtcCountControl[%i] = 0x%8.8x\n",
Crtc->Id,ModePriv->StoreCrtcCountControl);
Crtc->ModePriv = ModePriv;
}
/*
*
*/
static void
DxModeRestore(struct rhdCrtc *Crtc)
{
struct rhdCrtcModePrivate *ModePriv = Crtc->ModePriv;
CARD32 RegOff;
if (!ModePriv) {
xf86DrvMsg(Crtc->scrnIndex, X_ERROR, "%s: no registers stored!\n",
__func__);
return;
}
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
/* ModeSet */
RHDRegWrite(Crtc, RegOff + D1CRTC_CONTROL, ModePriv->StoreCrtcControl);
RHDRegWrite(Crtc, RegOff + D1CRTC_H_TOTAL, ModePriv->StoreCrtcHTotal);
RHDRegWrite(Crtc, RegOff + D1CRTC_H_BLANK_START_END,
ModePriv->StoreCrtcHBlankStartEnd);
RHDRegWrite(Crtc, RegOff + D1CRTC_H_SYNC_A, ModePriv->StoreCrtcHSyncA);
RHDRegWrite(Crtc, RegOff + D1CRTC_H_SYNC_A_CNTL, ModePriv->StoreCrtcHSyncACntl);
RHDRegWrite(Crtc, RegOff + D1CRTC_H_SYNC_B, ModePriv->StoreCrtcHSyncB);
RHDRegWrite(Crtc, RegOff + D1CRTC_H_SYNC_B_CNTL, ModePriv->StoreCrtcHSyncBCntl);
RHDRegWrite(Crtc, RegOff + D1MODE_DATA_FORMAT, ModePriv->StoreModeDataFormat);
RHDRegWrite(Crtc, RegOff + D1CRTC_INTERLACE_CONTROL, ModePriv->StoreCrtcInterlaceControl);
RHDRegWrite(Crtc, RegOff + D1CRTC_V_TOTAL, ModePriv->StoreCrtcVTotal);
RHDRegWrite(Crtc, RegOff + D1CRTC_V_BLANK_START_END,
ModePriv->StoreCrtcVBlankStartEnd);
RHDRegWrite(Crtc, RegOff + D1CRTC_V_SYNC_A, ModePriv->StoreCrtcVSyncA);
RHDRegWrite(Crtc, RegOff + D1CRTC_V_SYNC_A_CNTL, ModePriv->StoreCrtcVSyncACntl);
RHDRegWrite(Crtc, RegOff + D1CRTC_V_SYNC_B, ModePriv->StoreCrtcVSyncB);
RHDRegWrite(Crtc, RegOff + D1CRTC_V_SYNC_B_CNTL, ModePriv->StoreCrtcVSyncBCntl);
RHDRegWrite(Crtc, RegOff + D1CRTC_COUNT_CONTROL, ModePriv->StoreCrtcCountControl);
/* Blank */
RHDRegWrite(Crtc, RegOff + D1CRTC_BLACK_COLOR, ModePriv->StoreCrtcBlackColor);
RHDRegWrite(Crtc, RegOff + D1CRTC_BLANK_CONTROL, ModePriv->StoreCrtcBlankControl);
/* When VGA is enabled, it imposes its timing on us, so our CRTC SYNC
* timing can be set to 0. This doesn't always restore properly...
* Workaround is to set a valid sync length for a bit so VGA can
* latch in. */
if (!ModePriv->StoreCrtcVSyncA && (ModePriv->StoreCrtcControl & 0x00000001)) {
RHDRegWrite(Crtc, RegOff + D1CRTC_V_SYNC_A, 0x00040000);
usleep(300000); /* seems a reliable timeout here */
RHDRegWrite(Crtc, RegOff + D1CRTC_V_SYNC_A, ModePriv->StoreCrtcVSyncA);
}
}
/*
*
*/
static void
DxModeDestroy(struct rhdCrtc *Crtc)
{
RHDFUNC(Crtc);
if (Crtc->ModePriv)
xfree(Crtc->ModePriv);
Crtc->ModePriv = NULL;
}
/*
*
*/
struct rhdScalerOverscan
rhdCalculateOverscan(DisplayModePtr Mode, DisplayModePtr ScaledToMode, enum rhdCrtcScaleType Type)
{
struct rhdScalerOverscan Overscan;
int tmp;
Overscan.OverscanTop = Overscan.OverscanBottom = Overscan.OverscanLeft = Overscan.OverscanRight = 0;
Overscan.Type = Type;
if (ScaledToMode) {
Overscan.OverscanTop = ScaledToMode->CrtcVDisplay - Mode->CrtcVDisplay;
Overscan.OverscanLeft = ScaledToMode->CrtcHDisplay - Mode->CrtcHDisplay;
if (!Overscan.OverscanTop && !Overscan.OverscanLeft)
Overscan.Type = RHD_CRTC_SCALE_TYPE_NONE;
/* handle down scaling */
if (Overscan.OverscanTop < 0) {
Overscan.Type = RHD_CRTC_SCALE_TYPE_SCALE;
Overscan.OverscanTop = 0;
}
if (Overscan.OverscanLeft < 0) {
Overscan.Type = RHD_CRTC_SCALE_TYPE_SCALE;
Overscan.OverscanLeft = 0;
}
}
switch (Type) {
case RHD_CRTC_SCALE_TYPE_NONE:
break;
case RHD_CRTC_SCALE_TYPE_CENTER:
tmp = Overscan.OverscanTop;
Overscan.OverscanTop >>= 1;
Overscan.OverscanBottom = tmp - Overscan.OverscanTop;
tmp = Overscan.OverscanLeft;
Overscan.OverscanLeft >>= 1;
Overscan.OverscanRight = tmp - Overscan.OverscanLeft;
break;
case RHD_CRTC_SCALE_TYPE_SCALE:
Overscan.OverscanLeft = Overscan.OverscanRight = Overscan.OverscanTop = Overscan.OverscanBottom = 0;
break;
case RHD_CRTC_SCALE_TYPE_SCALE_KEEP_ASPECT_RATIO:
{
int p1, p2, tmp;
Overscan.OverscanLeft = Overscan.OverscanRight = Overscan.OverscanTop = Overscan.OverscanBottom = 0;
p1 = Mode->CrtcVDisplay * ScaledToMode->CrtcHDisplay;
p2 = ScaledToMode->CrtcVDisplay * Mode->CrtcHDisplay;
if (p1 == p2) {
Overscan.Type = RHD_CRTC_SCALE_TYPE_SCALE;
} else if (p1 > p2) {
tmp = (p2 / Mode->CrtcVDisplay);
tmp = ScaledToMode->CrtcHDisplay - tmp;
Overscan.OverscanLeft = tmp >> 1;
Overscan.OverscanRight = tmp - Overscan.OverscanLeft;
ErrorF("HScale %i %i\n", Overscan.OverscanLeft, Overscan.OverscanRight);
} else {
tmp = (p1 / Mode->CrtcHDisplay);
tmp = ScaledToMode->CrtcVDisplay - tmp;
Overscan.OverscanTop = tmp >> 1;
Overscan.OverscanBottom = tmp - Overscan.OverscanTop;
ErrorF("VScale %i %i\n", Overscan.OverscanTop, Overscan.OverscanBottom);
}
break;
}
}
return Overscan;
}
/*
*
*/
static ModeStatus
DxScaleValid(struct rhdCrtc *Crtc, enum rhdCrtcScaleType Type,
DisplayModePtr Mode, DisplayModePtr ScaledToMode)
{
struct rhdScalerOverscan Overscan;
/* D1_MODE_VIEWPORT_WIDTH: 14bits */
if (Mode->CrtcHDisplay >= 0x4000)
return MODE_BAD_HVALUE;
/* D1_MODE_VIEWPORT_HEIGHT: 14bits */
if (Mode->CrtcVDisplay >= 0x4000)
return MODE_BAD_VVALUE;
Overscan = rhdCalculateOverscan(Mode, ScaledToMode, Type);
if (Overscan.OverscanLeft >= 4096 || Overscan.OverscanRight >= 4096)
return MODE_HBLANK_WIDE;
if (Overscan.OverscanTop >= 4096 || Overscan.OverscanBottom >= 4096)
return MODE_VBLANK_WIDE;
if ((Type == RHD_CRTC_SCALE_TYPE_SCALE
|| Type == RHD_CRTC_SCALE_TYPE_SCALE_KEEP_ASPECT_RATIO)
&& (Mode->Flags & V_INTERLACE))
return MODE_NO_INTERLACE;
/* should we also fail of Type != Overscan.Type? */
return MODE_OK;
}
/*
*
*/
static void
DxScaleSet(struct rhdCrtc *Crtc, enum rhdCrtcScaleType Type,
DisplayModePtr Mode, DisplayModePtr ScaledToMode)
{
RHDPtr rhdPtr = RHDPTRI(Crtc);
CARD16 RegOff;
struct rhdScalerOverscan Overscan;
RHDDebug(Crtc->scrnIndex, "FUNCTION: %s: %s viewport: %ix%i\n", __func__, Crtc->Name,
Mode->CrtcHDisplay, Mode->CrtcVDisplay);
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
Overscan = rhdCalculateOverscan(Mode, ScaledToMode, Type);
Type = Overscan.Type;
RHDDebug(Crtc->scrnIndex, "FUNCTION: %s: %s viewport: %ix%i - OverScan: T: %i B: %i R: %i L: %i\n",
__func__, Crtc->Name, Mode->CrtcHDisplay, Mode->CrtcVDisplay,
Overscan.OverscanTop, Overscan.OverscanBottom,
Overscan.OverscanLeft, Overscan.OverscanRight);
/* D1Mode registers */
RHDRegWrite(Crtc, RegOff + D1MODE_VIEWPORT_SIZE,
Mode->CrtcVDisplay | (Mode->CrtcHDisplay << 16));
RHDRegWrite(Crtc, RegOff + D1MODE_VIEWPORT_START, 0);
RHDRegWrite(Crtc, RegOff + D1MODE_EXT_OVERSCAN_LEFT_RIGHT,
(Overscan.OverscanLeft << 16) | Overscan.OverscanRight);
RHDRegWrite(Crtc, RegOff + D1MODE_EXT_OVERSCAN_TOP_BOTTOM,
(Overscan.OverscanTop << 16) | Overscan.OverscanBottom);
switch (Type) {
case RHD_CRTC_SCALE_TYPE_NONE: /* No scaling whatsoever */
ErrorF("None\n");
RHDRegWrite(Crtc, RegOff + D1SCL_ENABLE, 0);
RHDRegWrite(Crtc, RegOff + D1SCL_TAP_CONTROL, 0);
RHDRegWrite(Crtc, RegOff + D1MODE_CENTER, 0);
break;
case RHD_CRTC_SCALE_TYPE_CENTER: /* center of the actual mode */
ErrorF("Center\n");
RHDRegWrite(Crtc, RegOff + D1SCL_ENABLE, 0);
RHDRegWrite(Crtc, RegOff + D1SCL_TAP_CONTROL, 0);
RHDRegWrite(Crtc, RegOff + D1MODE_CENTER, 1);
break;
case RHD_CRTC_SCALE_TYPE_SCALE_KEEP_ASPECT_RATIO: /* scaled to fullscreen */
case RHD_CRTC_SCALE_TYPE_SCALE: /* scaled to fullscreen */
ErrorF("Full\n");
if (Type == RHD_CRTC_SCALE_TYPE_SCALE_KEEP_ASPECT_RATIO)
RHDRegWrite(Crtc, RegOff + D1MODE_CENTER, 1);
else
RHDRegWrite(Crtc, RegOff + D1MODE_CENTER, 0);
RHDRegWrite(Crtc, RegOff + D1SCL_UPDATE, 0);
RHDRegWrite(Crtc, RegOff + D1SCL_DITHER, 0);
RHDRegWrite(Crtc, RegOff + D1SCL_ENABLE, 1);
RHDRegWrite(Crtc, RegOff + D1SCL_HVSCALE, 0x00010001); /* both h/v */
RHDRegWrite(Crtc, RegOff + D1SCL_TAP_CONTROL, 0x00000101);
RHDRegWrite(Crtc, RegOff + D1SCL_HFILTER, 0x00030100);
RHDRegWrite(Crtc, RegOff + D1SCL_VFILTER, 0x00030100);
RHDRegWrite(Crtc, RegOff + D1SCL_DITHER, 0x00001010);
break;
}
RHDMCTuneAccessForDisplay(rhdPtr, Crtc->Id, Mode,
ScaledToMode ? ScaledToMode : Mode);
}
/*
*
*/
static void
DxScaleSave(struct rhdCrtc *Crtc)
{
struct rhdCrtcScalePrivate *ScalePriv;
CARD32 RegOff;
if (!Crtc->ScalePriv)
ScalePriv = xnfcalloc(1, sizeof(struct rhdCrtcScalePrivate));
else
ScalePriv = Crtc->ScalePriv;
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
ScalePriv->StoreModeViewPortSize = RHDRegRead(Crtc, RegOff + D1MODE_VIEWPORT_SIZE);
ScalePriv->StoreModeViewPortStart = RHDRegRead(Crtc, RegOff + D1MODE_VIEWPORT_START);
ScalePriv->StoreModeOverScanH =
RHDRegRead(Crtc, RegOff + D1MODE_EXT_OVERSCAN_LEFT_RIGHT);
ScalePriv->StoreModeOverScanV =
RHDRegRead(Crtc, RegOff + D1MODE_EXT_OVERSCAN_TOP_BOTTOM);
ScalePriv->StoreScaleEnable = RHDRegRead(Crtc, RegOff + D1SCL_ENABLE);
ScalePriv->StoreScaleTapControl = RHDRegRead(Crtc, RegOff + D1SCL_TAP_CONTROL);
ScalePriv->StoreModeCenter = RHDRegRead(Crtc, RegOff + D1MODE_CENTER);
ScalePriv->StoreScaleHV = RHDRegRead(Crtc, RegOff + D1SCL_HVSCALE);
ScalePriv->StoreScaleHFilter = RHDRegRead(Crtc, RegOff + D1SCL_HFILTER);
ScalePriv->StoreScaleVFilter = RHDRegRead(Crtc, RegOff + D1SCL_VFILTER);
ScalePriv->StoreScaleDither = RHDRegRead(Crtc, RegOff + D1SCL_DITHER);
Crtc->ScalePriv = ScalePriv;
}
/*
*
*/
static void
DxScaleRestore(struct rhdCrtc *Crtc)
{
struct rhdCrtcScalePrivate *ScalePriv = Crtc->ScalePriv;
CARD32 RegOff;
if (!ScalePriv) {
xf86DrvMsg(Crtc->scrnIndex, X_ERROR, "%s: no registers stored!\n",
__func__);
return;
}
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
/* ScaleSet */
RHDRegWrite(Crtc, RegOff + D1MODE_VIEWPORT_SIZE, ScalePriv->StoreModeViewPortSize);
/* ScaleSet/ViewPortStart */
RHDRegWrite(Crtc, RegOff + D1MODE_VIEWPORT_START, ScalePriv->StoreModeViewPortStart);
/* ScaleSet */
RHDRegWrite(Crtc, RegOff + D1MODE_EXT_OVERSCAN_LEFT_RIGHT,
ScalePriv->StoreModeOverScanH);
RHDRegWrite(Crtc, RegOff + D1MODE_EXT_OVERSCAN_TOP_BOTTOM,
ScalePriv->StoreModeOverScanV);
RHDRegWrite(Crtc, RegOff + D1SCL_ENABLE, ScalePriv->StoreScaleEnable);
RHDRegWrite(Crtc, RegOff + D1SCL_TAP_CONTROL, ScalePriv->StoreScaleTapControl);
RHDRegWrite(Crtc, RegOff + D1MODE_CENTER, ScalePriv->StoreModeCenter);
RHDRegWrite(Crtc, RegOff + D1SCL_HVSCALE, ScalePriv->StoreScaleHV);
RHDRegWrite(Crtc, RegOff + D1SCL_HFILTER, ScalePriv->StoreScaleHFilter);
RHDRegWrite(Crtc, RegOff + D1SCL_VFILTER, ScalePriv->StoreScaleVFilter);
RHDRegWrite(Crtc, RegOff + D1SCL_DITHER, ScalePriv->StoreScaleDither);
}
/*
*
*/
static void
DxScaleDestroy(struct rhdCrtc *Crtc)
{
RHDFUNC(Crtc);
if (Crtc->ScalePriv)
xfree(Crtc->ScalePriv);
Crtc->ScalePriv = NULL;
}
/*
*
*/
static void
D1LUTSelect(struct rhdCrtc *Crtc, struct rhdLUT *LUT)
{
RHDFUNC(Crtc);
RHDRegWrite(Crtc, D1GRPH_LUT_SEL, LUT->Id & 1);
Crtc->LUT = LUT;
}
/*
*
*/
static void
D2LUTSelect(struct rhdCrtc *Crtc, struct rhdLUT *LUT)
{
RHDFUNC(Crtc);
RHDRegWrite(Crtc, D2GRPH_LUT_SEL, LUT->Id & 1);
Crtc->LUT = LUT;
}
/*
*
*/
static void
DxLUTSave(struct rhdCrtc *Crtc)
{
struct rhdCrtcLUTPrivate *LUTPriv;
CARD32 RegOff;
if (!Crtc->LUTPriv)
LUTPriv = xnfcalloc(1, sizeof(struct rhdCrtcLUTPrivate));
else
LUTPriv = Crtc->LUTPriv;
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
LUTPriv->StoreGrphLutSel = RHDRegRead(Crtc, RegOff + D1GRPH_LUT_SEL);
Crtc->LUTPriv = LUTPriv;
}
/*
*
*/
static void
DxLUTRestore(struct rhdCrtc *Crtc)
{
struct rhdCrtcLUTPrivate *LUTPriv = Crtc->LUTPriv;
CARD32 RegOff;
if (!LUTPriv) {
xf86DrvMsg(Crtc->scrnIndex, X_ERROR, "%s: no registers stored!\n",
__func__);
return;
}
if (Crtc->Id == RHD_CRTC_1)
RegOff = D1_REG_OFFSET;
else
RegOff = D2_REG_OFFSET;
/* LUTSelect */
RHDRegWrite(Crtc, RegOff + D1GRPH_LUT_SEL, LUTPriv->StoreGrphLutSel);
}
/*
*
*/
static void
DxLUTDestroy(struct rhdCrtc *Crtc)
{
RHDFUNC(Crtc);
if (Crtc->LUTPriv)
xfree(Crtc->LUTPriv);
Crtc->LUTPriv = NULL;
}
/*
*
*/
static void
D1ViewPortStart(struct rhdCrtc *Crtc, CARD16 X, CARD16 Y)
{
RHDFUNC(Crtc);
/* not as granular as docs make it seem to be.
* if the lower two bits are set the line buffer might screw up, requiring
* a power cycle. */
X = (X + 0x02) & ~0x03;
Y &= ~0x01;
RHDRegMask(Crtc, D1SCL_UPDATE, 0x00010000, 0x0001000);
RHDRegWrite(Crtc, D1MODE_VIEWPORT_START, (X << 16) | Y);
RHDRegMask(Crtc, D1SCL_UPDATE, 0, 0x0001000);
Crtc->X = X;
Crtc->Y = Y;
}
/*
*
*/
static void
D2ViewPortStart(struct rhdCrtc *Crtc, CARD16 X, CARD16 Y)
{
RHDFUNC(Crtc);
/* not as granular as docs make it seem to be. */
X = (X + 0x02) & ~0x03;
Y &= ~0x01;
RHDRegMask(Crtc, D2SCL_UPDATE, 0x00010000, 0x0001000);
RHDRegWrite(Crtc, D2MODE_VIEWPORT_START, (X << 16) | Y);
RHDRegMask(Crtc, D2SCL_UPDATE, 0, 0x0001000);
Crtc->X = X;
Crtc->Y = Y;
}
#define CRTC_SYNC_WAIT 0x100000
/*
*
*/
static Bool
D1CRTCDisable(struct rhdCrtc *Crtc)
{
if (RHDRegRead(Crtc, D1CRTC_CONTROL) & 0x00000001) {
CARD32 Control = RHDRegRead(Crtc, D1CRTC_CONTROL);
int i;
RHDRegMask(Crtc, D1CRTC_CONTROL, 0, 0x00000301);
(void)RHDRegRead(Crtc, D1CRTC_CONTROL);
for (i = 0; i < CRTC_SYNC_WAIT; i++)
if (!(RHDRegRead(Crtc, D1CRTC_CONTROL) & 0x00010000)) {
RHDDebug(Crtc->scrnIndex, "%s: %d loops\n", __func__, i);
RHDRegMask(Crtc, D1CRTC_CONTROL, Control, 0x00000300);
return TRUE;
}
xf86DrvMsg(Crtc->scrnIndex, X_ERROR,
"%s: Failed to Unsync %s\n", __func__, Crtc->Name);
RHDRegMask(Crtc, D1CRTC_CONTROL, Control, 0x00000300);
return FALSE;
}
return TRUE;
}
/*
*
*/
static Bool
D2CRTCDisable(struct rhdCrtc *Crtc)
{
if (RHDRegRead(Crtc, D2CRTC_CONTROL) & 0x00000001) {
CARD32 Control = RHDRegRead(Crtc, D2CRTC_CONTROL);
int i;
RHDRegMask(Crtc, D2CRTC_CONTROL, 0, 0x00000301);
(void)RHDRegRead(Crtc, D2CRTC_CONTROL);
for (i = 0; i < CRTC_SYNC_WAIT; i++)
if (!(RHDRegRead(Crtc, D2CRTC_CONTROL) & 0x00010000)) {
RHDDebug(Crtc->scrnIndex, "%s: %d loops\n", __func__, i);
RHDRegMask(Crtc, D2CRTC_CONTROL, Control, 0x00000300);
return TRUE;
}
xf86DrvMsg(Crtc->scrnIndex, X_ERROR,
"%s: Failed to Unsync %s\n", __func__, Crtc->Name);
RHDRegMask(Crtc, D2CRTC_CONTROL, Control, 0x00000300);
return FALSE;
}
return TRUE;
}
/*
*
*/
static Bool
D1Power(struct rhdCrtc *Crtc, int Power)
{
Bool ret;
RHDFUNC(Crtc);
switch (Power) {
case RHD_POWER_ON:
RHDRegMask(Crtc, D1GRPH_ENABLE, 0x00000001, 0x00000001);
usleep(2);
RHDRegMask(Crtc, D1CRTC_CONTROL, 0, 0x01000000); /* enable read requests */
RHDRegMask(Crtc, D1CRTC_CONTROL, 1, 1);
return TRUE;
case RHD_POWER_RESET:
RHDRegMask(Crtc, D1CRTC_CONTROL, 0x01000000, 0x01000000); /* disable read requests */
return D1CRTCDisable(Crtc);
case RHD_POWER_SHUTDOWN:
default:
RHDRegMask(Crtc, D1CRTC_CONTROL, 0x01000000, 0x01000000); /* disable read requests */
ret = D1CRTCDisable(Crtc);
RHDRegMask(Crtc, D1GRPH_ENABLE, 0, 0x00000001);
return ret;
}
}
/*
*
*/
static Bool
D2Power(struct rhdCrtc *Crtc, int Power)
{
Bool ret;
RHDFUNC(Crtc);
switch (Power) {
case RHD_POWER_ON:
RHDRegMask(Crtc, D2GRPH_ENABLE, 0x00000001, 0x00000001);
usleep(2);
RHDRegMask(Crtc, D2CRTC_CONTROL, 0, 0x01000000); /* enable read requests */
RHDRegMask(Crtc, D2CRTC_CONTROL, 1, 1);
return TRUE;
case RHD_POWER_RESET:
RHDRegMask(Crtc, D2CRTC_CONTROL, 0x01000000, 0x01000000); /* disable read requests */
return D2CRTCDisable(Crtc);
case RHD_POWER_SHUTDOWN:
default:
RHDRegMask(Crtc, D2CRTC_CONTROL, 0x01000000, 0x01000000); /* disable read requests */
ret = D2CRTCDisable(Crtc);
RHDRegMask(Crtc, D2GRPH_ENABLE, 0, 0x00000001);
return ret;
}
}
/*
* This is quite different from Power. Power disables and enables things,
* this here makes the hw send out black, and can switch back and forth
* immediately. Useful for covering up a framebuffer that is not filled
* in yet.
*/
static void
D1Blank(struct rhdCrtc *Crtc, Bool Blank)
{
RHDFUNC(Crtc);
RHDRegWrite(Crtc, D1CRTC_BLACK_COLOR, 0);
if (Blank)
RHDRegMask(Crtc, D1CRTC_BLANK_CONTROL, 0x00000100, 0x00000100);
else
RHDRegMask(Crtc, D1CRTC_BLANK_CONTROL, 0, 0x00000100);
}
/*
*
*/
static void
D2Blank(struct rhdCrtc *Crtc, Bool Blank)
{
RHDFUNC(Crtc);
RHDRegWrite(Crtc, D2CRTC_BLACK_COLOR, 0);
if (Blank)
RHDRegMask(Crtc, D2CRTC_BLANK_CONTROL, 0x00000100, 0x00000100);
else
RHDRegMask(Crtc, D2CRTC_BLANK_CONTROL, 0, 0x00000100);
}
/*
*
*/
static void
DxFMTSet(struct rhdCrtc *Crtc, struct rhdFMTDither *FMTDither)
{
CARD32 RegOff;
CARD32 fmt_cntl = 0;
RHDFUNC(Crtc);
if (Crtc->Id == RHD_CRTC_1)
RegOff = FMT1_REG_OFFSET;
else
RegOff = FMT2_REG_OFFSET;
if (FMTDither) {
/* set dither depth to 18/24 */
fmt_cntl = FMTDither->LVDS24Bit
? (RV62_FMT_SPATIAL_DITHER_DEPTH | RV62_FMT_TEMPORAL_DITHER_DEPTH)
: 0;
RHDRegMask(Crtc, RegOff + RV620_FMT1_BIT_DEPTH_CONTROL, fmt_cntl,
RV62_FMT_SPATIAL_DITHER_DEPTH | RV62_FMT_TEMPORAL_DITHER_DEPTH);
/* set temporal dither */
if (FMTDither->LVDSTemporalDither) {
fmt_cntl = FMTDither->LVDSGreyLevel ? RV62_FMT_TEMPORAL_LEVEL : 0x0;
/* grey level */
RHDRegMask(Crtc, RegOff + RV620_FMT1_BIT_DEPTH_CONTROL,
fmt_cntl, RV62_FMT_TEMPORAL_LEVEL);
/* turn on temporal dither and reset */
RHDRegMask(Crtc, RegOff + RV620_FMT1_BIT_DEPTH_CONTROL,
RV62_FMT_TEMPORAL_DITHER_EN | RV62_FMT_TEMPORAL_DITHER_RESET,
RV62_FMT_TEMPORAL_DITHER_EN | RV62_FMT_TEMPORAL_DITHER_RESET);
usleep(20);
/* turn off reset */
RHDRegMask(Crtc, RegOff + RV620_FMT1_BIT_DEPTH_CONTROL, 0x0,
RV62_FMT_TEMPORAL_DITHER_RESET);
}
/* spatial dither */
RHDRegMask(Crtc, RegOff + RV620_FMT1_BIT_DEPTH_CONTROL,
FMTDither->LVDSSpatialDither ? RV62_FMT_SPATIAL_DITHER_EN : 0,
RV62_FMT_SPATIAL_DITHER_EN);
} else
RHDRegWrite(Crtc, RegOff + RV620_FMT1_BIT_DEPTH_CONTROL, 0);
/* 4:4:4 encoding */
RHDRegMask(Crtc, RegOff + RV620_FMT1_CONTROL, 0, RV62_FMT_PIXEL_ENCODING);
/* disable color clamping */
RHDRegWrite(Crtc, RegOff + RV620_FMT1_CLAMP_CNTL, 0);
}
/*
*
*/
static void
DxFMTSave(struct rhdCrtc *Crtc)
{
struct rhdCrtcFMTPrivate *FMTPrivate;
CARD32 RegOff;
RHDFUNC(Crtc);
if (!Crtc->FMTPriv)
FMTPrivate = xnfcalloc(sizeof (struct rhdCrtcFMTPrivate),1);
else
FMTPrivate = Crtc->FMTPriv;
if (Crtc->Id == RHD_CRTC_1)
RegOff = FMT1_REG_OFFSET;
else
RegOff = FMT2_REG_OFFSET;
FMTPrivate->StoreControl = RHDRegRead(Crtc, RegOff + RV620_FMT1_CONTROL);
FMTPrivate->StoreBitDepthControl = RHDRegRead(Crtc, RegOff + RV620_FMT1_BIT_DEPTH_CONTROL);
FMTPrivate->StoreClampCntl = RHDRegRead(Crtc, RegOff + RV620_FMT1_CLAMP_CNTL);
Crtc->FMTPriv = FMTPrivate;
}
/*
*
*/
static void
DxFMTRestore(struct rhdCrtc *Crtc)
{
struct rhdCrtcFMTPrivate *FMTPrivate = Crtc->FMTPriv;
CARD32 RegOff;
RHDFUNC(Crtc);
if (!FMTPrivate)
return;
if (Crtc->Id == RHD_CRTC_1)
RegOff = FMT1_REG_OFFSET;
else
RegOff = FMT2_REG_OFFSET;
RHDRegWrite(Crtc, RegOff + RV620_FMT1_CONTROL, FMTPrivate->StoreControl);
RHDRegWrite(Crtc, RegOff + RV620_FMT1_BIT_DEPTH_CONTROL, FMTPrivate->StoreBitDepthControl);
RHDRegWrite(Crtc, RegOff + RV620_FMT1_CLAMP_CNTL, FMTPrivate->StoreClampCntl);
}
/*
*
*/
static void
DxFMTDestroy(struct rhdCrtc *Crtc)
{
RHDFUNC(Crtc);
if (Crtc->FMTPriv)
xfree(Crtc->FMTPriv);
Crtc->FMTPriv = NULL;
}
/*
*
*/
static enum rhdCrtcScaleType
rhdInitScaleType(RHDPtr rhdPtr)
{
RHDFUNC(rhdPtr);
/*
if (rhdPtr->scaleTypeOpt.set) {
if (!strcasecmp(rhdPtr->scaleTypeOpt.val.string, "none"))
return RHD_CRTC_SCALE_TYPE_NONE;
else if (!strcasecmp(rhdPtr->scaleTypeOpt.val.string, "center"))
return RHD_CRTC_SCALE_TYPE_CENTER;
else if (!strcasecmp(rhdPtr->scaleTypeOpt.val.string, "scale"))
return RHD_CRTC_SCALE_TYPE_SCALE;
else if (!strcasecmp(rhdPtr->scaleTypeOpt.val.string, "scale_keep_aspect_ratio"))
return RHD_CRTC_SCALE_TYPE_SCALE_KEEP_ASPECT_RATIO;
else if (!strcasecmp(rhdPtr->scaleTypeOpt.val.string, "default"))
return RHD_CRTC_SCALE_TYPE_DEFAULT;
else {
xf86DrvMsgVerb(rhdPtr->scrnIndex, X_ERROR, 0,
"Unknown scale type: %s\n", rhdPtr->scaleTypeOpt.val.string);
return RHD_CRTC_SCALE_TYPE_DEFAULT;
}
} else */
return RHD_CRTC_SCALE_TYPE_SCALE;
}
/*
*
*/
Bool
RHDCrtcsInit(RHDPtr rhdPtr)
{
struct rhdCrtc *Crtc;
enum rhdCrtcScaleType ScaleType;
Bool useAtom;
RHDFUNC(rhdPtr);
useAtom = RHDUseAtom(rhdPtr, NULL, atomUsageCrtc);
ScaleType = rhdInitScaleType(rhdPtr);
Crtc = xnfcalloc(sizeof(struct rhdCrtc), 1);
Crtc->scrnIndex = rhdPtr->scrnIndex;
Crtc->Name = "CRTC 1";
Crtc->Id = RHD_CRTC_1;
Crtc->ScaleType = ScaleType;
if (rhdPtr->ChipSet >= RHD_RV620) {
Crtc->FMTDestroy = DxFMTDestroy;
Crtc->FMTSave = DxFMTSave;
Crtc->FMTRestore = DxFMTRestore;
Crtc->FMTModeSet = DxFMTSet;
}
Crtc->FMTPriv = NULL;
Crtc->FBValid = DxFBValid;
Crtc->FBSet = DxFBSet;
Crtc->FBSave = DxFBSave;
Crtc->FBRestore = DxFBRestore;
Crtc->FBDestroy = DxFBDestroy;
Crtc->ModeValid = DxModeValid;
Crtc->ModeSet = DxModeSet;
Crtc->ModeSave = DxModeSave;
Crtc->ModeRestore = DxModeRestore;
Crtc->ModeDestroy = DxModeDestroy;
Crtc->ModePriv = NULL;
Crtc->ScaleValid = DxScaleValid;
Crtc->ScaleSet = DxScaleSet;
Crtc->ScaleSave = DxScaleSave;
Crtc->ScaleRestore = DxScaleRestore;
Crtc->ScaleDestroy = DxScaleDestroy;
Crtc->ScalePriv = NULL;
Crtc->LUTSelect = D1LUTSelect;
Crtc->LUTSave = DxLUTSave;
Crtc->LUTRestore = DxLUTRestore;
Crtc->LUTDestroy = DxLUTDestroy;
Crtc->LUTPriv = NULL;
Crtc->FrameSet = D1ViewPortStart;
Crtc->Power = D1Power;
Crtc->Blank = D1Blank;
rhdPtr->Crtc[0] = Crtc;
Crtc = xnfcalloc(sizeof(struct rhdCrtc), 1);
Crtc->scrnIndex = rhdPtr->scrnIndex;
Crtc->Name = "CRTC 2";
Crtc->Id = RHD_CRTC_2;
Crtc->ScaleType = ScaleType;
if (rhdPtr->ChipSet >= RHD_RV620) {
Crtc->FMTDestroy = DxFMTDestroy;
Crtc->FMTSave = DxFMTSave;
Crtc->FMTRestore = DxFMTRestore;
Crtc->FMTModeSet = DxFMTSet;
}
Crtc->FMTPriv = NULL;
Crtc->FBValid = DxFBValid;
Crtc->FBSet = DxFBSet;
Crtc->FBSave = DxFBSave;
Crtc->FBRestore = DxFBRestore;
Crtc->FBDestroy = DxFBDestroy;
Crtc->ModeValid = DxModeValid;
Crtc->ModeSet = DxModeSet;
Crtc->ModeSave = DxModeSave;
Crtc->ModeRestore = DxModeRestore;
Crtc->ModeDestroy = DxModeDestroy;
Crtc->ModePriv = NULL;
Crtc->ScaleValid = DxScaleValid;
Crtc->ScaleSet = DxScaleSet;
Crtc->ScaleSave = DxScaleSave;
Crtc->ScaleRestore = DxScaleRestore;
Crtc->ScaleDestroy = DxScaleDestroy;
Crtc->ScalePriv = NULL;
Crtc->LUTSelect = D2LUTSelect;
Crtc->LUTSave = DxLUTSave;
Crtc->LUTRestore = DxLUTRestore;
Crtc->LUTDestroy = DxLUTDestroy;
Crtc->LUTPriv = NULL;
Crtc->FrameSet = D2ViewPortStart;
Crtc->Power = D2Power;
Crtc->Blank = D2Blank;
rhdPtr->Crtc[1] = Crtc;
return !useAtom;
}
/*
*
*/
void
RHDCrtcsDestroy(RHDPtr rhdPtr)
{
struct rhdCrtc *Crtc;
int i;
RHDFUNC(rhdPtr);
for (i = 0; i < 2; i++) {
Crtc = rhdPtr->Crtc[i];
if (Crtc) {
if (Crtc->FMTDestroy)
Crtc->FMTDestroy(Crtc);
if (Crtc->LUTDestroy)
Crtc->LUTDestroy(Crtc);
if (Crtc->FBDestroy)
Crtc->FBDestroy(Crtc);
if (Crtc->ScaleDestroy)
Crtc->ScaleDestroy(Crtc);
if (Crtc->ModeDestroy)
Crtc->ModeDestroy(Crtc);
xfree(Crtc);
rhdPtr->Crtc[i] = NULL;
}
}
}
/*
*
*/
void
RHDCrtcSave(struct rhdCrtc *Crtc)
{
RHDDebug(Crtc->scrnIndex, "%s: %s\n", __func__, Crtc->Name);
if (Crtc->FMTSave)
Crtc->FMTSave(Crtc);
if (Crtc->FBSave)
Crtc->FBSave(Crtc);
if (Crtc->LUTSave)
Crtc->LUTSave(Crtc);
if (Crtc->ScaleSave)
Crtc->ScaleSave(Crtc);
if (Crtc->ModeSave)
Crtc->ModeSave(Crtc);
}
/*
*
*/
void
RHDCrtcRestore(struct rhdCrtc *Crtc)
{
RHDDebug(Crtc->scrnIndex, "%s: %s\n", __func__, Crtc->Name);
if (Crtc->FMTRestore)
Crtc->FMTRestore(Crtc);
if (Crtc->FBRestore)
Crtc->FBRestore(Crtc);
if (Crtc->LUTRestore)
Crtc->LUTRestore(Crtc);
if (Crtc->ScaleRestore)
Crtc->ScaleRestore(Crtc);
if (Crtc->ModeRestore)
Crtc->ModeRestore(Crtc);
}