/* * Copyright 2006 Red Hat, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software") * to deal in the software without restriction, including without limitation * on the rights to use, copy, modify, merge, publish, distribute, sub * license, and/or sell copies of the Software, and to permit persons to whom * them Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTIBILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. 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. * * Authors: * Adam Jackson */ /* * Sources: * - mga kdrive accel by Anders Carlsson * - mga g400 Render accel by Damien Ciabrini */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "xf86.h" #include "mga.h" #include "mga_reg.h" #include "mga_macros.h" #include "exa.h" #ifdef XF86DRI #include "mga_dri.h" #endif #include "xf86PciInfo.h" #if 0 #define DEBUG_MSG(x) ErrorF x #else #define DEBUG_MSG(x) #endif #define PMGA(x) \ MGAPtr pMga = xf86Screens[x->drawable.pScreen->myNum]->driverPrivate; /* FIXME: is this correct? */ #define QUIESCE_DMA(x) \ CHECK_DMA_QUIESCENT(pMga, xf86Screens[x->drawable.pScreen->myNum]); /* stuff stolen from mga_storm.c */ #define BLIT_LEFT 1 #define BLIT_UP 4 static const CARD32 mgaRop[16] = { /* GXclear */ MGADWG_RPL | 0x00000000, /* 0 */ /* GXand */ MGADWG_RSTR | 0x00080000, /* src AND dst */ /* GXandReverse */ MGADWG_RSTR | 0x00040000, /* src AND NOT dst */ /* GXcopy */ MGADWG_RSTR | 0x000c0000, /* src */ /* GXandInverted */ MGADWG_RSTR | 0x00020000, /* NOT src AND dst */ /* GXnoop */ MGADWG_RSTR | 0x000a0000, /* dst */ /* GXxor */ MGADWG_RSTR | 0x00060000, /* src XOR dst */ /* GXor */ MGADWG_RSTR | 0x000e0000, /* src OR dst */ /* GXnor */ MGADWG_RSTR | 0x00010000, /* NOT src AND NOT dst */ /* GXequiv */ MGADWG_RSTR | 0x00090000, /* NOT src XOR dst */ /* GXinvert */ MGADWG_RSTR | 0x00050000, /* NOT dst */ /* GXorReverse */ MGADWG_RSTR | 0x000d0000, /* src OR NOT dst */ /* GXcopyInverted */ MGADWG_RPL | 0x00030000, /* NOT src */ /* GXorInverted */ MGADWG_RSTR | 0x000b0000, /* NOT src OR dst */ /* GXnand */ MGADWG_RSTR | 0x00070000, /* NOT src OR NOT dst */ /* GXset */ MGADWG_RPL | 0x000f0000 /* 1 */ }; static const CARD32 atype[16] = { MGADWG_RPL | 0x00000000, MGADWG_RSTR | 0x00080000, MGADWG_RSTR | 0x00040000, MGADWG_BLK | 0x000c0000, MGADWG_RSTR | 0x00020000, MGADWG_RSTR | 0x000a0000, MGADWG_RSTR | 0x00060000, MGADWG_RSTR | 0x000e0000, MGADWG_RSTR | 0x00010000, MGADWG_RSTR | 0x00090000, MGADWG_RSTR | 0x00050000, MGADWG_RSTR | 0x000d0000, MGADWG_RPL | 0x00030000, MGADWG_RSTR | 0x000b0000, MGADWG_RSTR | 0x00070000, MGADWG_RPL | 0x000f0000 }; static const CARD32 atype_noblk[16] = { MGADWG_RPL | 0x00000000, MGADWG_RSTR | 0x00080000, MGADWG_RSTR | 0x00040000, MGADWG_RPL | 0x000c0000, MGADWG_RSTR | 0x00020000, MGADWG_RSTR | 0x000a0000, MGADWG_RSTR | 0x00060000, MGADWG_RSTR | 0x000e0000, MGADWG_RSTR | 0x00010000, MGADWG_RSTR | 0x00090000, MGADWG_RSTR | 0x00050000, MGADWG_RSTR | 0x000d0000, MGADWG_RPL | 0x00030000, MGADWG_RSTR | 0x000b0000, MGADWG_RSTR | 0x00070000, MGADWG_RPL | 0x000f0000 }; static const struct { Bool dst_alpha; Bool src_alpha; CARD32 blend_cntl; } mgaBlendOp[] = { /* Clear */ {0, 0, MGA_SRC_ZERO | MGA_DST_ZERO}, /* Src */ {0, 0, MGA_SRC_ONE | MGA_DST_ZERO}, /* Dst */ {0, 0, MGA_SRC_ZERO | MGA_DST_ONE}, /* Over */ {0, 1, MGA_SRC_ONE | MGA_DST_ONE_MINUS_SRC_ALPHA}, /* OverReverse */ {1, 0, MGA_SRC_ONE_MINUS_DST_ALPHA | MGA_DST_ONE}, /* In */ {1, 0, MGA_SRC_DST_ALPHA | MGA_DST_ZERO}, /* InReverse */ {0, 1, MGA_SRC_ZERO | MGA_DST_SRC_ALPHA}, /* Out */ {1, 0, MGA_SRC_ONE_MINUS_DST_ALPHA | MGA_DST_ZERO}, /* OutReverse */ {0, 1, MGA_SRC_ZERO | MGA_DST_ONE_MINUS_SRC_ALPHA}, /* Atop */ {1, 1, MGA_SRC_DST_ALPHA | MGA_DST_ONE_MINUS_SRC_ALPHA}, /* AtopReverse */ {1, 1, MGA_SRC_ONE_MINUS_DST_ALPHA | MGA_DST_SRC_ALPHA}, /* Xor */ {1, 1, MGA_SRC_ONE_MINUS_DST_ALPHA | MGA_DST_ONE_MINUS_SRC_ALPHA}, /* Add */ {0, 0, MGA_SRC_ONE | MGA_DST_ONE}, }; static const struct { int fmt; CARD32 card_fmt; } texformats[] = { { PICT_a8r8g8b8, MGA_TW32 }, { PICT_x8r8g8b8, MGA_TW32 }, { PICT_r5g6b5, MGA_TW16 }, { PICT_a1r5g5b5, MGA_TW15 }, { PICT_x1r5g5b5, MGA_TW15 }, { PICT_a4r4g4b4, MGA_TW12 }, { PICT_x4r4g4b4, MGA_TW12 }, { PICT_a8, MGA_TW8A }, }; static CARD32 mgaGetPixmapPitch(PixmapPtr pPix) { return exaGetPixmapPitch(pPix) / (pPix->drawable.bitsPerPixel >> 3); } static Bool mgaSetup(MGAPtr pMga, int dest_bpp, int wait) { unsigned int maccess = 0; static const unsigned int maccess_table[5] = { 0, /* dummy */ 0, /* 8 bpp, PW8 */ 1, /* 16 bpp, PW16 */ 3, /* 24 bpp, PW24 */ 2, /* 32 bpp, PW32 */ }; WAITFIFO(wait + 4); /* Set the format of the destination pixmap. * Taken from MGAStormEngineInit(). */ maccess |= maccess_table[dest_bpp / 8]; OUTREG(MGAREG_MACCESS, maccess); OUTREG(MGAREG_CXBNDRY, 0xffff0000); OUTREG(MGAREG_YTOP, 0x00000000); OUTREG(MGAREG_YBOT, 0x007fffff); return TRUE; } static void mgaNoopDone(PixmapPtr pPixmap) { } static Bool mgaPrepareSolid(PixmapPtr pPixmap, int alu, Pixel planemask, Pixel fg) { PMGA(pPixmap); QUIESCE_DMA(pPixmap); /* We must pad planemask and fg depending on the format of the * destination pixmap */ switch (pPixmap->drawable.bitsPerPixel) { case 8: fg |= fg << 8; planemask |= planemask << 8; /* fall through */ case 16: fg |= fg << 16; planemask |= planemask << 16; break; } pMga->FilledRectCMD = MGADWG_TRAP | MGADWG_SOLID | MGADWG_ARZERO | MGADWG_SGNZERO | MGADWG_SHIFTZERO | mgaRop[alu]; mgaSetup(pMga, pPixmap->drawable.bitsPerPixel, 5); OUTREG(MGAREG_PITCH, mgaGetPixmapPitch(pPixmap)); OUTREG(MGAREG_DSTORG, exaGetPixmapOffset(pPixmap)); OUTREG(MGAREG_FCOL, fg); OUTREG(MGAREG_PLNWT, planemask); OUTREG(MGAREG_DWGCTL, pMga->FilledRectCMD); return TRUE; } static void mgaSolid(PixmapPtr pPixmap, int x1, int y1, int x2, int y2) { PMGA(pPixmap); WAITFIFO(2); OUTREG(MGAREG_FXBNDRY, (x2 << 16) | (x1 & 0xffff)); OUTREG(MGAREG_YDSTLEN | MGAREG_EXEC, (y1 << 16) | (y2 - y1)); } static Bool mgaPrepareCopy(PixmapPtr pSrc, PixmapPtr pDst, int xdir, int ydir, int alu, Pixel planemask) { PMGA(pSrc); int blit_direction = 0; int dwgctl = 0; QUIESCE_DMA(pSrc); DEBUG_MSG(("s: %x@%x d: %x@%x xdir %d ydir %d alu %d pm %d\n", exaGetPixmapOffset(pSrc), exaGetPixmapPitch(pSrc), exaGetPixmapOffset(pDst), exaGetPixmapPitch(pDst), xdir, ydir, alu, planemask)); if (xdir < 0) blit_direction |= BLIT_LEFT; if (ydir < 0) blit_direction |= BLIT_UP; pMga->BltScanDirection = blit_direction; dwgctl = mgaRop[alu] | MGADWG_SHIFTZERO | MGADWG_BITBLT | MGADWG_BFCOL; pMga->src_pitch = mgaGetPixmapPitch(pSrc); mgaSetup(pMga, pDst->drawable.bitsPerPixel, 7); OUTREG(MGAREG_PITCH, mgaGetPixmapPitch(pDst)); OUTREG(MGAREG_SRCORG, exaGetPixmapOffset(pSrc)); OUTREG(MGAREG_DSTORG, exaGetPixmapOffset(pDst)); OUTREG(MGAREG_DWGCTL, dwgctl); OUTREG(MGAREG_SGN, blit_direction); OUTREG(MGAREG_PLNWT, planemask); OUTREG(MGAREG_AR5, (ydir < -0 ? -1 : 1) * pMga->src_pitch); return TRUE; } static void mgaCopy(PixmapPtr pDst, int srcx, int srcy, int dstx, int dsty, int w, int h) { PMGA(pDst); int start, end; DEBUG_MSG((" %d,%d -> %d,%d %dx%d\n", srcx, srcy, dstx,dsty, w, h)); w--; if (pMga->BltScanDirection & BLIT_UP) { srcy += h - 1; dsty += h - 1; } start = end = srcy * pMga->src_pitch + srcx; if (pMga->BltScanDirection & BLIT_LEFT) start += w; else end += w; DEBUG_MSG((" end %d start %d dstx %d dsty %d w %d h %d\n", end, start, dstx, dsty, w, h)); WAITFIFO(4); OUTREG(MGAREG_AR0, end); OUTREG(MGAREG_AR3, start); OUTREG(MGAREG_FXBNDRY, ((dstx + w) << 16) | (dstx & 0xffff)); OUTREG(MGAREG_YDSTLEN | MGAREG_EXEC, (dsty << 16) | h); } static int MGA_LOG2(int val) { int ret = 0; if (val == 1) return 0; while (val >> ret) ret++; return ((1 << (ret - 1)) == val) ? (ret - 1) : ret; } static Bool mgaCheckSourceTexture(int tmu, PicturePtr pPict) { int w = pPict->pDrawable->width; int h = pPict->pDrawable->height; int i; CARD32 texctl = 0; if ((w > 2047) || (h > 2047)){ DEBUG_MSG(("Picture w/h too large (%dx%d)\n", w, h)); return FALSE; } for (i = 0; i < sizeof(texformats) / sizeof(texformats[0]); i++) { if (texformats[i].fmt == pPict->format) { texctl = texformats[i].card_fmt; break; } } if (texctl == 0) { DEBUG_MSG(("Unsupported picture format 0x%x\n", pPict->format)); return FALSE; } if (pPict->repeat && ((w & (w - 1)) != 0 || (h & (h - 1)) != 0)) { DEBUG_MSG(("NPOT repeat unsupported (%dx%d)\n", w, h)); return FALSE; } if (pPict->filter != PictFilterNearest && pPict->filter != PictFilterBilinear) { DEBUG_MSG(("Unsupported filter 0x%x\n", pPict->filter)); return FALSE; } return TRUE; } static Bool mgaCheckComposite(int op, PicturePtr pSrcPict, PicturePtr pMaskPict, PicturePtr pDstPict) { if (op >= sizeof(mgaBlendOp) / sizeof(mgaBlendOp[0])) { DEBUG_MSG(("unsupported op %x\n", op)); return FALSE; } if (!mgaCheckSourceTexture(0, pSrcPict)) return FALSE; if (pMaskPict) { if (PICT_FORMAT_A(pMaskPict->format) == 0) { DEBUG_MSG(("Mask without alpha unsupported\n")); return FALSE; } if (!mgaCheckSourceTexture(1, pMaskPict)) return FALSE; if (pMaskPict->componentAlpha) { DEBUG_MSG(("Component alpha unsupported\n")); return FALSE; } } switch (pDstPict->format) { case PICT_a8: DEBUG_MSG(("render to A8 unsupported\n")); return FALSE; default: break; } return TRUE; } static Bool PrepareSourceTexture(int tmu, PicturePtr pSrcPicture, PixmapPtr pSrc) { PMGA(pSrc); int i; int pitch = mgaGetPixmapPitch(pSrc); int w = pSrc->drawable.width; int h = pSrc->drawable.height; int w_log2 = MGA_LOG2(w); int h_log2 = MGA_LOG2(h); int texctl = MGA_PITCHLIN | ((pitch & (2048 - 1)) << 9) | MGA_CLAMPUV | MGA_NOPERSPECTIVE; int flags = 0; int texctl2 = MGA_G400_TC2_MAGIC | flags; for (i = 0; i < sizeof(texformats) / sizeof(texformats[0]); i++) { if (texformats[i].fmt == pSrcPicture->format) { texctl |= texformats[i].card_fmt; break; } } if (PICT_FORMAT_A(pSrcPicture->format) != 0) { texctl |= MGA_TAKEY; } else { texctl |= MGA_TAMASK | MGA_TAKEY; } if (pSrcPicture->repeat) { texctl &= ~MGA_CLAMPUV; } if (tmu == 1) texctl2 |= MGA_TC2_DUALTEX | MGA_TC2_SELECT_TMU1 | flags; WAITFIFO(6); OUTREG(MGAREG_TEXCTL2, texctl2); OUTREG(MGAREG_TEXCTL, texctl); /* Source (texture) address + pitch */ OUTREG(MGAREG_TEXORG, exaGetPixmapOffset(pSrc)); OUTREG(MGAREG_TEXWIDTH, (w-1)<<18 | ((8-w_log2)&63)<<9 | w_log2); OUTREG(MGAREG_TEXHEIGHT, (h-1)<<18 | ((8-h_log2)&63)<<9 | h_log2); /* Set blit filtering flags */ if (pSrcPicture->filter == PictFilterBilinear) OUTREG(MGAREG_TEXFILTER, (0x10<<21) | MGA_MAG_BILIN | MGA_MIN_BILIN); else OUTREG(MGAREG_TEXFILTER, (0x10<<21) | MGA_MAG_NRST | MGA_MIN_NRST); if (tmu == 1) { WAITFIFO(1); OUTREG(MGAREG_TEXCTL2, MGA_G400_TC2_MAGIC | MGA_TC2_DUALTEX | flags); } return TRUE; } /* * The formals params are the elements of the following matrix: * * Dest Transform Src * coords coords * / Xdst \ / X_incx X_incy X_init \ / Xsrc \ * | Ydst | = | Y_incx Y_incy Y_init | x | Ysrc | * \ 1 / \ H_incx H_incy H_init / \ 1 / * * matrix elements are 32bits fixed points (16.16) * mga_fx_* is the size of the fixed point for the TMU */ static void setTMIncrementsRegs(PixmapPtr pPix, int X_incx, int X_incy, int X_init, int Y_incx, int Y_incy, int Y_init, int H_incx, int H_incy, int H_init, int mga_fx_width_size, int mga_fx_height_size) { PMGA(pPix); int decalw = mga_fx_width_size - 16; int decalh = mga_fx_height_size - 16; /* Convert 16 bits fixpoint -> MGA variable size fixpoint */ if (decalw >= 0) { X_incx = X_incx << decalw; X_incy = X_incy << decalw; X_init = X_init << decalw; } else { decalw =- decalw; X_incx = X_incx >> decalw; X_incy = X_incy >> decalw; X_init = X_init >> decalw; } /* Convert 16 bits fixpoint -> MGA variable size fixpoint */ if (decalh >= 0) { Y_incx = Y_incx << decalh; Y_incy = Y_incy << decalh; Y_init = Y_init << decalh; } else { decalh =- decalh; Y_incx = Y_incx >> decalh; Y_incy = Y_incy >> decalh; Y_init = Y_init >> decalh; } /* Set TM registers */ WAITFIFO(9); OUTREG(MGAREG_TMR0, X_incx); OUTREG(MGAREG_TMR1, Y_incx); OUTREG(MGAREG_TMR2, X_incy); OUTREG(MGAREG_TMR3, Y_incy); OUTREG(MGAREG_TMR4, H_incx); OUTREG(MGAREG_TMR5, H_incy); OUTREG(MGAREG_TMR6, X_init); OUTREG(MGAREG_TMR7, Y_init); OUTREG(MGAREG_TMR8, H_init); } /* XXX these look like magic */ #define C_ARG1_CUR 0x0 #define C_ARG1_ALPHA MGA_TDS_COLOR_ARG1_REPLICATEALPHA #define C_ARG2_DIFFUSE MGA_TDS_COLOR_ARG2_DIFFUSE #define C_ARG2_FCOL MGA_TDS_COLOR_ARG2_FCOL #define C_ARG2_PREV MGA_TDS_COLOR_ARG2_PREVSTAGE #define C_ARG1_INV MGA_TDS_COLOR_ARG1_INV #define C_ARG2_INV MGA_TDS_COLOR_ARG2_INV #define COLOR_MUL MGA_TDS_COLOR_SEL_MUL #define COLOR_ARG1 MGA_TDS_COLOR_SEL_ARG1 #define COLOR_ARG2 MGA_TDS_COLOR_SEL_ARG2 #define A_ARG1_CUR 0x0 #define A_ARG2_IGN A_ARG2_DIFFUSE #define A_ARG2_FCOL MGA_TDS_ALPHA_ARG2_FCOL #define A_ARG2_DIFFUSE MGA_TDS_ALPHA_ARG2_DIFFUSE #define A_ARG2_PREV MGA_TDS_ALPHA_ARG2_PREVSTAGE #define ALPHA_MUL MGA_TDS_ALPHA_SEL_MUL #define ALPHA_ARG1 MGA_TDS_ALPHA_SEL_ARG1 #define ALPHA_ARG2 MGA_TDS_ALPHA_SEL_ARG2 static Bool mgaPrepareComposite(int op, PicturePtr pSrcPict, PicturePtr pMaskPict, PicturePtr pDstPict, PixmapPtr pSrc, PixmapPtr pMask, PixmapPtr pDst) { PMGA(pDst); CARD32 ds0 = 0, ds1 = 0, cmd, blendcntl; mgaSetup(pMga, pDst->drawable.bitsPerPixel, 3); OUTREG(MGAREG_FCOL, 0xff000000); OUTREG(MGAREG_DSTORG, exaGetPixmapOffset(pDst)); OUTREG(MGAREG_PITCH, mgaGetPixmapPitch(pDst)); if (!PrepareSourceTexture(0, pSrcPict, pSrc)) return FALSE; if (pMask && !PrepareSourceTexture(1, pMaskPict, pMask)) return FALSE; if (pSrcPict->format == PICT_a8) { /* C = 0 A = As */ /* MGA HW: A8 format makes RGB white. We use FCOL for the black * If FCOL was not 0, it would have been be premultiplied (RENDER) * color component would have been: * C_ARG1_ALPHA | C_ARG2_FCOL | COLOR_MUL */ ds0 = C_ARG2_FCOL | COLOR_ARG2 | A_ARG1_CUR | ALPHA_ARG1; /* MGA HW: TMU1 must be enabled when DUALSTAGE0 contains something */ if (!pMask) { if (!PrepareSourceTexture(1, pSrcPict, pSrc)) return FALSE; ds1 = C_ARG2_PREV | COLOR_ARG2 | A_ARG2_PREV | ALPHA_ARG2; } } else { /* C = Cs A = As */ ds0 = C_ARG1_CUR | COLOR_ARG1 | A_ARG1_CUR | ALPHA_ARG1; } if (pMask) { /* As or Am might be NULL. in this case we don't multiply because, * the alpha component holds garbage. */ int color, alpha; if (PICT_FORMAT_A(pMaskPict->format) == 0) { /* C = Cs */ color = C_ARG2_PREV | COLOR_ARG2; } else { /* C = Am * Cs */ color = C_ARG1_ALPHA | C_ARG2_PREV | COLOR_MUL; } if (PICT_FORMAT_A(pMaskPict->format) == 0) { /* A = As */ alpha = A_ARG2_PREV | ALPHA_ARG2; } else if (PICT_FORMAT_A(pSrcPict->format) == 0) { /* A = Am */ alpha = A_ARG1_CUR | ALPHA_ARG1; } else { /* A = Am * As */ alpha = A_ARG1_CUR | A_ARG2_PREV | ALPHA_MUL; } ds1 = color | alpha; } cmd = MGADWG_TEXTURE_TRAP | MGADWG_I | 0x000c0000 | MGADWG_SHIFTZERO | MGADWG_SGNZERO | MGADWG_ARZERO; blendcntl = mgaBlendOp[op].blend_cntl; if (PICT_FORMAT_A(pDstPict->format) == 0 && mgaBlendOp[op].dst_alpha) { if ((blendcntl & MGA_SRC_BLEND_MASK) == MGA_SRC_DST_ALPHA) blendcntl = (blendcntl & ~MGA_SRC_BLEND_MASK) | MGA_SRC_ONE; else if ((blendcntl&MGA_SRC_BLEND_MASK) == MGA_SRC_ONE_MINUS_DST_ALPHA) blendcntl = (blendcntl & ~MGA_SRC_BLEND_MASK) | MGA_SRC_ZERO; } WAITFIFO(4); OUTREG(MGAREG_TDUALSTAGE0, ds0); OUTREG(MGAREG_TDUALSTAGE1, ds1); OUTREG(MGAREG_DWGCTL, cmd); OUTREG(MGAREG_ALPHACTRL, MGA_ALPHACHANNEL | blendcntl); pMga->currentSrcPicture = pSrcPict; pMga->currentMaskPicture = pMaskPict; pMga->currentSrc = pSrc; pMga->currentMask = pMask; pMga->src_w2 = MGA_LOG2 (pSrc->drawable.width); pMga->src_h2 = MGA_LOG2 (pSrc->drawable.height); if (pMask) { pMga->mask_w2 = MGA_LOG2 (pMask->drawable.width); pMga->mask_h2 = MGA_LOG2 (pMask->drawable.height); } return TRUE; } static void mgaComposite(PixmapPtr pDst, int srcx, int srcy, int maskx, int masky, int dstx, int dsty, int w, int h) { PMGA(pDst); PictTransformPtr t; srcx %= pMga->currentSrc->drawable.width; srcy %= pMga->currentSrc->drawable.height; if (pMga->currentMask) { maskx %= pMga->currentMask->drawable.width; masky %= pMga->currentMask->drawable.height; } t = pMga->currentSrcPicture->transform; if (t) setTMIncrementsRegs(pMga->currentSrc, t->matrix[0][0], t->matrix[0][1], t->matrix[0][2] + (srcx << 16), t->matrix[1][0], t->matrix[1][1], t->matrix[1][2] + (srcy << 16), t->matrix[2][0], t->matrix[2][1], t->matrix[2][2], 20 - pMga->src_w2, 20 - pMga->src_h2); else setTMIncrementsRegs(pMga->currentSrc, 1 << 16, 0, srcx << 16, 0, 1 << 16, srcy << 16, 0, 0, 1 << 16, 20 - pMga->src_w2, 20 - pMga->src_h2); if (pMga->currentMask) { WAITFIFO(1); OUTREG(MGAREG_TEXCTL2, MGA_G400_TC2_MAGIC | MGA_TC2_DUALTEX | MGA_TC2_SELECT_TMU1); t = pMga->currentMaskPicture->transform; if (t) setTMIncrementsRegs(pMga->currentMask, t->matrix[0][0], t->matrix[0][1], t->matrix[0][2] + (maskx << 16), t->matrix[1][0], t->matrix[1][1], t->matrix[1][2] + (masky << 16), t->matrix[2][0], t->matrix[2][1], t->matrix[2][2], 20 - pMga->mask_w2, 20 - pMga->mask_h2); else setTMIncrementsRegs(pMga->currentMask, 1 << 16, 0, maskx << 16, 0, 1 << 16, masky << 16, 0, 0, 1 << 16, 20 - pMga->mask_w2, 20 - pMga->mask_h2); WAITFIFO(1); OUTREG(MGAREG_TEXCTL2, MGA_G400_TC2_MAGIC | MGA_TC2_DUALTEX); } WAITFIFO(2); OUTREG(MGAREG_FXBNDRY, ((dstx + w) << 16) | (dstx & 0xffff)); OUTREG(MGAREG_YDSTLEN | MGAREG_EXEC, (dsty << 16) | (h & 0xffff)); } static Bool mgaUploadToScreen(PixmapPtr pDst, int x, int y, int w, int h, char *src, int src_pitch) { return FALSE; } static Bool mgaDownloadFromScreen(PixmapPtr pSrc, int x, int y, int w, int h, char *dst, int dst_pitch) { return FALSE; } static void mgaWaitMarker(ScreenPtr pScreen, int marker) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; MGAPtr pMga = pScrn->driverPrivate; WAITFIFO(1); OUTREG(MGAREG_CACHEFLUSH, 0); /* wait until the "drawing engine busy" bit is unset */ while (INREG (MGAREG_Status) & 0x10000); } Bool mgaExaInit(ScreenPtr pScreen) { ExaDriverPtr pExa; ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; MGAPtr pMga = pScrn->driverPrivate; pExa = exaDriverAlloc(); if (!pExa) { pMga->NoAccel = TRUE; return FALSE; } pMga->ExaDriver = pExa; pExa->exa_major = EXA_VERSION_MAJOR; pExa->exa_minor = EXA_VERSION_MINOR; pExa->flags = EXA_OFFSCREEN_PIXMAPS | EXA_OFFSCREEN_ALIGN_POT; pExa->memoryBase = pMga->FbStart; pExa->memorySize = pMga->FbUsableSize - 4096; pExa->offScreenBase = (pScrn->virtualX * pScrn->virtualY * pScrn->bitsPerPixel/8) + 4096; xf86DrvMsg(pScrn->scrnIndex, X_INFO, "X %d Y %d bpp %d\n", pScrn->virtualX, pScrn->virtualY, pScrn->bitsPerPixel); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Start at %p, size %x, osb %x\n", pExa->memoryBase, pExa->memorySize, pExa->offScreenBase); /* In PW24 mode, we need to align to "3 64-bytes" */ pExa->pixmapOffsetAlign = 192; /* Pitch alignment is in sets of 32 pixels, and we need to cover * 32bpp, so it's 128 bytes. */ pExa->pixmapPitchAlign = 128; pExa->maxX = 2048; pExa->maxY = 2048; pExa->WaitMarker = mgaWaitMarker; pExa->PrepareSolid = mgaPrepareSolid; pExa->Solid = mgaSolid; pExa->DoneSolid = mgaNoopDone; pExa->PrepareCopy = mgaPrepareCopy; pExa->Copy = mgaCopy; pExa->DoneCopy = mgaNoopDone; if (pMga->Chipset >= PCI_CHIP_MGAG400) { pExa->CheckComposite = mgaCheckComposite; pExa->PrepareComposite = mgaPrepareComposite; pExa->Composite = mgaComposite; pExa->DoneComposite = mgaNoopDone; } if (0) { pExa->DownloadFromScreen = mgaDownloadFromScreen; pExa->UploadToScreen = mgaUploadToScreen; } /* XXX fill in the XAA setup code here */ #if 0 if(pMga->HasSDRAM) { pMga->Atype = pMga->AtypeNoBLK = atype_noblk; } else { pMga->Atype = atype; pMga->AtypeNoBLK = atype_noblk; } #endif return exaDriverInit(pScreen, pExa); }