/******************************Module*Header*******************************\ * * ******************* * * GDI SAMPLE CODE * * ******************* * * Module Name: bltmm.c * * Contains the low-level memory-mapped IO blt functions. This module * mirrors 'bltio.c'. * * Hopefully, if you're basing your display driver on this code, to * support all of DrvBitBlt and DrvCopyBits, you'll only have to implement * the following routines. You shouldn't have to modify much in * 'bitblt.c'. I've tried to make these routines as few, modular, simple, * and efficient as I could, while still accelerating as many calls as * possible that would be cost-effective in terms of performance wins * versus size and effort. * * Note: In the following, 'relative' coordinates refers to coordinates * that haven't yet had the offscreen bitmap (DFB) offset applied. * 'Absolute' coordinates have had the offset applied. For example, * we may be told to blt to (1, 1) of the bitmap, but the bitmap may * be sitting in offscreen memory starting at coordinate (0, 768) -- * (1, 1) would be the 'relative' start coordinate, and (1, 769) * would be the 'absolute' start coordinate'. * * Copyright (c) 1992-1998 Microsoft Corporation * \**************************************************************************/ #include "precomp.h" /******************************Public*Routine******************************\ * VOID vMmImageTransferMm16 * * Low-level routine for transferring a bitmap image via the data transfer * register using 16 bit writes and entirely memory-mapped I/O. * * NOTE: Upon entry, there must be 1 guaranteed free empty FIFO! * \**************************************************************************/ VOID vMmImageTransferMm16( // Type FNIMAGETRANSFER PDEV* ppdev, BYTE* pjSrc, // Source pointer LONG lDelta, // Delta from start of scan to start of next LONG cjSrc, // Number of bytes to be output on every scan LONG cScans, // Number of scans ULONG ulCmd) // Accelerator command - shouldn't include bus size { BYTE* pjMmBase; LONG cwSrc; ASSERTDD(cScans > 0, "Can't handle non-positive count of scans"); ASSERTDD((ulCmd & (BUS_SIZE_8 | BUS_SIZE_16 | BUS_SIZE_32)) == 0, "Shouldn't specify bus size in command -- we handle that"); IO_GP_WAIT(ppdev); pjMmBase = ppdev->pjMmBase; MM_CMD(ppdev, pjMmBase, ulCmd | BUS_SIZE_16); CHECK_DATA_READY(ppdev); cwSrc = (cjSrc) >> 1; // Floor if (cjSrc & 1) { do { if (cwSrc > 0) { MM_TRANSFER_WORD(ppdev, pjMmBase, pjSrc, cwSrc); } // Make sure we do only a byte read of the last odd byte // in the scan so that we'll never read past the end of // the bitmap: MM_PIX_TRANS(ppdev, pjMmBase, *(pjSrc + cjSrc - 1)); pjSrc += lDelta; } while (--cScans != 0); } else { do { MM_TRANSFER_WORD(ppdev, pjMmBase, pjSrc, cwSrc); pjSrc += lDelta; } while (--cScans != 0); } CHECK_DATA_COMPLETE(ppdev); } /******************************Public*Routine******************************\ * VOID vMmImageTransferMm32 * * Low-level routine for transferring a bitmap image via the data transfer * register using 32 bit writes and entirely memory-mapped I/O. * * NOTE: Upon entry, there must be 1 guaranteed free empty FIFO! * \**************************************************************************/ VOID vMmImageTransferMm32( // Type FNIMAGETRANSFER PDEV* ppdev, BYTE* pjSrc, // Source pointer LONG lDelta, // Delta from start of scan to start of next LONG cjSrc, // Number of bytes to be output on every scan LONG cScans, // Number of scans ULONG ulCmd) // Accelerator command - shouldn't include bus size { BYTE* pjMmBase; LONG cdSrc; LONG cjEnd; ULONG d; ASSERTDD(cScans > 0, "Can't handle non-positive count of scans"); ASSERTDD((ulCmd & (BUS_SIZE_8 | BUS_SIZE_16 | BUS_SIZE_32)) == 0, "Shouldn't specify bus size in command -- we handle that"); IO_GP_WAIT(ppdev); pjMmBase = ppdev->pjMmBase; MM_CMD(ppdev, pjMmBase, ulCmd | BUS_SIZE_32); CHECK_DATA_READY(ppdev); cdSrc = cjSrc >> 2; cjEnd = cdSrc << 2; switch (cjSrc & 3) { case 3: do { if (cdSrc > 0) MM_TRANSFER_DWORD(ppdev, pjMmBase, pjSrc, cdSrc); d = (ULONG) (*(pjSrc + cjEnd)) | (*(pjSrc + cjEnd + 1) << 8) | (*(pjSrc + cjEnd + 2) << 16); MM_TRANSFER_DWORD(ppdev, pjMmBase, &d, 1); pjSrc += lDelta; } while (--cScans != 0); break; case 2: do { if (cdSrc > 0) MM_TRANSFER_DWORD(ppdev, pjMmBase, pjSrc, cdSrc); d = (ULONG) (*(pjSrc + cjEnd)) | (*(pjSrc + cjEnd + 1) << 8); MM_TRANSFER_DWORD(ppdev, pjMmBase, &d, 1); pjSrc += lDelta; } while (--cScans != 0); break; case 1: do { if (cdSrc > 0) MM_TRANSFER_DWORD(ppdev, pjMmBase, pjSrc, cdSrc); d = (ULONG) (*(pjSrc + cjEnd)); MM_TRANSFER_DWORD(ppdev, pjMmBase, &d, 1); pjSrc += lDelta; } while (--cScans != 0); break; case 0: do { MM_TRANSFER_DWORD(ppdev, pjMmBase, pjSrc, cdSrc); pjSrc += lDelta; } while (--cScans != 0); break; } CHECK_DATA_COMPLETE(ppdev); } /******************************Public*Routine******************************\ * VOID vMmFillSolid * * Fills a list of rectangles with a solid colour. * \**************************************************************************/ VOID vMmFillSolid( // Type FNFILL PDEV* ppdev, LONG c, // Can't be zero RECTL* prcl, // List of rectangles to be filled, in relative // coordinates ULONG rop4, // rop4 RBRUSH_COLOR rbc, // Drawing colour is rbc.iSolidColor POINTL* pptlBrush) // Not used { BYTE* pjMmBase = ppdev->pjMmBase; ULONG ulHwForeMix; ASSERTDD(c > 0, "Can't handle zero rectangles"); ulHwForeMix = gaulHwMixFromRop2[(rop4 >> 2) & 0xf]; // It's quite likely that we've just been called from GDI, so it's // even more likely that the accelerator's graphics engine has been // sitting around idle. Rather than doing a FIFO_WAIT(3) here and // then a FIFO_WAIT(5) before outputing the actual rectangle, // we can avoid an 'in' (which can be quite expensive, depending on // the card) by doing a single FIFO_WAIT(8) right off the bat: IO_FIFO_WAIT(ppdev, 8); MM_PIX_CNTL(ppdev, pjMmBase, ALL_ONES); MM_FRGD_MIX(ppdev, pjMmBase, FOREGROUND_COLOR | ulHwForeMix); MM_FRGD_COLOR(ppdev, pjMmBase, rbc.iSolidColor); while(TRUE) { MM_CUR_X(ppdev, pjMmBase, prcl->left); MM_CUR_Y(ppdev, pjMmBase, prcl->top); MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, prcl->right - prcl->left - 1); MM_MIN_AXIS_PCNT(ppdev, pjMmBase, prcl->bottom - prcl->top - 1); MM_CMD(ppdev, pjMmBase, RECTANGLE_FILL | DRAWING_DIR_TBLRXM | DRAW | DIR_TYPE_XY | LAST_PIXEL_ON | MULTIPLE_PIXELS | WRITE); if (--c == 0) return; prcl++; IO_FIFO_WAIT(ppdev, 5); } } /******************************Public*Routine******************************\ * VOID vMmFastPatRealize * * This routine transfers an 8x8 pattern to off-screen display memory, * so that it can be used by the S3 pattern hardware. * \**************************************************************************/ VOID vMmFastPatRealize( // Type FNFASTPATREALIZE PDEV* ppdev, RBRUSH* prb, // Points to brush realization structure POINTL* pptlBrush, // Brush origin for aligning realization BOOL bTransparent) // FALSE for normal patterns; TRUE for // patterns with a mask when the background // mix is LEAVE_ALONE. { BRUSHENTRY* pbe; LONG iBrushCache; LONG x; LONG y; LONG i; LONG xShift; LONG yShift; BYTE* pjSrc; BYTE* pjDst; LONG cjLeft; LONG cjRight; BYTE* pjPattern; LONG cwPattern; ULONG aulBrush[TOTAL_BRUSH_SIZE]; // Temporary buffer for aligning brush. Declared // as an array of ULONGs to get proper dword // alignment. Also leaves room for brushes that // are up to 32bpp. Note: this takes up 1/4k! BYTE* pjMmBase = ppdev->pjMmBase; ASSERTDD(!(bTransparent && ppdev->iBitmapFormat == BMF_24BPP), "s3 diamond 968 at 24bpp doesn't support transparent FastPatRealize"); pbe = prb->pbe; if ((pbe == NULL) || (pbe->prbVerify != prb)) { // We have to allocate a new off-screen cache brush entry for // the brush: iBrushCache = ppdev->iBrushCache; pbe = &ppdev->abe[iBrushCache]; iBrushCache++; if (iBrushCache >= ppdev->cBrushCache) iBrushCache = 0; ppdev->iBrushCache = iBrushCache; // Update our links: pbe->prbVerify = prb; prb->pbe = pbe; } // Load some variables onto the stack, so that we don't have to keep // dereferencing their pointers: x = pbe->x; y = pbe->y; // Because we handle only 8x8 brushes, it is easy to compute the // number of pels by which we have to rotate the brush pattern // right and down. Note that if we were to handle arbitrary sized // patterns, this calculation would require a modulus operation. // // The brush is aligned in absolute coordinates, so we have to add // in the surface offset: xShift = pptlBrush->x + ppdev->xOffset; yShift = pptlBrush->y + ppdev->yOffset; prb->ptlBrushOrg.x = xShift; // We have to remember the alignment prb->ptlBrushOrg.y = yShift; // that we used for caching (we check // this when we go to see if a brush's // cache entry is still valid) xShift &= 7; // Rotate pattern 'xShift' pels right yShift &= 7; // Rotate pattern 'yShift' pels down prb->bTransparent = bTransparent; // I considered doing the colour expansion for 1bpp brushes in // software, but by letting the hardware do it, we don't have // to do as many OUTs to transfer the pattern. if (prb->fl & RBRUSH_2COLOR) { // We're going to do a colour-expansion ('across the plane') // bitblt of the 1bpp 8x8 pattern to the screen. But first // we'll align it properly by copying it to a temporary buffer // (which we'll conveniently pack word aligned so that we can do a // REP OUTSW...) pjSrc = (BYTE*) &prb->aulPattern[0]; // Copy from the start of the // brush buffer pjDst = (BYTE*) &aulBrush[0]; // Copy to our temp buffer pjDst += yShift * sizeof(WORD); // starting yShift rows down i = 8 - yShift; // for 8 - yShift rows do { *pjDst = (*pjSrc >> xShift) | (*pjSrc << (8 - xShift)); pjDst += sizeof(WORD); // Destination is word packed pjSrc += sizeof(WORD); // Source is word aligned too } while (--i != 0); pjDst -= 8 * sizeof(WORD); // Move to the beginning of the source ASSERTDD(pjDst == (BYTE*) &aulBrush[0], "pjDst not back at start"); for (; yShift != 0; yShift--) { *pjDst = (*pjSrc >> xShift) | (*pjSrc << (8 - xShift)); pjDst += sizeof(WORD); // Destination is word packed pjSrc += sizeof(WORD); // Source is word aligned too } if (bTransparent) { IO_FIFO_WAIT(ppdev, 3); MM_PIX_CNTL(ppdev, pjMmBase, CPU_DATA); MM_FRGD_MIX(ppdev, pjMmBase, LOGICAL_1); MM_BKGD_MIX(ppdev, pjMmBase, LOGICAL_0); } else { IO_FIFO_WAIT(ppdev, 5); MM_PIX_CNTL(ppdev, pjMmBase, CPU_DATA); MM_FRGD_MIX(ppdev, pjMmBase, FOREGROUND_COLOR | OVERPAINT); MM_BKGD_MIX(ppdev, pjMmBase, BACKGROUND_COLOR | OVERPAINT); MM_FRGD_COLOR(ppdev, pjMmBase, prb->ulForeColor); MM_BKGD_COLOR(ppdev, pjMmBase, prb->ulBackColor); } IO_FIFO_WAIT(ppdev, 4); MM_ABS_CUR_X(ppdev, pjMmBase, x); MM_ABS_CUR_Y(ppdev, pjMmBase, y); MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, 7); // Brush is 8 wide MM_MIN_AXIS_PCNT(ppdev, pjMmBase, 7); // Brush is 8 high IO_GP_WAIT(ppdev); MM_CMD(ppdev, pjMmBase, RECTANGLE_FILL | BUS_SIZE_16 | WAIT | DRAWING_DIR_TBLRXM | DRAW | LAST_PIXEL_ON | MULTIPLE_PIXELS | WRITE | BYTE_SWAP); CHECK_DATA_READY(ppdev); pjPattern = (BYTE*) &aulBrush[0]; MM_TRANSFER_WORD_ALIGNED(ppdev, pjMmBase, pjPattern, 8); // Each word transferred // comprises one row of the // pattern, and there are // 8 rows in the pattern CHECK_DATA_COMPLETE(ppdev); } else { ASSERTDD(!bTransparent, "Shouldn't have been asked for transparency with a non-1bpp brush"); // We're going to do a straight ('through the plane') bitblt // of the Xbpp 8x8 pattern to the screen. But first we'll align // it properly by copying it to a temporary buffer: cjLeft = CONVERT_TO_BYTES(xShift, ppdev); // Number of bytes pattern // is shifted to the right cjRight = CONVERT_TO_BYTES(8, ppdev) - // Number of bytes pattern cjLeft; // is shifted to the left pjSrc = (BYTE*) &prb->aulPattern[0]; // Copy from brush buffer pjDst = (BYTE*) &aulBrush[0]; // Copy to our temp buffer pjDst += yShift * CONVERT_TO_BYTES(8, ppdev); // starting yShift rows i = 8 - yShift; // down for 8 - yShift rows do { RtlCopyMemory(pjDst + cjLeft, pjSrc, cjRight); RtlCopyMemory(pjDst, pjSrc + cjRight, cjLeft); pjDst += cjLeft + cjRight; pjSrc += cjLeft + cjRight; } while (--i != 0); pjDst = (BYTE*) &aulBrush[0]; // Move to the beginning of destination for (; yShift != 0; yShift--) { RtlCopyMemory(pjDst + cjLeft, pjSrc, cjRight); RtlCopyMemory(pjDst, pjSrc + cjRight, cjLeft); pjDst += cjLeft + cjRight; pjSrc += cjLeft + cjRight; } IO_FIFO_WAIT(ppdev, 6); MM_PIX_CNTL(ppdev, pjMmBase, ALL_ONES); MM_FRGD_MIX(ppdev, pjMmBase, SRC_CPU_DATA | OVERPAINT); MM_ABS_CUR_X(ppdev, pjMmBase, x); MM_ABS_CUR_Y(ppdev, pjMmBase, y); MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, 7); // Brush is 8 wide MM_MIN_AXIS_PCNT(ppdev, pjMmBase, 7); // Brush is 8 high IO_GP_WAIT(ppdev); MM_CMD(ppdev, pjMmBase, RECTANGLE_FILL | BUS_SIZE_16| WAIT | DRAWING_DIR_TBLRXM | DRAW | LAST_PIXEL_ON | SINGLE_PIXEL | WRITE | BYTE_SWAP); CHECK_DATA_READY(ppdev); pjPattern = (BYTE*) &aulBrush[0]; cwPattern = CONVERT_TO_BYTES((TOTAL_BRUSH_SIZE / 2), ppdev); MM_TRANSFER_WORD_ALIGNED(ppdev, pjMmBase, pjPattern, cwPattern); CHECK_DATA_COMPLETE(ppdev); } } /******************************Public*Routine******************************\ * VOID vMmFillPatFast * * This routine uses the S3 pattern hardware to draw a patterned list of * rectangles. * \**************************************************************************/ VOID vMmFillPatFast( // Type FNFILL PDEV* ppdev, LONG c, // Can't be zero RECTL* prcl, // List of rectangles to be filled, in relative // coordinates ULONG rop4, // rop4 RBRUSH_COLOR rbc, // rbc.prb points to brush realization structure POINTL* pptlBrush) // Pattern alignment { BOOL bTransparent; ULONG ulHwForeMix; BRUSHENTRY* pbe; // Pointer to brush entry data, which is used // for keeping track of the location and status // of the pattern bits cached in off-screen // memory BYTE* pjMmBase = ppdev->pjMmBase; ASSERTDD(c > 0, "Can't handle zero rectangles"); ASSERTDD(ppdev->flCaps & CAPS_HW_PATTERNS, "Shouldn't use fast patterns when can't do hw patterns"); bTransparent = (((rop4 >> 8) & 0xff) != (rop4 & 0xff)); // The S3's pattern hardware requires that we keep an aligned copy // of the brush in off-screen memory. We have to update this // realization if any of the following are true: // // 1) The brush alignment has changed; // 2) The off-screen location we thought we had reserved for our // realization got overwritten by a different pattern; // 3) We had realized the pattern to do transparent hatches, but // we're now being asked to do an opaque pattern, or vice // versa (since we use different realizations for transparent // vs. opaque patterns). // // To handle the initial realization of a pattern, we're a little // tricky in order to save an 'if' in the following expression. In // DrvRealizeBrush, we set 'prb->ptlBrushOrg.x' to be 0x80000000 (a // very negative number), which is guaranteed not to equal 'pptlBrush->x // + ppdev->xOffset'. So our check for brush alignment will also // handle the initialization case (note that this check must occur // *before* dereferencing 'prb->pbe' because that pointer will be // NULL for a new pattern). if ((rbc.prb->ptlBrushOrg.x != pptlBrush->x + ppdev->xOffset) || (rbc.prb->ptlBrushOrg.y != pptlBrush->y + ppdev->yOffset) || (rbc.prb->pbe->prbVerify != rbc.prb) || (rbc.prb->bTransparent != bTransparent)) { vMmFastPatRealize(ppdev, rbc.prb, pptlBrush, bTransparent); } else if (ppdev->flCaps & CAPS_RE_REALIZE_PATTERN) { // The initial revs of the Vision chips have a bug where, if // we have not just drawn the pattern to off-screen memory, // we have to draw some sort of 1x8 rectangle before using // the pattern hardware (note that a LEAVE_ALONE rop will not // work). IO_FIFO_WAIT(ppdev, 7); MM_PIX_CNTL(ppdev, pjMmBase, ALL_ONES); MM_FRGD_MIX(ppdev, pjMmBase, SRC_DISPLAY_MEMORY | OVERPAINT); MM_ABS_CUR_X(ppdev, pjMmBase, ppdev->ptlReRealize.x); MM_ABS_CUR_Y(ppdev, pjMmBase, ppdev->ptlReRealize.y); MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, 0); MM_MIN_AXIS_PCNT(ppdev, pjMmBase, 7); MM_CMD(ppdev, pjMmBase, RECTANGLE_FILL | DRAWING_DIR_TBLRXM | DRAW | DIR_TYPE_XY | LAST_PIXEL_ON | MULTIPLE_PIXELS | WRITE); } ASSERTDD(rbc.prb->bTransparent == bTransparent, "Not realized with correct transparency"); pbe = rbc.prb->pbe; ulHwForeMix = gaulHwMixFromRop2[(rop4 >> 2) & 0xf]; if (!bTransparent) { IO_FIFO_WAIT(ppdev, 4); MM_ABS_CUR_X(ppdev, pjMmBase, pbe->x); MM_ABS_CUR_Y(ppdev, pjMmBase, pbe->y); MM_PIX_CNTL(ppdev, pjMmBase, ALL_ONES); MM_FRGD_MIX(ppdev, pjMmBase, SRC_DISPLAY_MEMORY | ulHwForeMix); } else { IO_FIFO_WAIT(ppdev, 7); MM_FRGD_COLOR(ppdev, pjMmBase, rbc.prb->ulForeColor); MM_RD_MASK(ppdev, pjMmBase, 1); // Pick a plane, any plane MM_ABS_CUR_X(ppdev, pjMmBase, pbe->x); MM_ABS_CUR_Y(ppdev, pjMmBase, pbe->y); MM_PIX_CNTL(ppdev, pjMmBase, DISPLAY_MEMORY); MM_FRGD_MIX(ppdev, pjMmBase, FOREGROUND_COLOR | ulHwForeMix); MM_BKGD_MIX(ppdev, pjMmBase, BACKGROUND_COLOR | LEAVE_ALONE); } do { IO_FIFO_WAIT(ppdev, 5); MM_DEST_X(ppdev, pjMmBase, prcl->left); MM_DEST_Y(ppdev, pjMmBase, prcl->top); MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, prcl->right - prcl->left - 1); MM_MIN_AXIS_PCNT(ppdev, pjMmBase, prcl->bottom - prcl->top - 1); MM_CMD(ppdev, pjMmBase, PATTERN_FILL | BYTE_SWAP | DRAWING_DIR_TBLRXM | DRAW | WRITE); prcl++; } while (--c != 0); } /******************************Public*Routine******************************\ * VOID vMmXfer1bpp * * This routine colour expands a monochrome bitmap, possibly with different * Rop2's for the foreground and background. It will be called in the * following cases: * * 1) To colour-expand the monochrome text buffer for the vFastText routine. * 2) To blt a 1bpp source with a simple Rop2 between the source and * destination. * 3) To blt a true Rop3 when the source is a 1bpp bitmap that expands to * white and black, and the pattern is a solid colour. * 4) To handle a true Rop4 that works out to be two Rop2's between the * pattern and destination. * * Needless to say, making this routine fast can leverage a lot of * performance. * \**************************************************************************/ VOID vMmXfer1bpp( // Type FNXFER PDEV* ppdev, LONG c, // Count of rectangles, can't be zero RECTL* prcl, // List of destination rectangles, in relative // coordinates ROP4 rop4, // rop4 SURFOBJ* psoSrc, // Source surface POINTL* pptlSrc, // Original unclipped source point RECTL* prclDst, // Original unclipped destination rectangle XLATEOBJ* pxlo) // Translate that provides colour-expansion information { ULONG ulHwForeMix; ULONG ulHwBackMix; LONG dxSrc; LONG dySrc; LONG cx; LONG cy; LONG lSrcDelta; BYTE* pjSrcScan0; BYTE* pjSrc; LONG cjSrc; LONG xLeft; LONG yTop; LONG xBias; BYTE* pjMmBase = ppdev->pjMmBase; ASSERTDD(c > 0, "Can't handle zero rectangles"); ASSERTDD(pptlSrc != NULL && psoSrc != NULL, "Can't have NULL sources"); ASSERTDD(((((rop4 & 0xff00) >> 8) == (rop4 & 0xff)) || (rop4 == 0xaacc)), "Expect weird rops only when opaquing"); // Note that only our text routine calls us with a '0xaacc' rop: ulHwForeMix = gaulHwMixFromRop2[rop4 & 0xf]; ulHwBackMix = (rop4 != 0xaacc) ? ulHwForeMix : LEAVE_ALONE; IO_FIFO_WAIT(ppdev, 5); MM_PIX_CNTL(ppdev, pjMmBase, CPU_DATA); MM_FRGD_MIX(ppdev, pjMmBase, FOREGROUND_COLOR | ulHwForeMix); MM_BKGD_MIX(ppdev, pjMmBase, BACKGROUND_COLOR | ulHwBackMix); MM_FRGD_COLOR(ppdev, pjMmBase, pxlo->pulXlate[1]); MM_BKGD_COLOR(ppdev, pjMmBase, pxlo->pulXlate[0]); dxSrc = pptlSrc->x - prclDst->left; dySrc = pptlSrc->y - prclDst->top; // Add to destination to get source lSrcDelta = psoSrc->lDelta; pjSrcScan0 = psoSrc->pvScan0; do { IO_FIFO_WAIT(ppdev, 5); // We'll byte align to the source, but do word transfers // (implying that we may be doing unaligned reads from the // source). We do this because it may reduce the total // number of word outs/writes that we'll have to do to the // display: yTop = prcl->top; xLeft = prcl->left; xBias = (xLeft + dxSrc) & 7; // This is the byte-align bias if (xBias != 0) { // We could either align in software or use the hardware to do // it. We'll use the hardware; the cost we pay is the time spent // setting and resetting one scissors register: MM_SCISSORS_L(ppdev, pjMmBase, xLeft); xLeft -= xBias; } cx = prcl->right - xLeft; cy = prcl->bottom - yTop; MM_CUR_X(ppdev, pjMmBase, xLeft); MM_CUR_Y(ppdev, pjMmBase, yTop); MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, cx - 1); MM_MIN_AXIS_PCNT(ppdev, pjMmBase, cy - 1); cjSrc = (cx + 7) >> 3; // # bytes to transfer pjSrc = pjSrcScan0 + (yTop + dySrc) * lSrcDelta + ((xLeft + dxSrc) >> 3); // Start is byte aligned (note // that we don't have to add // xBias) ppdev->pfnImageTransfer(ppdev, pjSrc, lSrcDelta, cjSrc, cy, (RECTANGLE_FILL | WAIT | DRAWING_DIR_TBLRXM | DRAW | LAST_PIXEL_ON | MULTIPLE_PIXELS | WRITE | BYTE_SWAP)); if (xBias != 0) { IO_FIFO_WAIT(ppdev, 1); // Reset the clipping if we used it MM_ABS_SCISSORS_L(ppdev, pjMmBase, 0); } prcl++; } while (--c != 0); } /******************************Public*Routine******************************\ * VOID vMmXfer4bpp * * Does a 4bpp transfer from a bitmap to the screen. * * NOTE: The screen must be 8bpp for this function to be called! * * The reason we implement this is that a lot of resources are kept as 4bpp, * and used to initialize DFBs, some of which we of course keep off-screen. * \**************************************************************************/ // XLATE_BUFFER_SIZE defines the size of the stack-based buffer we use // for doing the translate. Note that in general stack buffers should // be kept as small as possible. The OS guarantees us only 8k for stack // from GDI down to the display driver in low memory situations; if we // ask for more, we'll access violate. Note also that at any time the // stack buffer cannot be larger than a page (4k) -- otherwise we may // miss touching the 'guard page' and access violate then too. #define XLATE_BUFFER_SIZE 256 VOID vMmXfer4bpp( // Type FNXFER PDEV* ppdev, LONG c, // Count of rectangles, can't be zero RECTL* prcl, // List of destination rectangles, in relative // coordinates ULONG rop4, // rop4 SURFOBJ* psoSrc, // Source surface POINTL* pptlSrc, // Original unclipped source point RECTL* prclDst, // Original unclipped destination rectangle XLATEOBJ* pxlo) // Translate that provides colour-expansion information { LONG dx; LONG dy; LONG cx; LONG cy; LONG lSrcDelta; BYTE* pjSrcScan0; BYTE* pjScan; BYTE* pjSrc; BYTE* pjDst; LONG cxThis; LONG cxToGo; LONG xSrc; LONG iLoop; BYTE jSrc; ULONG* pulXlate; LONG cwThis; BYTE* pjBuf; BYTE ajBuf[XLATE_BUFFER_SIZE]; BYTE* pjMmBase = ppdev->pjMmBase; ASSERTDD(ppdev->iBitmapFormat == BMF_8BPP, "Screen must be 8bpp"); ASSERTDD(psoSrc->iBitmapFormat == BMF_4BPP, "Source must be 4bpp"); ASSERTDD(c > 0, "Can't handle zero rectangles"); ASSERTDD(((rop4 & 0xff00) >> 8) == (rop4 & 0xff), "Expect only a rop2"); dx = pptlSrc->x - prclDst->left; dy = pptlSrc->y - prclDst->top; // Add to destination to get source lSrcDelta = psoSrc->lDelta; pjSrcScan0 = psoSrc->pvScan0; IO_FIFO_WAIT(ppdev, 6); MM_PIX_CNTL(ppdev, pjMmBase, ALL_ONES); MM_FRGD_MIX(ppdev, pjMmBase, SRC_CPU_DATA | gaulHwMixFromRop2[rop4 & 0xf]); while(TRUE) { cx = prcl->right - prcl->left; cy = prcl->bottom - prcl->top; MM_CUR_X(ppdev, pjMmBase, prcl->left); MM_CUR_Y(ppdev, pjMmBase, prcl->top); MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, cx - 1); MM_MIN_AXIS_PCNT(ppdev, pjMmBase, cy - 1); pulXlate = pxlo->pulXlate; xSrc = prcl->left + dx; pjScan = pjSrcScan0 + (prcl->top + dy) * lSrcDelta + (xSrc >> 1); IO_GP_WAIT(ppdev); MM_CMD(ppdev, pjMmBase, RECTANGLE_FILL | BUS_SIZE_16| WAIT | DRAWING_DIR_TBLRXM | DRAW | LAST_PIXEL_ON | SINGLE_PIXEL | WRITE | BYTE_SWAP); CHECK_DATA_READY(ppdev); do { pjSrc = pjScan; cxToGo = cx; // # of pels per scan in 4bpp source do { cxThis = XLATE_BUFFER_SIZE; // We can handle XLATE_BUFFER_SIZE number // of pels in this xlate batch cxToGo -= cxThis; // cxThis will be the actual number of // pels we'll do in this xlate batch if (cxToGo < 0) cxThis += cxToGo; pjDst = ajBuf; // Points to our temporary batch buffer // We handle alignment ourselves because it's easy to // do, rather than pay the cost of setting/resetting // the scissors register: if (xSrc & 1) { // When unaligned, we have to be careful not to read // past the end of the 4bpp bitmap (that could // potentially cause us to access violate): iLoop = cxThis >> 1; // Each loop handles 2 pels; // we'll handle odd pel // separately jSrc = *pjSrc; while (iLoop-- != 0) { *pjDst++ = (BYTE) pulXlate[jSrc & 0xf]; jSrc = *(++pjSrc); *pjDst++ = (BYTE) pulXlate[jSrc >> 4]; } if (cxThis & 1) { *pjDst++ = (BYTE) pulXlate[jSrc & 0xf]; *pjDst = 0; } } else { iLoop = (cxThis + 1) >> 1; // Each loop handles 2 pels do { jSrc = *pjSrc++; *pjDst++ = (BYTE) pulXlate[jSrc >> 4]; *pjDst++ = (BYTE) pulXlate[jSrc & 0xf]; } while (--iLoop != 0); } // The number of bytes we'll transfer is equal to the number // of pels we've processed in the batch. Since we're // transferring words, we have to round up to get the word // count: cwThis = (cxThis + 1) >> 1; pjBuf = ajBuf; MM_TRANSFER_WORD_ALIGNED(ppdev, pjMmBase, pjBuf, cwThis); } while (cxToGo > 0); pjScan += lSrcDelta; // Advance to next source scan. Note // that we could have computed the // value to advance 'pjSrc' directly, // but this method is less // error-prone. } while (--cy != 0); CHECK_DATA_COMPLETE(ppdev); if (--c == 0) return; prcl++; IO_FIFO_WAIT(ppdev, 4); } } /******************************Public*Routine******************************\ * VOID vMmXferNative * * Transfers a bitmap that is the same colour depth as the display to * the screen via the data transfer register, with no translation. * \**************************************************************************/ VOID vMmXferNative( // Type FNXFER PDEV* ppdev, LONG c, // Count of rectangles, can't be zero RECTL* prcl, // Array of relative coordinates destination rectangles ROP4 rop4, // rop4 SURFOBJ* psoSrc, // Source surface POINTL* pptlSrc, // Original unclipped source point RECTL* prclDst, // Original unclipped destination rectangle XLATEOBJ* pxlo) // Not used { LONG dx; LONG dy; LONG cx; LONG cy; LONG lSrcDelta; BYTE* pjSrcScan0; BYTE* pjSrc; LONG cjSrc; BYTE* pjMmBase = ppdev->pjMmBase; ASSERTDD((pxlo == NULL) || (pxlo->flXlate & XO_TRIVIAL), "Can handle trivial xlate only"); ASSERTDD(psoSrc->iBitmapFormat == ppdev->iBitmapFormat, "Source must be same colour depth as screen"); ASSERTDD(c > 0, "Can't handle zero rectangles"); ASSERTDD(((rop4 & 0xff00) >> 8) == (rop4 & 0xff), "Expect only a rop2"); dx = pptlSrc->x - prclDst->left; dy = pptlSrc->y - prclDst->top; // Add to destination to get source lSrcDelta = psoSrc->lDelta; pjSrcScan0 = psoSrc->pvScan0; IO_FIFO_WAIT(ppdev, 6); MM_PIX_CNTL(ppdev, pjMmBase, ALL_ONES); MM_FRGD_MIX(ppdev, pjMmBase, SRC_CPU_DATA | gaulHwMixFromRop2[rop4 & 0xf]); while(TRUE) { MM_CUR_X(ppdev, pjMmBase, prcl->left); MM_CUR_Y(ppdev, pjMmBase, prcl->top); cx = prcl->right - prcl->left; MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, cx - 1); cy = prcl->bottom - prcl->top; MM_MIN_AXIS_PCNT(ppdev, pjMmBase, cy - 1); cjSrc = CONVERT_TO_BYTES(cx, ppdev); pjSrc = pjSrcScan0 + (prcl->top + dy) * lSrcDelta + CONVERT_TO_BYTES((prcl->left + dx), ppdev); ppdev->pfnImageTransfer(ppdev, pjSrc, lSrcDelta, cjSrc, cy, (RECTANGLE_FILL | WAIT | DRAWING_DIR_TBLRXM | DRAW | LAST_PIXEL_ON | SINGLE_PIXEL | WRITE | BYTE_SWAP)); if (--c == 0) return; prcl++; IO_FIFO_WAIT(ppdev, 4); } } /******************************Public*Routine******************************\ * VOID vMmCopyBlt * * Does a screen-to-screen blt of a list of rectangles. * \**************************************************************************/ VOID vMmCopyBlt( // Type FNCOPY PDEV* ppdev, LONG c, // Can't be zero RECTL* prcl, // Array of relative coordinates destination rectangles ULONG rop4, // rop4 POINTL* pptlSrc, // Original unclipped source point RECTL* prclDst) // Original unclipped destination rectangle { LONG dx; LONG dy; // Add delta to destination to get source LONG cx; LONG cy; // Size of current rectangle - 1 BYTE* pjMmBase = ppdev->pjMmBase; ASSERTDD(c > 0, "Can't handle zero rectangles"); ASSERTDD(((rop4 & 0xff00) >> 8) == (rop4 & 0xff), "Expect only a rop2"); IO_FIFO_WAIT(ppdev, 2); MM_FRGD_MIX(ppdev, pjMmBase, SRC_DISPLAY_MEMORY | gaulHwMixFromRop2[rop4 & 0xf]); MM_PIX_CNTL(ppdev, pjMmBase, ALL_ONES); dx = pptlSrc->x - prclDst->left; dy = pptlSrc->y - prclDst->top; // The accelerator may not be as fast at doing right-to-left copies, so // only do them when the rectangles truly overlap: if (!OVERLAP(prclDst, pptlSrc)) goto Top_Down_Left_To_Right; if (prclDst->top <= pptlSrc->y) { if (prclDst->left <= pptlSrc->x) { Top_Down_Left_To_Right: do { IO_FIFO_WAIT(ppdev, 7); cx = prcl->right - prcl->left - 1; MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, cx); MM_DEST_X(ppdev, pjMmBase, prcl->left); MM_CUR_X(ppdev, pjMmBase, prcl->left + dx); cy = prcl->bottom - prcl->top - 1; MM_MIN_AXIS_PCNT(ppdev, pjMmBase, cy); MM_DEST_Y(ppdev, pjMmBase, prcl->top); MM_CUR_Y(ppdev, pjMmBase, prcl->top + dy); MM_CMD(ppdev, pjMmBase, BITBLT | DRAW | DIR_TYPE_XY | WRITE | DRAWING_DIR_TBLRXM); prcl++; } while (--c != 0); } else { do { IO_FIFO_WAIT(ppdev, 7); cx = prcl->right - prcl->left - 1; MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, cx); MM_DEST_X(ppdev, pjMmBase, prcl->left + cx); MM_CUR_X(ppdev, pjMmBase, prcl->left + cx + dx); cy = prcl->bottom - prcl->top - 1; MM_MIN_AXIS_PCNT(ppdev, pjMmBase, cy); MM_DEST_Y(ppdev, pjMmBase, prcl->top); MM_CUR_Y(ppdev, pjMmBase, prcl->top + dy); MM_CMD(ppdev, pjMmBase, BITBLT | DRAW | DIR_TYPE_XY | WRITE | DRAWING_DIR_TBRLXM); prcl++; } while (--c != 0); } } else { if (prclDst->left <= pptlSrc->x) { do { IO_FIFO_WAIT(ppdev, 7); cx = prcl->right - prcl->left - 1; MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, cx); MM_DEST_X(ppdev, pjMmBase, prcl->left); MM_CUR_X(ppdev, pjMmBase, prcl->left + dx); cy = prcl->bottom - prcl->top - 1; MM_MIN_AXIS_PCNT(ppdev, pjMmBase, cy); MM_DEST_Y(ppdev, pjMmBase, prcl->top + cy); MM_CUR_Y(ppdev, pjMmBase, prcl->top + cy + dy); MM_CMD(ppdev, pjMmBase, BITBLT | DRAW | DIR_TYPE_XY | WRITE | DRAWING_DIR_BTLRXM); prcl++; } while (--c != 0); } else { do { IO_FIFO_WAIT(ppdev, 7); cx = prcl->right - prcl->left - 1; MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, cx); MM_DEST_X(ppdev, pjMmBase, prcl->left + cx); MM_CUR_X(ppdev, pjMmBase, prcl->left + cx + dx); cy = prcl->bottom - prcl->top - 1; MM_MIN_AXIS_PCNT(ppdev, pjMmBase, cy); MM_DEST_Y(ppdev, pjMmBase, prcl->top + cy); MM_CUR_Y(ppdev, pjMmBase, prcl->top + cy + dy); MM_CMD(ppdev, pjMmBase, BITBLT | DRAW | DIR_TYPE_XY | WRITE | DRAWING_DIR_BTRLXM); prcl++; } while (--c != 0); } } } /******************************Public*Routine******************************\ * VOID vMmCopyTransparent * * Does a screen-to-screen blt of a list of rectangles using a source * colorkey for transparency. * \**************************************************************************/ VOID vMmCopyTransparent( // Type FNCOPYTRANSPARENT PDEV* ppdev, LONG c, // Can't be zero RECTL* prcl, // Array of relative coordinates destination rectangles POINTL* pptlSrc, // Original unclipped source point RECTL* prclDst, // Original unclipped destination rectangle ULONG iColor) { LONG dx; LONG dy; // Add delta to destination to get source BYTE* pjMmBase = ppdev->pjMmBase; ASSERTDD(c > 0, "Can't handle zero rectangles"); // Note that we don't have to worry about overlapping blts, since GDI // will never allow those down to us. dx = pptlSrc->x - prclDst->left; dy = pptlSrc->y - prclDst->top; IO_FIFO_WAIT(ppdev, 4); MM_COLOR_CMP(ppdev, pjMmBase, iColor); MM_MULTIFUNC_CNTL(ppdev, pjMmBase, ppdev->ulMiscState | MULT_MISC_COLOR_COMPARE); MM_FRGD_MIX(ppdev, pjMmBase, SRC_DISPLAY_MEMORY | OVERPAINT); MM_PIX_CNTL(ppdev, pjMmBase, ALL_ONES); while (TRUE) { IO_FIFO_WAIT(ppdev, 7); MM_CUR_X(ppdev, pjMmBase, prcl->left + dx); MM_CUR_Y(ppdev, pjMmBase, prcl->top + dy); MM_DEST_X(ppdev, pjMmBase, prcl->left); MM_DEST_Y(ppdev, pjMmBase, prcl->top); MM_MAJ_AXIS_PCNT(ppdev, pjMmBase, prcl->right - prcl->left - 1); MM_MIN_AXIS_PCNT(ppdev, pjMmBase, prcl->bottom - prcl->top - 1); MM_CMD(ppdev, pjMmBase, BITBLT | DRAW | DIR_TYPE_XY | WRITE | DRAWING_DIR_TBLRXM); if (--c == 0) { IO_FIFO_WAIT(ppdev, 1); MM_MULTIFUNC_CNTL(ppdev, pjMmBase, ppdev->ulMiscState); return; } prcl++; } }