/******************************************************************************\ * * $Workfile: fastfill.c $ * * Fast routine for drawing polygons that aren't complex in shape. * * Copyright (c) 1993-1997 Microsoft Corporation * Copyright (c) 1996-1997 Cirrus Logic, Inc., * * $Log: S:/projects/drivers/ntsrc/display/fastfill.c_v $ * * Rev 1.5 28 Jan 1997 13:46:30 PLCHU * * * Rev 1.3 10 Jan 1997 15:39:44 PLCHU * * * Rev 1.2 Nov 07 1996 16:48:02 unknown * * * Rev 1.1 Oct 10 1996 15:37:30 unknown * * * Rev 1.1 12 Aug 1996 16:53:14 frido * Removed unaccessed local variables. * * chu01 : 01-02-97 5480 BitBLT enhancement * \******************************************************************************/ #include "precomp.h" #define RIGHT 0 #define LEFT 1 typedef struct _TRAPEZOIDDATA TRAPEZOIDDATA; // Handy forward declaration typedef VOID (FNTRAPEZOID)(TRAPEZOIDDATA*, LONG, LONG); // Prototype for trapezoid // drawing routines typedef struct _EDGEDATA { LONG x; // Current x position LONG dx; // # pixels to advance x on each scan LONG lError; // Current DDA error LONG lErrorUp; // DDA error increment on each scan LONG dN; // Signed delta-y in fixed point form (also known // as the DDA error adjustment, and used to be // called 'lErrorDown') LONG dM; // Signed delta-x in fixed point form POINTFIX* pptfx; // Points to start of current edge LONG dptfx; // Delta (in bytes) from pptfx to next point LONG cy; // Number of scans to go for this edge LONG bNew; // Set to TRUE when a new DDA must be started // for the edge. } EDGEDATA; /* ed, ped */ typedef struct _TRAPEZOIDDATA { FNTRAPEZOID* pfnTrap; // Pointer to appropriate trapezoid drawing routine, // or trapezoid clip routine FNTRAPEZOID* pfnTrapClip;// Pointer to appropriate trapezoid drawing routine // if doing clipping PDEV* ppdev; // Pointer to PDEV EDGEDATA aed[2]; // DDA information for both edges POINTL ptlBrush; // Brush alignment LONG yClipTop; // Top of clip rectangle LONG yClipBottom;// Bottom of clip rectangle LONG xClipLeft; // Left edge of clip rectangle LONG xClipRight; // Right edge of clip rectangle BOOL bClip; // Are we clipping? } TRAPEZOIDDATA; /* td, ptd */ /******************************Public*Routine******************************\ * VOID vClipTrapezoid * * Clips a trapezoid. * * NOTE: This routine assumes that the polygon's dimensions are small * enough that its QUOTIENT_REMAINDER calculations won't overflow. * This means that large polygons must never make it here. * \**************************************************************************/ VOID vClipTrapezoid( TRAPEZOIDDATA* ptd, LONG yTrapTop, LONG cyTrapezoid) { LONG yTrapBottom; LONG dN; LONG lNum; LONG xDelta; LONG lError; DISPDBG((2, "vClipTrapezoid")); yTrapBottom = yTrapTop + cyTrapezoid; if (yTrapTop < ptd->yClipTop) { if ((ptd->aed[LEFT].bNew) && (yTrapBottom + ptd->aed[LEFT].cy > ptd->yClipTop)) { dN = ptd->aed[LEFT].dN; lNum = ptd->aed[LEFT].dM * (ptd->yClipTop - yTrapTop) + (ptd->aed[LEFT].lError + dN); if (lNum >= 0) { QUOTIENT_REMAINDER(lNum, dN, xDelta, lError); } else { lNum = -lNum; QUOTIENT_REMAINDER(lNum, dN, xDelta, lError); xDelta = -xDelta; if (lError != 0) { xDelta--; lError = dN - lError; } } ptd->aed[LEFT].x += xDelta; ptd->aed[LEFT].lError = lError - dN; } if ((ptd->aed[RIGHT].bNew) && (yTrapBottom + ptd->aed[RIGHT].cy > ptd->yClipTop)) { dN = ptd->aed[RIGHT].dN; lNum = ptd->aed[RIGHT].dM * (ptd->yClipTop - yTrapTop) + (ptd->aed[RIGHT].lError + dN); if (lNum >= 0) { QUOTIENT_REMAINDER(lNum, dN, xDelta, lError); } else { lNum = -lNum; QUOTIENT_REMAINDER(lNum, dN, xDelta, lError); xDelta = -xDelta; if (lError != 0) { xDelta--; lError = dN - lError; } } ptd->aed[RIGHT].x += xDelta; ptd->aed[RIGHT].lError = lError - dN; } } // If this trapezoid vertically intersects our clip rectangle, draw it: if ((yTrapBottom > ptd->yClipTop) && (yTrapTop < ptd->yClipBottom)) { if (yTrapTop <= ptd->yClipTop) { yTrapTop = ptd->yClipTop; // Have to let trapezoid drawer know that it has to load // its DDAs for very first trapezoid drawn: ptd->aed[RIGHT].bNew = TRUE; ptd->aed[LEFT].bNew = TRUE; } if (yTrapBottom >= ptd->yClipBottom) { yTrapBottom = ptd->yClipBottom; } ptd->pfnTrapClip(ptd, yTrapTop, yTrapBottom - yTrapTop); } } /******************************Public*Routine******************************\ * VOID vIoSolidTrapezoid * * Draws a solid trapezoid using a software DDA. * \**************************************************************************/ VOID vIoSolidTrapezoid( TRAPEZOIDDATA* ptd, LONG yTrapezoid, LONG cyTrapezoid) { PDEV* ppdev; LONG xOffset; LONG lLeftError; LONG xLeft; LONG lRightError; LONG xRight; LONG lTmp; EDGEDATA edTmp; BYTE* pjPorts; LONG lDelta; DISPDBG((2, "vIoSolidTrapezoid")); ppdev = ptd->ppdev; pjPorts = ppdev->pjPorts; lDelta = ppdev->lDelta; xOffset = ppdev->xOffset; yTrapezoid += ppdev->yOffset; yTrapezoid *= lDelta; // If the left and right edges are vertical, simply output as // a rectangle: if (((ptd->aed[LEFT].lErrorUp | ptd->aed[RIGHT].lErrorUp) == 0) && ((ptd->aed[LEFT].dx | ptd->aed[RIGHT].dx) == 0)) { ///////////////////////////////////////////////////////////////// // Vertical-edge special case xLeft = ptd->aed[LEFT].x + xOffset; xRight = ptd->aed[RIGHT].x + xOffset; if (xLeft > xRight) { SWAP(xLeft, xRight, lTmp); SWAP(ptd->aed[LEFT], ptd->aed[RIGHT], edTmp); } if (ptd->bClip) { xLeft = max(xLeft, ptd->xClipLeft + xOffset); xRight = min(xRight, ptd->xClipRight + xOffset); } if (xLeft < xRight) { CP_IO_WAIT_FOR_BLT_COMPLETE(ppdev, pjPorts); CP_IO_XCNT(ppdev, pjPorts, (PELS_TO_BYTES(xRight - xLeft) - 1)); CP_IO_YCNT(ppdev, pjPorts, (cyTrapezoid - 1)); CP_IO_DST_ADDR_ABS(ppdev, pjPorts, (yTrapezoid + PELS_TO_BYTES(xLeft))); CP_IO_START_BLT(ppdev, pjPorts); } } else { lLeftError = ptd->aed[LEFT].lError; xLeft = ptd->aed[LEFT].x + xOffset; lRightError = ptd->aed[RIGHT].lError; xRight = ptd->aed[RIGHT].x + xOffset; while (TRUE) { LONG xLeftClipped; LONG xRightClipped; if (ptd->bClip) { xLeftClipped = max(xLeft, ptd->xClipLeft + xOffset); xRightClipped = min(xRight, ptd->xClipRight + xOffset); } else { xLeftClipped = xLeft; xRightClipped = xRight; } ///////////////////////////////////////////////////////////////// // Run the DDAs if (xLeftClipped < xRightClipped) { CP_IO_WAIT_FOR_BLT_COMPLETE(ppdev, pjPorts); CP_IO_XCNT(ppdev, pjPorts, (PELS_TO_BYTES(xRightClipped - xLeftClipped) - 1)); CP_IO_YCNT(ppdev, pjPorts, 0); CP_IO_DST_ADDR_ABS(ppdev, pjPorts, (yTrapezoid + PELS_TO_BYTES(xLeftClipped))); CP_IO_START_BLT(ppdev, pjPorts); } else if (xLeft > xRight) { // We don't bother optimizing this case because we should // rarely get self-intersecting polygons (if we're slow, // the app gets what it deserves). SWAP(xLeft, xRight, lTmp); SWAP(lLeftError, lRightError, lTmp); SWAP(ptd->aed[LEFT], ptd->aed[RIGHT], edTmp); continue; } // Advance the right wall: xRight += ptd->aed[RIGHT].dx; lRightError += ptd->aed[RIGHT].lErrorUp; if (lRightError >= 0) { lRightError -= ptd->aed[RIGHT].dN; xRight++; } // Advance the left wall: xLeft += ptd->aed[LEFT].dx; lLeftError += ptd->aed[LEFT].lErrorUp; if (lLeftError >= 0) { lLeftError -= ptd->aed[LEFT].dN; xLeft++; } cyTrapezoid--; if (cyTrapezoid == 0) break; yTrapezoid += lDelta; } ptd->aed[LEFT].lError = lLeftError; ptd->aed[LEFT].x = xLeft - xOffset; ptd->aed[RIGHT].lError = lRightError; ptd->aed[RIGHT].x = xRight - xOffset; } } /******************************Public*Routine******************************\ * VOID vIoTrapezoidSetup * * Initialize the hardware and some state for doing trapezoids. * \**************************************************************************/ VOID vIoTrapezoidSetup( PDEV* ppdev, ULONG rop4, ULONG ulSolidColor, RBRUSH* prb, POINTL* pptlBrush, TRAPEZOIDDATA* ptd, RECTL* prclClip) // NULL if no clipping { BYTE* pjPorts = ppdev->pjPorts; LONG cBpp = ppdev->cBpp; LONG lDelta = ppdev->lDelta; BYTE jHwRop; DISPDBG((2, "vIoTrapezoidSetup")); ptd->ppdev = ppdev; jHwRop = gajHwMixFromRop2[(rop4 >> 2) & 0xf]; ///////////////////////////////////////////////////////////////// // Setup the hardware for solid colours ptd->pfnTrap = vIoSolidTrapezoid; // We initialize the hardware for the color, rop, start address, // and blt mode if (cBpp == 1) { ulSolidColor |= ulSolidColor << 8; ulSolidColor |= ulSolidColor << 16; } else if (cBpp == 2) { ulSolidColor |= ulSolidColor << 16; } CP_IO_WAIT_FOR_BLT_COMPLETE(ppdev, pjPorts); CP_IO_ROP(ppdev, pjPorts, jHwRop); CP_IO_SRC_ADDR(ppdev, pjPorts, ppdev->ulSolidColorOffset); CP_IO_DST_Y_OFFSET(ppdev, pjPorts, lDelta); CP_IO_BLT_MODE(ppdev, pjPorts, ENABLE_COLOR_EXPAND | ENABLE_8x8_PATTERN_COPY | ppdev->jModeColor); CP_IO_FG_COLOR(ppdev, pjPorts, ulSolidColor); if (prclClip != NULL) { ptd->pfnTrapClip = ptd->pfnTrap; ptd->pfnTrap = vClipTrapezoid; ptd->yClipTop = prclClip->top; ptd->yClipBottom = prclClip->bottom; ptd->xClipLeft = prclClip->left; ptd->xClipRight = prclClip->right; ptd->bClip = TRUE; } else { ptd->bClip = FALSE; } } /******************************Public*Routine******************************\ * VOID vMmSolidTrapezoid * * Draws a solid trapezoid using a software DDA. * \**************************************************************************/ VOID vMmSolidTrapezoid( TRAPEZOIDDATA* ptd, LONG yTrapezoid, LONG cyTrapezoid) { PDEV* ppdev; LONG xOffset; LONG lLeftError; LONG xLeft; LONG lRightError; LONG xRight; LONG lTmp; EDGEDATA edTmp; BYTE* pjBase; LONG lDelta; DISPDBG((2, "vMmSolidTrapezoid")); ppdev = ptd->ppdev; pjBase = ppdev->pjBase; lDelta = ppdev->lDelta; xOffset = ppdev->xOffset; yTrapezoid += ppdev->yOffset; yTrapezoid *= lDelta; // If the left and right edges are vertical, simply output as // a rectangle: if (((ptd->aed[LEFT].lErrorUp | ptd->aed[RIGHT].lErrorUp) == 0) && ((ptd->aed[LEFT].dx | ptd->aed[RIGHT].dx) == 0)) { ///////////////////////////////////////////////////////////////// // Vertical-edge special case xLeft = ptd->aed[LEFT].x + xOffset; xRight = ptd->aed[RIGHT].x + xOffset; if (xLeft > xRight) { SWAP(xLeft, xRight, lTmp); SWAP(ptd->aed[LEFT], ptd->aed[RIGHT], edTmp); } if (ptd->bClip) { xLeft = max(xLeft, ptd->xClipLeft + xOffset); xRight = min(xRight, ptd->xClipRight + xOffset); } if (xLeft < xRight) { CP_MM_WAIT_FOR_BLT_COMPLETE(ppdev, pjBase); CP_MM_XCNT(ppdev, pjBase, (PELS_TO_BYTES(xRight - xLeft) - 1)); CP_MM_YCNT(ppdev, pjBase, (cyTrapezoid - 1)); CP_MM_DST_ADDR_ABS(ppdev, pjBase, (yTrapezoid + PELS_TO_BYTES(xLeft))); CP_MM_START_BLT(ppdev, pjBase); } } else { lLeftError = ptd->aed[LEFT].lError; xLeft = ptd->aed[LEFT].x + xOffset; lRightError = ptd->aed[RIGHT].lError; xRight = ptd->aed[RIGHT].x + xOffset; CP_MM_WAIT_FOR_BLT_COMPLETE(ppdev, pjBase); CP_MM_YCNT(ppdev, pjBase, 0); while (TRUE) { LONG xLeftClipped; LONG xRightClipped; if (ptd->bClip) { xLeftClipped = max(xLeft, ptd->xClipLeft + xOffset); xRightClipped = min(xRight, ptd->xClipRight + xOffset); } else { xLeftClipped = xLeft; xRightClipped = xRight; } ///////////////////////////////////////////////////////////////// // Run the DDAs if (xLeftClipped < xRightClipped) { CP_MM_WAIT_FOR_BLT_COMPLETE(ppdev, pjBase); CP_MM_XCNT(ppdev, pjBase, (PELS_TO_BYTES(xRightClipped - xLeftClipped) - 1)); //CP_MM_YCNT(ppdev, pjBase, 0); CP_MM_DST_ADDR_ABS(ppdev, pjBase, (yTrapezoid + PELS_TO_BYTES(xLeftClipped))); CP_MM_START_BLT(ppdev, pjBase); } else if (xLeft > xRight) { // We don't bother optimizing this case because we should // rarely get self-intersecting polygons (if we're slow, // the app gets what it deserves). SWAP(xLeft, xRight, lTmp); SWAP(lLeftError, lRightError, lTmp); SWAP(ptd->aed[LEFT], ptd->aed[RIGHT], edTmp); continue; } // Advance the right wall: xRight += ptd->aed[RIGHT].dx; lRightError += ptd->aed[RIGHT].lErrorUp; if (lRightError >= 0) { lRightError -= ptd->aed[RIGHT].dN; xRight++; } // Advance the left wall: xLeft += ptd->aed[LEFT].dx; lLeftError += ptd->aed[LEFT].lErrorUp; if (lLeftError >= 0) { lLeftError -= ptd->aed[LEFT].dN; xLeft++; } cyTrapezoid--; if (cyTrapezoid == 0) break; yTrapezoid += lDelta; } ptd->aed[LEFT].lError = lLeftError; ptd->aed[LEFT].x = xLeft - xOffset; ptd->aed[RIGHT].lError = lRightError; ptd->aed[RIGHT].x = xRight - xOffset; } } /******************************Public*Routine******************************\ * VOID vMmTrapezoidSetup * * Initialize the hardware and some state for doing trapezoids. * \**************************************************************************/ VOID vMmTrapezoidSetup( PDEV* ppdev, ULONG rop4, ULONG ulSolidColor, RBRUSH* prb, POINTL* pptlBrush, TRAPEZOIDDATA* ptd, RECTL* prclClip) // NULL if no clipping { BYTE* pjBase = ppdev->pjBase; LONG cBpp = ppdev->cBpp; LONG lDelta = ppdev->lDelta; BYTE jHwRop; DISPDBG((2, "vMmTrapezoidSetup")); ptd->ppdev = ppdev; jHwRop = gajHwMixFromRop2[(rop4 >> 2) & 0xf]; ///////////////////////////////////////////////////////////////// // Setup the hardware for solid colours ptd->pfnTrap = vMmSolidTrapezoid; // We initialize the hardware for the color, rop, start address, // and blt mode if (cBpp == 1) { ulSolidColor |= ulSolidColor << 8; ulSolidColor |= ulSolidColor << 16; } else if (cBpp == 2) { ulSolidColor |= ulSolidColor << 16; } CP_MM_WAIT_FOR_BLT_COMPLETE(ppdev, pjBase); CP_MM_ROP(ppdev, pjBase, jHwRop); CP_MM_SRC_ADDR(ppdev, pjBase, ppdev->ulSolidColorOffset); CP_MM_DST_Y_OFFSET(ppdev, pjBase, lDelta); CP_MM_BLT_MODE(ppdev, pjBase, ENABLE_COLOR_EXPAND | ENABLE_8x8_PATTERN_COPY | ppdev->jModeColor); CP_MM_FG_COLOR(ppdev, pjBase, ulSolidColor); if (prclClip != NULL) { ptd->pfnTrapClip = ptd->pfnTrap; ptd->pfnTrap = vClipTrapezoid; ptd->yClipTop = prclClip->top; ptd->yClipBottom = prclClip->bottom; ptd->xClipLeft = prclClip->left; ptd->xClipRight = prclClip->right; ptd->bClip = TRUE; } else { ptd->bClip = FALSE; } } // chu01 /******************************Public*Routine******************************\ * * B i t B L T E n h a n c e m e n t F o r C L - G D 5 4 8 0 * \**************************************************************************/ /******************************Public*Routine******************************\ * VOID vMmSolidTrapezoid80 * * Draws a solid trapezoid using a software DDA. This is for CL-GD5480 with * enhanced BitBLT features. * \**************************************************************************/ VOID vMmSolidTrapezoid80( TRAPEZOIDDATA* ptd, LONG yTrapezoid, LONG cyTrapezoid) { PDEV* ppdev; LONG xOffset; LONG lLeftError; LONG xLeft; LONG lRightError; LONG xRight; LONG lTmp; EDGEDATA edTmp; BYTE* pjBase; LONG lDelta; DISPDBG((2, "vMmSolidTrapezoid80")) ; ppdev = ptd->ppdev ; pjBase = ppdev->pjBase ; lDelta = ppdev->lDelta ; xOffset = ppdev->xOffset ; yTrapezoid += ppdev->yOffset ; // If the left and right edges are vertical, simply output as // a rectangle: if (((ptd->aed[LEFT].lErrorUp | ptd->aed[RIGHT].lErrorUp) == 0) && ((ptd->aed[LEFT].dx | ptd->aed[RIGHT].dx) == 0)) { ///////////////////////////////////////////////////////////////// // Vertical-edge special case xLeft = ptd->aed[LEFT].x + xOffset; xRight = ptd->aed[RIGHT].x + xOffset; if (xLeft > xRight) { SWAP(xLeft, xRight, lTmp); SWAP(ptd->aed[LEFT], ptd->aed[RIGHT], edTmp); } if (ptd->bClip) { xLeft = max(xLeft, ptd->xClipLeft + xOffset); xRight = min(xRight, ptd->xClipRight + xOffset); } if (xLeft < xRight) { CP_MM_WAIT_FOR_BLT_COMPLETE(ppdev, pjBase) ; CP_MM_XCNT(ppdev, pjBase, (xRight - xLeft) - 1) ; CP_MM_YCNT(ppdev, pjBase, (cyTrapezoid - 1)) ; CP_MM_DST_ADDR_ABS(ppdev, pjBase, 0); CP_MM_DST_Y(ppdev, pjBase, yTrapezoid) ; CP_MM_DST_X(ppdev, pjBase, xLeft) ; } } else { lLeftError = ptd->aed[LEFT].lError; xLeft = ptd->aed[LEFT].x + xOffset; lRightError = ptd->aed[RIGHT].lError; xRight = ptd->aed[RIGHT].x + xOffset; CP_MM_WAIT_FOR_BLT_COMPLETE(ppdev, pjBase); CP_MM_YCNT(ppdev, pjBase, 0); while (TRUE) { LONG xLeftClipped; LONG xRightClipped; if (ptd->bClip) { xLeftClipped = max(xLeft, ptd->xClipLeft + xOffset); xRightClipped = min(xRight, ptd->xClipRight + xOffset); } else { xLeftClipped = xLeft; xRightClipped = xRight; } ///////////////////////////////////////////////////////////////// // Run the DDAs if (xLeftClipped < xRightClipped) { CP_MM_WAIT_FOR_BLT_COMPLETE(ppdev, pjBase) ; CP_MM_XCNT(ppdev, pjBase, (xRightClipped - xLeftClipped) - 1) ; // CP_MM_YCNT(ppdev, pjBase, 0) ; CP_MM_DST_ADDR_ABS(ppdev, pjBase, 0) ; CP_MM_DST_Y(ppdev, pjBase, yTrapezoid) ; CP_MM_DST_X(ppdev, pjBase, xLeftClipped) ; } else if (xLeft > xRight) { // We don't bother optimizing this case because we should // rarely get self-intersecting polygons (if we're slow, // the app gets what it deserves). SWAP(xLeft, xRight, lTmp); SWAP(lLeftError, lRightError, lTmp); SWAP(ptd->aed[LEFT], ptd->aed[RIGHT], edTmp); continue; } // Advance the right wall: xRight += ptd->aed[RIGHT].dx; lRightError += ptd->aed[RIGHT].lErrorUp; if (lRightError >= 0) { lRightError -= ptd->aed[RIGHT].dN; xRight++; } // Advance the left wall: xLeft += ptd->aed[LEFT].dx; lLeftError += ptd->aed[LEFT].lErrorUp; if (lLeftError >= 0) { lLeftError -= ptd->aed[LEFT].dN; xLeft++; } cyTrapezoid--; if (cyTrapezoid == 0) break; yTrapezoid += 1 ; } ptd->aed[LEFT].lError = lLeftError; ptd->aed[LEFT].x = xLeft - xOffset; ptd->aed[RIGHT].lError = lRightError; ptd->aed[RIGHT].x = xRight - xOffset; } } /******************************Public*Routine******************************\ * VOID vMmTrapezoidSetup80 * * Initialize the hardware and some state for doing trapezoids. This is for * CL-GD5480 with enhanced BitBLT features. * \**************************************************************************/ VOID vMmTrapezoidSetup80( PDEV* ppdev, ULONG rop4, ULONG ulSolidColor, RBRUSH* prb, POINTL* pptlBrush, TRAPEZOIDDATA* ptd, RECTL* prclClip) // NULL if no clipping { BYTE* pjBase = ppdev->pjBase ; LONG cBpp = ppdev->cBpp ; LONG lDelta = ppdev->lDelta ; ULONG jHwRop ; DWORD jExtMode = 0 ; DISPDBG((2, "vMmTrapezoidSetup80")) ; ptd->ppdev = ppdev ; jHwRop = gajHwPackedMixFromRop2[(rop4 >> 2) & 0xf] ; ///////////////////////////////////////////////////////////////// // Setup the hardware for solid colours ptd->pfnTrap = vMmSolidTrapezoid80 ; // We initialize the hardware for the color, rop, start address, // and blt mode if (cBpp == 1) { ulSolidColor |= ulSolidColor << 8 ; ulSolidColor |= ulSolidColor << 16 ; } else if (cBpp == 2) { ulSolidColor |= ulSolidColor << 16 ; } CP_MM_WAIT_FOR_BLT_COMPLETE(ppdev, pjBase) ; CP_MM_SRC_ADDR(ppdev, pjBase, ppdev->ulSolidColorOffset) ; CP_MM_DST_Y_OFFSET(ppdev, pjBase, lDelta); jExtMode = ( ENABLE_XY_POSITION_PACKED | ENABLE_COLOR_EXPAND | ENABLE_8x8_PATTERN_COPY | ppdev->jModeColor ) ; CP_MM_BLT_MODE_PACKED(ppdev, pjBase, jExtMode | jHwRop) ; CP_MM_FG_COLOR(ppdev, pjBase, ulSolidColor) ; if (prclClip != NULL) { ptd->pfnTrapClip = ptd->pfnTrap ; ptd->pfnTrap = vClipTrapezoid ; ptd->yClipTop = prclClip->top ; ptd->yClipBottom = prclClip->bottom ; ptd->xClipLeft = prclClip->left ; ptd->xClipRight = prclClip->right ; ptd->bClip = TRUE; } else { ptd->bClip = FALSE; } } /******************************Public*Routine******************************\ * BOOL bFastFill * * Draws a non-complex, unclipped polygon. 'Non-complex' is defined as * having only two edges that are monotonic increasing in 'y'. That is, * the polygon cannot have more than one disconnected segment on any given * scan. Note that the edges of the polygon can self-intersect, so hourglass * shapes are permissible. This restriction permits this routine to run two * simultaneous DDAs, and no sorting of the edges is required. * * Note that NT's fill convention is different from that of Win 3.1 or Win95. * With the additional complication of fractional end-points, our convention * is the same as in 'X-Windows'. But a DDA is a DDA is a DDA, so once you * figure out how we compute the DDA terms for NT, you're golden. * * This routine handles patterns only when the S3 hardware patterns can be * used. The reason for this is that once the S3 pattern initialization is * done, pattern fills appear to the programmer exactly the same as solid * fills (with the slight difference that different registers and commands * are used). Handling 'vIoFillPatSlow' style patterns in this routine * would be non-trivial... * * We take advantage of the fact that the S3 automatically advances the * current 'y' to the following scan whenever a rectangle is output so that * we have to write to the accelerator three times for every scan: one for * the new 'x', one for the new 'width', and one for the drawing command. * * Returns TRUE if the polygon was drawn; FALSE if the polygon was complex. * \**************************************************************************/ BOOL bFastFill( PDEV* ppdev, LONG cEdges, // Includes close figure edge POINTFIX* pptfxFirst, ULONG rop4, ULONG iSolidColor, RBRUSH* prb, POINTL* pptlBrush, RECTL* prclClip) // NULL if no clipping { LONG yTrapezoid; // Top scan for next trapezoid LONG cyTrapezoid; // Number of scans in current trapezoid LONG yStart; // y-position of start point in current edge LONG dM; // Edge delta in FIX units in x direction LONG dN; // Edge delta in FIX units in y direction LONG i; POINTFIX* pptfxLast; // Points to the last point in the polygon array POINTFIX* pptfxTop; // Points to the top-most point in the polygon POINTFIX* pptfxOld; // Start point in current edge POINTFIX* pptfxScan; // Current edge pointer for finding pptfxTop LONG cScanEdges; // Number of edges scanned to find pptfxTop // (doesn't include the closefigure edge) LONG iEdge; LONG lQuotient; LONG lRemainder; TRAPEZOIDDATA td; // Edge data and stuff EDGEDATA* ped; // Points to current edge being processed ///////////////////////////////////////////////////////////////// // See if the polygon is convex pptfxScan = pptfxFirst; pptfxTop = pptfxFirst; // Assume for now that the first // point in path is the topmost pptfxLast = pptfxFirst + cEdges - 1; if (cEdges <= 2) goto ReturnTrue; // 'pptfxScan' will always point to the first point in the current // edge, and 'cScanEdges' will the number of edges remaining, including // the current one: cScanEdges = cEdges - 1; // The number of edges, not counting close figure if ((pptfxScan + 1)->y > pptfxScan->y) { // Collect all downs: do { if (--cScanEdges == 0) goto SetUpForFilling; pptfxScan++; } while ((pptfxScan + 1)->y >= pptfxScan->y); // Collect all ups: do { if (--cScanEdges == 0) goto SetUpForFillingCheck; pptfxScan++; } while ((pptfxScan + 1)->y <= pptfxScan->y); // Collect all downs: pptfxTop = pptfxScan; do { if ((pptfxScan + 1)->y > pptfxFirst->y) break; if (--cScanEdges == 0) goto SetUpForFilling; pptfxScan++; } while ((pptfxScan + 1)->y >= pptfxScan->y); goto ReturnFalse; } else { // Collect all ups: do { pptfxTop++; // We increment this now because we // want it to point to the very last // point if we early out in the next // statement... if (--cScanEdges == 0) goto SetUpForFilling; } while ((pptfxTop + 1)->y <= pptfxTop->y); // Collect all downs: pptfxScan = pptfxTop; do { if (--cScanEdges == 0) goto SetUpForFilling; pptfxScan++; } while ((pptfxScan + 1)->y >= pptfxScan->y); // Collect all ups: do { if ((pptfxScan + 1)->y < pptfxFirst->y) break; if (--cScanEdges == 0) goto SetUpForFilling; pptfxScan++; } while ((pptfxScan + 1)->y <= pptfxScan->y); goto ReturnFalse; } SetUpForFillingCheck: // We check to see if the end of the current edge is higher // than the top edge we've found so far: if ((pptfxScan + 1)->y < pptfxTop->y) pptfxTop = pptfxScan + 1; SetUpForFilling: ///////////////////////////////////////////////////////////////// // Some Initialization td.aed[LEFT].pptfx = pptfxTop; td.aed[RIGHT].pptfx = pptfxTop; yTrapezoid = (pptfxTop->y + 15) >> 4; // Make sure we initialize the DDAs appropriately: td.aed[LEFT].cy = 0; td.aed[RIGHT].cy = 0; // Guess as to the ordering of the points: td.aed[LEFT].dptfx = sizeof(POINTFIX); td.aed[RIGHT].dptfx = -(LONG) sizeof(POINTFIX); if (ppdev->flCaps & CAPS_MM_IO) { // chu01 if ((ppdev->flCaps & CAPS_COMMAND_LIST) && (ppdev->pCommandList != NULL)) { vMmTrapezoidSetup80(ppdev, rop4, iSolidColor, prb, pptlBrush, &td, prclClip) ; } else vMmTrapezoidSetup(ppdev, rop4, iSolidColor, prb, pptlBrush, &td, prclClip) ; } else { vIoTrapezoidSetup(ppdev, rop4, iSolidColor, prb, pptlBrush, &td, prclClip); } NewTrapezoid: ///////////////////////////////////////////////////////////////// // DDA initialization for (iEdge = 1; iEdge >= 0; iEdge--) { ped = &td.aed[iEdge]; ped->bNew = FALSE; if (ped->cy == 0) { // Our trapezoid drawing routine may want to be notified when // it will have to reset its DDA to start a new edge: ped->bNew = TRUE; // Need a new DDA: do { cEdges--; if (cEdges < 0) goto ReturnTrue; // Find the next left edge, accounting for wrapping: pptfxOld = ped->pptfx; ped->pptfx = (POINTFIX*) ((BYTE*) ped->pptfx + ped->dptfx); if (ped->pptfx < pptfxFirst) ped->pptfx = pptfxLast; else if (ped->pptfx > pptfxLast) ped->pptfx = pptfxFirst; // Have to find the edge that spans yTrapezoid: ped->cy = ((ped->pptfx->y + 15) >> 4) - yTrapezoid; // With fractional coordinate end points, we may get edges // that don't cross any scans, in which case we try the // next one: } while (ped->cy <= 0); // 'pptfx' now points to the end point of the edge spanning // the scan 'yTrapezoid'. dN = ped->pptfx->y - pptfxOld->y; dM = ped->pptfx->x - pptfxOld->x; ASSERTDD(dN > 0, "Should be going down only"); // Compute the DDA increment terms: ped->dM = dM; // Not used for software trapezoid if (dM < 0) { dM = -dM; if (dM < dN) // Can't be '<=' { ped->dx = -1; ped->lErrorUp = dN - dM; } else { QUOTIENT_REMAINDER(dM, dN, lQuotient, lRemainder); ped->dx = -lQuotient; // - dM / dN ped->lErrorUp = lRemainder; // dM % dN if (ped->lErrorUp > 0) { ped->dx--; ped->lErrorUp = dN - ped->lErrorUp; } } } else { if (dM < dN) // Can't be '<=' { ped->dx = 0; ped->lErrorUp = dM; } else { QUOTIENT_REMAINDER(dM, dN, lQuotient, lRemainder); ped->dx = lQuotient; // dM / dN ped->lErrorUp = lRemainder; // dM % dN } } ped->dN = dN; // DDA limit ped->lError = -1; // Error is initially zero (add dN - 1 for // the ceiling, but subtract off dN so that // we can check the sign instead of comparing // to dN) ped->x = pptfxOld->x; yStart = pptfxOld->y; if ((yStart & 15) != 0) { // Advance to the next integer y coordinate for (i = 16 - (yStart & 15); i != 0; i--) { ped->x += ped->dx; ped->lError += ped->lErrorUp; if (ped->lError >= 0) { ped->lError -= ped->dN; ped->x++; } } } if ((ped->x & 15) != 0) { ped->lError -= ped->dN * (16 - (ped->x & 15)); ped->x += 15; // We'll want the ceiling in just a bit... } // Chop off those fractional bits: ped->x >>= 4; ped->lError >>= 4; } } cyTrapezoid = min(td.aed[LEFT].cy, td.aed[RIGHT].cy); // # of scans in this trap td.aed[LEFT].cy -= cyTrapezoid; td.aed[RIGHT].cy -= cyTrapezoid; td.pfnTrap(&td, yTrapezoid, cyTrapezoid); yTrapezoid += cyTrapezoid; goto NewTrapezoid; ReturnTrue: return(TRUE); ReturnFalse: return(FALSE); }