/* $XFree86: xc/programs/Xserver/hw/xfree86/drivers/ati/r128_accel.c,v 1.17 2003/10/03 20:11:11 herrb Exp $ */ /* * Copyright 1999, 2000 ATI Technologies Inc., Markham, Ontario, * Precision Insight, Inc., Cedar Park, Texas, and * VA Linux Systems Inc., Fremont, California. * * All Rights Reserved. * * 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, 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 (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 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NON-INFRINGEMENT. IN NO EVENT SHALL ATI, PRECISION INSIGHT, VA LINUX * SYSTEMS AND/OR THEIR SUPPLIERS 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: * Rickard E. Faith * Kevin E. Martin * Alan Hourihane * * Credits: * * Thanks to Alan Hourihane and SuSE for * providing source code to their 3.3.x Rage 128 driver. Portions of * this file are based on the acceleration code for that driver. * * References: * * RAGE 128 VR/ RAGE 128 GL Register Reference Manual (Technical * Reference Manual P/N RRG-G04100-C Rev. 0.04), ATI Technologies: April * 1999. * * RAGE 128 Software Development Manual (Technical Reference Manual P/N * SDK-G04000 Rev. 0.01), ATI Technologies: June 1999. * * Notes on unimplemented XAA optimizations: * * SetClipping: The Rage128 doesn't support the full 16bit registers needed * for XAA clip rect support. * SolidFillTrap: This will probably work if we can compute the correct * Bresenham error values. * TwoPointLine: The Rage 128 supports Bresenham lines instead. * DashedLine with non-power-of-two pattern length: Apparently, there is * no way to set the length of the pattern -- it is always * assumed to be 8 or 32 (or 1024?). * ScreenToScreenColorExpandFill: See p. 4-17 of the Technical Reference * Manual where it states that monochrome expansion of frame * buffer data is not supported. * CPUToScreenColorExpandFill, direct: The implementation here uses a hybrid * direct/indirect method. If we had more data registers, * then we could do better. If XAA supported a trigger write * address, the code would be simpler. * (Alan Hourihane) Update. We now use purely indirect and clip the full * rectangle. Seems as the direct method has some problems * with this, although this indirect method is much faster * than the old method of setting up the engine per scanline. * This code was the basis of the Radeon work we did. * Color8x8PatternFill: Apparently, an 8x8 color brush cannot take an 8x8 * pattern from frame buffer memory. * ImageWrites: See CPUToScreenColorExpandFill. * */ #define R128_TRAPEZOIDS 0 /* Trapezoids don't work */ /* Driver data structures */ #include "r128.h" #include "r128_reg.h" #ifdef XF86DRI #include "r128_sarea.h" #define _XF86DRI_SERVER_ #include "r128_dri.h" #endif /* Line support */ #include "miline.h" /* X and server generic header files */ #include "xf86.h" static struct { int rop; int pattern; } R128_ROP[] = { { R128_ROP3_ZERO, R128_ROP3_ZERO }, /* GXclear */ { R128_ROP3_DSa, R128_ROP3_DPa }, /* Gxand */ { R128_ROP3_SDna, R128_ROP3_PDna }, /* GXandReverse */ { R128_ROP3_S, R128_ROP3_P }, /* GXcopy */ { R128_ROP3_DSna, R128_ROP3_DPna }, /* GXandInverted */ { R128_ROP3_D, R128_ROP3_D }, /* GXnoop */ { R128_ROP3_DSx, R128_ROP3_DPx }, /* GXxor */ { R128_ROP3_DSo, R128_ROP3_DPo }, /* GXor */ { R128_ROP3_DSon, R128_ROP3_DPon }, /* GXnor */ { R128_ROP3_DSxn, R128_ROP3_PDxn }, /* GXequiv */ { R128_ROP3_Dn, R128_ROP3_Dn }, /* GXinvert */ { R128_ROP3_SDno, R128_ROP3_PDno }, /* GXorReverse */ { R128_ROP3_Sn, R128_ROP3_Pn }, /* GXcopyInverted */ { R128_ROP3_DSno, R128_ROP3_DPno }, /* GXorInverted */ { R128_ROP3_DSan, R128_ROP3_DPan }, /* GXnand */ { R128_ROP3_ONE, R128_ROP3_ONE } /* GXset */ }; /* Flush all dirty data in the Pixel Cache to memory. */ void R128EngineFlush(ScrnInfoPtr pScrn) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; int i; OUTREGP(R128_PC_NGUI_CTLSTAT, R128_PC_FLUSH_ALL, ~R128_PC_FLUSH_ALL); for (i = 0; i < R128_TIMEOUT; i++) { if (!(INREG(R128_PC_NGUI_CTLSTAT) & R128_PC_BUSY)) break; } } /* Reset graphics card to known state. */ void R128EngineReset(ScrnInfoPtr pScrn) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; CARD32 clock_cntl_index; CARD32 mclk_cntl; CARD32 gen_reset_cntl; R128EngineFlush(pScrn); clock_cntl_index = INREG(R128_CLOCK_CNTL_INDEX); mclk_cntl = INPLL(pScrn, R128_MCLK_CNTL); OUTPLL(R128_MCLK_CNTL, mclk_cntl | R128_FORCE_GCP | R128_FORCE_PIPE3D_CP); gen_reset_cntl = INREG(R128_GEN_RESET_CNTL); OUTREG(R128_GEN_RESET_CNTL, gen_reset_cntl | R128_SOFT_RESET_GUI); INREG(R128_GEN_RESET_CNTL); OUTREG(R128_GEN_RESET_CNTL, gen_reset_cntl & (CARD32)(~R128_SOFT_RESET_GUI)); INREG(R128_GEN_RESET_CNTL); OUTPLL(R128_MCLK_CNTL, mclk_cntl); OUTREG(R128_CLOCK_CNTL_INDEX, clock_cntl_index); OUTREG(R128_GEN_RESET_CNTL, gen_reset_cntl); } /* The FIFO has 64 slots. This routines waits until at least `entries' of these slots are empty. */ void R128WaitForFifoFunction(ScrnInfoPtr pScrn, int entries) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; int i; for (;;) { for (i = 0; i < R128_TIMEOUT; i++) { info->fifo_slots = INREG(R128_GUI_STAT) & R128_GUI_FIFOCNT_MASK; if (info->fifo_slots >= entries) return; } R128TRACE(("FIFO timed out: %d entries, stat=0x%08x, probe=0x%08x\n", INREG(R128_GUI_STAT) & R128_GUI_FIFOCNT_MASK, INREG(R128_GUI_STAT), INREG(R128_GUI_PROBE))); xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "FIFO timed out, resetting engine...\n"); R128EngineReset(pScrn); #ifdef XF86DRI R128CCE_RESET(pScrn, info); if (info->directRenderingEnabled) { R128CCE_START(pScrn, info); } #endif } } /* Wait for the graphics engine to be completely idle: the FIFO has drained, the Pixel Cache is flushed, and the engine is idle. This is a standard "sync" function that will make the hardware "quiescent". */ void R128WaitForIdle(ScrnInfoPtr pScrn) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; int i; R128WaitForFifoFunction(pScrn, 64); for (;;) { for (i = 0; i < R128_TIMEOUT; i++) { if (!(INREG(R128_GUI_STAT) & R128_GUI_ACTIVE)) { R128EngineFlush(pScrn); return; } } R128TRACE(("Idle timed out: %d entries, stat=0x%08x, probe=0x%08x\n", INREG(R128_GUI_STAT) & R128_GUI_FIFOCNT_MASK, INREG(R128_GUI_STAT), INREG(R128_GUI_PROBE))); xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Idle timed out, resetting engine...\n"); R128EngineReset(pScrn); #ifdef XF86DRI R128CCE_RESET(pScrn, info); if (info->directRenderingEnabled) { R128CCE_START(pScrn, info); } #endif } } #ifdef XF86DRI /* Wait until the CCE is completely idle: the FIFO has drained and the * CCE is idle. */ void R128CCEWaitForIdle(ScrnInfoPtr pScrn) { R128InfoPtr info = R128PTR(pScrn); int ret, i; FLUSH_RING(); for (;;) { i = 0; do { ret = drmCommandNone(info->drmFD, DRM_R128_CCE_IDLE); } while ( ret && errno == EBUSY && i++ < R128_IDLE_RETRY ); if (ret && ret != -EBUSY) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "%s: CCE idle %d\n", __FUNCTION__, ret); } if (ret == 0) return; xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Idle timed out, resetting engine...\n"); R128EngineReset(pScrn); /* Always restart the engine when doing CCE 2D acceleration */ R128CCE_RESET(pScrn, info); R128CCE_START(pScrn, info); } } int R128CCEStop(ScrnInfoPtr pScrn) { R128InfoPtr info = R128PTR(pScrn); drmR128CCEStop stop; int ret, i; stop.flush = 1; stop.idle = 1; ret = drmCommandWrite( info->drmFD, DRM_R128_CCE_STOP, &stop, sizeof(drmR128CCEStop) ); if ( ret == 0 ) { return 0; } else if ( errno != EBUSY ) { return -errno; } stop.flush = 0; i = 0; do { ret = drmCommandWrite( info->drmFD, DRM_R128_CCE_STOP, &stop, sizeof(drmR128CCEStop) ); } while ( ret && errno == EBUSY && i++ < R128_IDLE_RETRY ); if ( ret == 0 ) { return 0; } else if ( errno != EBUSY ) { return -errno; } stop.idle = 0; if ( drmCommandWrite( info->drmFD, DRM_R128_CCE_STOP, &stop, sizeof(drmR128CCEStop) )) { return -errno; } else { return 0; } } #endif /* Setup for XAA SolidFill. */ static void R128SetupForSolidFill(ScrnInfoPtr pScrn, int color, int rop, unsigned int planemask) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128WaitForFifo(pScrn, 4); OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_BRUSH_SOLID_COLOR | R128_GMC_SRC_DATATYPE_COLOR | R128_ROP[rop].pattern)); OUTREG(R128_DP_BRUSH_FRGD_CLR, color); OUTREG(R128_DP_WRITE_MASK, planemask); OUTREG(R128_DP_CNTL, (R128_DST_X_LEFT_TO_RIGHT | R128_DST_Y_TOP_TO_BOTTOM)); } /* Subsequent XAA SolidFillRect. Tests: xtest CH06/fllrctngl, xterm */ static void R128SubsequentSolidFillRect(ScrnInfoPtr pScrn, int x, int y, int w, int h) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128WaitForFifo(pScrn, 2); OUTREG(R128_DST_Y_X, (y << 16) | x); OUTREG(R128_DST_WIDTH_HEIGHT, (w << 16) | h); } /* Setup for XAA solid lines. */ static void R128SetupForSolidLine(ScrnInfoPtr pScrn, int color, int rop, unsigned int planemask) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128WaitForFifo(pScrn, 3); OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_BRUSH_SOLID_COLOR | R128_GMC_SRC_DATATYPE_COLOR | R128_ROP[rop].pattern)); OUTREG(R128_DP_BRUSH_FRGD_CLR, color); OUTREG(R128_DP_WRITE_MASK, planemask); } /* Subsequent XAA solid Bresenham line. Tests: xtest CH06/drwln, ico, Mark Vojkovich's linetest program [See http://www.xfree86.org/devel/archives/devel/1999-Jun/0102.shtml for Mark Vojkovich's linetest program, posted 2Jun99 to devel@xfree86.org.] x11perf -line500 1024x768@76Hz 1024x768@76Hz 8bpp 32bpp not used: 39700.0/sec 34100.0/sec used: 47600.0/sec 36800.0/sec */ static void R128SubsequentSolidBresenhamLine(ScrnInfoPtr pScrn, int x, int y, int major, int minor, int err, int len, int octant) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; int flags = 0; if (octant & YMAJOR) flags |= R128_DST_Y_MAJOR; if (!(octant & XDECREASING)) flags |= R128_DST_X_DIR_LEFT_TO_RIGHT; if (!(octant & YDECREASING)) flags |= R128_DST_Y_DIR_TOP_TO_BOTTOM; R128WaitForFifo(pScrn, 6); OUTREG(R128_DP_CNTL_XDIR_YDIR_YMAJOR, flags); OUTREG(R128_DST_Y_X, (y << 16) | x); OUTREG(R128_DST_BRES_ERR, err); OUTREG(R128_DST_BRES_INC, minor); OUTREG(R128_DST_BRES_DEC, -major); OUTREG(R128_DST_BRES_LNTH, len); } /* Subsequent XAA solid horizontal and vertical lines 1024x768@76Hz 8bpp Without With x11perf -hseg500 87600.0/sec 798000.0/sec x11perf -vseg500 38100.0/sec 38000.0/sec */ static void R128SubsequentSolidHorVertLine(ScrnInfoPtr pScrn, int x, int y, int len, int dir ) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128WaitForFifo(pScrn, 1); OUTREG(R128_DP_CNTL, (R128_DST_X_LEFT_TO_RIGHT | R128_DST_Y_TOP_TO_BOTTOM)); if (dir == DEGREES_0) { R128SubsequentSolidFillRect(pScrn, x, y, len, 1); } else { R128SubsequentSolidFillRect(pScrn, x, y, 1, len); } } /* Setup for XAA dashed lines. Tests: xtest CH05/stdshs, XFree86/drwln NOTE: Since we can only accelerate lines with power-of-2 patterns of length <= 32, these x11perf numbers are not representative of the speed-up on appropriately-sized patterns. 1024x768@76Hz 8bpp Without With x11perf -dseg100 218000.0/sec 222000.0/sec x11perf -dline100 215000.0/sec 221000.0/sec x11perf -ddline100 178000.0/sec 180000.0/sec */ static void R128SetupForDashedLine(ScrnInfoPtr pScrn, int fg, int bg, int rop, unsigned int planemask, int length, unsigned char *pattern) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; CARD32 pat = *(CARD32 *)(pointer)pattern; #if X_BYTE_ORDER == X_LITTLE_ENDIAN # define PAT_SHIFT(pat,n) pat << n #else # define PAT_SHIFT(pat,n) pat >> n #endif switch (length) { case 2: pat |= PAT_SHIFT(pat,2); /* fall through */ case 4: pat |= PAT_SHIFT(pat,4); /* fall through */ case 8: pat |= PAT_SHIFT(pat,8); /* fall through */ case 16: pat |= PAT_SHIFT(pat,16); } R128WaitForFifo(pScrn, 5); OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | (bg == -1 ? R128_GMC_BRUSH_32x1_MONO_FG_LA : R128_GMC_BRUSH_32x1_MONO_FG_BG) | R128_ROP[rop].pattern | R128_GMC_BYTE_LSB_TO_MSB)); OUTREG(R128_DP_WRITE_MASK, planemask); OUTREG(R128_DP_BRUSH_FRGD_CLR, fg); OUTREG(R128_DP_BRUSH_BKGD_CLR, bg); OUTREG(R128_BRUSH_DATA0, pat); } /* Subsequent XAA dashed line. */ static void R128SubsequentDashedBresenhamLine(ScrnInfoPtr pScrn, int x, int y, int major, int minor, int err, int len, int octant, int phase) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; int flags = 0; if (octant & YMAJOR) flags |= R128_DST_Y_MAJOR; if (!(octant & XDECREASING)) flags |= R128_DST_X_DIR_LEFT_TO_RIGHT; if (!(octant & YDECREASING)) flags |= R128_DST_Y_DIR_TOP_TO_BOTTOM; R128WaitForFifo(pScrn, 7); OUTREG(R128_DP_CNTL_XDIR_YDIR_YMAJOR, flags); OUTREG(R128_DST_Y_X, (y << 16) | x); OUTREG(R128_BRUSH_Y_X, (phase << 16) | phase); OUTREG(R128_DST_BRES_ERR, err); OUTREG(R128_DST_BRES_INC, minor); OUTREG(R128_DST_BRES_DEC, -major); OUTREG(R128_DST_BRES_LNTH, len); } #if R128_TRAPEZOIDS /* This doesn't work. Except in the lower-left quadrant, all of the pixel errors appear to be because eL and eR are not correct. Drawing from right to left doesn't help. Be aware that the non-_SUB registers set the sub-pixel values to 0.5 (0x08), which isn't what XAA wants. */ /* Subsequent XAA SolidFillTrap. XAA always passes data that assumes we fill from top to bottom, so dyL and dyR are always non-negative. */ static void R128SubsequentSolidFillTrap(ScrnInfoPtr pScrn, int y, int h, int left, int dxL, int dyL, int eL, int right, int dxR, int dyR, int eR) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; int flags = 0; int Lymajor = 0; int Rymajor = 0; int origdxL = dxL; int origdxR = dxR; R128TRACE(("Trap %d %d; L %d %d %d %d; R %d %d %d %d\n", y, h, left, dxL, dyL, eL, right, dxR, dyR, eR)); if (dxL < 0) dxL = -dxL; else flags |= (1 << 0) /* | (1 << 8) */; if (dxR < 0) dxR = -dxR; else flags |= (1 << 6); R128WaitForFifo(pScrn, 11); #if 1 OUTREG(R128_DP_CNTL, flags | (1 << 1) | (1 << 7)); OUTREG(R128_DST_Y_SUB, ((y) << 4) | 0x0 ); OUTREG(R128_DST_X_SUB, ((left) << 4)|0x0); OUTREG(R128_TRAIL_BRES_ERR, eR-dxR); OUTREG(R128_TRAIL_BRES_INC, dxR); OUTREG(R128_TRAIL_BRES_DEC, -dyR); OUTREG(R128_TRAIL_X_SUB, ((right) << 4) | 0x0); OUTREG(R128_LEAD_BRES_ERR, eL-dxL); OUTREG(R128_LEAD_BRES_INC, dxL); OUTREG(R128_LEAD_BRES_DEC, -dyL); OUTREG(R128_LEAD_BRES_LNTH_SUB, ((h) << 4) | 0x00); #else OUTREG(R128_DP_CNTL, flags | (1 << 1) ); OUTREG(R128_DST_Y_SUB, (y << 4)); OUTREG(R128_DST_X_SUB, (right << 4)); OUTREG(R128_TRAIL_BRES_ERR, eL); OUTREG(R128_TRAIL_BRES_INC, dxL); OUTREG(R128_TRAIL_BRES_DEC, -dyL); OUTREG(R128_TRAIL_X_SUB, (left << 4) | 0); OUTREG(R128_LEAD_BRES_ERR, eR); OUTREG(R128_LEAD_BRES_INC, dxR); OUTREG(R128_LEAD_BRES_DEC, -dyR); OUTREG(R128_LEAD_BRES_LNTH_SUB, h << 4); #endif } #endif /* Setup for XAA screen-to-screen copy. Tests: xtest CH06/fllrctngl (also tests transparency). */ static void R128SetupForScreenToScreenCopy(ScrnInfoPtr pScrn, int xdir, int ydir, int rop, unsigned int planemask, int trans_color) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; info->xdir = xdir; info->ydir = ydir; R128WaitForFifo(pScrn, 3); OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_BRUSH_SOLID_COLOR | R128_GMC_SRC_DATATYPE_COLOR | R128_ROP[rop].rop | R128_DP_SRC_SOURCE_MEMORY)); OUTREG(R128_DP_WRITE_MASK, planemask); OUTREG(R128_DP_CNTL, ((xdir >= 0 ? R128_DST_X_LEFT_TO_RIGHT : 0) | (ydir >= 0 ? R128_DST_Y_TOP_TO_BOTTOM : 0))); if ((trans_color != -1) || (info->XAAForceTransBlit == TRUE)) { /* Set up for transparency */ R128WaitForFifo(pScrn, 3); OUTREG(R128_CLR_CMP_CLR_SRC, trans_color); OUTREG(R128_CLR_CMP_MASK, R128_CLR_CMP_MSK); OUTREG(R128_CLR_CMP_CNTL, (R128_SRC_CMP_NEQ_COLOR | R128_CLR_CMP_SRC_SOURCE)); } } /* Subsequent XAA screen-to-screen copy. */ static void R128SubsequentScreenToScreenCopy(ScrnInfoPtr pScrn, int xa, int ya, int xb, int yb, int w, int h) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; if (info->xdir < 0) xa += w - 1, xb += w - 1; if (info->ydir < 0) ya += h - 1, yb += h - 1; R128WaitForFifo(pScrn, 3); OUTREG(R128_SRC_Y_X, (ya << 16) | xa); OUTREG(R128_DST_Y_X, (yb << 16) | xb); OUTREG(R128_DST_HEIGHT_WIDTH, (h << 16) | w); } /* Setup for XAA mono 8x8 pattern color expansion. Patterns with transparency use `bg == -1'. This routine is only used if the XAA pixmap cache is turned on. Tests: xtest XFree86/fllrctngl (no other test will test this routine with both transparency and non-transparency) 1024x768@76Hz 8bpp Without With x11perf -srect100 38600.0/sec 85700.0/sec x11perf -osrect100 38600.0/sec 85700.0/sec */ static void R128SetupForMono8x8PatternFill(ScrnInfoPtr pScrn, int patternx, int patterny, int fg, int bg, int rop, unsigned int planemask) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128WaitForFifo(pScrn, 6); OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | (bg == -1 ? R128_GMC_BRUSH_8X8_MONO_FG_LA : R128_GMC_BRUSH_8X8_MONO_FG_BG) | R128_ROP[rop].pattern | R128_GMC_BYTE_LSB_TO_MSB)); OUTREG(R128_DP_WRITE_MASK, planemask); OUTREG(R128_DP_BRUSH_FRGD_CLR, fg); OUTREG(R128_DP_BRUSH_BKGD_CLR, bg); OUTREG(R128_BRUSH_DATA0, patternx); OUTREG(R128_BRUSH_DATA1, patterny); } /* Subsequent XAA 8x8 pattern color expansion. Because they are used in the setup function, `patternx' and `patterny' are not used here. */ static void R128SubsequentMono8x8PatternFillRect(ScrnInfoPtr pScrn, int patternx, int patterny, int x, int y, int w, int h) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128WaitForFifo(pScrn, 3); OUTREG(R128_BRUSH_Y_X, (patterny << 8) | patternx); OUTREG(R128_DST_Y_X, (y << 16) | x); OUTREG(R128_DST_HEIGHT_WIDTH, (h << 16) | w); } #if 0 /* Setup for XAA color 8x8 pattern fill. Tests: xtest XFree86/fllrctngl (with Mono8x8PatternFill off) */ static void R128SetupForColor8x8PatternFill(ScrnInfoPtr pScrn, int patx, int paty, int rop, unsigned int planemask, int trans_color) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128TRACE(("Color8x8 %d %d %d\n", trans_color, patx, paty)); R128WaitForFifo(pScrn, 2); OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_BRUSH_8x8_COLOR | R128_GMC_SRC_DATATYPE_COLOR | R128_ROP[rop].rop | R128_DP_SRC_SOURCE_MEMORY)); OUTREG(R128_DP_WRITE_MASK, planemask); if (trans_color != -1) { /* Set up for transparency */ R128WaitForFifo(pScrn, 3); OUTREG(R128_CLR_CMP_CLR_SRC, trans_color); OUTREG(R128_CLR_CMP_MASK, R128_CLR_CMP_MSK); OUTREG(R128_CLR_CMP_CNTL, (R128_SRC_CMP_NEQ_COLOR | R128_CLR_CMP_SRC_SOURCE)); } } /* Subsequent XAA 8x8 pattern color expansion. */ static void R128SubsequentColor8x8PatternFillRect( ScrnInfoPtr pScrn, int patx, int paty, int x, int y, int w, int h) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128TRACE(("Color8x8 %d,%d %d,%d %d %d\n", patx, paty, x, y, w, h)); R128WaitForFifo(pScrn, 3); OUTREG(R128_SRC_Y_X, (paty << 16) | patx); OUTREG(R128_DST_Y_X, (y << 16) | x); OUTREG(R128_DST_HEIGHT_WIDTH, (h << 16) | w); } #endif /* Setup for XAA indirect CPU-to-screen color expansion (indirect). Because of how the scratch buffer is initialized, this is really a mainstore-to-screen color expansion. Transparency is supported when `bg == -1'. x11perf -ftext (pure indirect): 1024x768@76Hz 1024x768@76Hz 8bpp 32bpp not used: 685000.0/sec 794000.0/sec used: 1070000.0/sec 1080000.0/sec We could improve this indirect routine by about 10% if the hardware could accept DWORD padded scanlines, or if XAA could provide bit-packed data. We might also be able to move to a direct routine if there were more HOST_DATA registers. Implementing the hybrid indirect/direct scheme improved performance in a few areas: 1024x768@76 8bpp Indirect Hybrid x11perf -oddsrect10 50100.0/sec 71700.0/sec x11perf -oddsrect100 4240.0/sec 6660.0/sec x11perf -bigsrect10 50300.0/sec 71100.0/sec x11perf -bigsrect100 4190.0/sec 6800.0/sec x11perf -polytext 584000.0/sec 714000.0/sec x11perf -polytext16 154000.0/sec 172000.0/sec x11perf -seg1 1780000.0/sec 1880000.0/sec x11perf -copyplane10 42900.0/sec 58300.0/sec x11perf -copyplane100 4400.0/sec 6710.0/sec x11perf -putimagexy10 5090.0/sec 6670.0/sec x11perf -putimagexy100 424.0/sec 575.0/sec 1024x768@76 -depth 24 -fbbpp 32 Indirect Hybrid x11perf -oddsrect100 4240.0/sec 6670.0/sec x11perf -bigsrect100 4190.0/sec 6800.0/sec x11perf -polytext 585000.0/sec 719000.0/sec x11perf -seg1 2960000.0/sec 2990000.0/sec x11perf -copyplane100 4400.0/sec 6700.0/sec x11perf -putimagexy100 138.0/sec 191.0/sec */ static void R128SetupForScanlineCPUToScreenColorExpandFill(ScrnInfoPtr pScrn, int fg, int bg, int rop, unsigned int planemask) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128WaitForFifo(pScrn, 4); #if X_BYTE_ORDER == X_LITTLE_ENDIAN OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_DST_CLIPPING | R128_GMC_BRUSH_NONE | (bg == -1 ? R128_GMC_SRC_DATATYPE_MONO_FG_LA : R128_GMC_SRC_DATATYPE_MONO_FG_BG) | R128_ROP[rop].rop | R128_GMC_BYTE_LSB_TO_MSB | R128_DP_SRC_SOURCE_HOST_DATA)); #else /* X_BYTE_ORDER == X_BIG_ENDIAN */ OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_DST_CLIPPING | R128_GMC_BRUSH_NONE | (bg == -1 ? R128_GMC_SRC_DATATYPE_MONO_FG_LA : R128_GMC_SRC_DATATYPE_MONO_FG_BG) | R128_ROP[rop].rop | R128_DP_SRC_SOURCE_HOST_DATA)); #endif OUTREG(R128_DP_WRITE_MASK, planemask); OUTREG(R128_DP_SRC_FRGD_CLR, fg); OUTREG(R128_DP_SRC_BKGD_CLR, bg); } /* Subsequent XAA indirect CPU-to-screen color expansion. This is only called once for each rectangle. */ static void R128SubsequentScanlineCPUToScreenColorExpandFill(ScrnInfoPtr pScrn, int x, int y, int w, int h, int skipleft) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; int x1clip = x+skipleft; int x2clip = x+w; info->scanline_h = h; info->scanline_words = (w + 31) >> 5; #if 0 /* Seems as though the Rage128's doesn't like blitting directly * as we must be overwriting something too quickly, therefore we * render to the buffer first and then blit */ if ((info->scanline_words * h) <= 9) { /* Turn on direct for less than 9 dword colour expansion */ info->scratch_buffer[0] = (unsigned char *)(ADDRREG(R128_HOST_DATA_LAST) - (info->scanline_words - 1)); info->scanline_direct = 1; } else #endif { /* Use indirect for anything else */ info->scratch_buffer[0] = info->scratch_save; info->scanline_direct = 0; } if (pScrn->bitsPerPixel == 24) { x1clip *= 3; x2clip *= 3; } R128WaitForFifo(pScrn, 4 + (info->scanline_direct ? (info->scanline_words * h) : 0) ); OUTREG(R128_SC_TOP_LEFT, (y << 16) | (x1clip & 0xffff)); OUTREG(R128_SC_BOTTOM_RIGHT, ((y+h-1) << 16) | ((x2clip-1) & 0xffff)); OUTREG(R128_DST_Y_X, (y << 16) | (x & 0xffff)); /* Have to pad the width here and use clipping engine */ OUTREG(R128_DST_HEIGHT_WIDTH, (h << 16) | ((w + 31) & ~31)); } /* Subsequent XAA indirect CPU-to-screen color expansion. This is called once for each scanline. */ static void R128SubsequentColorExpandScanline(ScrnInfoPtr pScrn, int bufno) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; CARD32 *p = (pointer)info->scratch_buffer[bufno]; int i; int left = info->scanline_words; volatile CARD32 *d; if (info->scanline_direct) return; --info->scanline_h; while (left) { write_mem_barrier(); if (left <= 8) { /* Last scanline - finish write to DATA_LAST */ if (info->scanline_h == 0) { R128WaitForFifo(pScrn, left); /* Unrolling doesn't improve performance */ for (d = ADDRREG(R128_HOST_DATA_LAST) - (left - 1); left; --left) *d++ = *p++; return; } else { R128WaitForFifo(pScrn, left); /* Unrolling doesn't improve performance */ for (d = ADDRREG(R128_HOST_DATA7) - (left - 1); left; --left) *d++ = *p++; } } else { R128WaitForFifo(pScrn, 8); /* Unrolling doesn't improve performance */ for (d = ADDRREG(R128_HOST_DATA0), i = 0; i < 8; i++) *d++ = *p++; left -= 8; } } } /* Setup for XAA indirect image write. 1024x768@76Hz 8bpp Without With x11perf -putimage10 37500.0/sec 39300.0/sec x11perf -putimage100 2150.0/sec 1170.0/sec x11perf -putimage500 108.0/sec 49.8/sec */ static void R128SetupForScanlineImageWrite(ScrnInfoPtr pScrn, int rop, unsigned int planemask, int trans_color, int bpp, int depth) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; info->scanline_bpp = bpp; R128WaitForFifo(pScrn, 2); OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_DST_CLIPPING | R128_GMC_BRUSH_1X8_COLOR | R128_GMC_SRC_DATATYPE_COLOR | R128_ROP[rop].rop | R128_GMC_BYTE_LSB_TO_MSB | R128_DP_SRC_SOURCE_HOST_DATA)); OUTREG(R128_DP_WRITE_MASK, planemask); if (trans_color != -1) { /* Set up for transparency */ R128WaitForFifo(pScrn, 3); OUTREG(R128_CLR_CMP_CLR_SRC, trans_color); OUTREG(R128_CLR_CMP_MASK, R128_CLR_CMP_MSK); OUTREG(R128_CLR_CMP_CNTL, (R128_SRC_CMP_NEQ_COLOR | R128_CLR_CMP_SRC_SOURCE)); } } /* Subsequent XAA indirect image write. This is only called once for each rectangle. */ static void R128SubsequentScanlineImageWriteRect(ScrnInfoPtr pScrn, int x, int y, int w, int h, int skipleft) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; int x1clip = x+skipleft; int x2clip = x+w; int shift = 0; /* 32bpp */ if (pScrn->bitsPerPixel == 8) shift = 3; else if (pScrn->bitsPerPixel == 16) shift = 1; info->scanline_h = h; info->scanline_words = (w * info->scanline_bpp + 31) >> 5; #if 0 /* Seeing as the CPUToScreen doesn't like this, I've done this * here too, as it uses pretty much the same path. */ if ((info->scanline_words * h) <= 9) { /* Turn on direct for less than 9 dword colour expansion */ info->scratch_buffer[0] = (unsigned char *)(ADDRREG(R128_HOST_DATA_LAST) - (info->scanline_words - 1)); info->scanline_direct = 1; } else #endif { /* Use indirect for anything else */ info->scratch_buffer[0] = info->scratch_save; info->scanline_direct = 0; } if (pScrn->bitsPerPixel == 24) { x1clip *= 3; x2clip *= 3; } R128WaitForFifo(pScrn, 4 + (info->scanline_direct ? (info->scanline_words * h) : 0) ); OUTREG(R128_SC_TOP_LEFT, (y << 16) | (x1clip & 0xffff)); OUTREG(R128_SC_BOTTOM_RIGHT, ((y+h-1) << 16) | ((x2clip-1) & 0xffff)); OUTREG(R128_DST_Y_X, (y << 16) | (x & 0xffff)); /* Have to pad the width here and use clipping engine */ OUTREG(R128_DST_HEIGHT_WIDTH, (h << 16) | ((w + shift) & ~shift)); } /* Subsequent XAA indirect iamge write. This is called once for each scanline. */ static void R128SubsequentImageWriteScanline(ScrnInfoPtr pScrn, int bufno) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; CARD32 *p = (pointer)info->scratch_buffer[bufno]; int i; int left = info->scanline_words; volatile CARD32 *d; if (info->scanline_direct) return; --info->scanline_h; while (left) { write_mem_barrier(); if (left <= 8) { /* Last scanline - finish write to DATA_LAST */ if (info->scanline_h == 0) { R128WaitForFifo(pScrn, left); /* Unrolling doesn't improve performance */ for (d = ADDRREG(R128_HOST_DATA_LAST) - (left - 1); left; --left) *d++ = *p++; return; } else { R128WaitForFifo(pScrn, left); /* Unrolling doesn't improve performance */ for (d = ADDRREG(R128_HOST_DATA7) - (left - 1); left; --left) *d++ = *p++; } } else { R128WaitForFifo(pScrn, 8); /* Unrolling doesn't improve performance */ for (d = ADDRREG(R128_HOST_DATA0), i = 0; i < 8; i++) *d++ = *p++; left -= 8; } } } /* Initialize the acceleration hardware. */ void R128EngineInit(ScrnInfoPtr pScrn) { R128InfoPtr info = R128PTR(pScrn); unsigned char *R128MMIO = info->MMIO; R128TRACE(("EngineInit (%d/%d)\n", info->CurrentLayout.pixel_code, info->CurrentLayout.bitsPerPixel)); OUTREG(R128_SCALE_3D_CNTL, 0); R128EngineReset(pScrn); switch (info->CurrentLayout.pixel_code) { case 8: info->datatype = 2; break; case 15: info->datatype = 3; break; case 16: info->datatype = 4; break; case 24: info->datatype = 5; break; case 32: info->datatype = 6; break; default: R128TRACE(("Unknown depth/bpp = %d/%d (code = %d)\n", info->CurrentLayout.depth, info->CurrentLayout.bitsPerPixel, info->CurrentLayout.pixel_code)); } info->pitch = (info->CurrentLayout.displayWidth / 8) * (info->CurrentLayout.pixel_bytes == 3 ? 3 : 1); R128TRACE(("Pitch for acceleration = %d\n", info->pitch)); R128WaitForFifo(pScrn, 2); OUTREG(R128_DEFAULT_OFFSET, 0); OUTREG(R128_DEFAULT_PITCH, info->pitch); R128WaitForFifo(pScrn, 4); OUTREG(R128_AUX_SC_CNTL, 0); OUTREG(R128_DEFAULT_SC_BOTTOM_RIGHT, (R128_DEFAULT_SC_RIGHT_MAX | R128_DEFAULT_SC_BOTTOM_MAX)); OUTREG(R128_SC_TOP_LEFT, 0); OUTREG(R128_SC_BOTTOM_RIGHT, (R128_DEFAULT_SC_RIGHT_MAX | R128_DEFAULT_SC_BOTTOM_MAX)); info->dp_gui_master_cntl = ((info->datatype << R128_GMC_DST_DATATYPE_SHIFT) | R128_GMC_CLR_CMP_CNTL_DIS | R128_GMC_AUX_CLIP_DIS); R128WaitForFifo(pScrn, 1); OUTREG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_BRUSH_SOLID_COLOR | R128_GMC_SRC_DATATYPE_COLOR)); R128WaitForFifo(pScrn, 8); OUTREG(R128_DST_BRES_ERR, 0); OUTREG(R128_DST_BRES_INC, 0); OUTREG(R128_DST_BRES_DEC, 0); OUTREG(R128_DP_BRUSH_FRGD_CLR, 0xffffffff); OUTREG(R128_DP_BRUSH_BKGD_CLR, 0x00000000); OUTREG(R128_DP_SRC_FRGD_CLR, 0xffffffff); OUTREG(R128_DP_SRC_BKGD_CLR, 0x00000000); OUTREG(R128_DP_WRITE_MASK, 0xffffffff); R128WaitForFifo(pScrn, 1); #if X_BYTE_ORDER == X_BIG_ENDIAN /* FIXME: this is a kludge for texture uploads in the 3D driver. Look at * how the radeon driver handles HOST_DATA_SWAP if you want to implement * CCE ImageWrite acceleration or anything needing this bit */ #ifdef XF86DRI if (info->directRenderingEnabled) OUTREGP(R128_DP_DATATYPE, 0, ~R128_HOST_BIG_ENDIAN_EN); else #endif OUTREGP(R128_DP_DATATYPE, R128_HOST_BIG_ENDIAN_EN, ~R128_HOST_BIG_ENDIAN_EN); #else /* X_LITTLE_ENDIAN */ OUTREGP(R128_DP_DATATYPE, 0, ~R128_HOST_BIG_ENDIAN_EN); #endif #ifdef XF86DRI info->sc_left = 0x00000000; info->sc_right = R128_DEFAULT_SC_RIGHT_MAX; info->sc_top = 0x00000000; info->sc_bottom = R128_DEFAULT_SC_BOTTOM_MAX; info->re_top_left = 0x00000000; info->re_width_height = ((0x7ff << R128_RE_WIDTH_SHIFT) | (0x7ff << R128_RE_HEIGHT_SHIFT)); info->aux_sc_cntl = 0x00000000; #endif R128WaitForIdle(pScrn); } #ifdef XF86DRI /* Setup for XAA SolidFill. */ static void R128CCESetupForSolidFill(ScrnInfoPtr pScrn, int color, int rop, unsigned int planemask) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); BEGIN_RING( 8 ); OUT_RING_REG( R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_BRUSH_SOLID_COLOR | R128_GMC_SRC_DATATYPE_COLOR | R128_ROP[rop].pattern) ); OUT_RING_REG( R128_DP_BRUSH_FRGD_CLR, color ); OUT_RING_REG( R128_DP_WRITE_MASK, planemask ); OUT_RING_REG( R128_DP_CNTL, (R128_DST_X_LEFT_TO_RIGHT | R128_DST_Y_TOP_TO_BOTTOM)); ADVANCE_RING(); } /* Subsequent XAA SolidFillRect. Tests: xtest CH06/fllrctngl, xterm */ static void R128CCESubsequentSolidFillRect(ScrnInfoPtr pScrn, int x, int y, int w, int h) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); BEGIN_RING( 4 ); OUT_RING_REG( R128_DST_Y_X, (y << 16) | x ); OUT_RING_REG( R128_DST_WIDTH_HEIGHT, (w << 16) | h ); ADVANCE_RING(); } /* Setup for XAA screen-to-screen copy. Tests: xtest CH06/fllrctngl (also tests transparency). */ static void R128CCESetupForScreenToScreenCopy(ScrnInfoPtr pScrn, int xdir, int ydir, int rop, unsigned int planemask, int trans_color) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); info->xdir = xdir; info->ydir = ydir; BEGIN_RING( 6 ); OUT_RING_REG( R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_BRUSH_NONE | R128_GMC_SRC_DATATYPE_COLOR | R128_ROP[rop].rop | R128_DP_SRC_SOURCE_MEMORY) ); OUT_RING_REG( R128_DP_WRITE_MASK, planemask ); OUT_RING_REG( R128_DP_CNTL, ((xdir >= 0 ? R128_DST_X_LEFT_TO_RIGHT : 0) | (ydir >= 0 ? R128_DST_Y_TOP_TO_BOTTOM : 0)) ); ADVANCE_RING(); if ((trans_color != -1) || (info->XAAForceTransBlit == TRUE)) { BEGIN_RING( 6 ); OUT_RING_REG( R128_CLR_CMP_CLR_SRC, trans_color ); OUT_RING_REG( R128_CLR_CMP_MASK, R128_CLR_CMP_MSK ); OUT_RING_REG( R128_CLR_CMP_CNTL, (R128_SRC_CMP_NEQ_COLOR | R128_CLR_CMP_SRC_SOURCE) ); ADVANCE_RING(); } } /* Subsequent XAA screen-to-screen copy. */ static void R128CCESubsequentScreenToScreenCopy(ScrnInfoPtr pScrn, int xa, int ya, int xb, int yb, int w, int h) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); if (info->xdir < 0) xa += w - 1, xb += w - 1; if (info->ydir < 0) ya += h - 1, yb += h - 1; BEGIN_RING( 6 ); OUT_RING_REG( R128_SRC_Y_X, (ya << 16) | xa ); OUT_RING_REG( R128_DST_Y_X, (yb << 16) | xb ); OUT_RING_REG( R128_DST_HEIGHT_WIDTH, (h << 16) | w ); ADVANCE_RING(); } /* * XAA scanline color expansion * * We use HOSTDATA_BLT CCE packets, dividing the image in chunks that fit into * the indirect buffer if necessary. */ static void R128CCESetupForScanlineCPUToScreenColorExpandFill(ScrnInfoPtr pScrn, int fg, int bg, int rop, unsigned int planemask) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); BEGIN_RING( 2 ); OUT_RING_REG(R128_DP_WRITE_MASK, planemask); ADVANCE_RING(); info->scanline_rop = rop; info->scanline_fg = fg; info->scanline_bg = bg; } /* Helper function to write out a HOSTDATA_BLT packet into the indirect buffer and set the XAA scratch buffer address appropriately */ static void R128CCEScanlineCPUToScreenColorExpandFillPacket(ScrnInfoPtr pScrn, int bufno) { R128InfoPtr info = R128PTR(pScrn); int chunk_words = info->scanline_hpass * info->scanline_words; RING_LOCALS; R128CCE_REFRESH( pScrn, info ); BEGIN_RING( chunk_words+9 ); OUT_RING( CCE_PACKET3( R128_CCE_PACKET3_CNTL_HOSTDATA_BLT, chunk_words+9-2 ) ); #if X_BYTE_ORDER == X_LITTLE_ENDIAN OUT_RING( (info->dp_gui_master_cntl | R128_GMC_DST_CLIPPING | R128_GMC_BRUSH_NONE | (info->scanline_bg == -1 ? R128_GMC_SRC_DATATYPE_MONO_FG_LA : R128_GMC_SRC_DATATYPE_MONO_FG_BG) | R128_ROP[info->scanline_rop].rop | R128_GMC_BYTE_LSB_TO_MSB | R128_DP_SRC_SOURCE_HOST_DATA)); #else /* X_BYTE_ORDER == X_BIG_ENDIAN */ OUT_RING( (info->dp_gui_master_cntl | R128_GMC_DST_CLIPPING | R128_GMC_BRUSH_NONE | (info->scanline_bg == -1 ? R128_GMC_SRC_DATATYPE_MONO_FG_LA : R128_GMC_SRC_DATATYPE_MONO_FG_BG) | R128_ROP[info->scanline_rop].rop | R128_DP_SRC_SOURCE_HOST_DATA)); #endif OUT_RING( (info->scanline_y << 16) | (info->scanline_x1clip & 0xffff) ); OUT_RING( ((info->scanline_y+info->scanline_hpass-1) << 16) | ((info->scanline_x2clip-1) & 0xffff) ); OUT_RING( info->scanline_fg ); OUT_RING( info->scanline_bg ); OUT_RING( (info->scanline_y << 16) | (info->scanline_x & 0xffff)); /* Have to pad the width here and use clipping engine */ OUT_RING( (info->scanline_hpass << 16) | ((info->scanline_w + 31) & ~31)); OUT_RING( chunk_words ); info->scratch_buffer[bufno] = (unsigned char *) &__head[__count]; __count += chunk_words; ADVANCE_RING(); info->scanline_y += info->scanline_hpass; info->scanline_h -= info->scanline_hpass; if ( R128_VERBOSE ) xf86DrvMsg( pScrn->scrnIndex, X_INFO, "%s: hpass=%d, words=%d => chunk_words=%d, y=%d, h=%d\n", __FUNCTION__, info->scanline_hpass, info->scanline_words, chunk_words, info->scanline_y, info->scanline_h ); } /* Subsequent XAA indirect CPU-to-screen color expansion. This is only called once for each rectangle. */ static void R128CCESubsequentScanlineCPUToScreenColorExpandFill(ScrnInfoPtr pScrn, int x, int y, int w, int h, int skipleft) { R128InfoPtr info = R128PTR(pScrn); #define BUFSIZE ( R128_BUFFER_SIZE/4-9 ) info->scanline_x = x; info->scanline_y = y; info->scanline_w = w; info->scanline_h = h; info->scanline_x1clip = x+skipleft; info->scanline_x2clip = x+w; info->scanline_words = (w + 31) >> 5; info->scanline_hpass = min(h,(BUFSIZE/info->scanline_words)); if ( R128_VERBOSE ) xf86DrvMsg( pScrn->scrnIndex, X_INFO, "%s: x=%d, y=%d, w=%d, h=%d, skipleft=%d => x1clip=%d, x2clip=%d, hpass=%d, words=%d\n", __FUNCTION__, x, y, w, h, skipleft, info->scanline_x1clip, info->scanline_x2clip, info->scanline_hpass, info->scanline_words ); R128CCEScanlineCPUToScreenColorExpandFillPacket(pScrn, 0); } /* Subsequent XAA indirect CPU-to-screen color expansion. This is called once for each scanline. */ static void R128CCESubsequentColorExpandScanline(ScrnInfoPtr pScrn, int bufno) { R128InfoPtr info = R128PTR(pScrn); if ( R128_VERBOSE ) xf86DrvMsg( pScrn->scrnIndex, X_INFO, "%s enter: scanline_hpass=%d, scanline_h=%d\n", __FUNCTION__, info->scanline_hpass, info->scanline_h ); if (--info->scanline_hpass) { info->scratch_buffer[bufno] += 4 * info->scanline_words; } else if(info->scanline_h) { info->scanline_hpass = min(info->scanline_h,(BUFSIZE/info->scanline_words)); R128CCEScanlineCPUToScreenColorExpandFillPacket(pScrn, bufno); } if ( R128_VERBOSE ) xf86DrvMsg( pScrn->scrnIndex, X_INFO, "%s exit: scanline_hpass=%d, scanline_h=%d\n", __FUNCTION__, info->scanline_hpass, info->scanline_h ); } /* Solid lines */ static void R128CCESetupForSolidLine(ScrnInfoPtr pScrn, int color, int rop, unsigned int planemask) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); BEGIN_RING( 6 ); OUT_RING_REG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | R128_GMC_BRUSH_SOLID_COLOR | R128_GMC_SRC_DATATYPE_COLOR | R128_ROP[rop].pattern)); OUT_RING_REG(R128_DP_BRUSH_FRGD_CLR, color); OUT_RING_REG(R128_DP_WRITE_MASK, planemask); ADVANCE_RING(); } static void R128CCESubsequentSolidBresenhamLine(ScrnInfoPtr pScrn, int x, int y, int major, int minor, int err, int len, int octant) { R128InfoPtr info = R128PTR(pScrn); int flags = 0; RING_LOCALS; R128CCE_REFRESH( pScrn, info ); if (octant & YMAJOR) flags |= R128_DST_Y_MAJOR; if (!(octant & XDECREASING)) flags |= R128_DST_X_DIR_LEFT_TO_RIGHT; if (!(octant & YDECREASING)) flags |= R128_DST_Y_DIR_TOP_TO_BOTTOM; BEGIN_RING( 12 ); OUT_RING_REG(R128_DP_CNTL_XDIR_YDIR_YMAJOR, flags); OUT_RING_REG(R128_DST_Y_X, (y << 16) | x); OUT_RING_REG(R128_DST_BRES_ERR, err); OUT_RING_REG(R128_DST_BRES_INC, minor); OUT_RING_REG(R128_DST_BRES_DEC, -major); OUT_RING_REG(R128_DST_BRES_LNTH, len); ADVANCE_RING(); } static void R128CCESubsequentSolidHorVertLine(ScrnInfoPtr pScrn, int x, int y, int len, int dir ) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); BEGIN_RING( 2 ); OUT_RING_REG(R128_DP_CNTL, (R128_DST_X_LEFT_TO_RIGHT | R128_DST_Y_TOP_TO_BOTTOM)); ADVANCE_RING(); if (dir == DEGREES_0) { R128CCESubsequentSolidFillRect(pScrn, x, y, len, 1); } else { R128CCESubsequentSolidFillRect(pScrn, x, y, 1, len); } } /* Dashed lines */ static void R128CCESetupForDashedLine(ScrnInfoPtr pScrn, int fg, int bg, int rop, unsigned int planemask, int length, unsigned char *pattern) { R128InfoPtr info = R128PTR(pScrn); CARD32 pat = *(CARD32 *)(pointer)pattern; RING_LOCALS; R128CCE_REFRESH( pScrn, info ); #if X_BYTE_ORDER == X_LITTLE_ENDIAN # define PAT_SHIFT(pat,n) pat << n #else # define PAT_SHIFT(pat,n) pat >> n #endif switch (length) { case 2: pat |= PAT_SHIFT(pat,2); /* fall through */ case 4: pat |= PAT_SHIFT(pat,4); /* fall through */ case 8: pat |= PAT_SHIFT(pat,8); /* fall through */ case 16: pat |= PAT_SHIFT(pat,16); } BEGIN_RING( 10 ); OUT_RING_REG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | (bg == -1 ? R128_GMC_BRUSH_32x1_MONO_FG_LA : R128_GMC_BRUSH_32x1_MONO_FG_BG) | R128_ROP[rop].pattern | R128_GMC_BYTE_LSB_TO_MSB)); OUT_RING_REG(R128_DP_WRITE_MASK, planemask); OUT_RING_REG(R128_DP_BRUSH_FRGD_CLR, fg); OUT_RING_REG(R128_DP_BRUSH_BKGD_CLR, bg); OUT_RING_REG(R128_BRUSH_DATA0, pat); ADVANCE_RING(); } static void R128CCESubsequentDashedBresenhamLine(ScrnInfoPtr pScrn, int x, int y, int major, int minor, int err, int len, int octant, int phase) { R128InfoPtr info = R128PTR(pScrn); int flags = 0; RING_LOCALS; R128CCE_REFRESH( pScrn, info ); if (octant & YMAJOR) flags |= R128_DST_Y_MAJOR; if (!(octant & XDECREASING)) flags |= R128_DST_X_DIR_LEFT_TO_RIGHT; if (!(octant & YDECREASING)) flags |= R128_DST_Y_DIR_TOP_TO_BOTTOM; BEGIN_RING( 14 ); OUT_RING_REG(R128_DP_CNTL_XDIR_YDIR_YMAJOR, flags); OUT_RING_REG(R128_DST_Y_X, (y << 16) | x); OUT_RING_REG(R128_BRUSH_Y_X, (phase << 16) | phase); OUT_RING_REG(R128_DST_BRES_ERR, err); OUT_RING_REG(R128_DST_BRES_INC, minor); OUT_RING_REG(R128_DST_BRES_DEC, -major); OUT_RING_REG(R128_DST_BRES_LNTH, len); ADVANCE_RING(); } /* Mono 8x8 pattern color expansion */ static void R128CCESetupForMono8x8PatternFill(ScrnInfoPtr pScrn, int patternx, int patterny, int fg, int bg, int rop, unsigned int planemask) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); BEGIN_RING( 12 ); OUT_RING_REG(R128_DP_GUI_MASTER_CNTL, (info->dp_gui_master_cntl | (bg == -1 ? R128_GMC_BRUSH_8X8_MONO_FG_LA : R128_GMC_BRUSH_8X8_MONO_FG_BG) | R128_ROP[rop].pattern | R128_GMC_BYTE_LSB_TO_MSB)); OUT_RING_REG(R128_DP_WRITE_MASK, planemask); OUT_RING_REG(R128_DP_BRUSH_FRGD_CLR, fg); OUT_RING_REG(R128_DP_BRUSH_BKGD_CLR, bg); OUT_RING_REG(R128_BRUSH_DATA0, patternx); OUT_RING_REG(R128_BRUSH_DATA1, patterny); ADVANCE_RING(); } static void R128CCESubsequentMono8x8PatternFillRect(ScrnInfoPtr pScrn, int patternx, int patterny, int x, int y, int w, int h) { R128InfoPtr info = R128PTR(pScrn); RING_LOCALS; R128CCE_REFRESH( pScrn, info ); BEGIN_RING( 6 ); OUT_RING_REG(R128_BRUSH_Y_X, (patterny << 8) | patternx); OUT_RING_REG(R128_DST_Y_X, (y << 16) | x); OUT_RING_REG(R128_DST_HEIGHT_WIDTH, (h << 16) | w); ADVANCE_RING(); } /* Get an indirect buffer for the CCE 2D acceleration commands. */ drmBufPtr R128CCEGetBuffer( ScrnInfoPtr pScrn ) { R128InfoPtr info = R128PTR(pScrn); drmDMAReq dma; drmBufPtr buf = NULL; int indx = 0; int size = 0; int ret, i = 0; #if 0 /* FIXME: pScrn->pScreen has not been initialized when this is first called from RADEONSelectBuffer via RADEONDRICPInit. We could use the screen index from pScrn, which is initialized, and then get the screen from screenInfo.screens[index], but that is a hack. */ dma.context = DRIGetContext(pScrn->pScreen); #else dma.context = 0x00000001; /* This is the X server's context */ #endif dma.send_count = 0; dma.send_list = NULL; dma.send_sizes = NULL; dma.flags = 0; dma.request_count = 1; dma.request_size = R128_BUFFER_SIZE; dma.request_list = &indx; dma.request_sizes = &size; dma.granted_count = 0; while ( 1 ) { do { ret = drmDMA( info->drmFD, &dma ); if ( ret && ret != -EAGAIN ) { xf86DrvMsg( pScrn->scrnIndex, X_ERROR, "%s: CCE GetBuffer %d\n", __FUNCTION__, ret ); } } while ( ( ret == -EAGAIN ) && ( i++ < R128_TIMEOUT ) ); if ( ret == 0 ) { buf = &info->buffers->list[indx]; buf->used = 0; if ( R128_VERBOSE ) { xf86DrvMsg( pScrn->scrnIndex, X_INFO, " GetBuffer returning %d\n", buf->idx ); } return buf; } xf86DrvMsg( pScrn->scrnIndex, X_ERROR, "GetBuffer timed out, resetting engine...\n"); R128EngineReset( pScrn ); /* R128EngineRestore( pScrn ); FIXME ??? */ /* Always restart the engine when doing CCE 2D acceleration */ R128CCE_RESET( pScrn, info ); R128CCE_START( pScrn, info ); } } /* Flush the indirect buffer to the kernel for submission to the card. */ void R128CCEFlushIndirect( ScrnInfoPtr pScrn, int discard ) { R128InfoPtr info = R128PTR(pScrn); drmBufPtr buffer = info->indirectBuffer; int start = info->indirectStart; drmR128Indirect indirect; if ( !buffer ) return; if ( (start == buffer->used) && !discard ) return; indirect.idx = buffer->idx; indirect.start = start; indirect.end = buffer->used; indirect.discard = discard; drmCommandWriteRead( info->drmFD, DRM_R128_INDIRECT, &indirect, sizeof(drmR128Indirect)); if ( discard ) buffer = info->indirectBuffer = R128CCEGetBuffer( pScrn ); /* pad to an even number of dwords */ if (buffer->used & 7) buffer->used = ( buffer->used+7 ) & ~7; info->indirectStart = buffer->used; } /* Flush and release the indirect buffer. */ void R128CCEReleaseIndirect( ScrnInfoPtr pScrn ) { R128InfoPtr info = R128PTR(pScrn); drmBufPtr buffer = info->indirectBuffer; int start = info->indirectStart; drmR128Indirect indirect; info->indirectBuffer = NULL; info->indirectStart = 0; if ( !buffer ) return; indirect.idx = buffer->idx; indirect.start = start; indirect.end = buffer->used; indirect.discard = 1; drmCommandWriteRead( info->drmFD, DRM_R128_INDIRECT, &indirect, sizeof(drmR128Indirect)); } static void R128CCEAccelInit(ScrnInfoPtr pScrn, XAAInfoRecPtr a) { R128InfoPtr info = R128PTR(pScrn); a->Flags = (PIXMAP_CACHE | OFFSCREEN_PIXMAPS | LINEAR_FRAMEBUFFER); /* Sync */ a->Sync = R128CCEWaitForIdle; /* Solid Filled Rectangle */ a->PolyFillRectSolidFlags = 0; a->SetupForSolidFill = R128CCESetupForSolidFill; a->SubsequentSolidFillRect = R128CCESubsequentSolidFillRect; /* Screen-to-screen Copy */ /* Transparency uses the wrong colors for 24 bpp mode -- the transparent part is correct, but the opaque color is wrong. This can be seen with netscape's I-bar cursor when editing in the URL location box. */ a->ScreenToScreenCopyFlags = ((pScrn->bitsPerPixel == 24) ? NO_TRANSPARENCY : 0); a->SetupForScreenToScreenCopy = R128CCESetupForScreenToScreenCopy; a->SubsequentScreenToScreenCopy = R128CCESubsequentScreenToScreenCopy; /* Indirect CPU-To-Screen Color Expand */ a->ScanlineCPUToScreenColorExpandFillFlags = LEFT_EDGE_CLIPPING | LEFT_EDGE_CLIPPING_NEGATIVE_X; a->NumScanlineColorExpandBuffers = 1; a->ScanlineColorExpandBuffers = info->scratch_buffer; info->scratch_buffer[0] = NULL; a->SetupForScanlineCPUToScreenColorExpandFill = R128CCESetupForScanlineCPUToScreenColorExpandFill; a->SubsequentScanlineCPUToScreenColorExpandFill = R128CCESubsequentScanlineCPUToScreenColorExpandFill; a->SubsequentColorExpandScanline = R128CCESubsequentColorExpandScanline; /* Bresenham Solid Lines */ a->SetupForSolidLine = R128CCESetupForSolidLine; a->SubsequentSolidBresenhamLine = R128CCESubsequentSolidBresenhamLine; a->SubsequentSolidHorVertLine = R128CCESubsequentSolidHorVertLine; /* Bresenham Dashed Lines*/ a->SetupForDashedLine = R128CCESetupForDashedLine; a->SubsequentDashedBresenhamLine = R128CCESubsequentDashedBresenhamLine; a->DashPatternMaxLength = 32; a->DashedLineFlags = (LINE_PATTERN_LSBFIRST_LSBJUSTIFIED | LINE_PATTERN_POWER_OF_2_ONLY); /* Mono 8x8 Pattern Fill (Color Expand) */ a->SetupForMono8x8PatternFill = R128CCESetupForMono8x8PatternFill; a->SubsequentMono8x8PatternFillRect = R128CCESubsequentMono8x8PatternFillRect; a->Mono8x8PatternFillFlags = (HARDWARE_PATTERN_PROGRAMMED_BITS | HARDWARE_PATTERN_PROGRAMMED_ORIGIN | HARDWARE_PATTERN_SCREEN_ORIGIN | BIT_ORDER_IN_BYTE_LSBFIRST); } #endif static void R128MMIOAccelInit(ScrnInfoPtr pScrn, XAAInfoRecPtr a) { R128InfoPtr info = R128PTR(pScrn); a->Flags = (PIXMAP_CACHE | OFFSCREEN_PIXMAPS | LINEAR_FRAMEBUFFER); /* Sync */ a->Sync = R128WaitForIdle; /* Solid Filled Rectangle */ a->PolyFillRectSolidFlags = 0; a->SetupForSolidFill = R128SetupForSolidFill; a->SubsequentSolidFillRect = R128SubsequentSolidFillRect; /* Screen-to-screen Copy */ /* Transparency uses the wrong colors for 24 bpp mode -- the transparent part is correct, but the opaque color is wrong. This can be seen with netscape's I-bar cursor when editing in the URL location box. */ a->ScreenToScreenCopyFlags = ((pScrn->bitsPerPixel == 24) ? NO_TRANSPARENCY : 0); a->SetupForScreenToScreenCopy = R128SetupForScreenToScreenCopy; a->SubsequentScreenToScreenCopy = R128SubsequentScreenToScreenCopy; /* Mono 8x8 Pattern Fill (Color Expand) */ a->SetupForMono8x8PatternFill = R128SetupForMono8x8PatternFill; a->SubsequentMono8x8PatternFillRect = R128SubsequentMono8x8PatternFillRect; a->Mono8x8PatternFillFlags = (HARDWARE_PATTERN_PROGRAMMED_BITS | HARDWARE_PATTERN_PROGRAMMED_ORIGIN | HARDWARE_PATTERN_SCREEN_ORIGIN | BIT_ORDER_IN_BYTE_LSBFIRST); /* Indirect CPU-To-Screen Color Expand */ a->ScanlineCPUToScreenColorExpandFillFlags = LEFT_EDGE_CLIPPING | LEFT_EDGE_CLIPPING_NEGATIVE_X; a->NumScanlineColorExpandBuffers = 1; a->ScanlineColorExpandBuffers = info->scratch_buffer; info->scratch_save = xalloc(((pScrn->virtualX+31)/32*4) + (pScrn->virtualX * info->CurrentLayout.pixel_bytes)); info->scratch_buffer[0] = info->scratch_save; a->SetupForScanlineCPUToScreenColorExpandFill = R128SetupForScanlineCPUToScreenColorExpandFill; a->SubsequentScanlineCPUToScreenColorExpandFill = R128SubsequentScanlineCPUToScreenColorExpandFill; a->SubsequentColorExpandScanline = R128SubsequentColorExpandScanline; /* Bresenham Solid Lines */ a->SetupForSolidLine = R128SetupForSolidLine; a->SubsequentSolidBresenhamLine = R128SubsequentSolidBresenhamLine; a->SubsequentSolidHorVertLine = R128SubsequentSolidHorVertLine; /* Bresenham Dashed Lines*/ a->SetupForDashedLine = R128SetupForDashedLine; a->SubsequentDashedBresenhamLine = R128SubsequentDashedBresenhamLine; a->DashPatternMaxLength = 32; a->DashedLineFlags = (LINE_PATTERN_LSBFIRST_LSBJUSTIFIED | LINE_PATTERN_POWER_OF_2_ONLY); /* ImageWrite */ a->NumScanlineImageWriteBuffers = 1; a->ScanlineImageWriteBuffers = info->scratch_buffer; info->scratch_buffer[0] = info->scratch_save; a->SetupForScanlineImageWrite = R128SetupForScanlineImageWrite; a->SubsequentScanlineImageWriteRect= R128SubsequentScanlineImageWriteRect; a->SubsequentImageWriteScanline = R128SubsequentImageWriteScanline; a->ScanlineImageWriteFlags = CPU_TRANSFER_PAD_DWORD /* Performance tests show that we shouldn't use GXcopy for * uploads as a memcpy is faster */ | NO_GXCOPY | LEFT_EDGE_CLIPPING | LEFT_EDGE_CLIPPING_NEGATIVE_X | SCANLINE_PAD_DWORD; } /* Initialize XAA for supported acceleration and also initialize the graphics hardware for acceleration. */ Bool R128AccelInit(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; R128InfoPtr info = R128PTR(pScrn); XAAInfoRecPtr a; if (!(a = info->accel = XAACreateInfoRec())) return FALSE; #ifdef XF86DRI if (info->directRenderingEnabled) R128CCEAccelInit(pScrn, a); else #endif R128MMIOAccelInit(pScrn, a); R128EngineInit(pScrn); return XAAInit(pScreen, a); }