/* * Copyright (c) 2007,2010 NVIDIA Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include "g80_type.h" #include "g80_cursor.h" #include "g80_display.h" #include "g80_output.h" typedef struct G80CrtcPrivRec { Head head; int pclk; /* Target pixel clock in kHz */ Bool cursorVisible; Bool skipModeFixup; Bool dither; /* Look-up table values to be set when the CRTC is enabled */ uint16_t lut_r[256], lut_g[256], lut_b[256]; } G80CrtcPrivRec, *G80CrtcPrivPtr; static void G80CrtcShowHideCursor(xf86CrtcPtr crtc, Bool show, Bool update); /* * PLL calculation. pclk is in kHz. */ static void G80CalcPLL(float pclk, int *pNA, int *pMA, int *pNB, int *pMB, int *pP) { const float refclk = 27000.0f; const float minVcoA = 100000; const float maxVcoA = 400000; const float minVcoB = 600000; float maxVcoB = 1400000; const float minUA = 2000; const float maxUA = 400000; const float minUB = 50000; const float maxUB = 200000; const int minNA = 1, maxNA = 255; const int minNB = 1, maxNB = 31; const int minMA = 1, maxMA = 255; const int minMB = 1, maxMB = 31; const int minP = 0, maxP = 6; int lowP, highP; float vcoB; int na, ma, nb, mb, p; float bestError = FLT_MAX; *pNA = *pMA = *pNB = *pMB = *pP = 0; if(maxVcoB < pclk + pclk / 200) maxVcoB = pclk + pclk / 200; if(minVcoB / (1 << maxP) > pclk) pclk = minVcoB / (1 << maxP); vcoB = maxVcoB - maxVcoB / 200; lowP = minP; vcoB /= 1 << (lowP + 1); while(pclk <= vcoB && lowP < maxP) { vcoB /= 2; lowP++; } vcoB = maxVcoB + maxVcoB / 200; highP = lowP; vcoB /= 1 << (highP + 1); while(pclk <= vcoB && highP < maxP) { vcoB /= 2; highP++; } for(p = lowP; p <= highP; p++) { for(ma = minMA; ma <= maxMA; ma++) { if(refclk / ma < minUA) break; else if(refclk / ma > maxUA) continue; for(na = minNA; na <= maxNA; na++) { if(refclk * na / ma < minVcoA || refclk * na / ma > maxVcoA) continue; for(mb = minMB; mb <= maxMB; mb++) { if(refclk * na / ma / mb < minUB) break; else if(refclk * na / ma / mb > maxUB) continue; nb = rint(pclk * (1 << p) * (ma / (float)na) * mb / refclk); if(nb > maxNB) break; else if(nb < minNB) continue; else { float freq = refclk * (na / (float)ma) * (nb / (float)mb) / (1 << p); float error = fabsf(pclk - freq); if(error < bestError) { *pNA = na; *pMA = ma; *pNB = nb; *pMB = mb; *pP = p; bestError = error; } } } } } } } static void G80CalcPLL2(float pclk, int *pN, int *pM, int *pPL) { const float refclk = 27000.0f; const int minN = 8, maxN = 255; const int minM = 1, maxM = 255; const int minPL = 1, maxPL = 63; const int minU = 25000, maxU = 50000; const int minVco = 500000; int maxVco = 1000000; int lowPL, highPL, pl; float vco, bestError = FLT_MAX; vco = pclk + pclk / 50; if(maxVco < vco) maxVco = vco; highPL = (maxVco + vco - 1) / pclk; if(highPL > maxPL) highPL = maxPL; if(highPL < minPL) highPL = minPL; lowPL = minVco / vco; if(lowPL > maxPL) lowPL = maxPL; if(lowPL < minPL) lowPL = minPL; for(pl = highPL; pl >= lowPL; pl--) { int m; for(m = minM; m <= maxM; m++) { int n; float freq, error; if(refclk / m < minU) break; if(refclk / m > maxU) continue; n = rint(pclk * pl * m / refclk); if(n > maxN) break; if(n < minN) continue; freq = refclk * (n / (float)m) / pl; error = fabsf(pclk - freq); if(error < bestError) { *pN = n; *pM = m; *pPL = pl; bestError = error; } } } } static void G80CrtcSetPClk(xf86CrtcPtr crtc) { G80Ptr pNv = G80PTR(crtc->scrn); G80CrtcPrivPtr pPriv = crtc->driver_private; xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(crtc->scrn); const int headOff = 0x800 * pPriv->head; int i; if(pPriv->pclk == 0) return; if(pNv->architecture <= 0xa0 || pNv->architecture == 0xaa || pNv->architecture == 0xac) { int lo_n, lo_m, hi_n, hi_m, p; CARD32 lo = pNv->reg[(0x00614104+headOff)/4]; CARD32 hi = pNv->reg[(0x00614108+headOff)/4]; pNv->reg[(0x00614100+headOff)/4] = 0x10000610; lo &= 0xff00ff00; hi &= 0x8000ff00; G80CalcPLL(pPriv->pclk, &lo_n, &lo_m, &hi_n, &hi_m, &p); lo |= (lo_m << 16) | lo_n; hi |= (p << 28) | (hi_m << 16) | hi_n; pNv->reg[(0x00614104+headOff)/4] = lo; pNv->reg[(0x00614108+headOff)/4] = hi; } else { int n, m, pl; CARD32 r = pNv->reg[(0x00614104+headOff)/4]; pNv->reg[(0x00614100+headOff)/4] = 0x50000610; r &= 0xffc00000; G80CalcPLL2(pPriv->pclk, &n, &m, &pl); r |= pl << 16 | m << 8 | n; pNv->reg[(0x00614104+headOff)/4] = r; } pNv->reg[(0x00614200+headOff)/4] = 0; for(i = 0; i < xf86_config->num_output; i++) { xf86OutputPtr output = xf86_config->output[i]; if(output->crtc != crtc) continue; G80OutputSetPClk(output, pPriv->pclk); } } void G80DispCommand(ScrnInfoPtr pScrn, CARD32 addr, CARD32 data) { G80Ptr pNv = G80PTR(pScrn); pNv->reg[0x00610304/4] = data; pNv->reg[0x00610300/4] = addr | 0x80010001; while(pNv->reg[0x00610300/4] & 0x80000000) { const int super = ffs((pNv->reg[0x00610024/4] >> 4) & 7); if(super) { if(super == 2) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(pScrn); int i; for(i = 0; i < xf86_config->num_crtc; i++) { xf86CrtcPtr crtc = xf86_config->crtc[i]; const int headOff = 0x800 * G80CrtcGetHead(crtc); if((pNv->reg[(0x00614200+headOff)/4] & 0xc0) == 0x80) G80CrtcSetPClk(crtc); } } pNv->reg[0x00610024/4] = 8 << super; pNv->reg[0x00610030/4] = 0x80000000; } } } Head G80CrtcGetHead(xf86CrtcPtr crtc) { G80CrtcPrivPtr pPriv = crtc->driver_private; return pPriv->head; } Bool G80DispPreInit(ScrnInfoPtr pScrn) { G80Ptr pNv = G80PTR(pScrn); xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(pScrn); /* nouveau guys dont know what this does */ pNv->reg[0x00610184/4] = pNv->reg[0x00614004/4]; /* CRTC capabilities */ for(int i = 0; i < xf86_config->num_crtc; i++) { xf86CrtcPtr crtc = xf86_config->crtc[i]; const int headOff = 0x800 * G80CrtcGetHead(crtc); /* Some photos of G80 cards had more than two of these, I think this can be justified */ pNv->reg[(0x00610190 + (G80CrtcGetHead(crtc) * 0x10))/4] = pNv->reg[(0x00616100 + headOff)/4]; pNv->reg[(0x00610194 + (G80CrtcGetHead(crtc) * 0x10))/4] = pNv->reg[(0x00616104 + headOff)/4]; pNv->reg[(0x00610198 + (G80CrtcGetHead(crtc) * 0x10))/4] = pNv->reg[(0x00616108 + headOff)/4]; pNv->reg[(0x0061019C + (G80CrtcGetHead(crtc) * 0x10))/4] = pNv->reg[(0x0061610C + headOff)/4]; } /* DAC capabilities */ pNv->reg[0x006101D0/4] = pNv->reg[0x0061A000/4]; pNv->reg[0x006101D4/4] = pNv->reg[0x0061A800/4]; pNv->reg[0x006101D8/4] = pNv->reg[0x0061B000/4]; /* SOR capabilities */ pNv->reg[0x006101E0/4] = pNv->reg[0x0061C000/4]; pNv->reg[0x006101E4/4] = pNv->reg[0x0061C800/4]; pNv->reg[0x006101E8/4] = pNv->reg[0x0061D000/4]; pNv->reg[0x006101EC/4] = pNv->reg[0x0061D800/4]; /* Setting the rest of the capabilities */ pNv->reg[0x0061A004/4] = 0x80550000; pNv->reg[0x0061A010/4] = 0x00000001; pNv->reg[0x0061A804/4] = 0x80550000; pNv->reg[0x0061A810/4] = 0x00000001; pNv->reg[0x0061B004/4] = 0x80550000; pNv->reg[0x0061B010/4] = 0x00000001; return TRUE; } Bool G80DispInit(ScrnInfoPtr pScrn) { G80Ptr pNv = G80PTR(pScrn); CARD32 val; if(pNv->reg[0x00610024/4] & 0x100) { pNv->reg[0x00610024/4] = 0x100; pNv->reg[0x006194E8/4] &= ~1; while(pNv->reg[0x006194E8/4] & 2); } pNv->reg[0x00610200/4] = 0x2b00; do { val = pNv->reg[0x00610200/4]; if ((val & 0x9f0000) == 0x20000) pNv->reg[0x00610200/4] = val | 0x800000; if ((val & 0x3f0000) == 0x30000) pNv->reg[0x00610200/4] = val | 0x200000; } while ((val & 0x1e0000) != 0); pNv->reg[0x00610300/4] = 1; pNv->reg[0x00610200/4] = 0x1000b03; while(!(pNv->reg[0x00610200/4] & 0x40000000)); C(0x00000084, 0); C(0x00000088, 0); C(0x00000874, 0); C(0x00000800, 0); C(0x00000810, 0); C(0x0000082C, 0); return TRUE; } void G80DispShutdown(ScrnInfoPtr pScrn) { G80Ptr pNv = G80PTR(pScrn); xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(pScrn); int i; for(i = 0; i < xf86_config->num_crtc; i++) { xf86CrtcPtr crtc = xf86_config->crtc[i]; G80CrtcBlankScreen(crtc, TRUE); } C(0x00000080, 0); for(i = 0; i < xf86_config->num_crtc; i++) { xf86CrtcPtr crtc = xf86_config->crtc[i]; if(crtc->enabled) { const CARD32 mask = 4 << G80CrtcGetHead(crtc); pNv->reg[0x00610024/4] = mask; while(!(pNv->reg[0x00610024/4] & mask)); } } pNv->reg[0x00610200/4] = 0; pNv->reg[0x00610300/4] = 0; while((pNv->reg[0x00610200/4] & 0x1e0000) != 0); while((pNv->reg[0x61C030/4] & 0x10000000)); while((pNv->reg[0x61C830/4] & 0x10000000)); } void G80CrtcDoModeFixup(DisplayModePtr dst, const DisplayModePtr src) { /* Magic mode timing fudge factor */ const int fudge = ((src->Flags & V_INTERLACE) && (src->Flags & V_DBLSCAN)) ? 2 : 1; const int interlaceDiv = (src->Flags & V_INTERLACE) ? 2 : 1; /* Stash the src timings in the Crtc fields in dst */ dst->CrtcHBlankStart = src->CrtcVTotal << 16 | src->CrtcHTotal; dst->CrtcHSyncEnd = ((src->CrtcVSyncEnd - src->CrtcVSyncStart) / interlaceDiv - 1) << 16 | (src->CrtcHSyncEnd - src->CrtcHSyncStart - 1); dst->CrtcHBlankEnd = ((src->CrtcVBlankEnd - src->CrtcVSyncStart) / interlaceDiv - fudge) << 16 | (src->CrtcHBlankEnd - src->CrtcHSyncStart - 1); dst->CrtcHTotal = ((src->CrtcVTotal - src->CrtcVSyncStart + src->CrtcVBlankStart) / interlaceDiv - fudge) << 16 | (src->CrtcHTotal - src->CrtcHSyncStart + src->CrtcHBlankStart - 1); dst->CrtcHSkew = ((src->CrtcVTotal + src->CrtcVBlankEnd - src->CrtcVSyncStart) / 2 - 2) << 16 | ((2*src->CrtcVTotal - src->CrtcVSyncStart + src->CrtcVBlankStart) / 2 - 2); } static Bool G80CrtcModeFixup(xf86CrtcPtr crtc, DisplayModePtr mode, DisplayModePtr adjusted_mode) { G80CrtcPrivPtr pPriv = crtc->driver_private; if(pPriv->skipModeFixup) return TRUE; G80CrtcDoModeFixup(adjusted_mode, mode); return TRUE; } static void G80CrtcModeSet(xf86CrtcPtr crtc, DisplayModePtr mode, DisplayModePtr adjusted_mode, int x, int y) { ScrnInfoPtr pScrn = crtc->scrn; G80CrtcPrivPtr pPriv = crtc->driver_private; const int HDisplay = adjusted_mode->HDisplay, VDisplay = adjusted_mode->VDisplay; const int headOff = 0x400 * G80CrtcGetHead(crtc); pPriv->pclk = adjusted_mode->Clock; C(0x00000804 + headOff, adjusted_mode->Clock | 0x800000); C(0x00000808 + headOff, (adjusted_mode->Flags & V_INTERLACE) ? 2 : 0); C(0x00000810 + headOff, 0); C(0x0000082C + headOff, 0); C(0x00000814 + headOff, adjusted_mode->CrtcHBlankStart); C(0x00000818 + headOff, adjusted_mode->CrtcHSyncEnd); C(0x0000081C + headOff, adjusted_mode->CrtcHBlankEnd); C(0x00000820 + headOff, adjusted_mode->CrtcHTotal); if(adjusted_mode->Flags & V_INTERLACE) C(0x00000824 + headOff, adjusted_mode->CrtcHSkew); C(0x00000868 + headOff, pScrn->virtualY << 16 | pScrn->virtualX); C(0x0000086C + headOff, pScrn->displayWidth * (pScrn->bitsPerPixel / 8) | 0x100000); switch(pScrn->depth) { case 8: C(0x00000870 + headOff, 0x1E00); break; case 15: C(0x00000870 + headOff, 0xE900); break; case 16: C(0x00000870 + headOff, 0xE800); break; case 24: C(0x00000870 + headOff, 0xCF00); break; } G80CrtcSetDither(crtc, pPriv->dither, FALSE); C(0x000008A8 + headOff, 0x40000); C(0x000008C0 + headOff, y << 16 | x); C(0x000008C8 + headOff, VDisplay << 16 | HDisplay); C(0x000008D4 + headOff, 0); G80CrtcBlankScreen(crtc, FALSE); } void G80CrtcBlankScreen(xf86CrtcPtr crtc, Bool blank) { ScrnInfoPtr pScrn = crtc->scrn; G80Ptr pNv = G80PTR(pScrn); G80CrtcPrivPtr pPriv = crtc->driver_private; const int headOff = 0x400 * pPriv->head; if(blank) { G80CrtcShowHideCursor(crtc, FALSE, FALSE); C(0x00000840 + headOff, 0); C(0x00000844 + headOff, 0); if(pNv->architecture != 0x50) C(0x0000085C + headOff, 0); C(0x00000874 + headOff, 0); if(pNv->architecture != 0x50) C(0x0000089C + headOff, 0); } else { C(0x00000860 + headOff, 0); C(0x00000864 + headOff, 0); pNv->reg[0x00610380/4] = 0; pNv->reg[0x00610384/4] = pNv->videoRam * 1024 - 1; pNv->reg[0x00610388/4] = 0x150000; pNv->reg[0x0061038C/4] = 0; C(0x00000884 + headOff, (pNv->videoRam << 2) - 0x40); if(pNv->architecture != 0x50) C(0x0000089C + headOff, 1); if(pPriv->cursorVisible) G80CrtcShowHideCursor(crtc, TRUE, FALSE); C(0x00000840 + headOff, pScrn->depth == 8 ? 0x80000000 : 0xc0000000); C(0x00000844 + headOff, (pNv->videoRam * 1024 - 0x5000 - 0x1000 * pPriv->head) >> 8); if(pNv->architecture != 0x50) C(0x0000085C + headOff, 1); C(0x00000874 + headOff, 1); } } static void G80CrtcDPMSSet(xf86CrtcPtr crtc, int mode) { } /******************************** Cursor stuff ********************************/ static void G80CrtcShowHideCursor(xf86CrtcPtr crtc, Bool show, Bool update) { ScrnInfoPtr pScrn = crtc->scrn; G80CrtcPrivPtr pPriv = crtc->driver_private; const int headOff = 0x400 * G80CrtcGetHead(crtc); C(0x00000880 + headOff, show ? 0x85000000 : 0x5000000); if(update) { pPriv->cursorVisible = show; C(0x00000080, 0); } } static void G80CrtcShowCursor(xf86CrtcPtr crtc) { G80CrtcShowHideCursor(crtc, TRUE, TRUE); } static void G80CrtcHideCursor(xf86CrtcPtr crtc) { G80CrtcShowHideCursor(crtc, FALSE, TRUE); } /******************************** CRTC stuff ********************************/ static Bool G80CrtcLock(xf86CrtcPtr crtc) { return FALSE; } static void G80CrtcPrepare(xf86CrtcPtr crtc) { ScrnInfoPtr pScrn = crtc->scrn; G80CrtcPrivPtr pPriv = crtc->driver_private; xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(pScrn); int i; for(i = 0; i < xf86_config->num_output; i++) { xf86OutputPtr output = xf86_config->output[i]; if(!output->crtc) output->funcs->mode_set(output, NULL, NULL); } pPriv->skipModeFixup = FALSE; } void G80CrtcSkipModeFixup(xf86CrtcPtr crtc) { G80CrtcPrivPtr pPriv = crtc->driver_private; pPriv->skipModeFixup = TRUE; } void G80CrtcSetDither(xf86CrtcPtr crtc, Bool dither, Bool update) { ScrnInfoPtr pScrn = crtc->scrn; G80CrtcPrivPtr pPriv = crtc->driver_private; const int headOff = 0x400 * G80CrtcGetHead(crtc); pPriv->dither = dither; C(0x000008A0 + headOff, dither ? 0x11 : 0); if(update) C(0x00000080, 0); } static void ComputeAspectScale(DisplayModePtr mode, int *outX, int *outY) { float scaleX, scaleY, scale; scaleX = mode->CrtcHDisplay / (float)mode->HDisplay; scaleY = mode->CrtcVDisplay / (float)mode->VDisplay; if(scaleX > scaleY) scale = scaleY; else scale = scaleX; *outX = mode->HDisplay * scale; *outY = mode->VDisplay * scale; } void G80CrtcSetScale(xf86CrtcPtr crtc, DisplayModePtr mode, enum G80ScaleMode scale) { ScrnInfoPtr pScrn = crtc->scrn; G80CrtcPrivPtr pPriv = crtc->driver_private; const int headOff = 0x400 * pPriv->head; int outX, outY; switch(scale) { default: case G80_SCALE_ASPECT: ComputeAspectScale(mode, &outX, &outY); break; case G80_SCALE_OFF: case G80_SCALE_FILL: outX = mode->CrtcHDisplay; outY = mode->CrtcVDisplay; break; case G80_SCALE_CENTER: outX = mode->HDisplay; outY = mode->VDisplay; break; } if((mode->Flags & V_DBLSCAN) || (mode->Flags & V_INTERLACE) || mode->HDisplay != outX || mode->VDisplay != outY) { C(0x000008A4 + headOff, 9); } else { C(0x000008A4 + headOff, 0); } C(0x000008D8 + headOff, outY << 16 | outX); C(0x000008DC + headOff, outY << 16 | outX); } static void G80CrtcCommit(xf86CrtcPtr crtc) { ScrnInfoPtr pScrn = crtc->scrn; xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(crtc->scrn); int i, crtc_mask = 0; /* If any heads are unused, blank them */ for(i = 0; i < xf86_config->num_output; i++) { xf86OutputPtr output = xf86_config->output[i]; if(output->crtc) /* XXXagp: This assumes that xf86_config->crtc[i] is HEADi */ crtc_mask |= 1 << G80CrtcGetHead(output->crtc); } for(i = 0; i < xf86_config->num_crtc; i++) if(!((1 << i) & crtc_mask)) G80CrtcBlankScreen(xf86_config->crtc[i], TRUE); C(0x00000080, 0); } static void G80CrtcGammaSet(xf86CrtcPtr crtc, CARD16 *red, CARD16 *green, CARD16 *blue, int size) { ScrnInfoPtr pScrn = crtc->scrn; G80Ptr pNv = G80PTR(pScrn); G80CrtcPrivPtr pPriv = crtc->driver_private; int i; volatile struct { uint16_t red, green, blue, unused; } *lut = (void*)&pNv->mem[pNv->videoRam * 1024 - 0x5000 - 0x1000 * pPriv->head]; assert(size == 256); for(i = 0; i < size; i++) { pPriv->lut_r[i] = lut[i].red = red[i] >> 2; pPriv->lut_g[i] = lut[i].green = green[i] >> 2; pPriv->lut_b[i] = lut[i].blue = blue[i] >> 2; } lut[256] = lut[255]; } void G80LoadPalette(ScrnInfoPtr pScrn, int numColors, int *indices, LOCO *colors, VisualPtr pVisual) { xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(pScrn); int i, j, index; int p; uint16_t lut_r[256], lut_g[256], lut_b[256]; for(p = 0; p < xf86_config->num_crtc; p++) { xf86CrtcPtr crtc = xf86_config->crtc[p]; G80CrtcPrivPtr pPriv = crtc->driver_private; /* Initialize to the old lookup table values. */ for(i = 0; i < 256; i++) { lut_r[i] = pPriv->lut_r[i] << 2; lut_g[i] = pPriv->lut_g[i] << 2; lut_b[i] = pPriv->lut_b[i] << 2; } switch(pScrn->depth) { case 15: for(i = 0; i < numColors; i++) { index = indices[i]; for(j = 0; j < 8; j++) { lut_r[index * 8 + j] = colors[index].red << 8; lut_g[index * 8 + j] = colors[index].green << 8; lut_b[index * 8 + j] = colors[index].blue << 8; } } break; case 16: for(i = 0; i < numColors; i++) { index = indices[i]; if(index <= 31) { for(j = 0; j < 8; j++) { lut_r[index * 8 + j] = colors[index].red << 8; lut_b[index * 8 + j] = colors[index].blue << 8; } } for(j = 0; j < 4; j++) { lut_g[index * 4 + j] = colors[index].green << 8; } } break; default: for(i = 0; i < numColors; i++) { index = indices[i]; lut_r[index] = colors[index].red << 8; lut_g[index] = colors[index].green << 8; lut_b[index] = colors[index].blue << 8; } break; } /* Make the change through RandR */ RRCrtcGammaSet(crtc->randr_crtc, lut_r, lut_g, lut_b); } } static const xf86CrtcFuncsRec g80_crtc_funcs = { .dpms = G80CrtcDPMSSet, .save = NULL, .restore = NULL, .lock = G80CrtcLock, .unlock = NULL, .mode_fixup = G80CrtcModeFixup, .prepare = G80CrtcPrepare, .mode_set = G80CrtcModeSet, .gamma_set = G80CrtcGammaSet, .commit = G80CrtcCommit, .shadow_create = NULL, .shadow_destroy = NULL, .set_cursor_position = G80SetCursorPosition, .show_cursor = G80CrtcShowCursor, .hide_cursor = G80CrtcHideCursor, .load_cursor_argb = G80LoadCursorARGB, .destroy = NULL, }; void G80DispCreateCrtcs(ScrnInfoPtr pScrn) { G80Ptr pNv = G80PTR(pScrn); Head head; xf86CrtcPtr crtc; G80CrtcPrivPtr g80_crtc; /* Create a "crtc" object for each head */ for(head = HEAD0; head <= HEAD1; head++) { crtc = xf86CrtcCreate(pScrn, &g80_crtc_funcs); if(!crtc) return; g80_crtc = XNFcallocarray(sizeof(*g80_crtc), 1); g80_crtc->head = head; g80_crtc->dither = pNv->Dither; crtc->driver_private = g80_crtc; } }