/* * Copyright 1997 through 2004 by Marc Aurele La France (TSI @ UQV), tsi@xfree86.org * * Permission to use, copy, modify, distribute, and sell this software and its * documentation for any purpose is hereby granted without fee, provided that * the above copyright notice appear in all copies and that both that copyright * notice and this permission notice appear in supporting documentation, and * that the name of Marc Aurele La France not be used in advertising or * publicity pertaining to distribution of the software without specific, * written prior permission. Marc Aurele La France makes no representations * about the suitability of this software for any purpose. It is provided * "as-is" without express or implied warranty. * * MARC AURELE LA FRANCE DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO * EVENT SHALL MARC AURELE LA FRANCE BE LIABLE FOR ANY SPECIAL, INDIRECT OR * CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, * DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR * PERFORMANCE OF THIS SOFTWARE. */ /* * For all supported programmable clock generators, the driver will ignore any * XF86Config clock line and programme, as needed, the clock number reserved by * the BIOS for accelerated drivers. The driver's mode initialisation routine * finds integers N, M and D such that * * N * R * ------- MHz * M * D * * best approximates the mode's clock frequency, where R is the crystal- * generated reference frequency (usually 14.318 MHz). D is a power of 2 * except for those integrated controllers that also offer odd dividers. * Different clock generators have different restrictions on the value N, M and * D can assume. The driver contains an internal table to record these * restrictions (among other things). The resulting values of N, M and D are * then encoded in a generator-specific way and used to programme the clock. * The Mach64's clock divider is not used in this case. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include "ati.h" #include "atichip.h" #include "atidac.h" #include "atidsp.h" #include "atimach64io.h" #include "atimode.h" #include "atiwonderio.h" /* * Definitions related to programmable clock generators. */ static CARD16 ATIPostDividers[] = {1, 2, 4, 8, 16, 32, 64, 128}, ATI264xTPostDividers[] = {1, 2, 4, 8, 3, 0, 6, 12}; ClockRec ATIClockDescriptors[] = { { 0, 0, 0, 1, 1, 1, 1, 0, 0, NULL, "Non-programmable" }, { 257, 512, 257, 1, 1, 46, 46, 0, 4, ATIPostDividers, "ATI 18818 or ICS 2595 or similar" }, { 2, 129, 2, 1, 1, 8, 14, 2, 8, ATIPostDividers, "SGS-Thompson 1703 or similar" }, { 16, 263, 8, 8, 9, 4, 12, 2, 4, ATIPostDividers, "Chrontel 8398 or similar" }, { 2, 255, 0, 1, 1, 45, 45, 0, 4, ATI264xTPostDividers, "Internal" }, { 2, 257, 2, 1, 1, 2, 32, 2, 4, ATIPostDividers, "AT&T 20C408 or similar" }, { 65, 128, 65, 1, 1, 2, 14, 0, 4, ATIPostDividers, "IBM RGB 514 or similar" } }; /* * ATIClockPreInit -- * * This function is called by ATIPreInit() and handles the XF86Config clocks * line (or lack thereof). */ void ATIClockPreInit ( ScrnInfoPtr pScreenInfo, ATIPtr pATI ) { /* * Recognise supported clock generators. This involves telling the * rest of the server about it and (re-)initializing the XF86Config * clocks line. */ pScreenInfo->progClock = TRUE; xf86DrvMsg(pScreenInfo->scrnIndex, X_PROBED, "%s programmable clock generator detected.\n", pATI->ClockDescriptor.ClockName); if (pATI->ReferenceDenominator == 1) xf86DrvMsg(pScreenInfo->scrnIndex, X_PROBED, "Reference clock %.3f MHz.\n", (double)pATI->ReferenceNumerator / 1000.0); else xf86DrvMsg(pScreenInfo->scrnIndex, X_PROBED, "Reference clock %.6g/%d (%.3f) MHz.\n", (double)pATI->ReferenceNumerator / 1000.0, pATI->ReferenceDenominator, (double)pATI->ReferenceNumerator / ((double)pATI->ReferenceDenominator * 1000.0)); #if defined(__sparc__) if ((pATI->refclk / 100000) != 286 && (pATI->refclk / 100000) != 295) { xf86DrvMsg(pScreenInfo->scrnIndex, X_INFO, "If modes do not work on Ultra 5/10 or Blade 100/150,\n" "\tset option \"reference_clock\" to \"28.636 MHz\"" " or \"29.5 MHz\"\n"); } #endif if (pATI->ProgrammableClock == ATI_CLOCK_CH8398) { /* First two are fixed */ pScreenInfo->numClocks = 2; pScreenInfo->clock[0] = 25175; pScreenInfo->clock[1] = 28322; } else if (pATI->ProgrammableClock == ATI_CLOCK_INTERNAL) { /* * The integrated PLL generates clocks as if the reference * frequency were doubled. */ pATI->ReferenceNumerator <<= 1; } } /* * ATIClockCalculate -- * * This function is called to generate, if necessary, the data needed for clock * programming, and set clock select bits in various register values. */ Bool ATIClockCalculate ( int iScreen, ATIPtr pATI, ATIHWPtr pATIHW, DisplayModePtr pMode ) { int N, M, D; int ClockSelect, N1, MinimumGap; int Frequency, Multiple; /* Used as temporaries */ /* Set default values */ pATIHW->FeedbackDivider = pATIHW->ReferenceDivider = pATIHW->PostDivider = 0; if (((pATI->ProgrammableClock == ATI_CLOCK_CH8398) && (pMode->ClockIndex < 2))) { xf86DrvMsg(iScreen, X_ERROR, "First two clocks of Chrontel 8398 clock generator are fixed\n"); return FALSE; } { /* Generate clock programme word, using units of kHz */ MinimumGap = ((unsigned int)(-1)) >> 1; /* Loop through reference dividers */ for (M = pATI->ClockDescriptor.MinM; M <= pATI->ClockDescriptor.MaxM; M++) { /* Loop through post-dividers */ for (D = 0; D < pATI->ClockDescriptor.NumD; D++) { if (!pATI->ClockDescriptor.PostDividers[D]) continue; /* Limit undivided VCO to maxClock */ if (pATI->maxClock && ((pATI->maxClock / pATI->ClockDescriptor.PostDividers[D]) < pMode->Clock)) continue; /* * Calculate closest feedback divider and apply its * restrictions. */ Multiple = M * pATI->ReferenceDenominator * pATI->ClockDescriptor.PostDividers[D]; N = ATIDivide(pMode->Clock * Multiple, pATI->ReferenceNumerator, 0, 0); if (N < pATI->ClockDescriptor.MinN) N = pATI->ClockDescriptor.MinN; else if (N > pATI->ClockDescriptor.MaxN) N = pATI->ClockDescriptor.MaxN; N -= pATI->ClockDescriptor.NAdjust; N1 = (N / pATI->ClockDescriptor.N1) * pATI->ClockDescriptor.N2; if (N > N1) N = ATIDivide(N1 + 1, pATI->ClockDescriptor.N1, 0, 1); N += pATI->ClockDescriptor.NAdjust; N1 += pATI->ClockDescriptor.NAdjust; for (; ; N = N1) { /* Pick the closest setting */ Frequency = abs(ATIDivide(N * pATI->ReferenceNumerator, Multiple, 0, 0) - pMode->Clock); if ((Frequency < MinimumGap) || ((Frequency == MinimumGap) && (pATIHW->FeedbackDivider < N))) { /* Save settings */ pATIHW->FeedbackDivider = N; pATIHW->ReferenceDivider = M; pATIHW->PostDivider = D; MinimumGap = Frequency; } if (N <= N1) break; } } } Multiple = pATIHW->ReferenceDivider * pATI->ReferenceDenominator * pATI->ClockDescriptor.PostDividers[pATIHW->PostDivider]; Frequency = pATIHW->FeedbackDivider * pATI->ReferenceNumerator; Frequency = ATIDivide(Frequency, Multiple, 0, 0); if (abs(Frequency - pMode->Clock) > CLOCK_TOLERANCE) { xf86DrvMsg(iScreen, X_ERROR, "Unable to programme clock %.3fMHz for mode %s.\n", (double)(pMode->Clock) / 1000.0, pMode->name); return FALSE; } pMode->SynthClock = Frequency; ClockSelect = pATI->ClockNumberToProgramme; xf86ErrorFVerb(4, "\n Programming clock %d to %.3fMHz for mode %s." " N=%d, M=%d, D=%d.\n", ClockSelect, (double)Frequency / 1000.0, pMode->name, pATIHW->FeedbackDivider, pATIHW->ReferenceDivider, pATIHW->PostDivider); if (pATI->Chip >= ATI_CHIP_264VTB) ATIDSPCalculate(pATI, pATIHW, pMode); } /* Set clock select bits */ pATIHW->clock = ClockSelect; { pATIHW->clock_cntl = CLOCK_STROBE | SetBits(ClockSelect, CLOCK_SELECT | CLOCK_DIVIDER); } return TRUE; } /* * ATIClockSet -- * * This function is called to programme a clock for the mode being set. */ void ATIClockSet ( ATIPtr pATI, ATIHWPtr pATIHW ) { CARD32 crtc_gen_cntl, tmp; CARD8 clock_cntl0; CARD8 tmp2; unsigned int Programme; int N = pATIHW->FeedbackDivider - pATI->ClockDescriptor.NAdjust; int M = pATIHW->ReferenceDivider - pATI->ClockDescriptor.MAdjust; int D = pATIHW->PostDivider; /* Temporarily switch to accelerator mode */ crtc_gen_cntl = inr(CRTC_GEN_CNTL); if (!(crtc_gen_cntl & CRTC_EXT_DISP_EN)) outr(CRTC_GEN_CNTL, crtc_gen_cntl | CRTC_EXT_DISP_EN); switch (pATI->ProgrammableClock) { case ATI_CLOCK_ICS2595: clock_cntl0 = in8(CLOCK_CNTL); Programme = (SetBits(pATIHW->clock, ICS2595_CLOCK) | SetBits(N, ICS2595_FB_DIV) | SetBits(D, ICS2595_POST_DIV)) ^ ICS2595_TOGGLE; ATIDelay(50000); /* 50 milliseconds */ /* Send all 20 bits of programme word */ while (Programme >= CLOCK_BIT) { tmp = (Programme & CLOCK_BIT) | CLOCK_STROBE; out8(CLOCK_CNTL, tmp); ATIDelay(26); /* 26 microseconds */ out8(CLOCK_CNTL, tmp | CLOCK_PULSE); ATIDelay(26); /* 26 microseconds */ Programme >>= 1; } /* Restore register */ out8(CLOCK_CNTL, clock_cntl0 | CLOCK_STROBE); break; case ATI_CLOCK_STG1703: (void)ATIGetDACCmdReg(pATI); (void)in8(M64_DAC_MASK); out8(M64_DAC_MASK, (pATIHW->clock << 1) + 0x20U); out8(M64_DAC_MASK, 0); out8(M64_DAC_MASK, SetBits(N, 0xFFU)); out8(M64_DAC_MASK, SetBits(M, 0x1FU) | SetBits(D, 0xE0U)); break; case ATI_CLOCK_CH8398: tmp = inr(DAC_CNTL) | (DAC_EXT_SEL_RS2 | DAC_EXT_SEL_RS3); outr(DAC_CNTL, tmp); out8(M64_DAC_WRITE, pATIHW->clock); out8(M64_DAC_DATA, SetBits(N, 0xFFU)); out8(M64_DAC_DATA, SetBits(M, 0x3FU) | SetBits(D, 0xC0U)); out8(M64_DAC_MASK, 0x04U); outr(DAC_CNTL, tmp & ~(DAC_EXT_SEL_RS2 | DAC_EXT_SEL_RS3)); tmp2 = in8(M64_DAC_WRITE); out8(M64_DAC_WRITE, (tmp2 & 0x70U) | 0x80U); outr(DAC_CNTL, tmp & ~DAC_EXT_SEL_RS2); break; case ATI_CLOCK_INTERNAL: /* Reset VCLK generator */ ATIMach64PutPLLReg(PLL_VCLK_CNTL, pATIHW->pll_vclk_cntl); /* Set post-divider */ tmp2 = pATIHW->clock << 1; tmp = ATIMach64GetPLLReg(PLL_VCLK_POST_DIV); tmp &= ~(0x03U << tmp2); tmp |= SetBits(D, 0x03U) << tmp2; ATIMach64PutPLLReg(PLL_VCLK_POST_DIV, tmp); /* Set extended post-divider */ tmp = ATIMach64GetPLLReg(PLL_XCLK_CNTL); tmp &= ~(SetBits(1, PLL_VCLK0_XDIV) << pATIHW->clock); tmp |= SetBits(D >> 2, PLL_VCLK0_XDIV) << pATIHW->clock; ATIMach64PutPLLReg(PLL_XCLK_CNTL, tmp); /* Set feedback divider */ tmp = PLL_VCLK0_FB_DIV + pATIHW->clock; ATIMach64PutPLLReg(tmp, SetBits(N, 0xFFU)); /* End VCLK generator reset */ ATIMach64PutPLLReg(PLL_VCLK_CNTL, pATIHW->pll_vclk_cntl & ~PLL_VCLK_RESET); /* Reset write bit */ ATIMach64AccessPLLReg(pATI, 0, FALSE); break; case ATI_CLOCK_ATT20C408: (void)ATIGetDACCmdReg(pATI); tmp = in8(M64_DAC_MASK); (void)ATIGetDACCmdReg(pATI); out8(M64_DAC_MASK, tmp | 1); out8(M64_DAC_WRITE, 1); out8(M64_DAC_MASK, tmp | 9); ATIDelay(400); /* 400 microseconds */ tmp2 = (pATIHW->clock << 2) + 0x40U; out8(M64_DAC_WRITE, tmp2); out8(M64_DAC_MASK, SetBits(N, 0xFFU)); out8(M64_DAC_WRITE, ++tmp2); out8(M64_DAC_MASK, SetBits(M, 0x3FU) | SetBits(D, 0xC0U)); out8(M64_DAC_WRITE, ++tmp2); out8(M64_DAC_MASK, 0x77U); ATIDelay(400); /* 400 microseconds */ out8(M64_DAC_WRITE, 1); out8(M64_DAC_MASK, tmp); break; case ATI_CLOCK_IBMRGB514: /* * Here, only update in-core data. It will be written out later by * ATIRGB514Set(). */ tmp = (pATIHW->clock << 1) + 0x20U; pATIHW->ibmrgb514[tmp] = (SetBits(N, 0x3FU) | SetBits(D, 0xC0U)) ^ 0xC0U; pATIHW->ibmrgb514[tmp + 1] = SetBits(M, 0x3FU); break; default: break; } (void)in8(M64_DAC_WRITE); /* Clear DAC counter */ /* Restore register */ if (!(crtc_gen_cntl & CRTC_EXT_DISP_EN)) outr(CRTC_GEN_CNTL, crtc_gen_cntl); }