1da177e4c3
Initial git repository build. I'm not bothering with the full history, even though we have it. We can create a separate "historical" git archive of that later if we want to, and in the meantime it's about 3.2GB when imported into git - space that would just make the early git days unnecessarily complicated, when we don't have a lot of good infrastructure for it. Let it rip!
326 lines
9.6 KiB
C
326 lines
9.6 KiB
C
/*
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* linux/drivers/video/kyro/STG4000InitDevice.c
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*
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* Copyright (C) 2000 Imagination Technologies Ltd
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* Copyright (C) 2002 STMicroelectronics
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*
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* This file is subject to the terms and conditions of the GNU General Public
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* License. See the file COPYING in the main directory of this archive
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* for more details.
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*/
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#include <linux/kernel.h>
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#include <linux/errno.h>
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#include <linux/types.h>
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#include <linux/pci.h>
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#include "STG4000Reg.h"
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/* SDRAM fixed settings */
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#define SDRAM_CFG_0 0x49A1
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#define SDRAM_CFG_1 0xA732
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#define SDRAM_CFG_2 0x31
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#define SDRAM_ARB_CFG 0xA0
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#define SDRAM_REFRESH 0x20
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/* Reset values */
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#define PMX2_SOFTRESET_DAC_RST 0x0001
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#define PMX2_SOFTRESET_C1_RST 0x0004
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#define PMX2_SOFTRESET_C2_RST 0x0008
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#define PMX2_SOFTRESET_3D_RST 0x0010
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#define PMX2_SOFTRESET_VIDIN_RST 0x0020
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#define PMX2_SOFTRESET_TLB_RST 0x0040
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#define PMX2_SOFTRESET_SD_RST 0x0080
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#define PMX2_SOFTRESET_VGA_RST 0x0100
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#define PMX2_SOFTRESET_ROM_RST 0x0200 /* reserved bit, do not reset */
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#define PMX2_SOFTRESET_TA_RST 0x0400
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#define PMX2_SOFTRESET_REG_RST 0x4000
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#define PMX2_SOFTRESET_ALL 0x7fff
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/* Core clock freq */
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#define CORE_PLL_FREQ 1000000
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/* Reference Clock freq */
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#define REF_FREQ 14318
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/* PCI Registers */
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static u16 CorePllControl = 0x70;
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#define PCI_CONFIG_SUBSYS_ID 0x2e
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/* Misc */
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#define CORE_PLL_MODE_REG_0_7 3
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#define CORE_PLL_MODE_REG_8_15 2
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#define CORE_PLL_MODE_CONFIG_REG 1
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#define DAC_PLL_CONFIG_REG 0
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#define STG_MAX_VCO 500000
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#define STG_MIN_VCO 100000
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/* PLL Clock */
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#define STG4K3_PLL_SCALER 8 /* scale numbers by 2^8 for fixed point calc */
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#define STG4K3_PLL_MIN_R 2 /* Minimum multiplier */
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#define STG4K3_PLL_MAX_R 33 /* Max */
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#define STG4K3_PLL_MIN_F 2 /* Minimum divisor */
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#define STG4K3_PLL_MAX_F 513 /* Max */
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#define STG4K3_PLL_MIN_OD 0 /* Min output divider (shift) */
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#define STG4K3_PLL_MAX_OD 2 /* Max */
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#define STG4K3_PLL_MIN_VCO_SC (100000000 >> STG4K3_PLL_SCALER) /* Min VCO rate */
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#define STG4K3_PLL_MAX_VCO_SC (500000000 >> STG4K3_PLL_SCALER) /* Max VCO rate */
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#define STG4K3_PLL_MINR_VCO_SC (100000000 >> STG4K3_PLL_SCALER) /* Min VCO rate (restricted) */
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#define STG4K3_PLL_MAXR_VCO_SC (500000000 >> STG4K3_PLL_SCALER) /* Max VCO rate (restricted) */
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#define STG4K3_PLL_MINR_VCO 100000000 /* Min VCO rate (restricted) */
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#define STG4K3_PLL_MAX_VCO 500000000 /* Max VCO rate */
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#define STG4K3_PLL_MAXR_VCO 500000000 /* Max VCO rate (restricted) */
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#define OS_DELAY(X) \
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{ \
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volatile u32 i,count=0; \
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for(i=0;i<X;i++) count++; \
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}
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static u32 InitSDRAMRegisters(volatile STG4000REG __iomem *pSTGReg,
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u32 dwSubSysID, u32 dwRevID)
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{
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u32 adwSDRAMArgCfg0[] = { 0xa0, 0x80, 0xa0, 0xa0, 0xa0 };
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u32 adwSDRAMCfg1[] = { 0x8732, 0x8732, 0xa732, 0xa732, 0x8732 };
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u32 adwSDRAMCfg2[] = { 0x87d2, 0x87d2, 0xa7d2, 0x87d2, 0xa7d2 };
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u32 adwSDRAMRsh[] = { 36, 39, 40 };
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u32 adwChipSpeed[] = { 110, 120, 125 };
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u32 dwMemTypeIdx;
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u32 dwChipSpeedIdx;
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/* Get memory tpye and chip speed indexs from the SubSysDevID */
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dwMemTypeIdx = (dwSubSysID & 0x70) >> 4;
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dwChipSpeedIdx = (dwSubSysID & 0x180) >> 7;
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if (dwMemTypeIdx > 4 || dwChipSpeedIdx > 2)
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return 0;
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/* Program SD-RAM interface */
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STG_WRITE_REG(SDRAMArbiterConf, adwSDRAMArgCfg0[dwMemTypeIdx]);
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if (dwRevID < 5) {
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STG_WRITE_REG(SDRAMConf0, 0x49A1);
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STG_WRITE_REG(SDRAMConf1, adwSDRAMCfg1[dwMemTypeIdx]);
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} else {
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STG_WRITE_REG(SDRAMConf0, 0x4DF1);
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STG_WRITE_REG(SDRAMConf1, adwSDRAMCfg2[dwMemTypeIdx]);
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}
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STG_WRITE_REG(SDRAMConf2, 0x31);
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STG_WRITE_REG(SDRAMRefresh, adwSDRAMRsh[dwChipSpeedIdx]);
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return adwChipSpeed[dwChipSpeedIdx] * 10000;
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}
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u32 ProgramClock(u32 refClock,
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u32 coreClock,
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u32 * FOut, u32 * ROut, u32 * POut)
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{
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u32 R = 0, F = 0, OD = 0, ODIndex = 0;
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u32 ulBestR = 0, ulBestF = 0, ulBestOD = 0;
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u32 ulBestVCO = 0, ulBestClk = 0, ulBestScore = 0;
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u32 ulScore, ulPhaseScore, ulVcoScore;
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u32 ulTmp = 0, ulVCO;
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u32 ulScaleClockReq, ulMinClock, ulMaxClock;
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u32 ODValues[] = { 1, 2, 0 };
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/* Translate clock in Hz */
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coreClock *= 100; /* in Hz */
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refClock *= 1000; /* in Hz */
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/* Work out acceptable clock
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* The method calculates ~ +- 0.4% (1/256)
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*/
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ulMinClock = coreClock - (coreClock >> 8);
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ulMaxClock = coreClock + (coreClock >> 8);
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/* Scale clock required for use in calculations */
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ulScaleClockReq = coreClock >> STG4K3_PLL_SCALER;
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/* Iterate through post divider values */
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for (ODIndex = 0; ODIndex < 3; ODIndex++) {
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OD = ODValues[ODIndex];
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R = STG4K3_PLL_MIN_R;
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/* loop for pre-divider from min to max */
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while (R <= STG4K3_PLL_MAX_R) {
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/* estimate required feedback multiplier */
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ulTmp = R * (ulScaleClockReq << OD);
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/* F = ClkRequired * R * (2^OD) / Fref */
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F = (u32)(ulTmp / (refClock >> STG4K3_PLL_SCALER));
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/* compensate for accuracy */
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if (F > STG4K3_PLL_MIN_F)
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F--;
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/*
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* We should be close to our target frequency (if it's
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* achievable with current OD & R) let's iterate
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* through F for best fit
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*/
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while ((F >= STG4K3_PLL_MIN_F) &&
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(F <= STG4K3_PLL_MAX_F)) {
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/* Calc VCO at full accuracy */
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ulVCO = refClock / R;
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ulVCO = F * ulVCO;
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/*
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* Check it's within restricted VCO range
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* unless of course the desired frequency is
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* above the restricted range, then test
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* against VCO limit
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*/
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if ((ulVCO >= STG4K3_PLL_MINR_VCO) &&
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((ulVCO <= STG4K3_PLL_MAXR_VCO) ||
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((coreClock > STG4K3_PLL_MAXR_VCO)
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&& (ulVCO <= STG4K3_PLL_MAX_VCO)))) {
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ulTmp = (ulVCO >> OD); /* Clock = VCO / (2^OD) */
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/* Is this clock good enough? */
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if ((ulTmp >= ulMinClock)
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&& (ulTmp <= ulMaxClock)) {
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ulPhaseScore = (((refClock / R) - (refClock / STG4K3_PLL_MAX_R))) / ((refClock - (refClock / STG4K3_PLL_MAX_R)) >> 10);
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ulVcoScore = ((ulVCO - STG4K3_PLL_MINR_VCO)) / ((STG4K3_PLL_MAXR_VCO - STG4K3_PLL_MINR_VCO) >> 10);
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ulScore = ulPhaseScore + ulVcoScore;
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if (!ulBestScore) {
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ulBestVCO = ulVCO;
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ulBestOD = OD;
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ulBestF = F;
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ulBestR = R;
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ulBestClk = ulTmp;
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ulBestScore =
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ulScore;
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}
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/* is this better, ( aim for highest Score) */
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/*--------------------------------------------------------------------------
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Here we want to use a scoring system which will take account of both the
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value at the phase comparater and the VCO output
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to do this we will use a cumulative score between the two
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The way this ends up is that we choose the first value in the loop anyway
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but we shall keep this code in case new restrictions come into play
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--------------------------------------------------------------------------*/
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if ((ulScore >= ulBestScore) && (OD > 0)) {
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ulBestVCO = ulVCO;
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ulBestOD = OD;
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ulBestF = F;
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ulBestR = R;
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ulBestClk = ulTmp;
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ulBestScore =
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ulScore;
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}
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}
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}
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F++;
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}
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R++;
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}
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}
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/*
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did we find anything?
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Then return RFOD
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*/
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if (ulBestScore) {
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*ROut = ulBestR;
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*FOut = ulBestF;
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if ((ulBestOD == 2) || (ulBestOD == 3)) {
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*POut = 3;
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} else
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*POut = ulBestOD;
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}
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return (ulBestClk);
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}
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int SetCoreClockPLL(volatile STG4000REG __iomem *pSTGReg, struct pci_dev *pDev)
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{
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u32 F, R, P;
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u16 core_pll = 0, sub;
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u32 ulCoreClock;
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u32 tmp;
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u32 ulChipSpeed;
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u8 rev;
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STG_WRITE_REG(IntMask, 0xFFFF);
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/* Disable Primary Core Thread0 */
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tmp = STG_READ_REG(Thread0Enable);
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CLEAR_BIT(0);
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STG_WRITE_REG(Thread0Enable, tmp);
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/* Disable Primary Core Thread1 */
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tmp = STG_READ_REG(Thread1Enable);
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CLEAR_BIT(0);
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STG_WRITE_REG(Thread1Enable, tmp);
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STG_WRITE_REG(SoftwareReset,
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PMX2_SOFTRESET_REG_RST | PMX2_SOFTRESET_ROM_RST);
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STG_WRITE_REG(SoftwareReset,
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PMX2_SOFTRESET_REG_RST | PMX2_SOFTRESET_TA_RST |
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PMX2_SOFTRESET_ROM_RST);
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/* Need to play around to reset TA */
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STG_WRITE_REG(TAConfiguration, 0);
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STG_WRITE_REG(SoftwareReset,
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PMX2_SOFTRESET_REG_RST | PMX2_SOFTRESET_ROM_RST);
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STG_WRITE_REG(SoftwareReset,
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PMX2_SOFTRESET_REG_RST | PMX2_SOFTRESET_TA_RST |
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PMX2_SOFTRESET_ROM_RST);
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pci_read_config_word(pDev, PCI_CONFIG_SUBSYS_ID, &sub);
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pci_read_config_byte(pDev, PCI_REVISION_ID, &rev);
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ulChipSpeed = InitSDRAMRegisters(pSTGReg, (u32)sub, (u32)rev);
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if (ulChipSpeed == 0)
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return -EINVAL;
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ulCoreClock = ProgramClock(REF_FREQ, CORE_PLL_FREQ, &F, &R, &P);
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core_pll |= ((P) | ((F - 2) << 2) | ((R - 2) << 11));
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/* Set Core PLL Control to Core PLL Mode */
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/* Send bits 0:7 of the Core PLL Mode register */
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tmp = ((CORE_PLL_MODE_REG_0_7 << 8) | (core_pll & 0x00FF));
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pci_write_config_word(pDev, CorePllControl, tmp);
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/* Without some delay between the PCI config writes the clock does
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not reliably set when the code is compiled -O3
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*/
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OS_DELAY(1000000);
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tmp |= SET_BIT(14);
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pci_write_config_word(pDev, CorePllControl, tmp);
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OS_DELAY(1000000);
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/* Send bits 8:15 of the Core PLL Mode register */
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tmp =
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((CORE_PLL_MODE_REG_8_15 << 8) | ((core_pll & 0xFF00) >> 8));
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pci_write_config_word(pDev, CorePllControl, tmp);
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OS_DELAY(1000000);
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tmp |= SET_BIT(14);
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pci_write_config_word(pDev, CorePllControl, tmp);
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OS_DELAY(1000000);
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STG_WRITE_REG(SoftwareReset, PMX2_SOFTRESET_ALL);
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#if 0
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/* Enable Primary Core Thread0 */
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tmp = ((STG_READ_REG(Thread0Enable)) | SET_BIT(0));
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STG_WRITE_REG(Thread0Enable, tmp);
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/* Enable Primary Core Thread1 */
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tmp = ((STG_READ_REG(Thread1Enable)) | SET_BIT(0));
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STG_WRITE_REG(Thread1Enable, tmp);
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#endif
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return 0;
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}
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