src/northbridge/amd/gx2/raminit.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /*
  * This file is part of the coreboot project.
  *
  * Copyright (C) 2007 Advanced Micro Devices, Inc.
  * Copyright (C) 2010 Nils Jacobs
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 as
  * published by the Free Software Foundation.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
  * GNU General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
  */

 #include <cpu/amd/gx2def.h>
 #include <spd.h>

 static const unsigned char NumColAddr[] = {
 	0x00, 0x10, 0x11, 0x00, 0x00, 0x00, 0x00, 0x07,
 	0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F,
 };

 static void hcf(void)
 {
 	printk(BIOS_EMERG, "DIE\n");
 	/* this guarantees we flush the UART fifos (if any) and also
 	 * ensures that things, in general, keep going so no debug output
 	 * is lost
 	 */
 	while (1)
 		printk(BIOS_EMERG, (0));
 }

 static void auto_size_dimm(unsigned int dimm)
 {
 	uint32_t dimm_setting;
 	uint16_t dimm_size;
 	uint8_t spd_byte;
 	msr_t msr;

 	dimm_setting = 0;

 	printk(BIOS_DEBUG, "Check present\n");
 	/* Check that we have a dimm */
 	if (spd_read_byte(dimm, SPD_MEMORY_TYPE) == 0xFF) {
 		return;
 	}

 	printk(BIOS_DEBUG, "MODBANKS\n");
 	/* Field: Module Banks per DIMM */
 	/* EEPROM byte usage: (5) Number of DIMM Banks */
 	spd_byte = spd_read_byte(dimm, SPD_NUM_DIMM_BANKS);
 	if ((MIN_MOD_BANKS > spd_byte) || (spd_byte > MAX_MOD_BANKS)) {
 		printk(BIOS_EMERG, "Number of module banks not compatible\n");
 		post_code(ERROR_BANK_SET);
 		hcf();
 	}
 	dimm_setting |= (spd_byte >> 1) << CF07_UPPER_D0_MB_SHIFT;

 	printk(BIOS_DEBUG, "FIELDBANKS\n");
 	/* Field: Banks per SDRAM device */
 	/* EEPROM byte usage: (17) Number of Banks on SDRAM Device */
 	spd_byte = spd_read_byte(dimm, SPD_NUM_BANKS_PER_SDRAM);
 	if ((MIN_DEV_BANKS > spd_byte) || (spd_byte > MAX_DEV_BANKS)) {
 		printk(BIOS_EMERG, "Number of device banks not compatible\n");
 		post_code(ERROR_BANK_SET);
 		hcf();
 	}
 	dimm_setting |= (spd_byte >> 2) << CF07_UPPER_D0_CB_SHIFT;

 	printk(BIOS_DEBUG, "SPDNUMROWS\n");
 	/* Field: DIMM size
 	 * EEPROM byte usage:
 	 *   (3)  Number of Row Addresses
 	 *   (4)  Number of Column Addresses
 	 *   (5)  Number of DIMM Banks
 	 *   (31) Module Bank Density
 	 * Size = Module Density * Module Banks
 	 */
 	if ((spd_read_byte(dimm, SPD_NUM_ROWS) & 0xF0)
 	    || (spd_read_byte(dimm, SPD_NUM_COLUMNS) & 0xF0)) {
 		printk(BIOS_EMERG, "Asymmetric DIMM not compatible\n");
 		post_code(ERROR_UNSUPPORTED_DIMM);
 		hcf();
 	}

 	printk(BIOS_DEBUG, "SPDBANKDENSITY\n");
 	dimm_size = spd_read_byte(dimm, SPD_BANK_DENSITY);
 	printk(BIOS_DEBUG, "DIMMSIZE\n");
 	dimm_size |= (dimm_size << 8);	/* align so 1GB(bit0) is bit 8, this is a little weird to get gcc to not optimize this out */
 	dimm_size &= 0x01FC;	/* and off 2GB DIMM size : not supported and the 1GB size we just moved up to bit 8 as well as all the extra on top */

 	/* Module Density * Module Banks */
 	dimm_size <<= (dimm_setting >> CF07_UPPER_D0_MB_SHIFT) & 1;	/* shift to multiply by # DIMM banks */
 	printk(BIOS_DEBUG, "BEFORT CTZ\n");
 	dimm_size = __builtin_ctz(dimm_size);
 	printk(BIOS_DEBUG, "TEST DIMM SIZE>7\n");
 	if (dimm_size > 7) {	/* 7 is 512MB only support 512MB per DIMM */
 		printk(BIOS_EMERG, "Only support up to 512MB per DIMM\n");
 		post_code(ERROR_DENSITY_DIMM);
 		hcf();
 	}
 	dimm_setting |= dimm_size << CF07_UPPER_D0_SZ_SHIFT;
 	printk(BIOS_DEBUG, "PAGESIZE\n");

 /*
  * Field: PAGE size
  * EEPROM byte usage: (4)  Number of Column Addresses
  * PageSize = 2^# Column Addresses * Data width in bytes
  *                                   (should be 8bytes for a normal DIMM)
  *
  * But this really works by magic.
  * If ma[11:0] is the memory address pins, and pa[13:0] is the physical column
  * address that MC generates, here is how the MC assigns the pa onto the
  * ma pins:
  *
  * ma  11 10 09 08 07 06 05 04 03 02 01 00
  * ---------------------------------------
  * pa                 09 08 07 06 05 04 03  (7 col addr bits = 1K page size)
  * pa              10 09 08 07 06 05 04 03  (8 col addr bits = 2K page size)
  * pa           11 10 09 08 07 06 05 04 03  (9 col addr bits = 4K page size)
  * pa        12 11 10 09 08 07 06 05 04 03  (10 col addr bits = 8K page size)
  * pa  13 AP 12 11 10 09 08 07 06 05 04 03  (11 col addr bits = 16K page size)
  *
  * (AP = autoprecharge bit)
  *
  * Remember that pa[2:0] are zeroed out since it's a 64-bit data bus (8 bytes),
  * so lower 3 address bits are dont_cares. So from the table above,
  * it's easier to see what the old code is doing: if for example,
  * #col_addr_bits=7(06h), it adds 3 to get 10, then does 2^10=1K.
  */

 	spd_byte = NumColAddr[spd_read_byte(dimm, SPD_NUM_COLUMNS) & 0xF];
 	printk(BIOS_DEBUG, "MAXCOLADDR\n");
 	if (spd_byte > MAX_COL_ADDR) {
 		printk(BIOS_EMERG, "DIMM page size not compatible\n");
 		post_code(ERROR_SET_PAGE);
 		hcf();
 	}
 	printk(BIOS_DEBUG, ">11address test\n");
 	spd_byte -= 7;
 	if (spd_byte > 4) {	/* if the value is above 4 it means >11 col address lines */
 		spd_byte = 7;	/* which means >16k so set to disabled */
 	}
 	dimm_setting |= spd_byte << CF07_UPPER_D0_PSZ_SHIFT;	/* 0=1k,1=2k,2=4k,etc */

 	printk(BIOS_DEBUG, "RDMSR CF07\n");
 	msr = rdmsr(MC_CF07_DATA);
 	printk(BIOS_DEBUG, "WRMSR CF07\n");
 	if (dimm == DIMM0) {
 		msr.hi &= 0xFFFF0000;
 		msr.hi |= dimm_setting;
 	} else {
 		msr.hi &= 0x0000FFFF;
 		msr.hi |= dimm_setting << 16;
 	}
 	wrmsr(MC_CF07_DATA, msr);
 	printk(BIOS_DEBUG, "ALL DONE\n");
 }

 static void checkDDRMax(void)
 {
 	uint8_t spd_byte0, spd_byte1;
 	uint16_t speed;

 	/* PC133 identifier */
 	spd_byte0 = spd_read_byte(DIMM0, SPD_MIN_CYCLE_TIME_AT_CAS_MAX);
 	if (spd_byte0 == 0xFF) {
 		spd_byte0 = 0;
 	}
 	spd_byte1 = spd_read_byte(DIMM1, SPD_MIN_CYCLE_TIME_AT_CAS_MAX);
 	if (spd_byte1 == 0xFF) {
 		spd_byte1 = 0;
 	}

 	/* Use the slowest DIMM */
 	if (spd_byte0 < spd_byte1) {
 		spd_byte0 = spd_byte1;
 	}

 	/* Turn SPD ns time into MHZ. Check what the asm does to this math. */
 	speed = 20000 / (((spd_byte0 >> 4) * 10) + (spd_byte0 & 0x0F));

 	/* current speed > max speed? */
 	if (GeodeLinkSpeed() > speed) {
 		printk(BIOS_EMERG, "DIMM overclocked. Check GeodeLink Speed\n");
 		post_code(POST_PLL_MEM_FAIL);
 		hcf();
 	}
 }

 const uint16_t REF_RATE[] = { 15, 3, 7, 31, 62, 125 };	/* ns */

 static void set_refresh_rate(void)
 {
 	uint8_t spd_byte0, spd_byte1;
 	uint16_t rate0, rate1;
 	msr_t msr;

 	spd_byte0 = spd_read_byte(DIMM0, SPD_REFRESH);
 	spd_byte0 &= 0xF;
 	if (spd_byte0 > 5) {
 		spd_byte0 = 5;
 	}
 	rate0 = REF_RATE[spd_byte0];

 	spd_byte1 = spd_read_byte(DIMM1, SPD_REFRESH);
 	spd_byte1 &= 0xF;
 	if (spd_byte1 > 5) {
 		spd_byte1 = 5;
 	}
 	rate1 = REF_RATE[spd_byte1];

 	/* Use the faster rate (lowest number) */
 	if (rate0 > rate1) {
 		rate0 = rate1;
 	}

 	msr = rdmsr(MC_CF07_DATA);
 	msr.lo |= ((rate0 * (GeodeLinkSpeed() / 2)) / 16)
 			<< CF07_LOWER_REF_INT_SHIFT;
 	wrmsr(MC_CF07_DATA, msr);
 }

 const uint8_t CASDDR[] = { 5, 5, 2, 6, 0 };	/* 1(1.5), 1.5, 2, 2.5, 0 */

 static u8 getcasmap(u32 dimm, u16 glspeed)
 {
 	u16 dimm_speed;
 	u8 spd_byte, casmap, casmap_shift=0;

 	/**************************	 DIMM0	**********************************/
 	casmap = spd_read_byte(dimm, SPD_ACCEPTABLE_CAS_LATENCIES);
 	if (casmap != 0xFF) {
 		/* IF -.5 timing is supported, check -.5 timing > GeodeLink */
 		spd_byte = spd_read_byte(dimm, SPD_SDRAM_CYCLE_TIME_2ND);
 		if (spd_byte != 0) {
 			/* Turn SPD ns time into MHZ. Check what the asm does to this math. */
 			dimm_speed = 20000 / (((spd_byte >> 4) * 10) + (spd_byte & 0x0F));
 			if (dimm_speed >= glspeed) {
 				casmap_shift = 1; /* -.5 is a shift of 1 */
 				/* IF -1 timing is supported, check -1 timing > GeodeLink */
 				spd_byte = spd_read_byte(dimm, SPD_SDRAM_CYCLE_TIME_3RD);
 				if (spd_byte != 0) {
 					/* Turn SPD ns time into MHZ. Check what the asm does to this math. */
 					dimm_speed = 20000 / (((spd_byte >> 4) * 10) + (spd_byte & 0x0F));
 					if (dimm_speed >= glspeed) {
 						casmap_shift = 2; /* -1 is a shift of 2 */
 					}
 				}	/* SPD_SDRAM_CYCLE_TIME_3RD (-1) !=0 */
 			} else {
 				casmap_shift = 0;
 			}
 		}	/* SPD_SDRAM_CYCLE_TIME_2ND (-.5) !=0 */
 		/* set the casmap based on the shift to limit possible CAS settings */
 		spd_byte = 31 - __builtin_clz((uint32_t) casmap);
 		/* just want bits in the lower byte since we have to cast to a 32 */
 		casmap &= 0xFF << (spd_byte - casmap_shift);
 	} else {		/* No DIMM */
 		casmap = 0;
 	}
 	return casmap;
 }

 static void setCAS(void)
 {
 /*
  *	setCAS
  *	EEPROM byte usage: (18) SDRAM device attributes - CAS latency
  *	EEPROM byte usage: (23) SDRAM Minimum Clock Cycle Time @ CLX -.5
  *	EEPROM byte usage: (25) SDRAM Minimum Clock Cycle Time @ CLX -1
  *
  *	The CAS setting is based on the information provided in each DIMMs SPD.
  *	 The speed at which a DIMM can run is described relative to the slowest
  *	 CAS the DIMM supports. Each speed for the relative CAS settings is
  *	 checked that it is within the GeodeLink speed. If it isn't within the GeodeLink
  *	 speed, the CAS setting	 is removed from the list of good settings for
  *	 the DIMM. This is done for both DIMMs and the lists are compared to
  *	 find the lowest common CAS latency setting. If there are no CAS settings
  *	 in common we out a ERROR_DIFF_DIMMS (78h) to port 80h and halt.
  *
  *	Entry:
  *	Exit: Set fastest CAS Latency based on GeodeLink speed and SPD information.
  *	Destroys: We really use everything !
  */
 	uint16_t glspeed;
 	uint8_t spd_byte, casmap0, casmap1;
 	msr_t msr;

 	glspeed = GeodeLinkSpeed();

 	casmap0 = getcasmap(DIMM0, glspeed);
 	casmap1 = getcasmap(DIMM1, glspeed);

 	/* CAS_LAT MAP COMPARE */
 	if (casmap0 == 0) {
 		spd_byte = CASDDR[__builtin_ctz(casmap1)];
 	} else if (casmap1 == 0) {
 		spd_byte = CASDDR[__builtin_ctz(casmap0)];
 	} else if ((casmap0 &= casmap1)) {
 		spd_byte = CASDDR[__builtin_ctz(casmap0)];
 	} else {
 		printk(BIOS_EMERG, "DIMM CAS Latencies not compatible\n");
 		post_code(ERROR_DIFF_DIMMS);
 		hcf();
 	}

 	msr = rdmsr(MC_CF8F_DATA);
 	msr.lo &= ~(7 << CF8F_LOWER_CAS_LAT_SHIFT);
 	msr.lo |= spd_byte << CF8F_LOWER_CAS_LAT_SHIFT;
 	wrmsr(MC_CF8F_DATA, msr);
 }

 static void set_latencies(void)
 {
 	uint32_t memspeed, dimm_setting;
 	uint8_t spd_byte0, spd_byte1;
 	msr_t msr;

 	memspeed = GeodeLinkSpeed() / 2;
 	dimm_setting = 0;

 	/* MC_CF8F setup */
 	/* tRAS */
 	spd_byte0 = spd_read_byte(DIMM0, SPD_tRAS);
 	if (spd_byte0 == 0xFF) {
 		spd_byte0 = 0;
 	}
 	spd_byte1 = spd_read_byte(DIMM1, SPD_tRAS);
 	if (spd_byte1 == 0xFF) {
 		spd_byte1 = 0;
 	}
 	if (spd_byte0 < spd_byte1) {
 		spd_byte0 = spd_byte1;
 	}
 	/* (ns/(1/MHz) = (us*MHZ)/1000 = clocks/1000 = clocks) */
 	spd_byte1 = (spd_byte0 * memspeed) / 1000;
 	if (((spd_byte0 * memspeed) % 1000)) {
 		++spd_byte1;
 	}
 	if (spd_byte1 > 6) {
 		--spd_byte1;
 	}
 	dimm_setting |= spd_byte1 << CF8F_LOWER_ACT2PRE_SHIFT;

 	/* tRP */
 	spd_byte0 = spd_read_byte(DIMM0, SPD_tRP);
 	if (spd_byte0 == 0xFF) {
 		spd_byte0 = 0;
 	}
 	spd_byte1 = spd_read_byte(DIMM1, SPD_tRP);
 	if (spd_byte1 == 0xFF) {
 		spd_byte1 = 0;
 	}
 	if (spd_byte0 < spd_byte1) {
 		spd_byte0 = spd_byte1;
 	}
 	/* (ns/(1/MHz) = (us*MHZ)/1000 = clocks/1000 = clocks) */
 	spd_byte1 = ((spd_byte0 >> 2) * memspeed) / 1000;
 	if ((((spd_byte0 >> 2) * memspeed) % 1000)) {
 		++spd_byte1;
 	}
 	dimm_setting |= spd_byte1 << CF8F_LOWER_PRE2ACT_SHIFT;

 	/* tRCD */
 	spd_byte0 = spd_read_byte(DIMM0, SPD_tRCD);
 	if (spd_byte0 == 0xFF) {
 		spd_byte0 = 0;
 	}
 	spd_byte1 = spd_read_byte(DIMM1, SPD_tRCD);
 	if (spd_byte1 == 0xFF) {
 		spd_byte1 = 0;
 	}
 	if (spd_byte0 < spd_byte1) {
 		spd_byte0 = spd_byte1;
 	}
 	/* (ns/(1/MHz) = (us*MHZ)/1000 = clocks/1000 = clocks) */
 	spd_byte1 = ((spd_byte0 >> 2) * memspeed) / 1000;
 	if ((((spd_byte0 >> 2) * memspeed) % 1000)) {
 		++spd_byte1;
 	}
 	dimm_setting |= spd_byte1 << CF8F_LOWER_ACT2CMD_SHIFT;

 	/* tRRD */
 	spd_byte0 = spd_read_byte(DIMM0, SPD_tRRD);
 	if (spd_byte0 == 0xFF) {
 		spd_byte0 = 0;
 	}
 	spd_byte1 = spd_read_byte(DIMM1, SPD_tRRD);
 	if (spd_byte1 == 0xFF) {
 		spd_byte1 = 0;
 	}
 	if (spd_byte0 < spd_byte1) {
 		spd_byte0 = spd_byte1;
 	}
 	/* (ns/(1/MHz) = (us*MHZ)/1000 = clocks/1000 = clocks) */
 	spd_byte1 = ((spd_byte0 >> 2) * memspeed) / 1000;
 	if ((((spd_byte0 >> 2) * memspeed) % 1000)) {
 		++spd_byte1;
 	}
 	dimm_setting |= spd_byte1 << CF8F_LOWER_ACT2ACT_SHIFT;

 	/* tRC = tRP + tRAS */
 	dimm_setting |= (((dimm_setting >> CF8F_LOWER_ACT2PRE_SHIFT) & 0x0F) +
 	     		((dimm_setting >> CF8F_LOWER_PRE2ACT_SHIFT) & 0x07))
 	    			<< CF8F_LOWER_REF2ACT_SHIFT;

 	msr = rdmsr(MC_CF8F_DATA);
 	msr.lo &= 0xF00000FF;
 	msr.lo |= dimm_setting;
 	msr.hi |= CF8F_UPPER_REORDER_DIS_SET;
 	wrmsr(MC_CF8F_DATA, msr);
 	printk(BIOS_DEBUG, "MSR MC_CF8F_DATA (%08x) value is %08x:%08x\n",
 	MC_CF8F_DATA, msr.hi, msr.lo);
 }

 static void set_extended_mode_registers(void)
 {
 	uint8_t spd_byte0, spd_byte1;
 	msr_t msr;
 	spd_byte0 = spd_read_byte(DIMM0, SPD_DEVICE_ATTRIBUTES_GENERAL);
 	if (spd_byte0 == 0xFF) {
 		spd_byte0 = 0;
 	}
 	spd_byte1 = spd_read_byte(DIMM1, SPD_DEVICE_ATTRIBUTES_GENERAL);
 	if (spd_byte1 == 0xFF) {
 		spd_byte1 = 0;
 	}
 	spd_byte1 &= spd_byte0;

 	msr = rdmsr(MC_CF07_DATA);
 	if (spd_byte1 & 1) {	/* Drive Strength Control */
 		msr.lo |= CF07_LOWER_EMR_DRV_SET;
 	}
 	if (spd_byte1 & 2) {	/* FET Control */
 		msr.lo |= CF07_LOWER_EMR_QFC_SET;
 	}
 	wrmsr(MC_CF07_DATA, msr);
 }

 static void sdram_set_registers(const struct mem_controller *ctrl)
 {
 	msr_t msr;
 	uint32_t msrnum;

 	/* Set Refresh Staggering */
 	msrnum = MC_CF07_DATA;
 	msr = rdmsr(msrnum);
 	msr.lo &= ~0xC0;
 	msr.lo |= 0x0;		/* set refresh to 4SDRAM clocks */
 	wrmsr(msrnum, msr);
 }

 static void sdram_set_spd_registers(const struct mem_controller *ctrl)
 {
 	uint8_t spd_byte;

 	printk(BIOS_DEBUG, "sdram_set_spd_register\n");
 	post_code(POST_MEM_SETUP);	/* post_70h */

 	spd_byte = spd_read_byte(DIMM0, SPD_MODULE_ATTRIBUTES);
 	printk(BIOS_DEBUG, "Check DIMM 0\n");
 	/* Check DIMM is not Register and not Buffered DIMMs. */
 	if ((spd_byte != 0xFF) && (spd_byte & 3)) {
 		printk(BIOS_EMERG, "DIMM0 NOT COMPATIBLE\n");
 		post_code(ERROR_UNSUPPORTED_DIMM);
 		hcf();
 	}
 	printk(BIOS_DEBUG, "Check DIMM 1\n");
 	spd_byte = spd_read_byte(DIMM1, SPD_MODULE_ATTRIBUTES);
 	if ((spd_byte != 0xFF) && (spd_byte & 3)) {
 		printk(BIOS_EMERG, "DIMM1 NOT COMPATIBLE\n");
 		post_code(ERROR_UNSUPPORTED_DIMM);
 		hcf();
 	}

 	post_code(POST_MEM_SETUP2);	/* post_72h */
 	printk(BIOS_DEBUG, "Check DDR MAX\n");

 	/* Check that the memory is not overclocked. */
 	checkDDRMax();

 	/* Size the DIMMS */
 	post_code(POST_MEM_SETUP3);	/* post_73h */
 	printk(BIOS_DEBUG, "AUTOSIZE DIMM 0\n");
 	auto_size_dimm(DIMM0);
 	post_code(POST_MEM_SETUP4);	/* post_74h */
 	printk(BIOS_DEBUG, "AUTOSIZE DIMM 1\n");
 	auto_size_dimm(DIMM1);

 	/* Set CAS latency */
 	printk(BIOS_DEBUG, "set cas latency\n");
 	post_code(POST_MEM_SETUP5);	/* post_75h */
 	setCAS();

 	/* Set all the other latencies here (tRAS, tRP....) */
 	printk(BIOS_DEBUG, "set all latency\n");
 	set_latencies();

 	/* Set Extended Mode Registers */
 	printk(BIOS_DEBUG, "set emrs\n");
 	set_extended_mode_registers();

 	printk(BIOS_DEBUG, "set ref rate\n");
 	/* Set Memory Refresh Rate */
 	set_refresh_rate();
 }

 /* Section 6.1.3, LX processor databooks, BIOS Initialization Sequence
  * Section 4.1.4, GX/CS5535 GeodeROM Porting guide */
 static void sdram_enable(int controllers, const struct mem_controller *ctrl)
 {
 	int i;
 	msr_t msr;

 	/* 2. clock gating for PMode */
 	msr = rdmsr(MC_GLD_MSR_PM);
 	msr.lo &= ~0x04;
 	msr.lo |=  0x01;
 	wrmsr(MC_GLD_MSR_PM, msr);
 	/* undocmented bits in GX, in LX there are
 	 * 8 bits in PM1_UP_DLY */
 	msr = rdmsr(MC_CF1017_DATA);
 	msr.lo = 0x0101;
 	wrmsr(MC_CF1017_DATA, msr);
 	printk(BIOS_DEBUG, "sdram_enable step 2\n");

 	/* 3. release CKE mask to enable CKE */
 	msr = rdmsr(MC_CFCLK_DBUG);
 	msr.lo &= ~(0x03 << 8);
 	wrmsr(MC_CFCLK_DBUG, msr);
 	printk(BIOS_DEBUG, "sdram_enable step 3\n");

 	/* 4. set and clear REF_TST 16 times, more shouldn't hurt
 	 * why this is before EMRS and MRS ? */
 	for (i = 0; i < 19; i++) {
 		msr = rdmsr(MC_CF07_DATA);
 		msr.lo |=  (0x01 << 3);
 		wrmsr(MC_CF07_DATA, msr);
 		msr.lo &= ~(0x01 << 3);
 		wrmsr(MC_CF07_DATA, msr);
 	}
 	printk(BIOS_DEBUG, "sdram_enable step 4\n");

 	/* 6. enable DLL, load Extended Mode Register by set and clear PROG_DRAM */
 	msr = rdmsr(MC_CF07_DATA);
 	msr.lo |=  ((0x01 << 28) | 0x01);
 	wrmsr(MC_CF07_DATA, msr);
 	msr.lo &= ~((0x01 << 28) | 0x01);
 	wrmsr(MC_CF07_DATA, msr);
 	printk(BIOS_DEBUG, "sdram_enable step 6\n");

 	/* 7. Reset DLL, Bit 27 is undocumented in GX datasheet,
 	 * it is documented in LX datasheet */
 	/* load Mode Register by set and clear PROG_DRAM */
 	msr = rdmsr(MC_CF07_DATA);
 	msr.lo |=  ((0x01 << 27) | 0x01);
 	wrmsr(MC_CF07_DATA, msr);
 	msr.lo &= ~((0x01 << 27) | 0x01);
 	wrmsr(MC_CF07_DATA, msr);
 	printk(BIOS_DEBUG, "sdram_enable step 7\n");

 	/* 8. load Mode Register by set and clear PROG_DRAM */
 	msr = rdmsr(MC_CF07_DATA);
 	msr.lo |=  0x01;
 	wrmsr(MC_CF07_DATA, msr);
 	msr.lo &= ~0x01;
 	wrmsr(MC_CF07_DATA, msr);
 	printk(BIOS_DEBUG, "sdram_enable step 8\n");

 	/* wait 200 SDCLKs */
 	for (i = 0; i < 200; i++)
 		outb(0xaa, 0x80);

 	/* load RDSYNC */
 	msr = rdmsr(MC_CF_RDSYNC);
 	msr.hi = 0x000ff310;
 	/* the above setting is supposed to be good for "slow" ram. We have found that for
 	 * some dram, at some clock rates, e.g. hynix at 366/244, this will actually
 	 * cause errors. The fix is to just set it to 0x310. Tested on 3 boards
 	 * with 3 different type of dram -- Hynix, PSC, infineon.
 	 * I am leaving this comment here so that at some future time nobody is tempted
 	 * to mess with this setting -- RGM, 9/2006
 	 */
 	msr.hi = 0x00000310;
 	msr.lo = 0x00000000;
 	wrmsr(MC_CF_RDSYNC, msr);

 	/* set delay control */
 	msr = rdmsr(GLCP_DELAY_CONTROLS);
 	msr.hi = 0x830d415a;
 	msr.lo = 0x8ea0ad6a;
 	wrmsr(GLCP_DELAY_CONTROLS, msr);

 	/* The RAM dll needs a write to lock on so generate a few dummy writes */
 	/* Note: The descriptor needs to be enabled to point at memory */
 	volatile unsigned long *ptr;
 	for (i = 0; i < 5; i++) {
 		ptr = (void *)i;
 		*ptr = (unsigned long)i;
 	}

 	print_info("RAM DLL lock\n");

 }
	/*
	* This file is part of the coreboot project.
	*
	* Copyright (C) 2007 Advanced Micro Devices, Inc.
	* Copyright (C) 2010 Nils Jacobs
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 as
	* published by the Free Software Foundation.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
	*/

	#include <cpu/amd/gx2def.h>
	#include <spd.h>

	static const unsigned char NumColAddr[] = {
	0x00, 0x10, 0x11, 0x00, 0x00, 0x00, 0x00, 0x07,
	0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F,
	};

	static void hcf(void)
	{
	printk(BIOS_EMERG, "DIE\n");
	/* this guarantees we flush the UART fifos (if any) and also
	* ensures that things, in general, keep going so no debug output
	* is lost
	*/
	while (1)
	printk(BIOS_EMERG, (0));
	}

	static void auto_size_dimm(unsigned int dimm)
	{
	uint32_t dimm_setting;
	uint16_t dimm_size;
	uint8_t spd_byte;
	msr_t msr;

	dimm_setting = 0;

	printk(BIOS_DEBUG, "Check present\n");
	/* Check that we have a dimm */
	if (spd_read_byte(dimm, SPD_MEMORY_TYPE) == 0xFF) {
	return;
	}

	printk(BIOS_DEBUG, "MODBANKS\n");
	/* Field: Module Banks per DIMM */
	/* EEPROM byte usage: (5) Number of DIMM Banks */
	spd_byte = spd_read_byte(dimm, SPD_NUM_DIMM_BANKS);
	if ((MIN_MOD_BANKS > spd_byte) \|\| (spd_byte > MAX_MOD_BANKS)) {
	printk(BIOS_EMERG, "Number of module banks not compatible\n");
	post_code(ERROR_BANK_SET);
	hcf();
	}
	dimm_setting \|= (spd_byte >> 1) << CF07_UPPER_D0_MB_SHIFT;

	printk(BIOS_DEBUG, "FIELDBANKS\n");
	/* Field: Banks per SDRAM device */
	/* EEPROM byte usage: (17) Number of Banks on SDRAM Device */
	spd_byte = spd_read_byte(dimm, SPD_NUM_BANKS_PER_SDRAM);
	if ((MIN_DEV_BANKS > spd_byte) \|\| (spd_byte > MAX_DEV_BANKS)) {
	printk(BIOS_EMERG, "Number of device banks not compatible\n");
	post_code(ERROR_BANK_SET);
	hcf();
	}
	dimm_setting \|= (spd_byte >> 2) << CF07_UPPER_D0_CB_SHIFT;

	printk(BIOS_DEBUG, "SPDNUMROWS\n");
	/* Field: DIMM size
	* EEPROM byte usage:
	* (3) Number of Row Addresses
	* (4) Number of Column Addresses
	* (5) Number of DIMM Banks
	* (31) Module Bank Density
	* Size = Module Density * Module Banks
	*/
	if ((spd_read_byte(dimm, SPD_NUM_ROWS) & 0xF0)
	\|\| (spd_read_byte(dimm, SPD_NUM_COLUMNS) & 0xF0)) {
	printk(BIOS_EMERG, "Asymmetric DIMM not compatible\n");
	post_code(ERROR_UNSUPPORTED_DIMM);
	hcf();
	}

	printk(BIOS_DEBUG, "SPDBANKDENSITY\n");
	dimm_size = spd_read_byte(dimm, SPD_BANK_DENSITY);
	printk(BIOS_DEBUG, "DIMMSIZE\n");
	dimm_size \|= (dimm_size << 8); /* align so 1GB(bit0) is bit 8, this is a little weird to get gcc to not optimize this out */
	dimm_size &= 0x01FC; /* and off 2GB DIMM size : not supported and the 1GB size we just moved up to bit 8 as well as all the extra on top */

	/* Module Density * Module Banks */
	dimm_size <<= (dimm_setting >> CF07_UPPER_D0_MB_SHIFT) & 1; /* shift to multiply by # DIMM banks */
	printk(BIOS_DEBUG, "BEFORT CTZ\n");
	dimm_size = __builtin_ctz(dimm_size);
	printk(BIOS_DEBUG, "TEST DIMM SIZE>7\n");
	if (dimm_size > 7) { /* 7 is 512MB only support 512MB per DIMM */
	printk(BIOS_EMERG, "Only support up to 512MB per DIMM\n");
	post_code(ERROR_DENSITY_DIMM);
	hcf();
	}
	dimm_setting \|= dimm_size << CF07_UPPER_D0_SZ_SHIFT;
	printk(BIOS_DEBUG, "PAGESIZE\n");

	/*
	* Field: PAGE size
	* EEPROM byte usage: (4) Number of Column Addresses
	* PageSize = 2^# Column Addresses * Data width in bytes
	* (should be 8bytes for a normal DIMM)
	*
	* But this really works by magic.
	* If ma[11:0] is the memory address pins, and pa[13:0] is the physical column
	* address that MC generates, here is how the MC assigns the pa onto the
	* ma pins:
	*
	* ma 11 10 09 08 07 06 05 04 03 02 01 00
	* ---------------------------------------
	* pa 09 08 07 06 05 04 03 (7 col addr bits = 1K page size)
	* pa 10 09 08 07 06 05 04 03 (8 col addr bits = 2K page size)
	* pa 11 10 09 08 07 06 05 04 03 (9 col addr bits = 4K page size)
	* pa 12 11 10 09 08 07 06 05 04 03 (10 col addr bits = 8K page size)
	* pa 13 AP 12 11 10 09 08 07 06 05 04 03 (11 col addr bits = 16K page size)
	*
	* (AP = autoprecharge bit)
	*
	* Remember that pa[2:0] are zeroed out since it's a 64-bit data bus (8 bytes),
	* so lower 3 address bits are dont_cares. So from the table above,
	* it's easier to see what the old code is doing: if for example,
	* #col_addr_bits=7(06h), it adds 3 to get 10, then does 2^10=1K.
	*/

	spd_byte = NumColAddr[spd_read_byte(dimm, SPD_NUM_COLUMNS) & 0xF];
	printk(BIOS_DEBUG, "MAXCOLADDR\n");
	if (spd_byte > MAX_COL_ADDR) {
	printk(BIOS_EMERG, "DIMM page size not compatible\n");
	post_code(ERROR_SET_PAGE);
	hcf();
	}
	printk(BIOS_DEBUG, ">11address test\n");
	spd_byte -= 7;
	if (spd_byte > 4) { /* if the value is above 4 it means >11 col address lines */
	spd_byte = 7; /* which means >16k so set to disabled */
	}
	dimm_setting \|= spd_byte << CF07_UPPER_D0_PSZ_SHIFT; /* 0=1k,1=2k,2=4k,etc */

	printk(BIOS_DEBUG, "RDMSR CF07\n");
	msr = rdmsr(MC_CF07_DATA);
	printk(BIOS_DEBUG, "WRMSR CF07\n");
	if (dimm == DIMM0) {
	msr.hi &= 0xFFFF0000;
	msr.hi \|= dimm_setting;
	} else {
	msr.hi &= 0x0000FFFF;
	msr.hi \|= dimm_setting << 16;
	}
	wrmsr(MC_CF07_DATA, msr);
	printk(BIOS_DEBUG, "ALL DONE\n");
	}

	static void checkDDRMax(void)
	{
	uint8_t spd_byte0, spd_byte1;
	uint16_t speed;

	/* PC133 identifier */
	spd_byte0 = spd_read_byte(DIMM0, SPD_MIN_CYCLE_TIME_AT_CAS_MAX);
	if (spd_byte0 == 0xFF) {
	spd_byte0 = 0;
	}
	spd_byte1 = spd_read_byte(DIMM1, SPD_MIN_CYCLE_TIME_AT_CAS_MAX);
	if (spd_byte1 == 0xFF) {
	spd_byte1 = 0;
	}

	/* Use the slowest DIMM */
	if (spd_byte0 < spd_byte1) {
	spd_byte0 = spd_byte1;
	}

	/* Turn SPD ns time into MHZ. Check what the asm does to this math. */
	speed = 20000 / (((spd_byte0 >> 4) * 10) + (spd_byte0 & 0x0F));

	/* current speed > max speed? */
	if (GeodeLinkSpeed() > speed) {
	printk(BIOS_EMERG, "DIMM overclocked. Check GeodeLink Speed\n");
	post_code(POST_PLL_MEM_FAIL);
	hcf();
	}
	}

	const uint16_t REF_RATE[] = { 15, 3, 7, 31, 62, 125 }; /* ns */

	static void set_refresh_rate(void)
	{
	uint8_t spd_byte0, spd_byte1;
	uint16_t rate0, rate1;
	msr_t msr;

	spd_byte0 = spd_read_byte(DIMM0, SPD_REFRESH);
	spd_byte0 &= 0xF;
	if (spd_byte0 > 5) {
	spd_byte0 = 5;
	}
	rate0 = REF_RATE[spd_byte0];

	spd_byte1 = spd_read_byte(DIMM1, SPD_REFRESH);
	spd_byte1 &= 0xF;
	if (spd_byte1 > 5) {
	spd_byte1 = 5;
	}
	rate1 = REF_RATE[spd_byte1];

	/* Use the faster rate (lowest number) */
	if (rate0 > rate1) {
	rate0 = rate1;
	}

	msr = rdmsr(MC_CF07_DATA);
	msr.lo \|= ((rate0 * (GeodeLinkSpeed() / 2)) / 16)
	<< CF07_LOWER_REF_INT_SHIFT;
	wrmsr(MC_CF07_DATA, msr);
	}

	const uint8_t CASDDR[] = { 5, 5, 2, 6, 0 }; /* 1(1.5), 1.5, 2, 2.5, 0 */

	static u8 getcasmap(u32 dimm, u16 glspeed)
	{
	u16 dimm_speed;
	u8 spd_byte, casmap, casmap_shift=0;

	/************************ DIMM0 ********************************/
	casmap = spd_read_byte(dimm, SPD_ACCEPTABLE_CAS_LATENCIES);
	if (casmap != 0xFF) {
	/* IF -.5 timing is supported, check -.5 timing > GeodeLink */
	spd_byte = spd_read_byte(dimm, SPD_SDRAM_CYCLE_TIME_2ND);
	if (spd_byte != 0) {
	/* Turn SPD ns time into MHZ. Check what the asm does to this math. */
	dimm_speed = 20000 / (((spd_byte >> 4) * 10) + (spd_byte & 0x0F));
	if (dimm_speed >= glspeed) {
	casmap_shift = 1; /* -.5 is a shift of 1 */
	/* IF -1 timing is supported, check -1 timing > GeodeLink */
	spd_byte = spd_read_byte(dimm, SPD_SDRAM_CYCLE_TIME_3RD);
	if (spd_byte != 0) {
	/* Turn SPD ns time into MHZ. Check what the asm does to this math. */
	dimm_speed = 20000 / (((spd_byte >> 4) * 10) + (spd_byte & 0x0F));
	if (dimm_speed >= glspeed) {
	casmap_shift = 2; /* -1 is a shift of 2 */
	}
	} /* SPD_SDRAM_CYCLE_TIME_3RD (-1) !=0 */
	} else {
	casmap_shift = 0;
	}
	} /* SPD_SDRAM_CYCLE_TIME_2ND (-.5) !=0 */
	/* set the casmap based on the shift to limit possible CAS settings */
	spd_byte = 31 - __builtin_clz((uint32_t) casmap);
	/* just want bits in the lower byte since we have to cast to a 32 */
	casmap &= 0xFF << (spd_byte - casmap_shift);
	} else { /* No DIMM */
	casmap = 0;
	}
	return casmap;
	}

	static void setCAS(void)
	{
	/*
	* setCAS
	* EEPROM byte usage: (18) SDRAM device attributes - CAS latency
	* EEPROM byte usage: (23) SDRAM Minimum Clock Cycle Time @ CLX -.5
	* EEPROM byte usage: (25) SDRAM Minimum Clock Cycle Time @ CLX -1
	*
	* The CAS setting is based on the information provided in each DIMMs SPD.
	* The speed at which a DIMM can run is described relative to the slowest
	* CAS the DIMM supports. Each speed for the relative CAS settings is
	* checked that it is within the GeodeLink speed. If it isn't within the GeodeLink
	* speed, the CAS setting is removed from the list of good settings for
	* the DIMM. This is done for both DIMMs and the lists are compared to
	* find the lowest common CAS latency setting. If there are no CAS settings
	* in common we out a ERROR_DIFF_DIMMS (78h) to port 80h and halt.
	*
	* Entry:
	* Exit: Set fastest CAS Latency based on GeodeLink speed and SPD information.
	* Destroys: We really use everything !
	*/
	uint16_t glspeed;
	uint8_t spd_byte, casmap0, casmap1;
	msr_t msr;

	glspeed = GeodeLinkSpeed();

	casmap0 = getcasmap(DIMM0, glspeed);
	casmap1 = getcasmap(DIMM1, glspeed);

	/* CAS_LAT MAP COMPARE */
	if (casmap0 == 0) {
	spd_byte = CASDDR[__builtin_ctz(casmap1)];
	} else if (casmap1 == 0) {
	spd_byte = CASDDR[__builtin_ctz(casmap0)];
	} else if ((casmap0 &= casmap1)) {
	spd_byte = CASDDR[__builtin_ctz(casmap0)];
	} else {
	printk(BIOS_EMERG, "DIMM CAS Latencies not compatible\n");
	post_code(ERROR_DIFF_DIMMS);
	hcf();
	}

	msr = rdmsr(MC_CF8F_DATA);
	msr.lo &= ~(7 << CF8F_LOWER_CAS_LAT_SHIFT);
	msr.lo \|= spd_byte << CF8F_LOWER_CAS_LAT_SHIFT;
	wrmsr(MC_CF8F_DATA, msr);
	}

	static void set_latencies(void)
	{
	uint32_t memspeed, dimm_setting;
	uint8_t spd_byte0, spd_byte1;
	msr_t msr;

	memspeed = GeodeLinkSpeed() / 2;
	dimm_setting = 0;

	/* MC_CF8F setup */
	/* tRAS */
	spd_byte0 = spd_read_byte(DIMM0, SPD_tRAS);
	if (spd_byte0 == 0xFF) {
	spd_byte0 = 0;
	}
	spd_byte1 = spd_read_byte(DIMM1, SPD_tRAS);
	if (spd_byte1 == 0xFF) {
	spd_byte1 = 0;
	}
	if (spd_byte0 < spd_byte1) {
	spd_byte0 = spd_byte1;
	}
	/* (ns/(1/MHz) = (usMHZ)/1000 = clocks/1000 = clocks) /
	spd_byte1 = (spd_byte0 * memspeed) / 1000;
	if (((spd_byte0 * memspeed) % 1000)) {
	++spd_byte1;
	}
	if (spd_byte1 > 6) {
	--spd_byte1;
	}
	dimm_setting \|= spd_byte1 << CF8F_LOWER_ACT2PRE_SHIFT;

	/* tRP */
	spd_byte0 = spd_read_byte(DIMM0, SPD_tRP);
	if (spd_byte0 == 0xFF) {
	spd_byte0 = 0;
	}
	spd_byte1 = spd_read_byte(DIMM1, SPD_tRP);
	if (spd_byte1 == 0xFF) {
	spd_byte1 = 0;
	}
	if (spd_byte0 < spd_byte1) {
	spd_byte0 = spd_byte1;
	}
	/* (ns/(1/MHz) = (usMHZ)/1000 = clocks/1000 = clocks) /
	spd_byte1 = ((spd_byte0 >> 2) * memspeed) / 1000;
	if ((((spd_byte0 >> 2) * memspeed) % 1000)) {
	++spd_byte1;
	}
	dimm_setting \|= spd_byte1 << CF8F_LOWER_PRE2ACT_SHIFT;

	/* tRCD */
	spd_byte0 = spd_read_byte(DIMM0, SPD_tRCD);
	if (spd_byte0 == 0xFF) {
	spd_byte0 = 0;
	}
	spd_byte1 = spd_read_byte(DIMM1, SPD_tRCD);
	if (spd_byte1 == 0xFF) {
	spd_byte1 = 0;
	}
	if (spd_byte0 < spd_byte1) {
	spd_byte0 = spd_byte1;
	}
	/* (ns/(1/MHz) = (usMHZ)/1000 = clocks/1000 = clocks) /
	spd_byte1 = ((spd_byte0 >> 2) * memspeed) / 1000;
	if ((((spd_byte0 >> 2) * memspeed) % 1000)) {
	++spd_byte1;
	}
	dimm_setting \|= spd_byte1 << CF8F_LOWER_ACT2CMD_SHIFT;

	/* tRRD */
	spd_byte0 = spd_read_byte(DIMM0, SPD_tRRD);
	if (spd_byte0 == 0xFF) {
	spd_byte0 = 0;
	}
	spd_byte1 = spd_read_byte(DIMM1, SPD_tRRD);
	if (spd_byte1 == 0xFF) {
	spd_byte1 = 0;
	}
	if (spd_byte0 < spd_byte1) {
	spd_byte0 = spd_byte1;
	}
	/* (ns/(1/MHz) = (usMHZ)/1000 = clocks/1000 = clocks) /
	spd_byte1 = ((spd_byte0 >> 2) * memspeed) / 1000;
	if ((((spd_byte0 >> 2) * memspeed) % 1000)) {
	++spd_byte1;
	}
	dimm_setting \|= spd_byte1 << CF8F_LOWER_ACT2ACT_SHIFT;

	/* tRC = tRP + tRAS */
	dimm_setting \|= (((dimm_setting >> CF8F_LOWER_ACT2PRE_SHIFT) & 0x0F) +
	((dimm_setting >> CF8F_LOWER_PRE2ACT_SHIFT) & 0x07))
	<< CF8F_LOWER_REF2ACT_SHIFT;

	msr = rdmsr(MC_CF8F_DATA);
	msr.lo &= 0xF00000FF;
	msr.lo \|= dimm_setting;
	msr.hi \|= CF8F_UPPER_REORDER_DIS_SET;
	wrmsr(MC_CF8F_DATA, msr);
	printk(BIOS_DEBUG, "MSR MC_CF8F_DATA (%08x) value is %08x:%08x\n",
	MC_CF8F_DATA, msr.hi, msr.lo);
	}

	static void set_extended_mode_registers(void)
	{
	uint8_t spd_byte0, spd_byte1;
	msr_t msr;
	spd_byte0 = spd_read_byte(DIMM0, SPD_DEVICE_ATTRIBUTES_GENERAL);
	if (spd_byte0 == 0xFF) {
	spd_byte0 = 0;
	}
	spd_byte1 = spd_read_byte(DIMM1, SPD_DEVICE_ATTRIBUTES_GENERAL);
	if (spd_byte1 == 0xFF) {
	spd_byte1 = 0;
	}
	spd_byte1 &= spd_byte0;

	msr = rdmsr(MC_CF07_DATA);
	if (spd_byte1 & 1) { /* Drive Strength Control */
	msr.lo \|= CF07_LOWER_EMR_DRV_SET;
	}
	if (spd_byte1 & 2) { /* FET Control */
	msr.lo \|= CF07_LOWER_EMR_QFC_SET;
	}
	wrmsr(MC_CF07_DATA, msr);
	}

	static void sdram_set_registers(const struct mem_controller *ctrl)
	{
	msr_t msr;
	uint32_t msrnum;

	/* Set Refresh Staggering */
	msrnum = MC_CF07_DATA;
	msr = rdmsr(msrnum);
	msr.lo &= ~0xC0;
	msr.lo \|= 0x0; /* set refresh to 4SDRAM clocks */
	wrmsr(msrnum, msr);
	}

	static void sdram_set_spd_registers(const struct mem_controller *ctrl)
	{
	uint8_t spd_byte;

	printk(BIOS_DEBUG, "sdram_set_spd_register\n");
	post_code(POST_MEM_SETUP); /* post_70h */

	spd_byte = spd_read_byte(DIMM0, SPD_MODULE_ATTRIBUTES);
	printk(BIOS_DEBUG, "Check DIMM 0\n");
	/* Check DIMM is not Register and not Buffered DIMMs. */
	if ((spd_byte != 0xFF) && (spd_byte & 3)) {
	printk(BIOS_EMERG, "DIMM0 NOT COMPATIBLE\n");
	post_code(ERROR_UNSUPPORTED_DIMM);
	hcf();
	}
	printk(BIOS_DEBUG, "Check DIMM 1\n");
	spd_byte = spd_read_byte(DIMM1, SPD_MODULE_ATTRIBUTES);
	if ((spd_byte != 0xFF) && (spd_byte & 3)) {
	printk(BIOS_EMERG, "DIMM1 NOT COMPATIBLE\n");
	post_code(ERROR_UNSUPPORTED_DIMM);
	hcf();
	}

	post_code(POST_MEM_SETUP2); /* post_72h */
	printk(BIOS_DEBUG, "Check DDR MAX\n");

	/* Check that the memory is not overclocked. */
	checkDDRMax();

	/* Size the DIMMS */
	post_code(POST_MEM_SETUP3); /* post_73h */
	printk(BIOS_DEBUG, "AUTOSIZE DIMM 0\n");
	auto_size_dimm(DIMM0);
	post_code(POST_MEM_SETUP4); /* post_74h */
	printk(BIOS_DEBUG, "AUTOSIZE DIMM 1\n");
	auto_size_dimm(DIMM1);

	/* Set CAS latency */
	printk(BIOS_DEBUG, "set cas latency\n");
	post_code(POST_MEM_SETUP5); /* post_75h */
	setCAS();

	/* Set all the other latencies here (tRAS, tRP....) */
	printk(BIOS_DEBUG, "set all latency\n");
	set_latencies();

	/* Set Extended Mode Registers */
	printk(BIOS_DEBUG, "set emrs\n");
	set_extended_mode_registers();

	printk(BIOS_DEBUG, "set ref rate\n");
	/* Set Memory Refresh Rate */
	set_refresh_rate();
	}

	/* Section 6.1.3, LX processor databooks, BIOS Initialization Sequence
	* Section 4.1.4, GX/CS5535 GeodeROM Porting guide */
	static void sdram_enable(int controllers, const struct mem_controller *ctrl)
	{
	int i;
	msr_t msr;

	/* 2. clock gating for PMode */
	msr = rdmsr(MC_GLD_MSR_PM);
	msr.lo &= ~0x04;
	msr.lo \|= 0x01;
	wrmsr(MC_GLD_MSR_PM, msr);
	/* undocmented bits in GX, in LX there are
	* 8 bits in PM1_UP_DLY */
	msr = rdmsr(MC_CF1017_DATA);
	msr.lo = 0x0101;
	wrmsr(MC_CF1017_DATA, msr);
	printk(BIOS_DEBUG, "sdram_enable step 2\n");

	/* 3. release CKE mask to enable CKE */
	msr = rdmsr(MC_CFCLK_DBUG);
	msr.lo &= ~(0x03 << 8);
	wrmsr(MC_CFCLK_DBUG, msr);
	printk(BIOS_DEBUG, "sdram_enable step 3\n");

	/* 4. set and clear REF_TST 16 times, more shouldn't hurt
	* why this is before EMRS and MRS ? */
	for (i = 0; i < 19; i++) {
	msr = rdmsr(MC_CF07_DATA);
	msr.lo \|= (0x01 << 3);
	wrmsr(MC_CF07_DATA, msr);
	msr.lo &= ~(0x01 << 3);
	wrmsr(MC_CF07_DATA, msr);
	}
	printk(BIOS_DEBUG, "sdram_enable step 4\n");

	/* 6. enable DLL, load Extended Mode Register by set and clear PROG_DRAM */
	msr = rdmsr(MC_CF07_DATA);
	msr.lo \|= ((0x01 << 28) \| 0x01);
	wrmsr(MC_CF07_DATA, msr);
	msr.lo &= ~((0x01 << 28) \| 0x01);
	wrmsr(MC_CF07_DATA, msr);
	printk(BIOS_DEBUG, "sdram_enable step 6\n");

	/* 7. Reset DLL, Bit 27 is undocumented in GX datasheet,
	* it is documented in LX datasheet */
	/* load Mode Register by set and clear PROG_DRAM */
	msr = rdmsr(MC_CF07_DATA);
	msr.lo \|= ((0x01 << 27) \| 0x01);
	wrmsr(MC_CF07_DATA, msr);
	msr.lo &= ~((0x01 << 27) \| 0x01);
	wrmsr(MC_CF07_DATA, msr);
	printk(BIOS_DEBUG, "sdram_enable step 7\n");

	/* 8. load Mode Register by set and clear PROG_DRAM */
	msr = rdmsr(MC_CF07_DATA);
	msr.lo \|= 0x01;
	wrmsr(MC_CF07_DATA, msr);
	msr.lo &= ~0x01;
	wrmsr(MC_CF07_DATA, msr);
	printk(BIOS_DEBUG, "sdram_enable step 8\n");

	/* wait 200 SDCLKs */
	for (i = 0; i < 200; i++)
	outb(0xaa, 0x80);

	/* load RDSYNC */
	msr = rdmsr(MC_CF_RDSYNC);
	msr.hi = 0x000ff310;
	/* the above setting is supposed to be good for "slow" ram. We have found that for
	* some dram, at some clock rates, e.g. hynix at 366/244, this will actually
	* cause errors. The fix is to just set it to 0x310. Tested on 3 boards
	* with 3 different type of dram -- Hynix, PSC, infineon.
	* I am leaving this comment here so that at some future time nobody is tempted
	* to mess with this setting -- RGM, 9/2006
	*/
	msr.hi = 0x00000310;
	msr.lo = 0x00000000;
	wrmsr(MC_CF_RDSYNC, msr);

	/* set delay control */
	msr = rdmsr(GLCP_DELAY_CONTROLS);
	msr.hi = 0x830d415a;
	msr.lo = 0x8ea0ad6a;
	wrmsr(GLCP_DELAY_CONTROLS, msr);

	/* The RAM dll needs a write to lock on so generate a few dummy writes */
	/* Note: The descriptor needs to be enabled to point at memory */
	volatile unsigned long *ptr;
	for (i = 0; i < 5; i++) {
	ptr = (void *)i;
	*ptr = (unsigned long)i;
	}

	print_info("RAM DLL lock\n");

	}