src/device/dram/ddr3.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /*
  * This file is part of the coreboot project.
  *
  * Copyright (C) 2011-2013  Alexandru Gagniuc <mr.nuke.me@gmail.com>
  *
  * This program is free software: you can redistribute it and/or modify
  * it under the terms of the GNU General Public License as published by
  * the Free Software Foundation, either version 2 of the License, or
  * (at your option) any later version.
  *
  * 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.
  */

 /**
  * @file ddr3.c
  *
  * \brief Utilities for decoding DDR3 SPDs
  */

 #include <console/console.h>
 #include <device/device.h>
 #include <device/dram/ddr3.h>
 #include <string.h>

 /*==============================================================================
  * = DDR3 SPD decoding helpers
  *----------------------------------------------------------------------------*/

 /**
  * \brief Checks if the DIMM is Registered based on byte[3] of the SPD
  *
  * Tells if the DIMM type is registered or not.
  *
  * @param type DIMM type. This is byte[3] of the SPD.
  */
 int spd_dimm_is_registered_ddr3(enum spd_dimm_type type)
 {
 	if ((type == SPD_DIMM_TYPE_RDIMM)
 	    | (type == SPD_DIMM_TYPE_MINI_RDIMM)
 	    | (type == SPD_DIMM_TYPE_72B_SO_RDIMM))
 		return 1;

 	return 0;
 }

 u16 ddr3_crc16(const u8 *ptr, int n_crc)
 {
 	int i;
 	u16 crc = 0;

 	while (--n_crc >= 0) {
 		crc = crc ^ ((int)*ptr++ << 8);
 		for (i = 0; i < 8; ++i)
 			if (crc & 0x8000) {
 				crc = (crc << 1) ^ 0x1021;
 			} else {
 				crc = crc << 1;
 			}
 	}

 	return crc;
 }

 /**
  * \brief Calculate the CRC of a DDR3 SPD
  *
  * @param spd pointer to raw SPD data
  * @param len length of data in SPD
  *
  * @return the CRC of the SPD data, or 0 when spd data is truncated.
  */
 u16 spd_ddr3_calc_crc(u8 *spd, int len)
 {
 	int n_crc;

 	/* Find the number of bytes covered by CRC */
 	if (spd[0] & 0x80) {
 		n_crc = 117;
 	} else {
 		n_crc = 126;
 	}

 	if (len < n_crc)
 		/* Not enough bytes available to get the CRC */
 		return 0;

 	return ddr3_crc16(spd, n_crc);
 }

 /**
  * \brief Calculate the CRC of a DDR3 SPD unique identifier
  *
  * @param spd pointer to raw SPD data
  * @param len length of data in SPD
  *
  * @return the CRC of SPD data bytes 117..127, or 0 when spd data is truncated.
  */
 u16 spd_ddr3_calc_unique_crc(u8 *spd, int len)
 {
 	if (len < (117 + 11))
 		/* Not enough bytes available to get the CRC */
 		return 0;

 	return ddr3_crc16(&spd[117], 11);
 }

 /**
  * \brief Decode the raw SPD data
  *
  * Decodes a raw SPD data from a DDR3 DIMM, and organizes it into a
  * @ref dimm_attr structure. The SPD data must first be read in a contiguous
  * array, and passed to this function.
  *
  * @param dimm pointer to @ref dimm_attr structure where the decoded data is to
  * 	       be stored
  * @param spd array of raw data previously read from the SPD.
  *
  * @return @ref spd_status enumerator
  *		SPD_STATUS_OK -- decoding was successful
  *		SPD_STATUS_INVALID -- invalid SPD or not a DDR3 SPD
  *		SPD_STATUS_CRC_ERROR -- CRC did not verify
  *		SPD_STATUS_INVALID_FIELD -- A field with an invalid value was
  * 					    detected.
  */
 int spd_decode_ddr3(dimm_attr * dimm, spd_raw_data spd)
 {
 	int ret;
 	u16 crc, spd_crc;
 	u8 capacity_shift, bus_width;
 	u8 reg8;
 	u32 mtb;		/* medium time base */
 	u32 ftb;		/* fine time base */
 	unsigned int val, param;

 	ret = SPD_STATUS_OK;

 	/* Don't assume we memset 0 dimm struct. Clear all our flags */
 	dimm->flags.raw = 0;
 	dimm->dimms_per_channel = 3;

 	/* Make sure that the SPD dump is indeed from a DDR3 module */
 	if (spd[2] != SPD_MEMORY_TYPE_SDRAM_DDR3) {
 		printram("Not a DDR3 SPD!\n");
 		dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED;
 		return SPD_STATUS_INVALID;
 	}
 	dimm->dram_type = SPD_MEMORY_TYPE_SDRAM_DDR3;
 	dimm->dimm_type = spd[3] & 0xf;

 	crc = spd_ddr3_calc_crc(spd, sizeof(spd_raw_data));
 	/* Compare with the CRC in the SPD */
 	spd_crc = (spd[127] << 8) + spd[126];
 	/* Verify the CRC is correct */
 	if (crc != spd_crc) {
 		printram("ERROR: SPD CRC failed!!!\n");
 		ret = SPD_STATUS_CRC_ERROR;
 	};

 	printram("  Revision           : %x\n", spd[1]);
 	printram("  Type               : %x\n", spd[2]);
 	printram("  Key                : %x\n", spd[3]);

 	reg8 = spd[4];
 	/* Number of memory banks */
 	val = (reg8 >> 4) & 0x07;
 	if (val > 0x03) {
 		printram("  Invalid number of memory banks\n");
 		ret = SPD_STATUS_INVALID_FIELD;
 	}
 	param = 1 << (val + 3);
 	printram("  Banks              : %u\n", param);
 	/* SDRAM capacity */
 	capacity_shift = reg8 & 0x0f;
 	if (capacity_shift > 0x06) {
 		printram("  Invalid module capacity\n");
 		ret = SPD_STATUS_INVALID_FIELD;
 	}
 	if (capacity_shift < 0x02) {
 		printram("  Capacity           : %u Mb\n", 256 << capacity_shift);
 	} else {
 		printram("  Capacity           : %u Gb\n", 1 << (capacity_shift - 2));
 	}

 	reg8 = spd[5];
 	/* Row address bits */
 	val = (reg8 >> 3) & 0x07;
 	if (val > 0x04) {
 		printram("  Invalid row address bits\n");
 		ret = SPD_STATUS_INVALID_FIELD;
 	}
 	dimm->row_bits = val + 12;
 	/* Column address bits */
 	val = reg8 & 0x07;
 	if (val > 0x03) {
 		printram("  Invalid column address bits\n");
 		ret = SPD_STATUS_INVALID_FIELD;
 	}
 	dimm->col_bits = val + 9;

 	/* Module nominal voltage */
 	reg8 = spd[6];
 	printram("  Supported voltages :");
 	if (reg8 & (1 << 2)) {
 		dimm->flags.operable_1_25V = 1;
 		dimm->voltage = 1250;
 		printram(" 1.25V");
 	}
 	if (reg8 & (1 << 1)) {
 		dimm->flags.operable_1_35V = 1;
 		dimm->voltage = 1300;
 		printram(" 1.35V");
 	}
 	if (!(reg8 & (1 << 0))) {
 		dimm->flags.operable_1_50V = 1;
 		dimm->voltage = 1500;
 		printram(" 1.5V");
 	}
 	printram("\n");

 	/* Module organization */
 	reg8 = spd[7];
 	/* Number of ranks */
 	val = (reg8 >> 3) & 0x07;
 	if (val > 3) {
 		printram("  Invalid number of ranks\n");
 		ret = SPD_STATUS_INVALID_FIELD;
 	}
 	dimm->ranks = val + 1;
 	/* SDRAM device width */
 	val = (reg8 & 0x07);
 	if (val > 3) {
 		printram("  Invalid SDRAM width\n");
 		ret = SPD_STATUS_INVALID_FIELD;
 	}
 	dimm->width = (4 << val);
 	printram("  SDRAM width        : %u\n", dimm->width);

 	/* Memory bus width */
 	reg8 = spd[8];
 	/* Bus extension */
 	val = (reg8 >> 3) & 0x03;
 	if (val > 1) {
 		printram("  Invalid bus extension\n");
 		ret = SPD_STATUS_INVALID_FIELD;
 	}
 	dimm->flags.is_ecc = val ? 1 : 0;
 	printram("  Bus extension      : %u bits\n", val ? 8 : 0);
 	/* Bus width */
 	val = reg8 & 0x07;
 	if (val > 3) {
 		printram("  Invalid bus width\n");
 		ret = SPD_STATUS_INVALID_FIELD;
 	}
 	bus_width = 8 << val;
 	printram("  Bus width          : %u\n", bus_width);

 	/* We have all the info we need to compute the dimm size */
 	/* Capacity is 256Mbit multiplied by the power of 2 specified in
 	 * capacity_shift
 	 * The rest is the JEDEC formula */
 	dimm->size_mb = ((1 << (capacity_shift + (25 - 20))) * bus_width
 			 * dimm->ranks) / dimm->width;

 	/* Medium Timebase =
 	 *   Medium Timebase (MTB) Dividend /
 	 *   Medium Timebase (MTB) Divisor */
 	mtb = (((u32) spd[10]) << 8) / spd[11];

 	/* SDRAM Minimum Cycle Time (tCKmin) */
 	dimm->tCK = spd[12] * mtb;
 	/* CAS Latencies Supported */
 	dimm->cas_supported = (spd[15] << 8) + spd[14];
 	/* Minimum CAS Latency Time (tAAmin) */
 	dimm->tAA = spd[16] * mtb;
 	/* Minimum Write Recovery Time (tWRmin) */
 	dimm->tWR = spd[17] * mtb;
 	/* Minimum RAS# to CAS# Delay Time (tRCDmin) */
 	dimm->tRCD = spd[18] * mtb;
 	/* Minimum Row Active to Row Active Delay Time (tRRDmin) */
 	dimm->tRRD = spd[19] * mtb;
 	/* Minimum Row Precharge Delay Time (tRPmin) */
 	dimm->tRP = spd[20] * mtb;
 	/* Minimum Active to Precharge Delay Time (tRASmin) */
 	dimm->tRAS = (((spd[21] & 0x0f) << 8) + spd[22]) * mtb;
 	/* Minimum Active to Active/Refresh Delay Time (tRCmin) */
 	dimm->tRC = (((spd[21] & 0xf0) << 4) + spd[23]) * mtb;
 	/* Minimum Refresh Recovery Delay Time (tRFCmin) */
 	dimm->tRFC = ((spd[25] << 8) + spd[24]) * mtb;
 	/* Minimum Internal Write to Read Command Delay Time (tWTRmin) */
 	dimm->tWTR = spd[26] * mtb;
 	/* Minimum Internal Read to Precharge Command Delay Time (tRTPmin) */
 	dimm->tRTP = spd[27] * mtb;
 	/* Minimum Four Activate Window Delay Time (tFAWmin) */
 	dimm->tFAW = (((spd[28] & 0x0f) << 8) + spd[29]) * mtb;
 	/* Minimum CAS Write Latency Time (tCWLmin)
 	 * - not present in standard SPD */
 	dimm->tCWL = 0;
 	/* System CMD Rate Mode - not present in standard SPD */
 	dimm->tCMD = 0;

 	printram("  FTB timings        :");
 	/* FTB is introduced in SPD revision 1.1 */
 	if (spd[1] >= 0x11 && spd[9] & 0x0f) {
 		printram(" yes\n");

 		/* Fine timebase (1/256 ps) =
 		 *   Fine Timebase (FTB) Dividend /
 		 *   Fine Timebase (FTB) Divisor */
 		ftb = (((u16) spd[9] & 0xf0) << 4) / (spd[9] & 0x0f);

 		/* SPD recommends to round up the MTB part and use a negative
 		 * FTB, so a negative rounding should be always safe */

 		/* SDRAM Minimum Cycle Time (tCKmin) correction */
 		dimm->tCK += (s32)((s8) spd[34] * ftb - 500) / 1000;
 		/* Minimum CAS Latency Time (tAAmin) correction */
 		dimm->tAA += (s32)((s8) spd[35] * ftb - 500) / 1000;
 		/* Minimum RAS# to CAS# Delay Time (tRCDmin) correction */
 		dimm->tRCD += (s32)((s8) spd[36] * ftb - 500) / 1000;
 		/* Minimum Row Precharge Delay Time (tRPmin) correction */
 		dimm->tRP += (s32)((s8) spd[37] * ftb - 500) / 1000;
 		/* Minimum Active to Active/Refresh Delay Time (tRCmin) corr. */
 		dimm->tRC += (s32)((s8) spd[38] * ftb - 500) / 1000;
 	}
 	else {
 		printram(" no\n");
 	}

 	/* SDRAM Optional Features */
 	reg8 = spd[30];
 	printram("  Optional features  :");
 	if (reg8 & 0x80) {
 		dimm->flags.dll_off_mode = 1;
 		printram(" DLL-Off_mode");
 	}
 	if (reg8 & 0x02) {
 		dimm->flags.rzq7_supported = 1;
 		printram(" RZQ/7");
 	}
 	if (reg8 & 0x01) {
 		dimm->flags.rzq6_supported = 1;
 		printram(" RZQ/6");
 	}
 	printram("\n");

 	/* SDRAM Thermal and Refresh Options */
 	reg8 = spd[31];
 	printram("  Thermal features   :");
 	if (reg8 & 0x80) {
 		dimm->flags.pasr = 1;
 		printram(" PASR");
 	}
 	if (reg8 & 0x08) {
 		dimm->flags.odts = 1;
 		printram(" ODTS");
 	}
 	if (reg8 & 0x04) {
 		dimm->flags.asr = 1;
 		printram(" ASR");
 	}
 	if (reg8 & 0x02) {
 		dimm->flags.ext_temp_range = 1;
 		printram(" ext_temp_refresh");
 	}
 	if (reg8 & 0x01) {
 		dimm->flags.ext_temp_refresh = 1;
 		printram(" ext_temp_range");
 	}
 	printram("\n");

 	/*  Module Thermal Sensor */
 	reg8 = spd[32];
 	if (reg8 & 0x80)
 		dimm->flags.therm_sensor = 1;
 	printram("  Thermal sensor     : %s\n",
 		 dimm->flags.therm_sensor ? "yes" : "no");

 	/*  SDRAM Device Type */
 	reg8 = spd[33];
 	printram("  Standard SDRAM     : %s\n", (reg8 & 0x80) ? "no" : "yes");

 	if (spd[63] & 0x01) {
 		dimm->flags.pins_mirrored = 1;
 	}
 	printram("  Rank1 Address bits : %s\n",
 			(spd[63] & 0x01) ? "mirrored" : "normal");

 	dimm->reference_card = spd[62] & 0x1f;
 	printram("  DIMM Reference card: %c\n", 'A' + dimm->reference_card);

 	dimm->manufacturer_id = (spd[118] << 8) | spd[117];
 	printram("  Manufacturer ID    : %x\n", dimm->manufacturer_id);

 	dimm->part_number[16] = 0;
 	memcpy(dimm->part_number, &spd[128], 16);
 	printram("  Part number        : %s\n", dimm->part_number);

 	return ret;
 }

 /**
  * \brief Decode the raw SPD XMP data
  *
  * Decodes a raw SPD XMP data from a DDR3 DIMM, and organizes it into a
  * @ref dimm_attr structure. The SPD data must first be read in a contiguous
  * array, and passed to this function.
  *
  * @param dimm pointer to @ref dimm_attr structure where the decoded data is to
  *        be stored
  * @param spd array of raw data previously read from the SPD.
  *
  * @param profile select one of the profiles to load
  *
  * @return @ref spd_status enumerator
  *		SPD_STATUS_OK -- decoding was successful
  *		SPD_STATUS_INVALID -- invalid SPD or not a DDR3 SPD
  *		SPD_STATUS_CRC_ERROR -- CRC did not verify
  *		SPD_STATUS_INVALID_FIELD -- A field with an invalid value was
  *					    detected.
  */
 int spd_xmp_decode_ddr3(dimm_attr *dimm,
 		       spd_raw_data spd,
 		       enum ddr3_xmp_profile profile)
 {
 	int ret;
 	u32 mtb;		/* medium time base */
 	u8 *xmp;		/* pointer to XMP profile data */

 	/* need a valid SPD */
 	ret = spd_decode_ddr3(dimm, spd);
 	if (ret != SPD_STATUS_OK)
 		return ret;

 	/* search for magic header */
 	if (spd[176] != 0x0C || spd[177] != 0x4A) {
 		printram("Not a DDR3 XMP profile!\n");
 		dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED;
 		return SPD_STATUS_INVALID;
 	}

 	if (profile == DDR3_XMP_PROFILE_1) {
 		if (!(spd[178] & 1)) {
 			printram("Selected XMP profile disabled!\n");
 			dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED;
 			return SPD_STATUS_INVALID;
 		}

 		printram("  XMP Profile        : 1\n");
 		xmp = &spd[185];

 		/* Medium Timebase =
 		 *   Medium Timebase (MTB) Dividend /
 		 *   Medium Timebase (MTB) Divisor */
 		mtb = (((u32) spd[180]) << 8) / spd[181];

 		dimm->dimms_per_channel = ((spd[178] >> 2) & 0x3) + 1;
 	} else {
 		if (!(spd[178] & 2)) {
 			printram("Selected XMP profile disabled!\n");
 			dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED;
 			return SPD_STATUS_INVALID;
 		}
 		printram("  XMP Profile        : 2\n");
 		xmp = &spd[220];

 		/* Medium Timebase =
 		 *   Medium Timebase (MTB) Dividend /
 		 *   Medium Timebase (MTB) Divisor */
 		mtb = (((u32) spd[182]) << 8) / spd[183];

 		dimm->dimms_per_channel = ((spd[178] >> 4) & 0x3) + 1;
 	}

 	printram("  Max DIMMs/channel  : %u\n",
 			dimm->dimms_per_channel);

 	printram("  XMP Revision       : %u.%u\n", spd[179] >> 4, spd[179] & 0xf);

 	/* calculate voltage in mV */
 	dimm->voltage = (xmp[0] & 1) * 50;
 	dimm->voltage += ((xmp[0] >> 1) & 0xf) * 100;
 	dimm->voltage += ((xmp[0] >> 5) & 0x3) * 1000;

 	printram("  Requested voltage  : %u mV\n", dimm->voltage);

 	/* SDRAM Minimum Cycle Time (tCKmin) */
 	dimm->tCK = xmp[1] * mtb;
 	/* CAS Latencies Supported */
 	dimm->cas_supported = ((xmp[4] << 8) + xmp[3]) & 0x7fff;
 	/* Minimum CAS Latency Time (tAAmin) */
 	dimm->tAA = xmp[2] * mtb;
 	/* Minimum Write Recovery Time (tWRmin) */
 	dimm->tWR = xmp[8] * mtb;
 	/* Minimum RAS# to CAS# Delay Time (tRCDmin) */
 	dimm->tRCD = xmp[7] * mtb;
 	/* Minimum Row Active to Row Active Delay Time (tRRDmin) */
 	dimm->tRRD = xmp[17] * mtb;
 	/* Minimum Row Precharge Delay Time (tRPmin) */
 	dimm->tRP = xmp[6] * mtb;
 	/* Minimum Active to Precharge Delay Time (tRASmin) */
 	dimm->tRAS = (((xmp[9] & 0x0f) << 8) + xmp[10]) * mtb;
 	/* Minimum Active to Active/Refresh Delay Time (tRCmin) */
 	dimm->tRC = (((xmp[9] & 0xf0) << 4) + xmp[11]) * mtb;
 	/* Minimum Refresh Recovery Delay Time (tRFCmin) */
 	dimm->tRFC = ((xmp[15] << 8) + xmp[14]) * mtb;
 	/* Minimum Internal Write to Read Command Delay Time (tWTRmin) */
 	dimm->tWTR = xmp[20] * mtb;
 	/* Minimum Internal Read to Precharge Command Delay Time (tRTPmin) */
 	dimm->tRTP = xmp[16] * mtb;
 	/* Minimum Four Activate Window Delay Time (tFAWmin) */
 	dimm->tFAW = (((xmp[18] & 0x0f) << 8) + xmp[19]) * mtb;
 	/* Minimum CAS Write Latency Time (tCWLmin) */
 	dimm->tCWL = xmp[5] * mtb;
 	/* System CMD Rate Mode */
 	dimm->tCMD = xmp[23] * mtb;

 	return ret;
 }

 /*
  * The information printed below has a more informational character, and is not
  * necessarily tied in to RAM init debugging. Hence, we stop using printram(),
  * and use the standard printk()'s below.
  */

 static void print_ns(const char *msg, u32 val)
 {
 	u32 mant, fp;
 	mant = val / 256;
 	fp = (val % 256) * 1000 / 256;

 	printk(BIOS_INFO, "%s%3u.%.3u ns\n", msg, mant, fp);
 }

 /**
 * \brief Print the info in DIMM
 *
 * Print info about the DIMM. Useful to use when CONFIG_DEBUG_RAM_SETUP is
 * selected, or for a purely informative output.
 *
 * @param dimm pointer to already decoded @ref dimm_attr structure
 */
 void dram_print_spd_ddr3(const dimm_attr * dimm)
 {
 	u16 val16;
 	int i;

 	printk(BIOS_INFO, "  Row    addr bits  : %u\n", dimm->row_bits);
 	printk(BIOS_INFO, "  Column addr bits  : %u\n", dimm->col_bits);
 	printk(BIOS_INFO, "  Number of ranks   : %u\n", dimm->ranks);
 	printk(BIOS_INFO, "  DIMM Capacity     : %u MB\n", dimm->size_mb);

 	/* CAS Latencies Supported */
 	val16 = dimm->cas_supported;
 	printk(BIOS_INFO, "  CAS latencies     :");
 	i = 0;
 	do {
 		if (val16 & 1)
 			printk(BIOS_INFO, " %u", i + 4);
 		i++;
 		val16 >>= 1;
 	} while (val16);
 	printk(BIOS_INFO, "\n");

 	print_ns("  tCKmin            : ", dimm->tCK);
 	print_ns("  tAAmin            : ", dimm->tAA);
 	print_ns("  tWRmin            : ", dimm->tWR);
 	print_ns("  tRCDmin           : ", dimm->tRCD);
 	print_ns("  tRRDmin           : ", dimm->tRRD);
 	print_ns("  tRPmin            : ", dimm->tRP);
 	print_ns("  tRASmin           : ", dimm->tRAS);
 	print_ns("  tRCmin            : ", dimm->tRC);
 	print_ns("  tRFCmin           : ", dimm->tRFC);
 	print_ns("  tWTRmin           : ", dimm->tWTR);
 	print_ns("  tRTPmin           : ", dimm->tRTP);
 	print_ns("  tFAWmin           : ", dimm->tFAW);
 	/* Those values are only relevant if an XMP profile sets them */
 	if (dimm->tCWL)
 		print_ns("  tCWLmin           : ", dimm->tCWL);
 	if (dimm->tCMD)
 		printk(BIOS_INFO, "  tCMDmin           : %3u\n",
 		       DIV_ROUND_UP(dimm->tCMD, 256));
 }

 /*==============================================================================
  *= DDR3 MRS helpers
  *----------------------------------------------------------------------------*/

 /*
  * MRS command structure:
  * cmd[15:0] = Address pins MA[15:0]
  * cmd[18:16] = Bank address BA[2:0]
  */

 /* Map tWR value to a bitmask of the MR0 cycle */
 static u16 ddr3_twr_to_mr0_map(u8 twr)
 {
 	if ((twr >= 5) && (twr <= 8))
 		return (twr - 4) << 9;

 	/*
 	 * From 8T onwards, we can only use even values. Round up if we are
 	 * given an odd value.
 	 */
 	if ((twr >= 9) && (twr <= 14))
 		return ((twr + 1) >> 1) << 9;

 	/* tWR == 16T is [000] */
 	return 0;
 }

 /* Map the CAS latency to a bitmask for the MR0 cycle */
 static u16 ddr3_cas_to_mr0_map(u8 cas)
 {
 	u16 mask = 0;
 	/* A[6:4] are bits [2:0] of (CAS - 4) */
 	mask = ((cas - 4) & 0x07) << 4;

 	/* A2 is the MSB of (CAS - 4) */
 	if ((cas - 4) & (1 << 3))
 		mask |= (1 << 2);

 	return mask;
 }

 /**
  * \brief Get command address for a DDR3 MR0 command
  *
  * The DDR3 specification only covers odd write_recovery up to 7T. If an odd
  * write_recovery greater than 7 is specified, it will be rounded up. If a tWR
  * greater than 8 is specified, it is recommended to explicitly round it up or
  * down before calling this function.
  *
  * write_recovery and cas are given in clock cycles. For example, a CAS of 7T
  * should be given as 7.
  *
  * @param precharge_pd
  * @param write_recovery Write recovery latency, tWR in clock cycles.
  * @param dll_reset
  * @param mode
  * @param cas CAS latency in clock cycles.
  * @param burst_type
  * @param burst_length
  */
 mrs_cmd_t ddr3_get_mr0(enum ddr3_mr0_precharge precharge_pd,
 		       u8 write_recovery,
 		       enum ddr3_mr0_dll_reset dll_reset,
 		       enum ddr3_mr0_mode mode,
 		       u8 cas,
 		       enum ddr3_mr0_burst_type burst_type,
 		       enum ddr3_mr0_burst_length burst_length)
 {
 	mrs_cmd_t cmd = 0 << 16;

 	if (precharge_pd == DDR3_MR0_PRECHARGE_FAST)
 		cmd |= (1 << 12);

 	cmd |= ddr3_twr_to_mr0_map(write_recovery);

 	if (dll_reset == DDR3_MR0_DLL_RESET_YES)
 		cmd |= (1 << 8);

 	if (mode == DDR3_MR0_MODE_TEST)
 		cmd |= (1 << 7);

 	cmd |= ddr3_cas_to_mr0_map(cas);

 	if (burst_type == DDR3_MR0_BURST_TYPE_INTERLEAVED)
 		cmd |= (1 << 3);

 	cmd |= (burst_length & 0x03) << 0;

 	return cmd;
 }

 static u16 ddr3_rtt_nom_to_mr1_map(enum ddr3_mr1_rtt_nom rtt_nom)
 {
 	u16 mask = 0;
 	/* A9 <-> rtt_nom[2] */
 	if (rtt_nom & (1 << 2))
 		mask |= (1 << 9);
 	/* A6 <-> rtt_nom[1] */
 	if (rtt_nom & (1 << 1))
 		mask |= (1 << 6);
 	/* A2 <-> rtt_nom[0] */
 	if (rtt_nom & (1 << 0))
 		mask |= (1 << 2);

 	return mask;
 }

 static u16 ddr3_ods_to_mr1_map(enum ddr3_mr1_ods ods)
 {
 	u16 mask = 0;
 	/* A5 <-> ods[1] */
 	if (ods & (1 << 1))
 		mask |= (1 << 5);
 	/* A1 <-> ods[0] */
 	if (ods & (1 << 0))
 		mask |= (1 << 1);

 	return mask;
 }

 /**
  * \brief Get command address for a DDR3 MR1 command
  */
 mrs_cmd_t ddr3_get_mr1(enum ddr3_mr1_qoff qoff,
 		       enum ddr3_mr1_tqds tqds,
 		       enum ddr3_mr1_rtt_nom rtt_nom,
 		       enum ddr3_mr1_write_leveling write_leveling,
 		       enum ddr3_mr1_ods ods,
 		       enum ddr3_mr1_additive_latency additive_latency,
 		       enum ddr3_mr1_dll dll_disable)
 {
 	mrs_cmd_t cmd = 1 << 16;

 	if (qoff == DDR3_MR1_QOFF_DISABLE)
 		cmd |= (1 << 12);

 	if (tqds == DDR3_MR1_TQDS_ENABLE)
 		cmd |= (1 << 11);

 	cmd |= ddr3_rtt_nom_to_mr1_map(rtt_nom);

 	if (write_leveling == DDR3_MR1_WRLVL_ENABLE)
 		cmd |= (1 << 7);

 	cmd |= ddr3_ods_to_mr1_map(ods);

 	cmd |= (additive_latency & 0x03) << 3;

 	if (dll_disable == DDR3_MR1_DLL_DISABLE)
 		cmd |= (1 << 0);

 	return cmd;
 }

 /**
  * \brief Get command address for a DDR3 MR2 command
  *
  * cas_cwl is given in clock cycles. For example, a cas_cwl of 7T should be
  * given as 7.
  *
  * @param rtt_wr
  * @param extended_temp
  * @param self_refresh
  * @param cas_cwl CAS write latency in clock cycles.
  */

 mrs_cmd_t ddr3_get_mr2(enum ddr3_mr2_rttwr rtt_wr,
 		       enum ddr3_mr2_srt_range extended_temp,
 		       enum ddr3_mr2_asr self_refresh, u8 cas_cwl)
 {
 	mrs_cmd_t cmd = 2 << 16;

 	cmd |= (rtt_wr & 0x03) << 9;

 	if (extended_temp == DDR3_MR2_SRT_EXTENDED)
 		cmd |= (1 << 7);

 	if (self_refresh == DDR3_MR2_ASR_AUTO)
 		cmd |= (1 << 6);

 	cmd |= ((cas_cwl - 5) & 0x07) << 3;

 	return cmd;
 }

 /**
  * \brief Get command address for a DDR3 MR3 command
  *
  * @param dataflow_from_mpr Specify a non-zero value to put DRAM in read
  *			    leveling mode. Zero for normal operation.
  */
 mrs_cmd_t ddr3_get_mr3(char dataflow_from_mpr)
 {
 	mrs_cmd_t cmd = 3 << 16;

 	if (dataflow_from_mpr)
 		cmd |= (1 << 2);

 	return cmd;
 }

 /**
  * \brief Mirror the address bits for this MRS command
  *
  * Swap the following bits in the MRS command:
  *	- MA3 <-> MA4
  *	- MA5 <-> MA6
  *	- MA7 <-> MA8
  *	- BA0 <-> BA1
  */
 mrs_cmd_t ddr3_mrs_mirror_pins(mrs_cmd_t cmd)
 {
 	u32 downshift, upshift;
 	/* High bits=    A4    |    A6    |    A8    |    BA1 */
 	/* Low bits =    A3    |    A5    |    A7    |    BA0 */
 	u32 lowbits = (1 << 3) | (1 << 5) | (1 << 7) | (1 << 16);
 	downshift = (cmd & (lowbits << 1));
 	upshift = (cmd & lowbits);
 	cmd &= ~(lowbits | (lowbits << 1));
 	cmd |= (downshift >> 1) | (upshift << 1);
 	return cmd;
 }
	/*
	* This file is part of the coreboot project.
	*
	* Copyright (C) 2011-2013 Alexandru Gagniuc <mr.nuke.me@gmail.com>
	*
	* This program is free software: you can redistribute it and/or modify
	* it under the terms of the GNU General Public License as published by
	* the Free Software Foundation, either version 2 of the License, or
	* (at your option) any later version.
	*
	* 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.
	*/

	/**
	* @file ddr3.c
	*
	* \brief Utilities for decoding DDR3 SPDs
	*/

	#include <console/console.h>
	#include <device/device.h>
	#include <device/dram/ddr3.h>
	#include <string.h>

	/*==============================================================================
	* = DDR3 SPD decoding helpers
	----------------------------------------------------------------------------/

	/**
	* \brief Checks if the DIMM is Registered based on byte[3] of the SPD
	*
	* Tells if the DIMM type is registered or not.
	*
	* @param type DIMM type. This is byte[3] of the SPD.
	*/
	int spd_dimm_is_registered_ddr3(enum spd_dimm_type type)
	{
	if ((type == SPD_DIMM_TYPE_RDIMM)
	\| (type == SPD_DIMM_TYPE_MINI_RDIMM)
	\| (type == SPD_DIMM_TYPE_72B_SO_RDIMM))
	return 1;

	return 0;
	}

	u16 ddr3_crc16(const u8 *ptr, int n_crc)
	{
	int i;
	u16 crc = 0;

	while (--n_crc >= 0) {
	crc = crc ^ ((int)*ptr++ << 8);
	for (i = 0; i < 8; ++i)
	if (crc & 0x8000) {
	crc = (crc << 1) ^ 0x1021;
	} else {
	crc = crc << 1;
	}
	}

	return crc;
	}

	/**
	* \brief Calculate the CRC of a DDR3 SPD
	*
	* @param spd pointer to raw SPD data
	* @param len length of data in SPD
	*
	* @return the CRC of the SPD data, or 0 when spd data is truncated.
	*/
	u16 spd_ddr3_calc_crc(u8 *spd, int len)
	{
	int n_crc;

	/* Find the number of bytes covered by CRC */
	if (spd[0] & 0x80) {
	n_crc = 117;
	} else {
	n_crc = 126;
	}

	if (len < n_crc)
	/* Not enough bytes available to get the CRC */
	return 0;

	return ddr3_crc16(spd, n_crc);
	}

	/**
	* \brief Calculate the CRC of a DDR3 SPD unique identifier
	*
	* @param spd pointer to raw SPD data
	* @param len length of data in SPD
	*
	* @return the CRC of SPD data bytes 117..127, or 0 when spd data is truncated.
	*/
	u16 spd_ddr3_calc_unique_crc(u8 *spd, int len)
	{
	if (len < (117 + 11))
	/* Not enough bytes available to get the CRC */
	return 0;

	return ddr3_crc16(&spd[117], 11);
	}

	/**
	* \brief Decode the raw SPD data
	*
	* Decodes a raw SPD data from a DDR3 DIMM, and organizes it into a
	* @ref dimm_attr structure. The SPD data must first be read in a contiguous
	* array, and passed to this function.
	*
	* @param dimm pointer to @ref dimm_attr structure where the decoded data is to
	* be stored
	* @param spd array of raw data previously read from the SPD.
	*
	* @return @ref spd_status enumerator
	* SPD_STATUS_OK -- decoding was successful
	* SPD_STATUS_INVALID -- invalid SPD or not a DDR3 SPD
	* SPD_STATUS_CRC_ERROR -- CRC did not verify
	* SPD_STATUS_INVALID_FIELD -- A field with an invalid value was
	* detected.
	*/
	int spd_decode_ddr3(dimm_attr * dimm, spd_raw_data spd)
	{
	int ret;
	u16 crc, spd_crc;
	u8 capacity_shift, bus_width;
	u8 reg8;
	u32 mtb; /* medium time base */
	u32 ftb; /* fine time base */
	unsigned int val, param;

	ret = SPD_STATUS_OK;

	/* Don't assume we memset 0 dimm struct. Clear all our flags */
	dimm->flags.raw = 0;
	dimm->dimms_per_channel = 3;

	/* Make sure that the SPD dump is indeed from a DDR3 module */
	if (spd[2] != SPD_MEMORY_TYPE_SDRAM_DDR3) {
	printram("Not a DDR3 SPD!\n");
	dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED;
	return SPD_STATUS_INVALID;
	}
	dimm->dram_type = SPD_MEMORY_TYPE_SDRAM_DDR3;
	dimm->dimm_type = spd[3] & 0xf;

	crc = spd_ddr3_calc_crc(spd, sizeof(spd_raw_data));
	/* Compare with the CRC in the SPD */
	spd_crc = (spd[127] << 8) + spd[126];
	/* Verify the CRC is correct */
	if (crc != spd_crc) {
	printram("ERROR: SPD CRC failed!!!\n");
	ret = SPD_STATUS_CRC_ERROR;
	};

	printram(" Revision : %x\n", spd[1]);
	printram(" Type : %x\n", spd[2]);
	printram(" Key : %x\n", spd[3]);

	reg8 = spd[4];
	/* Number of memory banks */
	val = (reg8 >> 4) & 0x07;
	if (val > 0x03) {
	printram(" Invalid number of memory banks\n");
	ret = SPD_STATUS_INVALID_FIELD;
	}
	param = 1 << (val + 3);
	printram(" Banks : %u\n", param);
	/* SDRAM capacity */
	capacity_shift = reg8 & 0x0f;
	if (capacity_shift > 0x06) {
	printram(" Invalid module capacity\n");
	ret = SPD_STATUS_INVALID_FIELD;
	}
	if (capacity_shift < 0x02) {
	printram(" Capacity : %u Mb\n", 256 << capacity_shift);
	} else {
	printram(" Capacity : %u Gb\n", 1 << (capacity_shift - 2));
	}

	reg8 = spd[5];
	/* Row address bits */
	val = (reg8 >> 3) & 0x07;
	if (val > 0x04) {
	printram(" Invalid row address bits\n");
	ret = SPD_STATUS_INVALID_FIELD;
	}
	dimm->row_bits = val + 12;
	/* Column address bits */
	val = reg8 & 0x07;
	if (val > 0x03) {
	printram(" Invalid column address bits\n");
	ret = SPD_STATUS_INVALID_FIELD;
	}
	dimm->col_bits = val + 9;

	/* Module nominal voltage */
	reg8 = spd[6];
	printram(" Supported voltages :");
	if (reg8 & (1 << 2)) {
	dimm->flags.operable_1_25V = 1;
	dimm->voltage = 1250;
	printram(" 1.25V");
	}
	if (reg8 & (1 << 1)) {
	dimm->flags.operable_1_35V = 1;
	dimm->voltage = 1300;
	printram(" 1.35V");
	}
	if (!(reg8 & (1 << 0))) {
	dimm->flags.operable_1_50V = 1;
	dimm->voltage = 1500;
	printram(" 1.5V");
	}
	printram("\n");

	/* Module organization */
	reg8 = spd[7];
	/* Number of ranks */
	val = (reg8 >> 3) & 0x07;
	if (val > 3) {
	printram(" Invalid number of ranks\n");
	ret = SPD_STATUS_INVALID_FIELD;
	}
	dimm->ranks = val + 1;
	/* SDRAM device width */
	val = (reg8 & 0x07);
	if (val > 3) {
	printram(" Invalid SDRAM width\n");
	ret = SPD_STATUS_INVALID_FIELD;
	}
	dimm->width = (4 << val);
	printram(" SDRAM width : %u\n", dimm->width);

	/* Memory bus width */
	reg8 = spd[8];
	/* Bus extension */
	val = (reg8 >> 3) & 0x03;
	if (val > 1) {
	printram(" Invalid bus extension\n");
	ret = SPD_STATUS_INVALID_FIELD;
	}
	dimm->flags.is_ecc = val ? 1 : 0;
	printram(" Bus extension : %u bits\n", val ? 8 : 0);
	/* Bus width */
	val = reg8 & 0x07;
	if (val > 3) {
	printram(" Invalid bus width\n");
	ret = SPD_STATUS_INVALID_FIELD;
	}
	bus_width = 8 << val;
	printram(" Bus width : %u\n", bus_width);

	/* We have all the info we need to compute the dimm size */
	/* Capacity is 256Mbit multiplied by the power of 2 specified in
	* capacity_shift
	* The rest is the JEDEC formula */
	dimm->size_mb = ((1 << (capacity_shift + (25 - 20))) * bus_width
	* dimm->ranks) / dimm->width;

	/* Medium Timebase =
	* Medium Timebase (MTB) Dividend /
	* Medium Timebase (MTB) Divisor */
	mtb = (((u32) spd[10]) << 8) / spd[11];

	/* SDRAM Minimum Cycle Time (tCKmin) */
	dimm->tCK = spd[12] * mtb;
	/* CAS Latencies Supported */
	dimm->cas_supported = (spd[15] << 8) + spd[14];
	/* Minimum CAS Latency Time (tAAmin) */
	dimm->tAA = spd[16] * mtb;
	/* Minimum Write Recovery Time (tWRmin) */
	dimm->tWR = spd[17] * mtb;
	/* Minimum RAS# to CAS# Delay Time (tRCDmin) */
	dimm->tRCD = spd[18] * mtb;
	/* Minimum Row Active to Row Active Delay Time (tRRDmin) */
	dimm->tRRD = spd[19] * mtb;
	/* Minimum Row Precharge Delay Time (tRPmin) */
	dimm->tRP = spd[20] * mtb;
	/* Minimum Active to Precharge Delay Time (tRASmin) */
	dimm->tRAS = (((spd[21] & 0x0f) << 8) + spd[22]) * mtb;
	/* Minimum Active to Active/Refresh Delay Time (tRCmin) */
	dimm->tRC = (((spd[21] & 0xf0) << 4) + spd[23]) * mtb;
	/* Minimum Refresh Recovery Delay Time (tRFCmin) */
	dimm->tRFC = ((spd[25] << 8) + spd[24]) * mtb;
	/* Minimum Internal Write to Read Command Delay Time (tWTRmin) */
	dimm->tWTR = spd[26] * mtb;
	/* Minimum Internal Read to Precharge Command Delay Time (tRTPmin) */
	dimm->tRTP = spd[27] * mtb;
	/* Minimum Four Activate Window Delay Time (tFAWmin) */
	dimm->tFAW = (((spd[28] & 0x0f) << 8) + spd[29]) * mtb;
	/* Minimum CAS Write Latency Time (tCWLmin)
	* - not present in standard SPD */
	dimm->tCWL = 0;
	/* System CMD Rate Mode - not present in standard SPD */
	dimm->tCMD = 0;

	printram(" FTB timings :");
	/* FTB is introduced in SPD revision 1.1 */
	if (spd[1] >= 0x11 && spd[9] & 0x0f) {
	printram(" yes\n");

	/* Fine timebase (1/256 ps) =
	* Fine Timebase (FTB) Dividend /
	* Fine Timebase (FTB) Divisor */
	ftb = (((u16) spd[9] & 0xf0) << 4) / (spd[9] & 0x0f);

	/* SPD recommends to round up the MTB part and use a negative
	* FTB, so a negative rounding should be always safe */

	/* SDRAM Minimum Cycle Time (tCKmin) correction */
	dimm->tCK += (s32)((s8) spd[34] * ftb - 500) / 1000;
	/* Minimum CAS Latency Time (tAAmin) correction */
	dimm->tAA += (s32)((s8) spd[35] * ftb - 500) / 1000;
	/* Minimum RAS# to CAS# Delay Time (tRCDmin) correction */
	dimm->tRCD += (s32)((s8) spd[36] * ftb - 500) / 1000;
	/* Minimum Row Precharge Delay Time (tRPmin) correction */
	dimm->tRP += (s32)((s8) spd[37] * ftb - 500) / 1000;
	/* Minimum Active to Active/Refresh Delay Time (tRCmin) corr. */
	dimm->tRC += (s32)((s8) spd[38] * ftb - 500) / 1000;
	}
	else {
	printram(" no\n");
	}

	/* SDRAM Optional Features */
	reg8 = spd[30];
	printram(" Optional features :");
	if (reg8 & 0x80) {
	dimm->flags.dll_off_mode = 1;
	printram(" DLL-Off_mode");
	}
	if (reg8 & 0x02) {
	dimm->flags.rzq7_supported = 1;
	printram(" RZQ/7");
	}
	if (reg8 & 0x01) {
	dimm->flags.rzq6_supported = 1;
	printram(" RZQ/6");
	}
	printram("\n");

	/* SDRAM Thermal and Refresh Options */
	reg8 = spd[31];
	printram(" Thermal features :");
	if (reg8 & 0x80) {
	dimm->flags.pasr = 1;
	printram(" PASR");
	}
	if (reg8 & 0x08) {
	dimm->flags.odts = 1;
	printram(" ODTS");
	}
	if (reg8 & 0x04) {
	dimm->flags.asr = 1;
	printram(" ASR");
	}
	if (reg8 & 0x02) {
	dimm->flags.ext_temp_range = 1;
	printram(" ext_temp_refresh");
	}
	if (reg8 & 0x01) {
	dimm->flags.ext_temp_refresh = 1;
	printram(" ext_temp_range");
	}
	printram("\n");

	/* Module Thermal Sensor */
	reg8 = spd[32];
	if (reg8 & 0x80)
	dimm->flags.therm_sensor = 1;
	printram(" Thermal sensor : %s\n",
	dimm->flags.therm_sensor ? "yes" : "no");

	/* SDRAM Device Type */
	reg8 = spd[33];
	printram(" Standard SDRAM : %s\n", (reg8 & 0x80) ? "no" : "yes");

	if (spd[63] & 0x01) {
	dimm->flags.pins_mirrored = 1;
	}
	printram(" Rank1 Address bits : %s\n",
	(spd[63] & 0x01) ? "mirrored" : "normal");

	dimm->reference_card = spd[62] & 0x1f;
	printram(" DIMM Reference card: %c\n", 'A' + dimm->reference_card);

	dimm->manufacturer_id = (spd[118] << 8) \| spd[117];
	printram(" Manufacturer ID : %x\n", dimm->manufacturer_id);

	dimm->part_number[16] = 0;
	memcpy(dimm->part_number, &spd[128], 16);
	printram(" Part number : %s\n", dimm->part_number);

	return ret;
	}

	/**
	* \brief Decode the raw SPD XMP data
	*
	* Decodes a raw SPD XMP data from a DDR3 DIMM, and organizes it into a
	* @ref dimm_attr structure. The SPD data must first be read in a contiguous
	* array, and passed to this function.
	*
	* @param dimm pointer to @ref dimm_attr structure where the decoded data is to
	* be stored
	* @param spd array of raw data previously read from the SPD.
	*
	* @param profile select one of the profiles to load
	*
	* @return @ref spd_status enumerator
	* SPD_STATUS_OK -- decoding was successful
	* SPD_STATUS_INVALID -- invalid SPD or not a DDR3 SPD
	* SPD_STATUS_CRC_ERROR -- CRC did not verify
	* SPD_STATUS_INVALID_FIELD -- A field with an invalid value was
	* detected.
	*/
	int spd_xmp_decode_ddr3(dimm_attr *dimm,
	spd_raw_data spd,
	enum ddr3_xmp_profile profile)
	{
	int ret;
	u32 mtb; /* medium time base */
	u8 xmp; / pointer to XMP profile data */

	/* need a valid SPD */
	ret = spd_decode_ddr3(dimm, spd);
	if (ret != SPD_STATUS_OK)
	return ret;

	/* search for magic header */
	if (spd[176] != 0x0C \|\| spd[177] != 0x4A) {
	printram("Not a DDR3 XMP profile!\n");
	dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED;
	return SPD_STATUS_INVALID;
	}

	if (profile == DDR3_XMP_PROFILE_1) {
	if (!(spd[178] & 1)) {
	printram("Selected XMP profile disabled!\n");
	dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED;
	return SPD_STATUS_INVALID;
	}

	printram(" XMP Profile : 1\n");
	xmp = &spd[185];

	/* Medium Timebase =
	* Medium Timebase (MTB) Dividend /
	* Medium Timebase (MTB) Divisor */
	mtb = (((u32) spd[180]) << 8) / spd[181];

	dimm->dimms_per_channel = ((spd[178] >> 2) & 0x3) + 1;
	} else {
	if (!(spd[178] & 2)) {
	printram("Selected XMP profile disabled!\n");
	dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED;
	return SPD_STATUS_INVALID;
	}
	printram(" XMP Profile : 2\n");
	xmp = &spd[220];

	/* Medium Timebase =
	* Medium Timebase (MTB) Dividend /
	* Medium Timebase (MTB) Divisor */
	mtb = (((u32) spd[182]) << 8) / spd[183];

	dimm->dimms_per_channel = ((spd[178] >> 4) & 0x3) + 1;
	}

	printram(" Max DIMMs/channel : %u\n",
	dimm->dimms_per_channel);

	printram(" XMP Revision : %u.%u\n", spd[179] >> 4, spd[179] & 0xf);

	/* calculate voltage in mV */
	dimm->voltage = (xmp[0] & 1) * 50;
	dimm->voltage += ((xmp[0] >> 1) & 0xf) * 100;
	dimm->voltage += ((xmp[0] >> 5) & 0x3) * 1000;

	printram(" Requested voltage : %u mV\n", dimm->voltage);

	/* SDRAM Minimum Cycle Time (tCKmin) */
	dimm->tCK = xmp[1] * mtb;
	/* CAS Latencies Supported */
	dimm->cas_supported = ((xmp[4] << 8) + xmp[3]) & 0x7fff;
	/* Minimum CAS Latency Time (tAAmin) */
	dimm->tAA = xmp[2] * mtb;
	/* Minimum Write Recovery Time (tWRmin) */
	dimm->tWR = xmp[8] * mtb;
	/* Minimum RAS# to CAS# Delay Time (tRCDmin) */
	dimm->tRCD = xmp[7] * mtb;
	/* Minimum Row Active to Row Active Delay Time (tRRDmin) */
	dimm->tRRD = xmp[17] * mtb;
	/* Minimum Row Precharge Delay Time (tRPmin) */
	dimm->tRP = xmp[6] * mtb;
	/* Minimum Active to Precharge Delay Time (tRASmin) */
	dimm->tRAS = (((xmp[9] & 0x0f) << 8) + xmp[10]) * mtb;
	/* Minimum Active to Active/Refresh Delay Time (tRCmin) */
	dimm->tRC = (((xmp[9] & 0xf0) << 4) + xmp[11]) * mtb;
	/* Minimum Refresh Recovery Delay Time (tRFCmin) */
	dimm->tRFC = ((xmp[15] << 8) + xmp[14]) * mtb;
	/* Minimum Internal Write to Read Command Delay Time (tWTRmin) */
	dimm->tWTR = xmp[20] * mtb;
	/* Minimum Internal Read to Precharge Command Delay Time (tRTPmin) */
	dimm->tRTP = xmp[16] * mtb;
	/* Minimum Four Activate Window Delay Time (tFAWmin) */
	dimm->tFAW = (((xmp[18] & 0x0f) << 8) + xmp[19]) * mtb;
	/* Minimum CAS Write Latency Time (tCWLmin) */
	dimm->tCWL = xmp[5] * mtb;
	/* System CMD Rate Mode */
	dimm->tCMD = xmp[23] * mtb;

	return ret;
	}

	/*
	* The information printed below has a more informational character, and is not
	* necessarily tied in to RAM init debugging. Hence, we stop using printram(),
	* and use the standard printk()'s below.
	*/

	static void print_ns(const char *msg, u32 val)
	{
	u32 mant, fp;
	mant = val / 256;
	fp = (val % 256) * 1000 / 256;

	printk(BIOS_INFO, "%s%3u.%.3u ns\n", msg, mant, fp);
	}

	/**
	* \brief Print the info in DIMM
	*
	* Print info about the DIMM. Useful to use when CONFIG_DEBUG_RAM_SETUP is
	* selected, or for a purely informative output.
	*
	* @param dimm pointer to already decoded @ref dimm_attr structure
	*/
	void dram_print_spd_ddr3(const dimm_attr * dimm)
	{
	u16 val16;
	int i;

	printk(BIOS_INFO, " Row addr bits : %u\n", dimm->row_bits);
	printk(BIOS_INFO, " Column addr bits : %u\n", dimm->col_bits);
	printk(BIOS_INFO, " Number of ranks : %u\n", dimm->ranks);
	printk(BIOS_INFO, " DIMM Capacity : %u MB\n", dimm->size_mb);

	/* CAS Latencies Supported */
	val16 = dimm->cas_supported;
	printk(BIOS_INFO, " CAS latencies :");
	i = 0;
	do {
	if (val16 & 1)
	printk(BIOS_INFO, " %u", i + 4);
	i++;
	val16 >>= 1;
	} while (val16);
	printk(BIOS_INFO, "\n");

	print_ns(" tCKmin : ", dimm->tCK);
	print_ns(" tAAmin : ", dimm->tAA);
	print_ns(" tWRmin : ", dimm->tWR);
	print_ns(" tRCDmin : ", dimm->tRCD);
	print_ns(" tRRDmin : ", dimm->tRRD);
	print_ns(" tRPmin : ", dimm->tRP);
	print_ns(" tRASmin : ", dimm->tRAS);
	print_ns(" tRCmin : ", dimm->tRC);
	print_ns(" tRFCmin : ", dimm->tRFC);
	print_ns(" tWTRmin : ", dimm->tWTR);
	print_ns(" tRTPmin : ", dimm->tRTP);
	print_ns(" tFAWmin : ", dimm->tFAW);
	/* Those values are only relevant if an XMP profile sets them */
	if (dimm->tCWL)
	print_ns(" tCWLmin : ", dimm->tCWL);
	if (dimm->tCMD)
	printk(BIOS_INFO, " tCMDmin : %3u\n",
	DIV_ROUND_UP(dimm->tCMD, 256));
	}

	/*==============================================================================
	*= DDR3 MRS helpers
	----------------------------------------------------------------------------/

	/*
	* MRS command structure:
	* cmd[15:0] = Address pins MA[15:0]
	* cmd[18:16] = Bank address BA[2:0]
	*/

	/* Map tWR value to a bitmask of the MR0 cycle */
	static u16 ddr3_twr_to_mr0_map(u8 twr)
	{
	if ((twr >= 5) && (twr <= 8))
	return (twr - 4) << 9;

	/*
	* From 8T onwards, we can only use even values. Round up if we are
	* given an odd value.
	*/
	if ((twr >= 9) && (twr <= 14))
	return ((twr + 1) >> 1) << 9;

	/* tWR == 16T is [000] */
	return 0;
	}

	/* Map the CAS latency to a bitmask for the MR0 cycle */
	static u16 ddr3_cas_to_mr0_map(u8 cas)
	{
	u16 mask = 0;
	/* A[6:4] are bits [2:0] of (CAS - 4) */
	mask = ((cas - 4) & 0x07) << 4;

	/* A2 is the MSB of (CAS - 4) */
	if ((cas - 4) & (1 << 3))
	mask \|= (1 << 2);

	return mask;
	}

	/**
	* \brief Get command address for a DDR3 MR0 command
	*
	* The DDR3 specification only covers odd write_recovery up to 7T. If an odd
	* write_recovery greater than 7 is specified, it will be rounded up. If a tWR
	* greater than 8 is specified, it is recommended to explicitly round it up or
	* down before calling this function.
	*
	* write_recovery and cas are given in clock cycles. For example, a CAS of 7T
	* should be given as 7.
	*
	* @param precharge_pd
	* @param write_recovery Write recovery latency, tWR in clock cycles.
	* @param dll_reset
	* @param mode
	* @param cas CAS latency in clock cycles.
	* @param burst_type
	* @param burst_length
	*/
	mrs_cmd_t ddr3_get_mr0(enum ddr3_mr0_precharge precharge_pd,
	u8 write_recovery,
	enum ddr3_mr0_dll_reset dll_reset,
	enum ddr3_mr0_mode mode,
	u8 cas,
	enum ddr3_mr0_burst_type burst_type,
	enum ddr3_mr0_burst_length burst_length)
	{
	mrs_cmd_t cmd = 0 << 16;

	if (precharge_pd == DDR3_MR0_PRECHARGE_FAST)
	cmd \|= (1 << 12);

	cmd \|= ddr3_twr_to_mr0_map(write_recovery);

	if (dll_reset == DDR3_MR0_DLL_RESET_YES)
	cmd \|= (1 << 8);

	if (mode == DDR3_MR0_MODE_TEST)
	cmd \|= (1 << 7);

	cmd \|= ddr3_cas_to_mr0_map(cas);

	if (burst_type == DDR3_MR0_BURST_TYPE_INTERLEAVED)
	cmd \|= (1 << 3);

	cmd \|= (burst_length & 0x03) << 0;

	return cmd;
	}

	static u16 ddr3_rtt_nom_to_mr1_map(enum ddr3_mr1_rtt_nom rtt_nom)
	{
	u16 mask = 0;
	/* A9 <-> rtt_nom[2] */
	if (rtt_nom & (1 << 2))
	mask \|= (1 << 9);
	/* A6 <-> rtt_nom[1] */
	if (rtt_nom & (1 << 1))
	mask \|= (1 << 6);
	/* A2 <-> rtt_nom[0] */
	if (rtt_nom & (1 << 0))
	mask \|= (1 << 2);

	return mask;
	}

	static u16 ddr3_ods_to_mr1_map(enum ddr3_mr1_ods ods)
	{
	u16 mask = 0;
	/* A5 <-> ods[1] */
	if (ods & (1 << 1))
	mask \|= (1 << 5);
	/* A1 <-> ods[0] */
	if (ods & (1 << 0))
	mask \|= (1 << 1);

	return mask;
	}

	/**
	* \brief Get command address for a DDR3 MR1 command
	*/
	mrs_cmd_t ddr3_get_mr1(enum ddr3_mr1_qoff qoff,
	enum ddr3_mr1_tqds tqds,
	enum ddr3_mr1_rtt_nom rtt_nom,
	enum ddr3_mr1_write_leveling write_leveling,
	enum ddr3_mr1_ods ods,
	enum ddr3_mr1_additive_latency additive_latency,
	enum ddr3_mr1_dll dll_disable)
	{
	mrs_cmd_t cmd = 1 << 16;

	if (qoff == DDR3_MR1_QOFF_DISABLE)
	cmd \|= (1 << 12);

	if (tqds == DDR3_MR1_TQDS_ENABLE)
	cmd \|= (1 << 11);

	cmd \|= ddr3_rtt_nom_to_mr1_map(rtt_nom);

	if (write_leveling == DDR3_MR1_WRLVL_ENABLE)
	cmd \|= (1 << 7);

	cmd \|= ddr3_ods_to_mr1_map(ods);

	cmd \|= (additive_latency & 0x03) << 3;

	if (dll_disable == DDR3_MR1_DLL_DISABLE)
	cmd \|= (1 << 0);

	return cmd;
	}

	/**
	* \brief Get command address for a DDR3 MR2 command
	*
	* cas_cwl is given in clock cycles. For example, a cas_cwl of 7T should be
	* given as 7.
	*
	* @param rtt_wr
	* @param extended_temp
	* @param self_refresh
	* @param cas_cwl CAS write latency in clock cycles.
	*/

	mrs_cmd_t ddr3_get_mr2(enum ddr3_mr2_rttwr rtt_wr,
	enum ddr3_mr2_srt_range extended_temp,
	enum ddr3_mr2_asr self_refresh, u8 cas_cwl)
	{
	mrs_cmd_t cmd = 2 << 16;

	cmd \|= (rtt_wr & 0x03) << 9;

	if (extended_temp == DDR3_MR2_SRT_EXTENDED)
	cmd \|= (1 << 7);

	if (self_refresh == DDR3_MR2_ASR_AUTO)
	cmd \|= (1 << 6);

	cmd \|= ((cas_cwl - 5) & 0x07) << 3;

	return cmd;
	}

	/**
	* \brief Get command address for a DDR3 MR3 command
	*
	* @param dataflow_from_mpr Specify a non-zero value to put DRAM in read
	* leveling mode. Zero for normal operation.
	*/
	mrs_cmd_t ddr3_get_mr3(char dataflow_from_mpr)
	{
	mrs_cmd_t cmd = 3 << 16;

	if (dataflow_from_mpr)
	cmd \|= (1 << 2);

	return cmd;
	}

	/**
	* \brief Mirror the address bits for this MRS command
	*
	* Swap the following bits in the MRS command:
	* - MA3 <-> MA4
	* - MA5 <-> MA6
	* - MA7 <-> MA8
	* - BA0 <-> BA1
	*/
	mrs_cmd_t ddr3_mrs_mirror_pins(mrs_cmd_t cmd)
	{
	u32 downshift, upshift;
	/* High bits= A4 \| A6 \| A8 \| BA1 */
	/* Low bits = A3 \| A5 \| A7 \| BA0 */
	u32 lowbits = (1 << 3) \| (1 << 5) \| (1 << 7) \| (1 << 16);
	downshift = (cmd & (lowbits << 1));
	upshift = (cmd & lowbits);
	cmd &= ~(lowbits \| (lowbits << 1));
	cmd \|= (downshift >> 1) \| (upshift << 1);
	return cmd;
	}