coreboot/src/device/dram/ddr3.c
Patrick Georgi a73b93157f tree: drop last paragraph of GPL copyright header
It encourages users from writing to the FSF without giving an address.
Linux also prefers to drop that and their checkpatch.pl (that we
imported) looks out for that.

This is the result of util/scripts/no-fsf-addresses.sh with no further
editing.

Change-Id: Ie96faea295fe001911d77dbc51e9a6789558fbd6
Signed-off-by: Patrick Georgi <pgeorgi@chromium.org>
Reviewed-on: http://review.coreboot.org/11888
Tested-by: build bot (Jenkins)
Reviewed-by: Alexandru Gagniuc <mr.nuke.me@gmail.com>
Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2015-10-31 21:37:39 +01:00

621 lines
16 KiB
C

/*
* 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>
/*==============================================================================
* = 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 dimm_is_registered(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;
}
/**
* \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, i;
u8 *ptr;
u16 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;
/* Compute the CRC */
crc = 0;
ptr = spd;
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 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 ftb_divisor, ftb_dividend, capacity_shift, bus_width;
u8 reg8;
u32 mtb; /* medium 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;
/* 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;
printram(" 1.25V");
}
if (reg8 & (1 << 1)) {
dimm->flags.operable_1_35V = 1;
printram(" 1.35V");
}
if (!(reg8 & (1 << 0))) {
dimm->flags.operable_1_50V = 1;
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;
/* Fine Timebase (FTB) Dividend/Divisor */
/* Dividend */
ftb_dividend = (spd[9] >> 4) & 0x0f;
/* Divisor */
ftb_divisor = spd[9] & 0x0f;
/* 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;
/* 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(" DIMM Rank1 Address bits mirrored!!!\n");
}
dimm->reference_card = spd[62] & 0x1f;
printram(" DIMM Reference card %c\n", 'A' + dimm->reference_card);
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);
}
/*==============================================================================
*= 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;
}