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/* SPDX-License-Identifier: GPL-2.0-or-later */
/*
* JEDEC Standard No. 21-C
* Annex K: Serial Presence Detect (SPD) for DDR3 SDRAM Modules 2014
* http://www.jedec.org/sites/default/files/docs/4_01_02_11R24.pdf
*/
#ifndef DEVICE_DRAM_DDR3L_H
#define DEVICE_DRAM_DDR3L_H
/**
* @file ddr3.h
*
* \brief Utilities for decoding DDR3 SPDs
*/
#include <spd.h>
#include <device/dram/common.h>
#include <types.h>
/**
* Convenience definitions for SPD offsets
*
* @{
*/
#define SPD_DIMM_MOD_ID1 117
#define SPD_DIMM_MOD_ID2 118
#define SPD_DIMM_SERIAL_NUM 122
#define SPD_DIMM_SERIAL_LEN 4
#define SPD_DIMM_PART_NUM 128
#define SPD_DIMM_PART_LEN 18
/** @} */
/**
* \brief Convenience macro for enabling printk with CONFIG(DEBUG_RAM_SETUP)
*
* Use this macro instead of printk(); for verbose RAM initialization messages.
* When CONFIG(DEBUG_RAM_SETUP) is not selected, these messages are automatically
* disabled.
* @{
*/
#if CONFIG(DEBUG_RAM_SETUP)
#define printram(x, ...) printk(BIOS_DEBUG, x, ##__VA_ARGS__)
#else
#define printram(x, ...)
#endif
/** @} */
/*
* Module type (byte 3, bits 3:0) of SPD
* This definition is specific to DDR3. DDR2 SPDs have a different structure.
*/
enum spd_dimm_type {
SPD_DIMM_TYPE_UNDEFINED = 0x00,
SPD_DIMM_TYPE_RDIMM = 0x01,
SPD_DIMM_TYPE_UDIMM = 0x02,
SPD_DIMM_TYPE_SO_DIMM = 0x03,
SPD_DIMM_TYPE_MICRO_DIMM = 0x04,
SPD_DIMM_TYPE_MINI_RDIMM = 0x05,
SPD_DIMM_TYPE_MINI_UDIMM = 0x06,
SPD_DIMM_TYPE_MINI_CDIMM = 0x07,
SPD_DIMM_TYPE_72B_SO_UDIMM = 0x08,
SPD_DIMM_TYPE_72B_SO_RDIMM = 0x09,
SPD_DIMM_TYPE_72B_SO_CDIMM = 0x0a,
SPD_DIMM_TYPE_LRDIMM = 0x0b,
SPD_DIMM_TYPE_16B_SO_DIMM = 0x0c,
SPD_DIMM_TYPE_32B_SO_DIMM = 0x0d,
/* Masks to bits 3:0 to give the dimm type */
SPD_DIMM_TYPE_MASK = 0x0f,
};
/**
* \brief DIMM flags
*
* Characteristic flags for the DIMM, as presented by the SPD
*/
typedef union dimm_flags_st {
/* The whole point of the union/struct construct is to allow us to clear
* all the bits with one line: flags.raw = 0.
* We do not care how these bits are ordered */
struct {
/* Indicates if rank 1 of DIMM uses a mirrored pin mapping. See:
* Annex K: Serial Presence Detect (SPD) for DDR3 SDRAM */
unsigned int pins_mirrored:1;
/* Module can work at 1.50V - All DIMMS must be 1.5V operable */
unsigned int operable_1_50V:1;
/* Module can work at 1.35V */
unsigned int operable_1_35V:1;
/* Module can work at 1.20V */
unsigned int operable_1_25V:1;
/* Has an 8-bit bus extension, meaning the DIMM supports ECC */
unsigned int is_ecc:1;
/* DLL-Off Mode Support */
unsigned int dll_off_mode:1;
/* Indicates a drive strength of RZQ/6 (40 Ohm) is supported */
unsigned int rzq6_supported:1;
/* Indicates a drive strength of RZQ/7 (35 Ohm) is supported */
unsigned int rzq7_supported:1;
/* Partial Array Self Refresh */
unsigned int pasr:1;
/* On-die Thermal Sensor Readout */
unsigned int odts:1;
/* Auto Self Refresh */
unsigned int asr:1;
/* Extended temperature range supported */
unsigned int ext_temp_range:1;
/* Operating at extended temperature requires 2X refresh rate */
unsigned int ext_temp_refresh:1;
/* Thermal sensor incorporated */
unsigned int therm_sensor:1;
};
unsigned int raw;
} dimm_flags_t;
/**
* \brief DIMM characteristics
*
* The characteristics of each DIMM, as presented by the SPD
*/
typedef struct dimm_attr_st {
enum spd_memory_type dram_type;
enum spd_dimm_type dimm_type;
u16 cas_supported;
/* Flags extracted from SPD */
dimm_flags_t flags;
/* SDRAM width */
u8 width;
/* Number of ranks */
u8 ranks;
/* Number or row address bits */
u8 row_bits;
/* Number or column address bits */
u8 col_bits;
/* Size of module in MiB */
u32 size_mb;
/* Latencies are in units of 1/256 ns */
u32 tCK;
u32 tAA;
u32 tWR;
u32 tRCD;
u32 tRRD;
u32 tRP;
u32 tRAS;
u32 tRC;
u32 tRFC;
u32 tWTR;
u32 tRTP;
u32 tFAW;
u32 tCWL;
u16 tCMD;
u8 reference_card;
/* XMP: Module voltage in mV */
u16 voltage;
/* XMP: max DIMMs per channel supported (1-4) */
u8 dimms_per_channel;
/* Manufacturer ID */
u16 manufacturer_id;
/* ASCII part number - NULL terminated */
u8 part_number[17];
/* Serial number */
u8 serial[SPD_DIMM_SERIAL_LEN];
} dimm_attr;
enum ddr3_xmp_profile {
DDR3_XMP_PROFILE_1 = 0,
DDR3_XMP_PROFILE_2 = 1,
};
typedef u8 spd_raw_data[256];
u16 spd_ddr3_calc_crc(u8 *spd, int len);
u16 spd_ddr3_calc_unique_crc(u8 *spd, int len);
int spd_decode_ddr3(dimm_attr *dimm, spd_raw_data spd_data);
int spd_dimm_is_registered_ddr3(enum spd_dimm_type type);
void dram_print_spd_ddr3(const dimm_attr *dimm);
int spd_xmp_decode_ddr3(dimm_attr *dimm,
spd_raw_data spd,
enum ddr3_xmp_profile profile);
enum cb_err spd_add_smbios17(const u8 channel, const u8 slot,
const u16 selected_freq,
const dimm_attr *info);
/**
* \brief Read double word from specified address
*
* Should be useful when doing an MRS to the DIMM
*/
static inline u32 volatile_read(volatile uintptr_t addr)
{
volatile u32 result;
result = *(volatile u32 *)addr;
return result;
}
/**
* \brief Representation of an MRS command
*
* This represents an MRS command as seen by the DIMM. This is not a memory
* address that can be read to generate an MRS command. The mapping of CPU
* to memory pins is hardware-dependent.
* \n
* The idea is to generalize the MRS code, and only need a hardware-specific
* function to map the MRS bits to CPU address bits. An MRS command can be
* sent like:
* @code{.c}
* u32 addr;
* mrs_cmd_t mrs;
* chipset_enable_mrs_command_mode();
* mrs = ddr3_get_mr2(rtt_wr, srt, asr, cwl)
* if (rank_has_mirrorred_pins)
* mrs = ddr3_mrs_mirror_pins(mrs);
* addr = chipset_specific_get_mrs_addr(mrs);
* volatile_read(addr);
* @endcode
*
* The MRS representation has the following structure:
* - cmd[15:0] = Address pins MA[15:0]
* - cmd[18:16] = Bank address BA[2:0]
*/
typedef u32 mrs_cmd_t;
enum ddr3_mr0_precharge {
DDR3_MR0_PRECHARGE_SLOW = 0,
DDR3_MR0_PRECHARGE_FAST = 1,
};
enum ddr3_mr0_mode {
DDR3_MR0_MODE_NORMAL = 0,
DDR3_MR0_MODE_TEST = 1,
};
enum ddr3_mr0_dll_reset {
DDR3_MR0_DLL_RESET_NO = 0,
DDR3_MR0_DLL_RESET_YES = 1,
};
enum ddr3_mr0_burst_type {
DDR3_MR0_BURST_TYPE_SEQUENTIAL = 0,
DDR3_MR0_BURST_TYPE_INTERLEAVED = 1,
};
enum ddr3_mr0_burst_length {
DDR3_MR0_BURST_LENGTH_8 = 0,
DDR3_MR0_BURST_LENGTH_CHOP = 1,
DDR3_MR0_BURST_LENGTH_4 = 2,
};
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 interleaved_burst,
enum ddr3_mr0_burst_length burst_length);
enum ddr3_mr1_qoff {
DDR3_MR1_QOFF_ENABLE = 0,
DDR3_MR1_QOFF_DISABLE = 1,
};
enum ddr3_mr1_tqds {
DDR3_MR1_TQDS_DISABLE = 0,
DDR3_MR1_TQDS_ENABLE = 1,
};
enum ddr3_mr1_write_leveling {
DDR3_MR1_WRLVL_DISABLE = 0,
DDR3_MR1_WRLVL_ENABLE = 1,
};
enum ddr3_mr1_rtt_nom {
DDR3_MR1_RTT_NOM_OFF = 0,
DDR3_MR1_RTT_NOM_RZQ4 = 1,
DDR3_MR1_RTT_NOM_RZQ2 = 2,
DDR3_MR1_RTT_NOM_RZQ6 = 3,
DDR3_MR1_RTT_NOM_RZQ12 = 4,
DDR3_MR1_RTT_NOM_RZQ8 = 5,
};
enum ddr3_mr1_additive_latency {
DDR3_MR1_AL_DISABLE = 0,
DDR3_MR1_AL_CL_MINUS_1 = 1,
DDR3_MR1_AL_CL_MINUS_2 = 2,
};
enum ddr3_mr1_ods {
DDR3_MR1_ODS_RZQ6 = 0,
DDR3_MR1_ODS_RZQ7 = 1,
};
enum ddr3_mr1_dll {
DDR3_MR1_DLL_ENABLE = 0,
DDR3_MR1_DLL_DISABLE = 1,
};
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 output_drive_strenght,
enum ddr3_mr1_additive_latency additive_latency,
enum ddr3_mr1_dll dll_disable);
enum ddr3_mr2_rttwr {
DDR3_MR2_RTTWR_OFF = 0,
DDR3_MR2_RTTWR_RZQ4 = 1,
DDR3_MR2_RTTWR_RZQ2 = 2,
};
enum ddr3_mr2_srt_range {
DDR3_MR2_SRT_NORMAL = 0,
DDR3_MR2_SRT_EXTENDED = 1,
};
enum ddr3_mr2_asr {
DDR3_MR2_ASR_MANUAL = 0,
DDR3_MR2_ASR_AUTO = 1,
};
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 ddr3_get_mr3(char dataflow_from_mpr);
mrs_cmd_t ddr3_mrs_mirror_pins(mrs_cmd_t cmd);
#endif /* DEVICE_DRAM_DDR3L_H */
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