diff options
Diffstat (limited to 'src/device')
-rw-r--r-- | src/device/dram/Makefile.inc | 2 | ||||
-rw-r--r-- | src/device/dram/rcd.c | 218 |
2 files changed, 219 insertions, 1 deletions
diff --git a/src/device/dram/Makefile.inc b/src/device/dram/Makefile.inc index eb2e629991..64f1dba801 100644 --- a/src/device/dram/Makefile.inc +++ b/src/device/dram/Makefile.inc @@ -9,7 +9,7 @@ ramstage-$(CONFIG_USE_DDR5) += ddr5.c romstage-$(CONFIG_USE_LPDDR4) += lpddr4.c ramstage-$(CONFIG_USE_LPDDR4) += lpddr4.c -romstage-$(CONFIG_USE_DDR4) += ddr4.c +romstage-$(CONFIG_USE_DDR4) += ddr4.c rcd.c ramstage-$(CONFIG_USE_DDR4) += ddr4.c romstage-$(CONFIG_USE_DDR3) += ddr3.c diff --git a/src/device/dram/rcd.c b/src/device/dram/rcd.c new file mode 100644 index 0000000000..dc183352bd --- /dev/null +++ b/src/device/dram/rcd.c @@ -0,0 +1,218 @@ +/* SPDX-License-Identifier: GPL-2.0-only */ + +#include <console/console.h> +#include <device/dram/rcd.h> +#include <endian.h> +#include <lib.h> + +/** + * Registering Clock Driver (RCD) is responsible for driving address and control + * nets on RDIMM and LRDIMM applications. Its operation is configurable by a set + * of Register Control Words (RCWs). There are two ways of accessing RCWs: + * in-band on the memory channel as an MRS commands ("MR7") or through I2C. + * + * From JESD82-31: "For changes to the control word setting, (...) the + * controller needs to wait tMRD after _the last control word access_, before + * further access _to the DRAM_ can take place". MRS is passed to rank 0 of the + * DRAM, but MR7 is reserved so it is ignored by DRAM. tMRD (8nCK) applies here, + * unless longer delay is needed for RCWs which control the clock timing (see + * JESD82-31 for list of such). This makes sense from DRAMs point of view, + * however we are talking to the Registering Clock Driver (RCD), not DRAM. From + * parts marked in the sentence above one may assume that only one delay at the + * end is necessary and RCWs can be written back to back; however, in the same + * document in table 141 tMRD is defined as "Number of clock cycles between two + * control word accesses, MRS accesses, or any DRAM commands". + * + * I2C access to RCWs is required to support byte (8b), word (16b) and double + * word (32b) write size. Bigger blocks are not required. Reads must always be + * 32b, 32b-aligned blocks, even when reading just one RCW. RCD ignores the two + * lowest bits so unaligned accesses would return shifted values. RCWs are + * tightly packed in I2C space, so it is not possible to write just one 4b RCW + * without writing its neighbor. This is especially important for F0RC06, + * Command Space Control Word, as it is able to reset the state of RCD. For this + * reason, the mentioned register has NOP command (all 1's). JESD82-31 does not + * specify timeouts required for such multi-RCWs writes, or any other writes. + * These are not MRS accesses, so it would be strange to apply those timeouts. + * Perhaps only the registers that actually change the clock settings require + * time to stabilize. On the other hand, I2C is relatively slow, so it is + * possible that the write itself is long enough. + * + * RCD I2C address is 0xBx (or 0x58 + DIMM number, depending on convention), it + * is located on the same bus as SPD. It uses a bus command encoding, see + * section 3.3 in JESD82-31 for description of reading and writing register + * values. + * + * This file includes only functions for access through I2C - it is generic, + * while MRS commands are passed to memory controller registers in an + * implementation specific way. + */ + +#define RCD_CMD_BEGIN 0x80 +#define RCD_CMD_END 0x40 +#define RCD_CMD_PEC 0x10 +#define RCD_CMD_RD_DWORD 0x00 +#define RCD_CMD_WR_BYTE 0x04 +#define RCD_CMD_WR_WORD 0x08 +#define RCD_CMD_WR_DWORD 0x0C +#define RCD_CMD_BUS_BYTE 0x00 +#define RCD_CMD_BUS_BLOCK 0x02 + +/* Shorthand for block transfers */ +#define RCD_CMD_BLOCK (RCD_CMD_BEGIN | RCD_CMD_END | RCD_CMD_BUS_BLOCK) + +/* Excluding size of data */ +#define RCD_CMD_BYTES 4 + +/* Use byte fields to get rid of endianness issues. */ +struct rcd_i2c_cmd { + uint8_t cmd; + uint8_t bytes; /* From next byte up to PEC (excluding) */ + uint8_t reserved; + uint8_t devfun; + uint8_t reg_h; + uint8_t reg_l; + union { /* Not used for reads, can use 1, 2 or 4 for writes */ + uint8_t bdata; + uint32_t ddata; + }; + /* Optional PEC */ +} __packed; + +#define RCD_STS_SUCCESS 0x01 +#define RCD_STS_INTERNAL_TARGET_ABORT 0x10 + +/* Always 4 bytes data + status (for block commands) */ +#define RCD_RSP_BYTES 5 + +struct rcd_i2c_rsp { + uint8_t bytes; /* From next byte up to PEC (excluding) */ + uint8_t status; + union { + uint8_t bdata; + uint32_t ddata; + }; + /* Optional PEC */ +} __packed; + +/* Reads a register storing its value in the host's byte order. Returns non-zero on success. */ +static int rcd_readd(unsigned int bus, uint8_t slave, uint8_t reg, uint32_t *data) +{ + struct i2c_msg seg[2]; + struct rcd_i2c_cmd cmd = { + .cmd = RCD_CMD_BLOCK | RCD_CMD_RD_DWORD, + .bytes = RCD_CMD_BYTES, + .reg_l = reg + }; + struct rcd_i2c_rsp rsp = { 0xaa, 0x55 }; + + seg[0].flags = 0; + seg[0].slave = slave; + seg[0].buf = (uint8_t *)&cmd; + seg[0].len = cmd.bytes + 2; /* + .cmd and .bytes fields */ + + i2c_transfer(bus, seg, 1); + + seg[0].len = 1; /* Send just the command again */ + seg[1].flags = I2C_M_RD; + seg[1].slave = slave; + seg[1].buf = (uint8_t *)&rsp; + seg[1].len = RCD_RSP_BYTES + 1; /* + .bytes field */ + + i2c_transfer(bus, seg, ARRAY_SIZE(seg)); + + /* Data is sent MSB to LSB, i.e. higher registers to lower. */ + *data = be32toh(rsp.ddata); + + return rsp.status == RCD_STS_SUCCESS; +} + +static int rcd_writed(unsigned int bus, uint8_t slave, uint8_t reg, uint32_t data) +{ + struct i2c_msg seg; + struct rcd_i2c_cmd cmd = { + .cmd = RCD_CMD_BLOCK | RCD_CMD_WR_DWORD, + .bytes = RCD_CMD_BYTES + sizeof(data), + .reg_l = reg, + /* Data is sent MSB to LSB, i.e. higher registers to lower. */ + .ddata = htobe32(data) + }; + + seg.flags = 0; + seg.slave = slave; + seg.buf = (uint8_t *)&cmd; + seg.len = cmd.bytes + 2; /* + .cmd and .bytes fields */ + + return i2c_transfer(bus, &seg, 1); +} + +static int rcd_writeb(unsigned int bus, uint8_t slave, uint8_t reg, uint8_t data) +{ + struct i2c_msg seg; + struct rcd_i2c_cmd cmd = { + .cmd = RCD_CMD_BLOCK | RCD_CMD_WR_BYTE, + .bytes = RCD_CMD_BYTES + sizeof(data), + .reg_l = reg, + .bdata = data + }; + + seg.flags = 0; + seg.slave = slave; + seg.buf = (uint8_t *)&cmd; + seg.len = cmd.bytes + 2; /* + .cmd and .bytes fields */ + + return i2c_transfer(bus, &seg, 1); +} + +int rcd_write_reg(unsigned int bus, uint8_t slave, enum rcw_idx reg, + uint8_t data) +{ + if (reg < F0RC00_01 || reg > F0RCFx) { + printk(BIOS_ERR, "Trying to write to illegal RCW %#2.2x\n", + reg); + return 0; + } + + return rcd_writeb(bus, slave, reg, data); +} + +int rcd_write_32b(unsigned int bus, uint8_t slave, enum rcw_idx reg, + uint32_t data) +{ + if (reg < F0RC00_01 || reg > F0RCFx) { + printk(BIOS_ERR, "Trying to write to illegal RCW %#2.2x\n", + reg); + return 0; + } + + if (reg & 3) { + /* + * RCD would silently mask out the lowest bits, assume that this + * is not what caller wanted. + */ + printk(BIOS_ERR, "Unaligned RCW %#2.2x, aborting\n", reg); + return 0; + } + + return rcd_writed(bus, slave, reg, data); +} + +void dump_rcd(unsigned int bus, u8 addr) +{ + /* Can only read in 32b chunks */ + uint8_t buf[RCW_ALL_ALIGNED]; + int i; + + for (i = 0; i < RCW_ALL_ALIGNED; i += sizeof(uint32_t)) { + uint32_t data; + if (!rcd_readd(bus, addr, i, &data)) { + printk(BIOS_ERR, "Failed to read RCD (%d-%02x) at offset %#2.2x\n", + bus, addr, i); + return; + } + /* We want to dump memory the way it's stored, so make sure it's in LE. */ + *(uint32_t *)&buf[i] = htole32(data); + } + + printk(BIOS_DEBUG, "RCD dump for I2C address %#2.2x:\n", addr); + hexdump(buf, sizeof(buf)); +} |