linux_dsm_epyc7002/drivers/mtd/spi-nor/intel-spi.c
Alexander Sverdlin 2b75ebeea6 mtd: spi-nor: intel-spi: Avoid crossing 4K address boundary on read/write
It was observed that reads crossing 4K address boundary are failing.

This limitation is mentioned in Intel documents:

Intel(R) 9 Series Chipset Family Platform Controller Hub (PCH) Datasheet:

"5.26.3 Flash Access
Program Register Access:
* Program Register Accesses are not allowed to cross a 4 KB boundary..."

Enhanced Serial Peripheral Interface (eSPI)
Interface Base Specification (for Client and Server Platforms):

"5.1.4 Address
For other memory transactions, the address may start or end at any byte
boundary. However, the address and payload length combination must not
cross the naturally aligned address boundary of the corresponding Maximum
Payload Size. It must not cross a 4 KB address boundary."

Avoid this by splitting an operation crossing the boundary into two
operations.

Fixes: 8afda8b26d ("spi-nor: Add support for Intel SPI serial flash controller")
Cc: stable@vger.kernel.org
Reported-by: Romain Porte <romain.porte@nokia.com>
Tested-by: Pascal Fabreges <pascal.fabreges@nokia.com>
Signed-off-by: Alexander Sverdlin <alexander.sverdlin@nokia.com>
Reviewed-by: Tudor Ambarus <tudor.ambarus@microchip.com>
Acked-by: Mika Westerberg <mika.westerberg@linux.intel.com>
Signed-off-by: Miquel Raynal <miquel.raynal@bootlin.com>
2019-04-01 14:36:23 +02:00

936 lines
23 KiB
C

/*
* Intel PCH/PCU SPI flash driver.
*
* Copyright (C) 2016, Intel Corporation
* Author: Mika Westerberg <mika.westerberg@linux.intel.com>
*
* 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.
*/
#include <linux/err.h>
#include <linux/io.h>
#include <linux/iopoll.h>
#include <linux/module.h>
#include <linux/sched.h>
#include <linux/sizes.h>
#include <linux/mtd/mtd.h>
#include <linux/mtd/partitions.h>
#include <linux/mtd/spi-nor.h>
#include <linux/platform_data/intel-spi.h>
#include "intel-spi.h"
/* Offsets are from @ispi->base */
#define BFPREG 0x00
#define HSFSTS_CTL 0x04
#define HSFSTS_CTL_FSMIE BIT(31)
#define HSFSTS_CTL_FDBC_SHIFT 24
#define HSFSTS_CTL_FDBC_MASK (0x3f << HSFSTS_CTL_FDBC_SHIFT)
#define HSFSTS_CTL_FCYCLE_SHIFT 17
#define HSFSTS_CTL_FCYCLE_MASK (0x0f << HSFSTS_CTL_FCYCLE_SHIFT)
/* HW sequencer opcodes */
#define HSFSTS_CTL_FCYCLE_READ (0x00 << HSFSTS_CTL_FCYCLE_SHIFT)
#define HSFSTS_CTL_FCYCLE_WRITE (0x02 << HSFSTS_CTL_FCYCLE_SHIFT)
#define HSFSTS_CTL_FCYCLE_ERASE (0x03 << HSFSTS_CTL_FCYCLE_SHIFT)
#define HSFSTS_CTL_FCYCLE_ERASE_64K (0x04 << HSFSTS_CTL_FCYCLE_SHIFT)
#define HSFSTS_CTL_FCYCLE_RDID (0x06 << HSFSTS_CTL_FCYCLE_SHIFT)
#define HSFSTS_CTL_FCYCLE_WRSR (0x07 << HSFSTS_CTL_FCYCLE_SHIFT)
#define HSFSTS_CTL_FCYCLE_RDSR (0x08 << HSFSTS_CTL_FCYCLE_SHIFT)
#define HSFSTS_CTL_FGO BIT(16)
#define HSFSTS_CTL_FLOCKDN BIT(15)
#define HSFSTS_CTL_FDV BIT(14)
#define HSFSTS_CTL_SCIP BIT(5)
#define HSFSTS_CTL_AEL BIT(2)
#define HSFSTS_CTL_FCERR BIT(1)
#define HSFSTS_CTL_FDONE BIT(0)
#define FADDR 0x08
#define DLOCK 0x0c
#define FDATA(n) (0x10 + ((n) * 4))
#define FRACC 0x50
#define FREG(n) (0x54 + ((n) * 4))
#define FREG_BASE_MASK 0x3fff
#define FREG_LIMIT_SHIFT 16
#define FREG_LIMIT_MASK (0x03fff << FREG_LIMIT_SHIFT)
/* Offset is from @ispi->pregs */
#define PR(n) ((n) * 4)
#define PR_WPE BIT(31)
#define PR_LIMIT_SHIFT 16
#define PR_LIMIT_MASK (0x3fff << PR_LIMIT_SHIFT)
#define PR_RPE BIT(15)
#define PR_BASE_MASK 0x3fff
/* Offsets are from @ispi->sregs */
#define SSFSTS_CTL 0x00
#define SSFSTS_CTL_FSMIE BIT(23)
#define SSFSTS_CTL_DS BIT(22)
#define SSFSTS_CTL_DBC_SHIFT 16
#define SSFSTS_CTL_SPOP BIT(11)
#define SSFSTS_CTL_ACS BIT(10)
#define SSFSTS_CTL_SCGO BIT(9)
#define SSFSTS_CTL_COP_SHIFT 12
#define SSFSTS_CTL_FRS BIT(7)
#define SSFSTS_CTL_DOFRS BIT(6)
#define SSFSTS_CTL_AEL BIT(4)
#define SSFSTS_CTL_FCERR BIT(3)
#define SSFSTS_CTL_FDONE BIT(2)
#define SSFSTS_CTL_SCIP BIT(0)
#define PREOP_OPTYPE 0x04
#define OPMENU0 0x08
#define OPMENU1 0x0c
#define OPTYPE_READ_NO_ADDR 0
#define OPTYPE_WRITE_NO_ADDR 1
#define OPTYPE_READ_WITH_ADDR 2
#define OPTYPE_WRITE_WITH_ADDR 3
/* CPU specifics */
#define BYT_PR 0x74
#define BYT_SSFSTS_CTL 0x90
#define BYT_BCR 0xfc
#define BYT_BCR_WPD BIT(0)
#define BYT_FREG_NUM 5
#define BYT_PR_NUM 5
#define LPT_PR 0x74
#define LPT_SSFSTS_CTL 0x90
#define LPT_FREG_NUM 5
#define LPT_PR_NUM 5
#define BXT_PR 0x84
#define BXT_SSFSTS_CTL 0xa0
#define BXT_FREG_NUM 12
#define BXT_PR_NUM 6
#define LVSCC 0xc4
#define UVSCC 0xc8
#define ERASE_OPCODE_SHIFT 8
#define ERASE_OPCODE_MASK (0xff << ERASE_OPCODE_SHIFT)
#define ERASE_64K_OPCODE_SHIFT 16
#define ERASE_64K_OPCODE_MASK (0xff << ERASE_OPCODE_SHIFT)
#define INTEL_SPI_TIMEOUT 5000 /* ms */
#define INTEL_SPI_FIFO_SZ 64
/**
* struct intel_spi - Driver private data
* @dev: Device pointer
* @info: Pointer to board specific info
* @nor: SPI NOR layer structure
* @base: Beginning of MMIO space
* @pregs: Start of protection registers
* @sregs: Start of software sequencer registers
* @nregions: Maximum number of regions
* @pr_num: Maximum number of protected range registers
* @writeable: Is the chip writeable
* @locked: Is SPI setting locked
* @swseq_reg: Use SW sequencer in register reads/writes
* @swseq_erase: Use SW sequencer in erase operation
* @erase_64k: 64k erase supported
* @atomic_preopcode: Holds preopcode when atomic sequence is requested
* @opcodes: Opcodes which are supported. This are programmed by BIOS
* before it locks down the controller.
*/
struct intel_spi {
struct device *dev;
const struct intel_spi_boardinfo *info;
struct spi_nor nor;
void __iomem *base;
void __iomem *pregs;
void __iomem *sregs;
size_t nregions;
size_t pr_num;
bool writeable;
bool locked;
bool swseq_reg;
bool swseq_erase;
bool erase_64k;
u8 atomic_preopcode;
u8 opcodes[8];
};
static bool writeable;
module_param(writeable, bool, 0);
MODULE_PARM_DESC(writeable, "Enable write access to SPI flash chip (default=0)");
static void intel_spi_dump_regs(struct intel_spi *ispi)
{
u32 value;
int i;
dev_dbg(ispi->dev, "BFPREG=0x%08x\n", readl(ispi->base + BFPREG));
value = readl(ispi->base + HSFSTS_CTL);
dev_dbg(ispi->dev, "HSFSTS_CTL=0x%08x\n", value);
if (value & HSFSTS_CTL_FLOCKDN)
dev_dbg(ispi->dev, "-> Locked\n");
dev_dbg(ispi->dev, "FADDR=0x%08x\n", readl(ispi->base + FADDR));
dev_dbg(ispi->dev, "DLOCK=0x%08x\n", readl(ispi->base + DLOCK));
for (i = 0; i < 16; i++)
dev_dbg(ispi->dev, "FDATA(%d)=0x%08x\n",
i, readl(ispi->base + FDATA(i)));
dev_dbg(ispi->dev, "FRACC=0x%08x\n", readl(ispi->base + FRACC));
for (i = 0; i < ispi->nregions; i++)
dev_dbg(ispi->dev, "FREG(%d)=0x%08x\n", i,
readl(ispi->base + FREG(i)));
for (i = 0; i < ispi->pr_num; i++)
dev_dbg(ispi->dev, "PR(%d)=0x%08x\n", i,
readl(ispi->pregs + PR(i)));
value = readl(ispi->sregs + SSFSTS_CTL);
dev_dbg(ispi->dev, "SSFSTS_CTL=0x%08x\n", value);
dev_dbg(ispi->dev, "PREOP_OPTYPE=0x%08x\n",
readl(ispi->sregs + PREOP_OPTYPE));
dev_dbg(ispi->dev, "OPMENU0=0x%08x\n", readl(ispi->sregs + OPMENU0));
dev_dbg(ispi->dev, "OPMENU1=0x%08x\n", readl(ispi->sregs + OPMENU1));
if (ispi->info->type == INTEL_SPI_BYT)
dev_dbg(ispi->dev, "BCR=0x%08x\n", readl(ispi->base + BYT_BCR));
dev_dbg(ispi->dev, "LVSCC=0x%08x\n", readl(ispi->base + LVSCC));
dev_dbg(ispi->dev, "UVSCC=0x%08x\n", readl(ispi->base + UVSCC));
dev_dbg(ispi->dev, "Protected regions:\n");
for (i = 0; i < ispi->pr_num; i++) {
u32 base, limit;
value = readl(ispi->pregs + PR(i));
if (!(value & (PR_WPE | PR_RPE)))
continue;
limit = (value & PR_LIMIT_MASK) >> PR_LIMIT_SHIFT;
base = value & PR_BASE_MASK;
dev_dbg(ispi->dev, " %02d base: 0x%08x limit: 0x%08x [%c%c]\n",
i, base << 12, (limit << 12) | 0xfff,
value & PR_WPE ? 'W' : '.',
value & PR_RPE ? 'R' : '.');
}
dev_dbg(ispi->dev, "Flash regions:\n");
for (i = 0; i < ispi->nregions; i++) {
u32 region, base, limit;
region = readl(ispi->base + FREG(i));
base = region & FREG_BASE_MASK;
limit = (region & FREG_LIMIT_MASK) >> FREG_LIMIT_SHIFT;
if (base >= limit || (i > 0 && limit == 0))
dev_dbg(ispi->dev, " %02d disabled\n", i);
else
dev_dbg(ispi->dev, " %02d base: 0x%08x limit: 0x%08x\n",
i, base << 12, (limit << 12) | 0xfff);
}
dev_dbg(ispi->dev, "Using %cW sequencer for register access\n",
ispi->swseq_reg ? 'S' : 'H');
dev_dbg(ispi->dev, "Using %cW sequencer for erase operation\n",
ispi->swseq_erase ? 'S' : 'H');
}
/* Reads max INTEL_SPI_FIFO_SZ bytes from the device fifo */
static int intel_spi_read_block(struct intel_spi *ispi, void *buf, size_t size)
{
size_t bytes;
int i = 0;
if (size > INTEL_SPI_FIFO_SZ)
return -EINVAL;
while (size > 0) {
bytes = min_t(size_t, size, 4);
memcpy_fromio(buf, ispi->base + FDATA(i), bytes);
size -= bytes;
buf += bytes;
i++;
}
return 0;
}
/* Writes max INTEL_SPI_FIFO_SZ bytes to the device fifo */
static int intel_spi_write_block(struct intel_spi *ispi, const void *buf,
size_t size)
{
size_t bytes;
int i = 0;
if (size > INTEL_SPI_FIFO_SZ)
return -EINVAL;
while (size > 0) {
bytes = min_t(size_t, size, 4);
memcpy_toio(ispi->base + FDATA(i), buf, bytes);
size -= bytes;
buf += bytes;
i++;
}
return 0;
}
static int intel_spi_wait_hw_busy(struct intel_spi *ispi)
{
u32 val;
return readl_poll_timeout(ispi->base + HSFSTS_CTL, val,
!(val & HSFSTS_CTL_SCIP), 40,
INTEL_SPI_TIMEOUT * 1000);
}
static int intel_spi_wait_sw_busy(struct intel_spi *ispi)
{
u32 val;
return readl_poll_timeout(ispi->sregs + SSFSTS_CTL, val,
!(val & SSFSTS_CTL_SCIP), 40,
INTEL_SPI_TIMEOUT * 1000);
}
static int intel_spi_init(struct intel_spi *ispi)
{
u32 opmenu0, opmenu1, lvscc, uvscc, val;
int i;
switch (ispi->info->type) {
case INTEL_SPI_BYT:
ispi->sregs = ispi->base + BYT_SSFSTS_CTL;
ispi->pregs = ispi->base + BYT_PR;
ispi->nregions = BYT_FREG_NUM;
ispi->pr_num = BYT_PR_NUM;
ispi->swseq_reg = true;
if (writeable) {
/* Disable write protection */
val = readl(ispi->base + BYT_BCR);
if (!(val & BYT_BCR_WPD)) {
val |= BYT_BCR_WPD;
writel(val, ispi->base + BYT_BCR);
val = readl(ispi->base + BYT_BCR);
}
ispi->writeable = !!(val & BYT_BCR_WPD);
}
break;
case INTEL_SPI_LPT:
ispi->sregs = ispi->base + LPT_SSFSTS_CTL;
ispi->pregs = ispi->base + LPT_PR;
ispi->nregions = LPT_FREG_NUM;
ispi->pr_num = LPT_PR_NUM;
ispi->swseq_reg = true;
break;
case INTEL_SPI_BXT:
ispi->sregs = ispi->base + BXT_SSFSTS_CTL;
ispi->pregs = ispi->base + BXT_PR;
ispi->nregions = BXT_FREG_NUM;
ispi->pr_num = BXT_PR_NUM;
ispi->erase_64k = true;
break;
default:
return -EINVAL;
}
/* Disable #SMI generation from HW sequencer */
val = readl(ispi->base + HSFSTS_CTL);
val &= ~HSFSTS_CTL_FSMIE;
writel(val, ispi->base + HSFSTS_CTL);
/*
* Determine whether erase operation should use HW or SW sequencer.
*
* The HW sequencer has a predefined list of opcodes, with only the
* erase opcode being programmable in LVSCC and UVSCC registers.
* If these registers don't contain a valid erase opcode, erase
* cannot be done using HW sequencer.
*/
lvscc = readl(ispi->base + LVSCC);
uvscc = readl(ispi->base + UVSCC);
if (!(lvscc & ERASE_OPCODE_MASK) || !(uvscc & ERASE_OPCODE_MASK))
ispi->swseq_erase = true;
/* SPI controller on Intel BXT supports 64K erase opcode */
if (ispi->info->type == INTEL_SPI_BXT && !ispi->swseq_erase)
if (!(lvscc & ERASE_64K_OPCODE_MASK) ||
!(uvscc & ERASE_64K_OPCODE_MASK))
ispi->erase_64k = false;
/*
* Some controllers can only do basic operations using hardware
* sequencer. All other operations are supposed to be carried out
* using software sequencer.
*/
if (ispi->swseq_reg) {
/* Disable #SMI generation from SW sequencer */
val = readl(ispi->sregs + SSFSTS_CTL);
val &= ~SSFSTS_CTL_FSMIE;
writel(val, ispi->sregs + SSFSTS_CTL);
}
/* Check controller's lock status */
val = readl(ispi->base + HSFSTS_CTL);
ispi->locked = !!(val & HSFSTS_CTL_FLOCKDN);
if (ispi->locked) {
/*
* BIOS programs allowed opcodes and then locks down the
* register. So read back what opcodes it decided to support.
* That's the set we are going to support as well.
*/
opmenu0 = readl(ispi->sregs + OPMENU0);
opmenu1 = readl(ispi->sregs + OPMENU1);
if (opmenu0 && opmenu1) {
for (i = 0; i < ARRAY_SIZE(ispi->opcodes) / 2; i++) {
ispi->opcodes[i] = opmenu0 >> i * 8;
ispi->opcodes[i + 4] = opmenu1 >> i * 8;
}
}
}
intel_spi_dump_regs(ispi);
return 0;
}
static int intel_spi_opcode_index(struct intel_spi *ispi, u8 opcode, int optype)
{
int i;
int preop;
if (ispi->locked) {
for (i = 0; i < ARRAY_SIZE(ispi->opcodes); i++)
if (ispi->opcodes[i] == opcode)
return i;
return -EINVAL;
}
/* The lock is off, so just use index 0 */
writel(opcode, ispi->sregs + OPMENU0);
preop = readw(ispi->sregs + PREOP_OPTYPE);
writel(optype << 16 | preop, ispi->sregs + PREOP_OPTYPE);
return 0;
}
static int intel_spi_hw_cycle(struct intel_spi *ispi, u8 opcode, int len)
{
u32 val, status;
int ret;
val = readl(ispi->base + HSFSTS_CTL);
val &= ~(HSFSTS_CTL_FCYCLE_MASK | HSFSTS_CTL_FDBC_MASK);
switch (opcode) {
case SPINOR_OP_RDID:
val |= HSFSTS_CTL_FCYCLE_RDID;
break;
case SPINOR_OP_WRSR:
val |= HSFSTS_CTL_FCYCLE_WRSR;
break;
case SPINOR_OP_RDSR:
val |= HSFSTS_CTL_FCYCLE_RDSR;
break;
default:
return -EINVAL;
}
if (len > INTEL_SPI_FIFO_SZ)
return -EINVAL;
val |= (len - 1) << HSFSTS_CTL_FDBC_SHIFT;
val |= HSFSTS_CTL_FCERR | HSFSTS_CTL_FDONE;
val |= HSFSTS_CTL_FGO;
writel(val, ispi->base + HSFSTS_CTL);
ret = intel_spi_wait_hw_busy(ispi);
if (ret)
return ret;
status = readl(ispi->base + HSFSTS_CTL);
if (status & HSFSTS_CTL_FCERR)
return -EIO;
else if (status & HSFSTS_CTL_AEL)
return -EACCES;
return 0;
}
static int intel_spi_sw_cycle(struct intel_spi *ispi, u8 opcode, int len,
int optype)
{
u32 val = 0, status;
u8 atomic_preopcode;
int ret;
ret = intel_spi_opcode_index(ispi, opcode, optype);
if (ret < 0)
return ret;
if (len > INTEL_SPI_FIFO_SZ)
return -EINVAL;
/*
* Always clear it after each SW sequencer operation regardless
* of whether it is successful or not.
*/
atomic_preopcode = ispi->atomic_preopcode;
ispi->atomic_preopcode = 0;
/* Only mark 'Data Cycle' bit when there is data to be transferred */
if (len > 0)
val = ((len - 1) << SSFSTS_CTL_DBC_SHIFT) | SSFSTS_CTL_DS;
val |= ret << SSFSTS_CTL_COP_SHIFT;
val |= SSFSTS_CTL_FCERR | SSFSTS_CTL_FDONE;
val |= SSFSTS_CTL_SCGO;
if (atomic_preopcode) {
u16 preop;
switch (optype) {
case OPTYPE_WRITE_NO_ADDR:
case OPTYPE_WRITE_WITH_ADDR:
/* Pick matching preopcode for the atomic sequence */
preop = readw(ispi->sregs + PREOP_OPTYPE);
if ((preop & 0xff) == atomic_preopcode)
; /* Do nothing */
else if ((preop >> 8) == atomic_preopcode)
val |= SSFSTS_CTL_SPOP;
else
return -EINVAL;
/* Enable atomic sequence */
val |= SSFSTS_CTL_ACS;
break;
default:
return -EINVAL;
}
}
writel(val, ispi->sregs + SSFSTS_CTL);
ret = intel_spi_wait_sw_busy(ispi);
if (ret)
return ret;
status = readl(ispi->sregs + SSFSTS_CTL);
if (status & SSFSTS_CTL_FCERR)
return -EIO;
else if (status & SSFSTS_CTL_AEL)
return -EACCES;
return 0;
}
static int intel_spi_read_reg(struct spi_nor *nor, u8 opcode, u8 *buf, int len)
{
struct intel_spi *ispi = nor->priv;
int ret;
/* Address of the first chip */
writel(0, ispi->base + FADDR);
if (ispi->swseq_reg)
ret = intel_spi_sw_cycle(ispi, opcode, len,
OPTYPE_READ_NO_ADDR);
else
ret = intel_spi_hw_cycle(ispi, opcode, len);
if (ret)
return ret;
return intel_spi_read_block(ispi, buf, len);
}
static int intel_spi_write_reg(struct spi_nor *nor, u8 opcode, u8 *buf, int len)
{
struct intel_spi *ispi = nor->priv;
int ret;
/*
* This is handled with atomic operation and preop code in Intel
* controller so we only verify that it is available. If the
* controller is not locked, program the opcode to the PREOP
* register for later use.
*
* When hardware sequencer is used there is no need to program
* any opcodes (it handles them automatically as part of a command).
*/
if (opcode == SPINOR_OP_WREN) {
u16 preop;
if (!ispi->swseq_reg)
return 0;
preop = readw(ispi->sregs + PREOP_OPTYPE);
if ((preop & 0xff) != opcode && (preop >> 8) != opcode) {
if (ispi->locked)
return -EINVAL;
writel(opcode, ispi->sregs + PREOP_OPTYPE);
}
/*
* This enables atomic sequence on next SW sycle. Will
* be cleared after next operation.
*/
ispi->atomic_preopcode = opcode;
return 0;
}
writel(0, ispi->base + FADDR);
/* Write the value beforehand */
ret = intel_spi_write_block(ispi, buf, len);
if (ret)
return ret;
if (ispi->swseq_reg)
return intel_spi_sw_cycle(ispi, opcode, len,
OPTYPE_WRITE_NO_ADDR);
return intel_spi_hw_cycle(ispi, opcode, len);
}
static ssize_t intel_spi_read(struct spi_nor *nor, loff_t from, size_t len,
u_char *read_buf)
{
struct intel_spi *ispi = nor->priv;
size_t block_size, retlen = 0;
u32 val, status;
ssize_t ret;
/*
* Atomic sequence is not expected with HW sequencer reads. Make
* sure it is cleared regardless.
*/
if (WARN_ON_ONCE(ispi->atomic_preopcode))
ispi->atomic_preopcode = 0;
switch (nor->read_opcode) {
case SPINOR_OP_READ:
case SPINOR_OP_READ_FAST:
break;
default:
return -EINVAL;
}
while (len > 0) {
block_size = min_t(size_t, len, INTEL_SPI_FIFO_SZ);
/* Read cannot cross 4K boundary */
block_size = min_t(loff_t, from + block_size,
round_up(from + 1, SZ_4K)) - from;
writel(from, ispi->base + FADDR);
val = readl(ispi->base + HSFSTS_CTL);
val &= ~(HSFSTS_CTL_FDBC_MASK | HSFSTS_CTL_FCYCLE_MASK);
val |= HSFSTS_CTL_AEL | HSFSTS_CTL_FCERR | HSFSTS_CTL_FDONE;
val |= (block_size - 1) << HSFSTS_CTL_FDBC_SHIFT;
val |= HSFSTS_CTL_FCYCLE_READ;
val |= HSFSTS_CTL_FGO;
writel(val, ispi->base + HSFSTS_CTL);
ret = intel_spi_wait_hw_busy(ispi);
if (ret)
return ret;
status = readl(ispi->base + HSFSTS_CTL);
if (status & HSFSTS_CTL_FCERR)
ret = -EIO;
else if (status & HSFSTS_CTL_AEL)
ret = -EACCES;
if (ret < 0) {
dev_err(ispi->dev, "read error: %llx: %#x\n", from,
status);
return ret;
}
ret = intel_spi_read_block(ispi, read_buf, block_size);
if (ret)
return ret;
len -= block_size;
from += block_size;
retlen += block_size;
read_buf += block_size;
}
return retlen;
}
static ssize_t intel_spi_write(struct spi_nor *nor, loff_t to, size_t len,
const u_char *write_buf)
{
struct intel_spi *ispi = nor->priv;
size_t block_size, retlen = 0;
u32 val, status;
ssize_t ret;
/* Not needed with HW sequencer write, make sure it is cleared */
ispi->atomic_preopcode = 0;
while (len > 0) {
block_size = min_t(size_t, len, INTEL_SPI_FIFO_SZ);
/* Write cannot cross 4K boundary */
block_size = min_t(loff_t, to + block_size,
round_up(to + 1, SZ_4K)) - to;
writel(to, ispi->base + FADDR);
val = readl(ispi->base + HSFSTS_CTL);
val &= ~(HSFSTS_CTL_FDBC_MASK | HSFSTS_CTL_FCYCLE_MASK);
val |= HSFSTS_CTL_AEL | HSFSTS_CTL_FCERR | HSFSTS_CTL_FDONE;
val |= (block_size - 1) << HSFSTS_CTL_FDBC_SHIFT;
val |= HSFSTS_CTL_FCYCLE_WRITE;
ret = intel_spi_write_block(ispi, write_buf, block_size);
if (ret) {
dev_err(ispi->dev, "failed to write block\n");
return ret;
}
/* Start the write now */
val |= HSFSTS_CTL_FGO;
writel(val, ispi->base + HSFSTS_CTL);
ret = intel_spi_wait_hw_busy(ispi);
if (ret) {
dev_err(ispi->dev, "timeout\n");
return ret;
}
status = readl(ispi->base + HSFSTS_CTL);
if (status & HSFSTS_CTL_FCERR)
ret = -EIO;
else if (status & HSFSTS_CTL_AEL)
ret = -EACCES;
if (ret < 0) {
dev_err(ispi->dev, "write error: %llx: %#x\n", to,
status);
return ret;
}
len -= block_size;
to += block_size;
retlen += block_size;
write_buf += block_size;
}
return retlen;
}
static int intel_spi_erase(struct spi_nor *nor, loff_t offs)
{
size_t erase_size, len = nor->mtd.erasesize;
struct intel_spi *ispi = nor->priv;
u32 val, status, cmd;
int ret;
/* If the hardware can do 64k erase use that when possible */
if (len >= SZ_64K && ispi->erase_64k) {
cmd = HSFSTS_CTL_FCYCLE_ERASE_64K;
erase_size = SZ_64K;
} else {
cmd = HSFSTS_CTL_FCYCLE_ERASE;
erase_size = SZ_4K;
}
if (ispi->swseq_erase) {
while (len > 0) {
writel(offs, ispi->base + FADDR);
ret = intel_spi_sw_cycle(ispi, nor->erase_opcode,
0, OPTYPE_WRITE_WITH_ADDR);
if (ret)
return ret;
offs += erase_size;
len -= erase_size;
}
return 0;
}
/* Not needed with HW sequencer erase, make sure it is cleared */
ispi->atomic_preopcode = 0;
while (len > 0) {
writel(offs, ispi->base + FADDR);
val = readl(ispi->base + HSFSTS_CTL);
val &= ~(HSFSTS_CTL_FDBC_MASK | HSFSTS_CTL_FCYCLE_MASK);
val |= HSFSTS_CTL_AEL | HSFSTS_CTL_FCERR | HSFSTS_CTL_FDONE;
val |= cmd;
val |= HSFSTS_CTL_FGO;
writel(val, ispi->base + HSFSTS_CTL);
ret = intel_spi_wait_hw_busy(ispi);
if (ret)
return ret;
status = readl(ispi->base + HSFSTS_CTL);
if (status & HSFSTS_CTL_FCERR)
return -EIO;
else if (status & HSFSTS_CTL_AEL)
return -EACCES;
offs += erase_size;
len -= erase_size;
}
return 0;
}
static bool intel_spi_is_protected(const struct intel_spi *ispi,
unsigned int base, unsigned int limit)
{
int i;
for (i = 0; i < ispi->pr_num; i++) {
u32 pr_base, pr_limit, pr_value;
pr_value = readl(ispi->pregs + PR(i));
if (!(pr_value & (PR_WPE | PR_RPE)))
continue;
pr_limit = (pr_value & PR_LIMIT_MASK) >> PR_LIMIT_SHIFT;
pr_base = pr_value & PR_BASE_MASK;
if (pr_base >= base && pr_limit <= limit)
return true;
}
return false;
}
/*
* There will be a single partition holding all enabled flash regions. We
* call this "BIOS".
*/
static void intel_spi_fill_partition(struct intel_spi *ispi,
struct mtd_partition *part)
{
u64 end;
int i;
memset(part, 0, sizeof(*part));
/* Start from the mandatory descriptor region */
part->size = 4096;
part->name = "BIOS";
/*
* Now try to find where this partition ends based on the flash
* region registers.
*/
for (i = 1; i < ispi->nregions; i++) {
u32 region, base, limit;
region = readl(ispi->base + FREG(i));
base = region & FREG_BASE_MASK;
limit = (region & FREG_LIMIT_MASK) >> FREG_LIMIT_SHIFT;
if (base >= limit || limit == 0)
continue;
/*
* If any of the regions have protection bits set, make the
* whole partition read-only to be on the safe side.
*/
if (intel_spi_is_protected(ispi, base, limit))
ispi->writeable = false;
end = (limit << 12) + 4096;
if (end > part->size)
part->size = end;
}
}
struct intel_spi *intel_spi_probe(struct device *dev,
struct resource *mem, const struct intel_spi_boardinfo *info)
{
const struct spi_nor_hwcaps hwcaps = {
.mask = SNOR_HWCAPS_READ |
SNOR_HWCAPS_READ_FAST |
SNOR_HWCAPS_PP,
};
struct mtd_partition part;
struct intel_spi *ispi;
int ret;
if (!info || !mem)
return ERR_PTR(-EINVAL);
ispi = devm_kzalloc(dev, sizeof(*ispi), GFP_KERNEL);
if (!ispi)
return ERR_PTR(-ENOMEM);
ispi->base = devm_ioremap_resource(dev, mem);
if (IS_ERR(ispi->base))
return ERR_CAST(ispi->base);
ispi->dev = dev;
ispi->info = info;
ispi->writeable = info->writeable;
ret = intel_spi_init(ispi);
if (ret)
return ERR_PTR(ret);
ispi->nor.dev = ispi->dev;
ispi->nor.priv = ispi;
ispi->nor.read_reg = intel_spi_read_reg;
ispi->nor.write_reg = intel_spi_write_reg;
ispi->nor.read = intel_spi_read;
ispi->nor.write = intel_spi_write;
ispi->nor.erase = intel_spi_erase;
ret = spi_nor_scan(&ispi->nor, NULL, &hwcaps);
if (ret) {
dev_info(dev, "failed to locate the chip\n");
return ERR_PTR(ret);
}
intel_spi_fill_partition(ispi, &part);
/* Prevent writes if not explicitly enabled */
if (!ispi->writeable || !writeable)
ispi->nor.mtd.flags &= ~MTD_WRITEABLE;
ret = mtd_device_register(&ispi->nor.mtd, &part, 1);
if (ret)
return ERR_PTR(ret);
return ispi;
}
EXPORT_SYMBOL_GPL(intel_spi_probe);
int intel_spi_remove(struct intel_spi *ispi)
{
return mtd_device_unregister(&ispi->nor.mtd);
}
EXPORT_SYMBOL_GPL(intel_spi_remove);
MODULE_DESCRIPTION("Intel PCH/PCU SPI flash core driver");
MODULE_AUTHOR("Mika Westerberg <mika.westerberg@linux.intel.com>");
MODULE_LICENSE("GPL v2");