qemu/hw/block/pflash_cfi01.c

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/*
* CFI parallel flash with Intel command set emulation
*
* Copyright (c) 2006 Thorsten Zitterell
* Copyright (c) 2005 Jocelyn Mayer
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
/*
* For now, this code can emulate flashes of 1, 2 or 4 bytes width.
* Supported commands/modes are:
* - flash read
* - flash write
* - flash ID read
* - sector erase
* - CFI queries
*
* It does not support timings
* It does not support flash interleaving
* It does not implement software data protection as found in many real chips
* It does not implement erase suspend/resume commands
* It does not implement multiple sectors erase
*
* It does not implement much more ...
*/
#include "qemu/osdep.h"
#include "hw/hw.h"
#include "hw/block/flash.h"
#include "sysemu/block-backend.h"
2016-03-14 11:01:28 +03:00
#include "qapi/error.h"
#include "qemu/timer.h"
#include "qemu/bitops.h"
#include "exec/address-spaces.h"
#include "qemu/host-utils.h"
#include "qemu/log.h"
#include "hw/sysbus.h"
#include "sysemu/sysemu.h"
#define PFLASH_BUG(fmt, ...) \
do { \
fprintf(stderr, "PFLASH: Possible BUG - " fmt, ## __VA_ARGS__); \
exit(1); \
} while(0)
/* #define PFLASH_DEBUG */
#ifdef PFLASH_DEBUG
#define DPRINTF(fmt, ...) \
do { \
fprintf(stderr, "PFLASH: " fmt , ## __VA_ARGS__); \
} while (0)
#else
#define DPRINTF(fmt, ...) do { } while (0)
#endif
#define CFI_PFLASH01(obj) OBJECT_CHECK(pflash_t, (obj), TYPE_CFI_PFLASH01)
#define PFLASH_BE 0
#define PFLASH_SECURE 1
struct pflash_t {
/*< private >*/
SysBusDevice parent_obj;
/*< public >*/
BlockBackend *blk;
uint32_t nb_blocs;
uint64_t sector_len;
uint8_t bank_width;
uint8_t device_width; /* If 0, device width not specified. */
uint8_t max_device_width; /* max device width in bytes */
uint32_t features;
uint8_t wcycle; /* if 0, the flash is read normally */
int ro;
uint8_t cmd;
uint8_t status;
uint16_t ident0;
uint16_t ident1;
uint16_t ident2;
uint16_t ident3;
uint8_t cfi_len;
uint8_t cfi_table[0x52];
uint64_t counter;
unsigned int writeblock_size;
QEMUTimer *timer;
MemoryRegion mem;
char *name;
void *storage;
VMChangeStateEntry *vmstate;
pflash_cfi01: fix per-device sector length in CFI table For configurations of the pflash_cfi01 device which set it up with a device-width not equal to the width (ie where we are emulating multiple narrow flash devices wired up in parallel), we were giving incorrect values in the CFI data table: (1) the sector length entry should specify the sector length for a single device, not the length for the overall collection of devices (2) the number of blocks per device must not be divided by the number of devices because the resulting device size would not match the overall size (3) this then means that the overall write block size must be modified depending on the number of devices because the entry is per device and when the guest writes into the flash it calculates the write size by using the CFI entry (write size per device) multiplied by the number of chips. (It would alternatively be possible to modify the write block size in the CFI table (currently hardcoded at 2048) and leave the overall write block size alone.) This commit corrects these bugs, and adds a hw-compat property to retain the old behaviour on 2.8 and earlier versions. (The only board we have which uses this sort of flash config and has machine versioning is the "virt" board -- the PC uses a single flash device and so behaviour is unaffected whether using old-multiple-chip-handling or not.) Here is a configuration example from the vexpress board: VEXPRESS_FLASH_SIZE = 64M VEXPRESS_FLASH_SECT_SIZE 256K num-blocks = VEXPRESS_FLASH_SIZE / VEXPRESS_FLASH_SECT_SIZE = 256 sector-length = 256K width = 4 device-width = 2 The code will fill the CFI entry with the following entries: num-blocks = 256 sector-length = 128K writeblock_size = 2048 This results in two chips, each with 256 * 128K = 32M device size and a write block size of 2048. A sector erase will be sent to both chips, thus 256K must be erased. When the guest sends a block write command, it will write 4096 bytes data at once (2048 per device). Signed-off-by: David Engraf <david.engraf@sysgo.com> Reviewed-by: Peter Maydell <peter.maydell@linaro.org> [PMM: cleaned up and expanded commit message] Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2017-01-27 18:20:22 +03:00
bool old_multiple_chip_handling;
};
pflash_cfi01: write flash contents to bdrv on incoming migration A drive that backs a pflash device is special: - it is very small, - its entire contents are kept in a RAMBlock at all times, covering the guest-phys address range that provides the guest's view of the emulated flash chip. The pflash device model keeps the drive (the host-side file) and the guest-visible flash contents in sync. When migrating the guest, the guest-visible flash contents (the RAMBlock) is migrated by default, but on the target host, the drive (the host-side file) remains in full sync with the RAMBlock only if: - the source and target hosts share the storage underlying the pflash drive, - or the migration requests full or incremental block migration too, which then covers all drives. Due to the special nature of pflash drives, the following scenario makes sense as well: - no full nor incremental block migration, covering all drives, alongside the base migration (justified eg. by shared storage for "normal" (big) drives), - non-shared storage for pflash drives. In this case, currently only those portions of the flash drive are updated on the target disk that the guest reprograms while running on the target host. In order to restore accord, dump the entire flash contents to the bdrv in a post_load() callback. - The read-only check follows the other call-sites of pflash_update(); - both "pfl->ro" and pflash_update() reflect / consider the case when "pfl->bs" is NULL; - the total size of the flash device is calculated as in pflash_cfi01_realize(). When using shared storage, or requesting full or incremental block migration along with the normal migration, the patch should incur a harmless rewrite from the target side. It is assumed that, on the target host, RAM is loaded ahead of the call to pflash_post_load(). Suggested-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Laszlo Ersek <lersek@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2014-08-23 14:19:07 +04:00
static int pflash_post_load(void *opaque, int version_id);
static const VMStateDescription vmstate_pflash = {
.name = "pflash_cfi01",
.version_id = 1,
.minimum_version_id = 1,
pflash_cfi01: write flash contents to bdrv on incoming migration A drive that backs a pflash device is special: - it is very small, - its entire contents are kept in a RAMBlock at all times, covering the guest-phys address range that provides the guest's view of the emulated flash chip. The pflash device model keeps the drive (the host-side file) and the guest-visible flash contents in sync. When migrating the guest, the guest-visible flash contents (the RAMBlock) is migrated by default, but on the target host, the drive (the host-side file) remains in full sync with the RAMBlock only if: - the source and target hosts share the storage underlying the pflash drive, - or the migration requests full or incremental block migration too, which then covers all drives. Due to the special nature of pflash drives, the following scenario makes sense as well: - no full nor incremental block migration, covering all drives, alongside the base migration (justified eg. by shared storage for "normal" (big) drives), - non-shared storage for pflash drives. In this case, currently only those portions of the flash drive are updated on the target disk that the guest reprograms while running on the target host. In order to restore accord, dump the entire flash contents to the bdrv in a post_load() callback. - The read-only check follows the other call-sites of pflash_update(); - both "pfl->ro" and pflash_update() reflect / consider the case when "pfl->bs" is NULL; - the total size of the flash device is calculated as in pflash_cfi01_realize(). When using shared storage, or requesting full or incremental block migration along with the normal migration, the patch should incur a harmless rewrite from the target side. It is assumed that, on the target host, RAM is loaded ahead of the call to pflash_post_load(). Suggested-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Laszlo Ersek <lersek@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2014-08-23 14:19:07 +04:00
.post_load = pflash_post_load,
.fields = (VMStateField[]) {
VMSTATE_UINT8(wcycle, pflash_t),
VMSTATE_UINT8(cmd, pflash_t),
VMSTATE_UINT8(status, pflash_t),
VMSTATE_UINT64(counter, pflash_t),
VMSTATE_END_OF_LIST()
}
};
static void pflash_timer (void *opaque)
{
pflash_t *pfl = opaque;
DPRINTF("%s: command %02x done\n", __func__, pfl->cmd);
/* Reset flash */
pfl->status ^= 0x80;
memory_region_rom_device_set_romd(&pfl->mem, true);
pfl->wcycle = 0;
pfl->cmd = 0;
}
/* Perform a CFI query based on the bank width of the flash.
* If this code is called we know we have a device_width set for
* this flash.
*/
static uint32_t pflash_cfi_query(pflash_t *pfl, hwaddr offset)
{
int i;
uint32_t resp = 0;
hwaddr boff;
/* Adjust incoming offset to match expected device-width
* addressing. CFI query addresses are always specified in terms of
* the maximum supported width of the device. This means that x8
* devices and x8/x16 devices in x8 mode behave differently. For
* devices that are not used at their max width, we will be
* provided with addresses that use higher address bits than
* expected (based on the max width), so we will shift them lower
* so that they will match the addresses used when
* device_width==max_device_width.
*/
boff = offset >> (ctz32(pfl->bank_width) +
ctz32(pfl->max_device_width) - ctz32(pfl->device_width));
if (boff > pfl->cfi_len) {
return 0;
}
/* Now we will construct the CFI response generated by a single
* device, then replicate that for all devices that make up the
* bus. For wide parts used in x8 mode, CFI query responses
* are different than native byte-wide parts.
*/
resp = pfl->cfi_table[boff];
if (pfl->device_width != pfl->max_device_width) {
/* The only case currently supported is x8 mode for a
* wider part.
*/
if (pfl->device_width != 1 || pfl->bank_width > 4) {
DPRINTF("%s: Unsupported device configuration: "
"device_width=%d, max_device_width=%d\n",
__func__, pfl->device_width,
pfl->max_device_width);
return 0;
}
/* CFI query data is repeated, rather than zero padded for
* wide devices used in x8 mode.
*/
for (i = 1; i < pfl->max_device_width; i++) {
resp = deposit32(resp, 8 * i, 8, pfl->cfi_table[boff]);
}
}
/* Replicate responses for each device in bank. */
if (pfl->device_width < pfl->bank_width) {
for (i = pfl->device_width;
i < pfl->bank_width; i += pfl->device_width) {
resp = deposit32(resp, 8 * i, 8 * pfl->device_width, resp);
}
}
return resp;
}
/* Perform a device id query based on the bank width of the flash. */
static uint32_t pflash_devid_query(pflash_t *pfl, hwaddr offset)
{
int i;
uint32_t resp;
hwaddr boff;
/* Adjust incoming offset to match expected device-width
* addressing. Device ID read addresses are always specified in
* terms of the maximum supported width of the device. This means
* that x8 devices and x8/x16 devices in x8 mode behave
* differently. For devices that are not used at their max width,
* we will be provided with addresses that use higher address bits
* than expected (based on the max width), so we will shift them
* lower so that they will match the addresses used when
* device_width==max_device_width.
*/
boff = offset >> (ctz32(pfl->bank_width) +
ctz32(pfl->max_device_width) - ctz32(pfl->device_width));
/* Mask off upper bits which may be used in to query block
* or sector lock status at other addresses.
* Offsets 2/3 are block lock status, is not emulated.
*/
switch (boff & 0xFF) {
case 0:
resp = pfl->ident0;
DPRINTF("%s: Manufacturer Code %04x\n", __func__, resp);
break;
case 1:
resp = pfl->ident1;
DPRINTF("%s: Device ID Code %04x\n", __func__, resp);
break;
default:
DPRINTF("%s: Read Device Information offset=%x\n", __func__,
(unsigned)offset);
return 0;
break;
}
/* Replicate responses for each device in bank. */
if (pfl->device_width < pfl->bank_width) {
for (i = pfl->device_width;
i < pfl->bank_width; i += pfl->device_width) {
resp = deposit32(resp, 8 * i, 8 * pfl->device_width, resp);
}
}
return resp;
}
static uint32_t pflash_data_read(pflash_t *pfl, hwaddr offset,
int width, int be)
{
uint8_t *p;
uint32_t ret;
p = pfl->storage;
switch (width) {
case 1:
ret = p[offset];
DPRINTF("%s: data offset " TARGET_FMT_plx " %02x\n",
__func__, offset, ret);
break;
case 2:
if (be) {
ret = p[offset] << 8;
ret |= p[offset + 1];
} else {
ret = p[offset];
ret |= p[offset + 1] << 8;
}
DPRINTF("%s: data offset " TARGET_FMT_plx " %04x\n",
__func__, offset, ret);
break;
case 4:
if (be) {
ret = p[offset] << 24;
ret |= p[offset + 1] << 16;
ret |= p[offset + 2] << 8;
ret |= p[offset + 3];
} else {
ret = p[offset];
ret |= p[offset + 1] << 8;
ret |= p[offset + 2] << 16;
ret |= p[offset + 3] << 24;
}
DPRINTF("%s: data offset " TARGET_FMT_plx " %08x\n",
__func__, offset, ret);
break;
default:
DPRINTF("BUG in %s\n", __func__);
abort();
}
return ret;
}
static uint32_t pflash_read (pflash_t *pfl, hwaddr offset,
int width, int be)
{
hwaddr boff;
uint32_t ret;
ret = -1;
#if 0
DPRINTF("%s: reading offset " TARGET_FMT_plx " under cmd %02x width %d\n",
__func__, offset, pfl->cmd, width);
#endif
switch (pfl->cmd) {
default:
/* This should never happen : reset state & treat it as a read */
DPRINTF("%s: unknown command state: %x\n", __func__, pfl->cmd);
pfl->wcycle = 0;
pfl->cmd = 0;
/* fall through to read code */
case 0x00:
/* Flash area read */
ret = pflash_data_read(pfl, offset, width, be);
break;
case 0x10: /* Single byte program */
case 0x20: /* Block erase */
case 0x28: /* Block erase */
case 0x40: /* single byte program */
case 0x50: /* Clear status register */
case 0x60: /* Block /un)lock */
case 0x70: /* Status Register */
case 0xe8: /* Write block */
/* Status register read. Return status from each device in
* bank.
*/
ret = pfl->status;
if (pfl->device_width && width > pfl->device_width) {
int shift = pfl->device_width * 8;
while (shift + pfl->device_width * 8 <= width * 8) {
ret |= pfl->status << shift;
shift += pfl->device_width * 8;
}
} else if (!pfl->device_width && width > 2) {
/* Handle 32 bit flash cases where device width is not
* set. (Existing behavior before device width added.)
*/
ret |= pfl->status << 16;
}
DPRINTF("%s: status %x\n", __func__, ret);
break;
case 0x90:
if (!pfl->device_width) {
/* Preserve old behavior if device width not specified */
boff = offset & 0xFF;
if (pfl->bank_width == 2) {
boff = boff >> 1;
} else if (pfl->bank_width == 4) {
boff = boff >> 2;
}
switch (boff) {
case 0:
ret = pfl->ident0 << 8 | pfl->ident1;
DPRINTF("%s: Manufacturer Code %04x\n", __func__, ret);
break;
case 1:
ret = pfl->ident2 << 8 | pfl->ident3;
DPRINTF("%s: Device ID Code %04x\n", __func__, ret);
break;
default:
DPRINTF("%s: Read Device Information boff=%x\n", __func__,
(unsigned)boff);
ret = 0;
break;
}
} else {
/* If we have a read larger than the bank_width, combine multiple
* manufacturer/device ID queries into a single response.
*/
int i;
for (i = 0; i < width; i += pfl->bank_width) {
ret = deposit32(ret, i * 8, pfl->bank_width * 8,
pflash_devid_query(pfl,
offset + i * pfl->bank_width));
}
}
break;
case 0x98: /* Query mode */
if (!pfl->device_width) {
/* Preserve old behavior if device width not specified */
boff = offset & 0xFF;
if (pfl->bank_width == 2) {
boff = boff >> 1;
} else if (pfl->bank_width == 4) {
boff = boff >> 2;
}
if (boff > pfl->cfi_len) {
ret = 0;
} else {
ret = pfl->cfi_table[boff];
}
} else {
/* If we have a read larger than the bank_width, combine multiple
* CFI queries into a single response.
*/
int i;
for (i = 0; i < width; i += pfl->bank_width) {
ret = deposit32(ret, i * 8, pfl->bank_width * 8,
pflash_cfi_query(pfl,
offset + i * pfl->bank_width));
}
}
break;
}
return ret;
}
/* update flash content on disk */
static void pflash_update(pflash_t *pfl, int offset,
int size)
{
int offset_end;
if (pfl->blk) {
offset_end = offset + size;
/* widen to sector boundaries */
offset = QEMU_ALIGN_DOWN(offset, BDRV_SECTOR_SIZE);
offset_end = QEMU_ALIGN_UP(offset_end, BDRV_SECTOR_SIZE);
blk_pwrite(pfl->blk, offset, pfl->storage + offset,
offset_end - offset, 0);
}
}
static inline void pflash_data_write(pflash_t *pfl, hwaddr offset,
uint32_t value, int width, int be)
{
uint8_t *p = pfl->storage;
DPRINTF("%s: block write offset " TARGET_FMT_plx
" value %x counter %016" PRIx64 "\n",
__func__, offset, value, pfl->counter);
switch (width) {
case 1:
p[offset] = value;
break;
case 2:
if (be) {
p[offset] = value >> 8;
p[offset + 1] = value;
} else {
p[offset] = value;
p[offset + 1] = value >> 8;
}
break;
case 4:
if (be) {
p[offset] = value >> 24;
p[offset + 1] = value >> 16;
p[offset + 2] = value >> 8;
p[offset + 3] = value;
} else {
p[offset] = value;
p[offset + 1] = value >> 8;
p[offset + 2] = value >> 16;
p[offset + 3] = value >> 24;
}
break;
}
}
static void pflash_write(pflash_t *pfl, hwaddr offset,
uint32_t value, int width, int be)
{
uint8_t *p;
uint8_t cmd;
cmd = value;
DPRINTF("%s: writing offset " TARGET_FMT_plx " value %08x width %d wcycle 0x%x\n",
__func__, offset, value, width, pfl->wcycle);
if (!pfl->wcycle) {
/* Set the device in I/O access mode */
memory_region_rom_device_set_romd(&pfl->mem, false);
}
switch (pfl->wcycle) {
case 0:
/* read mode */
switch (cmd) {
case 0x00: /* ??? */
goto reset_flash;
case 0x10: /* Single Byte Program */
case 0x40: /* Single Byte Program */
DPRINTF("%s: Single Byte Program\n", __func__);
break;
case 0x20: /* Block erase */
p = pfl->storage;
offset &= ~(pfl->sector_len - 1);
DPRINTF("%s: block erase at " TARGET_FMT_plx " bytes %x\n",
__func__, offset, (unsigned)pfl->sector_len);
if (!pfl->ro) {
memset(p + offset, 0xff, pfl->sector_len);
pflash_update(pfl, offset, pfl->sector_len);
} else {
pfl->status |= 0x20; /* Block erase error */
}
pfl->status |= 0x80; /* Ready! */
break;
case 0x50: /* Clear status bits */
DPRINTF("%s: Clear status bits\n", __func__);
pfl->status = 0x0;
goto reset_flash;
case 0x60: /* Block (un)lock */
DPRINTF("%s: Block unlock\n", __func__);
break;
case 0x70: /* Status Register */
DPRINTF("%s: Read status register\n", __func__);
pfl->cmd = cmd;
return;
case 0x90: /* Read Device ID */
DPRINTF("%s: Read Device information\n", __func__);
pfl->cmd = cmd;
return;
case 0x98: /* CFI query */
DPRINTF("%s: CFI query\n", __func__);
break;
case 0xe8: /* Write to buffer */
DPRINTF("%s: Write to buffer\n", __func__);
pfl->status |= 0x80; /* Ready! */
break;
case 0xf0: /* Probe for AMD flash */
DPRINTF("%s: Probe for AMD flash\n", __func__);
goto reset_flash;
case 0xff: /* Read array mode */
DPRINTF("%s: Read array mode\n", __func__);
goto reset_flash;
default:
goto error_flash;
}
pfl->wcycle++;
pfl->cmd = cmd;
break;
case 1:
switch (pfl->cmd) {
case 0x10: /* Single Byte Program */
case 0x40: /* Single Byte Program */
DPRINTF("%s: Single Byte Program\n", __func__);
if (!pfl->ro) {
pflash_data_write(pfl, offset, value, width, be);
pflash_update(pfl, offset, width);
} else {
pfl->status |= 0x10; /* Programming error */
}
pfl->status |= 0x80; /* Ready! */
pfl->wcycle = 0;
break;
case 0x20: /* Block erase */
case 0x28:
if (cmd == 0xd0) { /* confirm */
pfl->wcycle = 0;
pfl->status |= 0x80;
} else if (cmd == 0xff) { /* read array mode */
goto reset_flash;
} else
goto error_flash;
break;
case 0xe8:
/* Mask writeblock size based on device width, or bank width if
* device width not specified.
*/
if (pfl->device_width) {
value = extract32(value, 0, pfl->device_width * 8);
} else {
value = extract32(value, 0, pfl->bank_width * 8);
}
DPRINTF("%s: block write of %x bytes\n", __func__, value);
pfl->counter = value;
pfl->wcycle++;
break;
case 0x60:
if (cmd == 0xd0) {
pfl->wcycle = 0;
pfl->status |= 0x80;
} else if (cmd == 0x01) {
pfl->wcycle = 0;
pfl->status |= 0x80;
} else if (cmd == 0xff) {
goto reset_flash;
} else {
DPRINTF("%s: Unknown (un)locking command\n", __func__);
goto reset_flash;
}
break;
case 0x98:
if (cmd == 0xff) {
goto reset_flash;
} else {
DPRINTF("%s: leaving query mode\n", __func__);
}
break;
default:
goto error_flash;
}
break;
case 2:
switch (pfl->cmd) {
case 0xe8: /* Block write */
if (!pfl->ro) {
pflash_data_write(pfl, offset, value, width, be);
} else {
pfl->status |= 0x10; /* Programming error */
}
pfl->status |= 0x80;
if (!pfl->counter) {
hwaddr mask = pfl->writeblock_size - 1;
mask = ~mask;
DPRINTF("%s: block write finished\n", __func__);
pfl->wcycle++;
if (!pfl->ro) {
/* Flush the entire write buffer onto backing storage. */
pflash_update(pfl, offset & mask, pfl->writeblock_size);
} else {
pfl->status |= 0x10; /* Programming error */
}
}
pfl->counter--;
break;
default:
goto error_flash;
}
break;
case 3: /* Confirm mode */
switch (pfl->cmd) {
case 0xe8: /* Block write */
if (cmd == 0xd0) {
pfl->wcycle = 0;
pfl->status |= 0x80;
} else {
DPRINTF("%s: unknown command for \"write block\"\n", __func__);
PFLASH_BUG("Write block confirm");
goto reset_flash;
}
break;
default:
goto error_flash;
}
break;
default:
/* Should never happen */
DPRINTF("%s: invalid write state\n", __func__);
goto reset_flash;
}
return;
error_flash:
qemu_log_mask(LOG_UNIMP, "%s: Unimplemented flash cmd sequence "
"(offset " TARGET_FMT_plx ", wcycle 0x%x cmd 0x%x value 0x%x)"
"\n", __func__, offset, pfl->wcycle, pfl->cmd, value);
reset_flash:
memory_region_rom_device_set_romd(&pfl->mem, true);
pfl->wcycle = 0;
pfl->cmd = 0;
}
static MemTxResult pflash_mem_read_with_attrs(void *opaque, hwaddr addr, uint64_t *value,
unsigned len, MemTxAttrs attrs)
{
pflash_t *pfl = opaque;
bool be = !!(pfl->features & (1 << PFLASH_BE));
if ((pfl->features & (1 << PFLASH_SECURE)) && !attrs.secure) {
*value = pflash_data_read(opaque, addr, len, be);
} else {
*value = pflash_read(opaque, addr, len, be);
}
return MEMTX_OK;
}
static MemTxResult pflash_mem_write_with_attrs(void *opaque, hwaddr addr, uint64_t value,
unsigned len, MemTxAttrs attrs)
{
pflash_t *pfl = opaque;
bool be = !!(pfl->features & (1 << PFLASH_BE));
if ((pfl->features & (1 << PFLASH_SECURE)) && !attrs.secure) {
return MEMTX_ERROR;
} else {
pflash_write(opaque, addr, value, len, be);
return MEMTX_OK;
}
}
static const MemoryRegionOps pflash_cfi01_ops = {
.read_with_attrs = pflash_mem_read_with_attrs,
.write_with_attrs = pflash_mem_write_with_attrs,
.endianness = DEVICE_NATIVE_ENDIAN,
};
static void pflash_cfi01_realize(DeviceState *dev, Error **errp)
{
pflash_t *pfl = CFI_PFLASH01(dev);
uint64_t total_len;
int ret;
pflash_cfi01: fix per-device sector length in CFI table For configurations of the pflash_cfi01 device which set it up with a device-width not equal to the width (ie where we are emulating multiple narrow flash devices wired up in parallel), we were giving incorrect values in the CFI data table: (1) the sector length entry should specify the sector length for a single device, not the length for the overall collection of devices (2) the number of blocks per device must not be divided by the number of devices because the resulting device size would not match the overall size (3) this then means that the overall write block size must be modified depending on the number of devices because the entry is per device and when the guest writes into the flash it calculates the write size by using the CFI entry (write size per device) multiplied by the number of chips. (It would alternatively be possible to modify the write block size in the CFI table (currently hardcoded at 2048) and leave the overall write block size alone.) This commit corrects these bugs, and adds a hw-compat property to retain the old behaviour on 2.8 and earlier versions. (The only board we have which uses this sort of flash config and has machine versioning is the "virt" board -- the PC uses a single flash device and so behaviour is unaffected whether using old-multiple-chip-handling or not.) Here is a configuration example from the vexpress board: VEXPRESS_FLASH_SIZE = 64M VEXPRESS_FLASH_SECT_SIZE 256K num-blocks = VEXPRESS_FLASH_SIZE / VEXPRESS_FLASH_SECT_SIZE = 256 sector-length = 256K width = 4 device-width = 2 The code will fill the CFI entry with the following entries: num-blocks = 256 sector-length = 128K writeblock_size = 2048 This results in two chips, each with 256 * 128K = 32M device size and a write block size of 2048. A sector erase will be sent to both chips, thus 256K must be erased. When the guest sends a block write command, it will write 4096 bytes data at once (2048 per device). Signed-off-by: David Engraf <david.engraf@sysgo.com> Reviewed-by: Peter Maydell <peter.maydell@linaro.org> [PMM: cleaned up and expanded commit message] Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2017-01-27 18:20:22 +03:00
uint64_t blocks_per_device, sector_len_per_device, device_len;
int num_devices;
Error *local_err = NULL;
if (pfl->sector_len == 0) {
error_setg(errp, "attribute \"sector-length\" not specified or zero.");
return;
}
if (pfl->nb_blocs == 0) {
error_setg(errp, "attribute \"num-blocks\" not specified or zero.");
return;
}
if (pfl->name == NULL) {
error_setg(errp, "attribute \"name\" not specified.");
return;
}
total_len = pfl->sector_len * pfl->nb_blocs;
/* These are only used to expose the parameters of each device
* in the cfi_table[].
*/
num_devices = pfl->device_width ? (pfl->bank_width / pfl->device_width) : 1;
pflash_cfi01: fix per-device sector length in CFI table For configurations of the pflash_cfi01 device which set it up with a device-width not equal to the width (ie where we are emulating multiple narrow flash devices wired up in parallel), we were giving incorrect values in the CFI data table: (1) the sector length entry should specify the sector length for a single device, not the length for the overall collection of devices (2) the number of blocks per device must not be divided by the number of devices because the resulting device size would not match the overall size (3) this then means that the overall write block size must be modified depending on the number of devices because the entry is per device and when the guest writes into the flash it calculates the write size by using the CFI entry (write size per device) multiplied by the number of chips. (It would alternatively be possible to modify the write block size in the CFI table (currently hardcoded at 2048) and leave the overall write block size alone.) This commit corrects these bugs, and adds a hw-compat property to retain the old behaviour on 2.8 and earlier versions. (The only board we have which uses this sort of flash config and has machine versioning is the "virt" board -- the PC uses a single flash device and so behaviour is unaffected whether using old-multiple-chip-handling or not.) Here is a configuration example from the vexpress board: VEXPRESS_FLASH_SIZE = 64M VEXPRESS_FLASH_SECT_SIZE 256K num-blocks = VEXPRESS_FLASH_SIZE / VEXPRESS_FLASH_SECT_SIZE = 256 sector-length = 256K width = 4 device-width = 2 The code will fill the CFI entry with the following entries: num-blocks = 256 sector-length = 128K writeblock_size = 2048 This results in two chips, each with 256 * 128K = 32M device size and a write block size of 2048. A sector erase will be sent to both chips, thus 256K must be erased. When the guest sends a block write command, it will write 4096 bytes data at once (2048 per device). Signed-off-by: David Engraf <david.engraf@sysgo.com> Reviewed-by: Peter Maydell <peter.maydell@linaro.org> [PMM: cleaned up and expanded commit message] Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2017-01-27 18:20:22 +03:00
if (pfl->old_multiple_chip_handling) {
blocks_per_device = pfl->nb_blocs / num_devices;
sector_len_per_device = pfl->sector_len;
} else {
blocks_per_device = pfl->nb_blocs;
sector_len_per_device = pfl->sector_len / num_devices;
}
device_len = sector_len_per_device * blocks_per_device;
/* XXX: to be fixed */
#if 0
if (total_len != (8 * 1024 * 1024) && total_len != (16 * 1024 * 1024) &&
total_len != (32 * 1024 * 1024) && total_len != (64 * 1024 * 1024))
return NULL;
#endif
memory_region_init_rom_device(
&pfl->mem, OBJECT(dev),
&pflash_cfi01_ops,
pfl,
pfl->name, total_len, &local_err);
if (local_err) {
error_propagate(errp, local_err);
return;
}
vmstate_register_ram(&pfl->mem, DEVICE(pfl));
pfl->storage = memory_region_get_ram_ptr(&pfl->mem);
sysbus_init_mmio(SYS_BUS_DEVICE(dev), &pfl->mem);
if (pfl->blk) {
/* read the initial flash content */
ret = blk_pread(pfl->blk, 0, pfl->storage, total_len);
if (ret < 0) {
vmstate_unregister_ram(&pfl->mem, DEVICE(pfl));
error_setg(errp, "failed to read the initial flash content");
return;
}
}
if (pfl->blk) {
pfl->ro = blk_is_read_only(pfl->blk);
} else {
pfl->ro = 0;
}
/* Default to devices being used at their maximum device width. This was
* assumed before the device_width support was added.
*/
if (!pfl->max_device_width) {
pfl->max_device_width = pfl->device_width;
}
pfl->timer = timer_new_ns(QEMU_CLOCK_VIRTUAL, pflash_timer, pfl);
pfl->wcycle = 0;
pfl->cmd = 0;
pfl->status = 0;
/* Hardcoded CFI table */
pfl->cfi_len = 0x52;
/* Standard "QRY" string */
pfl->cfi_table[0x10] = 'Q';
pfl->cfi_table[0x11] = 'R';
pfl->cfi_table[0x12] = 'Y';
/* Command set (Intel) */
pfl->cfi_table[0x13] = 0x01;
pfl->cfi_table[0x14] = 0x00;
/* Primary extended table address (none) */
pfl->cfi_table[0x15] = 0x31;
pfl->cfi_table[0x16] = 0x00;
/* Alternate command set (none) */
pfl->cfi_table[0x17] = 0x00;
pfl->cfi_table[0x18] = 0x00;
/* Alternate extended table (none) */
pfl->cfi_table[0x19] = 0x00;
pfl->cfi_table[0x1A] = 0x00;
/* Vcc min */
pfl->cfi_table[0x1B] = 0x45;
/* Vcc max */
pfl->cfi_table[0x1C] = 0x55;
/* Vpp min (no Vpp pin) */
pfl->cfi_table[0x1D] = 0x00;
/* Vpp max (no Vpp pin) */
pfl->cfi_table[0x1E] = 0x00;
/* Reserved */
pfl->cfi_table[0x1F] = 0x07;
/* Timeout for min size buffer write */
pfl->cfi_table[0x20] = 0x07;
/* Typical timeout for block erase */
pfl->cfi_table[0x21] = 0x0a;
/* Typical timeout for full chip erase (4096 ms) */
pfl->cfi_table[0x22] = 0x00;
/* Reserved */
pfl->cfi_table[0x23] = 0x04;
/* Max timeout for buffer write */
pfl->cfi_table[0x24] = 0x04;
/* Max timeout for block erase */
pfl->cfi_table[0x25] = 0x04;
/* Max timeout for chip erase */
pfl->cfi_table[0x26] = 0x00;
/* Device size */
pfl->cfi_table[0x27] = ctz32(device_len); /* + 1; */
/* Flash device interface (8 & 16 bits) */
pfl->cfi_table[0x28] = 0x02;
pfl->cfi_table[0x29] = 0x00;
/* Max number of bytes in multi-bytes write */
if (pfl->bank_width == 1) {
pfl->cfi_table[0x2A] = 0x08;
} else {
pfl->cfi_table[0x2A] = 0x0B;
}
pfl->writeblock_size = 1 << pfl->cfi_table[0x2A];
pflash_cfi01: fix per-device sector length in CFI table For configurations of the pflash_cfi01 device which set it up with a device-width not equal to the width (ie where we are emulating multiple narrow flash devices wired up in parallel), we were giving incorrect values in the CFI data table: (1) the sector length entry should specify the sector length for a single device, not the length for the overall collection of devices (2) the number of blocks per device must not be divided by the number of devices because the resulting device size would not match the overall size (3) this then means that the overall write block size must be modified depending on the number of devices because the entry is per device and when the guest writes into the flash it calculates the write size by using the CFI entry (write size per device) multiplied by the number of chips. (It would alternatively be possible to modify the write block size in the CFI table (currently hardcoded at 2048) and leave the overall write block size alone.) This commit corrects these bugs, and adds a hw-compat property to retain the old behaviour on 2.8 and earlier versions. (The only board we have which uses this sort of flash config and has machine versioning is the "virt" board -- the PC uses a single flash device and so behaviour is unaffected whether using old-multiple-chip-handling or not.) Here is a configuration example from the vexpress board: VEXPRESS_FLASH_SIZE = 64M VEXPRESS_FLASH_SECT_SIZE 256K num-blocks = VEXPRESS_FLASH_SIZE / VEXPRESS_FLASH_SECT_SIZE = 256 sector-length = 256K width = 4 device-width = 2 The code will fill the CFI entry with the following entries: num-blocks = 256 sector-length = 128K writeblock_size = 2048 This results in two chips, each with 256 * 128K = 32M device size and a write block size of 2048. A sector erase will be sent to both chips, thus 256K must be erased. When the guest sends a block write command, it will write 4096 bytes data at once (2048 per device). Signed-off-by: David Engraf <david.engraf@sysgo.com> Reviewed-by: Peter Maydell <peter.maydell@linaro.org> [PMM: cleaned up and expanded commit message] Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2017-01-27 18:20:22 +03:00
if (!pfl->old_multiple_chip_handling && num_devices > 1) {
pfl->writeblock_size *= num_devices;
}
pfl->cfi_table[0x2B] = 0x00;
/* Number of erase block regions (uniform) */
pfl->cfi_table[0x2C] = 0x01;
/* Erase block region 1 */
pfl->cfi_table[0x2D] = blocks_per_device - 1;
pfl->cfi_table[0x2E] = (blocks_per_device - 1) >> 8;
pflash_cfi01: fix per-device sector length in CFI table For configurations of the pflash_cfi01 device which set it up with a device-width not equal to the width (ie where we are emulating multiple narrow flash devices wired up in parallel), we were giving incorrect values in the CFI data table: (1) the sector length entry should specify the sector length for a single device, not the length for the overall collection of devices (2) the number of blocks per device must not be divided by the number of devices because the resulting device size would not match the overall size (3) this then means that the overall write block size must be modified depending on the number of devices because the entry is per device and when the guest writes into the flash it calculates the write size by using the CFI entry (write size per device) multiplied by the number of chips. (It would alternatively be possible to modify the write block size in the CFI table (currently hardcoded at 2048) and leave the overall write block size alone.) This commit corrects these bugs, and adds a hw-compat property to retain the old behaviour on 2.8 and earlier versions. (The only board we have which uses this sort of flash config and has machine versioning is the "virt" board -- the PC uses a single flash device and so behaviour is unaffected whether using old-multiple-chip-handling or not.) Here is a configuration example from the vexpress board: VEXPRESS_FLASH_SIZE = 64M VEXPRESS_FLASH_SECT_SIZE 256K num-blocks = VEXPRESS_FLASH_SIZE / VEXPRESS_FLASH_SECT_SIZE = 256 sector-length = 256K width = 4 device-width = 2 The code will fill the CFI entry with the following entries: num-blocks = 256 sector-length = 128K writeblock_size = 2048 This results in two chips, each with 256 * 128K = 32M device size and a write block size of 2048. A sector erase will be sent to both chips, thus 256K must be erased. When the guest sends a block write command, it will write 4096 bytes data at once (2048 per device). Signed-off-by: David Engraf <david.engraf@sysgo.com> Reviewed-by: Peter Maydell <peter.maydell@linaro.org> [PMM: cleaned up and expanded commit message] Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2017-01-27 18:20:22 +03:00
pfl->cfi_table[0x2F] = sector_len_per_device >> 8;
pfl->cfi_table[0x30] = sector_len_per_device >> 16;
/* Extended */
pfl->cfi_table[0x31] = 'P';
pfl->cfi_table[0x32] = 'R';
pfl->cfi_table[0x33] = 'I';
pfl->cfi_table[0x34] = '1';
pfl->cfi_table[0x35] = '0';
pfl->cfi_table[0x36] = 0x00;
pfl->cfi_table[0x37] = 0x00;
pfl->cfi_table[0x38] = 0x00;
pfl->cfi_table[0x39] = 0x00;
pfl->cfi_table[0x3a] = 0x00;
pfl->cfi_table[0x3b] = 0x00;
pfl->cfi_table[0x3c] = 0x00;
pfl->cfi_table[0x3f] = 0x01; /* Number of protection fields */
}
static Property pflash_cfi01_properties[] = {
DEFINE_PROP_DRIVE("drive", struct pflash_t, blk),
/* num-blocks is the number of blocks actually visible to the guest,
* ie the total size of the device divided by the sector length.
* If we're emulating flash devices wired in parallel the actual
* number of blocks per indvidual device will differ.
*/
DEFINE_PROP_UINT32("num-blocks", struct pflash_t, nb_blocs, 0),
DEFINE_PROP_UINT64("sector-length", struct pflash_t, sector_len, 0),
/* width here is the overall width of this QEMU device in bytes.
* The QEMU device may be emulating a number of flash devices
* wired up in parallel; the width of each individual flash
* device should be specified via device-width. If the individual
* devices have a maximum width which is greater than the width
* they are being used for, this maximum width should be set via
* max-device-width (which otherwise defaults to device-width).
* So for instance a 32-bit wide QEMU flash device made from four
* 16-bit flash devices used in 8-bit wide mode would be configured
* with width = 4, device-width = 1, max-device-width = 2.
*
* If device-width is not specified we default to backwards
* compatible behaviour which is a bad emulation of two
* 16 bit devices making up a 32 bit wide QEMU device. This
* is deprecated for new uses of this device.
*/
DEFINE_PROP_UINT8("width", struct pflash_t, bank_width, 0),
DEFINE_PROP_UINT8("device-width", struct pflash_t, device_width, 0),
DEFINE_PROP_UINT8("max-device-width", struct pflash_t, max_device_width, 0),
DEFINE_PROP_BIT("big-endian", struct pflash_t, features, PFLASH_BE, 0),
DEFINE_PROP_BIT("secure", struct pflash_t, features, PFLASH_SECURE, 0),
DEFINE_PROP_UINT16("id0", struct pflash_t, ident0, 0),
DEFINE_PROP_UINT16("id1", struct pflash_t, ident1, 0),
DEFINE_PROP_UINT16("id2", struct pflash_t, ident2, 0),
DEFINE_PROP_UINT16("id3", struct pflash_t, ident3, 0),
DEFINE_PROP_STRING("name", struct pflash_t, name),
pflash_cfi01: fix per-device sector length in CFI table For configurations of the pflash_cfi01 device which set it up with a device-width not equal to the width (ie where we are emulating multiple narrow flash devices wired up in parallel), we were giving incorrect values in the CFI data table: (1) the sector length entry should specify the sector length for a single device, not the length for the overall collection of devices (2) the number of blocks per device must not be divided by the number of devices because the resulting device size would not match the overall size (3) this then means that the overall write block size must be modified depending on the number of devices because the entry is per device and when the guest writes into the flash it calculates the write size by using the CFI entry (write size per device) multiplied by the number of chips. (It would alternatively be possible to modify the write block size in the CFI table (currently hardcoded at 2048) and leave the overall write block size alone.) This commit corrects these bugs, and adds a hw-compat property to retain the old behaviour on 2.8 and earlier versions. (The only board we have which uses this sort of flash config and has machine versioning is the "virt" board -- the PC uses a single flash device and so behaviour is unaffected whether using old-multiple-chip-handling or not.) Here is a configuration example from the vexpress board: VEXPRESS_FLASH_SIZE = 64M VEXPRESS_FLASH_SECT_SIZE 256K num-blocks = VEXPRESS_FLASH_SIZE / VEXPRESS_FLASH_SECT_SIZE = 256 sector-length = 256K width = 4 device-width = 2 The code will fill the CFI entry with the following entries: num-blocks = 256 sector-length = 128K writeblock_size = 2048 This results in two chips, each with 256 * 128K = 32M device size and a write block size of 2048. A sector erase will be sent to both chips, thus 256K must be erased. When the guest sends a block write command, it will write 4096 bytes data at once (2048 per device). Signed-off-by: David Engraf <david.engraf@sysgo.com> Reviewed-by: Peter Maydell <peter.maydell@linaro.org> [PMM: cleaned up and expanded commit message] Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2017-01-27 18:20:22 +03:00
DEFINE_PROP_BOOL("old-multiple-chip-handling", struct pflash_t,
old_multiple_chip_handling, false),
DEFINE_PROP_END_OF_LIST(),
};
static void pflash_cfi01_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
dc->realize = pflash_cfi01_realize;
dc->props = pflash_cfi01_properties;
dc->vmsd = &vmstate_pflash;
set_bit(DEVICE_CATEGORY_STORAGE, dc->categories);
}
static const TypeInfo pflash_cfi01_info = {
.name = TYPE_CFI_PFLASH01,
.parent = TYPE_SYS_BUS_DEVICE,
.instance_size = sizeof(struct pflash_t),
.class_init = pflash_cfi01_class_init,
};
static void pflash_cfi01_register_types(void)
{
type_register_static(&pflash_cfi01_info);
}
type_init(pflash_cfi01_register_types)
pflash_t *pflash_cfi01_register(hwaddr base,
DeviceState *qdev, const char *name,
hwaddr size,
BlockBackend *blk,
uint32_t sector_len, int nb_blocs,
int bank_width, uint16_t id0, uint16_t id1,
uint16_t id2, uint16_t id3, int be)
{
DeviceState *dev = qdev_create(NULL, TYPE_CFI_PFLASH01);
if (blk) {
qdev_prop_set_drive(dev, "drive", blk, &error_abort);
}
qdev_prop_set_uint32(dev, "num-blocks", nb_blocs);
qdev_prop_set_uint64(dev, "sector-length", sector_len);
qdev_prop_set_uint8(dev, "width", bank_width);
qdev_prop_set_bit(dev, "big-endian", !!be);
qdev_prop_set_uint16(dev, "id0", id0);
qdev_prop_set_uint16(dev, "id1", id1);
qdev_prop_set_uint16(dev, "id2", id2);
qdev_prop_set_uint16(dev, "id3", id3);
qdev_prop_set_string(dev, "name", name);
qdev_init_nofail(dev);
sysbus_mmio_map(SYS_BUS_DEVICE(dev), 0, base);
return CFI_PFLASH01(dev);
}
MemoryRegion *pflash_cfi01_get_memory(pflash_t *fl)
{
return &fl->mem;
}
pflash_cfi01: write flash contents to bdrv on incoming migration A drive that backs a pflash device is special: - it is very small, - its entire contents are kept in a RAMBlock at all times, covering the guest-phys address range that provides the guest's view of the emulated flash chip. The pflash device model keeps the drive (the host-side file) and the guest-visible flash contents in sync. When migrating the guest, the guest-visible flash contents (the RAMBlock) is migrated by default, but on the target host, the drive (the host-side file) remains in full sync with the RAMBlock only if: - the source and target hosts share the storage underlying the pflash drive, - or the migration requests full or incremental block migration too, which then covers all drives. Due to the special nature of pflash drives, the following scenario makes sense as well: - no full nor incremental block migration, covering all drives, alongside the base migration (justified eg. by shared storage for "normal" (big) drives), - non-shared storage for pflash drives. In this case, currently only those portions of the flash drive are updated on the target disk that the guest reprograms while running on the target host. In order to restore accord, dump the entire flash contents to the bdrv in a post_load() callback. - The read-only check follows the other call-sites of pflash_update(); - both "pfl->ro" and pflash_update() reflect / consider the case when "pfl->bs" is NULL; - the total size of the flash device is calculated as in pflash_cfi01_realize(). When using shared storage, or requesting full or incremental block migration along with the normal migration, the patch should incur a harmless rewrite from the target side. It is assumed that, on the target host, RAM is loaded ahead of the call to pflash_post_load(). Suggested-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Laszlo Ersek <lersek@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2014-08-23 14:19:07 +04:00
static void postload_update_cb(void *opaque, int running, RunState state)
{
pflash_t *pfl = opaque;
/* This is called after bdrv_invalidate_cache_all. */
qemu_del_vm_change_state_handler(pfl->vmstate);
pfl->vmstate = NULL;
DPRINTF("%s: updating bdrv for %s\n", __func__, pfl->name);
pflash_update(pfl, 0, pfl->sector_len * pfl->nb_blocs);
}
pflash_cfi01: write flash contents to bdrv on incoming migration A drive that backs a pflash device is special: - it is very small, - its entire contents are kept in a RAMBlock at all times, covering the guest-phys address range that provides the guest's view of the emulated flash chip. The pflash device model keeps the drive (the host-side file) and the guest-visible flash contents in sync. When migrating the guest, the guest-visible flash contents (the RAMBlock) is migrated by default, but on the target host, the drive (the host-side file) remains in full sync with the RAMBlock only if: - the source and target hosts share the storage underlying the pflash drive, - or the migration requests full or incremental block migration too, which then covers all drives. Due to the special nature of pflash drives, the following scenario makes sense as well: - no full nor incremental block migration, covering all drives, alongside the base migration (justified eg. by shared storage for "normal" (big) drives), - non-shared storage for pflash drives. In this case, currently only those portions of the flash drive are updated on the target disk that the guest reprograms while running on the target host. In order to restore accord, dump the entire flash contents to the bdrv in a post_load() callback. - The read-only check follows the other call-sites of pflash_update(); - both "pfl->ro" and pflash_update() reflect / consider the case when "pfl->bs" is NULL; - the total size of the flash device is calculated as in pflash_cfi01_realize(). When using shared storage, or requesting full or incremental block migration along with the normal migration, the patch should incur a harmless rewrite from the target side. It is assumed that, on the target host, RAM is loaded ahead of the call to pflash_post_load(). Suggested-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Laszlo Ersek <lersek@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2014-08-23 14:19:07 +04:00
static int pflash_post_load(void *opaque, int version_id)
{
pflash_t *pfl = opaque;
if (!pfl->ro) {
pfl->vmstate = qemu_add_vm_change_state_handler(postload_update_cb,
pfl);
pflash_cfi01: write flash contents to bdrv on incoming migration A drive that backs a pflash device is special: - it is very small, - its entire contents are kept in a RAMBlock at all times, covering the guest-phys address range that provides the guest's view of the emulated flash chip. The pflash device model keeps the drive (the host-side file) and the guest-visible flash contents in sync. When migrating the guest, the guest-visible flash contents (the RAMBlock) is migrated by default, but on the target host, the drive (the host-side file) remains in full sync with the RAMBlock only if: - the source and target hosts share the storage underlying the pflash drive, - or the migration requests full or incremental block migration too, which then covers all drives. Due to the special nature of pflash drives, the following scenario makes sense as well: - no full nor incremental block migration, covering all drives, alongside the base migration (justified eg. by shared storage for "normal" (big) drives), - non-shared storage for pflash drives. In this case, currently only those portions of the flash drive are updated on the target disk that the guest reprograms while running on the target host. In order to restore accord, dump the entire flash contents to the bdrv in a post_load() callback. - The read-only check follows the other call-sites of pflash_update(); - both "pfl->ro" and pflash_update() reflect / consider the case when "pfl->bs" is NULL; - the total size of the flash device is calculated as in pflash_cfi01_realize(). When using shared storage, or requesting full or incremental block migration along with the normal migration, the patch should incur a harmless rewrite from the target side. It is assumed that, on the target host, RAM is loaded ahead of the call to pflash_post_load(). Suggested-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Laszlo Ersek <lersek@redhat.com> Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
2014-08-23 14:19:07 +04:00
}
return 0;
}