qemu/hw/misc/omap_gpmc.c
Peter Maydell 89f26e6b7b hw/arm/omap_gpmc: Avoid buffer overrun filling prefetch FIFO
In fill_prefetch_fifo(), if the device we are reading from is 16 bit,
then we must not try to transfer an odd number of bytes into the FIFO.
This could otherwise have resulted in our overrunning the prefetch.fifo
array by one byte.

Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
Reviewed-by: Peter Crosthwaite <peter.crosthwaite@xilinx.com>
2014-05-13 16:09:39 +01:00

899 lines
28 KiB
C

/*
* TI OMAP general purpose memory controller emulation.
*
* Copyright (C) 2007-2009 Nokia Corporation
* Original code written by Andrzej Zaborowski <andrew@openedhand.com>
* Enhancements for OMAP3 and NAND support written by Juha Riihimäki
*
* 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 or
* (at your option) any later version of the License.
*
* 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.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include "hw/hw.h"
#include "hw/block/flash.h"
#include "hw/arm/omap.h"
#include "exec/memory.h"
#include "exec/address-spaces.h"
/* General-Purpose Memory Controller */
struct omap_gpmc_s {
qemu_irq irq;
qemu_irq drq;
MemoryRegion iomem;
int accept_256;
uint8_t revision;
uint8_t sysconfig;
uint16_t irqst;
uint16_t irqen;
uint16_t lastirq;
uint16_t timeout;
uint16_t config;
struct omap_gpmc_cs_file_s {
uint32_t config[7];
MemoryRegion *iomem;
MemoryRegion container;
MemoryRegion nandiomem;
DeviceState *dev;
} cs_file[8];
int ecc_cs;
int ecc_ptr;
uint32_t ecc_cfg;
ECCState ecc[9];
struct prefetch {
uint32_t config1; /* GPMC_PREFETCH_CONFIG1 */
uint32_t transfercount; /* GPMC_PREFETCH_CONFIG2:TRANSFERCOUNT */
int startengine; /* GPMC_PREFETCH_CONTROL:STARTENGINE */
int fifopointer; /* GPMC_PREFETCH_STATUS:FIFOPOINTER */
int count; /* GPMC_PREFETCH_STATUS:COUNTVALUE */
MemoryRegion iomem;
uint8_t fifo[64];
} prefetch;
};
#define OMAP_GPMC_8BIT 0
#define OMAP_GPMC_16BIT 1
#define OMAP_GPMC_NOR 0
#define OMAP_GPMC_NAND 2
static int omap_gpmc_devtype(struct omap_gpmc_cs_file_s *f)
{
return (f->config[0] >> 10) & 3;
}
static int omap_gpmc_devsize(struct omap_gpmc_cs_file_s *f)
{
/* devsize field is really 2 bits but we ignore the high
* bit to ensure consistent behaviour if the guest sets
* it (values 2 and 3 are reserved in the TRM)
*/
return (f->config[0] >> 12) & 1;
}
/* Extract the chip-select value from the prefetch config1 register */
static int prefetch_cs(uint32_t config1)
{
return (config1 >> 24) & 7;
}
static int prefetch_threshold(uint32_t config1)
{
return (config1 >> 8) & 0x7f;
}
static void omap_gpmc_int_update(struct omap_gpmc_s *s)
{
/* The TRM is a bit unclear, but it seems to say that
* the TERMINALCOUNTSTATUS bit is set only on the
* transition when the prefetch engine goes from
* active to inactive, whereas the FIFOEVENTSTATUS
* bit is held high as long as the fifo has at
* least THRESHOLD bytes available.
* So we do the latter here, but TERMINALCOUNTSTATUS
* is set elsewhere.
*/
if (s->prefetch.fifopointer >= prefetch_threshold(s->prefetch.config1)) {
s->irqst |= 1;
}
if ((s->irqen & s->irqst) != s->lastirq) {
s->lastirq = s->irqen & s->irqst;
qemu_set_irq(s->irq, s->lastirq);
}
}
static void omap_gpmc_dma_update(struct omap_gpmc_s *s, int value)
{
if (s->prefetch.config1 & 4) {
qemu_set_irq(s->drq, value);
}
}
/* Access functions for when a NAND-like device is mapped into memory:
* all addresses in the region behave like accesses to the relevant
* GPMC_NAND_DATA_i register (which is actually implemented to call these)
*/
static uint64_t omap_nand_read(void *opaque, hwaddr addr,
unsigned size)
{
struct omap_gpmc_cs_file_s *f = (struct omap_gpmc_cs_file_s *)opaque;
uint64_t v;
nand_setpins(f->dev, 0, 0, 0, 1, 0);
switch (omap_gpmc_devsize(f)) {
case OMAP_GPMC_8BIT:
v = nand_getio(f->dev);
if (size == 1) {
return v;
}
v |= (nand_getio(f->dev) << 8);
if (size == 2) {
return v;
}
v |= (nand_getio(f->dev) << 16);
v |= (nand_getio(f->dev) << 24);
return v;
case OMAP_GPMC_16BIT:
v = nand_getio(f->dev);
if (size == 1) {
/* 8 bit read from 16 bit device : probably a guest bug */
return v & 0xff;
}
if (size == 2) {
return v;
}
v |= (nand_getio(f->dev) << 16);
return v;
default:
abort();
}
}
static void omap_nand_setio(DeviceState *dev, uint64_t value,
int nandsize, int size)
{
/* Write the specified value to the NAND device, respecting
* both size of the NAND device and size of the write access.
*/
switch (nandsize) {
case OMAP_GPMC_8BIT:
switch (size) {
case 1:
nand_setio(dev, value & 0xff);
break;
case 2:
nand_setio(dev, value & 0xff);
nand_setio(dev, (value >> 8) & 0xff);
break;
case 4:
default:
nand_setio(dev, value & 0xff);
nand_setio(dev, (value >> 8) & 0xff);
nand_setio(dev, (value >> 16) & 0xff);
nand_setio(dev, (value >> 24) & 0xff);
break;
}
break;
case OMAP_GPMC_16BIT:
switch (size) {
case 1:
/* writing to a 16bit device with 8bit access is probably a guest
* bug; pass the value through anyway.
*/
case 2:
nand_setio(dev, value & 0xffff);
break;
case 4:
default:
nand_setio(dev, value & 0xffff);
nand_setio(dev, (value >> 16) & 0xffff);
break;
}
break;
}
}
static void omap_nand_write(void *opaque, hwaddr addr,
uint64_t value, unsigned size)
{
struct omap_gpmc_cs_file_s *f = (struct omap_gpmc_cs_file_s *)opaque;
nand_setpins(f->dev, 0, 0, 0, 1, 0);
omap_nand_setio(f->dev, value, omap_gpmc_devsize(f), size);
}
static const MemoryRegionOps omap_nand_ops = {
.read = omap_nand_read,
.write = omap_nand_write,
.endianness = DEVICE_NATIVE_ENDIAN,
};
static void fill_prefetch_fifo(struct omap_gpmc_s *s)
{
/* Fill the prefetch FIFO by reading data from NAND.
* We do this synchronously, unlike the hardware which
* will do this asynchronously. We refill when the
* FIFO has THRESHOLD bytes free, and we always refill
* as much data as possible starting at the top end
* of the FIFO.
* (We have to refill at THRESHOLD rather than waiting
* for the FIFO to empty to allow for the case where
* the FIFO size isn't an exact multiple of THRESHOLD
* and we're doing DMA transfers.)
* This means we never need to handle wrap-around in
* the fifo-reading code, and the next byte of data
* to read is always fifo[63 - fifopointer].
*/
int fptr;
int cs = prefetch_cs(s->prefetch.config1);
int is16bit = (((s->cs_file[cs].config[0] >> 12) & 3) != 0);
int bytes;
/* Don't believe the bit of the OMAP TRM that says that COUNTVALUE
* and TRANSFERCOUNT are in units of 16 bit words for 16 bit NAND.
* Instead believe the bit that says it is always a byte count.
*/
bytes = 64 - s->prefetch.fifopointer;
if (bytes > s->prefetch.count) {
bytes = s->prefetch.count;
}
if (is16bit) {
bytes &= ~1;
}
s->prefetch.count -= bytes;
s->prefetch.fifopointer += bytes;
fptr = 64 - s->prefetch.fifopointer;
/* Move the existing data in the FIFO so it sits just
* before what we're about to read in
*/
while (fptr < (64 - bytes)) {
s->prefetch.fifo[fptr] = s->prefetch.fifo[fptr + bytes];
fptr++;
}
while (fptr < 64) {
if (is16bit) {
uint32_t v = omap_nand_read(&s->cs_file[cs], 0, 2);
s->prefetch.fifo[fptr++] = v & 0xff;
s->prefetch.fifo[fptr++] = (v >> 8) & 0xff;
} else {
s->prefetch.fifo[fptr++] = omap_nand_read(&s->cs_file[cs], 0, 1);
}
}
if (s->prefetch.startengine && (s->prefetch.count == 0)) {
/* This was the final transfer: raise TERMINALCOUNTSTATUS */
s->irqst |= 2;
s->prefetch.startengine = 0;
}
/* If there are any bytes in the FIFO at this point then
* we must raise a DMA request (either this is a final part
* transfer, or we filled the FIFO in which case we certainly
* have THRESHOLD bytes available)
*/
if (s->prefetch.fifopointer != 0) {
omap_gpmc_dma_update(s, 1);
}
omap_gpmc_int_update(s);
}
/* Access functions for a NAND-like device when the prefetch/postwrite
* engine is enabled -- all addresses in the region behave alike:
* data is read or written to the FIFO.
*/
static uint64_t omap_gpmc_prefetch_read(void *opaque, hwaddr addr,
unsigned size)
{
struct omap_gpmc_s *s = (struct omap_gpmc_s *) opaque;
uint32_t data;
if (s->prefetch.config1 & 1) {
/* The TRM doesn't define the behaviour if you read from the
* FIFO when the prefetch engine is in write mode. We choose
* to always return zero.
*/
return 0;
}
/* Note that trying to read an empty fifo repeats the last byte */
if (s->prefetch.fifopointer) {
s->prefetch.fifopointer--;
}
data = s->prefetch.fifo[63 - s->prefetch.fifopointer];
if (s->prefetch.fifopointer ==
(64 - prefetch_threshold(s->prefetch.config1))) {
/* We've drained THRESHOLD bytes now. So deassert the
* DMA request, then refill the FIFO (which will probably
* assert it again.)
*/
omap_gpmc_dma_update(s, 0);
fill_prefetch_fifo(s);
}
omap_gpmc_int_update(s);
return data;
}
static void omap_gpmc_prefetch_write(void *opaque, hwaddr addr,
uint64_t value, unsigned size)
{
struct omap_gpmc_s *s = (struct omap_gpmc_s *) opaque;
int cs = prefetch_cs(s->prefetch.config1);
if ((s->prefetch.config1 & 1) == 0) {
/* The TRM doesn't define the behaviour of writing to the
* FIFO when the prefetch engine is in read mode. We
* choose to ignore the write.
*/
return;
}
if (s->prefetch.count == 0) {
/* The TRM doesn't define the behaviour of writing to the
* FIFO if the transfer is complete. We choose to ignore.
*/
return;
}
/* The only reason we do any data buffering in postwrite
* mode is if we are talking to a 16 bit NAND device, in
* which case we need to buffer the first byte of the
* 16 bit word until the other byte arrives.
*/
int is16bit = (((s->cs_file[cs].config[0] >> 12) & 3) != 0);
if (is16bit) {
/* fifopointer alternates between 64 (waiting for first
* byte of word) and 63 (waiting for second byte)
*/
if (s->prefetch.fifopointer == 64) {
s->prefetch.fifo[0] = value;
s->prefetch.fifopointer--;
} else {
value = (value << 8) | s->prefetch.fifo[0];
omap_nand_write(&s->cs_file[cs], 0, value, 2);
s->prefetch.count--;
s->prefetch.fifopointer = 64;
}
} else {
/* Just write the byte : fifopointer remains 64 at all times */
omap_nand_write(&s->cs_file[cs], 0, value, 1);
s->prefetch.count--;
}
if (s->prefetch.count == 0) {
/* Final transfer: raise TERMINALCOUNTSTATUS */
s->irqst |= 2;
s->prefetch.startengine = 0;
}
omap_gpmc_int_update(s);
}
static const MemoryRegionOps omap_prefetch_ops = {
.read = omap_gpmc_prefetch_read,
.write = omap_gpmc_prefetch_write,
.endianness = DEVICE_NATIVE_ENDIAN,
.impl.min_access_size = 1,
.impl.max_access_size = 1,
};
static MemoryRegion *omap_gpmc_cs_memregion(struct omap_gpmc_s *s, int cs)
{
/* Return the MemoryRegion* to map/unmap for this chipselect */
struct omap_gpmc_cs_file_s *f = &s->cs_file[cs];
if (omap_gpmc_devtype(f) == OMAP_GPMC_NOR) {
return f->iomem;
}
if ((s->prefetch.config1 & 0x80) &&
(prefetch_cs(s->prefetch.config1) == cs)) {
/* The prefetch engine is enabled for this CS: map the FIFO */
return &s->prefetch.iomem;
}
return &f->nandiomem;
}
static void omap_gpmc_cs_map(struct omap_gpmc_s *s, int cs)
{
struct omap_gpmc_cs_file_s *f = &s->cs_file[cs];
uint32_t mask = (f->config[6] >> 8) & 0xf;
uint32_t base = f->config[6] & 0x3f;
uint32_t size;
if (!f->iomem && !f->dev) {
return;
}
if (!(f->config[6] & (1 << 6))) {
/* Do nothing unless CSVALID */
return;
}
/* TODO: check for overlapping regions and report access errors */
if (mask != 0x8 && mask != 0xc && mask != 0xe && mask != 0xf
&& !(s->accept_256 && !mask)) {
fprintf(stderr, "%s: invalid chip-select mask address (0x%x)\n",
__func__, mask);
}
base <<= 24;
size = (0x0fffffff & ~(mask << 24)) + 1;
/* TODO: rather than setting the size of the mapping (which should be
* constant), the mask should cause wrapping of the address space, so
* that the same memory becomes accessible at every <i>size</i> bytes
* starting from <i>base</i>. */
memory_region_init(&f->container, NULL, "omap-gpmc-file", size);
memory_region_add_subregion(&f->container, 0,
omap_gpmc_cs_memregion(s, cs));
memory_region_add_subregion(get_system_memory(), base,
&f->container);
}
static void omap_gpmc_cs_unmap(struct omap_gpmc_s *s, int cs)
{
struct omap_gpmc_cs_file_s *f = &s->cs_file[cs];
if (!(f->config[6] & (1 << 6))) {
/* Do nothing unless CSVALID */
return;
}
if (!f->iomem && !f->dev) {
return;
}
memory_region_del_subregion(get_system_memory(), &f->container);
memory_region_del_subregion(&f->container, omap_gpmc_cs_memregion(s, cs));
memory_region_destroy(&f->container);
}
void omap_gpmc_reset(struct omap_gpmc_s *s)
{
int i;
s->sysconfig = 0;
s->irqst = 0;
s->irqen = 0;
omap_gpmc_int_update(s);
for (i = 0; i < 8; i++) {
/* This has to happen before we change any of the config
* used to determine which memory regions are mapped or unmapped.
*/
omap_gpmc_cs_unmap(s, i);
}
s->timeout = 0;
s->config = 0xa00;
s->prefetch.config1 = 0x00004000;
s->prefetch.transfercount = 0x00000000;
s->prefetch.startengine = 0;
s->prefetch.fifopointer = 0;
s->prefetch.count = 0;
for (i = 0; i < 8; i ++) {
s->cs_file[i].config[1] = 0x101001;
s->cs_file[i].config[2] = 0x020201;
s->cs_file[i].config[3] = 0x10031003;
s->cs_file[i].config[4] = 0x10f1111;
s->cs_file[i].config[5] = 0;
s->cs_file[i].config[6] = 0xf00 | (i ? 0 : 1 << 6);
s->cs_file[i].config[6] = 0xf00;
/* In theory we could probe attached devices for some CFG1
* bits here, but we just retain them across resets as they
* were set initially by omap_gpmc_attach().
*/
if (i == 0) {
s->cs_file[i].config[0] &= 0x00433e00;
s->cs_file[i].config[6] |= 1 << 6; /* CSVALID */
omap_gpmc_cs_map(s, i);
} else {
s->cs_file[i].config[0] &= 0x00403c00;
}
}
s->ecc_cs = 0;
s->ecc_ptr = 0;
s->ecc_cfg = 0x3fcff000;
for (i = 0; i < 9; i ++)
ecc_reset(&s->ecc[i]);
}
static int gpmc_wordaccess_only(hwaddr addr)
{
/* Return true if the register offset is to a register that
* only permits word width accesses.
* Non-word accesses are only OK for GPMC_NAND_DATA/ADDRESS/COMMAND
* for any chipselect.
*/
if (addr >= 0x60 && addr <= 0x1d4) {
int cs = (addr - 0x60) / 0x30;
addr -= cs * 0x30;
if (addr >= 0x7c && addr < 0x88) {
/* GPMC_NAND_COMMAND, GPMC_NAND_ADDRESS, GPMC_NAND_DATA */
return 0;
}
}
return 1;
}
static uint64_t omap_gpmc_read(void *opaque, hwaddr addr,
unsigned size)
{
struct omap_gpmc_s *s = (struct omap_gpmc_s *) opaque;
int cs;
struct omap_gpmc_cs_file_s *f;
if (size != 4 && gpmc_wordaccess_only(addr)) {
return omap_badwidth_read32(opaque, addr);
}
switch (addr) {
case 0x000: /* GPMC_REVISION */
return s->revision;
case 0x010: /* GPMC_SYSCONFIG */
return s->sysconfig;
case 0x014: /* GPMC_SYSSTATUS */
return 1; /* RESETDONE */
case 0x018: /* GPMC_IRQSTATUS */
return s->irqst;
case 0x01c: /* GPMC_IRQENABLE */
return s->irqen;
case 0x040: /* GPMC_TIMEOUT_CONTROL */
return s->timeout;
case 0x044: /* GPMC_ERR_ADDRESS */
case 0x048: /* GPMC_ERR_TYPE */
return 0;
case 0x050: /* GPMC_CONFIG */
return s->config;
case 0x054: /* GPMC_STATUS */
return 0x001;
case 0x060 ... 0x1d4:
cs = (addr - 0x060) / 0x30;
addr -= cs * 0x30;
f = s->cs_file + cs;
switch (addr) {
case 0x60: /* GPMC_CONFIG1 */
return f->config[0];
case 0x64: /* GPMC_CONFIG2 */
return f->config[1];
case 0x68: /* GPMC_CONFIG3 */
return f->config[2];
case 0x6c: /* GPMC_CONFIG4 */
return f->config[3];
case 0x70: /* GPMC_CONFIG5 */
return f->config[4];
case 0x74: /* GPMC_CONFIG6 */
return f->config[5];
case 0x78: /* GPMC_CONFIG7 */
return f->config[6];
case 0x84 ... 0x87: /* GPMC_NAND_DATA */
if (omap_gpmc_devtype(f) == OMAP_GPMC_NAND) {
return omap_nand_read(f, 0, size);
}
return 0;
}
break;
case 0x1e0: /* GPMC_PREFETCH_CONFIG1 */
return s->prefetch.config1;
case 0x1e4: /* GPMC_PREFETCH_CONFIG2 */
return s->prefetch.transfercount;
case 0x1ec: /* GPMC_PREFETCH_CONTROL */
return s->prefetch.startengine;
case 0x1f0: /* GPMC_PREFETCH_STATUS */
/* NB: The OMAP3 TRM is inconsistent about whether the GPMC
* FIFOTHRESHOLDSTATUS bit should be set when
* FIFOPOINTER > FIFOTHRESHOLD or when it is >= FIFOTHRESHOLD.
* Apparently the underlying functional spec from which the TRM was
* created states that the behaviour is ">=", and this also
* makes more conceptual sense.
*/
return (s->prefetch.fifopointer << 24) |
((s->prefetch.fifopointer >=
((s->prefetch.config1 >> 8) & 0x7f) ? 1 : 0) << 16) |
s->prefetch.count;
case 0x1f4: /* GPMC_ECC_CONFIG */
return s->ecc_cs;
case 0x1f8: /* GPMC_ECC_CONTROL */
return s->ecc_ptr;
case 0x1fc: /* GPMC_ECC_SIZE_CONFIG */
return s->ecc_cfg;
case 0x200 ... 0x220: /* GPMC_ECC_RESULT */
cs = (addr & 0x1f) >> 2;
/* TODO: check correctness */
return
((s->ecc[cs].cp & 0x07) << 0) |
((s->ecc[cs].cp & 0x38) << 13) |
((s->ecc[cs].lp[0] & 0x1ff) << 3) |
((s->ecc[cs].lp[1] & 0x1ff) << 19);
case 0x230: /* GPMC_TESTMODE_CTRL */
return 0;
case 0x234: /* GPMC_PSA_LSB */
case 0x238: /* GPMC_PSA_MSB */
return 0x00000000;
}
OMAP_BAD_REG(addr);
return 0;
}
static void omap_gpmc_write(void *opaque, hwaddr addr,
uint64_t value, unsigned size)
{
struct omap_gpmc_s *s = (struct omap_gpmc_s *) opaque;
int cs;
struct omap_gpmc_cs_file_s *f;
if (size != 4 && gpmc_wordaccess_only(addr)) {
return omap_badwidth_write32(opaque, addr, value);
}
switch (addr) {
case 0x000: /* GPMC_REVISION */
case 0x014: /* GPMC_SYSSTATUS */
case 0x054: /* GPMC_STATUS */
case 0x1f0: /* GPMC_PREFETCH_STATUS */
case 0x200 ... 0x220: /* GPMC_ECC_RESULT */
case 0x234: /* GPMC_PSA_LSB */
case 0x238: /* GPMC_PSA_MSB */
OMAP_RO_REG(addr);
break;
case 0x010: /* GPMC_SYSCONFIG */
if ((value >> 3) == 0x3)
fprintf(stderr, "%s: bad SDRAM idle mode %"PRIi64"\n",
__FUNCTION__, value >> 3);
if (value & 2)
omap_gpmc_reset(s);
s->sysconfig = value & 0x19;
break;
case 0x018: /* GPMC_IRQSTATUS */
s->irqst &= ~value;
omap_gpmc_int_update(s);
break;
case 0x01c: /* GPMC_IRQENABLE */
s->irqen = value & 0xf03;
omap_gpmc_int_update(s);
break;
case 0x040: /* GPMC_TIMEOUT_CONTROL */
s->timeout = value & 0x1ff1;
break;
case 0x044: /* GPMC_ERR_ADDRESS */
case 0x048: /* GPMC_ERR_TYPE */
break;
case 0x050: /* GPMC_CONFIG */
s->config = value & 0xf13;
break;
case 0x060 ... 0x1d4:
cs = (addr - 0x060) / 0x30;
addr -= cs * 0x30;
f = s->cs_file + cs;
switch (addr) {
case 0x60: /* GPMC_CONFIG1 */
f->config[0] = value & 0xffef3e13;
break;
case 0x64: /* GPMC_CONFIG2 */
f->config[1] = value & 0x001f1f8f;
break;
case 0x68: /* GPMC_CONFIG3 */
f->config[2] = value & 0x001f1f8f;
break;
case 0x6c: /* GPMC_CONFIG4 */
f->config[3] = value & 0x1f8f1f8f;
break;
case 0x70: /* GPMC_CONFIG5 */
f->config[4] = value & 0x0f1f1f1f;
break;
case 0x74: /* GPMC_CONFIG6 */
f->config[5] = value & 0x00000fcf;
break;
case 0x78: /* GPMC_CONFIG7 */
if ((f->config[6] ^ value) & 0xf7f) {
omap_gpmc_cs_unmap(s, cs);
f->config[6] = value & 0x00000f7f;
omap_gpmc_cs_map(s, cs);
}
break;
case 0x7c ... 0x7f: /* GPMC_NAND_COMMAND */
if (omap_gpmc_devtype(f) == OMAP_GPMC_NAND) {
nand_setpins(f->dev, 1, 0, 0, 1, 0); /* CLE */
omap_nand_setio(f->dev, value, omap_gpmc_devsize(f), size);
}
break;
case 0x80 ... 0x83: /* GPMC_NAND_ADDRESS */
if (omap_gpmc_devtype(f) == OMAP_GPMC_NAND) {
nand_setpins(f->dev, 0, 1, 0, 1, 0); /* ALE */
omap_nand_setio(f->dev, value, omap_gpmc_devsize(f), size);
}
break;
case 0x84 ... 0x87: /* GPMC_NAND_DATA */
if (omap_gpmc_devtype(f) == OMAP_GPMC_NAND) {
omap_nand_write(f, 0, value, size);
}
break;
default:
goto bad_reg;
}
break;
case 0x1e0: /* GPMC_PREFETCH_CONFIG1 */
if (!s->prefetch.startengine) {
uint32_t newconfig1 = value & 0x7f8f7fbf;
uint32_t changed;
changed = newconfig1 ^ s->prefetch.config1;
if (changed & (0x80 | 0x7000000)) {
/* Turning the engine on or off, or mapping it somewhere else.
* cs_map() and cs_unmap() check the prefetch config and
* overall CSVALID bits, so it is sufficient to unmap-and-map
* both the old cs and the new one. Note that we adhere to
* the "unmap/change config/map" order (and not unmap twice
* if newcs == oldcs), otherwise we'll try to delete the wrong
* memory region.
*/
int oldcs = prefetch_cs(s->prefetch.config1);
int newcs = prefetch_cs(newconfig1);
omap_gpmc_cs_unmap(s, oldcs);
if (oldcs != newcs) {
omap_gpmc_cs_unmap(s, newcs);
}
s->prefetch.config1 = newconfig1;
omap_gpmc_cs_map(s, oldcs);
if (oldcs != newcs) {
omap_gpmc_cs_map(s, newcs);
}
} else {
s->prefetch.config1 = newconfig1;
}
}
break;
case 0x1e4: /* GPMC_PREFETCH_CONFIG2 */
if (!s->prefetch.startengine) {
s->prefetch.transfercount = value & 0x3fff;
}
break;
case 0x1ec: /* GPMC_PREFETCH_CONTROL */
if (s->prefetch.startengine != (value & 1)) {
s->prefetch.startengine = value & 1;
if (s->prefetch.startengine) {
/* Prefetch engine start */
s->prefetch.count = s->prefetch.transfercount;
if (s->prefetch.config1 & 1) {
/* Write */
s->prefetch.fifopointer = 64;
} else {
/* Read */
s->prefetch.fifopointer = 0;
fill_prefetch_fifo(s);
}
} else {
/* Prefetch engine forcibly stopped. The TRM
* doesn't define the behaviour if you do this.
* We clear the prefetch count, which means that
* we permit no more writes, and don't read any
* more data from NAND. The CPU can still drain
* the FIFO of unread data.
*/
s->prefetch.count = 0;
}
omap_gpmc_int_update(s);
}
break;
case 0x1f4: /* GPMC_ECC_CONFIG */
s->ecc_cs = 0x8f;
break;
case 0x1f8: /* GPMC_ECC_CONTROL */
if (value & (1 << 8))
for (cs = 0; cs < 9; cs ++)
ecc_reset(&s->ecc[cs]);
s->ecc_ptr = value & 0xf;
if (s->ecc_ptr == 0 || s->ecc_ptr > 9) {
s->ecc_ptr = 0;
s->ecc_cs &= ~1;
}
break;
case 0x1fc: /* GPMC_ECC_SIZE_CONFIG */
s->ecc_cfg = value & 0x3fcff1ff;
break;
case 0x230: /* GPMC_TESTMODE_CTRL */
if (value & 7)
fprintf(stderr, "%s: test mode enable attempt\n", __FUNCTION__);
break;
default:
bad_reg:
OMAP_BAD_REG(addr);
return;
}
}
static const MemoryRegionOps omap_gpmc_ops = {
.read = omap_gpmc_read,
.write = omap_gpmc_write,
.endianness = DEVICE_NATIVE_ENDIAN,
};
struct omap_gpmc_s *omap_gpmc_init(struct omap_mpu_state_s *mpu,
hwaddr base,
qemu_irq irq, qemu_irq drq)
{
int cs;
struct omap_gpmc_s *s = (struct omap_gpmc_s *)
g_malloc0(sizeof(struct omap_gpmc_s));
memory_region_init_io(&s->iomem, NULL, &omap_gpmc_ops, s, "omap-gpmc", 0x1000);
memory_region_add_subregion(get_system_memory(), base, &s->iomem);
s->irq = irq;
s->drq = drq;
s->accept_256 = cpu_is_omap3630(mpu);
s->revision = cpu_class_omap3(mpu) ? 0x50 : 0x20;
s->lastirq = 0;
omap_gpmc_reset(s);
/* We have to register a different IO memory handler for each
* chip select region in case a NAND device is mapped there. We
* make the region the worst-case size of 256MB and rely on the
* container memory region in cs_map to chop it down to the actual
* guest-requested size.
*/
for (cs = 0; cs < 8; cs++) {
memory_region_init_io(&s->cs_file[cs].nandiomem, NULL,
&omap_nand_ops,
&s->cs_file[cs],
"omap-nand",
256 * 1024 * 1024);
}
memory_region_init_io(&s->prefetch.iomem, NULL, &omap_prefetch_ops, s,
"omap-gpmc-prefetch", 256 * 1024 * 1024);
return s;
}
void omap_gpmc_attach(struct omap_gpmc_s *s, int cs, MemoryRegion *iomem)
{
struct omap_gpmc_cs_file_s *f;
assert(iomem);
if (cs < 0 || cs >= 8) {
fprintf(stderr, "%s: bad chip-select %i\n", __FUNCTION__, cs);
exit(-1);
}
f = &s->cs_file[cs];
omap_gpmc_cs_unmap(s, cs);
f->config[0] &= ~(0xf << 10);
f->iomem = iomem;
omap_gpmc_cs_map(s, cs);
}
void omap_gpmc_attach_nand(struct omap_gpmc_s *s, int cs, DeviceState *nand)
{
struct omap_gpmc_cs_file_s *f;
assert(nand);
if (cs < 0 || cs >= 8) {
fprintf(stderr, "%s: bad chip-select %i\n", __func__, cs);
exit(-1);
}
f = &s->cs_file[cs];
omap_gpmc_cs_unmap(s, cs);
f->config[0] &= ~(0xf << 10);
f->config[0] |= (OMAP_GPMC_NAND << 10);
f->dev = nand;
if (nand_getbuswidth(f->dev) == 16) {
f->config[0] |= OMAP_GPMC_16BIT << 12;
}
omap_gpmc_cs_map(s, cs);
}