#include <target/image.h>
+/**
+ * @file
+ * Upper level of NOR flash framework.
+ * The lower level interfaces are to drivers. These upper level ones
+ * primarily support access from Tcl scripts or from GDB.
+ */
+
struct flash_bank *flash_banks;
int flash_driver_erase(struct flash_bank *bank, int first, int last)
return ERROR_OK;
}
-/* erase given flash region, selects proper bank according to target and address */
+/* Manipulate given flash region, selecting the bank according to target
+ * and address. Maps an address range to a set of sectors, and issues
+ * the callback() on that set ... e.g. to erase or unprotect its members.
+ *
+ * (Note a current bad assumption: that protection operates on the same
+ * size sectors as erase operations use.)
+ *
+ * The "pad_reason" parameter is a kind of boolean: when it's NULL, the
+ * range must fit those sectors exactly. This is clearly safe; it can't
+ * erase data which the caller said to leave alone, for example. If it's
+ * non-NULL, rather than failing, extra data in the first and/or last
+ * sectors will be added to the range, and that reason string is used when
+ * warning about those additions.
+ */
static int flash_iterate_address_range(struct target *target,
- uint32_t addr, uint32_t length,
+ char *pad_reason, uint32_t addr, uint32_t length,
int (*callback)(struct flash_bank *bank, int first, int last))
{
struct flash_bank *c;
{
/* special case, erase whole bank when length is zero */
if (addr != c->base)
+ {
+ LOG_ERROR("Whole bank access must start at beginning of bank.");
return ERROR_FLASH_DST_BREAKS_ALIGNMENT;
+ }
return callback(c, 0, c->num_sectors - 1);
}
/* check whether it all fits in this bank */
if (addr + length - 1 > c->base + c->size - 1)
+ {
+ LOG_ERROR("Flash access does not fit into bank.");
return ERROR_FLASH_DST_BREAKS_ALIGNMENT;
+ }
/** @todo: handle erasures that cross into adjacent banks */
for (i = 0; i < c->num_sectors; i++)
{
struct flash_sector *f = c->sectors + i;
+ uint32_t end = f->offset + f->size;
/* start only on a sector boundary */
if (first < 0) {
+ /* scanned past the first sector? */
+ if (addr < f->offset)
+ break;
+
/* is this the first sector? */
if (addr == f->offset)
first = i;
- else if (addr < f->offset)
- break;
+
+ /* Does this need head-padding? If so, pad and warn;
+ * or else force an error.
+ *
+ * Such padding can make trouble, since *WE* can't
+ * ever know if that data was in use. The warning
+ * should help users sort out messes later.
+ */
+ else if (addr < end && pad_reason) {
+ /* FIXME say how many bytes (e.g. 80 KB) */
+ LOG_WARNING("Adding extra %s range, "
+ "%#8.8x to %#8.8x",
+ pad_reason,
+ (unsigned) f->offset,
+ (unsigned) addr - 1);
+ first = i;
+ } else
+ continue;
}
/* is this (also?) the last sector? */
- if (last_addr == f->offset + f->size) {
+ if (last_addr == end) {
+ last = i;
+ break;
+ }
+
+ /* Does this need tail-padding? If so, pad and warn;
+ * or else force an error.
+ */
+ if (last_addr < end && pad_reason) {
+ /* FIXME say how many bytes (e.g. 80 KB) */
+ LOG_WARNING("Adding extra %s range, "
+ "%#8.8x to %#8.8x",
+ pad_reason,
+ (unsigned) last_addr,
+ (unsigned) end - 1);
last = i;
break;
}
LOG_ERROR("address range 0x%8.8x .. 0x%8.8x "
"is not sector-aligned",
(unsigned) (c->base + addr),
- (unsigned) (last_addr - 1));
+ (unsigned) (c->base + last_addr - 1));
return ERROR_FLASH_DST_BREAKS_ALIGNMENT;
}
- /* The NOR driver may trim this range down, based on
- * whether or not a given sector is already erased.
- *
- * REVISIT should *we* trim it... ?
+ /* The NOR driver may trim this range down, based on what
+ * sectors are already erased/unprotected. GDB currently
+ * blocks such optimizations.
*/
return callback(c, first, last);
}
int flash_erase_address_range(struct target *target,
- uint32_t addr, uint32_t length)
+ bool pad, uint32_t addr, uint32_t length)
{
- return flash_iterate_address_range(target,
+ return flash_iterate_address_range(target, pad ? "erase" : NULL,
addr, length, &flash_driver_erase);
}
static int flash_unlock_address_range(struct target *target, uint32_t addr, uint32_t length)
{
- return flash_iterate_address_range(target,
+ /* By default, pad to sector boundaries ... the real issue here
+ * is that our (only) caller *permanently* removes protection,
+ * and doesn't restore it.
+ */
+ return flash_iterate_address_range(target, "unprotect",
addr, length, &flash_driver_unprotect);
}
struct flash_bank *c;
int *padding;
+ /* REVISIT do_pad should perhaps just be another parameter.
+ * GDB wouldn't ever need it, since it erases separately.
+ * But "flash write_image" commands might want that option.
+ */
+ bool do_pad = false;
+
section = 0;
section_offset = 0;
break;
}
- /* REVISIT This needlessly touches sectors BETWEEN the
+ /* FIXME This needlessly touches sectors BETWEEN the
* sections it's writing. Without auto erase, it just
- * writes ones; unlikely to destroy data.
+ * writes ones. That WILL INVALIDATE data in cases
+ * like Stellaris Tempest chips, corrupting internal
+ * ECC codes; and at least FreeScale suggests issues
+ * with that approach (in HC11 documentation).
*
* With auto erase enabled, data in those sectors will
* be needlessly destroyed; and some of the limited
* In both cases, the extra writes slow things down.
*/
- /* if we have multiple sections within our image, flash programming could fail due to alignment issues
+ /* if we have multiple sections within our image,
+ * flash programming could fail due to alignment issues
* attempt to rebuild a consecutive buffer for the flash loader */
pad_bytes = (image->sections[section_last + 1].base_address) - (run_address + run_size);
if ((run_address + run_size + pad_bytes) > (c->base + c->size))
if (erase)
{
/* calculate and erase sectors */
- retval = flash_erase_address_range(target, run_address, run_size);
+ retval = flash_erase_address_range(target,
+ do_pad, run_address, run_size);
}
}
{
return flash_write_unlock(target, image, written, erase, false);
}
+
+/**
+ * Invalidates cached flash state which a target can change as it runs.
+ *
+ * @param target The target being resumed
+ *
+ * OpenOCD caches some flash state for brief periods. For example, a sector
+ * that is protected must be unprotected before OpenOCD tries to write it,
+ * Also, a sector that's not erased must be erased before it's written.
+ *
+ * As a rule, OpenOCD and target firmware can both modify the flash, so when
+ * a target starts running, OpenOCD needs to invalidate its cached state.
+ */
+void nor_resume(struct target *target)
+{
+ struct flash_bank *bank;
+
+ for (bank = flash_banks; bank; bank = bank->next) {
+ int i;
+
+ if (bank->target != target)
+ continue;
+
+ for (i = 0; i < bank->num_sectors; i++) {
+ struct flash_sector *sector = bank->sectors + i;
+
+ sector->is_erased = -1;
+ sector->is_protected = -1;
+ }
+ }
+}