This patch adds "high coreboot table support" to coreboot version 2.

Some bootloaders seem to overwrite memory starting at 0x600, thus destroying
the coreboot table integrity, rendering the table useless.

By moving the table to the high tables area (if it's activated), this problem
is fixed.

In order to move the table, a 40 bytes mini coreboot table with a single sub
table is placed at 0x500/0x530 that points to the real coreboot table. This is
comparable to the ACPI RSDT or the MP floating table.

This patch also adds "table forward" support to flashrom and nvramtool.

Signed-off-by: Stefan Reinauer <stepan@coresystems.de>
Acked-by: Peter Stuge <peter@stuge.se>



git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4011 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
This commit is contained in:
Stefan Reinauer 2009-03-17 14:38:48 +00:00 committed by Stefan Reinauer
parent 5d6645ae44
commit efab4ba3bb
4 changed files with 53 additions and 22 deletions

View File

@ -196,6 +196,18 @@ void lb_strings(struct lb_header *header)
}
struct lb_forward *lb_forward(struct lb_header *header, struct lb_header *next_header)
{
struct lb_record *rec;
struct lb_forward *forward;
rec = lb_new_record(header);
forward = (struct lb_forward *)rec;
forward->tag = LB_TAG_FORWARD;
forward->size = sizeof(*forward);
forward->forward = (uint64_t) next_header;
return forward;
}
void lb_memory_range(struct lb_memory *mem,
uint32_t type, uint64_t start, uint64_t size)
{
@ -239,14 +251,17 @@ static void lb_reserve_table_memory(struct lb_header *head)
}
}
unsigned long lb_table_fini(struct lb_header *head)
static unsigned long lb_table_fini(struct lb_header *head, int fixup)
{
struct lb_record *rec, *first_rec;
rec = lb_last_record(head);
if (head->table_entries) {
head->table_bytes += rec->size;
}
if (fixup)
lb_reserve_table_memory(head);
first_rec = lb_first_record(head);
head->table_checksum = compute_ip_checksum(first_rec, head->table_bytes);
head->header_checksum = 0;
@ -406,6 +421,22 @@ unsigned long write_coreboot_table(
struct lb_header *head;
struct lb_memory *mem;
#if HAVE_HIGH_TABLES == 1
printk_debug("Writing high table forward entry at 0x%08lx\n",
low_table_end);
head = lb_table_init(low_table_end);
lb_forward(head, rom_table_end);
lb_table_fini(head, 0);
low_table_end = (unsigned long)head;
printk_debug("New low_table_end: 0x%08lx\n", low_table_end);
printk_debug("Now going to write high coreboot table at 0x%08lx\n",
rom_table_end);
head = lb_table_init(rom_table_end);
rom_table_end = (unsigned long)head;
printk_debug("rom_table_end = 0x%08lx\n", rom_table_end);
#else
if(low_table_end > (0x1000 - sizeof(struct lb_header))) { /* after 4K */
/* We need to put lbtable on to [0xf0000,0x100000) */
head = lb_table_init(rom_table_end);
@ -414,6 +445,7 @@ unsigned long write_coreboot_table(
head = lb_table_init(low_table_end);
low_table_end = (unsigned long)head;
}
#endif
printk_debug("Adjust low_table_end from 0x%08lx to ", low_table_end);
low_table_end += 0xfff; // 4K aligned
@ -469,6 +501,6 @@ unsigned long write_coreboot_table(
lb_strings(head);
/* Remember where my valid memory ranges are */
return lb_table_fini(head);
return lb_table_fini(head, 1);
}

View File

@ -17,7 +17,6 @@ struct lb_memory *lb_memory(struct lb_header *header);
void lb_memory_range(struct lb_memory *mem,
uint32_t type, uint64_t start, uint64_t size);
struct lb_mainboard *lb_mainboard(struct lb_header *header);
unsigned long lb_table_fini(struct lb_header *header);
/* Routines to extract part so the coreboot table or information
* from the coreboot table.

View File

@ -75,7 +75,7 @@ struct lb_memory *write_tables(void)
unsigned long high_table_start, high_table_end=0;
if (high_tables_base) {
printk_debug("High Tables Base is %lx.\n", high_tables_base);
printk_debug("High Tables Base is %llx.\n", high_tables_base);
high_table_start = high_tables_base;
high_table_end = high_tables_base;
} else {
@ -189,26 +189,19 @@ struct lb_memory *write_tables(void)
rom_table_start, rom_table_end);
#endif
#if HAVE_HIGH_TABLES == 1
if (high_tables_base) {
write_coreboot_table(low_table_start, low_table_end,
high_table_start, high_table_end);
} else {
printk_err("ERROR: No high_tables_base.\n");
write_coreboot_table(low_table_start, low_table_end,
rom_table_start, rom_table_end);
}
#else
/* The coreboot table must be in 0-4K or 960K-1M */
write_coreboot_table(low_table_start, low_table_end,
rom_table_start, rom_table_end);
#if 0 && HAVE_HIGH_TABLES == 1
/* This is currently broken and should be severely refactored. Ideally
* we only have a pointer to the coreboot table in the low memory, so
* anyone can find the real position.
* write_coreboot_table does a lot more than just writing the coreboot
* table. It magically decides where the table should go, and therefore
* it consumes two base addresses. If we call write_coreboot_table like
* below, we get weird effects.
*/
/* And we want another copy in high area because the low area might be
* corrupted
*/
if (high_tables_base) {
write_coreboot_table(high_table_start, high_table_end,
high_table_start, high_table_end);
}
#endif
return get_lb_mem();

View File

@ -155,6 +155,13 @@ struct lb_console {
uint16_t type;
};
#define LB_TAG_FORWARD 0x0011
struct lb_forward {
uint32_t tag;
uint32_t size;
uint64_t forward;
};
#define LB_TAG_CONSOLE_SERIAL8250 0
#define LB_TAG_CONSOLE_VGA 1
#define LB_TAG_CONSOLE_BTEXT 2