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-rw-r--r--src/cpu/x86/mtrr/mtrr.c236
1 files changed, 188 insertions, 48 deletions
diff --git a/src/cpu/x86/mtrr/mtrr.c b/src/cpu/x86/mtrr/mtrr.c
index 9c8f8c7647..005ea81063 100644
--- a/src/cpu/x86/mtrr/mtrr.c
+++ b/src/cpu/x86/mtrr/mtrr.c
@@ -122,6 +122,21 @@ static inline unsigned int fls(unsigned int x)
#define RANGE_1MB PHYS_TO_RANGE_ADDR(1 << 20)
#define RANGE_4GB (1 << (ADDR_SHIFT_TO_RANGE_SHIFT(32)))
+/*
+ * The default MTRR type selection uses 3 approaches for selecting the
+ * optimal number of variable MTRRs. For each range do 3 calculations:
+ * 1. UC as default type with no holes at top of range.
+ * 2. UC as default using holes at top of range.
+ * 3. WB as default.
+ * If using holes is optimal for a range when UC is the default type the
+ * tag is updated to direct the commit routine to use a hole at the top
+ * of a range.
+ */
+#define MTRR_ALGO_SHIFT (8)
+#define MTRR_TAG_MASK ((1 << MTRR_ALGO_SHIFT) - 1)
+/* If the default type is UC use the hole carving algorithm for a range. */
+#define MTRR_RANGE_UC_USE_HOLE (1 << MTRR_ALGO_SHIFT)
+
static inline uint32_t range_entry_base_mtrr_addr(struct range_entry *r)
{
return PHYS_TO_RANGE_ADDR(range_entry_base(r));
@@ -132,6 +147,11 @@ static inline uint32_t range_entry_end_mtrr_addr(struct range_entry *r)
return PHYS_TO_RANGE_ADDR(range_entry_end(r));
}
+static inline int range_entry_mtrr_type(struct range_entry *r)
+{
+ return range_entry_tag(r) & MTRR_TAG_MASK;
+}
+
static struct memranges *get_physical_address_space(void)
{
static struct memranges *addr_space;
@@ -491,9 +511,72 @@ static void calc_var_mtrr_range(struct var_mtrr_state *var_state,
}
}
-static void setup_var_mtrrs_by_state(struct var_mtrr_state *var_state)
+static void calc_var_mtrrs_with_hole(struct var_mtrr_state *var_state,
+ struct range_entry *r)
{
- struct range_entry *r;
+ uint32_t a1, a2, b1, b2;
+ int mtrr_type;
+ struct range_entry *next;
+
+ /*
+ * Determine MTRRs based on the following algoirthm for the given entry:
+ * +------------------+ b2 = ALIGN_UP(end)
+ * | 0 or more bytes | <-- hole is carved out between b1 and b2
+ * +------------------+ a2 = b1 = end
+ * | |
+ * +------------------+ a1 = begin
+ *
+ * Thus, there are 3 sub-ranges to configure variable MTRRs for.
+ */
+ mtrr_type = range_entry_mtrr_type(r);
+
+ a1 = range_entry_base_mtrr_addr(r);
+ a2 = range_entry_end_mtrr_addr(r);
+
+ /* The end address is under 1MiB. The fixed MTRRs take
+ * precedence over the variable ones. Therefore this range
+ * can be ignored. */
+ if (a2 < RANGE_1MB)
+ return;
+
+ /* Again, the fixed MTRRs take precedence so the beginning
+ * of the range can be set to 0 if it starts below 1MiB. */
+ if (a1 < RANGE_1MB)
+ a1 = 0;
+
+ /* If the range starts above 4GiB the processing is done. */
+ if (!var_state->above4gb && a1 >= RANGE_4GB)
+ return;
+
+ /* Clip the upper address to 4GiB if addresses above 4GiB
+ * are not being processed. */
+ if (!var_state->above4gb && a2 > RANGE_4GB)
+ a2 = RANGE_4GB;
+
+ b1 = a2;
+ b2 = ALIGN_UP(a2, MTRR_MIN_ALIGN);
+
+ /* Check against the next range. If the current range_entry is the
+ * last entry then carving a hole is no problem. If the current entry
+ * isn't the last entry then check that the last entry covers the
+ * entire hole range with the default mtrr type. */
+ next = memranges_next_entry(var_state->addr_space, r);
+ if (next != NULL &&
+ (range_entry_mtrr_type(next) != var_state->def_mtrr_type ||
+ range_entry_end_mtrr_addr(next) < b2)) {
+ calc_var_mtrr_range(var_state, a1, a2 - a1, mtrr_type);
+ return;
+ }
+
+ calc_var_mtrr_range(var_state, a1, b2 - a1, mtrr_type);
+ calc_var_mtrr_range(var_state, b1, b2 - b1, var_state->def_mtrr_type);
+}
+
+static void calc_var_mtrrs_without_hole(struct var_mtrr_state *var_state,
+ struct range_entry *r)
+{
+ uint32_t a1, a2, b1, b2, c1, c2;
+ int mtrr_type;
/*
* For each range that meets the non-default type process it in the
@@ -508,51 +591,44 @@ static void setup_var_mtrrs_by_state(struct var_mtrr_state *var_state)
*
* Thus, there are 3 sub-ranges to configure variable MTRRs for.
*/
- memranges_each_entry(r, var_state->addr_space) {
- uint32_t a1, a2, b1, b2, c1, c2;
- int mtrr_type = range_entry_tag(r);
+ mtrr_type = range_entry_mtrr_type(r);
- /* Skip default type. */
- if (var_state->def_mtrr_type == mtrr_type)
- continue;
-
- a1 = range_entry_base_mtrr_addr(r);
- c2 = range_entry_end_mtrr_addr(r);
+ a1 = range_entry_base_mtrr_addr(r);
+ c2 = range_entry_end_mtrr_addr(r);
- /* The end address is under 1MiB. The fixed MTRRs take
- * precedence over the variable ones. Therefore this range
- * can be ignored. */
- if (c2 < RANGE_1MB)
- continue;
+ /* The end address is under 1MiB. The fixed MTRRs take
+ * precedence over the variable ones. Therefore this range
+ * can be ignored. */
+ if (c2 < RANGE_1MB)
+ return;
- /* Again, the fixed MTRRs take precedence so the beginning
- * of the range can be set to 0 if it starts below 1MiB. */
- if (a1 < RANGE_1MB)
- a1 = 0;
+ /* Again, the fixed MTRRs take precedence so the beginning
+ * of the range can be set to 0 if it starts below 1MiB. */
+ if (a1 < RANGE_1MB)
+ a1 = 0;
- /* If the range starts above 4GiB the processing is done. */
- if (!var_state->above4gb && a1 >= RANGE_4GB)
- break;
+ /* If the range starts above 4GiB the processing is done. */
+ if (!var_state->above4gb && a1 >= RANGE_4GB)
+ return;
- /* Clip the upper address to 4GiB if addresses above 4GiB
- * are not being processed. */
- if (!var_state->above4gb && c2 > RANGE_4GB)
- c2 = RANGE_4GB;
+ /* Clip the upper address to 4GiB if addresses above 4GiB
+ * are not being processed. */
+ if (!var_state->above4gb && c2 > RANGE_4GB)
+ c2 = RANGE_4GB;
- /* Don't align up or down on the range if it is smaller
- * than the minimum granularity. */
- if ((c2 - a1) < MTRR_MIN_ALIGN) {
- calc_var_mtrr_range(var_state, a1, c2 - a1, mtrr_type);
- continue;
- }
+ /* Don't align up or down on the range if it is smaller
+ * than the minimum granularity. */
+ if ((c2 - a1) < MTRR_MIN_ALIGN) {
+ calc_var_mtrr_range(var_state, a1, c2 - a1, mtrr_type);
+ return;
+ }
- b1 = a2 = ALIGN_UP(a1, MTRR_MIN_ALIGN);
- b2 = c1 = ALIGN_DOWN(c2, MTRR_MIN_ALIGN);
+ b1 = a2 = ALIGN_UP(a1, MTRR_MIN_ALIGN);
+ b2 = c1 = ALIGN_DOWN(c2, MTRR_MIN_ALIGN);
- calc_var_mtrr_range(var_state, a1, a2 - a1, mtrr_type);
- calc_var_mtrr_range(var_state, b1, b2 - b1, mtrr_type);
- calc_var_mtrr_range(var_state, c1, c2 - c1, mtrr_type);
- }
+ calc_var_mtrr_range(var_state, a1, a2 - a1, mtrr_type);
+ calc_var_mtrr_range(var_state, b1, b2 - b1, mtrr_type);
+ calc_var_mtrr_range(var_state, c1, c2 - c1, mtrr_type);
}
static int calc_var_mtrrs(struct memranges *addr_space,
@@ -560,6 +636,7 @@ static int calc_var_mtrrs(struct memranges *addr_space,
{
int wb_deftype_count;
int uc_deftype_count;
+ struct range_entry *r;
struct var_mtrr_state var_state;
/* The default MTRR cacheability type is determined by calculating
@@ -570,15 +647,67 @@ static int calc_var_mtrrs(struct memranges *addr_space,
var_state.address_bits = address_bits;
var_state.commit_mtrrs = 0;
- var_state.mtrr_index = 0;
- var_state.def_mtrr_type = MTRR_TYPE_WRBACK;
- setup_var_mtrrs_by_state(&var_state);
- wb_deftype_count = var_state.mtrr_index;
+ wb_deftype_count = 0;
+ uc_deftype_count = 0;
- var_state.mtrr_index = 0;
- var_state.def_mtrr_type = MTRR_TYPE_UNCACHEABLE;
- setup_var_mtrrs_by_state(&var_state);
- uc_deftype_count = var_state.mtrr_index;
+ /*
+ * For each range do 3 calculations:
+ * 1. UC as default type with no holes at top of range.
+ * 2. UC as default using holes at top of range.
+ * 3. WB as default.
+ * The lowest count is then used as default after totalling all
+ * MTRRs. Note that the optimal algoirthm for UC default is marked in
+ * the tag of each range regardless of final decision. UC takes
+ * precedence in the MTRR archiecture. Therefore, only holes can be
+ * used when the type of the region is MTRR_TYPE_WRBACK with
+ * MTRR_TYPE_UNCACHEABLE as the default type.
+ */
+ memranges_each_entry(r, var_state.addr_space) {
+ int mtrr_type;
+
+ mtrr_type = range_entry_mtrr_type(r);
+
+ if (mtrr_type != MTRR_TYPE_UNCACHEABLE) {
+ int uc_hole_count;
+ int uc_no_hole_count;
+
+ var_state.def_mtrr_type = MTRR_TYPE_UNCACHEABLE;
+ var_state.mtrr_index = 0;
+
+ /* No hole calculation. */
+ calc_var_mtrrs_without_hole(&var_state, r);
+ uc_no_hole_count = var_state.mtrr_index;
+
+ /* Hole calculation only if type is WB. The 64 number
+ * is a count that is unachievable, thus making it
+ * a default large number in the case of not doing
+ * the hole calculation. */
+ uc_hole_count = 64;
+ if (mtrr_type == MTRR_TYPE_WRBACK) {
+ var_state.mtrr_index = 0;
+ calc_var_mtrrs_with_hole(&var_state, r);
+ uc_hole_count = var_state.mtrr_index;
+ }
+
+ /* Mark the entry with the optimal algorithm. */
+ if (uc_no_hole_count < uc_hole_count) {
+ uc_deftype_count += uc_no_hole_count;
+ } else {
+ unsigned long new_tag;
+
+ new_tag = mtrr_type | MTRR_RANGE_UC_USE_HOLE;
+ range_entry_update_tag(r, new_tag);
+ uc_deftype_count += uc_hole_count;
+ }
+ }
+
+ if (mtrr_type != MTRR_TYPE_WRBACK) {
+ var_state.mtrr_index = 0;
+ var_state.def_mtrr_type = MTRR_TYPE_WRBACK;
+ calc_var_mtrrs_without_hole(&var_state, r);
+ wb_deftype_count += var_state.mtrr_index;
+ }
+ }
printk(BIOS_DEBUG, "MTRR: default type WB/UC MTRR counts: %d/%d.\n",
wb_deftype_count, uc_deftype_count);
@@ -594,6 +723,7 @@ static int calc_var_mtrrs(struct memranges *addr_space,
static void commit_var_mtrrs(struct memranges *addr_space, int def_type,
int above4gb, int address_bits)
{
+ struct range_entry *r;
struct var_mtrr_state var_state;
int i;
@@ -604,7 +734,17 @@ static void commit_var_mtrrs(struct memranges *addr_space, int def_type,
var_state.commit_mtrrs = 1;
var_state.mtrr_index = 0;
var_state.def_mtrr_type = def_type;
- setup_var_mtrrs_by_state(&var_state);
+
+ memranges_each_entry(r, var_state.addr_space) {
+ if (range_entry_mtrr_type(r) == def_type)
+ continue;
+
+ if (def_type == MTRR_TYPE_UNCACHEABLE &&
+ (range_entry_tag(r) & MTRR_RANGE_UC_USE_HOLE))
+ calc_var_mtrrs_with_hole(&var_state, r);
+ else
+ calc_var_mtrrs_without_hole(&var_state, r);
+ }
/* Clear all remaining variable MTTRs. */
for (i = var_state.mtrr_index; i < total_mtrrs; i++)