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|
/*
* mtrr.c: setting MTRR to decent values for cache initialization on P6
*
* Derived from intel_set_mtrr in intel_subr.c and mtrr.c in linux kernel
*
* Copyright 2000 Silicon Integrated System Corporation
* Copyright 2013 Google Inc.
*
* 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 of the License, or
* (at your option) any later version.
*
* 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.
*
*
* Reference: Intel Architecture Software Developer's Manual, Volume 3: System Programming
*/
#include <stddef.h>
#include <stdlib.h>
#include <string.h>
#include <bootstate.h>
#include <console/console.h>
#include <device/device.h>
#include <device/pci_ids.h>
#include <cpu/cpu.h>
#include <cpu/x86/msr.h>
#include <cpu/x86/mtrr.h>
#include <cpu/x86/cache.h>
#include <cpu/x86/lapic.h>
#include <arch/cpu.h>
#include <arch/acpi.h>
#include <memrange.h>
#if CONFIG_X86_AMD_FIXED_MTRRS
#include <cpu/amd/mtrr.h>
#define MTRR_FIXED_WRBACK_BITS (MTRR_READ_MEM | MTRR_WRITE_MEM)
#else
#define MTRR_FIXED_WRBACK_BITS 0
#endif
/* 2 MTRRS are reserved for the operating system */
#define BIOS_MTRRS 6
#define OS_MTRRS 2
#define MTRRS (BIOS_MTRRS + OS_MTRRS)
/*
* Static storage size for variable MTRRs. It's sized sufficiently large to
* handle different types of CPUs. Empirically, 16 variable MTRRs has not
* yet been observed.
*/
#define NUM_MTRR_STATIC_STORAGE 16
static int total_mtrrs = MTRRS;
static int bios_mtrrs = BIOS_MTRRS;
static void detect_var_mtrrs(void)
{
msr_t msr;
msr = rdmsr(MTRR_CAP_MSR);
total_mtrrs = msr.lo & 0xff;
if (total_mtrrs > NUM_MTRR_STATIC_STORAGE) {
printk(BIOS_WARNING,
"MTRRs detected (%d) > NUM_MTRR_STATIC_STORAGE (%d)\n",
total_mtrrs, NUM_MTRR_STATIC_STORAGE);
total_mtrrs = NUM_MTRR_STATIC_STORAGE;
}
bios_mtrrs = total_mtrrs - OS_MTRRS;
}
void enable_fixed_mtrr(void)
{
msr_t msr;
msr = rdmsr(MTRR_DEF_TYPE_MSR);
msr.lo |= MTRR_DEF_TYPE_EN | MTRR_DEF_TYPE_FIX_EN;
wrmsr(MTRR_DEF_TYPE_MSR, msr);
}
static void enable_var_mtrr(unsigned char deftype)
{
msr_t msr;
msr = rdmsr(MTRR_DEF_TYPE_MSR);
msr.lo &= ~0xff;
msr.lo |= MTRR_DEF_TYPE_EN | deftype;
wrmsr(MTRR_DEF_TYPE_MSR, msr);
}
#define MTRR_VERBOSE_LEVEL BIOS_NEVER
/* MTRRs are at a 4KiB granularity. Therefore all address calculations can
* be done with 32-bit numbers. This allows for the MTRR code to handle
* up to 2^44 bytes (16 TiB) of address space. */
#define RANGE_SHIFT 12
#define ADDR_SHIFT_TO_RANGE_SHIFT(x) \
(((x) > RANGE_SHIFT) ? ((x) - RANGE_SHIFT) : RANGE_SHIFT)
#define PHYS_TO_RANGE_ADDR(x) ((x) >> RANGE_SHIFT)
#define RANGE_TO_PHYS_ADDR(x) (((resource_t)(x)) << RANGE_SHIFT)
#define NUM_FIXED_MTRRS (NUM_FIXED_RANGES / RANGES_PER_FIXED_MTRR)
/* The minimum alignment while handling variable MTRR ranges is 64MiB. */
#define MTRR_MIN_ALIGN PHYS_TO_RANGE_ADDR(64 << 20)
/* Helpful constants. */
#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));
}
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 int filter_vga_wrcomb(struct device *dev, struct resource *res)
{
/* Only handle PCI devices. */
if (dev->path.type != DEVICE_PATH_PCI)
return 0;
/* Only handle VGA class devices. */
if (((dev->class >> 8) != PCI_CLASS_DISPLAY_VGA))
return 0;
/* Add resource as write-combining in the address space. */
return 1;
}
static void print_physical_address_space(const struct memranges *addr_space,
const char *identifier)
{
const struct range_entry *r;
if (identifier)
printk(BIOS_DEBUG, "MTRR: %s Physical address space:\n",
identifier);
else
printk(BIOS_DEBUG, "MTRR: Physical address space:\n");
memranges_each_entry(r, addr_space)
printk(BIOS_DEBUG,
"0x%016llx - 0x%016llx size 0x%08llx type %ld\n",
range_entry_base(r), range_entry_end(r),
range_entry_size(r), range_entry_tag(r));
}
static struct memranges *get_physical_address_space(void)
{
static struct memranges *addr_space;
static struct memranges addr_space_storage;
/* In order to handle some chipsets not being able to pre-determine
* uncacheable ranges, such as graphics memory, at resource insertion
* time remove uncacheable regions from the cacheable ones. */
if (addr_space == NULL) {
unsigned long mask;
unsigned long match;
addr_space = &addr_space_storage;
mask = IORESOURCE_CACHEABLE;
/* Collect cacheable and uncacheable address ranges. The
* uncacheable regions take precedence over the cacheable
* regions. */
memranges_init(addr_space, mask, mask, MTRR_TYPE_WRBACK);
memranges_add_resources(addr_space, mask, 0,
MTRR_TYPE_UNCACHEABLE);
/* Handle any write combining resources. Only prefetchable
* resources are appropriate for this MTRR type. */
match = IORESOURCE_PREFETCH;
mask |= match;
memranges_add_resources_filter(addr_space, mask, match, MTRR_TYPE_WRCOMB,
filter_vga_wrcomb);
/* The address space below 4GiB is special. It needs to be
* covered entirely by range entries so that MTRR calculations
* can be properly done for the full 32-bit address space.
* Therefore, ensure holes are filled up to 4GiB as
* uncacheable */
memranges_fill_holes_up_to(addr_space,
RANGE_TO_PHYS_ADDR(RANGE_4GB),
MTRR_TYPE_UNCACHEABLE);
print_physical_address_space(addr_space, NULL);
}
return addr_space;
}
/* Fixed MTRR descriptor. This structure defines the step size and begin
* and end (exclusive) address covered by a set of fixed MTRR MSRs.
* It also describes the offset in byte intervals to store the calculated MTRR
* type in an array. */
struct fixed_mtrr_desc {
uint32_t begin;
uint32_t end;
uint32_t step;
int range_index;
int msr_index_base;
};
/* Shared MTRR calculations. Can be reused by APs. */
static uint8_t fixed_mtrr_types[NUM_FIXED_RANGES];
/* Fixed MTRR descriptors. */
static const struct fixed_mtrr_desc fixed_mtrr_desc[] = {
{ PHYS_TO_RANGE_ADDR(0x000000), PHYS_TO_RANGE_ADDR(0x080000),
PHYS_TO_RANGE_ADDR(64 * 1024), 0, MTRR_FIX_64K_00000 },
{ PHYS_TO_RANGE_ADDR(0x080000), PHYS_TO_RANGE_ADDR(0x0C0000),
PHYS_TO_RANGE_ADDR(16 * 1024), 8, MTRR_FIX_16K_80000 },
{ PHYS_TO_RANGE_ADDR(0x0C0000), PHYS_TO_RANGE_ADDR(0x100000),
PHYS_TO_RANGE_ADDR(4 * 1024), 24, MTRR_FIX_4K_C0000 },
};
static void calc_fixed_mtrrs(void)
{
static int fixed_mtrr_types_initialized;
struct memranges *phys_addr_space;
struct range_entry *r;
const struct fixed_mtrr_desc *desc;
const struct fixed_mtrr_desc *last_desc;
uint32_t begin;
uint32_t end;
int type_index;
if (fixed_mtrr_types_initialized)
return;
phys_addr_space = get_physical_address_space();
/* Set all fixed ranges to uncacheable first. */
memset(&fixed_mtrr_types[0], MTRR_TYPE_UNCACHEABLE, NUM_FIXED_RANGES);
desc = &fixed_mtrr_desc[0];
last_desc = &fixed_mtrr_desc[ARRAY_SIZE(fixed_mtrr_desc) - 1];
memranges_each_entry(r, phys_addr_space) {
begin = range_entry_base_mtrr_addr(r);
end = range_entry_end_mtrr_addr(r);
if (begin >= last_desc->end)
break;
if (end > last_desc->end)
end = last_desc->end;
/* Get to the correct fixed mtrr descriptor. */
while (begin >= desc->end)
desc++;
type_index = desc->range_index;
type_index += (begin - desc->begin) / desc->step;
while (begin != end) {
unsigned char type;
type = range_entry_tag(r);
printk(MTRR_VERBOSE_LEVEL,
"MTRR addr 0x%x-0x%x set to %d type @ %d\n",
begin, begin + desc->step, type, type_index);
if (type == MTRR_TYPE_WRBACK)
type |= MTRR_FIXED_WRBACK_BITS;
fixed_mtrr_types[type_index] = type;
type_index++;
begin += desc->step;
if (begin == desc->end)
desc++;
}
}
fixed_mtrr_types_initialized = 1;
}
static void commit_fixed_mtrrs(void)
{
int i;
int j;
int msr_num;
int type_index;
/* 8 ranges per msr. */
msr_t fixed_msrs[NUM_FIXED_MTRRS];
unsigned long msr_index[NUM_FIXED_MTRRS];
memset(&fixed_msrs, 0, sizeof(fixed_msrs));
msr_num = 0;
type_index = 0;
for (i = 0; i < ARRAY_SIZE(fixed_mtrr_desc); i++) {
const struct fixed_mtrr_desc *desc;
int num_ranges;
desc = &fixed_mtrr_desc[i];
num_ranges = (desc->end - desc->begin) / desc->step;
for (j = 0; j < num_ranges; j += RANGES_PER_FIXED_MTRR) {
msr_index[msr_num] = desc->msr_index_base +
(j / RANGES_PER_FIXED_MTRR);
fixed_msrs[msr_num].lo |=
fixed_mtrr_types[type_index++] << 0;
fixed_msrs[msr_num].lo |=
fixed_mtrr_types[type_index++] << 8;
fixed_msrs[msr_num].lo |=
fixed_mtrr_types[type_index++] << 16;
fixed_msrs[msr_num].lo |=
fixed_mtrr_types[type_index++] << 24;
fixed_msrs[msr_num].hi |=
fixed_mtrr_types[type_index++] << 0;
fixed_msrs[msr_num].hi |=
fixed_mtrr_types[type_index++] << 8;
fixed_msrs[msr_num].hi |=
fixed_mtrr_types[type_index++] << 16;
fixed_msrs[msr_num].hi |=
fixed_mtrr_types[type_index++] << 24;
msr_num++;
}
}
for (i = 0; i < ARRAY_SIZE(fixed_msrs); i++)
printk(BIOS_DEBUG, "MTRR: Fixed MSR 0x%lx 0x%08x%08x\n",
msr_index[i], fixed_msrs[i].hi, fixed_msrs[i].lo);
disable_cache();
for (i = 0; i < ARRAY_SIZE(fixed_msrs); i++)
wrmsr(msr_index[i], fixed_msrs[i]);
enable_cache();
}
void x86_setup_fixed_mtrrs_no_enable(void)
{
calc_fixed_mtrrs();
commit_fixed_mtrrs();
}
void x86_setup_fixed_mtrrs(void)
{
x86_setup_fixed_mtrrs_no_enable();
printk(BIOS_SPEW, "call enable_fixed_mtrr()\n");
enable_fixed_mtrr();
}
struct var_mtrr_regs {
msr_t base;
msr_t mask;
};
struct var_mtrr_solution {
int mtrr_default_type;
int num_used;
struct var_mtrr_regs regs[NUM_MTRR_STATIC_STORAGE];
};
/* Global storage for variable MTRR solution. */
static struct var_mtrr_solution mtrr_global_solution;
struct var_mtrr_state {
struct memranges *addr_space;
int above4gb;
int address_bits;
int prepare_msrs;
int mtrr_index;
int def_mtrr_type;
struct var_mtrr_regs *regs;
};
static void clear_var_mtrr(int index)
{
msr_t msr = { .lo = 0, .hi = 0 };
wrmsr(MTRR_PHYS_BASE(index), msr);
wrmsr(MTRR_PHYS_MASK(index), msr);
}
static void prep_var_mtrr(struct var_mtrr_state *var_state,
uint32_t base, uint32_t size, int mtrr_type)
{
struct var_mtrr_regs *regs;
resource_t rbase;
resource_t rsize;
resource_t mask;
/* Some variable MTRRs are attempted to be saved for the OS use.
* However, it's more important to try to map the full address space
* properly. */
if (var_state->mtrr_index >= bios_mtrrs)
printk(BIOS_WARNING, "Taking a reserved OS MTRR.\n");
if (var_state->mtrr_index >= total_mtrrs) {
printk(BIOS_ERR, "ERROR: Not enough MTRRs available! MTRR index"
"is %d with %d MTTRs in total.\n",
var_state->mtrr_index, total_mtrrs);
return;
}
rbase = base;
rsize = size;
rbase = RANGE_TO_PHYS_ADDR(rbase);
rsize = RANGE_TO_PHYS_ADDR(rsize);
rsize = -rsize;
mask = (1ULL << var_state->address_bits) - 1;
rsize = rsize & mask;
printk(BIOS_DEBUG, "MTRR: %d base 0x%016llx mask 0x%016llx type %d\n",
var_state->mtrr_index, rbase, rsize, mtrr_type);
regs = &var_state->regs[var_state->mtrr_index];
regs->base.lo = rbase;
regs->base.lo |= mtrr_type;
regs->base.hi = rbase >> 32;
regs->mask.lo = rsize;
regs->mask.lo |= MTRR_PHYS_MASK_VALID;
regs->mask.hi = rsize >> 32;
}
static void calc_var_mtrr_range(struct var_mtrr_state *var_state,
uint32_t base, uint32_t size, int mtrr_type)
{
while (size != 0) {
uint32_t addr_lsb;
uint32_t size_msb;
uint32_t mtrr_size;
addr_lsb = fls(base);
size_msb = fms(size);
/* All MTRR entries need to have their base aligned to the mask
* size. The maximum size is calculated by a function of the
* min base bit set and maximum size bit set. */
if (addr_lsb > size_msb)
mtrr_size = 1 << size_msb;
else
mtrr_size = 1 << addr_lsb;
if (var_state->prepare_msrs)
prep_var_mtrr(var_state, base, mtrr_size, mtrr_type);
size -= mtrr_size;
base += mtrr_size;
var_state->mtrr_index++;
}
}
static void calc_var_mtrrs_with_hole(struct var_mtrr_state *var_state,
struct range_entry *r)
{
uint32_t a1, a2, b1, b2;
int mtrr_type;
struct range_entry *next;
/*
* Determine MTRRs based on the following algorithm 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 within the first 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 at or 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;
next = memranges_next_entry(var_state->addr_space, r);
b1 = a2;
/* First check if a1 is >= 4GiB and the current entry is the last
* entry. If so perform an optimization of covering a larger range
* defined by the base address' alignment. */
if (a1 >= RANGE_4GB && next == NULL) {
uint32_t addr_lsb;
addr_lsb = fls(a1);
b2 = (1 << addr_lsb) + a1;
if (b2 >= a2) {
calc_var_mtrr_range(var_state, a1, b2 - a1, mtrr_type);
return;
}
}
/* Handle the min alignment roundup case. */
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. */
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
* following manner:
* +------------------+ c2 = end
* | 0 or more bytes |
* +------------------+ b2 = c1 = ALIGN_DOWN(end)
* | |
* +------------------+ b1 = a2 = ALIGN_UP(begin)
* | 0 or more bytes |
* +------------------+ 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);
c2 = range_entry_end_mtrr_addr(r);
/* The end address is within the first 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 at or 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 && 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);
return;
}
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);
}
static void __calc_var_mtrrs(struct memranges *addr_space,
int above4gb, int address_bits,
int *num_def_wb_mtrrs, int *num_def_uc_mtrrs)
{
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
* the number of MTRRs required for each MTRR type as if it was the
* default. */
var_state.addr_space = addr_space;
var_state.above4gb = above4gb;
var_state.address_bits = address_bits;
var_state.prepare_msrs = 0;
wb_deftype_count = 0;
uc_deftype_count = 0;
/*
* 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 totaling all
* MTRRs. Note that the optimal algorithm for UC default is marked in
* the tag of each range regardless of final decision. UC takes
* precedence in the MTRR architecture. 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;
}
}
*num_def_wb_mtrrs = wb_deftype_count;
*num_def_uc_mtrrs = uc_deftype_count;
}
static int calc_var_mtrrs(struct memranges *addr_space,
int above4gb, int address_bits)
{
int wb_deftype_count = 0;
int uc_deftype_count = 0;
__calc_var_mtrrs(addr_space, above4gb, address_bits, &wb_deftype_count,
&uc_deftype_count);
if (wb_deftype_count > bios_mtrrs && uc_deftype_count > bios_mtrrs) {
printk(BIOS_DEBUG, "MTRR: Removing WRCOMB type. "
"WB/UC MTRR counts: %d/%d > %d.\n",
wb_deftype_count, uc_deftype_count, bios_mtrrs);
memranges_update_tag(addr_space, MTRR_TYPE_WRCOMB,
MTRR_TYPE_UNCACHEABLE);
__calc_var_mtrrs(addr_space, above4gb, address_bits,
&wb_deftype_count, &uc_deftype_count);
}
printk(BIOS_DEBUG, "MTRR: default type WB/UC MTRR counts: %d/%d.\n",
wb_deftype_count, uc_deftype_count);
if (wb_deftype_count < uc_deftype_count) {
printk(BIOS_DEBUG, "MTRR: WB selected as default type.\n");
return MTRR_TYPE_WRBACK;
}
printk(BIOS_DEBUG, "MTRR: UC selected as default type.\n");
return MTRR_TYPE_UNCACHEABLE;
}
static void prepare_var_mtrrs(struct memranges *addr_space, int def_type,
int above4gb, int address_bits,
struct var_mtrr_solution *sol)
{
struct range_entry *r;
struct var_mtrr_state var_state;
var_state.addr_space = addr_space;
var_state.above4gb = above4gb;
var_state.address_bits = address_bits;
/* Prepare the MSRs. */
var_state.prepare_msrs = 1;
var_state.mtrr_index = 0;
var_state.def_mtrr_type = def_type;
var_state.regs = &sol->regs[0];
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);
}
/* Update the solution. */
sol->num_used = var_state.mtrr_index;
}
static void commit_var_mtrrs(const struct var_mtrr_solution *sol)
{
int i;
/* Write out the variable MTRRs. */
disable_cache();
for (i = 0; i < sol->num_used; i++) {
wrmsr(MTRR_PHYS_BASE(i), sol->regs[i].base);
wrmsr(MTRR_PHYS_MASK(i), sol->regs[i].mask);
}
/* Clear the ones that are unused. */
for (; i < total_mtrrs; i++)
clear_var_mtrr(i);
enable_var_mtrr(sol->mtrr_default_type);
enable_cache();
}
void x86_setup_var_mtrrs(unsigned int address_bits, unsigned int above4gb)
{
static struct var_mtrr_solution *sol = NULL;
struct memranges *addr_space;
addr_space = get_physical_address_space();
if (sol == NULL) {
sol = &mtrr_global_solution;
sol->mtrr_default_type =
calc_var_mtrrs(addr_space, !!above4gb, address_bits);
prepare_var_mtrrs(addr_space, sol->mtrr_default_type,
!!above4gb, address_bits, sol);
}
commit_var_mtrrs(sol);
}
void x86_setup_mtrrs(void)
{
int address_size;
x86_setup_fixed_mtrrs();
address_size = cpu_phys_address_size();
printk(BIOS_DEBUG, "CPU physical address size: %d bits\n",
address_size);
/* Always handle addresses above 4GiB. */
x86_setup_var_mtrrs(address_size, 1);
}
void x86_setup_mtrrs_with_detect(void)
{
detect_var_mtrrs();
x86_setup_mtrrs();
}
void x86_mtrr_check(void)
{
/* Only Pentium Pro and later have MTRR */
msr_t msr;
printk(BIOS_DEBUG, "\nMTRR check\n");
msr = rdmsr(MTRR_DEF_TYPE_MSR);
printk(BIOS_DEBUG, "Fixed MTRRs : ");
if (msr.lo & MTRR_DEF_TYPE_FIX_EN)
printk(BIOS_DEBUG, "Enabled\n");
else
printk(BIOS_DEBUG, "Disabled\n");
printk(BIOS_DEBUG, "Variable MTRRs: ");
if (msr.lo & MTRR_DEF_TYPE_EN)
printk(BIOS_DEBUG, "Enabled\n");
else
printk(BIOS_DEBUG, "Disabled\n");
printk(BIOS_DEBUG, "\n");
post_code(0x93);
}
static bool put_back_original_solution;
void mtrr_use_temp_range(uintptr_t begin, size_t size, int type)
{
const struct range_entry *r;
const struct memranges *orig;
struct var_mtrr_solution sol;
struct memranges addr_space;
const int above4gb = 1; /* Cover above 4GiB by default. */
int address_bits;
/* Make a copy of the original address space and tweak it with the
* provided range. */
memranges_init_empty(&addr_space, NULL, 0);
orig = get_physical_address_space();
memranges_each_entry(r, orig) {
unsigned long tag = range_entry_tag(r);
/* Remove any special tags from original solution. */
tag &= ~MTRR_RANGE_UC_USE_HOLE;
/* Remove any write combining MTRRs from the temporary
* solution as it just fragments the address space. */
if (tag == MTRR_TYPE_WRCOMB)
tag = MTRR_TYPE_UNCACHEABLE;
memranges_insert(&addr_space, range_entry_base(r),
range_entry_size(r), tag);
}
/* Place new range into the address space. */
memranges_insert(&addr_space, begin, size, type);
print_physical_address_space(&addr_space, "TEMPORARY");
/* Calculate a new solution with the updated address space. */
address_bits = cpu_phys_address_size();
memset(&sol, 0, sizeof(sol));
sol.mtrr_default_type =
calc_var_mtrrs(&addr_space, above4gb, address_bits);
prepare_var_mtrrs(&addr_space, sol.mtrr_default_type,
above4gb, address_bits, &sol);
commit_var_mtrrs(&sol);
memranges_teardown(&addr_space);
put_back_original_solution = true;
}
static void remove_temp_solution(void *unused)
{
if (put_back_original_solution)
commit_var_mtrrs(&mtrr_global_solution);
}
BOOT_STATE_INIT_ENTRY(BS_OS_RESUME, BS_ON_ENTRY, remove_temp_solution, NULL);
BOOT_STATE_INIT_ENTRY(BS_PAYLOAD_LOAD, BS_ON_EXIT, remove_temp_solution, NULL);
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