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acrn-hypervisor/hypervisor/arch/x86/e820.c
Victor Sun 9dfac7a7a3 HV: init hv_e820 from efi mmap if boot from uefi 
Hypervisor use e820_alloc_memory() api to allocate memory for trampoline code
and ept pages, whereas the usable ram in hv_e820 might include efi boot service
region if system boot from uefi environment, this would result in some uefi
service broken in SOS. These boot service region should be filtered from
hv_e820.
This patch will parse the efi memory descriptor entries info from efi memory
map pointer when system boot from uefi environment, and then initialize hv_e820
accordingly, that all efi boot service region would be kept as reserved in
hv_e820.

Please note the original efi memory map could be above 4GB address space,
so the efi memory parsing process must be done after enable_paging().

Tracked-On: #5626

Signed-off-by: Victor Sun <victor.sun@intel.com>
Reviewed-by: Jason Chen CJ <jason.cj.chen@intel.com>
2021-06-11 10:06:02 +08:00

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6.8 KiB
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/*
* Copyright (C) 2018 Intel Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <types.h>
#include <acrn_hv_defs.h>
#include <asm/page.h>
#include <asm/e820.h>
#include <asm/mmu.h>
#include <boot.h>
#include <efi_mmap.h>
#include <logmsg.h>
#include <asm/guest/ept.h>
/*
* e820.c contains the related e820 operations; like HV to get memory info for its MMU setup;
* and hide HV memory from SOS_VM...
*/
static uint32_t hv_e820_entries_nr;
/* Describe the memory layout the hypervisor uses */
static struct e820_entry hv_e820[E820_MAX_ENTRIES];
#define DBG_LEVEL_E820 6U
/*
* @brief reserve some RAM, hide it from sos_vm, return its start address
* @param size_arg Amount of memory to be found and marked reserved
* @param max_addr Maximum address below which memory is to be identified
*
* @pre hv_e820_entries_nr > 0U
* @pre (size_arg & 0xFFFU) == 0U
* @return base address of the memory region
*/
uint64_t e820_alloc_memory(uint32_t size_arg, uint64_t max_addr)
{
int32_t i;
uint64_t size = size_arg;
uint64_t ret = INVALID_HPA;
struct e820_entry *entry, *new_entry;
for (i = (int32_t)hv_e820_entries_nr - 1; i >= 0; i--) {
entry = &hv_e820[i];
uint64_t start, end, length;
start = round_page_up(entry->baseaddr);
end = round_page_down(entry->baseaddr + entry->length);
length = (end > start) ? (end - start) : 0UL;
if ((entry->type == E820_TYPE_RAM) && (length >= size) && ((start + size) <= max_addr)) {
/* found exact size of e820 entry */
if (length == size) {
entry->type = E820_TYPE_RESERVED;
ret = start;
} else {
/*
* found entry with available memory larger than requested (length > size)
* Reserve memory if
* 1) hv_e820_entries_nr < E820_MAX_ENTRIES
* 2) if end of this "entry" is <= max_addr
* use memory from end of this e820 "entry".
*/
if ((hv_e820_entries_nr < E820_MAX_ENTRIES) && (end <= max_addr)) {
new_entry = &hv_e820[hv_e820_entries_nr];
new_entry->type = E820_TYPE_RESERVED;
new_entry->baseaddr = end - size;
new_entry->length = (entry->baseaddr + entry->length) - new_entry->baseaddr;
/* Shrink the existing entry and total available memory */
entry->length -= new_entry->length;
hv_e820_entries_nr++;
ret = new_entry->baseaddr;
}
}
if (ret != INVALID_HPA) {
break;
}
}
}
if ((ret == INVALID_HPA) || (ret == 0UL)) {
/* current memory allocation algorithm is to find the available address from the highest
* possible address below max_addr. if ret == 0, means all memory is used up and we have to
* put the resource at address 0, this is dangerous.
* Also ret == 0 would make code logic very complicated, since memcpy_s() doesn't support
* address 0 copy.
*/
panic("Requested memory from E820 cannot be reserved!!");
}
return ret;
}
static void init_e820_from_efi_mmap(void)
{
uint32_t i, e820_idx = 0U;
uint64_t top_addr_space = CONFIG_PLATFORM_RAM_SIZE + PLATFORM_LO_MMIO_SIZE;
const struct efi_memory_desc *efi_mmap_entry = get_efi_mmap_entry();
for (i = 0U; i < get_efi_mmap_entries_count(); i++) {
if (e820_idx >= E820_MAX_ENTRIES) {
pr_err("Too many efi memmap entries !");
break;
}
hv_e820[e820_idx].baseaddr = efi_mmap_entry[i].phys_addr;
hv_e820[e820_idx].length = efi_mmap_entry[i].num_pages * PAGE_SIZE;
if (hv_e820[e820_idx].baseaddr >= top_addr_space) {
hv_e820[e820_idx].length = 0UL;
} else {
if ((hv_e820[e820_idx].baseaddr + hv_e820[e820_idx].length) > top_addr_space) {
hv_e820[e820_idx].length = top_addr_space - hv_e820[e820_idx].baseaddr;
}
}
/* The EFI BOOT Service releated regions need to be set to reserved and avoid being touched by
* hypervisor, because at least below software modules rely on them:
* 1. EFI ESRT(The EFI System Resource Table) which used for UEFI firmware upgrade;
* 2. Image resource in ACPI BGRT(Boottime Graphics Resource Table) which used for boot time logo;
*/
switch (efi_mmap_entry[i].type) {
case EFI_LOADER_CODE:
case EFI_LOADER_DATA:
case EFI_CONVENTIONAL_MEMORY:
if ((efi_mmap_entry[i].attribute & EFI_MEMORY_WB) != 0UL) {
hv_e820[e820_idx].type = E820_TYPE_RAM;
} else {
hv_e820[e820_idx].type = E820_TYPE_RESERVED;
}
break;
case EFI_UNUSABLE_MEMORY:
hv_e820[e820_idx].type = E820_TYPE_UNUSABLE;
break;
case EFI_ACPI_RECLAIM_MEMORY:
hv_e820[e820_idx].type = E820_TYPE_ACPI_RECLAIM;
break;
case EFI_ACPI_MEMORY_NVS:
hv_e820[e820_idx].type = E820_TYPE_ACPI_NVS;
break;
/* case EFI_RESERVED_MEMORYTYPE:
* case EFI_BOOT_SERVICES_CODE:
* case EFI_BOOT_SERVICES_DATA:
* case EFI_RUNTIME_SERVICES_CODE:
* case EFI_RUNTIME_SERVICES_DATA:
* case EFI_MEMORYMAPPED_IO:
* case EFI_MEMORYMAPPED_IOPORTSPACE:
* case EFI_PALCODE:
* case EFI_PERSISTENT_MEMORY:
*/
default:
hv_e820[e820_idx].type = E820_TYPE_RESERVED;
break;
}
/* Given the efi memmap has been sorted, the hv_e820[] is also sorted.
* Then the algorithm is very simple, just merge with previous mmap entry
* if type is same and base addr is continuous.
*/
if ((e820_idx > 0U) && (hv_e820[e820_idx].type == hv_e820[e820_idx - 1U].type)
&& (hv_e820[e820_idx].baseaddr ==
(hv_e820[e820_idx - 1U].baseaddr
+ hv_e820[e820_idx - 1U].length))) {
hv_e820[e820_idx - 1U].length += hv_e820[e820_idx].length;
} else {
dev_dbg(DBG_LEVEL_E820, "efi mmap hv_e820[%d]: type: 0x%x Base: 0x%016lx length: 0x%016lx",
e820_idx, hv_e820[e820_idx].type, hv_e820[e820_idx].baseaddr, hv_e820[e820_idx].length);
e820_idx ++;
}
}
hv_e820_entries_nr = e820_idx;
}
/* HV read multiboot header to get e820 entries info and calc total RAM info */
static void init_e820_from_mmap(struct acrn_boot_info *abi)
{
uint32_t i;
uint64_t top_addr_space = CONFIG_PLATFORM_RAM_SIZE + PLATFORM_LO_MMIO_SIZE;
struct abi_mmap *mmap = abi->mmap_entry;
hv_e820_entries_nr = abi->mmap_entries;
dev_dbg(DBG_LEVEL_E820, "mmap addr 0x%x entries %d\n",
abi->mmap_entry, hv_e820_entries_nr);
for (i = 0U; i < hv_e820_entries_nr; i++) {
if (mmap[i].baseaddr >= top_addr_space) {
mmap[i].length = 0UL;
} else {
if ((mmap[i].baseaddr + mmap[i].length) > top_addr_space) {
mmap[i].length = top_addr_space - mmap[i].baseaddr;
}
}
hv_e820[i].baseaddr = mmap[i].baseaddr;
hv_e820[i].length = mmap[i].length;
hv_e820[i].type = mmap[i].type;
dev_dbg(DBG_LEVEL_E820, "mmap hv_e820[%d]: type: 0x%x Base: 0x%016lx length: 0x%016lx", i,
mmap[i].type, mmap[i].baseaddr, mmap[i].length);
}
}
void init_e820(void)
{
struct acrn_boot_info *abi = get_acrn_boot_info();
if (boot_from_uefi(abi)) {
init_efi_mmap_entries(&abi->uefi_info);
init_e820_from_efi_mmap();
} else {
init_e820_from_mmap(abi);
}
}
uint32_t get_e820_entries_count(void)
{
return hv_e820_entries_nr;
}
const struct e820_entry *get_e820_entry(void)
{
return hv_e820;
}
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