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kernel / pub / scm / virt / kvm / qemu-kvm / refs/tags/qemu-kvm-0.11.1 / . / exec.c
blob: 0655b4b55dde41336e1f3906174c846124d58a7d [file] [log] [blame]
/*
* virtual page mapping and translated block handling
*
* Copyright (c) 2003 Fabrice Bellard
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
#include "config.h"
#ifdef _WIN32
#include <windows.h>
#else
#include <sys/types.h>
#include <sys/mman.h>
#endif
#include <stdlib.h>
#include <stdio.h>
#include <stdarg.h>
#include <string.h>
#include <errno.h>
#include <unistd.h>
#include <inttypes.h>
#include "cpu.h"
#include "exec-all.h"
#include "qemu-common.h"
#include "cache-utils.h"
#if !defined(TARGET_IA64)
#include "tcg.h"
#endif
#include "qemu-kvm.h"
#include "hw/hw.h"
#include "osdep.h"
#include "kvm.h"
#if defined(CONFIG_USER_ONLY)
#include <qemu.h>
#endif
//#define DEBUG_TB_INVALIDATE
//#define DEBUG_FLUSH
//#define DEBUG_TLB
//#define DEBUG_UNASSIGNED
/* make various TB consistency checks */
//#define DEBUG_TB_CHECK
//#define DEBUG_TLB_CHECK
//#define DEBUG_IOPORT
//#define DEBUG_SUBPAGE
#if !defined(CONFIG_USER_ONLY)
/* TB consistency checks only implemented for usermode emulation. */
#undef DEBUG_TB_CHECK
#endif
#define SMC_BITMAP_USE_THRESHOLD 10
#if defined(TARGET_SPARC64)
#define TARGET_PHYS_ADDR_SPACE_BITS 41
#elif defined(TARGET_SPARC)
#define TARGET_PHYS_ADDR_SPACE_BITS 36
#elif defined(TARGET_ALPHA)
#define TARGET_PHYS_ADDR_SPACE_BITS 42
#define TARGET_VIRT_ADDR_SPACE_BITS 42
#elif defined(TARGET_PPC64)
#define TARGET_PHYS_ADDR_SPACE_BITS 42
#elif defined(TARGET_X86_64) && !defined(CONFIG_KQEMU)
#define TARGET_PHYS_ADDR_SPACE_BITS 42
#elif defined(TARGET_I386) && !defined(CONFIG_KQEMU)
#define TARGET_PHYS_ADDR_SPACE_BITS 36
#elif defined(TARGET_IA64)
#define TARGET_PHYS_ADDR_SPACE_BITS 36
#else
/* Note: for compatibility with kqemu, we use 32 bits for x86_64 */
#define TARGET_PHYS_ADDR_SPACE_BITS 32
#endif
static TranslationBlock *tbs;
int code_gen_max_blocks;
TranslationBlock *tb_phys_hash[CODE_GEN_PHYS_HASH_SIZE];
static int nb_tbs;
/* any access to the tbs or the page table must use this lock */
spinlock_t tb_lock = SPIN_LOCK_UNLOCKED;
#if defined(__arm__) || defined(__sparc_v9__)
/* The prologue must be reachable with a direct jump. ARM and Sparc64
have limited branch ranges (possibly also PPC) so place it in a
section close to code segment. */
#define code_gen_section \
__attribute__((__section__(".gen_code"))) \
__attribute__((aligned (32)))
#elif defined(_WIN32)
/* Maximum alignment for Win32 is 16. */
#define code_gen_section \
__attribute__((aligned (16)))
#else
#define code_gen_section \
__attribute__((aligned (32)))
#endif
uint8_t code_gen_prologue[1024] code_gen_section;
static uint8_t *code_gen_buffer;
static unsigned long code_gen_buffer_size;
/* threshold to flush the translated code buffer */
static unsigned long code_gen_buffer_max_size;
uint8_t *code_gen_ptr;
#if !defined(CONFIG_USER_ONLY)
int phys_ram_fd;
uint8_t *phys_ram_dirty;
uint8_t *bios_mem;
static int in_migration;
typedef struct RAMBlock {
uint8_t *host;
ram_addr_t offset;
ram_addr_t length;
struct RAMBlock *next;
} RAMBlock;
static RAMBlock *ram_blocks;
/* TODO: When we implement (and use) ram deallocation (e.g. for hotplug)
then we can no longer assume contiguous ram offsets, and external uses
of this variable will break. */
ram_addr_t last_ram_offset;
#endif
CPUState *first_cpu;
/* current CPU in the current thread. It is only valid inside
cpu_exec() */
CPUState *cpu_single_env;
/* 0 = Do not count executed instructions.
1 = Precise instruction counting.
2 = Adaptive rate instruction counting. */
int use_icount = 0;
/* Current instruction counter. While executing translated code this may
include some instructions that have not yet been executed. */
int64_t qemu_icount;
typedef struct PageDesc {
/* list of TBs intersecting this ram page */
TranslationBlock *first_tb;
/* in order to optimize self modifying code, we count the number
of lookups we do to a given page to use a bitmap */
unsigned int code_write_count;
uint8_t *code_bitmap;
#if defined(CONFIG_USER_ONLY)
unsigned long flags;
#endif
} PageDesc;
typedef struct PhysPageDesc {
/* offset in host memory of the page + io_index in the low bits */
ram_addr_t phys_offset;
ram_addr_t region_offset;
} PhysPageDesc;
#define L2_BITS 10
#if defined(CONFIG_USER_ONLY) && defined(TARGET_VIRT_ADDR_SPACE_BITS)
/* XXX: this is a temporary hack for alpha target.
* In the future, this is to be replaced by a multi-level table
* to actually be able to handle the complete 64 bits address space.
*/
#define L1_BITS (TARGET_VIRT_ADDR_SPACE_BITS - L2_BITS - TARGET_PAGE_BITS)
#else
#define L1_BITS (32 - L2_BITS - TARGET_PAGE_BITS)
#endif
#define L1_SIZE (1 << L1_BITS)
#define L2_SIZE (1 << L2_BITS)
unsigned long qemu_real_host_page_size;
unsigned long qemu_host_page_bits;
unsigned long qemu_host_page_size;
unsigned long qemu_host_page_mask;
/* XXX: for system emulation, it could just be an array */
static PageDesc *l1_map[L1_SIZE];
static PhysPageDesc **l1_phys_map;
#if !defined(CONFIG_USER_ONLY)
static void io_mem_init(void);
/* io memory support */
CPUWriteMemoryFunc *io_mem_write[IO_MEM_NB_ENTRIES][4];
CPUReadMemoryFunc *io_mem_read[IO_MEM_NB_ENTRIES][4];
void *io_mem_opaque[IO_MEM_NB_ENTRIES];
static char io_mem_used[IO_MEM_NB_ENTRIES];
static int io_mem_watch;
#endif
/* log support */
static const char *logfilename = "/tmp/qemu.log";
FILE *logfile;
int loglevel;
static int log_append = 0;
/* statistics */
static int tlb_flush_count;
static int tb_flush_count;
static int tb_phys_invalidate_count;
#define SUBPAGE_IDX(addr) ((addr) & ~TARGET_PAGE_MASK)
typedef struct subpage_t {
target_phys_addr_t base;
CPUReadMemoryFunc **mem_read[TARGET_PAGE_SIZE][4];
CPUWriteMemoryFunc **mem_write[TARGET_PAGE_SIZE][4];
void *opaque[TARGET_PAGE_SIZE][2][4];
ram_addr_t region_offset[TARGET_PAGE_SIZE][2][4];
} subpage_t;
#ifdef _WIN32
static void map_exec(void *addr, long size)
{
DWORD old_protect;
VirtualProtect(addr, size,
PAGE_EXECUTE_READWRITE, &old_protect);
}
#else
static void map_exec(void *addr, long size)
{
unsigned long start, end, page_size;
page_size = getpagesize();
start = (unsigned long)addr;
start &= ~(page_size - 1);
end = (unsigned long)addr + size;
end += page_size - 1;
end &= ~(page_size - 1);
mprotect((void *)start, end - start,
PROT_READ | PROT_WRITE | PROT_EXEC);
}
#endif
static void page_init(void)
{
/* NOTE: we can always suppose that qemu_host_page_size >=
TARGET_PAGE_SIZE */
#ifdef _WIN32
{
SYSTEM_INFO system_info;
GetSystemInfo(&system_info);
qemu_real_host_page_size = system_info.dwPageSize;
}
#else
qemu_real_host_page_size = getpagesize();
#endif
if (qemu_host_page_size == 0)
qemu_host_page_size = qemu_real_host_page_size;
if (qemu_host_page_size < TARGET_PAGE_SIZE)
qemu_host_page_size = TARGET_PAGE_SIZE;
qemu_host_page_bits = 0;
while ((1 << qemu_host_page_bits) < qemu_host_page_size)
qemu_host_page_bits++;
qemu_host_page_mask = ~(qemu_host_page_size - 1);
l1_phys_map = qemu_vmalloc(L1_SIZE * sizeof(void *));
memset(l1_phys_map, 0, L1_SIZE * sizeof(void *));
#if !defined(_WIN32) && defined(CONFIG_USER_ONLY)
{
long long startaddr, endaddr;
FILE *f;
int n;
mmap_lock();
last_brk = (unsigned long)sbrk(0);
f = fopen("/proc/self/maps", "r");
if (f) {
do {
n = fscanf (f, "%llx-%llx %*[^\n]\n", &startaddr, &endaddr);
if (n == 2) {
startaddr = MIN(startaddr,
(1ULL << TARGET_PHYS_ADDR_SPACE_BITS) - 1);
endaddr = MIN(endaddr,
(1ULL << TARGET_PHYS_ADDR_SPACE_BITS) - 1);
page_set_flags(startaddr & TARGET_PAGE_MASK,
TARGET_PAGE_ALIGN(endaddr),
PAGE_RESERVED);
}
} while (!feof(f));
fclose(f);
}
mmap_unlock();
}
#endif
}
static inline PageDesc **page_l1_map(target_ulong index)
{
#if TARGET_LONG_BITS > 32
/* Host memory outside guest VM. For 32-bit targets we have already
excluded high addresses. */
if (index > ((target_ulong)L2_SIZE * L1_SIZE))
return NULL;
#endif
return &l1_map[index >> L2_BITS];
}
static inline PageDesc *page_find_alloc(target_ulong index)
{
PageDesc **lp, *p;
lp = page_l1_map(index);
if (!lp)
return NULL;
p = *lp;
if (!p) {
/* allocate if not found */
#if defined(CONFIG_USER_ONLY)
size_t len = sizeof(PageDesc) * L2_SIZE;
/* Don't use qemu_malloc because it may recurse. */
p = mmap(NULL, len, PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
*lp = p;
if (h2g_valid(p)) {
unsigned long addr = h2g(p);
page_set_flags(addr & TARGET_PAGE_MASK,
TARGET_PAGE_ALIGN(addr + len),
PAGE_RESERVED);
}
#else
p = qemu_mallocz(sizeof(PageDesc) * L2_SIZE);
*lp = p;
#endif
}
return p + (index & (L2_SIZE - 1));
}
static inline PageDesc *page_find(target_ulong index)
{
PageDesc **lp, *p;
lp = page_l1_map(index);
if (!lp)
return NULL;
p = *lp;
if (!p) {
return NULL;
}
return p + (index & (L2_SIZE - 1));
}
static PhysPageDesc *phys_page_find_alloc(target_phys_addr_t index, int alloc)
{
void **lp, **p;
PhysPageDesc *pd;
p = (void **)l1_phys_map;
#if TARGET_PHYS_ADDR_SPACE_BITS > 32
#if TARGET_PHYS_ADDR_SPACE_BITS > (32 + L1_BITS)
#error unsupported TARGET_PHYS_ADDR_SPACE_BITS
#endif
lp = p + ((index >> (L1_BITS + L2_BITS)) & (L1_SIZE - 1));
p = *lp;
if (!p) {
/* allocate if not found */
if (!alloc)
return NULL;
p = qemu_vmalloc(sizeof(void *) * L1_SIZE);
memset(p, 0, sizeof(void *) * L1_SIZE);
*lp = p;
}
#endif
lp = p + ((index >> L2_BITS) & (L1_SIZE - 1));
pd = *lp;
if (!pd) {
int i;
/* allocate if not found */
if (!alloc)
return NULL;
pd = qemu_vmalloc(sizeof(PhysPageDesc) * L2_SIZE);
*lp = pd;
for (i = 0; i < L2_SIZE; i++) {
pd[i].phys_offset = IO_MEM_UNASSIGNED;
pd[i].region_offset = (index + i) << TARGET_PAGE_BITS;
}
}
return ((PhysPageDesc *)pd) + (index & (L2_SIZE - 1));
}
static inline PhysPageDesc *phys_page_find(target_phys_addr_t index)
{
return phys_page_find_alloc(index, 0);
}
#if !defined(CONFIG_USER_ONLY)
static void tlb_protect_code(ram_addr_t ram_addr);
static void tlb_unprotect_code_phys(CPUState *env, ram_addr_t ram_addr,
target_ulong vaddr);
#define mmap_lock() do { } while(0)
#define mmap_unlock() do { } while(0)
#endif
#define DEFAULT_CODE_GEN_BUFFER_SIZE (32 * 1024 * 1024)
#if defined(CONFIG_USER_ONLY)
/* Currently it is not recommended to allocate big chunks of data in
user mode. It will change when a dedicated libc will be used */
#define USE_STATIC_CODE_GEN_BUFFER
#endif
#ifdef USE_STATIC_CODE_GEN_BUFFER
static uint8_t static_code_gen_buffer[DEFAULT_CODE_GEN_BUFFER_SIZE];
#endif
static void code_gen_alloc(unsigned long tb_size)
{
if (kvm_enabled())
return;
#ifdef USE_STATIC_CODE_GEN_BUFFER
code_gen_buffer = static_code_gen_buffer;
code_gen_buffer_size = DEFAULT_CODE_GEN_BUFFER_SIZE;
map_exec(code_gen_buffer, code_gen_buffer_size);
#else
code_gen_buffer_size = tb_size;
if (code_gen_buffer_size == 0) {
#if defined(CONFIG_USER_ONLY)
/* in user mode, phys_ram_size is not meaningful */
code_gen_buffer_size = DEFAULT_CODE_GEN_BUFFER_SIZE;
#else
/* XXX: needs adjustments */
code_gen_buffer_size = (unsigned long)(ram_size / 4);
#endif
}
if (code_gen_buffer_size < MIN_CODE_GEN_BUFFER_SIZE)
code_gen_buffer_size = MIN_CODE_GEN_BUFFER_SIZE;
/* The code gen buffer location may have constraints depending on
the host cpu and OS */
#if defined(__linux__)
{
int flags;
void *start = NULL;
flags = MAP_PRIVATE | MAP_ANONYMOUS;
#if defined(__x86_64__)
flags |= MAP_32BIT;
/* Cannot map more than that */
if (code_gen_buffer_size > (800 * 1024 * 1024))
code_gen_buffer_size = (800 * 1024 * 1024);
#elif defined(__sparc_v9__)
// Map the buffer below 2G, so we can use direct calls and branches
flags |= MAP_FIXED;
start = (void *) 0x60000000UL;
if (code_gen_buffer_size > (512 * 1024 * 1024))
code_gen_buffer_size = (512 * 1024 * 1024);
#elif defined(__arm__)
/* Map the buffer below 32M, so we can use direct calls and branches */
flags |= MAP_FIXED;
start = (void *) 0x01000000UL;
if (code_gen_buffer_size > 16 * 1024 * 1024)
code_gen_buffer_size = 16 * 1024 * 1024;
#endif
code_gen_buffer = mmap(start, code_gen_buffer_size,
PROT_WRITE | PROT_READ | PROT_EXEC,
flags, -1, 0);
if (code_gen_buffer == MAP_FAILED) {
fprintf(stderr, "Could not allocate dynamic translator buffer\n");
exit(1);
}
}
#elif defined(__FreeBSD__) || defined(__DragonFly__)
{
int flags;
void *addr = NULL;
flags = MAP_PRIVATE | MAP_ANONYMOUS;
#if defined(__x86_64__)
/* FreeBSD doesn't have MAP_32BIT, use MAP_FIXED and assume
* 0x40000000 is free */
flags |= MAP_FIXED;
addr = (void *)0x40000000;
/* Cannot map more than that */
if (code_gen_buffer_size > (800 * 1024 * 1024))
code_gen_buffer_size = (800 * 1024 * 1024);
#endif
code_gen_buffer = mmap(addr, code_gen_buffer_size,
PROT_WRITE | PROT_READ | PROT_EXEC,
flags, -1, 0);
if (code_gen_buffer == MAP_FAILED) {
fprintf(stderr, "Could not allocate dynamic translator buffer\n");
exit(1);
}
}
#else
code_gen_buffer = qemu_malloc(code_gen_buffer_size);
map_exec(code_gen_buffer, code_gen_buffer_size);
#endif
#endif /* !USE_STATIC_CODE_GEN_BUFFER */
map_exec(code_gen_prologue, sizeof(code_gen_prologue));
code_gen_buffer_max_size = code_gen_buffer_size -
code_gen_max_block_size();
code_gen_max_blocks = code_gen_buffer_size / CODE_GEN_AVG_BLOCK_SIZE;
tbs = qemu_malloc(code_gen_max_blocks * sizeof(TranslationBlock));
}
/* Must be called before using the QEMU cpus. 'tb_size' is the size
(in bytes) allocated to the translation buffer. Zero means default
size. */
void cpu_exec_init_all(unsigned long tb_size)
{
cpu_gen_init();
code_gen_alloc(tb_size);
code_gen_ptr = code_gen_buffer;
page_init();
#if !defined(CONFIG_USER_ONLY)
io_mem_init();
#endif
}
#if defined(CPU_SAVE_VERSION) && !defined(CONFIG_USER_ONLY)
#define CPU_COMMON_SAVE_VERSION 1
static void cpu_common_save(QEMUFile *f, void *opaque)
{
CPUState *env = opaque;
cpu_synchronize_state(env, 0);
qemu_put_be32s(f, &env->halted);
qemu_put_be32s(f, &env->interrupt_request);
}
static int cpu_common_load(QEMUFile *f, void *opaque, int version_id)
{
CPUState *env = opaque;
if (version_id != CPU_COMMON_SAVE_VERSION)
return -EINVAL;
qemu_get_be32s(f, &env->halted);
qemu_get_be32s(f, &env->interrupt_request);
/* 0x01 was CPU_INTERRUPT_EXIT. This line can be removed when the
version_id is increased. */
env->interrupt_request &= ~0x01;
tlb_flush(env, 1);
cpu_synchronize_state(env, 1);
return 0;
}
#endif
CPUState *qemu_get_cpu(int cpu)
{
CPUState *env = first_cpu;
while (env) {
if (env->cpu_index == cpu)
break;
env = env->next_cpu;
}
return env;
}
void cpu_exec_init(CPUState *env)
{
CPUState **penv;
int cpu_index;
#if defined(CONFIG_USER_ONLY)
cpu_list_lock();
#endif
env->next_cpu = NULL;
penv = &first_cpu;
cpu_index = 0;
while (*penv != NULL) {
penv = &(*penv)->next_cpu;
cpu_index++;
}
env->cpu_index = cpu_index;
env->numa_node = 0;
TAILQ_INIT(&env->breakpoints);
TAILQ_INIT(&env->watchpoints);
#ifdef __WIN32
env->thread_id = GetCurrentProcessId();
#else
env->thread_id = getpid();
#endif
*penv = env;
#if defined(CONFIG_USER_ONLY)
cpu_list_unlock();
#endif
#if defined(CPU_SAVE_VERSION) && !defined(CONFIG_USER_ONLY)
register_savevm("cpu_common", cpu_index, CPU_COMMON_SAVE_VERSION,
cpu_common_save, cpu_common_load, env);
register_savevm("cpu", cpu_index, CPU_SAVE_VERSION,
cpu_save, cpu_load, env);
#endif
}
static inline void invalidate_page_bitmap(PageDesc *p)
{
if (p->code_bitmap) {
qemu_free(p->code_bitmap);
p->code_bitmap = NULL;
}
p->code_write_count = 0;
}
/* set to NULL all the 'first_tb' fields in all PageDescs */
static void page_flush_tb(void)
{
int i, j;
PageDesc *p;
for(i = 0; i < L1_SIZE; i++) {
p = l1_map[i];
if (p) {
for(j = 0; j < L2_SIZE; j++) {
p->first_tb = NULL;
invalidate_page_bitmap(p);
p++;
}
}
}
}
/* flush all the translation blocks */
/* XXX: tb_flush is currently not thread safe */
void tb_flush(CPUState *env1)
{
CPUState *env;
#if defined(DEBUG_FLUSH)
printf("qemu: flush code_size=%ld nb_tbs=%d avg_tb_size=%ld\n",
(unsigned long)(code_gen_ptr - code_gen_buffer),
nb_tbs, nb_tbs > 0 ?
((unsigned long)(code_gen_ptr - code_gen_buffer)) / nb_tbs : 0);
#endif
if ((unsigned long)(code_gen_ptr - code_gen_buffer) > code_gen_buffer_size)
cpu_abort(env1, "Internal error: code buffer overflow\n");
nb_tbs = 0;
for(env = first_cpu; env != NULL; env = env->next_cpu) {
memset (env->tb_jmp_cache, 0, TB_JMP_CACHE_SIZE * sizeof (void *));
}
memset (tb_phys_hash, 0, CODE_GEN_PHYS_HASH_SIZE * sizeof (void *));
page_flush_tb();
code_gen_ptr = code_gen_buffer;
/* XXX: flush processor icache at this point if cache flush is
expensive */
tb_flush_count++;
}
#ifdef DEBUG_TB_CHECK
static void tb_invalidate_check(target_ulong address)
{
TranslationBlock *tb;
int i;
address &= TARGET_PAGE_MASK;
for(i = 0;i < CODE_GEN_PHYS_HASH_SIZE; i++) {
for(tb = tb_phys_hash[i]; tb != NULL; tb = tb->phys_hash_next) {
if (!(address + TARGET_PAGE_SIZE <= tb->pc ||
address >= tb->pc + tb->size)) {
printf("ERROR invalidate: address=" TARGET_FMT_lx
" PC=%08lx size=%04x\n",
address, (long)tb->pc, tb->size);
}
}
}
}
/* verify that all the pages have correct rights for code */
static void tb_page_check(void)
{
TranslationBlock *tb;
int i, flags1, flags2;
for(i = 0;i < CODE_GEN_PHYS_HASH_SIZE; i++) {
for(tb = tb_phys_hash[i]; tb != NULL; tb = tb->phys_hash_next) {
flags1 = page_get_flags(tb->pc);
flags2 = page_get_flags(tb->pc + tb->size - 1);
if ((flags1 & PAGE_WRITE) || (flags2 & PAGE_WRITE)) {
printf("ERROR page flags: PC=%08lx size=%04x f1=%x f2=%x\n",
(long)tb->pc, tb->size, flags1, flags2);
}
}
}
}
#endif
/* invalidate one TB */
static inline void tb_remove(TranslationBlock **ptb, TranslationBlock *tb,
int next_offset)
{
TranslationBlock *tb1;
for(;;) {
tb1 = *ptb;
if (tb1 == tb) {
*ptb = *(TranslationBlock **)((char *)tb1 + next_offset);
break;
}
ptb = (TranslationBlock **)((char *)tb1 + next_offset);
}
}
static inline void tb_page_remove(TranslationBlock **ptb, TranslationBlock *tb)
{
TranslationBlock *tb1;
unsigned int n1;
for(;;) {
tb1 = *ptb;
n1 = (long)tb1 & 3;
tb1 = (TranslationBlock *)((long)tb1 & ~3);
if (tb1 == tb) {
*ptb = tb1->page_next[n1];
break;
}
ptb = &tb1->page_next[n1];
}
}
static inline void tb_jmp_remove(TranslationBlock *tb, int n)
{
TranslationBlock *tb1, **ptb;
unsigned int n1;
ptb = &tb->jmp_next[n];
tb1 = *ptb;
if (tb1) {
/* find tb(n) in circular list */
for(;;) {
tb1 = *ptb;
n1 = (long)tb1 & 3;
tb1 = (TranslationBlock *)((long)tb1 & ~3);
if (n1 == n && tb1 == tb)
break;
if (n1 == 2) {
ptb = &tb1->jmp_first;
} else {
ptb = &tb1->jmp_next[n1];
}
}
/* now we can suppress tb(n) from the list */
*ptb = tb->jmp_next[n];
tb->jmp_next[n] = NULL;
}
}
/* reset the jump entry 'n' of a TB so that it is not chained to
another TB */
static inline void tb_reset_jump(TranslationBlock *tb, int n)
{
tb_set_jmp_target(tb, n, (unsigned long)(tb->tc_ptr + tb->tb_next_offset[n]));
}
void tb_phys_invalidate(TranslationBlock *tb, target_ulong page_addr)
{
CPUState *env;
PageDesc *p;
unsigned int h, n1;
target_phys_addr_t phys_pc;
TranslationBlock *tb1, *tb2;
/* remove the TB from the hash list */
phys_pc = tb->page_addr[0] + (tb->pc & ~TARGET_PAGE_MASK);
h = tb_phys_hash_func(phys_pc);
tb_remove(&tb_phys_hash[h], tb,
offsetof(TranslationBlock, phys_hash_next));
/* remove the TB from the page list */
if (tb->page_addr[0] != page_addr) {
p = page_find(tb->page_addr[0] >> TARGET_PAGE_BITS);
tb_page_remove(&p->first_tb, tb);
invalidate_page_bitmap(p);
}
if (tb->page_addr[1] != -1 && tb->page_addr[1] != page_addr) {
p = page_find(tb->page_addr[1] >> TARGET_PAGE_BITS);
tb_page_remove(&p->first_tb, tb);
invalidate_page_bitmap(p);
}
tb_invalidated_flag = 1;
/* remove the TB from the hash list */
h = tb_jmp_cache_hash_func(tb->pc);
for(env = first_cpu; env != NULL; env = env->next_cpu) {
if (env->tb_jmp_cache[h] == tb)
env->tb_jmp_cache[h] = NULL;
}
/* suppress this TB from the two jump lists */
tb_jmp_remove(tb, 0);
tb_jmp_remove(tb, 1);
/* suppress any remaining jumps to this TB */
tb1 = tb->jmp_first;
for(;;) {
n1 = (long)tb1 & 3;
if (n1 == 2)
break;
tb1 = (TranslationBlock *)((long)tb1 & ~3);
tb2 = tb1->jmp_next[n1];
tb_reset_jump(tb1, n1);
tb1->jmp_next[n1] = NULL;
tb1 = tb2;
}
tb->jmp_first = (TranslationBlock *)((long)tb | 2); /* fail safe */
tb_phys_invalidate_count++;
}
static inline void set_bits(uint8_t *tab, int start, int len)
{
int end, mask, end1;
end = start + len;
tab += start >> 3;
mask = 0xff << (start & 7);
if ((start & ~7) == (end & ~7)) {
if (start < end) {
mask &= ~(0xff << (end & 7));
*tab |= mask;
}
} else {
*tab++ |= mask;
start = (start + 8) & ~7;
end1 = end & ~7;
while (start < end1) {
*tab++ = 0xff;
start += 8;
}
if (start < end) {
mask = ~(0xff << (end & 7));
*tab |= mask;
}
}
}
static void build_page_bitmap(PageDesc *p)
{
int n, tb_start, tb_end;
TranslationBlock *tb;
p->code_bitmap = qemu_mallocz(TARGET_PAGE_SIZE / 8);
tb = p->first_tb;
while (tb != NULL) {
n = (long)tb & 3;
tb = (TranslationBlock *)((long)tb & ~3);
/* NOTE: this is subtle as a TB may span two physical pages */
if (n == 0) {
/* NOTE: tb_end may be after the end of the page, but
it is not a problem */
tb_start = tb->pc & ~TARGET_PAGE_MASK;
tb_end = tb_start + tb->size;
if (tb_end > TARGET_PAGE_SIZE)
tb_end = TARGET_PAGE_SIZE;
} else {
tb_start = 0;
tb_end = ((tb->pc + tb->size) & ~TARGET_PAGE_MASK);
}
set_bits(p->code_bitmap, tb_start, tb_end - tb_start);
tb = tb->page_next[n];
}
}
TranslationBlock *tb_gen_code(CPUState *env,
target_ulong pc, target_ulong cs_base,
int flags, int cflags)
{
TranslationBlock *tb;
uint8_t *tc_ptr;
target_ulong phys_pc, phys_page2, virt_page2;
int code_gen_size;
phys_pc = get_phys_addr_code(env, pc);
tb = tb_alloc(pc);
if (!tb) {
/* flush must be done */
tb_flush(env);
/* cannot fail at this point */
tb = tb_alloc(pc);
/* Don't forget to invalidate previous TB info. */
tb_invalidated_flag = 1;
}
tc_ptr = code_gen_ptr;
tb->tc_ptr = tc_ptr;
tb->cs_base = cs_base;
tb->flags = flags;
tb->cflags = cflags;
cpu_gen_code(env, tb, &code_gen_size);
code_gen_ptr = (void *)(((unsigned long)code_gen_ptr + code_gen_size + CODE_GEN_ALIGN - 1) & ~(CODE_GEN_ALIGN - 1));
/* check next page if needed */
virt_page2 = (pc + tb->size - 1) & TARGET_PAGE_MASK;
phys_page2 = -1;
if ((pc & TARGET_PAGE_MASK) != virt_page2) {
phys_page2 = get_phys_addr_code(env, virt_page2);
}
tb_link_phys(tb, phys_pc, phys_page2);
return tb;
}
/* invalidate all TBs which intersect with the target physical page
starting in range [start;end[. NOTE: start and end must refer to
the same physical page. 'is_cpu_write_access' should be true if called
from a real cpu write access: the virtual CPU will exit the current
TB if code is modified inside this TB. */
void tb_invalidate_phys_page_range(target_phys_addr_t start, target_phys_addr_t end,
int is_cpu_write_access)
{
TranslationBlock *tb, *tb_next, *saved_tb;
CPUState *env = cpu_single_env;
target_ulong tb_start, tb_end;
PageDesc *p;
int n;
#ifdef TARGET_HAS_PRECISE_SMC
int current_tb_not_found = is_cpu_write_access;
TranslationBlock *current_tb = NULL;
int current_tb_modified = 0;
target_ulong current_pc = 0;
target_ulong current_cs_base = 0;
int current_flags = 0;
#endif /* TARGET_HAS_PRECISE_SMC */
p = page_find(start >> TARGET_PAGE_BITS);
if (!p)
return;
if (!p->code_bitmap &&
++p->code_write_count >= SMC_BITMAP_USE_THRESHOLD &&
is_cpu_write_access) {
/* build code bitmap */
build_page_bitmap(p);
}
/* we remove all the TBs in the range [start, end[ */
/* XXX: see if in some cases it could be faster to invalidate all the code */
tb = p->first_tb;
while (tb != NULL) {
n = (long)tb & 3;
tb = (TranslationBlock *)((long)tb & ~3);
tb_next = tb->page_next[n];
/* NOTE: this is subtle as a TB may span two physical pages */
if (n == 0) {
/* NOTE: tb_end may be after the end of the page, but
it is not a problem */
tb_start = tb->page_addr[0] + (tb->pc & ~TARGET_PAGE_MASK);
tb_end = tb_start + tb->size;
} else {
tb_start = tb->page_addr[1];
tb_end = tb_start + ((tb->pc + tb->size) & ~TARGET_PAGE_MASK);
}
if (!(tb_end <= start || tb_start >= end)) {
#ifdef TARGET_HAS_PRECISE_SMC
if (current_tb_not_found) {
current_tb_not_found = 0;
current_tb = NULL;
if (env->mem_io_pc) {
/* now we have a real cpu fault */
current_tb = tb_find_pc(env->mem_io_pc);
}
}
if (current_tb == tb &&
(current_tb->cflags & CF_COUNT_MASK) != 1) {
/* If we are modifying the current TB, we must stop
its execution. We could be more precise by checking
that the modification is after the current PC, but it
would require a specialized function to partially
restore the CPU state */
current_tb_modified = 1;
cpu_restore_state(current_tb, env,
env->mem_io_pc, NULL);
cpu_get_tb_cpu_state(env, &current_pc, &current_cs_base,
&current_flags);
}
#endif /* TARGET_HAS_PRECISE_SMC */
/* we need to do that to handle the case where a signal
occurs while doing tb_phys_invalidate() */
saved_tb = NULL;
if (env) {
saved_tb = env->current_tb;
env->current_tb = NULL;
}
tb_phys_invalidate(tb, -1);
if (env) {
env->current_tb = saved_tb;
if (env->interrupt_request && env->current_tb)
cpu_interrupt(env, env->interrupt_request);
}
}
tb = tb_next;
}
#if !defined(CONFIG_USER_ONLY)
/* if no code remaining, no need to continue to use slow writes */
if (!p->first_tb) {
invalidate_page_bitmap(p);
if (is_cpu_write_access) {
tlb_unprotect_code_phys(env, start, env->mem_io_vaddr);
}
}
#endif
#ifdef TARGET_HAS_PRECISE_SMC
if (current_tb_modified) {
/* we generate a block containing just the instruction
modifying the memory. It will ensure that it cannot modify
itself */
env->current_tb = NULL;
tb_gen_code(env, current_pc, current_cs_base, current_flags, 1);
cpu_resume_from_signal(env, NULL);
}
#endif
}
/* len must be <= 8 and start must be a multiple of len */
static inline void tb_invalidate_phys_page_fast(target_phys_addr_t start, int len)
{
PageDesc *p;
int offset, b;
#if 0
if (1) {
qemu_log("modifying code at 0x%x size=%d EIP=%x PC=%08x\n",
cpu_single_env->mem_io_vaddr, len,
cpu_single_env->eip,
cpu_single_env->eip + (long)cpu_single_env->segs[R_CS].base);
}
#endif
p = page_find(start >> TARGET_PAGE_BITS);
if (!p)
return;
if (p->code_bitmap) {
offset = start & ~TARGET_PAGE_MASK;
b = p->code_bitmap[offset >> 3] >> (offset & 7);
if (b & ((1 << len) - 1))
goto do_invalidate;
} else {
do_invalidate:
tb_invalidate_phys_page_range(start, start + len, 1);
}
}
#if !defined(CONFIG_SOFTMMU)
static void tb_invalidate_phys_page(target_phys_addr_t addr,
unsigned long pc, void *puc)
{
TranslationBlock *tb;
PageDesc *p;
int n;
#ifdef TARGET_HAS_PRECISE_SMC
TranslationBlock *current_tb = NULL;
CPUState *env = cpu_single_env;
int current_tb_modified = 0;
target_ulong current_pc = 0;
target_ulong current_cs_base = 0;
int current_flags = 0;
#endif
addr &= TARGET_PAGE_MASK;
p = page_find(addr >> TARGET_PAGE_BITS);
if (!p)
return;
tb = p->first_tb;
#ifdef TARGET_HAS_PRECISE_SMC
if (tb && pc != 0) {
current_tb = tb_find_pc(pc);
}
#endif
while (tb != NULL) {
n = (long)tb & 3;
tb = (TranslationBlock *)((long)tb & ~3);
#ifdef TARGET_HAS_PRECISE_SMC
if (current_tb == tb &&
(current_tb->cflags & CF_COUNT_MASK) != 1) {
/* If we are modifying the current TB, we must stop
its execution. We could be more precise by checking
that the modification is after the current PC, but it
would require a specialized function to partially
restore the CPU state */
current_tb_modified = 1;
cpu_restore_state(current_tb, env, pc, puc);
cpu_get_tb_cpu_state(env, &current_pc, &current_cs_base,
&current_flags);
}
#endif /* TARGET_HAS_PRECISE_SMC */
tb_phys_invalidate(tb, addr);
tb = tb->page_next[n];
}
p->first_tb = NULL;
#ifdef TARGET_HAS_PRECISE_SMC
if (current_tb_modified) {
/* we generate a block containing just the instruction
modifying the memory. It will ensure that it cannot modify
itself */
env->current_tb = NULL;
tb_gen_code(env, current_pc, current_cs_base, current_flags, 1);
cpu_resume_from_signal(env, puc);
}
#endif
}
#endif
/* add the tb in the target page and protect it if necessary */
static inline void tb_alloc_page(TranslationBlock *tb,
unsigned int n, target_ulong page_addr)
{
PageDesc *p;
TranslationBlock *last_first_tb;
tb->page_addr[n] = page_addr;
p = page_find_alloc(page_addr >> TARGET_PAGE_BITS);
tb->page_next[n] = p->first_tb;
last_first_tb = p->first_tb;
p->first_tb = (TranslationBlock *)((long)tb | n);
invalidate_page_bitmap(p);
#if defined(TARGET_HAS_SMC) || 1
#if defined(CONFIG_USER_ONLY)
if (p->flags & PAGE_WRITE) {
target_ulong addr;
PageDesc *p2;
int prot;
/* force the host page as non writable (writes will have a
page fault + mprotect overhead) */
page_addr &= qemu_host_page_mask;
prot = 0;
for(addr = page_addr; addr < page_addr + qemu_host_page_size;
addr += TARGET_PAGE_SIZE) {
p2 = page_find (addr >> TARGET_PAGE_BITS);
if (!p2)
continue;
prot |= p2->flags;
p2->flags &= ~PAGE_WRITE;
page_get_flags(addr);
}
mprotect(g2h(page_addr), qemu_host_page_size,
(prot & PAGE_BITS) & ~PAGE_WRITE);
#ifdef DEBUG_TB_INVALIDATE
printf("protecting code page: 0x" TARGET_FMT_lx "\n",
page_addr);
#endif
}
#else
/* if some code is already present, then the pages are already
protected. So we handle the case where only the first TB is
allocated in a physical page */
if (!last_first_tb) {
tlb_protect_code(page_addr);
}
#endif
#endif /* TARGET_HAS_SMC */
}
/* Allocate a new translation block. Flush the translation buffer if
too many translation blocks or too much generated code. */
TranslationBlock *tb_alloc(target_ulong pc)
{
TranslationBlock *tb;
if (nb_tbs >= code_gen_max_blocks ||
(code_gen_ptr - code_gen_buffer) >= code_gen_buffer_max_size)
return NULL;
tb = &tbs[nb_tbs++];
tb->pc = pc;
tb->cflags = 0;
return tb;
}
void tb_free(TranslationBlock *tb)
{
/* In practice this is mostly used for single use temporary TB
Ignore the hard cases and just back up if this TB happens to
be the last one generated. */
if (nb_tbs > 0 && tb == &tbs[nb_tbs - 1]) {
code_gen_ptr = tb->tc_ptr;
nb_tbs--;
}
}
/* add a new TB and link it to the physical page tables. phys_page2 is
(-1) to indicate that only one page contains the TB. */
void tb_link_phys(TranslationBlock *tb,
target_ulong phys_pc, target_ulong phys_page2)
{
unsigned int h;
TranslationBlock **ptb;
/* Grab the mmap lock to stop another thread invalidating this TB
before we are done. */
mmap_lock();
/* add in the physical hash table */
h = tb_phys_hash_func(phys_pc);
ptb = &tb_phys_hash[h];
tb->phys_hash_next = *ptb;
*ptb = tb;
/* add in the page list */
tb_alloc_page(tb, 0, phys_pc & TARGET_PAGE_MASK);
if (phys_page2 != -1)
tb_alloc_page(tb, 1, phys_page2);
else
tb->page_addr[1] = -1;
tb->jmp_first = (TranslationBlock *)((long)tb | 2);
tb->jmp_next[0] = NULL;
tb->jmp_next[1] = NULL;
/* init original jump addresses */
if (tb->tb_next_offset[0] != 0xffff)
tb_reset_jump(tb, 0);
if (tb->tb_next_offset[1] != 0xffff)
tb_reset_jump(tb, 1);
#ifdef DEBUG_TB_CHECK
tb_page_check();
#endif
mmap_unlock();
}
/* find the TB 'tb' such that tb[0].tc_ptr <= tc_ptr <
tb[1].tc_ptr. Return NULL if not found */
TranslationBlock *tb_find_pc(unsigned long tc_ptr)
{
int m_min, m_max, m;
unsigned long v;
TranslationBlock *tb;
if (nb_tbs <= 0)
return NULL;
if (tc_ptr < (unsigned long)code_gen_buffer ||
tc_ptr >= (unsigned long)code_gen_ptr)
return NULL;
/* binary search (cf Knuth) */
m_min = 0;
m_max = nb_tbs - 1;
while (m_min <= m_max) {
m = (m_min + m_max) >> 1;
tb = &tbs[m];
v = (unsigned long)tb->tc_ptr;
if (v == tc_ptr)
return tb;
else if (tc_ptr < v) {
m_max = m - 1;
} else {
m_min = m + 1;
}
}
return &tbs[m_max];
}
static void tb_reset_jump_recursive(TranslationBlock *tb);
static inline void tb_reset_jump_recursive2(TranslationBlock *tb, int n)
{
TranslationBlock *tb1, *tb_next, **ptb;
unsigned int n1;
tb1 = tb->jmp_next[n];
if (tb1 != NULL) {
/* find head of list */
for(;;) {
n1 = (long)tb1 & 3;
tb1 = (TranslationBlock *)((long)tb1 & ~3);
if (n1 == 2)
break;
tb1 = tb1->jmp_next[n1];
}
/* we are now sure now that tb jumps to tb1 */
tb_next = tb1;
/* remove tb from the jmp_first list */
ptb = &tb_next->jmp_first;
for(;;) {
tb1 = *ptb;
n1 = (long)tb1 & 3;
tb1 = (TranslationBlock *)((long)tb1 & ~3);
if (n1 == n && tb1 == tb)
break;
ptb = &tb1->jmp_next[n1];
}
*ptb = tb->jmp_next[n];
tb->jmp_next[n] = NULL;
/* suppress the jump to next tb in generated code */
tb_reset_jump(tb, n);
/* suppress jumps in the tb on which we could have jumped */
tb_reset_jump_recursive(tb_next);
}
}
static void tb_reset_jump_recursive(TranslationBlock *tb)
{
tb_reset_jump_recursive2(tb, 0);
tb_reset_jump_recursive2(tb, 1);
}
#if defined(TARGET_HAS_ICE)
static void breakpoint_invalidate(CPUState *env, target_ulong pc)
{
target_phys_addr_t addr;
target_ulong pd;
ram_addr_t ram_addr;
PhysPageDesc *p;
addr = cpu_get_phys_page_debug(env, pc);
p = phys_page_find(addr >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
ram_addr = (pd & TARGET_PAGE_MASK) | (pc & ~TARGET_PAGE_MASK);
tb_invalidate_phys_page_range(ram_addr, ram_addr + 1, 0);
}
#endif
/* Add a watchpoint. */
int cpu_watchpoint_insert(CPUState *env, target_ulong addr, target_ulong len,
int flags, CPUWatchpoint **watchpoint)
{
target_ulong len_mask = ~(len - 1);
CPUWatchpoint *wp;
/* sanity checks: allow power-of-2 lengths, deny unaligned watchpoints */
if ((len != 1 && len != 2 && len != 4 && len != 8) || (addr & ~len_mask)) {
fprintf(stderr, "qemu: tried to set invalid watchpoint at "
TARGET_FMT_lx ", len=" TARGET_FMT_lu "\n", addr, len);
return -EINVAL;
}
wp = qemu_malloc(sizeof(*wp));
wp->vaddr = addr;
wp->len_mask = len_mask;
wp->flags = flags;
/* keep all GDB-injected watchpoints in front */
if (flags & BP_GDB)
TAILQ_INSERT_HEAD(&env->watchpoints, wp, entry);
else
TAILQ_INSERT_TAIL(&env->watchpoints, wp, entry);
tlb_flush_page(env, addr);
if (watchpoint)
*watchpoint = wp;
return 0;
}
/* Remove a specific watchpoint. */
int cpu_watchpoint_remove(CPUState *env, target_ulong addr, target_ulong len,
int flags)
{
target_ulong len_mask = ~(len - 1);
CPUWatchpoint *wp;
TAILQ_FOREACH(wp, &env->watchpoints, entry) {
if (addr == wp->vaddr && len_mask == wp->len_mask
&& flags == (wp->flags & ~BP_WATCHPOINT_HIT)) {
cpu_watchpoint_remove_by_ref(env, wp);
return 0;
}
}
return -ENOENT;
}
/* Remove a specific watchpoint by reference. */
void cpu_watchpoint_remove_by_ref(CPUState *env, CPUWatchpoint *watchpoint)
{
TAILQ_REMOVE(&env->watchpoints, watchpoint, entry);
tlb_flush_page(env, watchpoint->vaddr);
qemu_free(watchpoint);
}
/* Remove all matching watchpoints. */
void cpu_watchpoint_remove_all(CPUState *env, int mask)
{
CPUWatchpoint *wp, *next;
TAILQ_FOREACH_SAFE(wp, &env->watchpoints, entry, next) {
if (wp->flags & mask)
cpu_watchpoint_remove_by_ref(env, wp);
}
}
/* Add a breakpoint. */
int cpu_breakpoint_insert(CPUState *env, target_ulong pc, int flags,
CPUBreakpoint **breakpoint)
{
#if defined(TARGET_HAS_ICE)
CPUBreakpoint *bp;
bp = qemu_malloc(sizeof(*bp));
bp->pc = pc;
bp->flags = flags;
/* keep all GDB-injected breakpoints in front */
if (flags & BP_GDB)
TAILQ_INSERT_HEAD(&env->breakpoints, bp, entry);
else
TAILQ_INSERT_TAIL(&env->breakpoints, bp, entry);
breakpoint_invalidate(env, pc);
if (breakpoint)
*breakpoint = bp;
return 0;
#else
return -ENOSYS;
#endif
}
/* Remove a specific breakpoint. */
int cpu_breakpoint_remove(CPUState *env, target_ulong pc, int flags)
{
#if defined(TARGET_HAS_ICE)
CPUBreakpoint *bp;
TAILQ_FOREACH(bp, &env->breakpoints, entry) {
if (bp->pc == pc && bp->flags == flags) {
cpu_breakpoint_remove_by_ref(env, bp);
return 0;
}
}
return -ENOENT;
#else
return -ENOSYS;
#endif
}
/* Remove a specific breakpoint by reference. */
void cpu_breakpoint_remove_by_ref(CPUState *env, CPUBreakpoint *breakpoint)
{
#if defined(TARGET_HAS_ICE)
TAILQ_REMOVE(&env->breakpoints, breakpoint, entry);
breakpoint_invalidate(env, breakpoint->pc);
qemu_free(breakpoint);
#endif
}
/* Remove all matching breakpoints. */
void cpu_breakpoint_remove_all(CPUState *env, int mask)
{
#if defined(TARGET_HAS_ICE)
CPUBreakpoint *bp, *next;
TAILQ_FOREACH_SAFE(bp, &env->breakpoints, entry, next) {
if (bp->flags & mask)
cpu_breakpoint_remove_by_ref(env, bp);
}
#endif
}
/* enable or disable single step mode. EXCP_DEBUG is returned by the
CPU loop after each instruction */
void cpu_single_step(CPUState *env, int enabled)
{
#if defined(TARGET_HAS_ICE)
if (env->singlestep_enabled != enabled) {
env->singlestep_enabled = enabled;
if (kvm_enabled())
kvm_update_guest_debug(env, 0);
else {
/* must flush all the translated code to avoid inconsistencies */
/* XXX: only flush what is necessary */
tb_flush(env);
}
}
#endif
}
/* enable or disable low levels log */
void cpu_set_log(int log_flags)
{
loglevel = log_flags;
if (loglevel && !logfile) {
logfile = fopen(logfilename, log_append ? "a" : "w");
if (!logfile) {
perror(logfilename);
_exit(1);
}
#if !defined(CONFIG_SOFTMMU)
/* must avoid mmap() usage of glibc by setting a buffer "by hand" */
{
static char logfile_buf[4096];
setvbuf(logfile, logfile_buf, _IOLBF, sizeof(logfile_buf));
}
#else
setvbuf(logfile, NULL, _IOLBF, 0);
#endif
log_append = 1;
}
if (!loglevel && logfile) {
fclose(logfile);
logfile = NULL;
}
}
void cpu_set_log_filename(const char *filename)
{
logfilename = strdup(filename);
if (logfile) {
fclose(logfile);
logfile = NULL;
}
cpu_set_log(loglevel);
}
static void cpu_unlink_tb(CPUState *env)
{
#if defined(USE_NPTL)
/* FIXME: TB unchaining isn't SMP safe. For now just ignore the
problem and hope the cpu will stop of its own accord. For userspace
emulation this often isn't actually as bad as it sounds. Often
signals are used primarily to interrupt blocking syscalls. */
#else
TranslationBlock *tb;
static spinlock_t interrupt_lock = SPIN_LOCK_UNLOCKED;
tb = env->current_tb;
/* if the cpu is currently executing code, we must unlink it and
all the potentially executing TB */
if (tb && !testandset(&interrupt_lock)) {
env->current_tb = NULL;
tb_reset_jump_recursive(tb);
resetlock(&interrupt_lock);
}
#endif
}
/* mask must never be zero, except for A20 change call */
void cpu_interrupt(CPUState *env, int mask)
{
int old_mask;
old_mask = env->interrupt_request;
env->interrupt_request |= mask;
if (kvm_enabled() && !qemu_kvm_irqchip_in_kernel())
kvm_update_interrupt_request(env);
#ifndef CONFIG_USER_ONLY
/*
* If called from iothread context, wake the target cpu in
* case its halted.
*/
if (!qemu_cpu_self(env)) {
qemu_cpu_kick(env);
return;
}
#endif
if (use_icount) {
env->icount_decr.u16.high = 0xffff;
#ifndef CONFIG_USER_ONLY
if (!can_do_io(env)
&& (mask & ~old_mask) != 0) {
cpu_abort(env, "Raised interrupt while not in I/O function");
}
#endif
} else {
cpu_unlink_tb(env);
}
}
void cpu_reset_interrupt(CPUState *env, int mask)
{
env->interrupt_request &= ~mask;
}
void cpu_exit(CPUState *env)
{
env->exit_request = 1;
cpu_unlink_tb(env);
}
const CPULogItem cpu_log_items[] = {
{ CPU_LOG_TB_OUT_ASM, "out_asm",
"show generated host assembly code for each compiled TB" },
{ CPU_LOG_TB_IN_ASM, "in_asm",
"show target assembly code for each compiled TB" },
{ CPU_LOG_TB_OP, "op",
"show micro ops for each compiled TB" },
{ CPU_LOG_TB_OP_OPT, "op_opt",
"show micro ops "
#ifdef TARGET_I386
"before eflags optimization and "
#endif
"after liveness analysis" },
{ CPU_LOG_INT, "int",
"show interrupts/exceptions in short format" },
{ CPU_LOG_EXEC, "exec",
"show trace before each executed TB (lots of logs)" },
{ CPU_LOG_TB_CPU, "cpu",
"show CPU state before block translation" },
#ifdef TARGET_I386
{ CPU_LOG_PCALL, "pcall",
"show protected mode far calls/returns/exceptions" },
{ CPU_LOG_RESET, "cpu_reset",
"show CPU state before CPU resets" },
#endif
#ifdef DEBUG_IOPORT
{ CPU_LOG_IOPORT, "ioport",
"show all i/o ports accesses" },
#endif
{ 0, NULL, NULL },
};
static int cmp1(const char *s1, int n, const char *s2)
{
if (strlen(s2) != n)
return 0;
return memcmp(s1, s2, n) == 0;
}
/* takes a comma separated list of log masks. Return 0 if error. */
int cpu_str_to_log_mask(const char *str)
{
const CPULogItem *item;
int mask;
const char *p, *p1;
p = str;
mask = 0;
for(;;) {
p1 = strchr(p, ',');
if (!p1)
p1 = p + strlen(p);
if(cmp1(p,p1-p,"all")) {
for(item = cpu_log_items; item->mask != 0; item++) {
mask |= item->mask;
}
} else {
for(item = cpu_log_items; item->mask != 0; item++) {
if (cmp1(p, p1 - p, item->name))
goto found;
}
return 0;
}
found:
mask |= item->mask;
if (*p1 != ',')
break;
p = p1 + 1;
}
return mask;
}
void cpu_abort(CPUState *env, const char *fmt, ...)
{
va_list ap;
va_list ap2;
va_start(ap, fmt);
va_copy(ap2, ap);
fprintf(stderr, "qemu: fatal: ");
vfprintf(stderr, fmt, ap);
fprintf(stderr, "\n");
#ifdef TARGET_I386
cpu_dump_state(env, stderr, fprintf, X86_DUMP_FPU | X86_DUMP_CCOP);
#else
cpu_dump_state(env, stderr, fprintf, 0);
#endif
if (qemu_log_enabled()) {
qemu_log("qemu: fatal: ");
qemu_log_vprintf(fmt, ap2);
qemu_log("\n");
#ifdef TARGET_I386
log_cpu_state(env, X86_DUMP_FPU | X86_DUMP_CCOP);
#else
log_cpu_state(env, 0);
#endif
qemu_log_flush();
qemu_log_close();
}
va_end(ap2);
va_end(ap);
abort();
}
CPUState *cpu_copy(CPUState *env)
{
CPUState *new_env = cpu_init(env->cpu_model_str);
CPUState *next_cpu = new_env->next_cpu;
int cpu_index = new_env->cpu_index;
#if defined(TARGET_HAS_ICE)
CPUBreakpoint *bp;
CPUWatchpoint *wp;
#endif
memcpy(new_env, env, sizeof(CPUState));
/* Preserve chaining and index. */
new_env->next_cpu = next_cpu;
new_env->cpu_index = cpu_index;
/* Clone all break/watchpoints.
Note: Once we support ptrace with hw-debug register access, make sure
BP_CPU break/watchpoints are handled correctly on clone. */
TAILQ_INIT(&env->breakpoints);
TAILQ_INIT(&env->watchpoints);
#if defined(TARGET_HAS_ICE)
TAILQ_FOREACH(bp, &env->breakpoints, entry) {
cpu_breakpoint_insert(new_env, bp->pc, bp->flags, NULL);
}
TAILQ_FOREACH(wp, &env->watchpoints, entry) {
cpu_watchpoint_insert(new_env, wp->vaddr, (~wp->len_mask) + 1,
wp->flags, NULL);
}
#endif
return new_env;
}
#if !defined(CONFIG_USER_ONLY)
static inline void tlb_flush_jmp_cache(CPUState *env, target_ulong addr)
{
unsigned int i;
/* Discard jump cache entries for any tb which might potentially
overlap the flushed page. */
i = tb_jmp_cache_hash_page(addr - TARGET_PAGE_SIZE);
memset (&env->tb_jmp_cache[i], 0,
TB_JMP_PAGE_SIZE * sizeof(TranslationBlock *));
i = tb_jmp_cache_hash_page(addr);
memset (&env->tb_jmp_cache[i], 0,
TB_JMP_PAGE_SIZE * sizeof(TranslationBlock *));
}
static CPUTLBEntry s_cputlb_empty_entry = {
.addr_read = -1,
.addr_write = -1,
.addr_code = -1,
.addend = -1,
};
/* NOTE: if flush_global is true, also flush global entries (not
implemented yet) */
void tlb_flush(CPUState *env, int flush_global)
{
int i;
#if defined(DEBUG_TLB)
printf("tlb_flush:\n");
#endif
/* must reset current TB so that interrupts cannot modify the
links while we are modifying them */
env->current_tb = NULL;
for(i = 0; i < CPU_TLB_SIZE; i++) {
int mmu_idx;
for (mmu_idx = 0; mmu_idx < NB_MMU_MODES; mmu_idx++) {
env->tlb_table[mmu_idx][i] = s_cputlb_empty_entry;
}
}
memset (env->tb_jmp_cache, 0, TB_JMP_CACHE_SIZE * sizeof (void *));
#ifdef CONFIG_KQEMU
if (env->kqemu_enabled) {
kqemu_flush(env, flush_global);
}
#endif
tlb_flush_count++;
}
static inline void tlb_flush_entry(CPUTLBEntry *tlb_entry, target_ulong addr)
{
if (addr == (tlb_entry->addr_read &
(TARGET_PAGE_MASK | TLB_INVALID_MASK)) ||
addr == (tlb_entry->addr_write &
(TARGET_PAGE_MASK | TLB_INVALID_MASK)) ||
addr == (tlb_entry->addr_code &
(TARGET_PAGE_MASK | TLB_INVALID_MASK))) {
*tlb_entry = s_cputlb_empty_entry;
}
}
void tlb_flush_page(CPUState *env, target_ulong addr)
{
int i;
int mmu_idx;
#if defined(DEBUG_TLB)
printf("tlb_flush_page: " TARGET_FMT_lx "\n", addr);
#endif
/* must reset current TB so that interrupts cannot modify the
links while we are modifying them */
env->current_tb = NULL;
addr &= TARGET_PAGE_MASK;
i = (addr >> TARGET_PAGE_BITS) & (CPU_TLB_SIZE - 1);
for (mmu_idx = 0; mmu_idx < NB_MMU_MODES; mmu_idx++)
tlb_flush_entry(&env->tlb_table[mmu_idx][i], addr);
tlb_flush_jmp_cache(env, addr);
#ifdef CONFIG_KQEMU
if (env->kqemu_enabled) {
kqemu_flush_page(env, addr);
}
#endif
}
/* update the TLBs so that writes to code in the virtual page 'addr'
can be detected */
static void tlb_protect_code(ram_addr_t ram_addr)
{
cpu_physical_memory_reset_dirty(ram_addr,
ram_addr + TARGET_PAGE_SIZE,
CODE_DIRTY_FLAG);
}
/* update the TLB so that writes in physical page 'phys_addr' are no longer
tested for self modifying code */
static void tlb_unprotect_code_phys(CPUState *env, ram_addr_t ram_addr,
target_ulong vaddr)
{
phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS] |= CODE_DIRTY_FLAG;
}
static inline void tlb_reset_dirty_range(CPUTLBEntry *tlb_entry,
unsigned long start, unsigned long length)
{
unsigned long addr;
if ((tlb_entry->addr_write & ~TARGET_PAGE_MASK) == IO_MEM_RAM) {
addr = (tlb_entry->addr_write & TARGET_PAGE_MASK) + tlb_entry->addend;
if ((addr - start) < length) {
tlb_entry->addr_write = (tlb_entry->addr_write & TARGET_PAGE_MASK) | TLB_NOTDIRTY;
}
}
}
/* Note: start and end must be within the same ram block. */
void cpu_physical_memory_reset_dirty(ram_addr_t start, ram_addr_t end,
int dirty_flags)
{
CPUState *env;
unsigned long length, start1;
int i, mask, len;
uint8_t *p;
start &= TARGET_PAGE_MASK;
end = TARGET_PAGE_ALIGN(end);
length = end - start;
if (length == 0)
return;
len = length >> TARGET_PAGE_BITS;
#ifdef CONFIG_KQEMU
/* XXX: should not depend on cpu context */
env = first_cpu;
if (env->kqemu_enabled) {
ram_addr_t addr;
addr = start;
for(i = 0; i < len; i++) {
kqemu_set_notdirty(env, addr);
addr += TARGET_PAGE_SIZE;
}
}
#endif
mask = ~dirty_flags;
p = phys_ram_dirty + (start >> TARGET_PAGE_BITS);
for(i = 0; i < len; i++)
p[i] &= mask;
/* we modify the TLB cache so that the dirty bit will be set again
when accessing the range */
start1 = (unsigned long)qemu_get_ram_ptr(start);
/* Chek that we don't span multiple blocks - this breaks the
address comparisons below. */
if ((unsigned long)qemu_get_ram_ptr(end - 1) - start1
!= (end - 1) - start) {
abort();
}
for(env = first_cpu; env != NULL; env = env->next_cpu) {
int mmu_idx;
for (mmu_idx = 0; mmu_idx < NB_MMU_MODES; mmu_idx++) {
for(i = 0; i < CPU_TLB_SIZE; i++)
tlb_reset_dirty_range(&env->tlb_table[mmu_idx][i],
start1, length);
}
}
}
int cpu_physical_memory_set_dirty_tracking(int enable)
{
if (kvm_enabled()) {
return kvm_set_migration_log(enable);
}
return 0;
}
int cpu_physical_memory_get_dirty_tracking(void)
{
return in_migration;
}
int cpu_physical_sync_dirty_bitmap(target_phys_addr_t start_addr,
target_phys_addr_t end_addr)
{
int ret = 0;
if (kvm_enabled())
ret = kvm_physical_sync_dirty_bitmap(start_addr, end_addr);
return ret;
}
static inline void tlb_update_dirty(CPUTLBEntry *tlb_entry)
{
ram_addr_t ram_addr;
void *p;
if ((tlb_entry->addr_write & ~TARGET_PAGE_MASK) == IO_MEM_RAM) {
p = (void *)(unsigned long)((tlb_entry->addr_write & TARGET_PAGE_MASK)
+ tlb_entry->addend);
ram_addr = qemu_ram_addr_from_host(p);
if (!cpu_physical_memory_is_dirty(ram_addr)) {
tlb_entry->addr_write |= TLB_NOTDIRTY;
}
}
}
/* update the TLB according to the current state of the dirty bits */
void cpu_tlb_update_dirty(CPUState *env)
{
int i;
int mmu_idx;
for (mmu_idx = 0; mmu_idx < NB_MMU_MODES; mmu_idx++) {
for(i = 0; i < CPU_TLB_SIZE; i++)
tlb_update_dirty(&env->tlb_table[mmu_idx][i]);
}
}
static inline void tlb_set_dirty1(CPUTLBEntry *tlb_entry, target_ulong vaddr)
{
if (tlb_entry->addr_write == (vaddr | TLB_NOTDIRTY))
tlb_entry->addr_write = vaddr;
}
/* update the TLB corresponding to virtual page vaddr
so that it is no longer dirty */
static inline void tlb_set_dirty(CPUState *env, target_ulong vaddr)
{
int i;
int mmu_idx;
vaddr &= TARGET_PAGE_MASK;
i = (vaddr >> TARGET_PAGE_BITS) & (CPU_TLB_SIZE - 1);
for (mmu_idx = 0; mmu_idx < NB_MMU_MODES; mmu_idx++)
tlb_set_dirty1(&env->tlb_table[mmu_idx][i], vaddr);
}
/* add a new TLB entry. At most one entry for a given virtual address
is permitted. Return 0 if OK or 2 if the page could not be mapped
(can only happen in non SOFTMMU mode for I/O pages or pages
conflicting with the host address space). */
int tlb_set_page_exec(CPUState *env, target_ulong vaddr,
target_phys_addr_t paddr, int prot,
int mmu_idx, int is_softmmu)
{
PhysPageDesc *p;
unsigned long pd;
unsigned int index;
target_ulong address;
target_ulong code_address;
target_phys_addr_t addend;
int ret;
CPUTLBEntry *te;
CPUWatchpoint *wp;
target_phys_addr_t iotlb;
p = phys_page_find(paddr >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
#if defined(DEBUG_TLB)
printf("tlb_set_page: vaddr=" TARGET_FMT_lx " paddr=0x%08x prot=%x idx=%d smmu=%d pd=0x%08lx\n",
vaddr, (int)paddr, prot, mmu_idx, is_softmmu, pd);
#endif
ret = 0;
address = vaddr;
if ((pd & ~TARGET_PAGE_MASK) > IO_MEM_ROM && !(pd & IO_MEM_ROMD)) {
/* IO memory case (romd handled later) */
address |= TLB_MMIO;
}
addend = (unsigned long)qemu_get_ram_ptr(pd & TARGET_PAGE_MASK);
if ((pd & ~TARGET_PAGE_MASK) <= IO_MEM_ROM) {
/* Normal RAM. */
iotlb = pd & TARGET_PAGE_MASK;
if ((pd & ~TARGET_PAGE_MASK) == IO_MEM_RAM)
iotlb |= IO_MEM_NOTDIRTY;
else
iotlb |= IO_MEM_ROM;
} else {
/* IO handlers are currently passed a physical address.
It would be nice to pass an offset from the base address
of that region. This would avoid having to special case RAM,
and avoid full address decoding in every device.
We can't use the high bits of pd for this because
IO_MEM_ROMD uses these as a ram address. */
iotlb = (pd & ~TARGET_PAGE_MASK);
if (p) {
iotlb += p->region_offset;
} else {
iotlb += paddr;
}
}
code_address = address;
/* Make accesses to pages with watchpoints go via the
watchpoint trap routines. */
TAILQ_FOREACH(wp, &env->watchpoints, entry) {
if (vaddr == (wp->vaddr & TARGET_PAGE_MASK)) {
iotlb = io_mem_watch + paddr;
/* TODO: The memory case can be optimized by not trapping
reads of pages with a write breakpoint. */
address |= TLB_MMIO;
}
}
index = (vaddr >> TARGET_PAGE_BITS) & (CPU_TLB_SIZE - 1);
env->iotlb[mmu_idx][index] = iotlb - vaddr;
te = &env->tlb_table[mmu_idx][index];
te->addend = addend - vaddr;
if (prot & PAGE_READ) {
te->addr_read = address;
} else {
te->addr_read = -1;
}
if (prot & PAGE_EXEC) {
te->addr_code = code_address;
} else {
te->addr_code = -1;
}
if (prot & PAGE_WRITE) {
if ((pd & ~TARGET_PAGE_MASK) == IO_MEM_ROM ||
(pd & IO_MEM_ROMD)) {
/* Write access calls the I/O callback. */
te->addr_write = address | TLB_MMIO;
} else if ((pd & ~TARGET_PAGE_MASK) == IO_MEM_RAM &&
!cpu_physical_memory_is_dirty(pd)) {
te->addr_write = address | TLB_NOTDIRTY;
} else {
te->addr_write = address;
}
} else {
te->addr_write = -1;
}
return ret;
}
#else
void tlb_flush(CPUState *env, int flush_global)
{
}
void tlb_flush_page(CPUState *env, target_ulong addr)
{
}
int tlb_set_page_exec(CPUState *env, target_ulong vaddr,
target_phys_addr_t paddr, int prot,
int mmu_idx, int is_softmmu)
{
return 0;
}
/*
* Walks guest process memory "regions" one by one
* and calls callback function 'fn' for each region.
*/
int walk_memory_regions(void *priv,
int (*fn)(void *, unsigned long, unsigned long, unsigned long))
{
unsigned long start, end;
PageDesc *p = NULL;
int i, j, prot, prot1;
int rc = 0;
start = end = -1;
prot = 0;
for (i = 0; i <= L1_SIZE; i++) {
p = (i < L1_SIZE) ? l1_map[i] : NULL;
for (j = 0; j < L2_SIZE; j++) {
prot1 = (p == NULL) ? 0 : p[j].flags;
/*
* "region" is one continuous chunk of memory
* that has same protection flags set.
*/
if (prot1 != prot) {
end = (i << (32 - L1_BITS)) | (j << TARGET_PAGE_BITS);
if (start != -1) {
rc = (*fn)(priv, start, end, prot);
/* callback can stop iteration by returning != 0 */
if (rc != 0)
return (rc);
}
if (prot1 != 0)
start = end;
else
start = -1;
prot = prot1;
}
if (p == NULL)
break;
}
}
return (rc);
}
static int dump_region(void *priv, unsigned long start,
unsigned long end, unsigned long prot)
{
FILE *f = (FILE *)priv;
(void) fprintf(f, "%08lx-%08lx %08lx %c%c%c\n",
start, end, end - start,
((prot & PAGE_READ) ? 'r' : '-'),
((prot & PAGE_WRITE) ? 'w' : '-'),
((prot & PAGE_EXEC) ? 'x' : '-'));
return (0);
}
/* dump memory mappings */
void page_dump(FILE *f)
{
(void) fprintf(f, "%-8s %-8s %-8s %s\n",
"start", "end", "size", "prot");
walk_memory_regions(f, dump_region);
}
int page_get_flags(target_ulong address)
{
PageDesc *p;
p = page_find(address >> TARGET_PAGE_BITS);
if (!p)
return 0;
return p->flags;
}
/* modify the flags of a page and invalidate the code if
necessary. The flag PAGE_WRITE_ORG is positioned automatically
depending on PAGE_WRITE */
void page_set_flags(target_ulong start, target_ulong end, int flags)
{
PageDesc *p;
target_ulong addr;
/* mmap_lock should already be held. */
start = start & TARGET_PAGE_MASK;
end = TARGET_PAGE_ALIGN(end);
if (flags & PAGE_WRITE)
flags |= PAGE_WRITE_ORG;
for(addr = start; addr < end; addr += TARGET_PAGE_SIZE) {
p = page_find_alloc(addr >> TARGET_PAGE_BITS);
/* We may be called for host regions that are outside guest
address space. */
if (!p)
return;
/* if the write protection is set, then we invalidate the code
inside */
if (!(p->flags & PAGE_WRITE) &&
(flags & PAGE_WRITE) &&
p->first_tb) {
tb_invalidate_phys_page(addr, 0, NULL);
}
p->flags = flags;
}
}
int page_check_range(target_ulong start, target_ulong len, int flags)
{
PageDesc *p;
target_ulong end;
target_ulong addr;
if (start + len < start)
/* we've wrapped around */
return -1;
end = TARGET_PAGE_ALIGN(start+len); /* must do before we loose bits in the next step */
start = start & TARGET_PAGE_MASK;
for(addr = start; addr < end; addr += TARGET_PAGE_SIZE) {
p = page_find(addr >> TARGET_PAGE_BITS);
if( !p )
return -1;
if( !(p->flags & PAGE_VALID) )
return -1;
if ((flags & PAGE_READ) && !(p->flags & PAGE_READ))
return -1;
if (flags & PAGE_WRITE) {
if (!(p->flags & PAGE_WRITE_ORG))
return -1;
/* unprotect the page if it was put read-only because it
contains translated code */
if (!(p->flags & PAGE_WRITE)) {
if (!page_unprotect(addr, 0, NULL))
return -1;
}
return 0;
}
}
return 0;
}
/* called from signal handler: invalidate the code and unprotect the
page. Return TRUE if the fault was successfully handled. */
int page_unprotect(target_ulong address, unsigned long pc, void *puc)
{
unsigned int page_index, prot, pindex;
PageDesc *p, *p1;
target_ulong host_start, host_end, addr;
/* Technically this isn't safe inside a signal handler. However we
know this only ever happens in a synchronous SEGV handler, so in
practice it seems to be ok. */
mmap_lock();
host_start = address & qemu_host_page_mask;
page_index = host_start >> TARGET_PAGE_BITS;
p1 = page_find(page_index);
if (!p1) {
mmap_unlock();
return 0;
}
host_end = host_start + qemu_host_page_size;
p = p1;
prot = 0;
for(addr = host_start;addr < host_end; addr += TARGET_PAGE_SIZE) {
prot |= p->flags;
p++;
}
/* if the page was really writable, then we change its
protection back to writable */
if (prot & PAGE_WRITE_ORG) {
pindex = (address - host_start) >> TARGET_PAGE_BITS;
if (!(p1[pindex].flags & PAGE_WRITE)) {
mprotect((void *)g2h(host_start), qemu_host_page_size,
(prot & PAGE_BITS) | PAGE_WRITE);
p1[pindex].flags |= PAGE_WRITE;
/* and since the content will be modified, we must invalidate
the corresponding translated code. */
tb_invalidate_phys_page(address, pc, puc);
#ifdef DEBUG_TB_CHECK
tb_invalidate_check(address);
#endif
mmap_unlock();
return 1;
}
}
mmap_unlock();
return 0;
}
static inline void tlb_set_dirty(CPUState *env,
unsigned long addr, target_ulong vaddr)
{
}
#endif /* defined(CONFIG_USER_ONLY) */
#if !defined(CONFIG_USER_ONLY)
static int subpage_register (subpage_t *mmio, uint32_t start, uint32_t end,
ram_addr_t memory, ram_addr_t region_offset);
static void *subpage_init (target_phys_addr_t base, ram_addr_t *phys,
ram_addr_t orig_memory, ram_addr_t region_offset);
#define CHECK_SUBPAGE(addr, start_addr, start_addr2, end_addr, end_addr2, \
need_subpage) \
do { \
if (addr > start_addr) \
start_addr2 = 0; \
else { \
start_addr2 = start_addr & ~TARGET_PAGE_MASK; \
if (start_addr2 > 0) \
need_subpage = 1; \
} \
\
if ((start_addr + orig_size) - addr >= TARGET_PAGE_SIZE) \
end_addr2 = TARGET_PAGE_SIZE - 1; \
else { \
end_addr2 = (start_addr + orig_size - 1) & ~TARGET_PAGE_MASK; \
if (end_addr2 < TARGET_PAGE_SIZE - 1) \
need_subpage = 1; \
} \
} while (0)
/* register physical memory. 'size' must be a multiple of the target
page size. If (phys_offset & ~TARGET_PAGE_MASK) != 0, then it is an
io memory page. The address used when calling the IO function is
the offset from the start of the region, plus region_offset. Both
start_addr and region_offset are rounded down to a page boundary
before calculating this offset. This should not be a problem unless
the low bits of start_addr and region_offset differ. */
void cpu_register_physical_memory_offset(target_phys_addr_t start_addr,
ram_addr_t size,
ram_addr_t phys_offset,
ram_addr_t region_offset)
{
target_phys_addr_t addr, end_addr;
PhysPageDesc *p;
CPUState *env;
ram_addr_t orig_size = size;
void *subpage;
#ifdef CONFIG_KQEMU
/* XXX: should not depend on cpu context */
env = first_cpu;
if (env->kqemu_enabled) {
kqemu_set_phys_mem(start_addr, size, phys_offset);
}
#endif
if (kvm_enabled())
kvm_set_phys_mem(start_addr, size, phys_offset);
if (phys_offset == IO_MEM_UNASSIGNED) {
region_offset = start_addr;
}
region_offset &= TARGET_PAGE_MASK;
size = (size + TARGET_PAGE_SIZE - 1) & TARGET_PAGE_MASK;
end_addr = start_addr + (target_phys_addr_t)size;
for(addr = start_addr; addr != end_addr; addr += TARGET_PAGE_SIZE) {
p = phys_page_find(addr >> TARGET_PAGE_BITS);
if (p && p->phys_offset != IO_MEM_UNASSIGNED) {
ram_addr_t orig_memory = p->phys_offset;
target_phys_addr_t start_addr2, end_addr2;
int need_subpage = 0;
CHECK_SUBPAGE(addr, start_addr, start_addr2, end_addr, end_addr2,
need_subpage);
if (need_subpage || phys_offset & IO_MEM_SUBWIDTH) {
if (!(orig_memory & IO_MEM_SUBPAGE)) {
subpage = subpage_init((addr & TARGET_PAGE_MASK),
&p->phys_offset, orig_memory,
p->region_offset);
} else {
subpage = io_mem_opaque[(orig_memory & ~TARGET_PAGE_MASK)
>> IO_MEM_SHIFT];
}
subpage_register(subpage, start_addr2, end_addr2, phys_offset,
region_offset);
p->region_offset = 0;
} else {
p->phys_offset = phys_offset;
if ((phys_offset & ~TARGET_PAGE_MASK) <= IO_MEM_ROM ||
(phys_offset & IO_MEM_ROMD))
phys_offset += TARGET_PAGE_SIZE;
}
} else {
p = phys_page_find_alloc(addr >> TARGET_PAGE_BITS, 1);
p->phys_offset = phys_offset;
p->region_offset = region_offset;
if ((phys_offset & ~TARGET_PAGE_MASK) <= IO_MEM_ROM ||
(phys_offset & IO_MEM_ROMD)) {
phys_offset += TARGET_PAGE_SIZE;
} else {
target_phys_addr_t start_addr2, end_addr2;
int need_subpage = 0;
CHECK_SUBPAGE(addr, start_addr, start_addr2, end_addr,
end_addr2, need_subpage);
if (need_subpage || phys_offset & IO_MEM_SUBWIDTH) {
subpage = subpage_init((addr & TARGET_PAGE_MASK),
&p->phys_offset, IO_MEM_UNASSIGNED,
addr & TARGET_PAGE_MASK);
subpage_register(subpage, start_addr2, end_addr2,
phys_offset, region_offset);
p->region_offset = 0;
}
}
}
region_offset += TARGET_PAGE_SIZE;
}
/* since each CPU stores ram addresses in its TLB cache, we must
reset the modified entries */
/* XXX: slow ! */
for(env = first_cpu; env != NULL; env = env->next_cpu) {
tlb_flush(env, 1);
}
}
/* XXX: temporary until new memory mapping API */
ram_addr_t cpu_get_physical_page_desc(target_phys_addr_t addr)
{
PhysPageDesc *p;
p = phys_page_find(addr >> TARGET_PAGE_BITS);
if (!p)
return IO_MEM_UNASSIGNED;
return p->phys_offset;
}
void qemu_register_coalesced_mmio(target_phys_addr_t addr, ram_addr_t size)
{
if (kvm_enabled())
kvm_coalesce_mmio_region(addr, size);
}
void qemu_unregister_coalesced_mmio(target_phys_addr_t addr, ram_addr_t size)
{
if (kvm_enabled())
kvm_uncoalesce_mmio_region(addr, size);
}
#ifdef CONFIG_KQEMU
/* XXX: better than nothing */
static ram_addr_t kqemu_ram_alloc(ram_addr_t size)
{
ram_addr_t addr;
if ((last_ram_offset + size) > kqemu_phys_ram_size) {
fprintf(stderr, "Not enough memory (requested_size = %" PRIu64 ", max memory = %" PRIu64 ")\n",
(uint64_t)size, (uint64_t)kqemu_phys_ram_size);
abort();
}
addr = last_ram_offset;
last_ram_offset = TARGET_PAGE_ALIGN(last_ram_offset + size);
return addr;
}
#endif
#ifdef __linux__
#include <sys/vfs.h>
#define HUGETLBFS_MAGIC 0x958458f6
static long gethugepagesize(const char *path)
{
struct statfs fs;
int ret;
do {
ret = statfs(path, &fs);
} while (ret != 0 && errno == EINTR);
if (ret != 0) {
perror("statfs");
return 0;
}
if (fs.f_type != HUGETLBFS_MAGIC)
fprintf(stderr, "Warning: path not on HugeTLBFS: %s\n", path);
return fs.f_bsize;
}
static void *file_ram_alloc(ram_addr_t memory, const char *path)
{
char *filename;
void *area;
int fd;
#ifdef MAP_POPULATE
int flags;
#endif
unsigned long hpagesize;
extern int mem_prealloc;
if (!path) {
return NULL;
}
hpagesize = gethugepagesize(path);
if (!hpagesize) {
return NULL;
}
if (memory < hpagesize) {
return NULL;
}
if (kvm_enabled() && !kvm_has_sync_mmu()) {
fprintf(stderr, "host lacks mmu notifiers, disabling --mem-path\n");
return NULL;
}
if (asprintf(&filename, "%s/kvm.XXXXXX", path) == -1) {
return NULL;
}
fd = mkstemp(filename);
if (fd < 0) {
perror("mkstemp");
free(filename);
return NULL;
}
unlink(filename);
free(filename);
memory = (memory+hpagesize-1) & ~(hpagesize-1);
/*
* ftruncate is not supported by hugetlbfs in older
* hosts, so don't bother checking for errors.
* If anything goes wrong with it under other filesystems,
* mmap will fail.
*/
ftruncate(fd, memory);
#ifdef MAP_POPULATE
/* NB: MAP_POPULATE won't exhaustively alloc all phys pages in the case
* MAP_PRIVATE is requested. For mem_prealloc we mmap as MAP_SHARED
* to sidestep this quirk.
*/
flags = mem_prealloc ? MAP_POPULATE|MAP_SHARED : MAP_PRIVATE;
area = mmap(0, memory, PROT_READ|PROT_WRITE, flags, fd, 0);
#else
area = mmap(0, memory, PROT_READ|PROT_WRITE, MAP_PRIVATE, fd, 0);
#endif
if (area == MAP_FAILED) {
perror("alloc_mem_area: can't mmap hugetlbfs pages");
close(fd);
return (NULL);
}
return area;
}
#else
static void *file_ram_alloc(ram_addr_t memory, const char *path)
{
return NULL;
}
#endif
extern const char *mem_path;
ram_addr_t qemu_ram_alloc(ram_addr_t size)
{
RAMBlock *new_block;
#ifdef CONFIG_KQEMU
if (kqemu_phys_ram_base) {
return kqemu_ram_alloc(size);
}
#endif
size = TARGET_PAGE_ALIGN(size);
new_block = qemu_malloc(sizeof(*new_block));
new_block->host = file_ram_alloc(size, mem_path);
if (!new_block->host) {
new_block->host = qemu_vmalloc(size);
}
new_block->offset = last_ram_offset;
new_block->length = size;
new_block->next = ram_blocks;
ram_blocks = new_block;
phys_ram_dirty = qemu_realloc(phys_ram_dirty,
(last_ram_offset + size) >> TARGET_PAGE_BITS);
memset(phys_ram_dirty + (last_ram_offset >> TARGET_PAGE_BITS),
0xff, size >> TARGET_PAGE_BITS);
last_ram_offset += size;
if (kvm_enabled())
kvm_setup_guest_memory(new_block->host, size);
return new_block->offset;
}
void qemu_ram_free(ram_addr_t addr)
{
/* TODO: implement this. */
}
/* Return a host pointer to ram allocated with qemu_ram_alloc.
With the exception of the softmmu code in this file, this should
only be used for local memory (e.g. video ram) that the device owns,
and knows it isn't going to access beyond the end of the block.
It should not be used for general purpose DMA.
Use cpu_physical_memory_map/cpu_physical_memory_rw instead.
*/
void *qemu_get_ram_ptr(ram_addr_t addr)
{
RAMBlock *prev;
RAMBlock **prevp;
RAMBlock *block;
#ifdef CONFIG_KQEMU
if (kqemu_phys_ram_base) {
return kqemu_phys_ram_base + addr;
}
#endif
prev = NULL;
prevp = &ram_blocks;
block = ram_blocks;
while (block && (block->offset > addr
|| block->offset + block->length <= addr)) {
if (prev)
prevp = &prev->next;
prev = block;
block = block->next;
}
if (!block) {
fprintf(stderr, "Bad ram offset %" PRIx64 "\n", (uint64_t)addr);
abort();
}
/* Move this entry to to start of the list. */
if (prev) {
prev->next = block->next;
block->next = *prevp;
*prevp = block;
}
return block->host + (addr - block->offset);
}
/* Some of the softmmu routines need to translate from a host pointer
(typically a TLB entry) back to a ram offset. */
ram_addr_t qemu_ram_addr_from_host(void *ptr)
{
RAMBlock *prev;
RAMBlock **prevp;
RAMBlock *block;
uint8_t *host = ptr;
#ifdef CONFIG_KQEMU
if (kqemu_phys_ram_base) {
return host - kqemu_phys_ram_base;
}
#endif
prev = NULL;
prevp = &ram_blocks;
block = ram_blocks;
while (block && (block->host > host
|| block->host + block->length <= host)) {
if (prev)
prevp = &prev->next;
prev = block;
block = block->next;
}
if (!block) {
fprintf(stderr, "Bad ram pointer %p\n", ptr);
abort();
}
return block->offset + (host - block->host);
}
static uint32_t unassigned_mem_readb(void *opaque, target_phys_addr_t addr)
{
#ifdef DEBUG_UNASSIGNED
printf("Unassigned mem read " TARGET_FMT_plx "\n", addr);
#endif
#if defined(TARGET_SPARC)
do_unassigned_access(addr, 0, 0, 0, 1);
#endif
return 0;
}
static uint32_t unassigned_mem_readw(void *opaque, target_phys_addr_t addr)
{
#ifdef DEBUG_UNASSIGNED
printf("Unassigned mem read " TARGET_FMT_plx "\n", addr);
#endif
#if defined(TARGET_SPARC)
do_unassigned_access(addr, 0, 0, 0, 2);
#endif
return 0;
}
static uint32_t unassigned_mem_readl(void *opaque, target_phys_addr_t addr)
{
#ifdef DEBUG_UNASSIGNED
printf("Unassigned mem read " TARGET_FMT_plx "\n", addr);
#endif
#if defined(TARGET_SPARC)
do_unassigned_access(addr, 0, 0, 0, 4);
#endif
return 0;
}
static void unassigned_mem_writeb(void *opaque, target_phys_addr_t addr, uint32_t val)
{
#ifdef DEBUG_UNASSIGNED
printf("Unassigned mem write " TARGET_FMT_plx " = 0x%x\n", addr, val);
#endif
#if defined(TARGET_SPARC)
do_unassigned_access(addr, 1, 0, 0, 1);
#endif
}
static void unassigned_mem_writew(void *opaque, target_phys_addr_t addr, uint32_t val)
{
#ifdef DEBUG_UNASSIGNED
printf("Unassigned mem write " TARGET_FMT_plx " = 0x%x\n", addr, val);
#endif
#if defined(TARGET_SPARC)
do_unassigned_access(addr, 1, 0, 0, 2);
#endif
}
static void unassigned_mem_writel(void *opaque, target_phys_addr_t addr, uint32_t val)
{
#ifdef DEBUG_UNASSIGNED
printf("Unassigned mem write " TARGET_FMT_plx " = 0x%x\n", addr, val);
#endif
#if defined(TARGET_SPARC)
do_unassigned_access(addr, 1, 0, 0, 4);
#endif
}
static CPUReadMemoryFunc *unassigned_mem_read[3] = {
unassigned_mem_readb,
unassigned_mem_readw,
unassigned_mem_readl,
};
static CPUWriteMemoryFunc *unassigned_mem_write[3] = {
unassigned_mem_writeb,
unassigned_mem_writew,
unassigned_mem_writel,
};
static void notdirty_mem_writeb(void *opaque, target_phys_addr_t ram_addr,
uint32_t val)
{
int dirty_flags;
dirty_flags = phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS];
if (!(dirty_flags & CODE_DIRTY_FLAG)) {
#if !defined(CONFIG_USER_ONLY)
tb_invalidate_phys_page_fast(ram_addr, 1);
dirty_flags = phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS];
#endif
}
stb_p(qemu_get_ram_ptr(ram_addr), val);
#ifdef CONFIG_KQEMU
if (cpu_single_env->kqemu_enabled &&
(dirty_flags & KQEMU_MODIFY_PAGE_MASK) != KQEMU_MODIFY_PAGE_MASK)
kqemu_modify_page(cpu_single_env, ram_addr);
#endif
dirty_flags |= (0xff & ~CODE_DIRTY_FLAG);
phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS] = dirty_flags;
/* we remove the notdirty callback only if the code has been
flushed */
if (dirty_flags == 0xff)
tlb_set_dirty(cpu_single_env, cpu_single_env->mem_io_vaddr);
}
static void notdirty_mem_writew(void *opaque, target_phys_addr_t ram_addr,
uint32_t val)
{
int dirty_flags;
dirty_flags = phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS];
if (!(dirty_flags & CODE_DIRTY_FLAG)) {
#if !defined(CONFIG_USER_ONLY)
tb_invalidate_phys_page_fast(ram_addr, 2);
dirty_flags = phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS];
#endif
}
stw_p(qemu_get_ram_ptr(ram_addr), val);
#ifdef CONFIG_KQEMU
if (cpu_single_env->kqemu_enabled &&
(dirty_flags & KQEMU_MODIFY_PAGE_MASK) != KQEMU_MODIFY_PAGE_MASK)
kqemu_modify_page(cpu_single_env, ram_addr);
#endif
dirty_flags |= (0xff & ~CODE_DIRTY_FLAG);
phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS] = dirty_flags;
/* we remove the notdirty callback only if the code has been
flushed */
if (dirty_flags == 0xff)
tlb_set_dirty(cpu_single_env, cpu_single_env->mem_io_vaddr);
}
static void notdirty_mem_writel(void *opaque, target_phys_addr_t ram_addr,
uint32_t val)
{
int dirty_flags;
dirty_flags = phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS];
if (!(dirty_flags & CODE_DIRTY_FLAG)) {
#if !defined(CONFIG_USER_ONLY)
tb_invalidate_phys_page_fast(ram_addr, 4);
dirty_flags = phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS];
#endif
}
stl_p(qemu_get_ram_ptr(ram_addr), val);
#ifdef CONFIG_KQEMU
if (cpu_single_env->kqemu_enabled &&
(dirty_flags & KQEMU_MODIFY_PAGE_MASK) != KQEMU_MODIFY_PAGE_MASK)
kqemu_modify_page(cpu_single_env, ram_addr);
#endif
dirty_flags |= (0xff & ~CODE_DIRTY_FLAG);
phys_ram_dirty[ram_addr >> TARGET_PAGE_BITS] = dirty_flags;
/* we remove the notdirty callback only if the code has been
flushed */
if (dirty_flags == 0xff)
tlb_set_dirty(cpu_single_env, cpu_single_env->mem_io_vaddr);
}
static CPUReadMemoryFunc *error_mem_read[3] = {
NULL, /* never used */
NULL, /* never used */
NULL, /* never used */
};
static CPUWriteMemoryFunc *notdirty_mem_write[3] = {
notdirty_mem_writeb,
notdirty_mem_writew,
notdirty_mem_writel,
};
/* Generate a debug exception if a watchpoint has been hit. */
static void check_watchpoint(int offset, int len_mask, int flags)
{
CPUState *env = cpu_single_env;
target_ulong pc, cs_base;
TranslationBlock *tb;
target_ulong vaddr;
CPUWatchpoint *wp;
int cpu_flags;
if (env->watchpoint_hit) {
/* We re-entered the check after replacing the TB. Now raise
* the debug interrupt so that is will trigger after the
* current instruction. */
cpu_interrupt(env, CPU_INTERRUPT_DEBUG);
return;
}
vaddr = (env->mem_io_vaddr & TARGET_PAGE_MASK) + offset;
TAILQ_FOREACH(wp, &env->watchpoints, entry) {
if ((vaddr == (wp->vaddr & len_mask) ||
(vaddr & wp->len_mask) == wp->vaddr) && (wp->flags & flags)) {
wp->flags |= BP_WATCHPOINT_HIT;
if (!env->watchpoint_hit) {
env->watchpoint_hit = wp;
tb = tb_find_pc(env->mem_io_pc);
if (!tb) {
cpu_abort(env, "check_watchpoint: could not find TB for "
"pc=%p", (void *)env->mem_io_pc);
}
cpu_restore_state(tb, env, env->mem_io_pc, NULL);
tb_phys_invalidate(tb, -1);
if (wp->flags & BP_STOP_BEFORE_ACCESS) {
env->exception_index = EXCP_DEBUG;
} else {
cpu_get_tb_cpu_state(env, &pc, &cs_base, &cpu_flags);
tb_gen_code(env, pc, cs_base, cpu_flags, 1);
}
cpu_resume_from_signal(env, NULL);
}
} else {
wp->flags &= ~BP_WATCHPOINT_HIT;
}
}
}
/* Watchpoint access routines. Watchpoints are inserted using TLB tricks,
so these check for a hit then pass through to the normal out-of-line
phys routines. */
static uint32_t watch_mem_readb(void *opaque, target_phys_addr_t addr)
{
check_watchpoint(addr & ~TARGET_PAGE_MASK, ~0x0, BP_MEM_READ);
return ldub_phys(addr);
}
static uint32_t watch_mem_readw(void *opaque, target_phys_addr_t addr)
{
check_watchpoint(addr & ~TARGET_PAGE_MASK, ~0x1, BP_MEM_READ);
return lduw_phys(addr);
}
static uint32_t watch_mem_readl(void *opaque, target_phys_addr_t addr)
{
check_watchpoint(addr & ~TARGET_PAGE_MASK, ~0x3, BP_MEM_READ);
return ldl_phys(addr);
}
static void watch_mem_writeb(void *opaque, target_phys_addr_t addr,
uint32_t val)
{
check_watchpoint(addr & ~TARGET_PAGE_MASK, ~0x0, BP_MEM_WRITE);
stb_phys(addr, val);
}
static void watch_mem_writew(void *opaque, target_phys_addr_t addr,
uint32_t val)
{
check_watchpoint(addr & ~TARGET_PAGE_MASK, ~0x1, BP_MEM_WRITE);
stw_phys(addr, val);
}
static void watch_mem_writel(void *opaque, target_phys_addr_t addr,
uint32_t val)
{
check_watchpoint(addr & ~TARGET_PAGE_MASK, ~0x3, BP_MEM_WRITE);
stl_phys(addr, val);
}
static CPUReadMemoryFunc *watch_mem_read[3] = {
watch_mem_readb,
watch_mem_readw,
watch_mem_readl,
};
static CPUWriteMemoryFunc *watch_mem_write[3] = {
watch_mem_writeb,
watch_mem_writew,
watch_mem_writel,
};
static inline uint32_t subpage_readlen (subpage_t *mmio, target_phys_addr_t addr,
unsigned int len)
{
uint32_t ret;
unsigned int idx;
idx = SUBPAGE_IDX(addr);
#if defined(DEBUG_SUBPAGE)
printf("%s: subpage %p len %d addr " TARGET_FMT_plx " idx %d\n", __func__,
mmio, len, addr, idx);
#endif
ret = (**mmio->mem_read[idx][len])(mmio->opaque[idx][0][len],
addr + mmio->region_offset[idx][0][len]);
return ret;
}
static inline void subpage_writelen (subpage_t *mmio, target_phys_addr_t addr,
uint32_t value, unsigned int len)
{
unsigned int idx;
idx = SUBPAGE_IDX(addr);
#if defined(DEBUG_SUBPAGE)
printf("%s: subpage %p len %d addr " TARGET_FMT_plx " idx %d value %08x\n", __func__,
mmio, len, addr, idx, value);
#endif
(**mmio->mem_write[idx][len])(mmio->opaque[idx][1][len],
addr + mmio->region_offset[idx][1][len],
value);
}
static uint32_t subpage_readb (void *opaque, target_phys_addr_t addr)
{
#if defined(DEBUG_SUBPAGE)
printf("%s: addr " TARGET_FMT_plx "\n", __func__, addr);
#endif
return subpage_readlen(opaque, addr, 0);
}
static void subpage_writeb (void *opaque, target_phys_addr_t addr,
uint32_t value)
{
#if defined(DEBUG_SUBPAGE)
printf("%s: addr " TARGET_FMT_plx " val %08x\n", __func__, addr, value);
#endif
subpage_writelen(opaque, addr, value, 0);
}
static uint32_t subpage_readw (void *opaque, target_phys_addr_t addr)
{
#if defined(DEBUG_SUBPAGE)
printf("%s: addr " TARGET_FMT_plx "\n", __func__, addr);
#endif
return subpage_readlen(opaque, addr, 1);
}
static void subpage_writew (void *opaque, target_phys_addr_t addr,
uint32_t value)
{
#if defined(DEBUG_SUBPAGE)
printf("%s: addr " TARGET_FMT_plx " val %08x\n", __func__, addr, value);
#endif
subpage_writelen(opaque, addr, value, 1);
}
static uint32_t subpage_readl (void *opaque, target_phys_addr_t addr)
{
#if defined(DEBUG_SUBPAGE)
printf("%s: addr " TARGET_FMT_plx "\n", __func__, addr);
#endif
return subpage_readlen(opaque, addr, 2);
}
static void subpage_writel (void *opaque,
target_phys_addr_t addr, uint32_t value)
{
#if defined(DEBUG_SUBPAGE)
printf("%s: addr " TARGET_FMT_plx " val %08x\n", __func__, addr, value);
#endif
subpage_writelen(opaque, addr, value, 2);
}
static CPUReadMemoryFunc *subpage_read[] = {
&subpage_readb,
&subpage_readw,
&subpage_readl,
};
static CPUWriteMemoryFunc *subpage_write[] = {
&subpage_writeb,
&subpage_writew,
&subpage_writel,
};
static int subpage_register (subpage_t *mmio, uint32_t start, uint32_t end,
ram_addr_t memory, ram_addr_t region_offset)
{
int idx, eidx;
unsigned int i;
if (start >= TARGET_PAGE_SIZE || end >= TARGET_PAGE_SIZE)
return -1;
idx = SUBPAGE_IDX(start);
eidx = SUBPAGE_IDX(end);
#if defined(DEBUG_SUBPAGE)
printf("%s: %p start %08x end %08x idx %08x eidx %08x mem %ld\n", __func__,
mmio, start, end, idx, eidx, memory);
#endif
memory >>= IO_MEM_SHIFT;
for (; idx <= eidx; idx++) {
for (i = 0; i < 4; i++) {
if (io_mem_read[memory][i]) {
mmio->mem_read[idx][i] = &io_mem_read[memory][i];
mmio->opaque[idx][0][i] = io_mem_opaque[memory];
mmio->region_offset[idx][0][i] = region_offset;
}
if (io_mem_write[memory][i]) {
mmio->mem_write[idx][i] = &io_mem_write[memory][i];
mmio->opaque[idx][1][i] = io_mem_opaque[memory];
mmio->region_offset[idx][1][i] = region_offset;
}
}
}
return 0;
}
static void *subpage_init (target_phys_addr_t base, ram_addr_t *phys,
ram_addr_t orig_memory, ram_addr_t region_offset)
{
subpage_t *mmio;
int subpage_memory;
mmio = qemu_mallocz(sizeof(subpage_t));
mmio->base = base;
subpage_memory = cpu_register_io_memory(subpage_read, subpage_write, mmio);
#if defined(DEBUG_SUBPAGE)
printf("%s: %p base " TARGET_FMT_plx " len %08x %d\n", __func__,
mmio, base, TARGET_PAGE_SIZE, subpage_memory);
#endif
*phys = subpage_memory | IO_MEM_SUBPAGE;
subpage_register(mmio, 0, TARGET_PAGE_SIZE - 1, orig_memory,
region_offset);
return mmio;
}
static int get_free_io_mem_idx(void)
{
int i;
for (i = 0; i<IO_MEM_NB_ENTRIES; i++)
if (!io_mem_used[i]) {
io_mem_used[i] = 1;
return i;
}
return -1;
}
/* mem_read and mem_write are arrays of functions containing the
function to access byte (index 0), word (index 1) and dword (index
2). Functions can be omitted with a NULL function pointer.
If io_index is non zero, the corresponding io zone is
modified. If it is zero, a new io zone is allocated. The return
value can be used with cpu_register_physical_memory(). (-1) is
returned if error. */
static int cpu_register_io_memory_fixed(int io_index,
CPUReadMemoryFunc **mem_read,
CPUWriteMemoryFunc **mem_write,
void *opaque)
{
int i, subwidth = 0;
if (io_index <= 0) {
io_index = get_free_io_mem_idx();
if (io_index == -1)
return io_index;
} else {
io_index >>= IO_MEM_SHIFT;
if (io_index >= IO_MEM_NB_ENTRIES)
return -1;
}
for(i = 0;i < 3; i++) {
if (!mem_read[i] || !mem_write[i])
subwidth = IO_MEM_SUBWIDTH;
io_mem_read[io_index][i] = mem_read[i];
io_mem_write[io_index][i] = mem_write[i];
}
io_mem_opaque[io_index] = opaque;
return (io_index << IO_MEM_SHIFT) | subwidth;
}
int cpu_register_io_memory(CPUReadMemoryFunc **mem_read,
CPUWriteMemoryFunc **mem_write,
void *opaque)
{
return cpu_register_io_memory_fixed(0, mem_read, mem_write, opaque);
}
void cpu_unregister_io_memory(int io_table_address)
{
int i;
int io_index = io_table_address >> IO_MEM_SHIFT;
for (i=0;i < 3; i++) {
io_mem_read[io_index][i] = unassigned_mem_read[i];
io_mem_write[io_index][i] = unassigned_mem_write[i];
}
io_mem_opaque[io_index] = NULL;
io_mem_used[io_index] = 0;
}
static void io_mem_init(void)
{
int i;
cpu_register_io_memory_fixed(IO_MEM_ROM, error_mem_read, unassigned_mem_write, NULL);
cpu_register_io_memory_fixed(IO_MEM_UNASSIGNED, unassigned_mem_read, unassigned_mem_write, NULL);
cpu_register_io_memory_fixed(IO_MEM_NOTDIRTY, error_mem_read, notdirty_mem_write, NULL);
for (i=0; i<5; i++)
io_mem_used[i] = 1;
io_mem_watch = cpu_register_io_memory(watch_mem_read,
watch_mem_write, NULL);
#ifdef CONFIG_KQEMU
if (kqemu_phys_ram_base) {
/* alloc dirty bits array */
phys_ram_dirty = qemu_vmalloc(kqemu_phys_ram_size >> TARGET_PAGE_BITS);
memset(phys_ram_dirty, 0xff, kqemu_phys_ram_size >> TARGET_PAGE_BITS);
}
#endif
}
#endif /* !defined(CONFIG_USER_ONLY) */
/* physical memory access (slow version, mainly for debug) */
#if defined(CONFIG_USER_ONLY)
void cpu_physical_memory_rw(target_phys_addr_t addr, uint8_t *buf,
int len, int is_write)
{
int l, flags;
target_ulong page;
void * p;
while (len > 0) {
page = addr & TARGET_PAGE_MASK;
l = (page + TARGET_PAGE_SIZE) - addr;
if (l > len)
l = len;
flags = page_get_flags(page);
if (!(flags & PAGE_VALID))
return;
if (is_write) {
if (!(flags & PAGE_WRITE))
return;
/* XXX: this code should not depend on lock_user */
if (!(p = lock_user(VERIFY_WRITE, addr, l, 0)))
/* FIXME - should this return an error rather than just fail? */
return;
memcpy(p, buf, l);
unlock_user(p, addr, l);
} else {
if (!(flags & PAGE_READ))
return;
/* XXX: this code should not depend on lock_user */
if (!(p = lock_user(VERIFY_READ, addr, l, 1)))
/* FIXME - should this return an error rather than just fail? */
return;
memcpy(buf, p, l);
unlock_user(p, addr, 0);
}
len -= l;
buf += l;
addr += l;
}
}
#else
void cpu_physical_memory_rw(target_phys_addr_t addr, uint8_t *buf,
int len, int is_write)
{
int l, io_index;
uint8_t *ptr;
uint32_t val;
target_phys_addr_t page;
unsigned long pd;
PhysPageDesc *p;
while (len > 0) {
page = addr & TARGET_PAGE_MASK;
l = (page + TARGET_PAGE_SIZE) - addr;
if (l > len)
l = len;
p = phys_page_find(page >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
if (is_write) {
if ((pd & ~TARGET_PAGE_MASK) != IO_MEM_RAM) {
target_phys_addr_t addr1 = addr;
io_index = (pd >> IO_MEM_SHIFT) & (IO_MEM_NB_ENTRIES - 1);
if (p)
addr1 = (addr & ~TARGET_PAGE_MASK) + p->region_offset;
/* XXX: could force cpu_single_env to NULL to avoid
potential bugs */
if (l >= 4 && ((addr1 & 3) == 0)) {
/* 32 bit write access */
val = ldl_p(buf);
io_mem_write[io_index][2](io_mem_opaque[io_index], addr1, val);
l = 4;
} else if (l >= 2 && ((addr1 & 1) == 0)) {
/* 16 bit write access */
val = lduw_p(buf);
io_mem_write[io_index][1](io_mem_opaque[io_index], addr1, val);
l = 2;
} else {
/* 8 bit write access */
val = ldub_p(buf);
io_mem_write[io_index][0](io_mem_opaque[io_index], addr1, val);
l = 1;
}
} else {
unsigned long addr1;
addr1 = (pd & TARGET_PAGE_MASK) + (addr & ~TARGET_PAGE_MASK);
/* RAM case */
ptr = qemu_get_ram_ptr(addr1);
memcpy(ptr, buf, l);
if (!cpu_physical_memory_is_dirty(addr1)) {
/* invalidate code */
tb_invalidate_phys_page_range(addr1, addr1 + l, 0);
/* set dirty bit */
phys_ram_dirty[addr1 >> TARGET_PAGE_BITS] |=
(0xff & ~CODE_DIRTY_FLAG);
}
/* qemu doesn't execute guest code directly, but kvm does
therefore flush instruction caches */
if (kvm_enabled())
flush_icache_range((unsigned long)ptr,
((unsigned long)ptr)+l);
}
} else {
if ((pd & ~TARGET_PAGE_MASK) > IO_MEM_ROM &&
!(pd & IO_MEM_ROMD)) {
target_phys_addr_t addr1 = addr;
/* I/O case */
io_index = (pd >> IO_MEM_SHIFT) & (IO_MEM_NB_ENTRIES - 1);
if (p)
addr1 = (addr & ~TARGET_PAGE_MASK) + p->region_offset;
if (l >= 4 && ((addr1 & 3) == 0)) {
/* 32 bit read access */
val = io_mem_read[io_index][2](io_mem_opaque[io_index], addr1);
stl_p(buf, val);
l = 4;
} else if (l >= 2 && ((addr1 & 1) == 0)) {
/* 16 bit read access */
val = io_mem_read[io_index][1](io_mem_opaque[io_index], addr1);
stw_p(buf, val);
l = 2;
} else {
/* 8 bit read access */
val = io_mem_read[io_index][0](io_mem_opaque[io_index], addr1);
stb_p(buf, val);
l = 1;
}
} else {
/* RAM case */
ptr = qemu_get_ram_ptr(pd & TARGET_PAGE_MASK) +
(addr & ~TARGET_PAGE_MASK);
memcpy(buf, ptr, l);
}
}
len -= l;
buf += l;
addr += l;
}
}
/* used for ROM loading : can write in RAM and ROM */
void cpu_physical_memory_write_rom(target_phys_addr_t addr,
const uint8_t *buf, int len)
{
int l;
uint8_t *ptr;
target_phys_addr_t page;
unsigned long pd;
PhysPageDesc *p;
while (len > 0) {
page = addr & TARGET_PAGE_MASK;
l = (page + TARGET_PAGE_SIZE) - addr;
if (l > len)
l = len;
p = phys_page_find(page >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
if ((pd & ~TARGET_PAGE_MASK) != IO_MEM_RAM &&
(pd & ~TARGET_PAGE_MASK) != IO_MEM_ROM &&
!(pd & IO_MEM_ROMD)) {
/* do nothing */
} else {
unsigned long addr1;
addr1 = (pd & TARGET_PAGE_MASK) + (addr & ~TARGET_PAGE_MASK);
/* ROM/RAM case */
ptr = qemu_get_ram_ptr(addr1);
memcpy(ptr, buf, l);
}
len -= l;
buf += l;
addr += l;
}
}
typedef struct {
void *buffer;
target_phys_addr_t addr;
target_phys_addr_t len;
} BounceBuffer;
static BounceBuffer bounce;
typedef struct MapClient {
void *opaque;
void (*callback)(void *opaque);
LIST_ENTRY(MapClient) link;
} MapClient;
static LIST_HEAD(map_client_list, MapClient) map_client_list
= LIST_HEAD_INITIALIZER(map_client_list);
void *cpu_register_map_client(void *opaque, void (*callback)(void *opaque))
{
MapClient *client = qemu_malloc(sizeof(*client));
client->opaque = opaque;
client->callback = callback;
LIST_INSERT_HEAD(&map_client_list, client, link);
return client;
}
void cpu_unregister_map_client(void *_client)
{
MapClient *client = (MapClient *)_client;
LIST_REMOVE(client, link);
qemu_free(client);
}
static void cpu_notify_map_clients(void)
{
MapClient *client;
while (!LIST_EMPTY(&map_client_list)) {
client = LIST_FIRST(&map_client_list);
client->callback(client->opaque);
cpu_unregister_map_client(client);
}
}
/* Map a physical memory region into a host virtual address.
* May map a subset of the requested range, given by and returned in *plen.
* May return NULL if resources needed to perform the mapping are exhausted.
* Use only for reads OR writes - not for read-modify-write operations.
* Use cpu_register_map_client() to know when retrying the map operation is
* likely to succeed.
*/
void *cpu_physical_memory_map(target_phys_addr_t addr,
target_phys_addr_t *plen,
int is_write)
{
target_phys_addr_t len = *plen;
target_phys_addr_t done = 0;
int l;
uint8_t *ret = NULL;
uint8_t *ptr;
target_phys_addr_t page;
unsigned long pd;
PhysPageDesc *p;
unsigned long addr1;
while (len > 0) {
page = addr & TARGET_PAGE_MASK;
l = (page + TARGET_PAGE_SIZE) - addr;
if (l > len)
l = len;
p = phys_page_find(page >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
if ((pd & ~TARGET_PAGE_MASK) != IO_MEM_RAM) {
if (done || bounce.buffer) {
break;
}
bounce.buffer = qemu_memalign(TARGET_PAGE_SIZE, TARGET_PAGE_SIZE);
bounce.addr = addr;
bounce.len = l;
if (!is_write) {
cpu_physical_memory_rw(addr, bounce.buffer, l, 0);
}
ptr = bounce.buffer;
} else {
addr1 = (pd & TARGET_PAGE_MASK) + (addr & ~TARGET_PAGE_MASK);
ptr = qemu_get_ram_ptr(addr1);
}
if (!done) {
ret = ptr;
} else if (ret + done != ptr) {
break;
}
len -= l;
addr += l;
done += l;
}
*plen = done;
return ret;
}
/* Unmaps a memory region previously mapped by cpu_physical_memory_map().
* Will also mark the memory as dirty if is_write == 1. access_len gives
* the amount of memory that was actually read or written by the caller.
*/
void cpu_physical_memory_unmap(void *buffer, target_phys_addr_t len,
int is_write, target_phys_addr_t access_len)
{
unsigned long flush_len = (unsigned long)access_len;
if (buffer != bounce.buffer) {
if (is_write) {
ram_addr_t addr1 = qemu_ram_addr_from_host(buffer);
while (access_len) {
unsigned l;
l = TARGET_PAGE_SIZE;
if (l > access_len)
l = access_len;
if (!cpu_physical_memory_is_dirty(addr1)) {
/* invalidate code */
tb_invalidate_phys_page_range(addr1, addr1 + l, 0);
/* set dirty bit */
phys_ram_dirty[addr1 >> TARGET_PAGE_BITS] |=
(0xff & ~CODE_DIRTY_FLAG);
}
addr1 += l;
access_len -= l;
}
dma_flush_range((unsigned long)buffer,
(unsigned long)buffer + flush_len);
}
return;
}
if (is_write) {
cpu_physical_memory_write(bounce.addr, bounce.buffer, access_len);
}
qemu_free(bounce.buffer);
bounce.buffer = NULL;
cpu_notify_map_clients();
}
/* warning: addr must be aligned */
uint32_t ldl_phys(target_phys_addr_t addr)
{
int io_index;
uint8_t *ptr;
uint32_t val;
unsigned long pd;
PhysPageDesc *p;
p = phys_page_find(addr >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
if ((pd & ~TARGET_PAGE_MASK) > IO_MEM_ROM &&
!(pd & IO_MEM_ROMD)) {
/* I/O case */
io_index = (pd >> IO_MEM_SHIFT) & (IO_MEM_NB_ENTRIES - 1);
if (p)
addr = (addr & ~TARGET_PAGE_MASK) + p->region_offset;
val = io_mem_read[io_index][2](io_mem_opaque[io_index], addr);
} else {
/* RAM case */
ptr = qemu_get_ram_ptr(pd & TARGET_PAGE_MASK) +
(addr & ~TARGET_PAGE_MASK);
val = ldl_p(ptr);
}
return val;
}
/* warning: addr must be aligned */
uint64_t ldq_phys(target_phys_addr_t addr)
{
int io_index;
uint8_t *ptr;
uint64_t val;
unsigned long pd;
PhysPageDesc *p;
p = phys_page_find(addr >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
if ((pd & ~TARGET_PAGE_MASK) > IO_MEM_ROM &&
!(pd & IO_MEM_ROMD)) {
/* I/O case */
io_index = (pd >> IO_MEM_SHIFT) & (IO_MEM_NB_ENTRIES - 1);
if (p)
addr = (addr & ~TARGET_PAGE_MASK) + p->region_offset;
#ifdef TARGET_WORDS_BIGENDIAN
val = (uint64_t)io_mem_read[io_index][2](io_mem_opaque[io_index], addr) << 32;
val |= io_mem_read[io_index][2](io_mem_opaque[io_index], addr + 4);
#else
val = io_mem_read[io_index][2](io_mem_opaque[io_index], addr);
val |= (uint64_t)io_mem_read[io_index][2](io_mem_opaque[io_index], addr + 4) << 32;
#endif
} else {
/* RAM case */
ptr = qemu_get_ram_ptr(pd & TARGET_PAGE_MASK) +
(addr & ~TARGET_PAGE_MASK);
val = ldq_p(ptr);
}
return val;
}
/* XXX: optimize */
uint32_t ldub_phys(target_phys_addr_t addr)
{
uint8_t val;
cpu_physical_memory_read(addr, &val, 1);
return val;
}
/* XXX: optimize */
uint32_t lduw_phys(target_phys_addr_t addr)
{
uint16_t val;
cpu_physical_memory_read(addr, (uint8_t *)&val, 2);
return tswap16(val);
}
/* warning: addr must be aligned. The ram page is not masked as dirty
and the code inside is not invalidated. It is useful if the dirty
bits are used to track modified PTEs */
void stl_phys_notdirty(target_phys_addr_t addr, uint32_t val)
{
int io_index;
uint8_t *ptr;
unsigned long pd;
PhysPageDesc *p;
p = phys_page_find(addr >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
if ((pd & ~TARGET_PAGE_MASK) != IO_MEM_RAM) {
io_index = (pd >> IO_MEM_SHIFT) & (IO_MEM_NB_ENTRIES - 1);
if (p)
addr = (addr & ~TARGET_PAGE_MASK) + p->region_offset;
io_mem_write[io_index][2](io_mem_opaque[io_index], addr, val);
} else {
unsigned long addr1 = (pd & TARGET_PAGE_MASK) + (addr & ~TARGET_PAGE_MASK);
ptr = qemu_get_ram_ptr(addr1);
stl_p(ptr, val);
if (unlikely(in_migration)) {
if (!cpu_physical_memory_is_dirty(addr1)) {
/* invalidate code */
tb_invalidate_phys_page_range(addr1, addr1 + 4, 0);
/* set dirty bit */
phys_ram_dirty[addr1 >> TARGET_PAGE_BITS] |=
(0xff & ~CODE_DIRTY_FLAG);
}
}
}
}
void stq_phys_notdirty(target_phys_addr_t addr, uint64_t val)
{
int io_index;
uint8_t *ptr;
unsigned long pd;
PhysPageDesc *p;
p = phys_page_find(addr >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
if ((pd & ~TARGET_PAGE_MASK) != IO_MEM_RAM) {
io_index = (pd >> IO_MEM_SHIFT) & (IO_MEM_NB_ENTRIES - 1);
if (p)
addr = (addr & ~TARGET_PAGE_MASK) + p->region_offset;
#ifdef TARGET_WORDS_BIGENDIAN
io_mem_write[io_index][2](io_mem_opaque[io_index], addr, val >> 32);
io_mem_write[io_index][2](io_mem_opaque[io_index], addr + 4, val);
#else
io_mem_write[io_index][2](io_mem_opaque[io_index], addr, val);
io_mem_write[io_index][2](io_mem_opaque[io_index], addr + 4, val >> 32);
#endif
} else {
ptr = qemu_get_ram_ptr(pd & TARGET_PAGE_MASK) +
(addr & ~TARGET_PAGE_MASK);
stq_p(ptr, val);
}
}
/* warning: addr must be aligned */
void stl_phys(target_phys_addr_t addr, uint32_t val)
{
int io_index;
uint8_t *ptr;
unsigned long pd;
PhysPageDesc *p;
p = phys_page_find(addr >> TARGET_PAGE_BITS);
if (!p) {
pd = IO_MEM_UNASSIGNED;
} else {
pd = p->phys_offset;
}
if ((pd & ~TARGET_PAGE_MASK) != IO_MEM_RAM) {
io_index = (pd >> IO_MEM_SHIFT) & (IO_MEM_NB_ENTRIES - 1);
if (p)
addr = (addr & ~TARGET_PAGE_MASK) + p->region_offset;
io_mem_write[io_index][2](io_mem_opaque[io_index], addr, val);
} else {
unsigned long addr1;
addr1 = (pd & TARGET_PAGE_MASK) + (addr & ~TARGET_PAGE_MASK);
/* RAM case */
ptr = qemu_get_ram_ptr(addr1);
stl_p(ptr, val);
if (!cpu_physical_memory_is_dirty(addr1)) {
/* invalidate code */
tb_invalidate_phys_page_range(addr1, addr1 + 4, 0);
/* set dirty bit */
phys_ram_dirty[addr1 >> TARGET_PAGE_BITS] |=
(0xff & ~CODE_DIRTY_FLAG);
}
}
}
/* XXX: optimize */
void stb_phys(target_phys_addr_t addr, uint32_t val)
{
uint8_t v = val;
cpu_physical_memory_write(addr, &v, 1);
}
/* XXX: optimize */
void stw_phys(target_phys_addr_t addr, uint32_t val)
{
uint16_t v = tswap16(val);
cpu_physical_memory_write(addr, (const uint8_t *)&v, 2);
}
/* XXX: optimize */
void stq_phys(target_phys_addr_t addr, uint64_t val)
{
val = tswap64(val);
cpu_physical_memory_write(addr, (const uint8_t *)&val, 8);
}
#endif
/* virtual memory access for debug (includes writing to ROM) */
int cpu_memory_rw_debug(CPUState *env, target_ulong addr,
uint8_t *buf, int len, int is_write)
{
int l;
target_phys_addr_t phys_addr;
target_ulong page;
while (len > 0) {
page = addr & TARGET_PAGE_MASK;
phys_addr = cpu_get_phys_page_debug(env, page);
/* if no physical page mapped, return an error */
if (phys_addr == -1)
return -1;
l = (page + TARGET_PAGE_SIZE) - addr;
if (l > len)
l = len;
phys_addr += (addr & ~TARGET_PAGE_MASK);
#if !defined(CONFIG_USER_ONLY)
if (is_write)
cpu_physical_memory_write_rom(phys_addr, buf, l);
else
#endif
cpu_physical_memory_rw(phys_addr, buf, l, is_write);
len -= l;
buf += l;
addr += l;
}
return 0;
}
/* in deterministic execution mode, instructions doing device I/Os
must be at the end of the TB */
void cpu_io_recompile(CPUState *env, void *retaddr)
{
TranslationBlock *tb;
uint32_t n, cflags;
target_ulong pc, cs_base;
uint64_t flags;
tb = tb_find_pc((unsigned long)retaddr);
if (!tb) {
cpu_abort(env, "cpu_io_recompile: could not find TB for pc=%p",
retaddr);
}
n = env->icount_decr.u16.low + tb->icount;
cpu_restore_state(tb, env, (unsigned long)retaddr, NULL);
/* Calculate how many instructions had been executed before the fault
occurred. */
n = n - env->icount_decr.u16.low;
/* Generate a new TB ending on the I/O insn. */
n++;
/* On MIPS and SH, delay slot instructions can only be restarted if
they were already the first instruction in the TB. If this is not
the first instruction in a TB then re-execute the preceding
branch. */
#if defined(TARGET_MIPS)
if ((env->hflags & MIPS_HFLAG_BMASK) != 0 && n > 1) {
env->active_tc.PC -= 4;
env->icount_decr.u16.low++;
env->hflags &= ~MIPS_HFLAG_BMASK;
}
#elif defined(TARGET_SH4)
if ((env->flags & ((DELAY_SLOT | DELAY_SLOT_CONDITIONAL))) != 0
&& n > 1) {
env->pc -= 2;
env->icount_decr.u16.low++;
env->flags &= ~(DELAY_SLOT | DELAY_SLOT_CONDITIONAL);
}
#endif
/* This should never happen. */
if (n > CF_COUNT_MASK)
cpu_abort(env, "TB too big during recompile");
cflags = n | CF_LAST_IO;
pc = tb->pc;
cs_base = tb->cs_base;
flags = tb->flags;
tb_phys_invalidate(tb, -1);
/* FIXME: In theory this could raise an exception. In practice
we have already translated the block once so it's probably ok. */
tb_gen_code(env, pc, cs_base, flags, cflags);
/* TODO: If env->pc != tb->pc (i.e. the faulting instruction was not
the first in the TB) then we end up generating a whole new TB and
repeating the fault, which is horribly inefficient.
Better would be to execute just this insn uncached, or generate a
second new TB. */
cpu_resume_from_signal(env, NULL);
}
void dump_exec_info(FILE *f,
int (*cpu_fprintf)(FILE *f, const char *fmt, ...))
{
int i, target_code_size, max_target_code_size;
int direct_jmp_count, direct_jmp2_count, cross_page;
TranslationBlock *tb;
target_code_size = 0;
max_target_code_size = 0;
cross_page = 0;
direct_jmp_count = 0;
direct_jmp2_count = 0;
for(i = 0; i < nb_tbs; i++) {
tb = &tbs[i];
target_code_size += tb->size;
if (tb->size > max_target_code_size)
max_target_code_size = tb->size;
if (tb->page_addr[1] != -1)
cross_page++;
if (tb->tb_next_offset[0] != 0xffff) {
direct_jmp_count++;
if (tb->tb_next_offset[1] != 0xffff) {
direct_jmp2_count++;
}
}
}
/* XXX: avoid using doubles ? */
cpu_fprintf(f, "Translation buffer state:\n");
cpu_fprintf(f, "gen code size %ld/%ld\n",
code_gen_ptr - code_gen_buffer, code_gen_buffer_max_size);
cpu_fprintf(f, "TB count %d/%d\n",
nb_tbs, code_gen_max_blocks);
cpu_fprintf(f, "TB avg target size %d max=%d bytes\n",
nb_tbs ? target_code_size / nb_tbs : 0,
max_target_code_size);
cpu_fprintf(f, "TB avg host size %d bytes (expansion ratio: %0.1f)\n",
nb_tbs ? (code_gen_ptr - code_gen_buffer) / nb_tbs : 0,
target_code_size ? (double) (code_gen_ptr - code_gen_buffer) / target_code_size : 0);
cpu_fprintf(f, "cross page TB count %d (%d%%)\n",
cross_page,
nb_tbs ? (cross_page * 100) / nb_tbs : 0);
cpu_fprintf(f, "direct jump count %d (%d%%) (2 jumps=%d %d%%)\n",
direct_jmp_count,
nb_tbs ? (direct_jmp_count * 100) / nb_tbs : 0,
direct_jmp2_count,
nb_tbs ? (direct_jmp2_count * 100) / nb_tbs : 0);
cpu_fprintf(f, "\nStatistics:\n");
cpu_fprintf(f, "TB flush count %d\n", tb_flush_count);
cpu_fprintf(f, "TB invalidate count %d\n", tb_phys_invalidate_count);
cpu_fprintf(f, "TLB flush count %d\n", tlb_flush_count);
tcg_dump_info(f, cpu_fprintf);
}
#if !defined(CONFIG_USER_ONLY)
#define MMUSUFFIX _cmmu
#define GETPC() NULL
#define env cpu_single_env
#define SOFTMMU_CODE_ACCESS
#define SHIFT 0
#include "softmmu_template.h"
#define SHIFT 1
#include "softmmu_template.h"
#define SHIFT 2
#include "softmmu_template.h"
#define SHIFT 3
#include "softmmu_template.h"
#undef env
#endif