qemu-e2k/exec.c

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/*
* Virtual page mapping
*
* 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 "qemu/osdep.h"
2016-03-14 09:01:28 +01:00
#include "qapi/error.h"
#ifndef _WIN32
#include <sys/mman.h>
#endif
#include "qemu/cutils.h"
#include "cpu.h"
#include "tcg.h"
#include "hw/hw.h"
#if !defined(CONFIG_USER_ONLY)
#include "hw/boards.h"
#endif
#include "hw/qdev.h"
#include "sysemu/kvm.h"
#include "sysemu/sysemu.h"
#include "hw/xen/xen.h"
#include "qemu/timer.h"
#include "qemu/config-file.h"
#include "qemu/error-report.h"
#include "exec/memory.h"
#include "sysemu/dma.h"
#include "exec/address-spaces.h"
#if defined(CONFIG_USER_ONLY)
#include <qemu.h>
#else /* !CONFIG_USER_ONLY */
#include "sysemu/xen-mapcache.h"
#include "trace.h"
#endif
#include "exec/cpu-all.h"
#include "qemu/rcu_queue.h"
#include "qemu/main-loop.h"
#include "translate-all.h"
#include "sysemu/replay.h"
#include "exec/memory-internal.h"
#include "exec/ram_addr.h"
#include "exec/log.h"
#include "qemu/range.h"
#ifndef _WIN32
#include "qemu/mmap-alloc.h"
#endif
//#define DEBUG_SUBPAGE
#if !defined(CONFIG_USER_ONLY)
/* ram_list is read under rcu_read_lock()/rcu_read_unlock(). Writes
* are protected by the ramlist lock.
*/
RAMList ram_list = { .blocks = QLIST_HEAD_INITIALIZER(ram_list.blocks) };
static MemoryRegion *system_memory;
static MemoryRegion *system_io;
AddressSpace address_space_io;
AddressSpace address_space_memory;
MemoryRegion io_mem_rom, io_mem_notdirty;
static MemoryRegion io_mem_unassigned;
/* RAM is pre-allocated and passed into qemu_ram_alloc_from_ptr */
#define RAM_PREALLOC (1 << 0)
/* RAM is mmap-ed with MAP_SHARED */
#define RAM_SHARED (1 << 1)
/* Only a portion of RAM (used_length) is actually used, and migrated.
* This used_length size can change across reboots.
*/
#define RAM_RESIZEABLE (1 << 2)
#endif
struct CPUTailQ cpus = QTAILQ_HEAD_INITIALIZER(cpus);
/* current CPU in the current thread. It is only valid inside
cpu_exec() */
__thread CPUState *current_cpu;
/* 0 = Do not count executed instructions.
1 = Precise instruction counting.
2 = Adaptive rate instruction counting. */
int use_icount;
#if !defined(CONFIG_USER_ONLY)
typedef struct PhysPageEntry PhysPageEntry;
struct PhysPageEntry {
/* How many bits skip to next level (in units of L2_SIZE). 0 for a leaf. */
uint32_t skip : 6;
/* index into phys_sections (!skip) or phys_map_nodes (skip) */
uint32_t ptr : 26;
};
#define PHYS_MAP_NODE_NIL (((uint32_t)~0) >> 6)
/* Size of the L2 (and L3, etc) page tables. */
#define ADDR_SPACE_BITS 64
#define P_L2_BITS 9
#define P_L2_SIZE (1 << P_L2_BITS)
#define P_L2_LEVELS (((ADDR_SPACE_BITS - TARGET_PAGE_BITS - 1) / P_L2_BITS) + 1)
typedef PhysPageEntry Node[P_L2_SIZE];
typedef struct PhysPageMap {
struct rcu_head rcu;
unsigned sections_nb;
unsigned sections_nb_alloc;
unsigned nodes_nb;
unsigned nodes_nb_alloc;
Node *nodes;
MemoryRegionSection *sections;
} PhysPageMap;
struct AddressSpaceDispatch {
struct rcu_head rcu;
MemoryRegionSection *mru_section;
/* This is a multi-level map on the physical address space.
* The bottom level has pointers to MemoryRegionSections.
*/
PhysPageEntry phys_map;
PhysPageMap map;
AddressSpace *as;
};
#define SUBPAGE_IDX(addr) ((addr) & ~TARGET_PAGE_MASK)
typedef struct subpage_t {
MemoryRegion iomem;
AddressSpace *as;
hwaddr base;
uint16_t sub_section[TARGET_PAGE_SIZE];
} subpage_t;
#define PHYS_SECTION_UNASSIGNED 0
#define PHYS_SECTION_NOTDIRTY 1
#define PHYS_SECTION_ROM 2
#define PHYS_SECTION_WATCH 3
static void io_mem_init(void);
static void memory_map_init(void);
static void tcg_commit(MemoryListener *listener);
static MemoryRegion io_mem_watch;
/**
* CPUAddressSpace: all the information a CPU needs about an AddressSpace
* @cpu: the CPU whose AddressSpace this is
* @as: the AddressSpace itself
* @memory_dispatch: its dispatch pointer (cached, RCU protected)
* @tcg_as_listener: listener for tracking changes to the AddressSpace
*/
struct CPUAddressSpace {
CPUState *cpu;
AddressSpace *as;
struct AddressSpaceDispatch *memory_dispatch;
MemoryListener tcg_as_listener;
};
#endif
#if !defined(CONFIG_USER_ONLY)
static void phys_map_node_reserve(PhysPageMap *map, unsigned nodes)
{
if (map->nodes_nb + nodes > map->nodes_nb_alloc) {
map->nodes_nb_alloc = MAX(map->nodes_nb_alloc * 2, 16);
map->nodes_nb_alloc = MAX(map->nodes_nb_alloc, map->nodes_nb + nodes);
map->nodes = g_renew(Node, map->nodes, map->nodes_nb_alloc);
}
}
static uint32_t phys_map_node_alloc(PhysPageMap *map, bool leaf)
{
unsigned i;
uint32_t ret;
PhysPageEntry e;
PhysPageEntry *p;
ret = map->nodes_nb++;
p = map->nodes[ret];
assert(ret != PHYS_MAP_NODE_NIL);
assert(ret != map->nodes_nb_alloc);
e.skip = leaf ? 0 : 1;
e.ptr = leaf ? PHYS_SECTION_UNASSIGNED : PHYS_MAP_NODE_NIL;
for (i = 0; i < P_L2_SIZE; ++i) {
memcpy(&p[i], &e, sizeof(e));
}
return ret;
}
static void phys_page_set_level(PhysPageMap *map, PhysPageEntry *lp,
hwaddr *index, hwaddr *nb, uint16_t leaf,
int level)
{
PhysPageEntry *p;
hwaddr step = (hwaddr)1 << (level * P_L2_BITS);
if (lp->skip && lp->ptr == PHYS_MAP_NODE_NIL) {
lp->ptr = phys_map_node_alloc(map, level == 0);
}
p = map->nodes[lp->ptr];
lp = &p[(*index >> (level * P_L2_BITS)) & (P_L2_SIZE - 1)];
while (*nb && lp < &p[P_L2_SIZE]) {
if ((*index & (step - 1)) == 0 && *nb >= step) {
lp->skip = 0;
lp->ptr = leaf;
*index += step;
*nb -= step;
} else {
phys_page_set_level(map, lp, index, nb, leaf, level - 1);
}
++lp;
}
}
static void phys_page_set(AddressSpaceDispatch *d,
hwaddr index, hwaddr nb,
uint16_t leaf)
{
/* Wildly overreserve - it doesn't matter much. */
phys_map_node_reserve(&d->map, 3 * P_L2_LEVELS);
phys_page_set_level(&d->map, &d->phys_map, &index, &nb, leaf, P_L2_LEVELS - 1);
}
/* Compact a non leaf page entry. Simply detect that the entry has a single child,
* and update our entry so we can skip it and go directly to the destination.
*/
static void phys_page_compact(PhysPageEntry *lp, Node *nodes, unsigned long *compacted)
{
unsigned valid_ptr = P_L2_SIZE;
int valid = 0;
PhysPageEntry *p;
int i;
if (lp->ptr == PHYS_MAP_NODE_NIL) {
return;
}
p = nodes[lp->ptr];
for (i = 0; i < P_L2_SIZE; i++) {
if (p[i].ptr == PHYS_MAP_NODE_NIL) {
continue;
}
valid_ptr = i;
valid++;
if (p[i].skip) {
phys_page_compact(&p[i], nodes, compacted);
}
}
/* We can only compress if there's only one child. */
if (valid != 1) {
return;
}
assert(valid_ptr < P_L2_SIZE);
/* Don't compress if it won't fit in the # of bits we have. */
if (lp->skip + p[valid_ptr].skip >= (1 << 3)) {
return;
}
lp->ptr = p[valid_ptr].ptr;
if (!p[valid_ptr].skip) {
/* If our only child is a leaf, make this a leaf. */
/* By design, we should have made this node a leaf to begin with so we
* should never reach here.
* But since it's so simple to handle this, let's do it just in case we
* change this rule.
*/
lp->skip = 0;
} else {
lp->skip += p[valid_ptr].skip;
}
}
static void phys_page_compact_all(AddressSpaceDispatch *d, int nodes_nb)
{
DECLARE_BITMAP(compacted, nodes_nb);
if (d->phys_map.skip) {
phys_page_compact(&d->phys_map, d->map.nodes, compacted);
}
}
static inline bool section_covers_addr(const MemoryRegionSection *section,
hwaddr addr)
{
/* Memory topology clips a memory region to [0, 2^64); size.hi > 0 means
* the section must cover the entire address space.
*/
return section->size.hi ||
range_covers_byte(section->offset_within_address_space,
section->size.lo, addr);
}
static MemoryRegionSection *phys_page_find(PhysPageEntry lp, hwaddr addr,
Node *nodes, MemoryRegionSection *sections)
{
PhysPageEntry *p;
hwaddr index = addr >> TARGET_PAGE_BITS;
int i;
for (i = P_L2_LEVELS; lp.skip && (i -= lp.skip) >= 0;) {
if (lp.ptr == PHYS_MAP_NODE_NIL) {
return &sections[PHYS_SECTION_UNASSIGNED];
}
p = nodes[lp.ptr];
lp = p[(index >> (i * P_L2_BITS)) & (P_L2_SIZE - 1)];
}
if (section_covers_addr(&sections[lp.ptr], addr)) {
return &sections[lp.ptr];
} else {
return &sections[PHYS_SECTION_UNASSIGNED];
}
}
bool memory_region_is_unassigned(MemoryRegion *mr)
{
return mr != &io_mem_rom && mr != &io_mem_notdirty && !mr->rom_device
&& mr != &io_mem_watch;
}
/* Called from RCU critical section */
static MemoryRegionSection *address_space_lookup_region(AddressSpaceDispatch *d,
hwaddr addr,
bool resolve_subpage)
{
MemoryRegionSection *section = atomic_read(&d->mru_section);
subpage_t *subpage;
bool update;
if (section && section != &d->map.sections[PHYS_SECTION_UNASSIGNED] &&
section_covers_addr(section, addr)) {
update = false;
} else {
section = phys_page_find(d->phys_map, addr, d->map.nodes,
d->map.sections);
update = true;
}
if (resolve_subpage && section->mr->subpage) {
subpage = container_of(section->mr, subpage_t, iomem);
section = &d->map.sections[subpage->sub_section[SUBPAGE_IDX(addr)]];
}
if (update) {
atomic_set(&d->mru_section, section);
}
return section;
}
/* Called from RCU critical section */
static MemoryRegionSection *
address_space_translate_internal(AddressSpaceDispatch *d, hwaddr addr, hwaddr *xlat,
hwaddr *plen, bool resolve_subpage)
{
MemoryRegionSection *section;
MemoryRegion *mr;
Int128 diff;
section = address_space_lookup_region(d, addr, resolve_subpage);
/* Compute offset within MemoryRegionSection */
addr -= section->offset_within_address_space;
/* Compute offset within MemoryRegion */
*xlat = addr + section->offset_within_region;
mr = section->mr;
exec: skip MMIO regions correctly in cpu_physical_memory_write_rom_internal Loading the BIOS in the mac99 machine is interesting, because there is a PROM in the middle of the BIOS region (from 16K to 32K). Before memory region accesses were clamped, when QEMU was asked to load a BIOS from 0xfff00000 to 0xffffffff it would put even those 16K from the BIOS file into the region. This is weird because those 16K were not actually visible between 0xfff04000 and 0xfff07fff. However, it worked. After clamping was added, this also worked. In this case, the cpu_physical_memory_write_rom_internal function split the write in three parts: the first 16K were copied, the PROM area (second 16K) were ignored, then the rest was copied. Problems then started with commit 965eb2f (exec: do not clamp accesses to MMIO regions, 2015-06-17). Clamping accesses is not done for MMIO regions because they can overlap wildly, and MMIO registers can be expected to perform full-width accesses based only on their address (with no respect for adjacent registers that could decode to completely different MemoryRegions). However, this lack of clamping also applied to the PROM area! cpu_physical_memory_write_rom_internal thus failed to copy the third range above, i.e. only copied the first 16K of the BIOS. In effect, address_space_translate is expecting _something else_ to do the clamping for MMIO regions if the incoming length is large. This "something else" is memory_access_size in the case of address_space_rw, so use the same logic in cpu_physical_memory_write_rom_internal. Reported-by: Alexander Graf <agraf@redhat.com> Reviewed-by: Laurent Vivier <lvivier@redhat.com> Tested-by: Laurent Vivier <lvivier@redhat.com> Fixes: 965eb2f Signed-off-by: Paolo Bonzini <pbonzini@redhat.com>
2015-07-04 00:24:51 +02:00
/* MMIO registers can be expected to perform full-width accesses based only
* on their address, without considering adjacent registers that could
* decode to completely different MemoryRegions. When such registers
* exist (e.g. I/O ports 0xcf8 and 0xcf9 on most PC chipsets), MMIO
* regions overlap wildly. For this reason we cannot clamp the accesses
* here.
*
* If the length is small (as is the case for address_space_ldl/stl),
* everything works fine. If the incoming length is large, however,
* the caller really has to do the clamping through memory_access_size.
*/
if (memory_region_is_ram(mr)) {
diff = int128_sub(section->size, int128_make64(addr));
*plen = int128_get64(int128_min(diff, int128_make64(*plen)));
}
return section;
}
/* Called from RCU critical section */
MemoryRegion *address_space_translate(AddressSpace *as, hwaddr addr,
hwaddr *xlat, hwaddr *plen,
bool is_write)
{
IOMMUTLBEntry iotlb;
MemoryRegionSection *section;
MemoryRegion *mr;
for (;;) {
AddressSpaceDispatch *d = atomic_rcu_read(&as->dispatch);
section = address_space_translate_internal(d, addr, &addr, plen, true);
mr = section->mr;
if (!mr->iommu_ops) {
break;
}
iotlb = mr->iommu_ops->translate(mr, addr, is_write);
addr = ((iotlb.translated_addr & ~iotlb.addr_mask)
| (addr & iotlb.addr_mask));
*plen = MIN(*plen, (addr | iotlb.addr_mask) - addr + 1);
if (!(iotlb.perm & (1 << is_write))) {
mr = &io_mem_unassigned;
break;
}
as = iotlb.target_as;
}
if (xen_enabled() && memory_access_is_direct(mr, is_write)) {
hwaddr page = ((addr & TARGET_PAGE_MASK) + TARGET_PAGE_SIZE) - addr;
*plen = MIN(page, *plen);
}
*xlat = addr;
return mr;
}
/* Called from RCU critical section */
MemoryRegionSection *
address_space_translate_for_iotlb(CPUState *cpu, int asidx, hwaddr addr,
hwaddr *xlat, hwaddr *plen)
{
MemoryRegionSection *section;
AddressSpaceDispatch *d = cpu->cpu_ases[asidx].memory_dispatch;
section = address_space_translate_internal(d, addr, xlat, plen, false);
assert(!section->mr->iommu_ops);
return section;
}
#endif
#if !defined(CONFIG_USER_ONLY)
static int cpu_common_post_load(void *opaque, int version_id)
{
CPUState *cpu = opaque;
/* 0x01 was CPU_INTERRUPT_EXIT. This line can be removed when the
version_id is increased. */
cpu->interrupt_request &= ~0x01;
tlb_flush(cpu, 1);
return 0;
}
static int cpu_common_pre_load(void *opaque)
{
CPUState *cpu = opaque;
exec: change default exception_index value for migration to -1 In QEMU 2.2 the exception_index value was added to the migration stream through a subsection. The default was set to 0, which is wrong and should have been -1. However, 2.2 does not have commit e511b4d (cpu-exec: reset exception_index correctly, 2014-11-26), hence in 2.2 the exception_index is never used and is set to -1 on the next call to cpu_exec. So we can change the migration stream to make the default -1. The effects are: - 2.2.1 -> 2.2.0: cpu->exception_index set incorrectly to 0 if it were -1 on the source; then reset to -1 in cpu_exec. This is TCG only; KVM does not use exception_index. - 2.2.0 -> 2.2.1: cpu->exception_index set incorrectly to -1 if it were 0 on the source; but it would be reset to -1 in cpu_exec anyway. This is TCG only; KVM does not use exception_index. - 2.2.1 -> 2.1: two bugs fixed: 1) can migrate backwards if cpu->exception_index is set to -1; 2) should not migrate backwards (but 2.2.0 allows it) if cpu->exception_index is set to 0 - 2.2.0 -> 2.3.0: 2.2.0 will send the subsection unnecessarily if exception_index is -1, but that is not a problem. 2.3.0 will set cpu->exception_index to -1 if it is 0 on the source, but this would be anyway a problem for 2.2.0 -> 2.2.x migration (due to lack of commit e511b4d in 2.2.x) so we can ignore it - 2.2.1 -> 2.3.0: everything works. In addition, play it safe and never send the subsection unless TCG is in use. KVM does not use exception_index (PPC KVM stores values in it for use in the subsequent call to ppc_cpu_do_interrupt, but does not need it as soon as kvm_handle_debug returns). Xen and qtest do not run any code for the CPU at all. Reported-by: Igor Mammedov <imammedo@redhat.com> Tested-by: Laurent Desnogues <laurent.desnogues@gmail.com> Tested-by: Eduardo Habkost <ehabkost@redhat.com> Signed-off-by: Paolo Bonzini <pbonzini@redhat.com> Message-id: 1418989994-17244-3-git-send-email-pbonzini@redhat.com Cc: qemu-stable@nongnu.org Signed-off-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2014-12-19 12:53:14 +01:00
cpu->exception_index = -1;
return 0;
}
static bool cpu_common_exception_index_needed(void *opaque)
{
CPUState *cpu = opaque;
exec: change default exception_index value for migration to -1 In QEMU 2.2 the exception_index value was added to the migration stream through a subsection. The default was set to 0, which is wrong and should have been -1. However, 2.2 does not have commit e511b4d (cpu-exec: reset exception_index correctly, 2014-11-26), hence in 2.2 the exception_index is never used and is set to -1 on the next call to cpu_exec. So we can change the migration stream to make the default -1. The effects are: - 2.2.1 -> 2.2.0: cpu->exception_index set incorrectly to 0 if it were -1 on the source; then reset to -1 in cpu_exec. This is TCG only; KVM does not use exception_index. - 2.2.0 -> 2.2.1: cpu->exception_index set incorrectly to -1 if it were 0 on the source; but it would be reset to -1 in cpu_exec anyway. This is TCG only; KVM does not use exception_index. - 2.2.1 -> 2.1: two bugs fixed: 1) can migrate backwards if cpu->exception_index is set to -1; 2) should not migrate backwards (but 2.2.0 allows it) if cpu->exception_index is set to 0 - 2.2.0 -> 2.3.0: 2.2.0 will send the subsection unnecessarily if exception_index is -1, but that is not a problem. 2.3.0 will set cpu->exception_index to -1 if it is 0 on the source, but this would be anyway a problem for 2.2.0 -> 2.2.x migration (due to lack of commit e511b4d in 2.2.x) so we can ignore it - 2.2.1 -> 2.3.0: everything works. In addition, play it safe and never send the subsection unless TCG is in use. KVM does not use exception_index (PPC KVM stores values in it for use in the subsequent call to ppc_cpu_do_interrupt, but does not need it as soon as kvm_handle_debug returns). Xen and qtest do not run any code for the CPU at all. Reported-by: Igor Mammedov <imammedo@redhat.com> Tested-by: Laurent Desnogues <laurent.desnogues@gmail.com> Tested-by: Eduardo Habkost <ehabkost@redhat.com> Signed-off-by: Paolo Bonzini <pbonzini@redhat.com> Message-id: 1418989994-17244-3-git-send-email-pbonzini@redhat.com Cc: qemu-stable@nongnu.org Signed-off-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2014-12-19 12:53:14 +01:00
return tcg_enabled() && cpu->exception_index != -1;
}
static const VMStateDescription vmstate_cpu_common_exception_index = {
.name = "cpu_common/exception_index",
.version_id = 1,
.minimum_version_id = 1,
.needed = cpu_common_exception_index_needed,
.fields = (VMStateField[]) {
VMSTATE_INT32(exception_index, CPUState),
VMSTATE_END_OF_LIST()
}
};
static bool cpu_common_crash_occurred_needed(void *opaque)
{
CPUState *cpu = opaque;
return cpu->crash_occurred;
}
static const VMStateDescription vmstate_cpu_common_crash_occurred = {
.name = "cpu_common/crash_occurred",
.version_id = 1,
.minimum_version_id = 1,
.needed = cpu_common_crash_occurred_needed,
.fields = (VMStateField[]) {
VMSTATE_BOOL(crash_occurred, CPUState),
VMSTATE_END_OF_LIST()
}
};
const VMStateDescription vmstate_cpu_common = {
.name = "cpu_common",
.version_id = 1,
.minimum_version_id = 1,
.pre_load = cpu_common_pre_load,
.post_load = cpu_common_post_load,
.fields = (VMStateField[]) {
VMSTATE_UINT32(halted, CPUState),
VMSTATE_UINT32(interrupt_request, CPUState),
VMSTATE_END_OF_LIST()
},
.subsections = (const VMStateDescription*[]) {
&vmstate_cpu_common_exception_index,
&vmstate_cpu_common_crash_occurred,
NULL
}
};
#endif
CPUState *qemu_get_cpu(int index)
{
CPUState *cpu;
CPU_FOREACH(cpu) {
if (cpu->cpu_index == index) {
return cpu;
}
}
return NULL;
}
#if !defined(CONFIG_USER_ONLY)
void cpu_address_space_init(CPUState *cpu, AddressSpace *as, int asidx)
{
CPUAddressSpace *newas;
/* Target code should have set num_ases before calling us */
assert(asidx < cpu->num_ases);
if (asidx == 0) {
/* address space 0 gets the convenience alias */
cpu->as = as;
}
/* KVM cannot currently support multiple address spaces. */
assert(asidx == 0 || !kvm_enabled());
if (!cpu->cpu_ases) {
cpu->cpu_ases = g_new0(CPUAddressSpace, cpu->num_ases);
}
newas = &cpu->cpu_ases[asidx];
newas->cpu = cpu;
newas->as = as;
if (tcg_enabled()) {
newas->tcg_as_listener.commit = tcg_commit;
memory_listener_register(&newas->tcg_as_listener, as);
}
}
AddressSpace *cpu_get_address_space(CPUState *cpu, int asidx)
{
/* Return the AddressSpace corresponding to the specified index */
return cpu->cpu_ases[asidx].as;
}
#endif
cpu: Convert cpu_index into a bitmap Currently CPUState::cpu_index is monotonically increasing and a newly created CPU always gets the next higher index. The next available index is calculated by counting the existing number of CPUs. This is fine as long as we only add CPUs, but there are architectures which are starting to support CPU removal, too. For an architecture like PowerPC which derives its CPU identifier (device tree ID) from cpu_index, the existing logic of generating cpu_index values causes problems. With the currently proposed method of handling vCPU removal by parking the vCPU fd in QEMU (Ref: http://lists.gnu.org/archive/html/qemu-devel/2015-02/msg02604.html), generating cpu_index this way will not work for PowerPC. This patch changes the way cpu_index is handed out by maintaining a bit map of the CPUs that tracks both addition and removal of CPUs. The CPU bitmap allocation logic is part of cpu_exec_init(), which is called by instance_init routines of various CPU targets. Newly added cpu_exec_exit() API handles the deallocation part and this routine is called from generic CPU instance_finalize. Note: This new CPU enumeration is for !CONFIG_USER_ONLY only. CONFIG_USER_ONLY continues to have the old enumeration logic. Signed-off-by: Bharata B Rao <bharata@linux.vnet.ibm.com> Reviewed-by: Eduardo Habkost <ehabkost@redhat.com> Reviewed-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: David Gibson <david@gibson.dropbear.id.au> Reviewed-by: Peter Crosthwaite <peter.crosthwaite@xilinx.com> Acked-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Peter Crosthwaite <crosthwaite.peter@gmail.com> [AF: max_cpus -> MAX_CPUMASK_BITS] Signed-off-by: Andreas Färber <afaerber@suse.de>
2015-06-24 04:31:13 +02:00
#ifndef CONFIG_USER_ONLY
static DECLARE_BITMAP(cpu_index_map, MAX_CPUMASK_BITS);
static int cpu_get_free_index(Error **errp)
{
int cpu = find_first_zero_bit(cpu_index_map, MAX_CPUMASK_BITS);
if (cpu >= MAX_CPUMASK_BITS) {
error_setg(errp, "Trying to use more CPUs than max of %d",
MAX_CPUMASK_BITS);
return -1;
}
bitmap_set(cpu_index_map, cpu, 1);
return cpu;
}
void cpu_exec_exit(CPUState *cpu)
{
if (cpu->cpu_index == -1) {
/* cpu_index was never allocated by this @cpu or was already freed. */
return;
}
bitmap_clear(cpu_index_map, cpu->cpu_index, 1);
cpu->cpu_index = -1;
}
#else
static int cpu_get_free_index(Error **errp)
{
CPUState *some_cpu;
int cpu_index = 0;
CPU_FOREACH(some_cpu) {
cpu_index++;
}
return cpu_index;
}
void cpu_exec_exit(CPUState *cpu)
{
}
#endif
void cpu_exec_init(CPUState *cpu, Error **errp)
{
CPUClass *cc = CPU_GET_CLASS(cpu);
int cpu_index;
cpu: Convert cpu_index into a bitmap Currently CPUState::cpu_index is monotonically increasing and a newly created CPU always gets the next higher index. The next available index is calculated by counting the existing number of CPUs. This is fine as long as we only add CPUs, but there are architectures which are starting to support CPU removal, too. For an architecture like PowerPC which derives its CPU identifier (device tree ID) from cpu_index, the existing logic of generating cpu_index values causes problems. With the currently proposed method of handling vCPU removal by parking the vCPU fd in QEMU (Ref: http://lists.gnu.org/archive/html/qemu-devel/2015-02/msg02604.html), generating cpu_index this way will not work for PowerPC. This patch changes the way cpu_index is handed out by maintaining a bit map of the CPUs that tracks both addition and removal of CPUs. The CPU bitmap allocation logic is part of cpu_exec_init(), which is called by instance_init routines of various CPU targets. Newly added cpu_exec_exit() API handles the deallocation part and this routine is called from generic CPU instance_finalize. Note: This new CPU enumeration is for !CONFIG_USER_ONLY only. CONFIG_USER_ONLY continues to have the old enumeration logic. Signed-off-by: Bharata B Rao <bharata@linux.vnet.ibm.com> Reviewed-by: Eduardo Habkost <ehabkost@redhat.com> Reviewed-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: David Gibson <david@gibson.dropbear.id.au> Reviewed-by: Peter Crosthwaite <peter.crosthwaite@xilinx.com> Acked-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Peter Crosthwaite <crosthwaite.peter@gmail.com> [AF: max_cpus -> MAX_CPUMASK_BITS] Signed-off-by: Andreas Färber <afaerber@suse.de>
2015-06-24 04:31:13 +02:00
Error *local_err = NULL;
cpu->as = NULL;
cpu->num_ases = 0;
#ifndef CONFIG_USER_ONLY
cpu->thread_id = qemu_get_thread_id();
/* This is a softmmu CPU object, so create a property for it
* so users can wire up its memory. (This can't go in qom/cpu.c
* because that file is compiled only once for both user-mode
* and system builds.) The default if no link is set up is to use
* the system address space.
*/
object_property_add_link(OBJECT(cpu), "memory", TYPE_MEMORY_REGION,
(Object **)&cpu->memory,
qdev_prop_allow_set_link_before_realize,
OBJ_PROP_LINK_UNREF_ON_RELEASE,
&error_abort);
cpu->memory = system_memory;
object_ref(OBJECT(cpu->memory));
#endif
#if defined(CONFIG_USER_ONLY)
cpu_list_lock();
#endif
cpu: Convert cpu_index into a bitmap Currently CPUState::cpu_index is monotonically increasing and a newly created CPU always gets the next higher index. The next available index is calculated by counting the existing number of CPUs. This is fine as long as we only add CPUs, but there are architectures which are starting to support CPU removal, too. For an architecture like PowerPC which derives its CPU identifier (device tree ID) from cpu_index, the existing logic of generating cpu_index values causes problems. With the currently proposed method of handling vCPU removal by parking the vCPU fd in QEMU (Ref: http://lists.gnu.org/archive/html/qemu-devel/2015-02/msg02604.html), generating cpu_index this way will not work for PowerPC. This patch changes the way cpu_index is handed out by maintaining a bit map of the CPUs that tracks both addition and removal of CPUs. The CPU bitmap allocation logic is part of cpu_exec_init(), which is called by instance_init routines of various CPU targets. Newly added cpu_exec_exit() API handles the deallocation part and this routine is called from generic CPU instance_finalize. Note: This new CPU enumeration is for !CONFIG_USER_ONLY only. CONFIG_USER_ONLY continues to have the old enumeration logic. Signed-off-by: Bharata B Rao <bharata@linux.vnet.ibm.com> Reviewed-by: Eduardo Habkost <ehabkost@redhat.com> Reviewed-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: David Gibson <david@gibson.dropbear.id.au> Reviewed-by: Peter Crosthwaite <peter.crosthwaite@xilinx.com> Acked-by: Paolo Bonzini <pbonzini@redhat.com> Signed-off-by: Peter Crosthwaite <crosthwaite.peter@gmail.com> [AF: max_cpus -> MAX_CPUMASK_BITS] Signed-off-by: Andreas Färber <afaerber@suse.de>
2015-06-24 04:31:13 +02:00
cpu_index = cpu->cpu_index = cpu_get_free_index(&local_err);
if (local_err) {
error_propagate(errp, local_err);
#if defined(CONFIG_USER_ONLY)
cpu_list_unlock();
#endif
return;
}
QTAILQ_INSERT_TAIL(&cpus, cpu, node);
#if defined(CONFIG_USER_ONLY)
cpu_list_unlock();
#endif
if (qdev_get_vmsd(DEVICE(cpu)) == NULL) {
vmstate_register(NULL, cpu_index, &vmstate_cpu_common, cpu);
}
if (cc->vmsd != NULL) {
vmstate_register(NULL, cpu_index, cc->vmsd, cpu);
}
}
#if defined(CONFIG_USER_ONLY)
static void breakpoint_invalidate(CPUState *cpu, target_ulong pc)
{
tb_invalidate_phys_page_range(pc, pc + 1, 0);
}
#else
static void breakpoint_invalidate(CPUState *cpu, target_ulong pc)
{
MemTxAttrs attrs;
hwaddr phys = cpu_get_phys_page_attrs_debug(cpu, pc, &attrs);
int asidx = cpu_asidx_from_attrs(cpu, attrs);
if (phys != -1) {
tb_invalidate_phys_addr(cpu->cpu_ases[asidx].as,
phys | (pc & ~TARGET_PAGE_MASK));
}
}
#endif
#if defined(CONFIG_USER_ONLY)
void cpu_watchpoint_remove_all(CPUState *cpu, int mask)
{
}
int cpu_watchpoint_remove(CPUState *cpu, vaddr addr, vaddr len,
int flags)
{
return -ENOSYS;
}
void cpu_watchpoint_remove_by_ref(CPUState *cpu, CPUWatchpoint *watchpoint)
{
}
int cpu_watchpoint_insert(CPUState *cpu, vaddr addr, vaddr len,
int flags, CPUWatchpoint **watchpoint)
{
return -ENOSYS;
}
#else
/* Add a watchpoint. */
int cpu_watchpoint_insert(CPUState *cpu, vaddr addr, vaddr len,
int flags, CPUWatchpoint **watchpoint)
{
CPUWatchpoint *wp;
/* forbid ranges which are empty or run off the end of the address space */
if (len == 0 || (addr + len - 1) < addr) {
error_report("tried to set invalid watchpoint at %"
VADDR_PRIx ", len=%" VADDR_PRIu, addr, len);
return -EINVAL;
}
wp = g_malloc(sizeof(*wp));
wp->vaddr = addr;
wp->len = len;
wp->flags = flags;
/* keep all GDB-injected watchpoints in front */
if (flags & BP_GDB) {
QTAILQ_INSERT_HEAD(&cpu->watchpoints, wp, entry);
} else {
QTAILQ_INSERT_TAIL(&cpu->watchpoints, wp, entry);
}
tlb_flush_page(cpu, addr);
if (watchpoint)
*watchpoint = wp;
return 0;
}
/* Remove a specific watchpoint. */
int cpu_watchpoint_remove(CPUState *cpu, vaddr addr, vaddr len,
int flags)
{
CPUWatchpoint *wp;
QTAILQ_FOREACH(wp, &cpu->watchpoints, entry) {
if (addr == wp->vaddr && len == wp->len
&& flags == (wp->flags & ~BP_WATCHPOINT_HIT)) {
cpu_watchpoint_remove_by_ref(cpu, wp);
return 0;
}
}
return -ENOENT;
}
/* Remove a specific watchpoint by reference. */
void cpu_watchpoint_remove_by_ref(CPUState *cpu, CPUWatchpoint *watchpoint)
{
QTAILQ_REMOVE(&cpu->watchpoints, watchpoint, entry);
tlb_flush_page(cpu, watchpoint->vaddr);
g_free(watchpoint);
}
/* Remove all matching watchpoints. */
void cpu_watchpoint_remove_all(CPUState *cpu, int mask)
{
CPUWatchpoint *wp, *next;
QTAILQ_FOREACH_SAFE(wp, &cpu->watchpoints, entry, next) {
if (wp->flags & mask) {
cpu_watchpoint_remove_by_ref(cpu, wp);
}
}
}
/* Return true if this watchpoint address matches the specified
* access (ie the address range covered by the watchpoint overlaps
* partially or completely with the address range covered by the
* access).
*/
static inline bool cpu_watchpoint_address_matches(CPUWatchpoint *wp,
vaddr addr,
vaddr len)
{
/* We know the lengths are non-zero, but a little caution is
* required to avoid errors in the case where the range ends
* exactly at the top of the address space and so addr + len
* wraps round to zero.
*/
vaddr wpend = wp->vaddr + wp->len - 1;
vaddr addrend = addr + len - 1;
return !(addr > wpend || wp->vaddr > addrend);
}
#endif
/* Add a breakpoint. */
int cpu_breakpoint_insert(CPUState *cpu, vaddr pc, int flags,
CPUBreakpoint **breakpoint)
{
CPUBreakpoint *bp;
bp = g_malloc(sizeof(*bp));
bp->pc = pc;
bp->flags = flags;
/* keep all GDB-injected breakpoints in front */
if (flags & BP_GDB) {
QTAILQ_INSERT_HEAD(&cpu->breakpoints, bp, entry);
} else {
QTAILQ_INSERT_TAIL(&cpu->breakpoints, bp, entry);
}
breakpoint_invalidate(cpu, pc);
if (breakpoint) {
*breakpoint = bp;
}
return 0;
}
/* Remove a specific breakpoint. */
int cpu_breakpoint_remove(CPUState *cpu, vaddr pc, int flags)
{
CPUBreakpoint *bp;
QTAILQ_FOREACH(bp, &cpu->breakpoints, entry) {
if (bp->pc == pc && bp->flags == flags) {
cpu_breakpoint_remove_by_ref(cpu, bp);
return 0;
}
}
return -ENOENT;
}
/* Remove a specific breakpoint by reference. */
void cpu_breakpoint_remove_by_ref(CPUState *cpu, CPUBreakpoint *breakpoint)
{
QTAILQ_REMOVE(&cpu->breakpoints, breakpoint, entry);
breakpoint_invalidate(cpu, breakpoint->pc);
g_free(breakpoint);
}
/* Remove all matching breakpoints. */
void cpu_breakpoint_remove_all(CPUState *cpu, int mask)
{
CPUBreakpoint *bp, *next;
QTAILQ_FOREACH_SAFE(bp, &cpu->breakpoints, entry, next) {
if (bp->flags & mask) {
cpu_breakpoint_remove_by_ref(cpu, bp);
}
}
}
/* enable or disable single step mode. EXCP_DEBUG is returned by the
CPU loop after each instruction */
void cpu_single_step(CPUState *cpu, int enabled)
{
if (cpu->singlestep_enabled != enabled) {
cpu->singlestep_enabled = enabled;
if (kvm_enabled()) {
kvm_update_guest_debug(cpu, 0);
} else {
/* must flush all the translated code to avoid inconsistencies */
/* XXX: only flush what is necessary */
tb_flush(cpu);
}
}
}
void cpu_abort(CPUState *cpu, 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");
cpu_dump_state(cpu, stderr, fprintf, CPU_DUMP_FPU | CPU_DUMP_CCOP);
if (qemu_log_separate()) {
qemu_log("qemu: fatal: ");
qemu_log_vprintf(fmt, ap2);
qemu_log("\n");
log_cpu_state(cpu, CPU_DUMP_FPU | CPU_DUMP_CCOP);
qemu_log_flush();
qemu_log_close();
}
va_end(ap2);
va_end(ap);
replay_finish();
#if defined(CONFIG_USER_ONLY)
{
struct sigaction act;
sigfillset(&act.sa_mask);
act.sa_handler = SIG_DFL;
sigaction(SIGABRT, &act, NULL);
}
#endif
abort();
}
#if !defined(CONFIG_USER_ONLY)
/* Called from RCU critical section */
static RAMBlock *qemu_get_ram_block(ram_addr_t addr)
{
RAMBlock *block;
block = atomic_rcu_read(&ram_list.mru_block);
if (block && addr - block->offset < block->max_length) {
return block;
}
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
if (addr - block->offset < block->max_length) {
goto found;
}
}
fprintf(stderr, "Bad ram offset %" PRIx64 "\n", (uint64_t)addr);
abort();
found:
/* It is safe to write mru_block outside the iothread lock. This
* is what happens:
*
* mru_block = xxx
* rcu_read_unlock()
* xxx removed from list
* rcu_read_lock()
* read mru_block
* mru_block = NULL;
* call_rcu(reclaim_ramblock, xxx);
* rcu_read_unlock()
*
* atomic_rcu_set is not needed here. The block was already published
* when it was placed into the list. Here we're just making an extra
* copy of the pointer.
*/
ram_list.mru_block = block;
return block;
}
static void tlb_reset_dirty_range_all(ram_addr_t start, ram_addr_t length)
{
CPUState *cpu;
ram_addr_t start1;
RAMBlock *block;
ram_addr_t end;
end = TARGET_PAGE_ALIGN(start + length);
start &= TARGET_PAGE_MASK;
rcu_read_lock();
block = qemu_get_ram_block(start);
assert(block == qemu_get_ram_block(end - 1));
start1 = (uintptr_t)ramblock_ptr(block, start - block->offset);
CPU_FOREACH(cpu) {
tlb_reset_dirty(cpu, start1, length);
}
rcu_read_unlock();
}
/* Note: start and end must be within the same ram block. */
bool cpu_physical_memory_test_and_clear_dirty(ram_addr_t start,
ram_addr_t length,
unsigned client)
{
DirtyMemoryBlocks *blocks;
unsigned long end, page;
bool dirty = false;
if (length == 0) {
return false;
}
end = TARGET_PAGE_ALIGN(start + length) >> TARGET_PAGE_BITS;
page = start >> TARGET_PAGE_BITS;
rcu_read_lock();
blocks = atomic_rcu_read(&ram_list.dirty_memory[client]);
while (page < end) {
unsigned long idx = page / DIRTY_MEMORY_BLOCK_SIZE;
unsigned long offset = page % DIRTY_MEMORY_BLOCK_SIZE;
unsigned long num = MIN(end - page, DIRTY_MEMORY_BLOCK_SIZE - offset);
dirty |= bitmap_test_and_clear_atomic(blocks->blocks[idx],
offset, num);
page += num;
}
rcu_read_unlock();
if (dirty && tcg_enabled()) {
tlb_reset_dirty_range_all(start, length);
}
return dirty;
}
/* Called from RCU critical section */
hwaddr memory_region_section_get_iotlb(CPUState *cpu,
MemoryRegionSection *section,
target_ulong vaddr,
hwaddr paddr, hwaddr xlat,
int prot,
target_ulong *address)
{
hwaddr iotlb;
CPUWatchpoint *wp;
if (memory_region_is_ram(section->mr)) {
/* Normal RAM. */
iotlb = (memory_region_get_ram_addr(section->mr) & TARGET_PAGE_MASK)
+ xlat;
if (!section->readonly) {
iotlb |= PHYS_SECTION_NOTDIRTY;
} else {
iotlb |= PHYS_SECTION_ROM;
}
} else {
AddressSpaceDispatch *d;
d = atomic_rcu_read(&section->address_space->dispatch);
iotlb = section - d->map.sections;
iotlb += xlat;
}
/* Make accesses to pages with watchpoints go via the
watchpoint trap routines. */
QTAILQ_FOREACH(wp, &cpu->watchpoints, entry) {
if (cpu_watchpoint_address_matches(wp, vaddr, TARGET_PAGE_SIZE)) {
/* Avoid trapping reads of pages with a write breakpoint. */
if ((prot & PAGE_WRITE) || (wp->flags & BP_MEM_READ)) {
iotlb = PHYS_SECTION_WATCH + paddr;
*address |= TLB_MMIO;
break;
}
}
}
return iotlb;
}
#endif /* defined(CONFIG_USER_ONLY) */
#if !defined(CONFIG_USER_ONLY)
static int subpage_register (subpage_t *mmio, uint32_t start, uint32_t end,
uint16_t section);
static subpage_t *subpage_init(AddressSpace *as, hwaddr base);
static void *(*phys_mem_alloc)(size_t size, uint64_t *align) =
qemu_anon_ram_alloc;
/*
* Set a custom physical guest memory alloator.
* Accelerators with unusual needs may need this. Hopefully, we can
* get rid of it eventually.
*/
void phys_mem_set_alloc(void *(*alloc)(size_t, uint64_t *align))
{
phys_mem_alloc = alloc;
}
static uint16_t phys_section_add(PhysPageMap *map,
MemoryRegionSection *section)
{
/* The physical section number is ORed with a page-aligned
* pointer to produce the iotlb entries. Thus it should
* never overflow into the page-aligned value.
*/
assert(map->sections_nb < TARGET_PAGE_SIZE);
if (map->sections_nb == map->sections_nb_alloc) {
map->sections_nb_alloc = MAX(map->sections_nb_alloc * 2, 16);
map->sections = g_renew(MemoryRegionSection, map->sections,
map->sections_nb_alloc);
}
map->sections[map->sections_nb] = *section;
memory_region_ref(section->mr);
return map->sections_nb++;
}
static void phys_section_destroy(MemoryRegion *mr)
{
bool have_sub_page = mr->subpage;
memory_region_unref(mr);
if (have_sub_page) {
subpage_t *subpage = container_of(mr, subpage_t, iomem);
object_unref(OBJECT(&subpage->iomem));
g_free(subpage);
}
}
static void phys_sections_free(PhysPageMap *map)
{
while (map->sections_nb > 0) {
MemoryRegionSection *section = &map->sections[--map->sections_nb];
phys_section_destroy(section->mr);
}
g_free(map->sections);
g_free(map->nodes);
}
static void register_subpage(AddressSpaceDispatch *d, MemoryRegionSection *section)
{
subpage_t *subpage;
hwaddr base = section->offset_within_address_space
& TARGET_PAGE_MASK;
MemoryRegionSection *existing = phys_page_find(d->phys_map, base,
d->map.nodes, d->map.sections);
MemoryRegionSection subsection = {
.offset_within_address_space = base,
.size = int128_make64(TARGET_PAGE_SIZE),
};
hwaddr start, end;
assert(existing->mr->subpage || existing->mr == &io_mem_unassigned);
if (!(existing->mr->subpage)) {
subpage = subpage_init(d->as, base);
subsection.address_space = d->as;
subsection.mr = &subpage->iomem;
phys_page_set(d, base >> TARGET_PAGE_BITS, 1,
phys_section_add(&d->map, &subsection));
} else {
subpage = container_of(existing->mr, subpage_t, iomem);
}
start = section->offset_within_address_space & ~TARGET_PAGE_MASK;
end = start + int128_get64(section->size) - 1;
subpage_register(subpage, start, end,
phys_section_add(&d->map, section));
}
static void register_multipage(AddressSpaceDispatch *d,
MemoryRegionSection *section)
{
hwaddr start_addr = section->offset_within_address_space;
uint16_t section_index = phys_section_add(&d->map, section);
uint64_t num_pages = int128_get64(int128_rshift(section->size,
TARGET_PAGE_BITS));
assert(num_pages);
phys_page_set(d, start_addr >> TARGET_PAGE_BITS, num_pages, section_index);
}
static void mem_add(MemoryListener *listener, MemoryRegionSection *section)
{
AddressSpace *as = container_of(listener, AddressSpace, dispatch_listener);
AddressSpaceDispatch *d = as->next_dispatch;
MemoryRegionSection now = *section, remain = *section;
Int128 page_size = int128_make64(TARGET_PAGE_SIZE);
if (now.offset_within_address_space & ~TARGET_PAGE_MASK) {
uint64_t left = TARGET_PAGE_ALIGN(now.offset_within_address_space)
- now.offset_within_address_space;
now.size = int128_min(int128_make64(left), now.size);
register_subpage(d, &now);
} else {
now.size = int128_zero();
}
while (int128_ne(remain.size, now.size)) {
remain.size = int128_sub(remain.size, now.size);
remain.offset_within_address_space += int128_get64(now.size);
remain.offset_within_region += int128_get64(now.size);
now = remain;
if (int128_lt(remain.size, page_size)) {
register_subpage(d, &now);
} else if (remain.offset_within_address_space & ~TARGET_PAGE_MASK) {
now.size = page_size;
register_subpage(d, &now);
} else {
now.size = int128_and(now.size, int128_neg(page_size));
register_multipage(d, &now);
}
}
}
void qemu_flush_coalesced_mmio_buffer(void)
{
if (kvm_enabled())
kvm_flush_coalesced_mmio_buffer();
}
void qemu_mutex_lock_ramlist(void)
{
qemu_mutex_lock(&ram_list.mutex);
}
void qemu_mutex_unlock_ramlist(void)
{
qemu_mutex_unlock(&ram_list.mutex);
}
#ifdef __linux__
static void *file_ram_alloc(RAMBlock *block,
ram_addr_t memory,
const char *path,
Error **errp)
{
bool unlink_on_error = false;
char *filename;
char *sanitized_name;
char *c;
void *area;
int fd = -1;
int64_t page_size;
if (kvm_enabled() && !kvm_has_sync_mmu()) {
error_setg(errp,
"host lacks kvm mmu notifiers, -mem-path unsupported");
return NULL;
}
for (;;) {
fd = open(path, O_RDWR);
if (fd >= 0) {
/* @path names an existing file, use it */
break;
}
if (errno == ENOENT) {
/* @path names a file that doesn't exist, create it */
fd = open(path, O_RDWR | O_CREAT | O_EXCL, 0644);
if (fd >= 0) {
unlink_on_error = true;
break;
}
} else if (errno == EISDIR) {
/* @path names a directory, create a file there */
/* Make name safe to use with mkstemp by replacing '/' with '_'. */
sanitized_name = g_strdup(memory_region_name(block->mr));
for (c = sanitized_name; *c != '\0'; c++) {
if (*c == '/') {
*c = '_';
}
}
filename = g_strdup_printf("%s/qemu_back_mem.%s.XXXXXX", path,
sanitized_name);
g_free(sanitized_name);
fd = mkstemp(filename);
if (fd >= 0) {
unlink(filename);
g_free(filename);
break;
}
g_free(filename);
}
if (errno != EEXIST && errno != EINTR) {
error_setg_errno(errp, errno,
"can't open backing store %s for guest RAM",
path);
goto error;
}
/*
* Try again on EINTR and EEXIST. The latter happens when
* something else creates the file between our two open().
*/
}
page_size = qemu_fd_getpagesize(fd);
block->mr->align = page_size;
if (memory < page_size) {
error_setg(errp, "memory size 0x" RAM_ADDR_FMT " must be equal to "
"or larger than page size 0x%" PRIx64,
memory, page_size);
goto error;
}
memory = ROUND_UP(memory, page_size);
/*
* ftruncate is not supported by hugetlbfs in older
* hosts, so don't bother bailing out on errors.
* If anything goes wrong with it under other filesystems,
* mmap will fail.
*/
if (ftruncate(fd, memory)) {
perror("ftruncate");
}
area = qemu_ram_mmap(fd, memory, page_size, block->flags & RAM_SHARED);
if (area == MAP_FAILED) {
error_setg_errno(errp, errno,
"unable to map backing store for guest RAM");
goto error;
}
if (mem_prealloc) {
os_mem_prealloc(fd, area, memory);
}
block->fd = fd;
return area;
error:
if (unlink_on_error) {
unlink(path);
}
if (fd != -1) {
close(fd);
}
return NULL;
}
#endif
/* Called with the ramlist lock held. */
static ram_addr_t find_ram_offset(ram_addr_t size)
{
RAMBlock *block, *next_block;
ram_addr_t offset = RAM_ADDR_MAX, mingap = RAM_ADDR_MAX;
assert(size != 0); /* it would hand out same offset multiple times */
if (QLIST_EMPTY_RCU(&ram_list.blocks)) {
return 0;
}
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
ram_addr_t end, next = RAM_ADDR_MAX;
end = block->offset + block->max_length;
QLIST_FOREACH_RCU(next_block, &ram_list.blocks, next) {
if (next_block->offset >= end) {
next = MIN(next, next_block->offset);
}
}
if (next - end >= size && next - end < mingap) {
offset = end;
mingap = next - end;
}
}
if (offset == RAM_ADDR_MAX) {
fprintf(stderr, "Failed to find gap of requested size: %" PRIu64 "\n",
(uint64_t)size);
abort();
}
return offset;
}
ram_addr_t last_ram_offset(void)
{
RAMBlock *block;
ram_addr_t last = 0;
rcu_read_lock();
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
last = MAX(last, block->offset + block->max_length);
}
rcu_read_unlock();
return last;
}
static void qemu_ram_setup_dump(void *addr, ram_addr_t size)
{
int ret;
/* Use MADV_DONTDUMP, if user doesn't want the guest memory in the core */
if (!machine_dump_guest_core(current_machine)) {
ret = qemu_madvise(addr, size, QEMU_MADV_DONTDUMP);
if (ret) {
perror("qemu_madvise");
fprintf(stderr, "madvise doesn't support MADV_DONTDUMP, "
"but dump_guest_core=off specified\n");
}
}
}
/* Called within an RCU critical section, or while the ramlist lock
* is held.
*/
static RAMBlock *find_ram_block(ram_addr_t addr)
{
RAMBlock *block;
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
if (block->offset == addr) {
return block;
}
}
return NULL;
}
const char *qemu_ram_get_idstr(RAMBlock *rb)
{
return rb->idstr;
}
/* Called with iothread lock held. */
void qemu_ram_set_idstr(ram_addr_t addr, const char *name, DeviceState *dev)
{
RAMBlock *new_block, *block;
rcu_read_lock();
new_block = find_ram_block(addr);
assert(new_block);
assert(!new_block->idstr[0]);
if (dev) {
char *id = qdev_get_dev_path(dev);
if (id) {
snprintf(new_block->idstr, sizeof(new_block->idstr), "%s/", id);
g_free(id);
}
}
pstrcat(new_block->idstr, sizeof(new_block->idstr), name);
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
if (block != new_block && !strcmp(block->idstr, new_block->idstr)) {
fprintf(stderr, "RAMBlock \"%s\" already registered, abort!\n",
new_block->idstr);
abort();
}
}
rcu_read_unlock();
}
/* Called with iothread lock held. */
void qemu_ram_unset_idstr(ram_addr_t addr)
{
RAMBlock *block;
/* FIXME: arch_init.c assumes that this is not called throughout
* migration. Ignore the problem since hot-unplug during migration
* does not work anyway.
*/
rcu_read_lock();
block = find_ram_block(addr);
if (block) {
memset(block->idstr, 0, sizeof(block->idstr));
}
rcu_read_unlock();
}
static int memory_try_enable_merging(void *addr, size_t len)
{
if (!machine_mem_merge(current_machine)) {
/* disabled by the user */
return 0;
}
return qemu_madvise(addr, len, QEMU_MADV_MERGEABLE);
}
/* Only legal before guest might have detected the memory size: e.g. on
* incoming migration, or right after reset.
*
* As memory core doesn't know how is memory accessed, it is up to
* resize callback to update device state and/or add assertions to detect
* misuse, if necessary.
*/
int qemu_ram_resize(ram_addr_t base, ram_addr_t newsize, Error **errp)
{
RAMBlock *block = find_ram_block(base);
assert(block);
newsize = HOST_PAGE_ALIGN(newsize);
if (block->used_length == newsize) {
return 0;
}
if (!(block->flags & RAM_RESIZEABLE)) {
error_setg_errno(errp, EINVAL,
"Length mismatch: %s: 0x" RAM_ADDR_FMT
" in != 0x" RAM_ADDR_FMT, block->idstr,
newsize, block->used_length);
return -EINVAL;
}
if (block->max_length < newsize) {
error_setg_errno(errp, EINVAL,
"Length too large: %s: 0x" RAM_ADDR_FMT
" > 0x" RAM_ADDR_FMT, block->idstr,
newsize, block->max_length);
return -EINVAL;
}
cpu_physical_memory_clear_dirty_range(block->offset, block->used_length);
block->used_length = newsize;
cpu_physical_memory_set_dirty_range(block->offset, block->used_length,
DIRTY_CLIENTS_ALL);
memory_region_set_size(block->mr, newsize);
if (block->resized) {
block->resized(block->idstr, newsize, block->host);
}
return 0;
}
/* Called with ram_list.mutex held */
static void dirty_memory_extend(ram_addr_t old_ram_size,
ram_addr_t new_ram_size)
{
ram_addr_t old_num_blocks = DIV_ROUND_UP(old_ram_size,
DIRTY_MEMORY_BLOCK_SIZE);
ram_addr_t new_num_blocks = DIV_ROUND_UP(new_ram_size,
DIRTY_MEMORY_BLOCK_SIZE);
int i;
/* Only need to extend if block count increased */
if (new_num_blocks <= old_num_blocks) {
return;
}
for (i = 0; i < DIRTY_MEMORY_NUM; i++) {
DirtyMemoryBlocks *old_blocks;
DirtyMemoryBlocks *new_blocks;
int j;
old_blocks = atomic_rcu_read(&ram_list.dirty_memory[i]);
new_blocks = g_malloc(sizeof(*new_blocks) +
sizeof(new_blocks->blocks[0]) * new_num_blocks);
if (old_num_blocks) {
memcpy(new_blocks->blocks, old_blocks->blocks,
old_num_blocks * sizeof(old_blocks->blocks[0]));
}
for (j = old_num_blocks; j < new_num_blocks; j++) {
new_blocks->blocks[j] = bitmap_new(DIRTY_MEMORY_BLOCK_SIZE);
}
atomic_rcu_set(&ram_list.dirty_memory[i], new_blocks);
if (old_blocks) {
g_free_rcu(old_blocks, rcu);
}
}
}
static void ram_block_add(RAMBlock *new_block, Error **errp)
{
RAMBlock *block;
RAMBlock *last_block = NULL;
ram_addr_t old_ram_size, new_ram_size;
Error *err = NULL;
old_ram_size = last_ram_offset() >> TARGET_PAGE_BITS;
qemu_mutex_lock_ramlist();
new_block->offset = find_ram_offset(new_block->max_length);
if (!new_block->host) {
if (xen_enabled()) {
xen_ram_alloc(new_block->offset, new_block->max_length,
new_block->mr, &err);
if (err) {
error_propagate(errp, err);
qemu_mutex_unlock_ramlist();
return;
}
} else {
new_block->host = phys_mem_alloc(new_block->max_length,
&new_block->mr->align);
if (!new_block->host) {
error_setg_errno(errp, errno,
"cannot set up guest memory '%s'",
memory_region_name(new_block->mr));
qemu_mutex_unlock_ramlist();
return;
}
memory_try_enable_merging(new_block->host, new_block->max_length);
}
}
new_ram_size = MAX(old_ram_size,
(new_block->offset + new_block->max_length) >> TARGET_PAGE_BITS);
if (new_ram_size > old_ram_size) {
migration_bitmap_extend(old_ram_size, new_ram_size);
dirty_memory_extend(old_ram_size, new_ram_size);
}
/* Keep the list sorted from biggest to smallest block. Unlike QTAILQ,
* QLIST (which has an RCU-friendly variant) does not have insertion at
* tail, so save the last element in last_block.
*/
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
last_block = block;
if (block->max_length < new_block->max_length) {
break;
}
}
if (block) {
QLIST_INSERT_BEFORE_RCU(block, new_block, next);
} else if (last_block) {
QLIST_INSERT_AFTER_RCU(last_block, new_block, next);
} else { /* list is empty */
QLIST_INSERT_HEAD_RCU(&ram_list.blocks, new_block, next);
}
ram_list.mru_block = NULL;
/* Write list before version */
smp_wmb();
ram_list.version++;
qemu_mutex_unlock_ramlist();
cpu_physical_memory_set_dirty_range(new_block->offset,
new_block->used_length,
DIRTY_CLIENTS_ALL);
if (new_block->host) {
qemu_ram_setup_dump(new_block->host, new_block->max_length);
qemu_madvise(new_block->host, new_block->max_length, QEMU_MADV_HUGEPAGE);
qemu_madvise(new_block->host, new_block->max_length, QEMU_MADV_DONTFORK);
if (kvm_enabled()) {
kvm_setup_guest_memory(new_block->host, new_block->max_length);
}
}
}
#ifdef __linux__
RAMBlock *qemu_ram_alloc_from_file(ram_addr_t size, MemoryRegion *mr,
bool share, const char *mem_path,
Error **errp)
{
RAMBlock *new_block;
Error *local_err = NULL;
if (xen_enabled()) {
error_setg(errp, "-mem-path not supported with Xen");
return NULL;
}
if (phys_mem_alloc != qemu_anon_ram_alloc) {
/*
* file_ram_alloc() needs to allocate just like
* phys_mem_alloc, but we haven't bothered to provide
* a hook there.
*/
error_setg(errp,
"-mem-path not supported with this accelerator");
return NULL;
}
size = HOST_PAGE_ALIGN(size);
new_block = g_malloc0(sizeof(*new_block));
new_block->mr = mr;
new_block->used_length = size;
new_block->max_length = size;
new_block->flags = share ? RAM_SHARED : 0;
new_block->host = file_ram_alloc(new_block, size,
mem_path, errp);
if (!new_block->host) {
g_free(new_block);
return NULL;
}
ram_block_add(new_block, &local_err);
if (local_err) {
g_free(new_block);
error_propagate(errp, local_err);
return NULL;
}
return new_block;
}
#endif
static
RAMBlock *qemu_ram_alloc_internal(ram_addr_t size, ram_addr_t max_size,
void (*resized)(const char*,
uint64_t length,
void *host),
void *host, bool resizeable,
MemoryRegion *mr, Error **errp)
{
RAMBlock *new_block;
Error *local_err = NULL;
size = HOST_PAGE_ALIGN(size);
max_size = HOST_PAGE_ALIGN(max_size);
new_block = g_malloc0(sizeof(*new_block));
new_block->mr = mr;
new_block->resized = resized;
new_block->used_length = size;
new_block->max_length = max_size;
assert(max_size >= size);
new_block->fd = -1;
new_block->host = host;
if (host) {
new_block->flags |= RAM_PREALLOC;
}
if (resizeable) {
new_block->flags |= RAM_RESIZEABLE;
}
ram_block_add(new_block, &local_err);
if (local_err) {
g_free(new_block);
error_propagate(errp, local_err);
return NULL;
}
return new_block;
}
RAMBlock *qemu_ram_alloc_from_ptr(ram_addr_t size, void *host,
MemoryRegion *mr, Error **errp)
{
return qemu_ram_alloc_internal(size, size, NULL, host, false, mr, errp);
}
RAMBlock *qemu_ram_alloc(ram_addr_t size, MemoryRegion *mr, Error **errp)
{
return qemu_ram_alloc_internal(size, size, NULL, NULL, false, mr, errp);
}
RAMBlock *qemu_ram_alloc_resizeable(ram_addr_t size, ram_addr_t maxsz,
void (*resized)(const char*,
uint64_t length,
void *host),
MemoryRegion *mr, Error **errp)
{
return qemu_ram_alloc_internal(size, maxsz, resized, NULL, true, mr, errp);
}
static void reclaim_ramblock(RAMBlock *block)
{
if (block->flags & RAM_PREALLOC) {
;
} else if (xen_enabled()) {
xen_invalidate_map_cache_entry(block->host);
#ifndef _WIN32
} else if (block->fd >= 0) {
qemu_ram_munmap(block->host, block->max_length);
close(block->fd);
#endif
} else {
qemu_anon_ram_free(block->host, block->max_length);
}
g_free(block);
}
void qemu_ram_free(RAMBlock *block)
{
qemu_mutex_lock_ramlist();
QLIST_REMOVE_RCU(block, next);
ram_list.mru_block = NULL;
/* Write list before version */
smp_wmb();
ram_list.version++;
call_rcu(block, reclaim_ramblock, rcu);
qemu_mutex_unlock_ramlist();
}
#ifndef _WIN32
void qemu_ram_remap(ram_addr_t addr, ram_addr_t length)
{
RAMBlock *block;
ram_addr_t offset;
int flags;
void *area, *vaddr;
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
offset = addr - block->offset;
if (offset < block->max_length) {
vaddr = ramblock_ptr(block, offset);
if (block->flags & RAM_PREALLOC) {
;
} else if (xen_enabled()) {
abort();
} else {
flags = MAP_FIXED;
if (block->fd >= 0) {
flags |= (block->flags & RAM_SHARED ?
MAP_SHARED : MAP_PRIVATE);
area = mmap(vaddr, length, PROT_READ | PROT_WRITE,
flags, block->fd, offset);
} else {
/*
* Remap needs to match alloc. Accelerators that
* set phys_mem_alloc never remap. If they did,
* we'd need a remap hook here.
*/
assert(phys_mem_alloc == qemu_anon_ram_alloc);
flags |= MAP_PRIVATE | MAP_ANONYMOUS;
area = mmap(vaddr, length, PROT_READ | PROT_WRITE,
flags, -1, 0);
}
if (area != vaddr) {
fprintf(stderr, "Could not remap addr: "
RAM_ADDR_FMT "@" RAM_ADDR_FMT "\n",
length, addr);
exit(1);
}
memory_try_enable_merging(vaddr, length);
qemu_ram_setup_dump(vaddr, length);
}
}
}
}
#endif /* !_WIN32 */
int qemu_get_ram_fd(ram_addr_t addr)
{
RAMBlock *block;
int fd;
rcu_read_lock();
block = qemu_get_ram_block(addr);
fd = block->fd;
rcu_read_unlock();
return fd;
}
void qemu_set_ram_fd(ram_addr_t addr, int fd)
{
RAMBlock *block;
rcu_read_lock();
block = qemu_get_ram_block(addr);
block->fd = fd;
rcu_read_unlock();
}
void *qemu_get_ram_block_host_ptr(ram_addr_t addr)
{
RAMBlock *block;
void *ptr;
rcu_read_lock();
block = qemu_get_ram_block(addr);
ptr = ramblock_ptr(block, 0);
rcu_read_unlock();
return ptr;
}
/* Return a host pointer to ram allocated with qemu_ram_alloc.
* This should not be used for general purpose DMA. Use address_space_map
* or address_space_rw instead. For local memory (e.g. video ram) that the
* device owns, use memory_region_get_ram_ptr.
*
* Called within RCU critical section.
*/
void *qemu_get_ram_ptr(RAMBlock *ram_block, ram_addr_t addr)
{
RAMBlock *block = ram_block;
if (block == NULL) {
block = qemu_get_ram_block(addr);
}
if (xen_enabled() && block->host == NULL) {
/* We need to check if the requested address is in the RAM
* because we don't want to map the entire memory in QEMU.
* In that case just map until the end of the page.
*/
if (block->offset == 0) {
return xen_map_cache(addr, 0, 0);
}
block->host = xen_map_cache(block->offset, block->max_length, 1);
}
return ramblock_ptr(block, addr - block->offset);
}
/* Return a host pointer to guest's ram. Similar to qemu_get_ram_ptr
* but takes a size argument.
*
* Called within RCU critical section.
*/
static void *qemu_ram_ptr_length(RAMBlock *ram_block, ram_addr_t addr,
hwaddr *size)
{
RAMBlock *block = ram_block;
ram_addr_t offset_inside_block;
if (*size == 0) {
return NULL;
}
if (block == NULL) {
block = qemu_get_ram_block(addr);
}
offset_inside_block = addr - block->offset;
*size = MIN(*size, block->max_length - offset_inside_block);
if (xen_enabled() && block->host == NULL) {
/* We need to check if the requested address is in the RAM
* because we don't want to map the entire memory in QEMU.
* In that case just map the requested area.
*/
if (block->offset == 0) {
return xen_map_cache(addr, *size, 1);
}
block->host = xen_map_cache(block->offset, block->max_length, 1);
}
return ramblock_ptr(block, offset_inside_block);
}
/*
* Translates a host ptr back to a RAMBlock, a ram_addr and an offset
* in that RAMBlock.
*
* ptr: Host pointer to look up
* round_offset: If true round the result offset down to a page boundary
* *ram_addr: set to result ram_addr
* *offset: set to result offset within the RAMBlock
*
* Returns: RAMBlock (or NULL if not found)
*
* By the time this function returns, the returned pointer is not protected
* by RCU anymore. If the caller is not within an RCU critical section and
* does not hold the iothread lock, it must have other means of protecting the
* pointer, such as a reference to the region that includes the incoming
* ram_addr_t.
*/
RAMBlock *qemu_ram_block_from_host(void *ptr, bool round_offset,
ram_addr_t *ram_addr,
ram_addr_t *offset)
{
RAMBlock *block;
uint8_t *host = ptr;
if (xen_enabled()) {
rcu_read_lock();
*ram_addr = xen_ram_addr_from_mapcache(ptr);
block = qemu_get_ram_block(*ram_addr);
if (block) {
*offset = (host - block->host);
}
rcu_read_unlock();
return block;
}
rcu_read_lock();
block = atomic_rcu_read(&ram_list.mru_block);
if (block && block->host && host - block->host < block->max_length) {
goto found;
}
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
/* This case append when the block is not mapped. */
if (block->host == NULL) {
continue;
}
if (host - block->host < block->max_length) {
goto found;
}
}
rcu_read_unlock();
return NULL;
found:
*offset = (host - block->host);
if (round_offset) {
*offset &= TARGET_PAGE_MASK;
}
*ram_addr = block->offset + *offset;
rcu_read_unlock();
return block;
}
/*
* Finds the named RAMBlock
*
* name: The name of RAMBlock to find
*
* Returns: RAMBlock (or NULL if not found)
*/
RAMBlock *qemu_ram_block_by_name(const char *name)
{
RAMBlock *block;
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
if (!strcmp(name, block->idstr)) {
return block;
}
}
return NULL;
}
/* Some of the softmmu routines need to translate from a host pointer
(typically a TLB entry) back to a ram offset. */
MemoryRegion *qemu_ram_addr_from_host(void *ptr, ram_addr_t *ram_addr)
{
RAMBlock *block;
ram_addr_t offset; /* Not used */
block = qemu_ram_block_from_host(ptr, false, ram_addr, &offset);
if (!block) {
return NULL;
}
return block->mr;
}
/* Called within RCU critical section. */
static void notdirty_mem_write(void *opaque, hwaddr ram_addr,
uint64_t val, unsigned size)
{
if (!cpu_physical_memory_get_dirty_flag(ram_addr, DIRTY_MEMORY_CODE)) {
tb_invalidate_phys_page_fast(ram_addr, size);
}
switch (size) {
case 1:
stb_p(qemu_get_ram_ptr(NULL, ram_addr), val);
break;
case 2:
stw_p(qemu_get_ram_ptr(NULL, ram_addr), val);
break;
case 4:
stl_p(qemu_get_ram_ptr(NULL, ram_addr), val);
break;
default:
abort();
}
/* Set both VGA and migration bits for simplicity and to remove
* the notdirty callback faster.
*/
cpu_physical_memory_set_dirty_range(ram_addr, size,
DIRTY_CLIENTS_NOCODE);
/* we remove the notdirty callback only if the code has been
flushed */
if (!cpu_physical_memory_is_clean(ram_addr)) {
tlb_set_dirty(current_cpu, current_cpu->mem_io_vaddr);
}
}
static bool notdirty_mem_accepts(void *opaque, hwaddr addr,
unsigned size, bool is_write)
{
return is_write;
}
static const MemoryRegionOps notdirty_mem_ops = {
.write = notdirty_mem_write,
.valid.accepts = notdirty_mem_accepts,
.endianness = DEVICE_NATIVE_ENDIAN,
};
/* Generate a debug exception if a watchpoint has been hit. */
static void check_watchpoint(int offset, int len, MemTxAttrs attrs, int flags)
{
CPUState *cpu = current_cpu;
CPUClass *cc = CPU_GET_CLASS(cpu);
CPUArchState *env = cpu->env_ptr;
target_ulong pc, cs_base;
target_ulong vaddr;
CPUWatchpoint *wp;
int cpu_flags;
if (cpu->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(cpu, CPU_INTERRUPT_DEBUG);
return;
}
vaddr = (cpu->mem_io_vaddr & TARGET_PAGE_MASK) + offset;
QTAILQ_FOREACH(wp, &cpu->watchpoints, entry) {
if (cpu_watchpoint_address_matches(wp, vaddr, len)
&& (wp->flags & flags)) {
if (flags == BP_MEM_READ) {
wp->flags |= BP_WATCHPOINT_HIT_READ;
} else {
wp->flags |= BP_WATCHPOINT_HIT_WRITE;
}
wp->hitaddr = vaddr;
wp->hitattrs = attrs;
if (!cpu->watchpoint_hit) {
if (wp->flags & BP_CPU &&
!cc->debug_check_watchpoint(cpu, wp)) {
wp->flags &= ~BP_WATCHPOINT_HIT;
continue;
}
cpu->watchpoint_hit = wp;
tb_check_watchpoint(cpu);
if (wp->flags & BP_STOP_BEFORE_ACCESS) {
cpu->exception_index = EXCP_DEBUG;
cpu_loop_exit(cpu);
} else {
cpu_get_tb_cpu_state(env, &pc, &cs_base, &cpu_flags);
tb_gen_code(cpu, pc, cs_base, cpu_flags, 1);
cpu_resume_from_signal(cpu, 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 MemTxResult watch_mem_read(void *opaque, hwaddr addr, uint64_t *pdata,
unsigned size, MemTxAttrs attrs)
{
MemTxResult res;
uint64_t data;
int asidx = cpu_asidx_from_attrs(current_cpu, attrs);
AddressSpace *as = current_cpu->cpu_ases[asidx].as;
check_watchpoint(addr & ~TARGET_PAGE_MASK, size, attrs, BP_MEM_READ);
switch (size) {
case 1:
data = address_space_ldub(as, addr, attrs, &res);
break;
case 2:
data = address_space_lduw(as, addr, attrs, &res);
break;
case 4:
data = address_space_ldl(as, addr, attrs, &res);
break;
default: abort();
}
*pdata = data;
return res;
}
static MemTxResult watch_mem_write(void *opaque, hwaddr addr,
uint64_t val, unsigned size,
MemTxAttrs attrs)
{
MemTxResult res;
int asidx = cpu_asidx_from_attrs(current_cpu, attrs);
AddressSpace *as = current_cpu->cpu_ases[asidx].as;
check_watchpoint(addr & ~TARGET_PAGE_MASK, size, attrs, BP_MEM_WRITE);
switch (size) {
case 1:
address_space_stb(as, addr, val, attrs, &res);
break;
case 2:
address_space_stw(as, addr, val, attrs, &res);
break;
case 4:
address_space_stl(as, addr, val, attrs, &res);
break;
default: abort();
}
return res;
}
static const MemoryRegionOps watch_mem_ops = {
.read_with_attrs = watch_mem_read,
.write_with_attrs = watch_mem_write,
.endianness = DEVICE_NATIVE_ENDIAN,
};
static MemTxResult subpage_read(void *opaque, hwaddr addr, uint64_t *data,
unsigned len, MemTxAttrs attrs)
{
subpage_t *subpage = opaque;
uint8_t buf[8];
MemTxResult res;
#if defined(DEBUG_SUBPAGE)
printf("%s: subpage %p len %u addr " TARGET_FMT_plx "\n", __func__,
subpage, len, addr);
#endif
res = address_space_read(subpage->as, addr + subpage->base,
attrs, buf, len);
if (res) {
return res;
}
switch (len) {
case 1:
*data = ldub_p(buf);
return MEMTX_OK;
case 2:
*data = lduw_p(buf);
return MEMTX_OK;
case 4:
*data = ldl_p(buf);
return MEMTX_OK;
case 8:
*data = ldq_p(buf);
return MEMTX_OK;
default:
abort();
}
}
static MemTxResult subpage_write(void *opaque, hwaddr addr,
uint64_t value, unsigned len, MemTxAttrs attrs)
{
subpage_t *subpage = opaque;
uint8_t buf[8];
#if defined(DEBUG_SUBPAGE)
printf("%s: subpage %p len %u addr " TARGET_FMT_plx
" value %"PRIx64"\n",
__func__, subpage, len, addr, value);
#endif
switch (len) {
case 1:
stb_p(buf, value);
break;
case 2:
stw_p(buf, value);
break;
case 4:
stl_p(buf, value);
break;
case 8:
stq_p(buf, value);
break;
default:
abort();
}
return address_space_write(subpage->as, addr + subpage->base,
attrs, buf, len);
}
static bool subpage_accepts(void *opaque, hwaddr addr,
unsigned len, bool is_write)
{
subpage_t *subpage = opaque;
#if defined(DEBUG_SUBPAGE)
printf("%s: subpage %p %c len %u addr " TARGET_FMT_plx "\n",
__func__, subpage, is_write ? 'w' : 'r', len, addr);
#endif
return address_space_access_valid(subpage->as, addr + subpage->base,
len, is_write);
}
static const MemoryRegionOps subpage_ops = {
.read_with_attrs = subpage_read,
.write_with_attrs = subpage_write,
.impl.min_access_size = 1,
.impl.max_access_size = 8,
.valid.min_access_size = 1,
.valid.max_access_size = 8,
.valid.accepts = subpage_accepts,
.endianness = DEVICE_NATIVE_ENDIAN,
};
static int subpage_register (subpage_t *mmio, uint32_t start, uint32_t end,
uint16_t section)
{
int idx, eidx;
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 section %d\n",
__func__, mmio, start, end, idx, eidx, section);
#endif
for (; idx <= eidx; idx++) {
mmio->sub_section[idx] = section;
}
return 0;
}
static subpage_t *subpage_init(AddressSpace *as, hwaddr base)
{
subpage_t *mmio;
mmio = g_malloc0(sizeof(subpage_t));
mmio->as = as;
mmio->base = base;
memory_region_init_io(&mmio->iomem, NULL, &subpage_ops, mmio,
NULL, TARGET_PAGE_SIZE);
mmio->iomem.subpage = true;
#if defined(DEBUG_SUBPAGE)
printf("%s: %p base " TARGET_FMT_plx " len %08x\n", __func__,
mmio, base, TARGET_PAGE_SIZE);
#endif
subpage_register(mmio, 0, TARGET_PAGE_SIZE-1, PHYS_SECTION_UNASSIGNED);
return mmio;
}
static uint16_t dummy_section(PhysPageMap *map, AddressSpace *as,
MemoryRegion *mr)
{
assert(as);
MemoryRegionSection section = {
.address_space = as,
.mr = mr,
.offset_within_address_space = 0,
.offset_within_region = 0,
.size = int128_2_64(),
};
return phys_section_add(map, &section);
}
MemoryRegion *iotlb_to_region(CPUState *cpu, hwaddr index, MemTxAttrs attrs)
{
int asidx = cpu_asidx_from_attrs(cpu, attrs);
CPUAddressSpace *cpuas = &cpu->cpu_ases[asidx];
AddressSpaceDispatch *d = atomic_rcu_read(&cpuas->memory_dispatch);
MemoryRegionSection *sections = d->map.sections;
return sections[index & ~TARGET_PAGE_MASK].mr;
}
static void io_mem_init(void)
{
memory_region_init_io(&io_mem_rom, NULL, &unassigned_mem_ops, NULL, NULL, UINT64_MAX);
memory_region_init_io(&io_mem_unassigned, NULL, &unassigned_mem_ops, NULL,
NULL, UINT64_MAX);
memory_region_init_io(&io_mem_notdirty, NULL, &notdirty_mem_ops, NULL,
NULL, UINT64_MAX);
memory_region_init_io(&io_mem_watch, NULL, &watch_mem_ops, NULL,
NULL, UINT64_MAX);
}
static void mem_begin(MemoryListener *listener)
{
AddressSpace *as = container_of(listener, AddressSpace, dispatch_listener);
AddressSpaceDispatch *d = g_new0(AddressSpaceDispatch, 1);
uint16_t n;
n = dummy_section(&d->map, as, &io_mem_unassigned);
assert(n == PHYS_SECTION_UNASSIGNED);
n = dummy_section(&d->map, as, &io_mem_notdirty);
assert(n == PHYS_SECTION_NOTDIRTY);
n = dummy_section(&d->map, as, &io_mem_rom);
assert(n == PHYS_SECTION_ROM);
n = dummy_section(&d->map, as, &io_mem_watch);
assert(n == PHYS_SECTION_WATCH);
d->phys_map = (PhysPageEntry) { .ptr = PHYS_MAP_NODE_NIL, .skip = 1 };
d->as = as;
as->next_dispatch = d;
}
static void address_space_dispatch_free(AddressSpaceDispatch *d)
{
phys_sections_free(&d->map);
g_free(d);
}
static void mem_commit(MemoryListener *listener)
{
AddressSpace *as = container_of(listener, AddressSpace, dispatch_listener);
AddressSpaceDispatch *cur = as->dispatch;
AddressSpaceDispatch *next = as->next_dispatch;
phys_page_compact_all(next, next->map.nodes_nb);
atomic_rcu_set(&as->dispatch, next);
if (cur) {
call_rcu(cur, address_space_dispatch_free, rcu);
}
}
static void tcg_commit(MemoryListener *listener)
{
CPUAddressSpace *cpuas;
AddressSpaceDispatch *d;
/* since each CPU stores ram addresses in its TLB cache, we must
reset the modified entries */
cpuas = container_of(listener, CPUAddressSpace, tcg_as_listener);
cpu_reloading_memory_map();
/* The CPU and TLB are protected by the iothread lock.
* We reload the dispatch pointer now because cpu_reloading_memory_map()
* may have split the RCU critical section.
*/
d = atomic_rcu_read(&cpuas->as->dispatch);
cpuas->memory_dispatch = d;
tlb_flush(cpuas->cpu, 1);
}
void address_space_init_dispatch(AddressSpace *as)
{
as->dispatch = NULL;
as->dispatch_listener = (MemoryListener) {
.begin = mem_begin,
.commit = mem_commit,
.region_add = mem_add,
.region_nop = mem_add,
.priority = 0,
};
memory_listener_register(&as->dispatch_listener, as);
}
void address_space_unregister(AddressSpace *as)
{
memory_listener_unregister(&as->dispatch_listener);
}
void address_space_destroy_dispatch(AddressSpace *as)
{
AddressSpaceDispatch *d = as->dispatch;
atomic_rcu_set(&as->dispatch, NULL);
if (d) {
call_rcu(d, address_space_dispatch_free, rcu);
}
}
static void memory_map_init(void)
{
system_memory = g_malloc(sizeof(*system_memory));
memory_region_init(system_memory, NULL, "system", UINT64_MAX);
address_space_init(&address_space_memory, system_memory, "memory");
system_io = g_malloc(sizeof(*system_io));
memory_region_init_io(system_io, NULL, &unassigned_io_ops, NULL, "io",
65536);
address_space_init(&address_space_io, system_io, "I/O");
}
MemoryRegion *get_system_memory(void)
{
return system_memory;
}
MemoryRegion *get_system_io(void)
{
return system_io;
}
#endif /* !defined(CONFIG_USER_ONLY) */
/* physical memory access (slow version, mainly for debug) */
#if defined(CONFIG_USER_ONLY)
int cpu_memory_rw_debug(CPUState *cpu, target_ulong 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 -1;
if (is_write) {
if (!(flags & PAGE_WRITE))
return -1;
/* XXX: this code should not depend on lock_user */
if (!(p = lock_user(VERIFY_WRITE, addr, l, 0)))
return -1;
memcpy(p, buf, l);
unlock_user(p, addr, l);
} else {
if (!(flags & PAGE_READ))
return -1;
/* XXX: this code should not depend on lock_user */
if (!(p = lock_user(VERIFY_READ, addr, l, 1)))
return -1;
memcpy(buf, p, l);
unlock_user(p, addr, 0);
}
len -= l;
buf += l;
addr += l;
}
return 0;
}
#else
static void invalidate_and_set_dirty(MemoryRegion *mr, hwaddr addr,
hwaddr length)
{
uint8_t dirty_log_mask = memory_region_get_dirty_log_mask(mr);
/* No early return if dirty_log_mask is or becomes 0, because
* cpu_physical_memory_set_dirty_range will still call
* xen_modified_memory.
*/
if (dirty_log_mask) {
dirty_log_mask =
cpu_physical_memory_range_includes_clean(addr, length, dirty_log_mask);
}
if (dirty_log_mask & (1 << DIRTY_MEMORY_CODE)) {
tb_invalidate_phys_range(addr, addr + length);
dirty_log_mask &= ~(1 << DIRTY_MEMORY_CODE);
}
cpu_physical_memory_set_dirty_range(addr, length, dirty_log_mask);
}
static int memory_access_size(MemoryRegion *mr, unsigned l, hwaddr addr)
{
unsigned access_size_max = mr->ops->valid.max_access_size;
/* Regions are assumed to support 1-4 byte accesses unless
otherwise specified. */
if (access_size_max == 0) {
access_size_max = 4;
}
/* Bound the maximum access by the alignment of the address. */
if (!mr->ops->impl.unaligned) {
unsigned align_size_max = addr & -addr;
if (align_size_max != 0 && align_size_max < access_size_max) {
access_size_max = align_size_max;
}
}
/* Don't attempt accesses larger than the maximum. */
if (l > access_size_max) {
l = access_size_max;
}
l = pow2floor(l);
return l;
}
static bool prepare_mmio_access(MemoryRegion *mr)
{
bool unlocked = !qemu_mutex_iothread_locked();
bool release_lock = false;
if (unlocked && mr->global_locking) {
qemu_mutex_lock_iothread();
unlocked = false;
release_lock = true;
}
if (mr->flush_coalesced_mmio) {
if (unlocked) {
qemu_mutex_lock_iothread();
}
qemu_flush_coalesced_mmio_buffer();
if (unlocked) {
qemu_mutex_unlock_iothread();
}
}
return release_lock;
}
/* Called within RCU critical section. */
static MemTxResult address_space_write_continue(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs,
const uint8_t *buf,
int len, hwaddr addr1,
hwaddr l, MemoryRegion *mr)
{
uint8_t *ptr;
uint64_t val;
MemTxResult result = MEMTX_OK;
bool release_lock = false;
for (;;) {
if (!memory_access_is_direct(mr, true)) {
release_lock |= prepare_mmio_access(mr);
l = memory_access_size(mr, l, addr1);
/* XXX: could force current_cpu to NULL to avoid
potential bugs */
switch (l) {
case 8:
/* 64 bit write access */
val = ldq_p(buf);
result |= memory_region_dispatch_write(mr, addr1, val, 8,
attrs);
break;
case 4:
/* 32 bit write access */
val = ldl_p(buf);
result |= memory_region_dispatch_write(mr, addr1, val, 4,
attrs);
break;
case 2:
/* 16 bit write access */
val = lduw_p(buf);
result |= memory_region_dispatch_write(mr, addr1, val, 2,
attrs);
break;
case 1:
/* 8 bit write access */
val = ldub_p(buf);
result |= memory_region_dispatch_write(mr, addr1, val, 1,
attrs);
break;
default:
abort();
}
} else {
addr1 += memory_region_get_ram_addr(mr);
/* RAM case */
ptr = qemu_get_ram_ptr(mr->ram_block, addr1);
memcpy(ptr, buf, l);
invalidate_and_set_dirty(mr, addr1, l);
}
if (release_lock) {
qemu_mutex_unlock_iothread();
release_lock = false;
}
len -= l;
buf += l;
addr += l;
if (!len) {
break;
}
l = len;
mr = address_space_translate(as, addr, &addr1, &l, true);
}
return result;
}
MemTxResult address_space_write(AddressSpace *as, hwaddr addr, MemTxAttrs attrs,
const uint8_t *buf, int len)
{
hwaddr l;
hwaddr addr1;
MemoryRegion *mr;
MemTxResult result = MEMTX_OK;
if (len > 0) {
rcu_read_lock();
l = len;
mr = address_space_translate(as, addr, &addr1, &l, true);
result = address_space_write_continue(as, addr, attrs, buf, len,
addr1, l, mr);
rcu_read_unlock();
}
return result;
}
/* Called within RCU critical section. */
MemTxResult address_space_read_continue(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, uint8_t *buf,
int len, hwaddr addr1, hwaddr l,
MemoryRegion *mr)
{
uint8_t *ptr;
uint64_t val;
MemTxResult result = MEMTX_OK;
bool release_lock = false;
for (;;) {
if (!memory_access_is_direct(mr, false)) {
/* I/O case */
release_lock |= prepare_mmio_access(mr);
l = memory_access_size(mr, l, addr1);
switch (l) {
case 8:
/* 64 bit read access */
result |= memory_region_dispatch_read(mr, addr1, &val, 8,
attrs);
stq_p(buf, val);
break;
case 4:
/* 32 bit read access */
result |= memory_region_dispatch_read(mr, addr1, &val, 4,
attrs);
stl_p(buf, val);
break;
case 2:
/* 16 bit read access */
result |= memory_region_dispatch_read(mr, addr1, &val, 2,
attrs);
stw_p(buf, val);
break;
case 1:
/* 8 bit read access */
result |= memory_region_dispatch_read(mr, addr1, &val, 1,
attrs);
stb_p(buf, val);
break;
default:
abort();
}
} else {
/* RAM case */
ptr = qemu_get_ram_ptr(mr->ram_block,
memory_region_get_ram_addr(mr) + addr1);
memcpy(buf, ptr, l);
}
if (release_lock) {
qemu_mutex_unlock_iothread();
release_lock = false;
}
len -= l;
buf += l;
addr += l;
if (!len) {
break;
}
l = len;
mr = address_space_translate(as, addr, &addr1, &l, false);
}
return result;
}
MemTxResult address_space_read_full(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, uint8_t *buf, int len)
{
hwaddr l;
hwaddr addr1;
MemoryRegion *mr;
MemTxResult result = MEMTX_OK;
if (len > 0) {
rcu_read_lock();
l = len;
mr = address_space_translate(as, addr, &addr1, &l, false);
result = address_space_read_continue(as, addr, attrs, buf, len,
addr1, l, mr);
rcu_read_unlock();
}
return result;
}
MemTxResult address_space_rw(AddressSpace *as, hwaddr addr, MemTxAttrs attrs,
uint8_t *buf, int len, bool is_write)
{
if (is_write) {
return address_space_write(as, addr, attrs, (uint8_t *)buf, len);
} else {
return address_space_read(as, addr, attrs, (uint8_t *)buf, len);
}
}
void cpu_physical_memory_rw(hwaddr addr, uint8_t *buf,
int len, int is_write)
{
address_space_rw(&address_space_memory, addr, MEMTXATTRS_UNSPECIFIED,
buf, len, is_write);
}
enum write_rom_type {
WRITE_DATA,
FLUSH_CACHE,
};
static inline void cpu_physical_memory_write_rom_internal(AddressSpace *as,
hwaddr addr, const uint8_t *buf, int len, enum write_rom_type type)
{
hwaddr l;
uint8_t *ptr;
hwaddr addr1;
MemoryRegion *mr;
rcu_read_lock();
while (len > 0) {
l = len;
mr = address_space_translate(as, addr, &addr1, &l, true);
if (!(memory_region_is_ram(mr) ||
memory_region_is_romd(mr))) {
exec: skip MMIO regions correctly in cpu_physical_memory_write_rom_internal Loading the BIOS in the mac99 machine is interesting, because there is a PROM in the middle of the BIOS region (from 16K to 32K). Before memory region accesses were clamped, when QEMU was asked to load a BIOS from 0xfff00000 to 0xffffffff it would put even those 16K from the BIOS file into the region. This is weird because those 16K were not actually visible between 0xfff04000 and 0xfff07fff. However, it worked. After clamping was added, this also worked. In this case, the cpu_physical_memory_write_rom_internal function split the write in three parts: the first 16K were copied, the PROM area (second 16K) were ignored, then the rest was copied. Problems then started with commit 965eb2f (exec: do not clamp accesses to MMIO regions, 2015-06-17). Clamping accesses is not done for MMIO regions because they can overlap wildly, and MMIO registers can be expected to perform full-width accesses based only on their address (with no respect for adjacent registers that could decode to completely different MemoryRegions). However, this lack of clamping also applied to the PROM area! cpu_physical_memory_write_rom_internal thus failed to copy the third range above, i.e. only copied the first 16K of the BIOS. In effect, address_space_translate is expecting _something else_ to do the clamping for MMIO regions if the incoming length is large. This "something else" is memory_access_size in the case of address_space_rw, so use the same logic in cpu_physical_memory_write_rom_internal. Reported-by: Alexander Graf <agraf@redhat.com> Reviewed-by: Laurent Vivier <lvivier@redhat.com> Tested-by: Laurent Vivier <lvivier@redhat.com> Fixes: 965eb2f Signed-off-by: Paolo Bonzini <pbonzini@redhat.com>
2015-07-04 00:24:51 +02:00
l = memory_access_size(mr, l, addr1);
} else {
addr1 += memory_region_get_ram_addr(mr);
/* ROM/RAM case */
ptr = qemu_get_ram_ptr(mr->ram_block, addr1);
switch (type) {
case WRITE_DATA:
memcpy(ptr, buf, l);
invalidate_and_set_dirty(mr, addr1, l);
break;
case FLUSH_CACHE:
flush_icache_range((uintptr_t)ptr, (uintptr_t)ptr + l);
break;
}
}
len -= l;
buf += l;
addr += l;
}
rcu_read_unlock();
}
/* used for ROM loading : can write in RAM and ROM */
void cpu_physical_memory_write_rom(AddressSpace *as, hwaddr addr,
const uint8_t *buf, int len)
{
cpu_physical_memory_write_rom_internal(as, addr, buf, len, WRITE_DATA);
}
void cpu_flush_icache_range(hwaddr start, int len)
{
/*
* This function should do the same thing as an icache flush that was
* triggered from within the guest. For TCG we are always cache coherent,
* so there is no need to flush anything. For KVM / Xen we need to flush
* the host's instruction cache at least.
*/
if (tcg_enabled()) {
return;
}
cpu_physical_memory_write_rom_internal(&address_space_memory,
start, NULL, len, FLUSH_CACHE);
}
typedef struct {
MemoryRegion *mr;
void *buffer;
hwaddr addr;
hwaddr len;
bool in_use;
} BounceBuffer;
static BounceBuffer bounce;
typedef struct MapClient {
QEMUBH *bh;
QLIST_ENTRY(MapClient) link;
} MapClient;
QemuMutex map_client_list_lock;
static QLIST_HEAD(map_client_list, MapClient) map_client_list
= QLIST_HEAD_INITIALIZER(map_client_list);
static void cpu_unregister_map_client_do(MapClient *client)
{
QLIST_REMOVE(client, link);
g_free(client);
}
static void cpu_notify_map_clients_locked(void)
{
MapClient *client;
while (!QLIST_EMPTY(&map_client_list)) {
client = QLIST_FIRST(&map_client_list);
qemu_bh_schedule(client->bh);
cpu_unregister_map_client_do(client);
}
}
void cpu_register_map_client(QEMUBH *bh)
{
MapClient *client = g_malloc(sizeof(*client));
qemu_mutex_lock(&map_client_list_lock);
client->bh = bh;
QLIST_INSERT_HEAD(&map_client_list, client, link);
if (!atomic_read(&bounce.in_use)) {
cpu_notify_map_clients_locked();
}
qemu_mutex_unlock(&map_client_list_lock);
}
void cpu_exec_init_all(void)
{
qemu_mutex_init(&ram_list.mutex);
io_mem_init();
memory_map_init();
qemu_mutex_init(&map_client_list_lock);
}
void cpu_unregister_map_client(QEMUBH *bh)
{
MapClient *client;
qemu_mutex_lock(&map_client_list_lock);
QLIST_FOREACH(client, &map_client_list, link) {
if (client->bh == bh) {
cpu_unregister_map_client_do(client);
break;
}
}
qemu_mutex_unlock(&map_client_list_lock);
}
static void cpu_notify_map_clients(void)
{
qemu_mutex_lock(&map_client_list_lock);
cpu_notify_map_clients_locked();
qemu_mutex_unlock(&map_client_list_lock);
}
bool address_space_access_valid(AddressSpace *as, hwaddr addr, int len, bool is_write)
{
MemoryRegion *mr;
hwaddr l, xlat;
rcu_read_lock();
while (len > 0) {
l = len;
mr = address_space_translate(as, addr, &xlat, &l, is_write);
if (!memory_access_is_direct(mr, is_write)) {
l = memory_access_size(mr, l, addr);
if (!memory_region_access_valid(mr, xlat, l, is_write)) {
return false;
}
}
len -= l;
addr += l;
}
rcu_read_unlock();
return true;
}
/* 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 *address_space_map(AddressSpace *as,
hwaddr addr,
hwaddr *plen,
bool is_write)
{
hwaddr len = *plen;
hwaddr done = 0;
hwaddr l, xlat, base;
MemoryRegion *mr, *this_mr;
ram_addr_t raddr;
void *ptr;
if (len == 0) {
return NULL;
}
l = len;
rcu_read_lock();
mr = address_space_translate(as, addr, &xlat, &l, is_write);
if (!memory_access_is_direct(mr, is_write)) {
if (atomic_xchg(&bounce.in_use, true)) {
rcu_read_unlock();
return NULL;
}
/* Avoid unbounded allocations */
l = MIN(l, TARGET_PAGE_SIZE);
bounce.buffer = qemu_memalign(TARGET_PAGE_SIZE, l);
bounce.addr = addr;
bounce.len = l;
memory_region_ref(mr);
bounce.mr = mr;
if (!is_write) {
address_space_read(as, addr, MEMTXATTRS_UNSPECIFIED,
bounce.buffer, l);
}
rcu_read_unlock();
*plen = l;
return bounce.buffer;
}
base = xlat;
raddr = memory_region_get_ram_addr(mr);
for (;;) {
len -= l;
addr += l;
done += l;
if (len == 0) {
break;
}
l = len;
this_mr = address_space_translate(as, addr, &xlat, &l, is_write);
if (this_mr != mr || xlat != base + done) {
break;
}
}
memory_region_ref(mr);
*plen = done;
ptr = qemu_ram_ptr_length(mr->ram_block, raddr + base, plen);
rcu_read_unlock();
return ptr;
}
/* Unmaps a memory region previously mapped by address_space_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 address_space_unmap(AddressSpace *as, void *buffer, hwaddr len,
int is_write, hwaddr access_len)
{
if (buffer != bounce.buffer) {
MemoryRegion *mr;
ram_addr_t addr1;
mr = qemu_ram_addr_from_host(buffer, &addr1);
assert(mr != NULL);
if (is_write) {
invalidate_and_set_dirty(mr, addr1, access_len);
}
if (xen_enabled()) {
xen_invalidate_map_cache_entry(buffer);
}
memory_region_unref(mr);
return;
}
if (is_write) {
address_space_write(as, bounce.addr, MEMTXATTRS_UNSPECIFIED,
bounce.buffer, access_len);
}
qemu_vfree(bounce.buffer);
bounce.buffer = NULL;
memory_region_unref(bounce.mr);
atomic_mb_set(&bounce.in_use, false);
cpu_notify_map_clients();
}
void *cpu_physical_memory_map(hwaddr addr,
hwaddr *plen,
int is_write)
{
return address_space_map(&address_space_memory, addr, plen, is_write);
}
void cpu_physical_memory_unmap(void *buffer, hwaddr len,
int is_write, hwaddr access_len)
{
return address_space_unmap(&address_space_memory, buffer, len, is_write, access_len);
}
/* warning: addr must be aligned */
static inline uint32_t address_space_ldl_internal(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs,
MemTxResult *result,
enum device_endian endian)
{
uint8_t *ptr;
uint64_t val;
MemoryRegion *mr;
hwaddr l = 4;
hwaddr addr1;
MemTxResult r;
bool release_lock = false;
rcu_read_lock();
mr = address_space_translate(as, addr, &addr1, &l, false);
if (l < 4 || !memory_access_is_direct(mr, false)) {
release_lock |= prepare_mmio_access(mr);
/* I/O case */
r = memory_region_dispatch_read(mr, addr1, &val, 4, attrs);
#if defined(TARGET_WORDS_BIGENDIAN)
if (endian == DEVICE_LITTLE_ENDIAN) {
val = bswap32(val);
}
#else
if (endian == DEVICE_BIG_ENDIAN) {
val = bswap32(val);
}
#endif
} else {
/* RAM case */
ptr = qemu_get_ram_ptr(mr->ram_block,
(memory_region_get_ram_addr(mr)
& TARGET_PAGE_MASK)
+ addr1);
switch (endian) {
case DEVICE_LITTLE_ENDIAN:
val = ldl_le_p(ptr);
break;
case DEVICE_BIG_ENDIAN:
val = ldl_be_p(ptr);
break;
default:
val = ldl_p(ptr);
break;
}
r = MEMTX_OK;
}
if (result) {
*result = r;
}
if (release_lock) {
qemu_mutex_unlock_iothread();
}
rcu_read_unlock();
return val;
}
uint32_t address_space_ldl(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_ldl_internal(as, addr, attrs, result,
DEVICE_NATIVE_ENDIAN);
}
uint32_t address_space_ldl_le(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_ldl_internal(as, addr, attrs, result,
DEVICE_LITTLE_ENDIAN);
}
uint32_t address_space_ldl_be(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_ldl_internal(as, addr, attrs, result,
DEVICE_BIG_ENDIAN);
}
uint32_t ldl_phys(AddressSpace *as, hwaddr addr)
{
return address_space_ldl(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
uint32_t ldl_le_phys(AddressSpace *as, hwaddr addr)
{
return address_space_ldl_le(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
uint32_t ldl_be_phys(AddressSpace *as, hwaddr addr)
{
return address_space_ldl_be(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* warning: addr must be aligned */
static inline uint64_t address_space_ldq_internal(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs,
MemTxResult *result,
enum device_endian endian)
{
uint8_t *ptr;
uint64_t val;
MemoryRegion *mr;
hwaddr l = 8;
hwaddr addr1;
MemTxResult r;
bool release_lock = false;
rcu_read_lock();
mr = address_space_translate(as, addr, &addr1, &l,
false);
if (l < 8 || !memory_access_is_direct(mr, false)) {
release_lock |= prepare_mmio_access(mr);
/* I/O case */
r = memory_region_dispatch_read(mr, addr1, &val, 8, attrs);
#if defined(TARGET_WORDS_BIGENDIAN)
if (endian == DEVICE_LITTLE_ENDIAN) {
val = bswap64(val);
}
#else
if (endian == DEVICE_BIG_ENDIAN) {
val = bswap64(val);
}
#endif
} else {
/* RAM case */
ptr = qemu_get_ram_ptr(mr->ram_block,
(memory_region_get_ram_addr(mr)
& TARGET_PAGE_MASK)
+ addr1);
switch (endian) {
case DEVICE_LITTLE_ENDIAN:
val = ldq_le_p(ptr);
break;
case DEVICE_BIG_ENDIAN:
val = ldq_be_p(ptr);
break;
default:
val = ldq_p(ptr);
break;
}
r = MEMTX_OK;
}
if (result) {
*result = r;
}
if (release_lock) {
qemu_mutex_unlock_iothread();
}
rcu_read_unlock();
return val;
}
uint64_t address_space_ldq(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_ldq_internal(as, addr, attrs, result,
DEVICE_NATIVE_ENDIAN);
}
uint64_t address_space_ldq_le(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_ldq_internal(as, addr, attrs, result,
DEVICE_LITTLE_ENDIAN);
}
uint64_t address_space_ldq_be(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_ldq_internal(as, addr, attrs, result,
DEVICE_BIG_ENDIAN);
}
uint64_t ldq_phys(AddressSpace *as, hwaddr addr)
{
return address_space_ldq(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
uint64_t ldq_le_phys(AddressSpace *as, hwaddr addr)
{
return address_space_ldq_le(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
uint64_t ldq_be_phys(AddressSpace *as, hwaddr addr)
{
return address_space_ldq_be(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* XXX: optimize */
uint32_t address_space_ldub(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
uint8_t val;
MemTxResult r;
r = address_space_rw(as, addr, attrs, &val, 1, 0);
if (result) {
*result = r;
}
return val;
}
uint32_t ldub_phys(AddressSpace *as, hwaddr addr)
{
return address_space_ldub(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* warning: addr must be aligned */
static inline uint32_t address_space_lduw_internal(AddressSpace *as,
hwaddr addr,
MemTxAttrs attrs,
MemTxResult *result,
enum device_endian endian)
{
uint8_t *ptr;
uint64_t val;
MemoryRegion *mr;
hwaddr l = 2;
hwaddr addr1;
MemTxResult r;
bool release_lock = false;
rcu_read_lock();
mr = address_space_translate(as, addr, &addr1, &l,
false);
if (l < 2 || !memory_access_is_direct(mr, false)) {
release_lock |= prepare_mmio_access(mr);
/* I/O case */
r = memory_region_dispatch_read(mr, addr1, &val, 2, attrs);
#if defined(TARGET_WORDS_BIGENDIAN)
if (endian == DEVICE_LITTLE_ENDIAN) {
val = bswap16(val);
}
#else
if (endian == DEVICE_BIG_ENDIAN) {
val = bswap16(val);
}
#endif
} else {
/* RAM case */
ptr = qemu_get_ram_ptr(mr->ram_block,
(memory_region_get_ram_addr(mr)
& TARGET_PAGE_MASK)
+ addr1);
switch (endian) {
case DEVICE_LITTLE_ENDIAN:
val = lduw_le_p(ptr);
break;
case DEVICE_BIG_ENDIAN:
val = lduw_be_p(ptr);
break;
default:
val = lduw_p(ptr);
break;
}
r = MEMTX_OK;
}
if (result) {
*result = r;
}
if (release_lock) {
qemu_mutex_unlock_iothread();
}
rcu_read_unlock();
return val;
}
uint32_t address_space_lduw(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_lduw_internal(as, addr, attrs, result,
DEVICE_NATIVE_ENDIAN);
}
uint32_t address_space_lduw_le(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_lduw_internal(as, addr, attrs, result,
DEVICE_LITTLE_ENDIAN);
}
uint32_t address_space_lduw_be(AddressSpace *as, hwaddr addr,
MemTxAttrs attrs, MemTxResult *result)
{
return address_space_lduw_internal(as, addr, attrs, result,
DEVICE_BIG_ENDIAN);
}
uint32_t lduw_phys(AddressSpace *as, hwaddr addr)
{
return address_space_lduw(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
uint32_t lduw_le_phys(AddressSpace *as, hwaddr addr)
{
return address_space_lduw_le(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
uint32_t lduw_be_phys(AddressSpace *as, hwaddr addr)
{
return address_space_lduw_be(as, addr, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* 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 address_space_stl_notdirty(AddressSpace *as, hwaddr addr, uint32_t val,
MemTxAttrs attrs, MemTxResult *result)
{
uint8_t *ptr;
MemoryRegion *mr;
hwaddr l = 4;
hwaddr addr1;
MemTxResult r;
uint8_t dirty_log_mask;
bool release_lock = false;
rcu_read_lock();
mr = address_space_translate(as, addr, &addr1, &l,
true);
if (l < 4 || !memory_access_is_direct(mr, true)) {
release_lock |= prepare_mmio_access(mr);
r = memory_region_dispatch_write(mr, addr1, val, 4, attrs);
} else {
addr1 += memory_region_get_ram_addr(mr) & TARGET_PAGE_MASK;
ptr = qemu_get_ram_ptr(mr->ram_block, addr1);
stl_p(ptr, val);
dirty_log_mask = memory_region_get_dirty_log_mask(mr);
dirty_log_mask &= ~(1 << DIRTY_MEMORY_CODE);
cpu_physical_memory_set_dirty_range(addr1, 4, dirty_log_mask);
r = MEMTX_OK;
}
if (result) {
*result = r;
}
if (release_lock) {
qemu_mutex_unlock_iothread();
}
rcu_read_unlock();
}
void stl_phys_notdirty(AddressSpace *as, hwaddr addr, uint32_t val)
{
address_space_stl_notdirty(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* warning: addr must be aligned */
static inline void address_space_stl_internal(AddressSpace *as,
hwaddr addr, uint32_t val,
MemTxAttrs attrs,
MemTxResult *result,
enum device_endian endian)
{
uint8_t *ptr;
MemoryRegion *mr;
hwaddr l = 4;
hwaddr addr1;
MemTxResult r;
bool release_lock = false;
rcu_read_lock();
mr = address_space_translate(as, addr, &addr1, &l,
true);
if (l < 4 || !memory_access_is_direct(mr, true)) {
release_lock |= prepare_mmio_access(mr);
#if defined(TARGET_WORDS_BIGENDIAN)
if (endian == DEVICE_LITTLE_ENDIAN) {
val = bswap32(val);
}
#else
if (endian == DEVICE_BIG_ENDIAN) {
val = bswap32(val);
}
#endif
r = memory_region_dispatch_write(mr, addr1, val, 4, attrs);
} else {
/* RAM case */
addr1 += memory_region_get_ram_addr(mr) & TARGET_PAGE_MASK;
ptr = qemu_get_ram_ptr(mr->ram_block, addr1);
switch (endian) {
case DEVICE_LITTLE_ENDIAN:
stl_le_p(ptr, val);
break;
case DEVICE_BIG_ENDIAN:
stl_be_p(ptr, val);
break;
default:
stl_p(ptr, val);
break;
}
invalidate_and_set_dirty(mr, addr1, 4);
r = MEMTX_OK;
}
if (result) {
*result = r;
}
if (release_lock) {
qemu_mutex_unlock_iothread();
}
rcu_read_unlock();
}
void address_space_stl(AddressSpace *as, hwaddr addr, uint32_t val,
MemTxAttrs attrs, MemTxResult *result)
{
address_space_stl_internal(as, addr, val, attrs, result,
DEVICE_NATIVE_ENDIAN);
}
void address_space_stl_le(AddressSpace *as, hwaddr addr, uint32_t val,
MemTxAttrs attrs, MemTxResult *result)
{
address_space_stl_internal(as, addr, val, attrs, result,
DEVICE_LITTLE_ENDIAN);
}
void address_space_stl_be(AddressSpace *as, hwaddr addr, uint32_t val,
MemTxAttrs attrs, MemTxResult *result)
{
address_space_stl_internal(as, addr, val, attrs, result,
DEVICE_BIG_ENDIAN);
}
void stl_phys(AddressSpace *as, hwaddr addr, uint32_t val)
{
address_space_stl(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
void stl_le_phys(AddressSpace *as, hwaddr addr, uint32_t val)
{
address_space_stl_le(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
void stl_be_phys(AddressSpace *as, hwaddr addr, uint32_t val)
{
address_space_stl_be(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* XXX: optimize */
void address_space_stb(AddressSpace *as, hwaddr addr, uint32_t val,
MemTxAttrs attrs, MemTxResult *result)
{
uint8_t v = val;
MemTxResult r;
r = address_space_rw(as, addr, attrs, &v, 1, 1);
if (result) {
*result = r;
}
}
void stb_phys(AddressSpace *as, hwaddr addr, uint32_t val)
{
address_space_stb(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* warning: addr must be aligned */
static inline void address_space_stw_internal(AddressSpace *as,
hwaddr addr, uint32_t val,
MemTxAttrs attrs,
MemTxResult *result,
enum device_endian endian)
{
uint8_t *ptr;
MemoryRegion *mr;
hwaddr l = 2;
hwaddr addr1;
MemTxResult r;
bool release_lock = false;
rcu_read_lock();
mr = address_space_translate(as, addr, &addr1, &l, true);
if (l < 2 || !memory_access_is_direct(mr, true)) {
release_lock |= prepare_mmio_access(mr);
#if defined(TARGET_WORDS_BIGENDIAN)
if (endian == DEVICE_LITTLE_ENDIAN) {
val = bswap16(val);
}
#else
if (endian == DEVICE_BIG_ENDIAN) {
val = bswap16(val);
}
#endif
r = memory_region_dispatch_write(mr, addr1, val, 2, attrs);
} else {
/* RAM case */
addr1 += memory_region_get_ram_addr(mr) & TARGET_PAGE_MASK;
ptr = qemu_get_ram_ptr(mr->ram_block, addr1);
switch (endian) {
case DEVICE_LITTLE_ENDIAN:
stw_le_p(ptr, val);
break;
case DEVICE_BIG_ENDIAN:
stw_be_p(ptr, val);
break;
default:
stw_p(ptr, val);
break;
}
invalidate_and_set_dirty(mr, addr1, 2);
r = MEMTX_OK;
}
if (result) {
*result = r;
}
if (release_lock) {
qemu_mutex_unlock_iothread();
}
rcu_read_unlock();
}
void address_space_stw(AddressSpace *as, hwaddr addr, uint32_t val,
MemTxAttrs attrs, MemTxResult *result)
{
address_space_stw_internal(as, addr, val, attrs, result,
DEVICE_NATIVE_ENDIAN);
}
void address_space_stw_le(AddressSpace *as, hwaddr addr, uint32_t val,
MemTxAttrs attrs, MemTxResult *result)
{
address_space_stw_internal(as, addr, val, attrs, result,
DEVICE_LITTLE_ENDIAN);
}
void address_space_stw_be(AddressSpace *as, hwaddr addr, uint32_t val,
MemTxAttrs attrs, MemTxResult *result)
{
address_space_stw_internal(as, addr, val, attrs, result,
DEVICE_BIG_ENDIAN);
}
void stw_phys(AddressSpace *as, hwaddr addr, uint32_t val)
{
address_space_stw(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
void stw_le_phys(AddressSpace *as, hwaddr addr, uint32_t val)
{
address_space_stw_le(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
void stw_be_phys(AddressSpace *as, hwaddr addr, uint32_t val)
{
address_space_stw_be(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* XXX: optimize */
void address_space_stq(AddressSpace *as, hwaddr addr, uint64_t val,
MemTxAttrs attrs, MemTxResult *result)
{
MemTxResult r;
val = tswap64(val);
r = address_space_rw(as, addr, attrs, (void *) &val, 8, 1);
if (result) {
*result = r;
}
}
void address_space_stq_le(AddressSpace *as, hwaddr addr, uint64_t val,
MemTxAttrs attrs, MemTxResult *result)
{
MemTxResult r;
val = cpu_to_le64(val);
r = address_space_rw(as, addr, attrs, (void *) &val, 8, 1);
if (result) {
*result = r;
}
}
void address_space_stq_be(AddressSpace *as, hwaddr addr, uint64_t val,
MemTxAttrs attrs, MemTxResult *result)
{
MemTxResult r;
val = cpu_to_be64(val);
r = address_space_rw(as, addr, attrs, (void *) &val, 8, 1);
if (result) {
*result = r;
}
}
void stq_phys(AddressSpace *as, hwaddr addr, uint64_t val)
{
address_space_stq(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
void stq_le_phys(AddressSpace *as, hwaddr addr, uint64_t val)
{
address_space_stq_le(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
void stq_be_phys(AddressSpace *as, hwaddr addr, uint64_t val)
{
address_space_stq_be(as, addr, val, MEMTXATTRS_UNSPECIFIED, NULL);
}
/* virtual memory access for debug (includes writing to ROM) */
int cpu_memory_rw_debug(CPUState *cpu, target_ulong addr,
uint8_t *buf, int len, int is_write)
{
int l;
hwaddr phys_addr;
target_ulong page;
while (len > 0) {
int asidx;
MemTxAttrs attrs;
page = addr & TARGET_PAGE_MASK;
phys_addr = cpu_get_phys_page_attrs_debug(cpu, page, &attrs);
asidx = cpu_asidx_from_attrs(cpu, attrs);
/* 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 (is_write) {
cpu_physical_memory_write_rom(cpu->cpu_ases[asidx].as,
phys_addr, buf, l);
} else {
address_space_rw(cpu->cpu_ases[asidx].as, phys_addr,
MEMTXATTRS_UNSPECIFIED,
buf, l, 0);
}
len -= l;
buf += l;
addr += l;
}
return 0;
}
/*
* Allows code that needs to deal with migration bitmaps etc to still be built
* target independent.
*/
size_t qemu_target_page_bits(void)
{
return TARGET_PAGE_BITS;
}
#endif
/*
* A helper function for the _utterly broken_ virtio device model to find out if
* it's running on a big endian machine. Don't do this at home kids!
*/
bool target_words_bigendian(void);
bool target_words_bigendian(void)
{
#if defined(TARGET_WORDS_BIGENDIAN)
return true;
#else
return false;
#endif
}
#ifndef CONFIG_USER_ONLY
bool cpu_physical_memory_is_io(hwaddr phys_addr)
{
MemoryRegion*mr;
hwaddr l = 1;
bool res;
rcu_read_lock();
mr = address_space_translate(&address_space_memory,
phys_addr, &phys_addr, &l, false);
res = !(memory_region_is_ram(mr) || memory_region_is_romd(mr));
rcu_read_unlock();
return res;
}
int qemu_ram_foreach_block(RAMBlockIterFunc func, void *opaque)
{
RAMBlock *block;
int ret = 0;
rcu_read_lock();
QLIST_FOREACH_RCU(block, &ram_list.blocks, next) {
ret = func(block->idstr, block->host, block->offset,
block->used_length, opaque);
if (ret) {
break;
}
}
rcu_read_unlock();
return ret;
}
#endif