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提交 7a542b67 编写于 作者: A Anthony Liguori
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Merge remote-tracking branch 'sstabellini/xen-pt' into staging 

* sstabellini/xen-pt:
  Introduce Xen PCI Passthrough, MSI
  Introduce apic-msidef.h
  Introduce Xen PCI Passthrough, PCI config space helpers
  Introduce Xen PCI Passthrough, qdevice
  qdev-properties: Introduce pci-host-devaddr.
  pci.c: Add opaque argument to pci_for_each_device.
  Introduce XenHostPCIDevice to access a pci device on the host.
  configure: Introduce --enable-xen-pci-passthrough.
  pci_ids: Add INTEL_82599_SFP_VF id.
上级 b1a6609e 3854ca57
隐藏空白更改
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Showing with 4301 addition and 19 deletion
configure
浏览文件 @ 7a542b67
......@@ -137,6 +137,7 @@ vnc_png=""
vnc_thread="no"
xen=""
xen_ctrl_version=""
xen_pci_passthrough=""
linux_aio=""
cap_ng=""
attr=""
......@@ -684,6 +685,10 @@ for opt do
;;
--enable-xen) xen="yes"
;;
--disable-xen-pci-passthrough) xen_pci_passthrough="no"
;;
--enable-xen-pci-passthrough) xen_pci_passthrough="yes"
;;
--disable-brlapi) brlapi="no"
;;
--enable-brlapi) brlapi="yes"
......@@ -1031,6 +1036,8 @@ echo " (affects only QEMU, not qemu-img)"
echo " --enable-mixemu enable mixer emulation"
echo " --disable-xen disable xen backend driver support"
echo " --enable-xen enable xen backend driver support"
echo " --disable-xen-pci-passthrough"
echo " --enable-xen-pci-passthrough"
echo " --disable-brlapi disable BrlAPI"
echo " --enable-brlapi enable BrlAPI"
echo " --disable-vnc-tls disable TLS encryption for VNC server"
......@@ -1507,6 +1514,25 @@ EOF
fi
fi
if test "$xen_pci_passthrough" != "no"; then
if test "$xen" = "yes" && test "$linux" = "yes" &&
test "$xen_ctrl_version" -ge 340; then
xen_pci_passthrough=yes
else
if test "$xen_pci_passthrough" = "yes"; then
echo "ERROR"
echo "ERROR: User requested feature Xen PCI Passthrough"
echo "ERROR: but this feature require /sys from Linux"
if test "$xen_ctrl_version" -lt 340; then
echo "ERROR: This feature does not work with Xen 3.3"
fi
echo "ERROR"
exit 1;
fi
xen_pci_passthrough=no
fi
fi
##########################################
# pkg-config probe
......@@ -3702,6 +3728,9 @@ case "$target_arch2" in
if test "$xen" = "yes" -a "$target_softmmu" = "yes" ; then
target_phys_bits=64
echo "CONFIG_XEN=y" >> $config_target_mak
if test "$xen_pci_passthrough" = yes; then
echo "CONFIG_XEN_PCI_PASSTHROUGH=y" >> "$config_target_mak"
fi
else
echo "CONFIG_NO_XEN=y" >> $config_target_mak
fi
......
hw/apic-msidef.h 0 → 100644
浏览文件 @ 7a542b67
#ifndef HW_APIC_MSIDEF_H
#define HW_APIC_MSIDEF_H
/*
* Intel APIC constants: from include/asm/msidef.h
*/
/*
* Shifts for MSI data
*/
#define MSI_DATA_VECTOR_SHIFT 0
#define MSI_DATA_VECTOR_MASK 0x000000ff
#define MSI_DATA_DELIVERY_MODE_SHIFT 8
#define MSI_DATA_LEVEL_SHIFT 14
#define MSI_DATA_TRIGGER_SHIFT 15
/*
* Shift/mask fields for msi address
*/
#define MSI_ADDR_DEST_MODE_SHIFT 2
#define MSI_ADDR_REDIRECTION_SHIFT 3
#define MSI_ADDR_DEST_ID_SHIFT 12
#define MSI_ADDR_DEST_ID_MASK 0x00ffff0
#endif /* HW_APIC_MSIDEF_H */
hw/apic.c
浏览文件 @ 7a542b67
......@@ -23,19 +23,10 @@
#include "host-utils.h"
#include "trace.h"
#include "pc.h"
#include "apic-msidef.h"
#define MAX_APIC_WORDS 8
/* Intel APIC constants: from include/asm/msidef.h */
#define MSI_DATA_VECTOR_SHIFT 0
#define MSI_DATA_VECTOR_MASK 0x000000ff
#define MSI_DATA_DELIVERY_MODE_SHIFT 8
#define MSI_DATA_TRIGGER_SHIFT 15
#define MSI_DATA_LEVEL_SHIFT 14
#define MSI_ADDR_DEST_MODE_SHIFT 2
#define MSI_ADDR_DEST_ID_SHIFT 12
#define MSI_ADDR_DEST_ID_MASK 0x00ffff0
#define SYNC_FROM_VAPIC 0x1
#define SYNC_TO_VAPIC 0x2
#define SYNC_ISR_IRR_TO_VAPIC 0x4
......
hw/i386/Makefile.objs
浏览文件 @ 7a542b67
......@@ -7,6 +7,8 @@ obj-y += debugcon.o multiboot.o
obj-y += pc_piix.o
obj-y += pc_sysfw.o
obj-$(CONFIG_XEN) += xen_platform.o xen_apic.o
obj-$(CONFIG_XEN_PCI_PASSTHROUGH) += xen-host-pci-device.o
obj-$(CONFIG_XEN_PCI_PASSTHROUGH) += xen_pt.o xen_pt_config_init.o xen_pt_msi.o
obj-y += kvm/
obj-$(CONFIG_SPICE) += qxl.o qxl-logger.o qxl-render.o
......
hw/pci.c
浏览文件 @ 7a542b67
......@@ -1144,7 +1144,9 @@ static const pci_class_desc pci_class_descriptions[] =
};
static void pci_for_each_device_under_bus(PCIBus *bus,
void (*fn)(PCIBus *b, PCIDevice *d))
void (*fn)(PCIBus *b, PCIDevice *d,
void *opaque),
void *opaque)
{
PCIDevice *d;
int devfn;
......@@ -1152,18 +1154,19 @@ static void pci_for_each_device_under_bus(PCIBus *bus,
for(devfn = 0; devfn < ARRAY_SIZE(bus->devices); devfn++) {
d = bus->devices[devfn];
if (d) {
fn(bus, d);
fn(bus, d, opaque);
}
}
}
void pci_for_each_device(PCIBus *bus, int bus_num,
void (*fn)(PCIBus *b, PCIDevice *d))
void (*fn)(PCIBus *b, PCIDevice *d, void *opaque),
void *opaque)
{
bus = pci_find_bus_nr(bus, bus_num);
if (bus) {
pci_for_each_device_under_bus(bus, fn);
pci_for_each_device_under_bus(bus, fn, opaque);
}
}
......
hw/pci.h
浏览文件 @ 7a542b67
......@@ -312,7 +312,9 @@ PCIDevice *pci_nic_init(NICInfo *nd, const char *default_model,
PCIDevice *pci_nic_init_nofail(NICInfo *nd, const char *default_model,
const char *default_devaddr);
int pci_bus_num(PCIBus *s);
void pci_for_each_device(PCIBus *bus, int bus_num, void (*fn)(PCIBus *bus, PCIDevice *d));
void pci_for_each_device(PCIBus *bus, int bus_num,
void (*fn)(PCIBus *bus, PCIDevice *d, void *opaque),
void *opaque);
PCIBus *pci_find_root_bus(int domain);
int pci_find_domain(const PCIBus *bus);
PCIDevice *pci_find_device(PCIBus *bus, int bus_num, uint8_t devfn);
......
hw/pci_ids.h
浏览文件 @ 7a542b67
......@@ -118,6 +118,7 @@
#define PCI_DEVICE_ID_INTEL_82801I_UHCI6 0x2939
#define PCI_DEVICE_ID_INTEL_82801I_EHCI1 0x293a
#define PCI_DEVICE_ID_INTEL_82801I_EHCI2 0x293c
#define PCI_DEVICE_ID_INTEL_82599_SFP_VF 0x10ed
#define PCI_VENDOR_ID_XEN 0x5853
#define PCI_DEVICE_ID_XEN_PLATFORM 0x0001
......
hw/qdev-properties.c
浏览文件 @ 7a542b67
......@@ -899,6 +899,113 @@ PropertyInfo qdev_prop_blocksize = {
.set = set_blocksize,
};
/* --- pci host address --- */
static void get_pci_host_devaddr(Object *obj, Visitor *v, void *opaque,
const char *name, Error **errp)
{
DeviceState *dev = DEVICE(obj);
Property *prop = opaque;
PCIHostDeviceAddress *addr = qdev_get_prop_ptr(dev, prop);
char buffer[] = "xxxx:xx:xx.x";
char *p = buffer;
int rc = 0;
rc = snprintf(buffer, sizeof(buffer), "%04x:%02x:%02x.%d",
addr->domain, addr->bus, addr->slot, addr->function);
assert(rc == sizeof(buffer) - 1);
visit_type_str(v, &p, name, errp);
}
/*
* Parse [<domain>:]<bus>:<slot>.<func>
* if <domain> is not supplied, it's assumed to be 0.
*/
static void set_pci_host_devaddr(Object *obj, Visitor *v, void *opaque,
const char *name, Error **errp)
{
DeviceState *dev = DEVICE(obj);
Property *prop = opaque;
PCIHostDeviceAddress *addr = qdev_get_prop_ptr(dev, prop);
Error *local_err = NULL;
char *str, *p;
char *e;
unsigned long val;
unsigned long dom = 0, bus = 0;
unsigned int slot = 0, func = 0;
if (dev->state != DEV_STATE_CREATED) {
error_set(errp, QERR_PERMISSION_DENIED);
return;
}
visit_type_str(v, &str, name, &local_err);
if (local_err) {
error_propagate(errp, local_err);
return;
}
p = str;
val = strtoul(p, &e, 16);
if (e == p || *e != ':') {
goto inval;
}
bus = val;
p = e + 1;
val = strtoul(p, &e, 16);
if (e == p) {
goto inval;
}
if (*e == ':') {
dom = bus;
bus = val;
p = e + 1;
val = strtoul(p, &e, 16);
if (e == p) {
goto inval;
}
}
slot = val;
if (*e != '.') {
goto inval;
}
p = e + 1;
val = strtoul(p, &e, 10);
if (e == p) {
goto inval;
}
func = val;
if (dom > 0xffff || bus > 0xff || slot > 0x1f || func > 7) {
goto inval;
}
if (*e) {
goto inval;
}
addr->domain = dom;
addr->bus = bus;
addr->slot = slot;
addr->function = func;
g_free(str);
return;
inval:
error_set_from_qdev_prop_error(errp, EINVAL, dev, prop, str);
g_free(str);
}
PropertyInfo qdev_prop_pci_host_devaddr = {
.name = "pci-host-devaddr",
.get = get_pci_host_devaddr,
.set = set_pci_host_devaddr,
};
/* --- public helpers --- */
static Property *qdev_prop_walk(Property *props, const char *name)
......
hw/qdev.h
浏览文件 @ 7a542b67
......@@ -237,6 +237,7 @@ extern PropertyInfo qdev_prop_netdev;
extern PropertyInfo qdev_prop_vlan;
extern PropertyInfo qdev_prop_pci_devfn;
extern PropertyInfo qdev_prop_blocksize;
extern PropertyInfo qdev_prop_pci_host_devaddr;
#define DEFINE_PROP(_name, _state, _field, _prop, _type) { \
.name = (_name), \
......@@ -300,6 +301,8 @@ extern PropertyInfo qdev_prop_blocksize;
LostTickPolicy)
#define DEFINE_PROP_BLOCKSIZE(_n, _s, _f, _d) \
DEFINE_PROP_DEFAULT(_n, _s, _f, _d, qdev_prop_blocksize, uint16_t)
#define DEFINE_PROP_PCI_HOST_DEVADDR(_n, _s, _f) \
DEFINE_PROP(_n, _s, _f, qdev_prop_pci_host_devaddr, PCIHostDeviceAddress)
#define DEFINE_PROP_END_OF_LIST() \
{}
......
hw/xen-host-pci-device.c 0 → 100644
浏览文件 @ 7a542b67
/*
* Copyright (C) 2011 Citrix Ltd.
*
* This work is licensed under the terms of the GNU GPL, version 2. See
* the COPYING file in the top-level directory.
*
*/
#include "qemu-common.h"
#include "xen-host-pci-device.h"
#define XEN_HOST_PCI_MAX_EXT_CAP \
((PCIE_CONFIG_SPACE_SIZE - PCI_CONFIG_SPACE_SIZE) / (PCI_CAP_SIZEOF + 4))
#ifdef XEN_HOST_PCI_DEVICE_DEBUG
# define XEN_HOST_PCI_LOG(f, a...) fprintf(stderr, "%s: " f, __func__, ##a)
#else
# define XEN_HOST_PCI_LOG(f, a...) (void)0
#endif
/*
* from linux/ioport.h
* IO resources have these defined flags.
*/
#define IORESOURCE_BITS 0x000000ff /* Bus-specific bits */
#define IORESOURCE_TYPE_BITS 0x00000f00 /* Resource type */
#define IORESOURCE_IO 0x00000100
#define IORESOURCE_MEM 0x00000200
#define IORESOURCE_PREFETCH 0x00001000 /* No side effects */
#define IORESOURCE_MEM_64 0x00100000
static int xen_host_pci_sysfs_path(const XenHostPCIDevice *d,
const char *name, char *buf, ssize_t size)
{
int rc;
rc = snprintf(buf, size, "/sys/bus/pci/devices/%04x:%02x:%02x.%d/%s",
d->domain, d->bus, d->dev, d->func, name);
if (rc >= size || rc < 0) {
/* The ouput is truncated or an other error is encountered */
return -ENODEV;
}
return 0;
}
/* This size should be enough to read the first 7 lines of a ressource file */
#define XEN_HOST_PCI_RESSOURCE_BUFFER_SIZE 400
static int xen_host_pci_get_resource(XenHostPCIDevice *d)
{
int i, rc, fd;
char path[PATH_MAX];
char buf[XEN_HOST_PCI_RESSOURCE_BUFFER_SIZE];
unsigned long long start, end, flags, size;
char *endptr, *s;
uint8_t type;
rc = xen_host_pci_sysfs_path(d, "resource", path, sizeof (path));
if (rc) {
return rc;
}
fd = open(path, O_RDONLY);
if (fd == -1) {
XEN_HOST_PCI_LOG("Error: Can't open %s: %s\n", path, strerror(errno));
return -errno;
}
do {
rc = read(fd, &buf, sizeof (buf) - 1);
if (rc < 0 && errno != EINTR) {
rc = -errno;
goto out;
}
} while (rc < 0);
buf[rc] = 0;
rc = 0;
s = buf;
for (i = 0; i < PCI_NUM_REGIONS; i++) {
type = 0;
start = strtoll(s, &endptr, 16);
if (*endptr != ' ' || s == endptr) {
break;
}
s = endptr + 1;
end = strtoll(s, &endptr, 16);
if (*endptr != ' ' || s == endptr) {
break;
}
s = endptr + 1;
flags = strtoll(s, &endptr, 16);
if (*endptr != '\n' || s == endptr) {
break;
}
s = endptr + 1;
if (start) {
size = end - start + 1;
} else {
size = 0;
}
if (flags & IORESOURCE_IO) {
type |= XEN_HOST_PCI_REGION_TYPE_IO;
}
if (flags & IORESOURCE_MEM) {
type |= XEN_HOST_PCI_REGION_TYPE_MEM;
}
if (flags & IORESOURCE_PREFETCH) {
type |= XEN_HOST_PCI_REGION_TYPE_PREFETCH;
}
if (flags & IORESOURCE_MEM_64) {
type |= XEN_HOST_PCI_REGION_TYPE_MEM_64;
}
if (i < PCI_ROM_SLOT) {
d->io_regions[i].base_addr = start;
d->io_regions[i].size = size;
d->io_regions[i].type = type;
d->io_regions[i].bus_flags = flags & IORESOURCE_BITS;
} else {
d->rom.base_addr = start;
d->rom.size = size;
d->rom.type = type;
d->rom.bus_flags = flags & IORESOURCE_BITS;
}
}
if (i != PCI_NUM_REGIONS) {
/* Invalid format or input to short */
rc = -ENODEV;
}
out:
close(fd);
return rc;
}
/* This size should be enough to read a long from a file */
#define XEN_HOST_PCI_GET_VALUE_BUFFER_SIZE 22
static int xen_host_pci_get_value(XenHostPCIDevice *d, const char *name,
unsigned int *pvalue, int base)
{
char path[PATH_MAX];
char buf[XEN_HOST_PCI_GET_VALUE_BUFFER_SIZE];
int fd, rc;
unsigned long value;
char *endptr;
rc = xen_host_pci_sysfs_path(d, name, path, sizeof (path));
if (rc) {
return rc;
}
fd = open(path, O_RDONLY);
if (fd == -1) {
XEN_HOST_PCI_LOG("Error: Can't open %s: %s\n", path, strerror(errno));
return -errno;
}
do {
rc = read(fd, &buf, sizeof (buf) - 1);
if (rc < 0 && errno != EINTR) {
rc = -errno;
goto out;
}
} while (rc < 0);
buf[rc] = 0;
value = strtol(buf, &endptr, base);
if (endptr == buf || *endptr != '\n') {
rc = -1;
} else if ((value == LONG_MIN || value == LONG_MAX) && errno == ERANGE) {
rc = -errno;
} else {
rc = 0;
*pvalue = value;
}
out:
close(fd);
return rc;
}
static inline int xen_host_pci_get_hex_value(XenHostPCIDevice *d,
const char *name,
unsigned int *pvalue)
{
return xen_host_pci_get_value(d, name, pvalue, 16);
}
static inline int xen_host_pci_get_dec_value(XenHostPCIDevice *d,
const char *name,
unsigned int *pvalue)
{
return xen_host_pci_get_value(d, name, pvalue, 10);
}
static bool xen_host_pci_dev_is_virtfn(XenHostPCIDevice *d)
{
char path[PATH_MAX];
struct stat buf;
if (xen_host_pci_sysfs_path(d, "physfn", path, sizeof (path))) {
return false;
}
return !stat(path, &buf);
}
static int xen_host_pci_config_open(XenHostPCIDevice *d)
{
char path[PATH_MAX];
int rc;
rc = xen_host_pci_sysfs_path(d, "config", path, sizeof (path));
if (rc) {
return rc;
}
d->config_fd = open(path, O_RDWR);
if (d->config_fd < 0) {
return -errno;
}
return 0;
}
static int xen_host_pci_config_read(XenHostPCIDevice *d,
int pos, void *buf, int len)
{
int rc;
do {
rc = pread(d->config_fd, buf, len, pos);
} while (rc < 0 && (errno == EINTR || errno == EAGAIN));
if (rc != len) {
return -errno;
}
return 0;
}
static int xen_host_pci_config_write(XenHostPCIDevice *d,
int pos, const void *buf, int len)
{
int rc;
do {
rc = pwrite(d->config_fd, buf, len, pos);
} while (rc < 0 && (errno == EINTR || errno == EAGAIN));
if (rc != len) {
return -errno;
}
return 0;
}
int xen_host_pci_get_byte(XenHostPCIDevice *d, int pos, uint8_t *p)
{
uint8_t buf;
int rc = xen_host_pci_config_read(d, pos, &buf, 1);
if (!rc) {
*p = buf;
}
return rc;
}
int xen_host_pci_get_word(XenHostPCIDevice *d, int pos, uint16_t *p)
{
uint16_t buf;
int rc = xen_host_pci_config_read(d, pos, &buf, 2);
if (!rc) {
*p = le16_to_cpu(buf);
}
return rc;
}
int xen_host_pci_get_long(XenHostPCIDevice *d, int pos, uint32_t *p)
{
uint32_t buf;
int rc = xen_host_pci_config_read(d, pos, &buf, 4);
if (!rc) {
*p = le32_to_cpu(buf);
}
return rc;
}
int xen_host_pci_get_block(XenHostPCIDevice *d, int pos, uint8_t *buf, int len)
{
return xen_host_pci_config_read(d, pos, buf, len);
}
int xen_host_pci_set_byte(XenHostPCIDevice *d, int pos, uint8_t data)
{
return xen_host_pci_config_write(d, pos, &data, 1);
}
int xen_host_pci_set_word(XenHostPCIDevice *d, int pos, uint16_t data)
{
data = cpu_to_le16(data);
return xen_host_pci_config_write(d, pos, &data, 2);
}
int xen_host_pci_set_long(XenHostPCIDevice *d, int pos, uint32_t data)
{
data = cpu_to_le32(data);
return xen_host_pci_config_write(d, pos, &data, 4);
}
int xen_host_pci_set_block(XenHostPCIDevice *d, int pos, uint8_t *buf, int len)
{
return xen_host_pci_config_write(d, pos, buf, len);
}
int xen_host_pci_find_ext_cap_offset(XenHostPCIDevice *d, uint32_t cap)
{
uint32_t header = 0;
int max_cap = XEN_HOST_PCI_MAX_EXT_CAP;
int pos = PCI_CONFIG_SPACE_SIZE;
do {
if (xen_host_pci_get_long(d, pos, &header)) {
break;
}
/*
* If we have no capabilities, this is indicated by cap ID,
* cap version and next pointer all being 0.
*/
if (header == 0) {
break;
}
if (PCI_EXT_CAP_ID(header) == cap) {
return pos;
}
pos = PCI_EXT_CAP_NEXT(header);
if (pos < PCI_CONFIG_SPACE_SIZE) {
break;
}
max_cap--;
} while (max_cap > 0);
return -1;
}
int xen_host_pci_device_get(XenHostPCIDevice *d, uint16_t domain,
uint8_t bus, uint8_t dev, uint8_t func)
{
unsigned int v;
int rc = 0;
d->config_fd = -1;
d->domain = domain;
d->bus = bus;
d->dev = dev;
d->func = func;
rc = xen_host_pci_config_open(d);
if (rc) {
goto error;
}
rc = xen_host_pci_get_resource(d);
if (rc) {
goto error;
}
rc = xen_host_pci_get_hex_value(d, "vendor", &v);
if (rc) {
goto error;
}
d->vendor_id = v;
rc = xen_host_pci_get_hex_value(d, "device", &v);
if (rc) {
goto error;
}
d->device_id = v;
rc = xen_host_pci_get_dec_value(d, "irq", &v);
if (rc) {
goto error;
}
d->irq = v;
d->is_virtfn = xen_host_pci_dev_is_virtfn(d);
return 0;
error:
if (d->config_fd >= 0) {
close(d->config_fd);
d->config_fd = -1;
}
return rc;
}
void xen_host_pci_device_put(XenHostPCIDevice *d)
{
if (d->config_fd >= 0) {
close(d->config_fd);
d->config_fd = -1;
}
}
hw/xen-host-pci-device.h 0 → 100644
浏览文件 @ 7a542b67
#ifndef XEN_HOST_PCI_DEVICE_H
#define XEN_HOST_PCI_DEVICE_H
#include "pci.h"
enum {
XEN_HOST_PCI_REGION_TYPE_IO = 1 << 1,
XEN_HOST_PCI_REGION_TYPE_MEM = 1 << 2,
XEN_HOST_PCI_REGION_TYPE_PREFETCH = 1 << 3,
XEN_HOST_PCI_REGION_TYPE_MEM_64 = 1 << 4,
};
typedef struct XenHostPCIIORegion {
pcibus_t base_addr;
pcibus_t size;
uint8_t type;
uint8_t bus_flags; /* Bus-specific bits */
} XenHostPCIIORegion;
typedef struct XenHostPCIDevice {
uint16_t domain;
uint8_t bus;
uint8_t dev;
uint8_t func;
uint16_t vendor_id;
uint16_t device_id;
int irq;
XenHostPCIIORegion io_regions[PCI_NUM_REGIONS - 1];
XenHostPCIIORegion rom;
bool is_virtfn;
int config_fd;
} XenHostPCIDevice;
int xen_host_pci_device_get(XenHostPCIDevice *d, uint16_t domain,
uint8_t bus, uint8_t dev, uint8_t func);
void xen_host_pci_device_put(XenHostPCIDevice *pci_dev);
int xen_host_pci_get_byte(XenHostPCIDevice *d, int pos, uint8_t *p);
int xen_host_pci_get_word(XenHostPCIDevice *d, int pos, uint16_t *p);
int xen_host_pci_get_long(XenHostPCIDevice *d, int pos, uint32_t *p);
int xen_host_pci_get_block(XenHostPCIDevice *d, int pos, uint8_t *buf,
int len);
int xen_host_pci_set_byte(XenHostPCIDevice *d, int pos, uint8_t data);
int xen_host_pci_set_word(XenHostPCIDevice *d, int pos, uint16_t data);
int xen_host_pci_set_long(XenHostPCIDevice *d, int pos, uint32_t data);
int xen_host_pci_set_block(XenHostPCIDevice *d, int pos, uint8_t *buf,
int len);
int xen_host_pci_find_ext_cap_offset(XenHostPCIDevice *s, uint32_t cap);
#endif /* !XEN_HOST_PCI_DEVICE_H_ */
hw/xen_common.h
浏览文件 @ 7a542b67
......@@ -150,4 +150,7 @@ static inline int xen_xc_hvm_inject_msi(XenXC xen_xc, domid_t dom,
void destroy_hvm_domain(bool reboot);
/* shutdown/destroy current domain because of an error */
void xen_shutdown_fatal_error(const char *fmt, ...) GCC_FMT_ATTR(1, 2);
#endif /* QEMU_HW_XEN_COMMON_H */
hw/xen_platform.c
浏览文件 @ 7a542b67
......@@ -83,7 +83,7 @@ static void log_writeb(PCIXenPlatformState *s, char val)
#define UNPLUG_ALL_NICS 2
#define UNPLUG_AUX_IDE_DISKS 4
static void unplug_nic(PCIBus *b, PCIDevice *d)
static void unplug_nic(PCIBus *b, PCIDevice *d, void *o)
{
if (pci_get_word(d->config + PCI_CLASS_DEVICE) ==
PCI_CLASS_NETWORK_ETHERNET) {
......@@ -96,10 +96,10 @@ static void unplug_nic(PCIBus *b, PCIDevice *d)
static void pci_unplug_nics(PCIBus *bus)
{
pci_for_each_device(bus, 0, unplug_nic);
pci_for_each_device(bus, 0, unplug_nic, NULL);
}
static void unplug_disks(PCIBus *b, PCIDevice *d)
static void unplug_disks(PCIBus *b, PCIDevice *d, void *o)
{
if (pci_get_word(d->config + PCI_CLASS_DEVICE) ==
PCI_CLASS_STORAGE_IDE) {
......@@ -109,7 +109,7 @@ static void unplug_disks(PCIBus *b, PCIDevice *d)
static void pci_unplug_disks(PCIBus *bus)
{
pci_for_each_device(bus, 0, unplug_disks);
pci_for_each_device(bus, 0, unplug_disks, NULL);
}
static void platform_fixed_ioport_writew(void *opaque, uint32_t addr, uint32_t val)
......
hw/xen_pt.c 0 → 100644
浏览文件 @ 7a542b67
/*
* Copyright (c) 2007, Neocleus Corporation.
* Copyright (c) 2007, Intel Corporation.
*
* This work is licensed under the terms of the GNU GPL, version 2. See
* the COPYING file in the top-level directory.
*
* Alex Novik <alex@neocleus.com>
* Allen Kay <allen.m.kay@intel.com>
* Guy Zana <guy@neocleus.com>
*
* This file implements direct PCI assignment to a HVM guest
*/
/*
* Interrupt Disable policy:
*
* INTx interrupt:
* Initialize(register_real_device)
* Map INTx(xc_physdev_map_pirq):
* <fail>
* - Set real Interrupt Disable bit to '1'.
* - Set machine_irq and assigned_device->machine_irq to '0'.
* * Don't bind INTx.
*
* Bind INTx(xc_domain_bind_pt_pci_irq):
* <fail>
* - Set real Interrupt Disable bit to '1'.
* - Unmap INTx.
* - Decrement xen_pt_mapped_machine_irq[machine_irq]
* - Set assigned_device->machine_irq to '0'.
*
* Write to Interrupt Disable bit by guest software(xen_pt_cmd_reg_write)
* Write '0'
* - Set real bit to '0' if assigned_device->machine_irq isn't '0'.
*
* Write '1'
* - Set real bit to '1'.
*
* MSI interrupt:
* Initialize MSI register(xen_pt_msi_setup, xen_pt_msi_update)
* Bind MSI(xc_domain_update_msi_irq)
* <fail>
* - Unmap MSI.
* - Set dev->msi->pirq to '-1'.
*
* MSI-X interrupt:
* Initialize MSI-X register(xen_pt_msix_update_one)
* Bind MSI-X(xc_domain_update_msi_irq)
* <fail>
* - Unmap MSI-X.
* - Set entry->pirq to '-1'.
*/
#include <sys/ioctl.h>
#include "pci.h"
#include "xen.h"
#include "xen_backend.h"
#include "xen_pt.h"
#include "range.h"
#define XEN_PT_NR_IRQS (256)
static uint8_t xen_pt_mapped_machine_irq[XEN_PT_NR_IRQS] = {0};
void xen_pt_log(const PCIDevice *d, const char *f, ...)
{
va_list ap;
va_start(ap, f);
if (d) {
fprintf(stderr, "[%02x:%02x.%d] ", pci_bus_num(d->bus),
PCI_SLOT(d->devfn), PCI_FUNC(d->devfn));
}
vfprintf(stderr, f, ap);
va_end(ap);
}
/* Config Space */
static int xen_pt_pci_config_access_check(PCIDevice *d, uint32_t addr, int len)
{
/* check offset range */
if (addr >= 0xFF) {
XEN_PT_ERR(d, "Failed to access register with offset exceeding 0xFF. "
"(addr: 0x%02x, len: %d)\n", addr, len);
return -1;
}
/* check read size */
if ((len != 1) && (len != 2) && (len != 4)) {
XEN_PT_ERR(d, "Failed to access register with invalid access length. "
"(addr: 0x%02x, len: %d)\n", addr, len);
return -1;
}
/* check offset alignment */
if (addr & (len - 1)) {
XEN_PT_ERR(d, "Failed to access register with invalid access size "
"alignment. (addr: 0x%02x, len: %d)\n", addr, len);
return -1;
}
return 0;
}
int xen_pt_bar_offset_to_index(uint32_t offset)
{
int index = 0;
/* check Exp ROM BAR */
if (offset == PCI_ROM_ADDRESS) {
return PCI_ROM_SLOT;
}
/* calculate BAR index */
index = (offset - PCI_BASE_ADDRESS_0) >> 2;
if (index >= PCI_NUM_REGIONS) {
return -1;
}
return index;
}
static uint32_t xen_pt_pci_read_config(PCIDevice *d, uint32_t addr, int len)
{
XenPCIPassthroughState *s = DO_UPCAST(XenPCIPassthroughState, dev, d);
uint32_t val = 0;
XenPTRegGroup *reg_grp_entry = NULL;
XenPTReg *reg_entry = NULL;
int rc = 0;
int emul_len = 0;
uint32_t find_addr = addr;
if (xen_pt_pci_config_access_check(d, addr, len)) {
goto exit;
}
/* find register group entry */
reg_grp_entry = xen_pt_find_reg_grp(s, addr);
if (reg_grp_entry) {
/* check 0-Hardwired register group */
if (reg_grp_entry->reg_grp->grp_type == XEN_PT_GRP_TYPE_HARDWIRED) {
/* no need to emulate, just return 0 */
val = 0;
goto exit;
}
}
/* read I/O device register value */
rc = xen_host_pci_get_block(&s->real_device, addr, (uint8_t *)&val, len);
if (rc < 0) {
XEN_PT_ERR(d, "pci_read_block failed. return value: %d.\n", rc);
memset(&val, 0xff, len);
}
/* just return the I/O device register value for
* passthrough type register group */
if (reg_grp_entry == NULL) {
goto exit;
}
/* adjust the read value to appropriate CFC-CFF window */
val <<= (addr & 3) << 3;
emul_len = len;
/* loop around the guest requested size */
while (emul_len > 0) {
/* find register entry to be emulated */
reg_entry = xen_pt_find_reg(reg_grp_entry, find_addr);
if (reg_entry) {
XenPTRegInfo *reg = reg_entry->reg;
uint32_t real_offset = reg_grp_entry->base_offset + reg->offset;
uint32_t valid_mask = 0xFFFFFFFF >> ((4 - emul_len) << 3);
uint8_t *ptr_val = NULL;
valid_mask <<= (find_addr - real_offset) << 3;
ptr_val = (uint8_t *)&val + (real_offset & 3);
/* do emulation based on register size */
switch (reg->size) {
case 1:
if (reg->u.b.read) {
rc = reg->u.b.read(s, reg_entry, ptr_val, valid_mask);
}
break;
case 2:
if (reg->u.w.read) {
rc = reg->u.w.read(s, reg_entry,
(uint16_t *)ptr_val, valid_mask);
}
break;
case 4:
if (reg->u.dw.read) {
rc = reg->u.dw.read(s, reg_entry,
(uint32_t *)ptr_val, valid_mask);
}
break;
}
if (rc < 0) {
xen_shutdown_fatal_error("Internal error: Invalid read "
"emulation. (%s, rc: %d)\n",
__func__, rc);
return 0;
}
/* calculate next address to find */
emul_len -= reg->size;
if (emul_len > 0) {
find_addr = real_offset + reg->size;
}
} else {
/* nothing to do with passthrough type register,
* continue to find next byte */
emul_len--;
find_addr++;
}
}
/* need to shift back before returning them to pci bus emulator */
val >>= ((addr & 3) << 3);
exit:
XEN_PT_LOG_CONFIG(d, addr, val, len);
return val;
}
static void xen_pt_pci_write_config(PCIDevice *d, uint32_t addr,
uint32_t val, int len)
{
XenPCIPassthroughState *s = DO_UPCAST(XenPCIPassthroughState, dev, d);
int index = 0;
XenPTRegGroup *reg_grp_entry = NULL;
int rc = 0;
uint32_t read_val = 0;
int emul_len = 0;
XenPTReg *reg_entry = NULL;
uint32_t find_addr = addr;
XenPTRegInfo *reg = NULL;
if (xen_pt_pci_config_access_check(d, addr, len)) {
return;
}
XEN_PT_LOG_CONFIG(d, addr, val, len);
/* check unused BAR register */
index = xen_pt_bar_offset_to_index(addr);
if ((index >= 0) && (val > 0 && val < XEN_PT_BAR_ALLF) &&
(s->bases[index].bar_flag == XEN_PT_BAR_FLAG_UNUSED)) {
XEN_PT_WARN(d, "Guest attempt to set address to unused Base Address "
"Register. (addr: 0x%02x, len: %d)\n", addr, len);
}
/* find register group entry */
reg_grp_entry = xen_pt_find_reg_grp(s, addr);
if (reg_grp_entry) {
/* check 0-Hardwired register group */
if (reg_grp_entry->reg_grp->grp_type == XEN_PT_GRP_TYPE_HARDWIRED) {
/* ignore silently */
XEN_PT_WARN(d, "Access to 0-Hardwired register. "
"(addr: 0x%02x, len: %d)\n", addr, len);
return;
}
}
rc = xen_host_pci_get_block(&s->real_device, addr,
(uint8_t *)&read_val, len);
if (rc < 0) {
XEN_PT_ERR(d, "pci_read_block failed. return value: %d.\n", rc);
memset(&read_val, 0xff, len);
}
/* pass directly to the real device for passthrough type register group */
if (reg_grp_entry == NULL) {
goto out;
}
memory_region_transaction_begin();
pci_default_write_config(d, addr, val, len);
/* adjust the read and write value to appropriate CFC-CFF window */
read_val <<= (addr & 3) << 3;
val <<= (addr & 3) << 3;
emul_len = len;
/* loop around the guest requested size */
while (emul_len > 0) {
/* find register entry to be emulated */
reg_entry = xen_pt_find_reg(reg_grp_entry, find_addr);
if (reg_entry) {
reg = reg_entry->reg;
uint32_t real_offset = reg_grp_entry->base_offset + reg->offset;
uint32_t valid_mask = 0xFFFFFFFF >> ((4 - emul_len) << 3);
uint8_t *ptr_val = NULL;
valid_mask <<= (find_addr - real_offset) << 3;
ptr_val = (uint8_t *)&val + (real_offset & 3);
/* do emulation based on register size */
switch (reg->size) {
case 1:
if (reg->u.b.write) {
rc = reg->u.b.write(s, reg_entry, ptr_val,
read_val >> ((real_offset & 3) << 3),
valid_mask);
}
break;
case 2:
if (reg->u.w.write) {
rc = reg->u.w.write(s, reg_entry, (uint16_t *)ptr_val,
(read_val >> ((real_offset & 3) << 3)),
valid_mask);
}
break;
case 4:
if (reg->u.dw.write) {
rc = reg->u.dw.write(s, reg_entry, (uint32_t *)ptr_val,
(read_val >> ((real_offset & 3) << 3)),
valid_mask);
}
break;
}
if (rc < 0) {
xen_shutdown_fatal_error("Internal error: Invalid write"
" emulation. (%s, rc: %d)\n",
__func__, rc);
return;
}
/* calculate next address to find */
emul_len -= reg->size;
if (emul_len > 0) {
find_addr = real_offset + reg->size;
}
} else {
/* nothing to do with passthrough type register,
* continue to find next byte */
emul_len--;
find_addr++;
}
}
/* need to shift back before passing them to xen_host_pci_device */
val >>= (addr & 3) << 3;
memory_region_transaction_commit();
out:
if (!(reg && reg->no_wb)) {
/* unknown regs are passed through */
rc = xen_host_pci_set_block(&s->real_device, addr,
(uint8_t *)&val, len);
if (rc < 0) {
XEN_PT_ERR(d, "pci_write_block failed. return value: %d.\n", rc);
}
}
}
/* register regions */
static uint64_t xen_pt_bar_read(void *o, target_phys_addr_t addr,
unsigned size)
{
PCIDevice *d = o;
/* if this function is called, that probably means that there is a
* misconfiguration of the IOMMU. */
XEN_PT_ERR(d, "Should not read BAR through QEMU. @0x"TARGET_FMT_plx"\n",
addr);
return 0;
}
static void xen_pt_bar_write(void *o, target_phys_addr_t addr, uint64_t val,
unsigned size)
{
PCIDevice *d = o;
/* Same comment as xen_pt_bar_read function */
XEN_PT_ERR(d, "Should not write BAR through QEMU. @0x"TARGET_FMT_plx"\n",
addr);
}
static const MemoryRegionOps ops = {
.endianness = DEVICE_NATIVE_ENDIAN,
.read = xen_pt_bar_read,
.write = xen_pt_bar_write,
};
static int xen_pt_register_regions(XenPCIPassthroughState *s)
{
int i = 0;
XenHostPCIDevice *d = &s->real_device;
/* Register PIO/MMIO BARs */
for (i = 0; i < PCI_ROM_SLOT; i++) {
XenHostPCIIORegion *r = &d->io_regions[i];
uint8_t type;
if (r->base_addr == 0 || r->size == 0) {
continue;
}
s->bases[i].access.u = r->base_addr;
if (r->type & XEN_HOST_PCI_REGION_TYPE_IO) {
type = PCI_BASE_ADDRESS_SPACE_IO;
} else {
type = PCI_BASE_ADDRESS_SPACE_MEMORY;
if (r->type & XEN_HOST_PCI_REGION_TYPE_PREFETCH) {
type |= PCI_BASE_ADDRESS_MEM_PREFETCH;
}
}
memory_region_init_io(&s->bar[i], &ops, &s->dev,
"xen-pci-pt-bar", r->size);
pci_register_bar(&s->dev, i, type, &s->bar[i]);
XEN_PT_LOG(&s->dev, "IO region %i registered (size=0x%08"PRIx64
" base_addr=0x%08"PRIx64" type: %#x)\n",
i, r->size, r->base_addr, type);
}
/* Register expansion ROM address */
if (d->rom.base_addr && d->rom.size) {
uint32_t bar_data = 0;
/* Re-set BAR reported by OS, otherwise ROM can't be read. */
if (xen_host_pci_get_long(d, PCI_ROM_ADDRESS, &bar_data)) {
return 0;
}
if ((bar_data & PCI_ROM_ADDRESS_MASK) == 0) {
bar_data |= d->rom.base_addr & PCI_ROM_ADDRESS_MASK;
xen_host_pci_set_long(d, PCI_ROM_ADDRESS, bar_data);
}
s->bases[PCI_ROM_SLOT].access.maddr = d->rom.base_addr;
memory_region_init_rom_device(&s->rom, NULL, NULL,
"xen-pci-pt-rom", d->rom.size);
pci_register_bar(&s->dev, PCI_ROM_SLOT, PCI_BASE_ADDRESS_MEM_PREFETCH,
&s->rom);
XEN_PT_LOG(&s->dev, "Expansion ROM registered (size=0x%08"PRIx64
" base_addr=0x%08"PRIx64")\n",
d->rom.size, d->rom.base_addr);
}
return 0;
}
static void xen_pt_unregister_regions(XenPCIPassthroughState *s)
{
XenHostPCIDevice *d = &s->real_device;
int i;
for (i = 0; i < PCI_NUM_REGIONS - 1; i++) {
XenHostPCIIORegion *r = &d->io_regions[i];
if (r->base_addr == 0 || r->size == 0) {
continue;
}
memory_region_destroy(&s->bar[i]);
}
if (d->rom.base_addr && d->rom.size) {
memory_region_destroy(&s->rom);
}
}
/* region mapping */
static int xen_pt_bar_from_region(XenPCIPassthroughState *s, MemoryRegion *mr)
{
int i = 0;
for (i = 0; i < PCI_NUM_REGIONS - 1; i++) {
if (mr == &s->bar[i]) {
return i;
}
}
if (mr == &s->rom) {
return PCI_ROM_SLOT;
}
return -1;
}
/*
* This function checks if an io_region overlaps an io_region from another
* device. The io_region to check is provided with (addr, size and type)
* A callback can be provided and will be called for every region that is
* overlapped.
* The return value indicates if the region is overlappsed */
struct CheckBarArgs {
XenPCIPassthroughState *s;
pcibus_t addr;
pcibus_t size;
uint8_t type;
bool rc;
};
static void xen_pt_check_bar_overlap(PCIBus *bus, PCIDevice *d, void *opaque)
{
struct CheckBarArgs *arg = opaque;
XenPCIPassthroughState *s = arg->s;
uint8_t type = arg->type;
int i;
if (d->devfn == s->dev.devfn) {
return;
}
/* xxx: This ignores bridges. */
for (i = 0; i < PCI_NUM_REGIONS; i++) {
const PCIIORegion *r = &d->io_regions[i];
if (!r->size) {
continue;
}
if ((type & PCI_BASE_ADDRESS_SPACE_IO)
!= (r->type & PCI_BASE_ADDRESS_SPACE_IO)) {
continue;
}
if (ranges_overlap(arg->addr, arg->size, r->addr, r->size)) {
XEN_PT_WARN(&s->dev,
"Overlapped to device [%02x:%02x.%d] Region: %i"
" (addr: %#"FMT_PCIBUS", len: %#"FMT_PCIBUS")\n",
pci_bus_num(bus), PCI_SLOT(d->devfn),
PCI_FUNC(d->devfn), i, r->addr, r->size);
arg->rc = true;
}
}
}
static void xen_pt_region_update(XenPCIPassthroughState *s,
MemoryRegionSection *sec, bool adding)
{
PCIDevice *d = &s->dev;
MemoryRegion *mr = sec->mr;
int bar = -1;
int rc;
int op = adding ? DPCI_ADD_MAPPING : DPCI_REMOVE_MAPPING;
struct CheckBarArgs args = {
.s = s,
.addr = sec->offset_within_address_space,
.size = sec->size,
.rc = false,
};
bar = xen_pt_bar_from_region(s, mr);
if (bar == -1 && (!s->msix || &s->msix->mmio != mr)) {
return;
}
if (s->msix && &s->msix->mmio == mr) {
if (adding) {
s->msix->mmio_base_addr = sec->offset_within_address_space;
rc = xen_pt_msix_update_remap(s, s->msix->bar_index);
}
return;
}
args.type = d->io_regions[bar].type;
pci_for_each_device(d->bus, pci_bus_num(d->bus),
xen_pt_check_bar_overlap, &args);
if (args.rc) {
XEN_PT_WARN(d, "Region: %d (addr: %#"FMT_PCIBUS
", len: %#"FMT_PCIBUS") is overlapped.\n",
bar, sec->offset_within_address_space, sec->size);
}
if (d->io_regions[bar].type & PCI_BASE_ADDRESS_SPACE_IO) {
uint32_t guest_port = sec->offset_within_address_space;
uint32_t machine_port = s->bases[bar].access.pio_base;
uint32_t size = sec->size;
rc = xc_domain_ioport_mapping(xen_xc, xen_domid,
guest_port, machine_port, size,
op);
if (rc) {
XEN_PT_ERR(d, "%s ioport mapping failed! (rc: %i)\n",
adding ? "create new" : "remove old", rc);
}
} else {
pcibus_t guest_addr = sec->offset_within_address_space;
pcibus_t machine_addr = s->bases[bar].access.maddr
+ sec->offset_within_region;
pcibus_t size = sec->size;
rc = xc_domain_memory_mapping(xen_xc, xen_domid,
XEN_PFN(guest_addr + XC_PAGE_SIZE - 1),
XEN_PFN(machine_addr + XC_PAGE_SIZE - 1),
XEN_PFN(size + XC_PAGE_SIZE - 1),
op);
if (rc) {
XEN_PT_ERR(d, "%s mem mapping failed! (rc: %i)\n",
adding ? "create new" : "remove old", rc);
}
}
}
static void xen_pt_begin(MemoryListener *l)
{
}
static void xen_pt_commit(MemoryListener *l)
{
}
static void xen_pt_region_add(MemoryListener *l, MemoryRegionSection *sec)
{
XenPCIPassthroughState *s = container_of(l, XenPCIPassthroughState,
memory_listener);
xen_pt_region_update(s, sec, true);
}
static void xen_pt_region_del(MemoryListener *l, MemoryRegionSection *sec)
{
XenPCIPassthroughState *s = container_of(l, XenPCIPassthroughState,
memory_listener);
xen_pt_region_update(s, sec, false);
}
static void xen_pt_region_nop(MemoryListener *l, MemoryRegionSection *s)
{
}
static void xen_pt_log_fns(MemoryListener *l, MemoryRegionSection *s)
{
}
static void xen_pt_log_global_fns(MemoryListener *l)
{
}
static void xen_pt_eventfd_fns(MemoryListener *l, MemoryRegionSection *s,
bool match_data, uint64_t data, int fd)
{
}
static const MemoryListener xen_pt_memory_listener = {
.begin = xen_pt_begin,
.commit = xen_pt_commit,
.region_add = xen_pt_region_add,
.region_nop = xen_pt_region_nop,
.region_del = xen_pt_region_del,
.log_start = xen_pt_log_fns,
.log_stop = xen_pt_log_fns,
.log_sync = xen_pt_log_fns,
.log_global_start = xen_pt_log_global_fns,
.log_global_stop = xen_pt_log_global_fns,
.eventfd_add = xen_pt_eventfd_fns,
.eventfd_del = xen_pt_eventfd_fns,
.priority = 10,
};
/* init */
static int xen_pt_initfn(PCIDevice *d)
{
XenPCIPassthroughState *s = DO_UPCAST(XenPCIPassthroughState, dev, d);
int rc = 0;
uint8_t machine_irq = 0;
int pirq = XEN_PT_UNASSIGNED_PIRQ;
/* register real device */
XEN_PT_LOG(d, "Assigning real physical device %02x:%02x.%d"
" to devfn %#x\n",
s->hostaddr.bus, s->hostaddr.slot, s->hostaddr.function,
s->dev.devfn);
rc = xen_host_pci_device_get(&s->real_device,
s->hostaddr.domain, s->hostaddr.bus,
s->hostaddr.slot, s->hostaddr.function);
if (rc) {
XEN_PT_ERR(d, "Failed to \"open\" the real pci device. rc: %i\n", rc);
return -1;
}
s->is_virtfn = s->real_device.is_virtfn;
if (s->is_virtfn) {
XEN_PT_LOG(d, "%04x:%02x:%02x.%d is a SR-IOV Virtual Function\n",
s->real_device.domain, bus, slot, func);
}
/* Initialize virtualized PCI configuration (Extended 256 Bytes) */
if (xen_host_pci_get_block(&s->real_device, 0, d->config,
PCI_CONFIG_SPACE_SIZE) == -1) {
xen_host_pci_device_put(&s->real_device);
return -1;
}
s->memory_listener = xen_pt_memory_listener;
/* Handle real device's MMIO/PIO BARs */
xen_pt_register_regions(s);
/* reinitialize each config register to be emulated */
if (xen_pt_config_init(s)) {
XEN_PT_ERR(d, "PCI Config space initialisation failed.\n");
xen_host_pci_device_put(&s->real_device);
return -1;
}
/* Bind interrupt */
if (!s->dev.config[PCI_INTERRUPT_PIN]) {
XEN_PT_LOG(d, "no pin interrupt\n");
goto out;
}
machine_irq = s->real_device.irq;
rc = xc_physdev_map_pirq(xen_xc, xen_domid, machine_irq, &pirq);
if (rc < 0) {
XEN_PT_ERR(d, "Mapping machine irq %u to pirq %i failed, (rc: %d)\n",
machine_irq, pirq, rc);
/* Disable PCI intx assertion (turn on bit10 of devctl) */
xen_host_pci_set_word(&s->real_device,
PCI_COMMAND,
pci_get_word(s->dev.config + PCI_COMMAND)
| PCI_COMMAND_INTX_DISABLE);
machine_irq = 0;
s->machine_irq = 0;
} else {
machine_irq = pirq;
s->machine_irq = pirq;
xen_pt_mapped_machine_irq[machine_irq]++;
}
/* bind machine_irq to device */
if (machine_irq != 0) {
uint8_t e_intx = xen_pt_pci_intx(s);
rc = xc_domain_bind_pt_pci_irq(xen_xc, xen_domid, machine_irq,
pci_bus_num(d->bus),
PCI_SLOT(d->devfn),
e_intx);
if (rc < 0) {
XEN_PT_ERR(d, "Binding of interrupt %i failed! (rc: %d)\n",
e_intx, rc);
/* Disable PCI intx assertion (turn on bit10 of devctl) */
xen_host_pci_set_word(&s->real_device, PCI_COMMAND,
*(uint16_t *)(&s->dev.config[PCI_COMMAND])
| PCI_COMMAND_INTX_DISABLE);
xen_pt_mapped_machine_irq[machine_irq]--;
if (xen_pt_mapped_machine_irq[machine_irq] == 0) {
if (xc_physdev_unmap_pirq(xen_xc, xen_domid, machine_irq)) {
XEN_PT_ERR(d, "Unmapping of machine interrupt %i failed!"
" (rc: %d)\n", machine_irq, rc);
}
}
s->machine_irq = 0;
}
}
out:
memory_listener_register(&s->memory_listener, NULL);
XEN_PT_LOG(d, "Real physical device %02x:%02x.%d registered successfuly!\n",
bus, slot, func);
return 0;
}
static int xen_pt_unregister_device(PCIDevice *d)
{
XenPCIPassthroughState *s = DO_UPCAST(XenPCIPassthroughState, dev, d);
uint8_t machine_irq = s->machine_irq;
uint8_t intx = xen_pt_pci_intx(s);
int rc;
if (machine_irq) {
rc = xc_domain_unbind_pt_irq(xen_xc, xen_domid, machine_irq,
PT_IRQ_TYPE_PCI,
pci_bus_num(d->bus),
PCI_SLOT(s->dev.devfn),
intx,
0 /* isa_irq */);
if (rc < 0) {
XEN_PT_ERR(d, "unbinding of interrupt INT%c failed."
" (machine irq: %i, rc: %d)"
" But bravely continuing on..\n",
'a' + intx, machine_irq, rc);
}
}
if (s->msi) {
xen_pt_msi_disable(s);
}
if (s->msix) {
xen_pt_msix_disable(s);
}
if (machine_irq) {
xen_pt_mapped_machine_irq[machine_irq]--;
if (xen_pt_mapped_machine_irq[machine_irq] == 0) {
rc = xc_physdev_unmap_pirq(xen_xc, xen_domid, machine_irq);
if (rc < 0) {
XEN_PT_ERR(d, "unmapping of interrupt %i failed. (rc: %d)"
" But bravely continuing on..\n",
machine_irq, rc);
}
}
}
/* delete all emulated config registers */
xen_pt_config_delete(s);
xen_pt_unregister_regions(s);
memory_listener_unregister(&s->memory_listener);
xen_host_pci_device_put(&s->real_device);
return 0;
}
static Property xen_pci_passthrough_properties[] = {
DEFINE_PROP_PCI_HOST_DEVADDR("hostaddr", XenPCIPassthroughState, hostaddr),
DEFINE_PROP_END_OF_LIST(),
};
static void xen_pci_passthrough_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
PCIDeviceClass *k = PCI_DEVICE_CLASS(klass);
k->init = xen_pt_initfn;
k->exit = xen_pt_unregister_device;
k->config_read = xen_pt_pci_read_config;
k->config_write = xen_pt_pci_write_config;
dc->desc = "Assign an host PCI device with Xen";
dc->props = xen_pci_passthrough_properties;
};
static TypeInfo xen_pci_passthrough_info = {
.name = "xen-pci-passthrough",
.parent = TYPE_PCI_DEVICE,
.instance_size = sizeof(XenPCIPassthroughState),
.class_init = xen_pci_passthrough_class_init,
};
static void xen_pci_passthrough_register_types(void)
{
type_register_static(&xen_pci_passthrough_info);
}
type_init(xen_pci_passthrough_register_types)
hw/xen_pt.h 0 → 100644
浏览文件 @ 7a542b67
#ifndef XEN_PT_H
#define XEN_PT_H
#include "qemu-common.h"
#include "xen_common.h"
#include "pci.h"
#include "xen-host-pci-device.h"
void xen_pt_log(const PCIDevice *d, const char *f, ...) GCC_FMT_ATTR(2, 3);
#define XEN_PT_ERR(d, _f, _a...) xen_pt_log(d, "%s: Error: "_f, __func__, ##_a)
#ifdef XEN_PT_LOGGING_ENABLED
# define XEN_PT_LOG(d, _f, _a...) xen_pt_log(d, "%s: " _f, __func__, ##_a)
# define XEN_PT_WARN(d, _f, _a...) \
xen_pt_log(d, "%s: Warning: "_f, __func__, ##_a)
#else
# define XEN_PT_LOG(d, _f, _a...)
# define XEN_PT_WARN(d, _f, _a...)
#endif
#ifdef XEN_PT_DEBUG_PCI_CONFIG_ACCESS
# define XEN_PT_LOG_CONFIG(d, addr, val, len) \
xen_pt_log(d, "%s: address=0x%04x val=0x%08x len=%d\n", \
__func__, addr, val, len)
#else
# define XEN_PT_LOG_CONFIG(d, addr, val, len)
#endif
/* Helper */
#define XEN_PFN(x) ((x) >> XC_PAGE_SHIFT)
typedef struct XenPTRegInfo XenPTRegInfo;
typedef struct XenPTReg XenPTReg;
typedef struct XenPCIPassthroughState XenPCIPassthroughState;
/* function type for config reg */
typedef int (*xen_pt_conf_reg_init)
(XenPCIPassthroughState *, XenPTRegInfo *, uint32_t real_offset,
uint32_t *data);
typedef int (*xen_pt_conf_dword_write)
(XenPCIPassthroughState *, XenPTReg *cfg_entry,
uint32_t *val, uint32_t dev_value, uint32_t valid_mask);
typedef int (*xen_pt_conf_word_write)
(XenPCIPassthroughState *, XenPTReg *cfg_entry,
uint16_t *val, uint16_t dev_value, uint16_t valid_mask);
typedef int (*xen_pt_conf_byte_write)
(XenPCIPassthroughState *, XenPTReg *cfg_entry,
uint8_t *val, uint8_t dev_value, uint8_t valid_mask);
typedef int (*xen_pt_conf_dword_read)
(XenPCIPassthroughState *, XenPTReg *cfg_entry,
uint32_t *val, uint32_t valid_mask);
typedef int (*xen_pt_conf_word_read)
(XenPCIPassthroughState *, XenPTReg *cfg_entry,
uint16_t *val, uint16_t valid_mask);
typedef int (*xen_pt_conf_byte_read)
(XenPCIPassthroughState *, XenPTReg *cfg_entry,
uint8_t *val, uint8_t valid_mask);
#define XEN_PT_BAR_ALLF 0xFFFFFFFF
#define XEN_PT_BAR_UNMAPPED (-1)
#define PCI_CAP_MAX 48
typedef enum {
XEN_PT_GRP_TYPE_HARDWIRED = 0, /* 0 Hardwired reg group */
XEN_PT_GRP_TYPE_EMU, /* emul reg group */
} XenPTRegisterGroupType;
typedef enum {
XEN_PT_BAR_FLAG_MEM = 0, /* Memory type BAR */
XEN_PT_BAR_FLAG_IO, /* I/O type BAR */
XEN_PT_BAR_FLAG_UPPER, /* upper 64bit BAR */
XEN_PT_BAR_FLAG_UNUSED, /* unused BAR */
} XenPTBarFlag;
typedef struct XenPTRegion {
/* BAR flag */
XenPTBarFlag bar_flag;
/* Translation of the emulated address */
union {
uint64_t maddr;
uint64_t pio_base;
uint64_t u;
} access;
} XenPTRegion;
/* XenPTRegInfo declaration
* - only for emulated register (either a part or whole bit).
* - for passthrough register that need special behavior (like interacting with
* other component), set emu_mask to all 0 and specify r/w func properly.
* - do NOT use ALL F for init_val, otherwise the tbl will not be registered.
*/
/* emulated register infomation */
struct XenPTRegInfo {
uint32_t offset;
uint32_t size;
uint32_t init_val;
/* reg read only field mask (ON:RO/ROS, OFF:other) */
uint32_t ro_mask;
/* reg emulate field mask (ON:emu, OFF:passthrough) */
uint32_t emu_mask;
/* no write back allowed */
uint32_t no_wb;
xen_pt_conf_reg_init init;
/* read/write function pointer
* for double_word/word/byte size */
union {
struct {
xen_pt_conf_dword_write write;
xen_pt_conf_dword_read read;
} dw;
struct {
xen_pt_conf_word_write write;
xen_pt_conf_word_read read;
} w;
struct {
xen_pt_conf_byte_write write;
xen_pt_conf_byte_read read;
} b;
} u;
};
/* emulated register management */
struct XenPTReg {
QLIST_ENTRY(XenPTReg) entries;
XenPTRegInfo *reg;
uint32_t data; /* emulated value */
};
typedef struct XenPTRegGroupInfo XenPTRegGroupInfo;
/* emul reg group size initialize method */
typedef int (*xen_pt_reg_size_init_fn)
(XenPCIPassthroughState *, const XenPTRegGroupInfo *,
uint32_t base_offset, uint8_t *size);
/* emulated register group infomation */
struct XenPTRegGroupInfo {
uint8_t grp_id;
XenPTRegisterGroupType grp_type;
uint8_t grp_size;
xen_pt_reg_size_init_fn size_init;
XenPTRegInfo *emu_regs;
};
/* emul register group management table */
typedef struct XenPTRegGroup {
QLIST_ENTRY(XenPTRegGroup) entries;
const XenPTRegGroupInfo *reg_grp;
uint32_t base_offset;
uint8_t size;
QLIST_HEAD(, XenPTReg) reg_tbl_list;
} XenPTRegGroup;
#define XEN_PT_UNASSIGNED_PIRQ (-1)
typedef struct XenPTMSI {
uint16_t flags;
uint32_t addr_lo; /* guest message address */
uint32_t addr_hi; /* guest message upper address */
uint16_t data; /* guest message data */
uint32_t ctrl_offset; /* saved control offset */
int pirq; /* guest pirq corresponding */
bool initialized; /* when guest MSI is initialized */
bool mapped; /* when pirq is mapped */
} XenPTMSI;
typedef struct XenPTMSIXEntry {
int pirq;
uint64_t addr;
uint32_t data;
uint32_t vector_ctrl;
bool updated; /* indicate whether MSI ADDR or DATA is updated */
} XenPTMSIXEntry;
typedef struct XenPTMSIX {
uint32_t ctrl_offset;
bool enabled;
int total_entries;
int bar_index;
uint64_t table_base;
uint32_t table_offset_adjust; /* page align mmap */
uint64_t mmio_base_addr;
MemoryRegion mmio;
void *phys_iomem_base;
XenPTMSIXEntry msix_entry[0];
} XenPTMSIX;
struct XenPCIPassthroughState {
PCIDevice dev;
PCIHostDeviceAddress hostaddr;
bool is_virtfn;
XenHostPCIDevice real_device;
XenPTRegion bases[PCI_NUM_REGIONS]; /* Access regions */
QLIST_HEAD(, XenPTRegGroup) reg_grps;
uint32_t machine_irq;
XenPTMSI *msi;
XenPTMSIX *msix;
MemoryRegion bar[PCI_NUM_REGIONS - 1];
MemoryRegion rom;
MemoryListener memory_listener;
};
int xen_pt_config_init(XenPCIPassthroughState *s);
void xen_pt_config_delete(XenPCIPassthroughState *s);
XenPTRegGroup *xen_pt_find_reg_grp(XenPCIPassthroughState *s, uint32_t address);
XenPTReg *xen_pt_find_reg(XenPTRegGroup *reg_grp, uint32_t address);
int xen_pt_bar_offset_to_index(uint32_t offset);
static inline pcibus_t xen_pt_get_emul_size(XenPTBarFlag flag, pcibus_t r_size)
{
/* align resource size (memory type only) */
if (flag == XEN_PT_BAR_FLAG_MEM) {
return (r_size + XC_PAGE_SIZE - 1) & XC_PAGE_MASK;
} else {
return r_size;
}
}
/* INTx */
/* The PCI Local Bus Specification, Rev. 3.0,
* Section 6.2.4 Miscellaneous Registers, pp 223
* outlines 5 valid values for the interrupt pin (intx).
* 0: For devices (or device functions) that don't use an interrupt in
* 1: INTA#
* 2: INTB#
* 3: INTC#
* 4: INTD#
*
* Xen uses the following 4 values for intx
* 0: INTA#
* 1: INTB#
* 2: INTC#
* 3: INTD#
*
* Observing that these list of values are not the same, xen_pt_pci_read_intx()
* uses the following mapping from hw to xen values.
* This seems to reflect the current usage within Xen.
*
* PCI hardware | Xen | Notes
* ----------------+-----+----------------------------------------------------
* 0 | 0 | No interrupt
* 1 | 0 | INTA#
* 2 | 1 | INTB#
* 3 | 2 | INTC#
* 4 | 3 | INTD#
* any other value | 0 | This should never happen, log error message
*/
static inline uint8_t xen_pt_pci_read_intx(XenPCIPassthroughState *s)
{
uint8_t v = 0;
xen_host_pci_get_byte(&s->real_device, PCI_INTERRUPT_PIN, &v);
return v;
}
static inline uint8_t xen_pt_pci_intx(XenPCIPassthroughState *s)
{
uint8_t r_val = xen_pt_pci_read_intx(s);
XEN_PT_LOG(&s->dev, "intx=%i\n", r_val);
if (r_val < 1 || r_val > 4) {
XEN_PT_LOG(&s->dev, "Interrupt pin read from hardware is out of range:"
" value=%i, acceptable range is 1 - 4\n", r_val);
r_val = 0;
} else {
r_val -= 1;
}
return r_val;
}
/* MSI/MSI-X */
int xen_pt_msi_set_enable(XenPCIPassthroughState *s, bool en);
int xen_pt_msi_setup(XenPCIPassthroughState *s);
int xen_pt_msi_update(XenPCIPassthroughState *d);
void xen_pt_msi_disable(XenPCIPassthroughState *s);
int xen_pt_msix_init(XenPCIPassthroughState *s, uint32_t base);
void xen_pt_msix_delete(XenPCIPassthroughState *s);
int xen_pt_msix_update(XenPCIPassthroughState *s);
int xen_pt_msix_update_remap(XenPCIPassthroughState *s, int bar_index);
void xen_pt_msix_disable(XenPCIPassthroughState *s);
static inline bool xen_pt_has_msix_mapping(XenPCIPassthroughState *s, int bar)
{
return s->msix && s->msix->bar_index == bar;
}
#endif /* !XEN_PT_H */
hw/xen_pt_config_init.c 0 → 100644
浏览文件 @ 7a542b67
/*
* Copyright (c) 2007, Neocleus Corporation.
* Copyright (c) 2007, Intel Corporation.
*
* This work is licensed under the terms of the GNU GPL, version 2. See
* the COPYING file in the top-level directory.
*
* Alex Novik <alex@neocleus.com>
* Allen Kay <allen.m.kay@intel.com>
* Guy Zana <guy@neocleus.com>
*
* This file implements direct PCI assignment to a HVM guest
*/
#include "qemu-timer.h"
#include "xen_backend.h"
#include "xen_pt.h"
#define XEN_PT_MERGE_VALUE(value, data, val_mask) \
(((value) & (val_mask)) | ((data) & ~(val_mask)))
#define XEN_PT_INVALID_REG 0xFFFFFFFF /* invalid register value */
/* prototype */
static int xen_pt_ptr_reg_init(XenPCIPassthroughState *s, XenPTRegInfo *reg,
uint32_t real_offset, uint32_t *data);
/* helper */
/* A return value of 1 means the capability should NOT be exposed to guest. */
static int xen_pt_hide_dev_cap(const XenHostPCIDevice *d, uint8_t grp_id)
{
switch (grp_id) {
case PCI_CAP_ID_EXP:
/* The PCI Express Capability Structure of the VF of Intel 82599 10GbE
* Controller looks trivial, e.g., the PCI Express Capabilities
* Register is 0. We should not try to expose it to guest.
*
* The datasheet is available at
* http://download.intel.com/design/network/datashts/82599_datasheet.pdf
*
* See 'Table 9.7. VF PCIe Configuration Space' of the datasheet, the
* PCI Express Capability Structure of the VF of Intel 82599 10GbE
* Controller looks trivial, e.g., the PCI Express Capabilities
* Register is 0, so the Capability Version is 0 and
* xen_pt_pcie_size_init() would fail.
*/
if (d->vendor_id == PCI_VENDOR_ID_INTEL &&
d->device_id == PCI_DEVICE_ID_INTEL_82599_SFP_VF) {
return 1;
}
break;
}
return 0;
}
/* find emulate register group entry */
XenPTRegGroup *xen_pt_find_reg_grp(XenPCIPassthroughState *s, uint32_t address)
{
XenPTRegGroup *entry = NULL;
/* find register group entry */
QLIST_FOREACH(entry, &s->reg_grps, entries) {
/* check address */
if ((entry->base_offset <= address)
&& ((entry->base_offset + entry->size) > address)) {
return entry;
}
}
/* group entry not found */
return NULL;
}
/* find emulate register entry */
XenPTReg *xen_pt_find_reg(XenPTRegGroup *reg_grp, uint32_t address)
{
XenPTReg *reg_entry = NULL;
XenPTRegInfo *reg = NULL;
uint32_t real_offset = 0;
/* find register entry */
QLIST_FOREACH(reg_entry, &reg_grp->reg_tbl_list, entries) {
reg = reg_entry->reg;
real_offset = reg_grp->base_offset + reg->offset;
/* check address */
if ((real_offset <= address)
&& ((real_offset + reg->size) > address)) {
return reg_entry;
}
}
return NULL;
}
/****************
* general register functions
*/
/* register initialization function */
static int xen_pt_common_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
*data = reg->init_val;
return 0;
}
/* Read register functions */
static int xen_pt_byte_reg_read(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint8_t *value, uint8_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint8_t valid_emu_mask = 0;
/* emulate byte register */
valid_emu_mask = reg->emu_mask & valid_mask;
*value = XEN_PT_MERGE_VALUE(*value, cfg_entry->data, ~valid_emu_mask);
return 0;
}
static int xen_pt_word_reg_read(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint16_t *value, uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint16_t valid_emu_mask = 0;
/* emulate word register */
valid_emu_mask = reg->emu_mask & valid_mask;
*value = XEN_PT_MERGE_VALUE(*value, cfg_entry->data, ~valid_emu_mask);
return 0;
}
static int xen_pt_long_reg_read(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint32_t *value, uint32_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint32_t valid_emu_mask = 0;
/* emulate long register */
valid_emu_mask = reg->emu_mask & valid_mask;
*value = XEN_PT_MERGE_VALUE(*value, cfg_entry->data, ~valid_emu_mask);
return 0;
}
/* Write register functions */
static int xen_pt_byte_reg_write(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint8_t *val, uint8_t dev_value,
uint8_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint8_t writable_mask = 0;
uint8_t throughable_mask = 0;
/* modify emulate register */
writable_mask = reg->emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* create value for writing to I/O device register */
throughable_mask = ~reg->emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
return 0;
}
static int xen_pt_word_reg_write(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint16_t *val, uint16_t dev_value,
uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint16_t writable_mask = 0;
uint16_t throughable_mask = 0;
/* modify emulate register */
writable_mask = reg->emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* create value for writing to I/O device register */
throughable_mask = ~reg->emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
return 0;
}
static int xen_pt_long_reg_write(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint32_t *val, uint32_t dev_value,
uint32_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint32_t writable_mask = 0;
uint32_t throughable_mask = 0;
/* modify emulate register */
writable_mask = reg->emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* create value for writing to I/O device register */
throughable_mask = ~reg->emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
return 0;
}
/* XenPTRegInfo declaration
* - only for emulated register (either a part or whole bit).
* - for passthrough register that need special behavior (like interacting with
* other component), set emu_mask to all 0 and specify r/w func properly.
* - do NOT use ALL F for init_val, otherwise the tbl will not be registered.
*/
/********************
* Header Type0
*/
static int xen_pt_vendor_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
*data = s->real_device.vendor_id;
return 0;
}
static int xen_pt_device_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
*data = s->real_device.device_id;
return 0;
}
static int xen_pt_status_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
XenPTRegGroup *reg_grp_entry = NULL;
XenPTReg *reg_entry = NULL;
uint32_t reg_field = 0;
/* find Header register group */
reg_grp_entry = xen_pt_find_reg_grp(s, PCI_CAPABILITY_LIST);
if (reg_grp_entry) {
/* find Capabilities Pointer register */
reg_entry = xen_pt_find_reg(reg_grp_entry, PCI_CAPABILITY_LIST);
if (reg_entry) {
/* check Capabilities Pointer register */
if (reg_entry->data) {
reg_field |= PCI_STATUS_CAP_LIST;
} else {
reg_field &= ~PCI_STATUS_CAP_LIST;
}
} else {
xen_shutdown_fatal_error("Internal error: Couldn't find XenPTReg*"
" for Capabilities Pointer register."
" (%s)\n", __func__);
return -1;
}
} else {
xen_shutdown_fatal_error("Internal error: Couldn't find XenPTRegGroup"
" for Header. (%s)\n", __func__);
return -1;
}
*data = reg_field;
return 0;
}
static int xen_pt_header_type_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
/* read PCI_HEADER_TYPE */
*data = reg->init_val | 0x80;
return 0;
}
/* initialize Interrupt Pin register */
static int xen_pt_irqpin_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
*data = xen_pt_pci_read_intx(s);
return 0;
}
/* Command register */
static int xen_pt_cmd_reg_read(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint16_t *value, uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint16_t valid_emu_mask = 0;
uint16_t emu_mask = reg->emu_mask;
if (s->is_virtfn) {
emu_mask |= PCI_COMMAND_MEMORY;
}
/* emulate word register */
valid_emu_mask = emu_mask & valid_mask;
*value = XEN_PT_MERGE_VALUE(*value, cfg_entry->data, ~valid_emu_mask);
return 0;
}
static int xen_pt_cmd_reg_write(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint16_t *val, uint16_t dev_value,
uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint16_t writable_mask = 0;
uint16_t throughable_mask = 0;
uint16_t emu_mask = reg->emu_mask;
if (s->is_virtfn) {
emu_mask |= PCI_COMMAND_MEMORY;
}
/* modify emulate register */
writable_mask = ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* create value for writing to I/O device register */
throughable_mask = ~emu_mask & valid_mask;
if (*val & PCI_COMMAND_INTX_DISABLE) {
throughable_mask |= PCI_COMMAND_INTX_DISABLE;
} else {
if (s->machine_irq) {
throughable_mask |= PCI_COMMAND_INTX_DISABLE;
}
}
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
return 0;
}
/* BAR */
#define XEN_PT_BAR_MEM_RO_MASK 0x0000000F /* BAR ReadOnly mask(Memory) */
#define XEN_PT_BAR_MEM_EMU_MASK 0xFFFFFFF0 /* BAR emul mask(Memory) */
#define XEN_PT_BAR_IO_RO_MASK 0x00000003 /* BAR ReadOnly mask(I/O) */
#define XEN_PT_BAR_IO_EMU_MASK 0xFFFFFFFC /* BAR emul mask(I/O) */
static XenPTBarFlag xen_pt_bar_reg_parse(XenPCIPassthroughState *s,
XenPTRegInfo *reg)
{
PCIDevice *d = &s->dev;
XenPTRegion *region = NULL;
PCIIORegion *r;
int index = 0;
/* check 64bit BAR */
index = xen_pt_bar_offset_to_index(reg->offset);
if ((0 < index) && (index < PCI_ROM_SLOT)) {
int type = s->real_device.io_regions[index - 1].type;
if ((type & XEN_HOST_PCI_REGION_TYPE_MEM)
&& (type & XEN_HOST_PCI_REGION_TYPE_MEM_64)) {
region = &s->bases[index - 1];
if (region->bar_flag != XEN_PT_BAR_FLAG_UPPER) {
return XEN_PT_BAR_FLAG_UPPER;
}
}
}
/* check unused BAR */
r = &d->io_regions[index];
if (r->size == 0) {
return XEN_PT_BAR_FLAG_UNUSED;
}
/* for ExpROM BAR */
if (index == PCI_ROM_SLOT) {
return XEN_PT_BAR_FLAG_MEM;
}
/* check BAR I/O indicator */
if (s->real_device.io_regions[index].type & XEN_HOST_PCI_REGION_TYPE_IO) {
return XEN_PT_BAR_FLAG_IO;
} else {
return XEN_PT_BAR_FLAG_MEM;
}
}
static inline uint32_t base_address_with_flags(XenHostPCIIORegion *hr)
{
if (hr->type & XEN_HOST_PCI_REGION_TYPE_IO) {
return hr->base_addr | (hr->bus_flags & ~PCI_BASE_ADDRESS_IO_MASK);
} else {
return hr->base_addr | (hr->bus_flags & ~PCI_BASE_ADDRESS_MEM_MASK);
}
}
static int xen_pt_bar_reg_init(XenPCIPassthroughState *s, XenPTRegInfo *reg,
uint32_t real_offset, uint32_t *data)
{
uint32_t reg_field = 0;
int index;
index = xen_pt_bar_offset_to_index(reg->offset);
if (index < 0 || index >= PCI_NUM_REGIONS) {
XEN_PT_ERR(&s->dev, "Internal error: Invalid BAR index [%d].\n", index);
return -1;
}
/* set BAR flag */
s->bases[index].bar_flag = xen_pt_bar_reg_parse(s, reg);
if (s->bases[index].bar_flag == XEN_PT_BAR_FLAG_UNUSED) {
reg_field = XEN_PT_INVALID_REG;
}
*data = reg_field;
return 0;
}
static int xen_pt_bar_reg_read(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint32_t *value, uint32_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint32_t valid_emu_mask = 0;
uint32_t bar_emu_mask = 0;
int index;
/* get BAR index */
index = xen_pt_bar_offset_to_index(reg->offset);
if (index < 0 || index >= PCI_NUM_REGIONS) {
XEN_PT_ERR(&s->dev, "Internal error: Invalid BAR index [%d].\n", index);
return -1;
}
/* use fixed-up value from kernel sysfs */
*value = base_address_with_flags(&s->real_device.io_regions[index]);
/* set emulate mask depend on BAR flag */
switch (s->bases[index].bar_flag) {
case XEN_PT_BAR_FLAG_MEM:
bar_emu_mask = XEN_PT_BAR_MEM_EMU_MASK;
break;
case XEN_PT_BAR_FLAG_IO:
bar_emu_mask = XEN_PT_BAR_IO_EMU_MASK;
break;
case XEN_PT_BAR_FLAG_UPPER:
bar_emu_mask = XEN_PT_BAR_ALLF;
break;
default:
break;
}
/* emulate BAR */
valid_emu_mask = bar_emu_mask & valid_mask;
*value = XEN_PT_MERGE_VALUE(*value, cfg_entry->data, ~valid_emu_mask);
return 0;
}
static int xen_pt_bar_reg_write(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint32_t *val, uint32_t dev_value,
uint32_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
XenPTRegion *base = NULL;
PCIDevice *d = &s->dev;
const PCIIORegion *r;
uint32_t writable_mask = 0;
uint32_t throughable_mask = 0;
uint32_t bar_emu_mask = 0;
uint32_t bar_ro_mask = 0;
uint32_t r_size = 0;
int index = 0;
index = xen_pt_bar_offset_to_index(reg->offset);
if (index < 0 || index >= PCI_NUM_REGIONS) {
XEN_PT_ERR(d, "Internal error: Invalid BAR index [%d].\n", index);
return -1;
}
r = &d->io_regions[index];
base = &s->bases[index];
r_size = xen_pt_get_emul_size(base->bar_flag, r->size);
/* set emulate mask and read-only mask values depend on the BAR flag */
switch (s->bases[index].bar_flag) {
case XEN_PT_BAR_FLAG_MEM:
bar_emu_mask = XEN_PT_BAR_MEM_EMU_MASK;
bar_ro_mask = XEN_PT_BAR_MEM_RO_MASK | (r_size - 1);
break;
case XEN_PT_BAR_FLAG_IO:
bar_emu_mask = XEN_PT_BAR_IO_EMU_MASK;
bar_ro_mask = XEN_PT_BAR_IO_RO_MASK | (r_size - 1);
break;
case XEN_PT_BAR_FLAG_UPPER:
bar_emu_mask = XEN_PT_BAR_ALLF;
bar_ro_mask = 0; /* all upper 32bit are R/W */
break;
default:
break;
}
/* modify emulate register */
writable_mask = bar_emu_mask & ~bar_ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* check whether we need to update the virtual region address or not */
switch (s->bases[index].bar_flag) {
case XEN_PT_BAR_FLAG_MEM:
/* nothing to do */
break;
case XEN_PT_BAR_FLAG_IO:
/* nothing to do */
break;
case XEN_PT_BAR_FLAG_UPPER:
if (cfg_entry->data) {
if (cfg_entry->data != (XEN_PT_BAR_ALLF & ~bar_ro_mask)) {
XEN_PT_WARN(d, "Guest attempt to set high MMIO Base Address. "
"Ignore mapping. "
"(offset: 0x%02x, high address: 0x%08x)\n",
reg->offset, cfg_entry->data);
}
}
break;
default:
break;
}
/* create value for writing to I/O device register */
throughable_mask = ~bar_emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
return 0;
}
/* write Exp ROM BAR */
static int xen_pt_exp_rom_bar_reg_write(XenPCIPassthroughState *s,
XenPTReg *cfg_entry, uint32_t *val,
uint32_t dev_value, uint32_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
XenPTRegion *base = NULL;
PCIDevice *d = (PCIDevice *)&s->dev;
uint32_t writable_mask = 0;
uint32_t throughable_mask = 0;
pcibus_t r_size = 0;
uint32_t bar_emu_mask = 0;
uint32_t bar_ro_mask = 0;
r_size = d->io_regions[PCI_ROM_SLOT].size;
base = &s->bases[PCI_ROM_SLOT];
/* align memory type resource size */
r_size = xen_pt_get_emul_size(base->bar_flag, r_size);
/* set emulate mask and read-only mask */
bar_emu_mask = reg->emu_mask;
bar_ro_mask = (reg->ro_mask | (r_size - 1)) & ~PCI_ROM_ADDRESS_ENABLE;
/* modify emulate register */
writable_mask = ~bar_ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* create value for writing to I/O device register */
throughable_mask = ~bar_emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
return 0;
}
/* Header Type0 reg static infomation table */
static XenPTRegInfo xen_pt_emu_reg_header0[] = {
/* Vendor ID reg */
{
.offset = PCI_VENDOR_ID,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0xFFFF,
.emu_mask = 0xFFFF,
.init = xen_pt_vendor_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_word_reg_write,
},
/* Device ID reg */
{
.offset = PCI_DEVICE_ID,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0xFFFF,
.emu_mask = 0xFFFF,
.init = xen_pt_device_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_word_reg_write,
},
/* Command reg */
{
.offset = PCI_COMMAND,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0xF880,
.emu_mask = 0x0740,
.init = xen_pt_common_reg_init,
.u.w.read = xen_pt_cmd_reg_read,
.u.w.write = xen_pt_cmd_reg_write,
},
/* Capabilities Pointer reg */
{
.offset = PCI_CAPABILITY_LIST,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0xFF,
.init = xen_pt_ptr_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Status reg */
/* use emulated Cap Ptr value to initialize,
* so need to be declared after Cap Ptr reg
*/
{
.offset = PCI_STATUS,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0x06FF,
.emu_mask = 0x0010,
.init = xen_pt_status_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_word_reg_write,
},
/* Cache Line Size reg */
{
.offset = PCI_CACHE_LINE_SIZE,
.size = 1,
.init_val = 0x00,
.ro_mask = 0x00,
.emu_mask = 0xFF,
.init = xen_pt_common_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Latency Timer reg */
{
.offset = PCI_LATENCY_TIMER,
.size = 1,
.init_val = 0x00,
.ro_mask = 0x00,
.emu_mask = 0xFF,
.init = xen_pt_common_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Header Type reg */
{
.offset = PCI_HEADER_TYPE,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0x00,
.init = xen_pt_header_type_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Interrupt Line reg */
{
.offset = PCI_INTERRUPT_LINE,
.size = 1,
.init_val = 0x00,
.ro_mask = 0x00,
.emu_mask = 0xFF,
.init = xen_pt_common_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Interrupt Pin reg */
{
.offset = PCI_INTERRUPT_PIN,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0xFF,
.init = xen_pt_irqpin_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* BAR 0 reg */
/* mask of BAR need to be decided later, depends on IO/MEM type */
{
.offset = PCI_BASE_ADDRESS_0,
.size = 4,
.init_val = 0x00000000,
.init = xen_pt_bar_reg_init,
.u.dw.read = xen_pt_bar_reg_read,
.u.dw.write = xen_pt_bar_reg_write,
},
/* BAR 1 reg */
{
.offset = PCI_BASE_ADDRESS_1,
.size = 4,
.init_val = 0x00000000,
.init = xen_pt_bar_reg_init,
.u.dw.read = xen_pt_bar_reg_read,
.u.dw.write = xen_pt_bar_reg_write,
},
/* BAR 2 reg */
{
.offset = PCI_BASE_ADDRESS_2,
.size = 4,
.init_val = 0x00000000,
.init = xen_pt_bar_reg_init,
.u.dw.read = xen_pt_bar_reg_read,
.u.dw.write = xen_pt_bar_reg_write,
},
/* BAR 3 reg */
{
.offset = PCI_BASE_ADDRESS_3,
.size = 4,
.init_val = 0x00000000,
.init = xen_pt_bar_reg_init,
.u.dw.read = xen_pt_bar_reg_read,
.u.dw.write = xen_pt_bar_reg_write,
},
/* BAR 4 reg */
{
.offset = PCI_BASE_ADDRESS_4,
.size = 4,
.init_val = 0x00000000,
.init = xen_pt_bar_reg_init,
.u.dw.read = xen_pt_bar_reg_read,
.u.dw.write = xen_pt_bar_reg_write,
},
/* BAR 5 reg */
{
.offset = PCI_BASE_ADDRESS_5,
.size = 4,
.init_val = 0x00000000,
.init = xen_pt_bar_reg_init,
.u.dw.read = xen_pt_bar_reg_read,
.u.dw.write = xen_pt_bar_reg_write,
},
/* Expansion ROM BAR reg */
{
.offset = PCI_ROM_ADDRESS,
.size = 4,
.init_val = 0x00000000,
.ro_mask = 0x000007FE,
.emu_mask = 0xFFFFF800,
.init = xen_pt_bar_reg_init,
.u.dw.read = xen_pt_long_reg_read,
.u.dw.write = xen_pt_exp_rom_bar_reg_write,
},
{
.size = 0,
},
};
/*********************************
* Vital Product Data Capability
*/
/* Vital Product Data Capability Structure reg static infomation table */
static XenPTRegInfo xen_pt_emu_reg_vpd[] = {
{
.offset = PCI_CAP_LIST_NEXT,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0xFF,
.init = xen_pt_ptr_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
{
.size = 0,
},
};
/**************************************
* Vendor Specific Capability
*/
/* Vendor Specific Capability Structure reg static infomation table */
static XenPTRegInfo xen_pt_emu_reg_vendor[] = {
{
.offset = PCI_CAP_LIST_NEXT,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0xFF,
.init = xen_pt_ptr_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
{
.size = 0,
},
};
/*****************************
* PCI Express Capability
*/
static inline uint8_t get_capability_version(XenPCIPassthroughState *s,
uint32_t offset)
{
uint8_t flags = pci_get_byte(s->dev.config + offset + PCI_EXP_FLAGS);
return flags & PCI_EXP_FLAGS_VERS;
}
static inline uint8_t get_device_type(XenPCIPassthroughState *s,
uint32_t offset)
{
uint8_t flags = pci_get_byte(s->dev.config + offset + PCI_EXP_FLAGS);
return (flags & PCI_EXP_FLAGS_TYPE) >> 4;
}
/* initialize Link Control register */
static int xen_pt_linkctrl_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
uint8_t cap_ver = get_capability_version(s, real_offset - reg->offset);
uint8_t dev_type = get_device_type(s, real_offset - reg->offset);
/* no need to initialize in case of Root Complex Integrated Endpoint
* with cap_ver 1.x
*/
if ((dev_type == PCI_EXP_TYPE_RC_END) && (cap_ver == 1)) {
*data = XEN_PT_INVALID_REG;
}
*data = reg->init_val;
return 0;
}
/* initialize Device Control 2 register */
static int xen_pt_devctrl2_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
uint8_t cap_ver = get_capability_version(s, real_offset - reg->offset);
/* no need to initialize in case of cap_ver 1.x */
if (cap_ver == 1) {
*data = XEN_PT_INVALID_REG;
}
*data = reg->init_val;
return 0;
}
/* initialize Link Control 2 register */
static int xen_pt_linkctrl2_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
uint8_t cap_ver = get_capability_version(s, real_offset - reg->offset);
uint32_t reg_field = 0;
/* no need to initialize in case of cap_ver 1.x */
if (cap_ver == 1) {
reg_field = XEN_PT_INVALID_REG;
} else {
/* set Supported Link Speed */
uint8_t lnkcap = pci_get_byte(s->dev.config + real_offset - reg->offset
+ PCI_EXP_LNKCAP);
reg_field |= PCI_EXP_LNKCAP_SLS & lnkcap;
}
*data = reg_field;
return 0;
}
/* PCI Express Capability Structure reg static infomation table */
static XenPTRegInfo xen_pt_emu_reg_pcie[] = {
/* Next Pointer reg */
{
.offset = PCI_CAP_LIST_NEXT,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0xFF,
.init = xen_pt_ptr_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Device Capabilities reg */
{
.offset = PCI_EXP_DEVCAP,
.size = 4,
.init_val = 0x00000000,
.ro_mask = 0x1FFCFFFF,
.emu_mask = 0x10000000,
.init = xen_pt_common_reg_init,
.u.dw.read = xen_pt_long_reg_read,
.u.dw.write = xen_pt_long_reg_write,
},
/* Device Control reg */
{
.offset = PCI_EXP_DEVCTL,
.size = 2,
.init_val = 0x2810,
.ro_mask = 0x8400,
.emu_mask = 0xFFFF,
.init = xen_pt_common_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_word_reg_write,
},
/* Link Control reg */
{
.offset = PCI_EXP_LNKCTL,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0xFC34,
.emu_mask = 0xFFFF,
.init = xen_pt_linkctrl_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_word_reg_write,
},
/* Device Control 2 reg */
{
.offset = 0x28,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0xFFE0,
.emu_mask = 0xFFFF,
.init = xen_pt_devctrl2_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_word_reg_write,
},
/* Link Control 2 reg */
{
.offset = 0x30,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0xE040,
.emu_mask = 0xFFFF,
.init = xen_pt_linkctrl2_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_word_reg_write,
},
{
.size = 0,
},
};
/*********************************
* Power Management Capability
*/
/* read Power Management Control/Status register */
static int xen_pt_pmcsr_reg_read(XenPCIPassthroughState *s, XenPTReg *cfg_entry,
uint16_t *value, uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint16_t valid_emu_mask = reg->emu_mask;
valid_emu_mask |= PCI_PM_CTRL_STATE_MASK | PCI_PM_CTRL_NO_SOFT_RESET;
valid_emu_mask = valid_emu_mask & valid_mask;
*value = XEN_PT_MERGE_VALUE(*value, cfg_entry->data, ~valid_emu_mask);
return 0;
}
/* write Power Management Control/Status register */
static int xen_pt_pmcsr_reg_write(XenPCIPassthroughState *s,
XenPTReg *cfg_entry, uint16_t *val,
uint16_t dev_value, uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint16_t emu_mask = reg->emu_mask;
uint16_t writable_mask = 0;
uint16_t throughable_mask = 0;
emu_mask |= PCI_PM_CTRL_STATE_MASK | PCI_PM_CTRL_NO_SOFT_RESET;
/* modify emulate register */
writable_mask = emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* create value for writing to I/O device register */
throughable_mask = ~emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
return 0;
}
/* Power Management Capability reg static infomation table */
static XenPTRegInfo xen_pt_emu_reg_pm[] = {
/* Next Pointer reg */
{
.offset = PCI_CAP_LIST_NEXT,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0xFF,
.init = xen_pt_ptr_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Power Management Capabilities reg */
{
.offset = PCI_CAP_FLAGS,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0xFFFF,
.emu_mask = 0xF9C8,
.init = xen_pt_common_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_word_reg_write,
},
/* PCI Power Management Control/Status reg */
{
.offset = PCI_PM_CTRL,
.size = 2,
.init_val = 0x0008,
.ro_mask = 0xE1FC,
.emu_mask = 0x8100,
.init = xen_pt_common_reg_init,
.u.w.read = xen_pt_pmcsr_reg_read,
.u.w.write = xen_pt_pmcsr_reg_write,
},
{
.size = 0,
},
};
/********************************
* MSI Capability
*/
/* Helper */
static bool xen_pt_msgdata_check_type(uint32_t offset, uint16_t flags)
{
/* check the offset whether matches the type or not */
bool is_32 = (offset == PCI_MSI_DATA_32) && !(flags & PCI_MSI_FLAGS_64BIT);
bool is_64 = (offset == PCI_MSI_DATA_64) && (flags & PCI_MSI_FLAGS_64BIT);
return is_32 || is_64;
}
/* Message Control register */
static int xen_pt_msgctrl_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
PCIDevice *d = &s->dev;
XenPTMSI *msi = s->msi;
uint16_t reg_field = 0;
/* use I/O device register's value as initial value */
reg_field = pci_get_word(d->config + real_offset);
if (reg_field & PCI_MSI_FLAGS_ENABLE) {
XEN_PT_LOG(&s->dev, "MSI already enabled, disabling it first\n");
xen_host_pci_set_word(&s->real_device, real_offset,
reg_field & ~PCI_MSI_FLAGS_ENABLE);
}
msi->flags |= reg_field;
msi->ctrl_offset = real_offset;
msi->initialized = false;
msi->mapped = false;
*data = reg->init_val;
return 0;
}
static int xen_pt_msgctrl_reg_write(XenPCIPassthroughState *s,
XenPTReg *cfg_entry, uint16_t *val,
uint16_t dev_value, uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
XenPTMSI *msi = s->msi;
uint16_t writable_mask = 0;
uint16_t throughable_mask = 0;
uint16_t raw_val;
/* Currently no support for multi-vector */
if (*val & PCI_MSI_FLAGS_QSIZE) {
XEN_PT_WARN(&s->dev, "Tries to set more than 1 vector ctrl %x\n", *val);
}
/* modify emulate register */
writable_mask = reg->emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
msi->flags |= cfg_entry->data & ~PCI_MSI_FLAGS_ENABLE;
/* create value for writing to I/O device register */
raw_val = *val;
throughable_mask = ~reg->emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
/* update MSI */
if (raw_val & PCI_MSI_FLAGS_ENABLE) {
/* setup MSI pirq for the first time */
if (!msi->initialized) {
/* Init physical one */
XEN_PT_LOG(&s->dev, "setup MSI\n");
if (xen_pt_msi_setup(s)) {
/* We do not broadcast the error to the framework code, so
* that MSI errors are contained in MSI emulation code and
* QEMU can go on running.
* Guest MSI would be actually not working.
*/
*val &= ~PCI_MSI_FLAGS_ENABLE;
XEN_PT_WARN(&s->dev, "Can not map MSI.\n");
return 0;
}
if (xen_pt_msi_update(s)) {
*val &= ~PCI_MSI_FLAGS_ENABLE;
XEN_PT_WARN(&s->dev, "Can not bind MSI\n");
return 0;
}
msi->initialized = true;
msi->mapped = true;
}
msi->flags |= PCI_MSI_FLAGS_ENABLE;
} else {
msi->flags &= ~PCI_MSI_FLAGS_ENABLE;
}
/* pass through MSI_ENABLE bit */
*val &= ~PCI_MSI_FLAGS_ENABLE;
*val |= raw_val & PCI_MSI_FLAGS_ENABLE;
return 0;
}
/* initialize Message Upper Address register */
static int xen_pt_msgaddr64_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
/* no need to initialize in case of 32 bit type */
if (!(s->msi->flags & PCI_MSI_FLAGS_64BIT)) {
*data = XEN_PT_INVALID_REG;
} else {
*data = reg->init_val;
}
return 0;
}
/* this function will be called twice (for 32 bit and 64 bit type) */
/* initialize Message Data register */
static int xen_pt_msgdata_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
uint32_t flags = s->msi->flags;
uint32_t offset = reg->offset;
/* check the offset whether matches the type or not */
if (xen_pt_msgdata_check_type(offset, flags)) {
*data = reg->init_val;
} else {
*data = XEN_PT_INVALID_REG;
}
return 0;
}
/* write Message Address register */
static int xen_pt_msgaddr32_reg_write(XenPCIPassthroughState *s,
XenPTReg *cfg_entry, uint32_t *val,
uint32_t dev_value, uint32_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint32_t writable_mask = 0;
uint32_t throughable_mask = 0;
uint32_t old_addr = cfg_entry->data;
/* modify emulate register */
writable_mask = reg->emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
s->msi->addr_lo = cfg_entry->data;
/* create value for writing to I/O device register */
throughable_mask = ~reg->emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
/* update MSI */
if (cfg_entry->data != old_addr) {
if (s->msi->mapped) {
xen_pt_msi_update(s);
}
}
return 0;
}
/* write Message Upper Address register */
static int xen_pt_msgaddr64_reg_write(XenPCIPassthroughState *s,
XenPTReg *cfg_entry, uint32_t *val,
uint32_t dev_value, uint32_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint32_t writable_mask = 0;
uint32_t throughable_mask = 0;
uint32_t old_addr = cfg_entry->data;
/* check whether the type is 64 bit or not */
if (!(s->msi->flags & PCI_MSI_FLAGS_64BIT)) {
XEN_PT_ERR(&s->dev,
"Can't write to the upper address without 64 bit support\n");
return -1;
}
/* modify emulate register */
writable_mask = reg->emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* update the msi_info too */
s->msi->addr_hi = cfg_entry->data;
/* create value for writing to I/O device register */
throughable_mask = ~reg->emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
/* update MSI */
if (cfg_entry->data != old_addr) {
if (s->msi->mapped) {
xen_pt_msi_update(s);
}
}
return 0;
}
/* this function will be called twice (for 32 bit and 64 bit type) */
/* write Message Data register */
static int xen_pt_msgdata_reg_write(XenPCIPassthroughState *s,
XenPTReg *cfg_entry, uint16_t *val,
uint16_t dev_value, uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
XenPTMSI *msi = s->msi;
uint16_t writable_mask = 0;
uint16_t throughable_mask = 0;
uint16_t old_data = cfg_entry->data;
uint32_t offset = reg->offset;
/* check the offset whether matches the type or not */
if (!xen_pt_msgdata_check_type(offset, msi->flags)) {
/* exit I/O emulator */
XEN_PT_ERR(&s->dev, "the offset does not match the 32/64 bit type!\n");
return -1;
}
/* modify emulate register */
writable_mask = reg->emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* update the msi_info too */
msi->data = cfg_entry->data;
/* create value for writing to I/O device register */
throughable_mask = ~reg->emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
/* update MSI */
if (cfg_entry->data != old_data) {
if (msi->mapped) {
xen_pt_msi_update(s);
}
}
return 0;
}
/* MSI Capability Structure reg static infomation table */
static XenPTRegInfo xen_pt_emu_reg_msi[] = {
/* Next Pointer reg */
{
.offset = PCI_CAP_LIST_NEXT,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0xFF,
.init = xen_pt_ptr_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Message Control reg */
{
.offset = PCI_MSI_FLAGS,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0xFF8E,
.emu_mask = 0x007F,
.init = xen_pt_msgctrl_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_msgctrl_reg_write,
},
/* Message Address reg */
{
.offset = PCI_MSI_ADDRESS_LO,
.size = 4,
.init_val = 0x00000000,
.ro_mask = 0x00000003,
.emu_mask = 0xFFFFFFFF,
.no_wb = 1,
.init = xen_pt_common_reg_init,
.u.dw.read = xen_pt_long_reg_read,
.u.dw.write = xen_pt_msgaddr32_reg_write,
},
/* Message Upper Address reg (if PCI_MSI_FLAGS_64BIT set) */
{
.offset = PCI_MSI_ADDRESS_HI,
.size = 4,
.init_val = 0x00000000,
.ro_mask = 0x00000000,
.emu_mask = 0xFFFFFFFF,
.no_wb = 1,
.init = xen_pt_msgaddr64_reg_init,
.u.dw.read = xen_pt_long_reg_read,
.u.dw.write = xen_pt_msgaddr64_reg_write,
},
/* Message Data reg (16 bits of data for 32-bit devices) */
{
.offset = PCI_MSI_DATA_32,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0x0000,
.emu_mask = 0xFFFF,
.no_wb = 1,
.init = xen_pt_msgdata_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_msgdata_reg_write,
},
/* Message Data reg (16 bits of data for 64-bit devices) */
{
.offset = PCI_MSI_DATA_64,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0x0000,
.emu_mask = 0xFFFF,
.no_wb = 1,
.init = xen_pt_msgdata_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_msgdata_reg_write,
},
{
.size = 0,
},
};
/**************************************
* MSI-X Capability
*/
/* Message Control register for MSI-X */
static int xen_pt_msixctrl_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
PCIDevice *d = &s->dev;
uint16_t reg_field = 0;
/* use I/O device register's value as initial value */
reg_field = pci_get_word(d->config + real_offset);
if (reg_field & PCI_MSIX_FLAGS_ENABLE) {
XEN_PT_LOG(d, "MSIX already enabled, disabling it first\n");
xen_host_pci_set_word(&s->real_device, real_offset,
reg_field & ~PCI_MSIX_FLAGS_ENABLE);
}
s->msix->ctrl_offset = real_offset;
*data = reg->init_val;
return 0;
}
static int xen_pt_msixctrl_reg_write(XenPCIPassthroughState *s,
XenPTReg *cfg_entry, uint16_t *val,
uint16_t dev_value, uint16_t valid_mask)
{
XenPTRegInfo *reg = cfg_entry->reg;
uint16_t writable_mask = 0;
uint16_t throughable_mask = 0;
int debug_msix_enabled_old;
/* modify emulate register */
writable_mask = reg->emu_mask & ~reg->ro_mask & valid_mask;
cfg_entry->data = XEN_PT_MERGE_VALUE(*val, cfg_entry->data, writable_mask);
/* create value for writing to I/O device register */
throughable_mask = ~reg->emu_mask & valid_mask;
*val = XEN_PT_MERGE_VALUE(*val, dev_value, throughable_mask);
/* update MSI-X */
if ((*val & PCI_MSIX_FLAGS_ENABLE)
&& !(*val & PCI_MSIX_FLAGS_MASKALL)) {
xen_pt_msix_update(s);
}
debug_msix_enabled_old = s->msix->enabled;
s->msix->enabled = !!(*val & PCI_MSIX_FLAGS_ENABLE);
if (s->msix->enabled != debug_msix_enabled_old) {
XEN_PT_LOG(&s->dev, "%s MSI-X\n",
s->msix->enabled ? "enable" : "disable");
}
return 0;
}
/* MSI-X Capability Structure reg static infomation table */
static XenPTRegInfo xen_pt_emu_reg_msix[] = {
/* Next Pointer reg */
{
.offset = PCI_CAP_LIST_NEXT,
.size = 1,
.init_val = 0x00,
.ro_mask = 0xFF,
.emu_mask = 0xFF,
.init = xen_pt_ptr_reg_init,
.u.b.read = xen_pt_byte_reg_read,
.u.b.write = xen_pt_byte_reg_write,
},
/* Message Control reg */
{
.offset = PCI_MSI_FLAGS,
.size = 2,
.init_val = 0x0000,
.ro_mask = 0x3FFF,
.emu_mask = 0x0000,
.init = xen_pt_msixctrl_reg_init,
.u.w.read = xen_pt_word_reg_read,
.u.w.write = xen_pt_msixctrl_reg_write,
},
{
.size = 0,
},
};
/****************************
* Capabilities
*/
/* capability structure register group size functions */
static int xen_pt_reg_grp_size_init(XenPCIPassthroughState *s,
const XenPTRegGroupInfo *grp_reg,
uint32_t base_offset, uint8_t *size)
{
*size = grp_reg->grp_size;
return 0;
}
/* get Vendor Specific Capability Structure register group size */
static int xen_pt_vendor_size_init(XenPCIPassthroughState *s,
const XenPTRegGroupInfo *grp_reg,
uint32_t base_offset, uint8_t *size)
{
*size = pci_get_byte(s->dev.config + base_offset + 0x02);
return 0;
}
/* get PCI Express Capability Structure register group size */
static int xen_pt_pcie_size_init(XenPCIPassthroughState *s,
const XenPTRegGroupInfo *grp_reg,
uint32_t base_offset, uint8_t *size)
{
PCIDevice *d = &s->dev;
uint8_t version = get_capability_version(s, base_offset);
uint8_t type = get_device_type(s, base_offset);
uint8_t pcie_size = 0;
/* calculate size depend on capability version and device/port type */
/* in case of PCI Express Base Specification Rev 1.x */
if (version == 1) {
/* The PCI Express Capabilities, Device Capabilities, and Device
* Status/Control registers are required for all PCI Express devices.
* The Link Capabilities and Link Status/Control are required for all
* Endpoints that are not Root Complex Integrated Endpoints. Endpoints
* are not required to implement registers other than those listed
* above and terminate the capability structure.
*/
switch (type) {
case PCI_EXP_TYPE_ENDPOINT:
case PCI_EXP_TYPE_LEG_END:
pcie_size = 0x14;
break;
case PCI_EXP_TYPE_RC_END:
/* has no link */
pcie_size = 0x0C;
break;
/* only EndPoint passthrough is supported */
case PCI_EXP_TYPE_ROOT_PORT:
case PCI_EXP_TYPE_UPSTREAM:
case PCI_EXP_TYPE_DOWNSTREAM:
case PCI_EXP_TYPE_PCI_BRIDGE:
case PCI_EXP_TYPE_PCIE_BRIDGE:
case PCI_EXP_TYPE_RC_EC:
default:
XEN_PT_ERR(d, "Unsupported device/port type %#x.\n", type);
return -1;
}
}
/* in case of PCI Express Base Specification Rev 2.0 */
else if (version == 2) {
switch (type) {
case PCI_EXP_TYPE_ENDPOINT:
case PCI_EXP_TYPE_LEG_END:
case PCI_EXP_TYPE_RC_END:
/* For Functions that do not implement the registers,
* these spaces must be hardwired to 0b.
*/
pcie_size = 0x3C;
break;
/* only EndPoint passthrough is supported */
case PCI_EXP_TYPE_ROOT_PORT:
case PCI_EXP_TYPE_UPSTREAM:
case PCI_EXP_TYPE_DOWNSTREAM:
case PCI_EXP_TYPE_PCI_BRIDGE:
case PCI_EXP_TYPE_PCIE_BRIDGE:
case PCI_EXP_TYPE_RC_EC:
default:
XEN_PT_ERR(d, "Unsupported device/port type %#x.\n", type);
return -1;
}
} else {
XEN_PT_ERR(d, "Unsupported capability version %#x.\n", version);
return -1;
}
*size = pcie_size;
return 0;
}
/* get MSI Capability Structure register group size */
static int xen_pt_msi_size_init(XenPCIPassthroughState *s,
const XenPTRegGroupInfo *grp_reg,
uint32_t base_offset, uint8_t *size)
{
PCIDevice *d = &s->dev;
uint16_t msg_ctrl = 0;
uint8_t msi_size = 0xa;
msg_ctrl = pci_get_word(d->config + (base_offset + PCI_MSI_FLAGS));
/* check if 64-bit address is capable of per-vector masking */
if (msg_ctrl & PCI_MSI_FLAGS_64BIT) {
msi_size += 4;
}
if (msg_ctrl & PCI_MSI_FLAGS_MASKBIT) {
msi_size += 10;
}
s->msi = g_new0(XenPTMSI, 1);
s->msi->pirq = XEN_PT_UNASSIGNED_PIRQ;
*size = msi_size;
return 0;
}
/* get MSI-X Capability Structure register group size */
static int xen_pt_msix_size_init(XenPCIPassthroughState *s,
const XenPTRegGroupInfo *grp_reg,
uint32_t base_offset, uint8_t *size)
{
int rc = 0;
rc = xen_pt_msix_init(s, base_offset);
if (rc < 0) {
XEN_PT_ERR(&s->dev, "Internal error: Invalid xen_pt_msix_init.\n");
return rc;
}
*size = grp_reg->grp_size;
return 0;
}
static const XenPTRegGroupInfo xen_pt_emu_reg_grps[] = {
/* Header Type0 reg group */
{
.grp_id = 0xFF,
.grp_type = XEN_PT_GRP_TYPE_EMU,
.grp_size = 0x40,
.size_init = xen_pt_reg_grp_size_init,
.emu_regs = xen_pt_emu_reg_header0,
},
/* PCI PowerManagement Capability reg group */
{
.grp_id = PCI_CAP_ID_PM,
.grp_type = XEN_PT_GRP_TYPE_EMU,
.grp_size = PCI_PM_SIZEOF,
.size_init = xen_pt_reg_grp_size_init,
.emu_regs = xen_pt_emu_reg_pm,
},
/* AGP Capability Structure reg group */
{
.grp_id = PCI_CAP_ID_AGP,
.grp_type = XEN_PT_GRP_TYPE_HARDWIRED,
.grp_size = 0x30,
.size_init = xen_pt_reg_grp_size_init,
},
/* Vital Product Data Capability Structure reg group */
{
.grp_id = PCI_CAP_ID_VPD,
.grp_type = XEN_PT_GRP_TYPE_EMU,
.grp_size = 0x08,
.size_init = xen_pt_reg_grp_size_init,
.emu_regs = xen_pt_emu_reg_vpd,
},
/* Slot Identification reg group */
{
.grp_id = PCI_CAP_ID_SLOTID,
.grp_type = XEN_PT_GRP_TYPE_HARDWIRED,
.grp_size = 0x04,
.size_init = xen_pt_reg_grp_size_init,
},
/* MSI Capability Structure reg group */
{
.grp_id = PCI_CAP_ID_MSI,
.grp_type = XEN_PT_GRP_TYPE_EMU,
.grp_size = 0xFF,
.size_init = xen_pt_msi_size_init,
.emu_regs = xen_pt_emu_reg_msi,
},
/* PCI-X Capabilities List Item reg group */
{
.grp_id = PCI_CAP_ID_PCIX,
.grp_type = XEN_PT_GRP_TYPE_HARDWIRED,
.grp_size = 0x18,
.size_init = xen_pt_reg_grp_size_init,
},
/* Vendor Specific Capability Structure reg group */
{
.grp_id = PCI_CAP_ID_VNDR,
.grp_type = XEN_PT_GRP_TYPE_EMU,
.grp_size = 0xFF,
.size_init = xen_pt_vendor_size_init,
.emu_regs = xen_pt_emu_reg_vendor,
},
/* SHPC Capability List Item reg group */
{
.grp_id = PCI_CAP_ID_SHPC,
.grp_type = XEN_PT_GRP_TYPE_HARDWIRED,
.grp_size = 0x08,
.size_init = xen_pt_reg_grp_size_init,
},
/* Subsystem ID and Subsystem Vendor ID Capability List Item reg group */
{
.grp_id = PCI_CAP_ID_SSVID,
.grp_type = XEN_PT_GRP_TYPE_HARDWIRED,
.grp_size = 0x08,
.size_init = xen_pt_reg_grp_size_init,
},
/* AGP 8x Capability Structure reg group */
{
.grp_id = PCI_CAP_ID_AGP3,
.grp_type = XEN_PT_GRP_TYPE_HARDWIRED,
.grp_size = 0x30,
.size_init = xen_pt_reg_grp_size_init,
},
/* PCI Express Capability Structure reg group */
{
.grp_id = PCI_CAP_ID_EXP,
.grp_type = XEN_PT_GRP_TYPE_EMU,
.grp_size = 0xFF,
.size_init = xen_pt_pcie_size_init,
.emu_regs = xen_pt_emu_reg_pcie,
},
/* MSI-X Capability Structure reg group */
{
.grp_id = PCI_CAP_ID_MSIX,
.grp_type = XEN_PT_GRP_TYPE_EMU,
.grp_size = 0x0C,
.size_init = xen_pt_msix_size_init,
.emu_regs = xen_pt_emu_reg_msix,
},
{
.grp_size = 0,
},
};
/* initialize Capabilities Pointer or Next Pointer register */
static int xen_pt_ptr_reg_init(XenPCIPassthroughState *s,
XenPTRegInfo *reg, uint32_t real_offset,
uint32_t *data)
{
int i;
uint8_t *config = s->dev.config;
uint32_t reg_field = pci_get_byte(config + real_offset);
uint8_t cap_id = 0;
/* find capability offset */
while (reg_field) {
for (i = 0; xen_pt_emu_reg_grps[i].grp_size != 0; i++) {
if (xen_pt_hide_dev_cap(&s->real_device,
xen_pt_emu_reg_grps[i].grp_id)) {
continue;
}
cap_id = pci_get_byte(config + reg_field + PCI_CAP_LIST_ID);
if (xen_pt_emu_reg_grps[i].grp_id == cap_id) {
if (xen_pt_emu_reg_grps[i].grp_type == XEN_PT_GRP_TYPE_EMU) {
goto out;
}
/* ignore the 0 hardwired capability, find next one */
break;
}
}
/* next capability */
reg_field = pci_get_byte(config + reg_field + PCI_CAP_LIST_NEXT);
}
out:
*data = reg_field;
return 0;
}
/*************
* Main
*/
static uint8_t find_cap_offset(XenPCIPassthroughState *s, uint8_t cap)
{
uint8_t id;
unsigned max_cap = PCI_CAP_MAX;
uint8_t pos = PCI_CAPABILITY_LIST;
uint8_t status = 0;
if (xen_host_pci_get_byte(&s->real_device, PCI_STATUS, &status)) {
return 0;
}
if ((status & PCI_STATUS_CAP_LIST) == 0) {
return 0;
}
while (max_cap--) {
if (xen_host_pci_get_byte(&s->real_device, pos, &pos)) {
break;
}
if (pos < PCI_CONFIG_HEADER_SIZE) {
break;
}
pos &= ~3;
if (xen_host_pci_get_byte(&s->real_device,
pos + PCI_CAP_LIST_ID, &id)) {
break;
}
if (id == 0xff) {
break;
}
if (id == cap) {
return pos;
}
pos += PCI_CAP_LIST_NEXT;
}
return 0;
}
static int xen_pt_config_reg_init(XenPCIPassthroughState *s,
XenPTRegGroup *reg_grp, XenPTRegInfo *reg)
{
XenPTReg *reg_entry;
uint32_t data = 0;
int rc = 0;
reg_entry = g_new0(XenPTReg, 1);
reg_entry->reg = reg;
if (reg->init) {
/* initialize emulate register */
rc = reg->init(s, reg_entry->reg,
reg_grp->base_offset + reg->offset, &data);
if (rc < 0) {
free(reg_entry);
return rc;
}
if (data == XEN_PT_INVALID_REG) {
/* free unused BAR register entry */
free(reg_entry);
return 0;
}
/* set register value */
reg_entry->data = data;
}
/* list add register entry */
QLIST_INSERT_HEAD(&reg_grp->reg_tbl_list, reg_entry, entries);
return 0;
}
int xen_pt_config_init(XenPCIPassthroughState *s)
{
int i, rc;
QLIST_INIT(&s->reg_grps);
for (i = 0; xen_pt_emu_reg_grps[i].grp_size != 0; i++) {
uint32_t reg_grp_offset = 0;
XenPTRegGroup *reg_grp_entry = NULL;
if (xen_pt_emu_reg_grps[i].grp_id != 0xFF) {
if (xen_pt_hide_dev_cap(&s->real_device,
xen_pt_emu_reg_grps[i].grp_id)) {
continue;
}
reg_grp_offset = find_cap_offset(s, xen_pt_emu_reg_grps[i].grp_id);
if (!reg_grp_offset) {
continue;
}
}
reg_grp_entry = g_new0(XenPTRegGroup, 1);
QLIST_INIT(&reg_grp_entry->reg_tbl_list);
QLIST_INSERT_HEAD(&s->reg_grps, reg_grp_entry, entries);
reg_grp_entry->base_offset = reg_grp_offset;
reg_grp_entry->reg_grp = xen_pt_emu_reg_grps + i;
if (xen_pt_emu_reg_grps[i].size_init) {
/* get register group size */
rc = xen_pt_emu_reg_grps[i].size_init(s, reg_grp_entry->reg_grp,
reg_grp_offset,
&reg_grp_entry->size);
if (rc < 0) {
xen_pt_config_delete(s);
return rc;
}
}
if (xen_pt_emu_reg_grps[i].grp_type == XEN_PT_GRP_TYPE_EMU) {
if (xen_pt_emu_reg_grps[i].emu_regs) {
int j = 0;
XenPTRegInfo *regs = xen_pt_emu_reg_grps[i].emu_regs;
/* initialize capability register */
for (j = 0; regs->size != 0; j++, regs++) {
/* initialize capability register */
rc = xen_pt_config_reg_init(s, reg_grp_entry, regs);
if (rc < 0) {
xen_pt_config_delete(s);
return rc;
}
}
}
}
}
return 0;
}
/* delete all emulate register */
void xen_pt_config_delete(XenPCIPassthroughState *s)
{
struct XenPTRegGroup *reg_group, *next_grp;
struct XenPTReg *reg, *next_reg;
/* free MSI/MSI-X info table */
if (s->msix) {
xen_pt_msix_delete(s);
}
if (s->msi) {
g_free(s->msi);
}
/* free all register group entry */
QLIST_FOREACH_SAFE(reg_group, &s->reg_grps, entries, next_grp) {
/* free all register entry */
QLIST_FOREACH_SAFE(reg, &reg_group->reg_tbl_list, entries, next_reg) {
QLIST_REMOVE(reg, entries);
g_free(reg);
}
QLIST_REMOVE(reg_group, entries);
g_free(reg_group);
}
}
hw/xen_pt_msi.c 0 → 100644
浏览文件 @ 7a542b67
/*
* Copyright (c) 2007, Intel Corporation.
*
* This work is licensed under the terms of the GNU GPL, version 2. See
* the COPYING file in the top-level directory.
*
* Jiang Yunhong <yunhong.jiang@intel.com>
*
* This file implements direct PCI assignment to a HVM guest
*/
#include <sys/mman.h>
#include "xen_backend.h"
#include "xen_pt.h"
#include "apic-msidef.h"
#define XEN_PT_AUTO_ASSIGN -1
/* shift count for gflags */
#define XEN_PT_GFLAGS_SHIFT_DEST_ID 0
#define XEN_PT_GFLAGS_SHIFT_RH 8
#define XEN_PT_GFLAGS_SHIFT_DM 9
#define XEN_PT_GFLAGSSHIFT_DELIV_MODE 12
#define XEN_PT_GFLAGSSHIFT_TRG_MODE 15
/*
* Helpers
*/
static inline uint8_t msi_vector(uint32_t data)
{
return (data & MSI_DATA_VECTOR_MASK) >> MSI_DATA_VECTOR_SHIFT;
}
static inline uint8_t msi_dest_id(uint32_t addr)
{
return (addr & MSI_ADDR_DEST_ID_MASK) >> MSI_ADDR_DEST_ID_SHIFT;
}
static inline uint32_t msi_ext_dest_id(uint32_t addr_hi)
{
return addr_hi & 0xffffff00;
}
static uint32_t msi_gflags(uint32_t data, uint64_t addr)
{
uint32_t result = 0;
int rh, dm, dest_id, deliv_mode, trig_mode;
rh = (addr >> MSI_ADDR_REDIRECTION_SHIFT) & 0x1;
dm = (addr >> MSI_ADDR_DEST_MODE_SHIFT) & 0x1;
dest_id = msi_dest_id(addr);
deliv_mode = (data >> MSI_DATA_DELIVERY_MODE_SHIFT) & 0x7;
trig_mode = (data >> MSI_DATA_TRIGGER_SHIFT) & 0x1;
result = dest_id | (rh << XEN_PT_GFLAGS_SHIFT_RH)
| (dm << XEN_PT_GFLAGS_SHIFT_DM)
| (deliv_mode << XEN_PT_GFLAGSSHIFT_DELIV_MODE)
| (trig_mode << XEN_PT_GFLAGSSHIFT_TRG_MODE);
return result;
}
static inline uint64_t msi_addr64(XenPTMSI *msi)
{
return (uint64_t)msi->addr_hi << 32 | msi->addr_lo;
}
static int msi_msix_enable(XenPCIPassthroughState *s,
uint32_t address,
uint16_t flag,
bool enable)
{
uint16_t val = 0;
if (!address) {
return -1;
}
xen_host_pci_get_word(&s->real_device, address, &val);
if (enable) {
val |= flag;
} else {
val &= ~flag;
}
xen_host_pci_set_word(&s->real_device, address, val);
return 0;
}
static int msi_msix_setup(XenPCIPassthroughState *s,
uint64_t addr,
uint32_t data,
int *ppirq,
bool is_msix,
int msix_entry,
bool is_not_mapped)
{
uint8_t gvec = msi_vector(data);
int rc = 0;
assert((!is_msix && msix_entry == 0) || is_msix);
if (gvec == 0) {
/* if gvec is 0, the guest is asking for a particular pirq that
* is passed as dest_id */
*ppirq = msi_ext_dest_id(addr >> 32) | msi_dest_id(addr);
if (!*ppirq) {
/* this probably identifies an misconfiguration of the guest,
* try the emulated path */
*ppirq = XEN_PT_UNASSIGNED_PIRQ;
} else {
XEN_PT_LOG(&s->dev, "requested pirq %d for MSI%s"
" (vec: %#x, entry: %#x)\n",
*ppirq, is_msix ? "-X" : "", gvec, msix_entry);
}
}
if (is_not_mapped) {
uint64_t table_base = 0;
if (is_msix) {
table_base = s->msix->table_base;
}
rc = xc_physdev_map_pirq_msi(xen_xc, xen_domid, XEN_PT_AUTO_ASSIGN,
ppirq, PCI_DEVFN(s->real_device.dev,
s->real_device.func),
s->real_device.bus,
msix_entry, table_base);
if (rc) {
XEN_PT_ERR(&s->dev,
"Mapping of MSI%s (rc: %i, vec: %#x, entry %#x)\n",
is_msix ? "-X" : "", rc, gvec, msix_entry);
return rc;
}
}
return 0;
}
static int msi_msix_update(XenPCIPassthroughState *s,
uint64_t addr,
uint32_t data,
int pirq,
bool is_msix,
int msix_entry,
int *old_pirq)
{
PCIDevice *d = &s->dev;
uint8_t gvec = msi_vector(data);
uint32_t gflags = msi_gflags(data, addr);
int rc = 0;
uint64_t table_addr = 0;
XEN_PT_LOG(d, "Updating MSI%s with pirq %d gvec %#x gflags %#x"
" (entry: %#x)\n",
is_msix ? "-X" : "", pirq, gvec, gflags, msix_entry);
if (is_msix) {
table_addr = s->msix->mmio_base_addr;
}
rc = xc_domain_update_msi_irq(xen_xc, xen_domid, gvec,
pirq, gflags, table_addr);
if (rc) {
XEN_PT_ERR(d, "Updating of MSI%s failed. (rc: %d)\n",
is_msix ? "-X" : "", rc);
if (xc_physdev_unmap_pirq(xen_xc, xen_domid, *old_pirq)) {
XEN_PT_ERR(d, "Unmapping of MSI%s pirq %d failed.\n",
is_msix ? "-X" : "", *old_pirq);
}
*old_pirq = XEN_PT_UNASSIGNED_PIRQ;
}
return rc;
}
static int msi_msix_disable(XenPCIPassthroughState *s,
uint64_t addr,
uint32_t data,
int pirq,
bool is_msix,
bool is_binded)
{
PCIDevice *d = &s->dev;
uint8_t gvec = msi_vector(data);
uint32_t gflags = msi_gflags(data, addr);
int rc = 0;
if (pirq == XEN_PT_UNASSIGNED_PIRQ) {
return 0;
}
if (is_binded) {
XEN_PT_LOG(d, "Unbind MSI%s with pirq %d, gvec %#x\n",
is_msix ? "-X" : "", pirq, gvec);
rc = xc_domain_unbind_msi_irq(xen_xc, xen_domid, gvec, pirq, gflags);
if (rc) {
XEN_PT_ERR(d, "Unbinding of MSI%s failed. (pirq: %d, gvec: %#x)\n",
is_msix ? "-X" : "", pirq, gvec);
return rc;
}
}
XEN_PT_LOG(d, "Unmap MSI%s pirq %d\n", is_msix ? "-X" : "", pirq);
rc = xc_physdev_unmap_pirq(xen_xc, xen_domid, pirq);
if (rc) {
XEN_PT_ERR(d, "Unmapping of MSI%s pirq %d failed. (rc: %i)\n",
is_msix ? "-X" : "", pirq, rc);
return rc;
}
return 0;
}
/*
* MSI virtualization functions
*/
int xen_pt_msi_set_enable(XenPCIPassthroughState *s, bool enable)
{
XEN_PT_LOG(&s->dev, "%s MSI.\n", enable ? "enabling" : "disabling");
if (!s->msi) {
return -1;
}
return msi_msix_enable(s, s->msi->ctrl_offset, PCI_MSI_FLAGS_ENABLE,
enable);
}
/* setup physical msi, but don't enable it */
int xen_pt_msi_setup(XenPCIPassthroughState *s)
{
int pirq = XEN_PT_UNASSIGNED_PIRQ;
int rc = 0;
XenPTMSI *msi = s->msi;
if (msi->initialized) {
XEN_PT_ERR(&s->dev,
"Setup physical MSI when it has been properly initialized.\n");
return -1;
}
rc = msi_msix_setup(s, msi_addr64(msi), msi->data, &pirq, false, 0, true);
if (rc) {
return rc;
}
if (pirq < 0) {
XEN_PT_ERR(&s->dev, "Invalid pirq number: %d.\n", pirq);
return -1;
}
msi->pirq = pirq;
XEN_PT_LOG(&s->dev, "MSI mapped with pirq %d.\n", pirq);
return 0;
}
int xen_pt_msi_update(XenPCIPassthroughState *s)
{
XenPTMSI *msi = s->msi;
return msi_msix_update(s, msi_addr64(msi), msi->data, msi->pirq,
false, 0, &msi->pirq);
}
void xen_pt_msi_disable(XenPCIPassthroughState *s)
{
XenPTMSI *msi = s->msi;
if (!msi) {
return;
}
xen_pt_msi_set_enable(s, false);
msi_msix_disable(s, msi_addr64(msi), msi->data, msi->pirq, false,
msi->initialized);
/* clear msi info */
msi->flags = 0;
msi->mapped = false;
msi->pirq = XEN_PT_UNASSIGNED_PIRQ;
}
/*
* MSI-X virtualization functions
*/
static int msix_set_enable(XenPCIPassthroughState *s, bool enabled)
{
XEN_PT_LOG(&s->dev, "%s MSI-X.\n", enabled ? "enabling" : "disabling");
if (!s->msix) {
return -1;
}
return msi_msix_enable(s, s->msix->ctrl_offset, PCI_MSIX_FLAGS_ENABLE,
enabled);
}
static int xen_pt_msix_update_one(XenPCIPassthroughState *s, int entry_nr)
{
XenPTMSIXEntry *entry = NULL;
int pirq;
int rc;
if (entry_nr < 0 || entry_nr >= s->msix->total_entries) {
return -EINVAL;
}
entry = &s->msix->msix_entry[entry_nr];
if (!entry->updated) {
return 0;
}
pirq = entry->pirq;
rc = msi_msix_setup(s, entry->data, entry->data, &pirq, true, entry_nr,
entry->pirq == XEN_PT_UNASSIGNED_PIRQ);
if (rc) {
return rc;
}
if (entry->pirq == XEN_PT_UNASSIGNED_PIRQ) {
entry->pirq = pirq;
}
rc = msi_msix_update(s, entry->addr, entry->data, pirq, true,
entry_nr, &entry->pirq);
if (!rc) {
entry->updated = false;
}
return rc;
}
int xen_pt_msix_update(XenPCIPassthroughState *s)
{
XenPTMSIX *msix = s->msix;
int i;
for (i = 0; i < msix->total_entries; i++) {
xen_pt_msix_update_one(s, i);
}
return 0;
}
void xen_pt_msix_disable(XenPCIPassthroughState *s)
{
int i = 0;
msix_set_enable(s, false);
for (i = 0; i < s->msix->total_entries; i++) {
XenPTMSIXEntry *entry = &s->msix->msix_entry[i];
msi_msix_disable(s, entry->addr, entry->data, entry->pirq, true, true);
/* clear MSI-X info */
entry->pirq = XEN_PT_UNASSIGNED_PIRQ;
entry->updated = false;
}
}
int xen_pt_msix_update_remap(XenPCIPassthroughState *s, int bar_index)
{
XenPTMSIXEntry *entry;
int i, ret;
if (!(s->msix && s->msix->bar_index == bar_index)) {
return 0;
}
for (i = 0; i < s->msix->total_entries; i++) {
entry = &s->msix->msix_entry[i];
if (entry->pirq != XEN_PT_UNASSIGNED_PIRQ) {
ret = xc_domain_unbind_pt_irq(xen_xc, xen_domid, entry->pirq,
PT_IRQ_TYPE_MSI, 0, 0, 0, 0);
if (ret) {
XEN_PT_ERR(&s->dev, "unbind MSI-X entry %d failed\n",
entry->pirq);
}
entry->updated = true;
}
}
return xen_pt_msix_update(s);
}
static uint32_t get_entry_value(XenPTMSIXEntry *e, int offset)
{
switch (offset) {
case PCI_MSIX_ENTRY_LOWER_ADDR:
return e->addr & UINT32_MAX;
case PCI_MSIX_ENTRY_UPPER_ADDR:
return e->addr >> 32;
case PCI_MSIX_ENTRY_DATA:
return e->data;
case PCI_MSIX_ENTRY_VECTOR_CTRL:
return e->vector_ctrl;
default:
return 0;
}
}
static void set_entry_value(XenPTMSIXEntry *e, int offset, uint32_t val)
{
switch (offset) {
case PCI_MSIX_ENTRY_LOWER_ADDR:
e->addr = (e->addr & ((uint64_t)UINT32_MAX << 32)) | val;
break;
case PCI_MSIX_ENTRY_UPPER_ADDR:
e->addr = (uint64_t)val << 32 | (e->addr & UINT32_MAX);
break;
case PCI_MSIX_ENTRY_DATA:
e->data = val;
break;
case PCI_MSIX_ENTRY_VECTOR_CTRL:
e->vector_ctrl = val;
break;
}
}
static void pci_msix_write(void *opaque, target_phys_addr_t addr,
uint64_t val, unsigned size)
{
XenPCIPassthroughState *s = opaque;
XenPTMSIX *msix = s->msix;
XenPTMSIXEntry *entry;
int entry_nr, offset;
entry_nr = addr / PCI_MSIX_ENTRY_SIZE;
if (entry_nr < 0 || entry_nr >= msix->total_entries) {
XEN_PT_ERR(&s->dev, "asked MSI-X entry '%i' invalid!\n", entry_nr);
return;
}
entry = &msix->msix_entry[entry_nr];
offset = addr % PCI_MSIX_ENTRY_SIZE;
if (offset != PCI_MSIX_ENTRY_VECTOR_CTRL) {
const volatile uint32_t *vec_ctrl;
if (get_entry_value(entry, offset) == val) {
return;
}
/*
* If Xen intercepts the mask bit access, entry->vec_ctrl may not be
* up-to-date. Read from hardware directly.
*/
vec_ctrl = s->msix->phys_iomem_base + entry_nr * PCI_MSIX_ENTRY_SIZE
+ PCI_MSIX_ENTRY_VECTOR_CTRL;
if (msix->enabled && !(*vec_ctrl & PCI_MSIX_ENTRY_CTRL_MASKBIT)) {
XEN_PT_ERR(&s->dev, "Can't update msix entry %d since MSI-X is"
" already enabled.\n", entry_nr);
return;
}
entry->updated = true;
}
set_entry_value(entry, offset, val);
if (offset == PCI_MSIX_ENTRY_VECTOR_CTRL) {
if (msix->enabled && !(val & PCI_MSIX_ENTRY_CTRL_MASKBIT)) {
xen_pt_msix_update_one(s, entry_nr);
}
}
}
static uint64_t pci_msix_read(void *opaque, target_phys_addr_t addr,
unsigned size)
{
XenPCIPassthroughState *s = opaque;
XenPTMSIX *msix = s->msix;
int entry_nr, offset;
entry_nr = addr / PCI_MSIX_ENTRY_SIZE;
if (entry_nr < 0) {
XEN_PT_ERR(&s->dev, "asked MSI-X entry '%i' invalid!\n", entry_nr);
return 0;
}
offset = addr % PCI_MSIX_ENTRY_SIZE;
if (addr < msix->total_entries * PCI_MSIX_ENTRY_SIZE) {
return get_entry_value(&msix->msix_entry[entry_nr], offset);
} else {
/* Pending Bit Array (PBA) */
return *(uint32_t *)(msix->phys_iomem_base + addr);
}
}
static const MemoryRegionOps pci_msix_ops = {
.read = pci_msix_read,
.write = pci_msix_write,
.endianness = DEVICE_NATIVE_ENDIAN,
.valid = {
.min_access_size = 4,
.max_access_size = 4,
.unaligned = false,
},
};
int xen_pt_msix_init(XenPCIPassthroughState *s, uint32_t base)
{
uint8_t id = 0;
uint16_t control = 0;
uint32_t table_off = 0;
int i, total_entries, bar_index;
XenHostPCIDevice *hd = &s->real_device;
PCIDevice *d = &s->dev;
int fd = -1;
XenPTMSIX *msix = NULL;
int rc = 0;
rc = xen_host_pci_get_byte(hd, base + PCI_CAP_LIST_ID, &id);
if (rc) {
return rc;
}
if (id != PCI_CAP_ID_MSIX) {
XEN_PT_ERR(d, "Invalid id %#x base %#x\n", id, base);
return -1;
}
xen_host_pci_get_word(hd, base + PCI_MSIX_FLAGS, &control);
total_entries = control & PCI_MSIX_FLAGS_QSIZE;
total_entries += 1;
s->msix = g_malloc0(sizeof (XenPTMSIX)
+ total_entries * sizeof (XenPTMSIXEntry));
msix = s->msix;
msix->total_entries = total_entries;
for (i = 0; i < total_entries; i++) {
msix->msix_entry[i].pirq = XEN_PT_UNASSIGNED_PIRQ;
}
memory_region_init_io(&msix->mmio, &pci_msix_ops, s, "xen-pci-pt-msix",
(total_entries * PCI_MSIX_ENTRY_SIZE
+ XC_PAGE_SIZE - 1)
& XC_PAGE_MASK);
xen_host_pci_get_long(hd, base + PCI_MSIX_TABLE, &table_off);
bar_index = msix->bar_index = table_off & PCI_MSIX_FLAGS_BIRMASK;
table_off = table_off & ~PCI_MSIX_FLAGS_BIRMASK;
msix->table_base = s->real_device.io_regions[bar_index].base_addr;
XEN_PT_LOG(d, "get MSI-X table BAR base 0x%"PRIx64"\n", msix->table_base);
fd = open("/dev/mem", O_RDWR);
if (fd == -1) {
rc = -errno;
XEN_PT_ERR(d, "Can't open /dev/mem: %s\n", strerror(errno));
goto error_out;
}
XEN_PT_LOG(d, "table_off = %#x, total_entries = %d\n",
table_off, total_entries);
msix->table_offset_adjust = table_off & 0x0fff;
msix->phys_iomem_base =
mmap(NULL,
total_entries * PCI_MSIX_ENTRY_SIZE + msix->table_offset_adjust,
PROT_READ,
MAP_SHARED | MAP_LOCKED,
fd,
msix->table_base + table_off - msix->table_offset_adjust);
close(fd);
if (msix->phys_iomem_base == MAP_FAILED) {
rc = -errno;
XEN_PT_ERR(d, "Can't map physical MSI-X table: %s\n", strerror(errno));
goto error_out;
}
msix->phys_iomem_base = (char *)msix->phys_iomem_base
+ msix->table_offset_adjust;
XEN_PT_LOG(d, "mapping physical MSI-X table to %p\n",
msix->phys_iomem_base);
memory_region_add_subregion_overlap(&s->bar[bar_index], table_off,
&msix->mmio,
2); /* Priority: pci default + 1 */
return 0;
error_out:
memory_region_destroy(&msix->mmio);
g_free(s->msix);
s->msix = NULL;
return rc;
}
void xen_pt_msix_delete(XenPCIPassthroughState *s)
{
XenPTMSIX *msix = s->msix;
if (!msix) {
return;
}
/* unmap the MSI-X memory mapped register area */
if (msix->phys_iomem_base) {
XEN_PT_LOG(&s->dev, "unmapping physical MSI-X table from %p\n",
msix->phys_iomem_base);
munmap(msix->phys_iomem_base, msix->total_entries * PCI_MSIX_ENTRY_SIZE
+ msix->table_offset_adjust);
}
memory_region_del_subregion(&s->bar[msix->bar_index], &msix->mmio);
memory_region_destroy(&msix->mmio);
g_free(s->msix);
s->msix = NULL;
}
qemu-common.h
浏览文件 @ 7a542b67
......@@ -275,6 +275,13 @@ typedef enum LostTickPolicy {
LOST_TICK_MAX
} LostTickPolicy;
typedef struct PCIHostDeviceAddress {
unsigned int domain;
unsigned int bus;
unsigned int slot;
unsigned int function;
} PCIHostDeviceAddress;
void tcg_exec_init(unsigned long tb_size);
bool tcg_enabled(void);
......
xen-all.c
浏览文件 @ 7a542b67
......@@ -1191,3 +1191,15 @@ void xen_register_framebuffer(MemoryRegion *mr)
{
framebuffer = mr;
}
void xen_shutdown_fatal_error(const char *fmt, ...)
{
va_list ap;
va_start(ap, fmt);
vfprintf(stderr, fmt, ap);
va_end(ap);
fprintf(stderr, "Will destroy the domain.\n");
/* destroy the domain */
qemu_system_shutdown_request();
}
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