qemu/hw/arm/virt.c

2262 lines
83 KiB
C
Raw Normal View History

/*
* ARM mach-virt emulation
*
* Copyright (c) 2013 Linaro Limited
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2 or later, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License along with
* this program. If not, see <http://www.gnu.org/licenses/>.
*
* Emulate a virtual board which works by passing Linux all the information
* it needs about what devices are present via the device tree.
* There are some restrictions about what we can do here:
* + we can only present devices whose Linux drivers will work based
* purely on the device tree with no platform data at all
* + we want to present a very stripped-down minimalist platform,
* both because this reduces the security attack surface from the guest
* and also because it reduces our exposure to being broken when
* the kernel updates its device tree bindings and requires further
* information in a device binding that we aren't providing.
* This is essentially the same approach kvmtool uses.
*/
#include "qemu/osdep.h"
#include "qemu-common.h"
#include "qemu/units.h"
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
#include "qemu/option.h"
2016-03-14 16:01:28 +08:00
#include "qapi/error.h"
#include "hw/sysbus.h"
#include "hw/boards.h"
#include "hw/arm/boot.h"
#include "hw/arm/primecell.h"
#include "hw/arm/virt.h"
#include "hw/block/flash.h"
#include "hw/vfio/vfio-calxeda-xgmac.h"
#include "hw/vfio/vfio-amd-xgbe.h"
#include "hw/display/ramfb.h"
#include "net/net.h"
#include "sysemu/device_tree.h"
#include "sysemu/numa.h"
#include "sysemu/runstate.h"
#include "sysemu/sysemu.h"
#include "sysemu/kvm.h"
#include "hw/loader.h"
#include "exec/address-spaces.h"
#include "qemu/bitops.h"
#include "qemu/error-report.h"
#include "qemu/module.h"
#include "hw/pci-host/gpex.h"
#include "hw/arm/sysbus-fdt.h"
#include "hw/platform-bus.h"
#include "hw/qdev-properties.h"
#include "hw/arm/fdt.h"
#include "hw/intc/arm_gic.h"
#include "hw/intc/arm_gicv3_common.h"
#include "hw/irq.h"
#include "kvm_arm.h"
#include "hw/firmware/smbios.h"
#include "qapi/visitor.h"
#include "standard-headers/linux/input.h"
#include "hw/arm/smmuv3.h"
#include "hw/acpi/acpi.h"
#include "target/arm/internals.h"
#include "hw/mem/pc-dimm.h"
#include "hw/mem/nvdimm.h"
#include "hw/acpi/generic_event_device.h"
#define DEFINE_VIRT_MACHINE_LATEST(major, minor, latest) \
static void virt_##major##_##minor##_class_init(ObjectClass *oc, \
void *data) \
{ \
MachineClass *mc = MACHINE_CLASS(oc); \
virt_machine_##major##_##minor##_options(mc); \
mc->desc = "QEMU " # major "." # minor " ARM Virtual Machine"; \
if (latest) { \
mc->alias = "virt"; \
} \
} \
static const TypeInfo machvirt_##major##_##minor##_info = { \
.name = MACHINE_TYPE_NAME("virt-" # major "." # minor), \
.parent = TYPE_VIRT_MACHINE, \
.class_init = virt_##major##_##minor##_class_init, \
}; \
static void machvirt_machine_##major##_##minor##_init(void) \
{ \
type_register_static(&machvirt_##major##_##minor##_info); \
} \
type_init(machvirt_machine_##major##_##minor##_init);
#define DEFINE_VIRT_MACHINE_AS_LATEST(major, minor) \
DEFINE_VIRT_MACHINE_LATEST(major, minor, true)
#define DEFINE_VIRT_MACHINE(major, minor) \
DEFINE_VIRT_MACHINE_LATEST(major, minor, false)
/* Number of external interrupt lines to configure the GIC with */
#define NUM_IRQS 256
#define PLATFORM_BUS_NUM_IRQS 64
/* Legacy RAM limit in GB (< version 4.0) */
#define LEGACY_RAMLIMIT_GB 255
#define LEGACY_RAMLIMIT_BYTES (LEGACY_RAMLIMIT_GB * GiB)
/* Addresses and sizes of our components.
* 0..128MB is space for a flash device so we can run bootrom code such as UEFI.
* 128MB..256MB is used for miscellaneous device I/O.
* 256MB..1GB is reserved for possible future PCI support (ie where the
* PCI memory window will go if we add a PCI host controller).
* 1GB and up is RAM (which may happily spill over into the
* high memory region beyond 4GB).
* This represents a compromise between how much RAM can be given to
* a 32 bit VM and leaving space for expansion and in particular for PCI.
* Note that devices should generally be placed at multiples of 0x10000,
* to accommodate guests using 64K pages.
*/
static const MemMapEntry base_memmap[] = {
/* Space up to 0x8000000 is reserved for a boot ROM */
[VIRT_FLASH] = { 0, 0x08000000 },
[VIRT_CPUPERIPHS] = { 0x08000000, 0x00020000 },
/* GIC distributor and CPU interfaces sit inside the CPU peripheral space */
[VIRT_GIC_DIST] = { 0x08000000, 0x00010000 },
[VIRT_GIC_CPU] = { 0x08010000, 0x00010000 },
[VIRT_GIC_V2M] = { 0x08020000, 0x00001000 },
[VIRT_GIC_HYP] = { 0x08030000, 0x00010000 },
[VIRT_GIC_VCPU] = { 0x08040000, 0x00010000 },
/* The space in between here is reserved for GICv3 CPU/vCPU/HYP */
[VIRT_GIC_ITS] = { 0x08080000, 0x00020000 },
/* This redistributor space allows up to 2*64kB*123 CPUs */
[VIRT_GIC_REDIST] = { 0x080A0000, 0x00F60000 },
[VIRT_UART] = { 0x09000000, 0x00001000 },
[VIRT_RTC] = { 0x09010000, 0x00001000 },
[VIRT_FW_CFG] = { 0x09020000, 0x00000018 },
[VIRT_GPIO] = { 0x09030000, 0x00001000 },
[VIRT_SECURE_UART] = { 0x09040000, 0x00001000 },
[VIRT_SMMU] = { 0x09050000, 0x00020000 },
[VIRT_PCDIMM_ACPI] = { 0x09070000, MEMORY_HOTPLUG_IO_LEN },
[VIRT_ACPI_GED] = { 0x09080000, ACPI_GED_EVT_SEL_LEN },
[VIRT_MMIO] = { 0x0a000000, 0x00000200 },
/* ...repeating for a total of NUM_VIRTIO_TRANSPORTS, each of that size */
[VIRT_PLATFORM_BUS] = { 0x0c000000, 0x02000000 },
[VIRT_SECURE_MEM] = { 0x0e000000, 0x01000000 },
[VIRT_PCIE_MMIO] = { 0x10000000, 0x2eff0000 },
[VIRT_PCIE_PIO] = { 0x3eff0000, 0x00010000 },
[VIRT_PCIE_ECAM] = { 0x3f000000, 0x01000000 },
/* Actual RAM size depends on initial RAM and device memory settings */
[VIRT_MEM] = { GiB, LEGACY_RAMLIMIT_BYTES },
};
/*
* Highmem IO Regions: This memory map is floating, located after the RAM.
* Each MemMapEntry base (GPA) will be dynamically computed, depending on the
* top of the RAM, so that its base get the same alignment as the size,
* ie. a 512GiB entry will be aligned on a 512GiB boundary. If there is
* less than 256GiB of RAM, the floating area starts at the 256GiB mark.
* Note the extended_memmap is sized so that it eventually also includes the
* base_memmap entries (VIRT_HIGH_GIC_REDIST2 index is greater than the last
* index of base_memmap).
*/
static MemMapEntry extended_memmap[] = {
/* Additional 64 MB redist region (can contain up to 512 redistributors) */
[VIRT_HIGH_GIC_REDIST2] = { 0x0, 64 * MiB },
[VIRT_HIGH_PCIE_ECAM] = { 0x0, 256 * MiB },
/* Second PCIe window */
[VIRT_HIGH_PCIE_MMIO] = { 0x0, 512 * GiB },
};
static const int a15irqmap[] = {
[VIRT_UART] = 1,
[VIRT_RTC] = 2,
[VIRT_PCIE] = 3, /* ... to 6 */
[VIRT_GPIO] = 7,
[VIRT_SECURE_UART] = 8,
[VIRT_ACPI_GED] = 9,
[VIRT_MMIO] = 16, /* ...to 16 + NUM_VIRTIO_TRANSPORTS - 1 */
[VIRT_GIC_V2M] = 48, /* ...to 48 + NUM_GICV2M_SPIS - 1 */
[VIRT_SMMU] = 74, /* ...to 74 + NUM_SMMU_IRQS - 1 */
[VIRT_PLATFORM_BUS] = 112, /* ...to 112 + PLATFORM_BUS_NUM_IRQS -1 */
};
static const char *valid_cpus[] = {
ARM_CPU_TYPE_NAME("cortex-a7"),
arm: drop intermediate cpu_model -> cpu type parsing and use cpu type directly there are 2 use cases to deal with: 1: fixed CPU models per board/soc 2: boards with user configurable cpu_model and fallback to default cpu_model if user hasn't specified one explicitly For the 1st drop intermediate cpu_model parsing and use const cpu type directly, which replaces: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) object_new(typename) with object_new(FOO_CPU_TYPE_NAME) or cpu_generic_init(BASE_CPU_TYPE, "my cpu model") with cpu_create(FOO_CPU_TYPE_NAME) as result 1st use case doesn't have to invoke not necessary translation and not needed code is removed. For the 2nd 1: set default cpu type with MachineClass::default_cpu_type and 2: use generic cpu_model parsing that done before machine_init() is run and: 2.1: drop custom cpu_model parsing where pattern is: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) [parse_features(typename, cpu_model, &err) ] 2.2: or replace cpu_generic_init() which does what 2.1 does + create_cpu(typename) with just create_cpu(machine->cpu_type) as result cpu_name -> cpu_type translation is done using generic machine code one including parsing optional features if supported/present (removes a bunch of duplicated cpu_model parsing code) and default cpu type is defined in an uniform way within machine_class_init callbacks instead of adhoc places in boadr's machine_init code. Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Eduardo Habkost <ehabkost@redhat.com> Message-Id: <1505318697-77161-6-git-send-email-imammedo@redhat.com> Reviewed-by: Alistair Francis <alistair.francis@xilinx.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Signed-off-by: Eduardo Habkost <ehabkost@redhat.com>
2017-09-14 00:04:57 +08:00
ARM_CPU_TYPE_NAME("cortex-a15"),
ARM_CPU_TYPE_NAME("cortex-a53"),
ARM_CPU_TYPE_NAME("cortex-a57"),
ARM_CPU_TYPE_NAME("cortex-a72"),
arm: drop intermediate cpu_model -> cpu type parsing and use cpu type directly there are 2 use cases to deal with: 1: fixed CPU models per board/soc 2: boards with user configurable cpu_model and fallback to default cpu_model if user hasn't specified one explicitly For the 1st drop intermediate cpu_model parsing and use const cpu type directly, which replaces: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) object_new(typename) with object_new(FOO_CPU_TYPE_NAME) or cpu_generic_init(BASE_CPU_TYPE, "my cpu model") with cpu_create(FOO_CPU_TYPE_NAME) as result 1st use case doesn't have to invoke not necessary translation and not needed code is removed. For the 2nd 1: set default cpu type with MachineClass::default_cpu_type and 2: use generic cpu_model parsing that done before machine_init() is run and: 2.1: drop custom cpu_model parsing where pattern is: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) [parse_features(typename, cpu_model, &err) ] 2.2: or replace cpu_generic_init() which does what 2.1 does + create_cpu(typename) with just create_cpu(machine->cpu_type) as result cpu_name -> cpu_type translation is done using generic machine code one including parsing optional features if supported/present (removes a bunch of duplicated cpu_model parsing code) and default cpu type is defined in an uniform way within machine_class_init callbacks instead of adhoc places in boadr's machine_init code. Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Eduardo Habkost <ehabkost@redhat.com> Message-Id: <1505318697-77161-6-git-send-email-imammedo@redhat.com> Reviewed-by: Alistair Francis <alistair.francis@xilinx.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Signed-off-by: Eduardo Habkost <ehabkost@redhat.com>
2017-09-14 00:04:57 +08:00
ARM_CPU_TYPE_NAME("host"),
ARM_CPU_TYPE_NAME("max"),
};
arm: drop intermediate cpu_model -> cpu type parsing and use cpu type directly there are 2 use cases to deal with: 1: fixed CPU models per board/soc 2: boards with user configurable cpu_model and fallback to default cpu_model if user hasn't specified one explicitly For the 1st drop intermediate cpu_model parsing and use const cpu type directly, which replaces: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) object_new(typename) with object_new(FOO_CPU_TYPE_NAME) or cpu_generic_init(BASE_CPU_TYPE, "my cpu model") with cpu_create(FOO_CPU_TYPE_NAME) as result 1st use case doesn't have to invoke not necessary translation and not needed code is removed. For the 2nd 1: set default cpu type with MachineClass::default_cpu_type and 2: use generic cpu_model parsing that done before machine_init() is run and: 2.1: drop custom cpu_model parsing where pattern is: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) [parse_features(typename, cpu_model, &err) ] 2.2: or replace cpu_generic_init() which does what 2.1 does + create_cpu(typename) with just create_cpu(machine->cpu_type) as result cpu_name -> cpu_type translation is done using generic machine code one including parsing optional features if supported/present (removes a bunch of duplicated cpu_model parsing code) and default cpu type is defined in an uniform way within machine_class_init callbacks instead of adhoc places in boadr's machine_init code. Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Eduardo Habkost <ehabkost@redhat.com> Message-Id: <1505318697-77161-6-git-send-email-imammedo@redhat.com> Reviewed-by: Alistair Francis <alistair.francis@xilinx.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Signed-off-by: Eduardo Habkost <ehabkost@redhat.com>
2017-09-14 00:04:57 +08:00
static bool cpu_type_valid(const char *cpu)
{
int i;
for (i = 0; i < ARRAY_SIZE(valid_cpus); i++) {
if (strcmp(cpu, valid_cpus[i]) == 0) {
return true;
}
}
return false;
}
static void create_fdt(VirtMachineState *vms)
{
MachineState *ms = MACHINE(vms);
int nb_numa_nodes = ms->numa_state->num_nodes;
void *fdt = create_device_tree(&vms->fdt_size);
if (!fdt) {
error_report("create_device_tree() failed");
exit(1);
}
vms->fdt = fdt;
/* Header */
qemu_fdt_setprop_string(fdt, "/", "compatible", "linux,dummy-virt");
qemu_fdt_setprop_cell(fdt, "/", "#address-cells", 0x2);
qemu_fdt_setprop_cell(fdt, "/", "#size-cells", 0x2);
/* /chosen must exist for load_dtb to fill in necessary properties later */
qemu_fdt_add_subnode(fdt, "/chosen");
/* Clock node, for the benefit of the UART. The kernel device tree
* binding documentation claims the PL011 node clock properties are
* optional but in practice if you omit them the kernel refuses to
* probe for the device.
*/
vms->clock_phandle = qemu_fdt_alloc_phandle(fdt);
qemu_fdt_add_subnode(fdt, "/apb-pclk");
qemu_fdt_setprop_string(fdt, "/apb-pclk", "compatible", "fixed-clock");
qemu_fdt_setprop_cell(fdt, "/apb-pclk", "#clock-cells", 0x0);
qemu_fdt_setprop_cell(fdt, "/apb-pclk", "clock-frequency", 24000000);
qemu_fdt_setprop_string(fdt, "/apb-pclk", "clock-output-names",
"clk24mhz");
qemu_fdt_setprop_cell(fdt, "/apb-pclk", "phandle", vms->clock_phandle);
if (nb_numa_nodes > 0 && ms->numa_state->have_numa_distance) {
int size = nb_numa_nodes * nb_numa_nodes * 3 * sizeof(uint32_t);
uint32_t *matrix = g_malloc0(size);
int idx, i, j;
for (i = 0; i < nb_numa_nodes; i++) {
for (j = 0; j < nb_numa_nodes; j++) {
idx = (i * nb_numa_nodes + j) * 3;
matrix[idx + 0] = cpu_to_be32(i);
matrix[idx + 1] = cpu_to_be32(j);
matrix[idx + 2] =
cpu_to_be32(ms->numa_state->nodes[i].distance[j]);
}
}
qemu_fdt_add_subnode(fdt, "/distance-map");
qemu_fdt_setprop_string(fdt, "/distance-map", "compatible",
"numa-distance-map-v1");
qemu_fdt_setprop(fdt, "/distance-map", "distance-matrix",
matrix, size);
g_free(matrix);
}
}
static void fdt_add_timer_nodes(const VirtMachineState *vms)
{
/* On real hardware these interrupts are level-triggered.
* On KVM they were edge-triggered before host kernel version 4.4,
* and level-triggered afterwards.
* On emulated QEMU they are level-triggered.
*
* Getting the DTB info about them wrong is awkward for some
* guest kernels:
* pre-4.8 ignore the DT and leave the interrupt configured
* with whatever the GIC reset value (or the bootloader) left it at
* 4.8 before rc6 honour the incorrect data by programming it back
* into the GIC, causing problems
* 4.8rc6 and later ignore the DT and always write "level triggered"
* into the GIC
*
* For backwards-compatibility, virt-2.8 and earlier will continue
* to say these are edge-triggered, but later machines will report
* the correct information.
*/
ARMCPU *armcpu;
VirtMachineClass *vmc = VIRT_MACHINE_GET_CLASS(vms);
uint32_t irqflags = GIC_FDT_IRQ_FLAGS_LEVEL_HI;
if (vmc->claim_edge_triggered_timers) {
irqflags = GIC_FDT_IRQ_FLAGS_EDGE_LO_HI;
}
if (vms->gic_version == 2) {
irqflags = deposit32(irqflags, GIC_FDT_IRQ_PPI_CPU_START,
GIC_FDT_IRQ_PPI_CPU_WIDTH,
(1 << vms->smp_cpus) - 1);
}
qemu_fdt_add_subnode(vms->fdt, "/timer");
armcpu = ARM_CPU(qemu_get_cpu(0));
if (arm_feature(&armcpu->env, ARM_FEATURE_V8)) {
const char compat[] = "arm,armv8-timer\0arm,armv7-timer";
qemu_fdt_setprop(vms->fdt, "/timer", "compatible",
compat, sizeof(compat));
} else {
qemu_fdt_setprop_string(vms->fdt, "/timer", "compatible",
"arm,armv7-timer");
}
qemu_fdt_setprop(vms->fdt, "/timer", "always-on", NULL, 0);
qemu_fdt_setprop_cells(vms->fdt, "/timer", "interrupts",
GIC_FDT_IRQ_TYPE_PPI, ARCH_TIMER_S_EL1_IRQ, irqflags,
GIC_FDT_IRQ_TYPE_PPI, ARCH_TIMER_NS_EL1_IRQ, irqflags,
GIC_FDT_IRQ_TYPE_PPI, ARCH_TIMER_VIRT_IRQ, irqflags,
GIC_FDT_IRQ_TYPE_PPI, ARCH_TIMER_NS_EL2_IRQ, irqflags);
}
static void fdt_add_cpu_nodes(const VirtMachineState *vms)
{
int cpu;
int addr_cells = 1;
const MachineState *ms = MACHINE(vms);
/*
* From Documentation/devicetree/bindings/arm/cpus.txt
* On ARM v8 64-bit systems value should be set to 2,
* that corresponds to the MPIDR_EL1 register size.
* If MPIDR_EL1[63:32] value is equal to 0 on all CPUs
* in the system, #address-cells can be set to 1, since
* MPIDR_EL1[63:32] bits are not used for CPUs
* identification.
*
* Here we actually don't know whether our system is 32- or 64-bit one.
* The simplest way to go is to examine affinity IDs of all our CPUs. If
* at least one of them has Aff3 populated, we set #address-cells to 2.
*/
for (cpu = 0; cpu < vms->smp_cpus; cpu++) {
ARMCPU *armcpu = ARM_CPU(qemu_get_cpu(cpu));
if (armcpu->mp_affinity & ARM_AFF3_MASK) {
addr_cells = 2;
break;
}
}
qemu_fdt_add_subnode(vms->fdt, "/cpus");
qemu_fdt_setprop_cell(vms->fdt, "/cpus", "#address-cells", addr_cells);
qemu_fdt_setprop_cell(vms->fdt, "/cpus", "#size-cells", 0x0);
for (cpu = vms->smp_cpus - 1; cpu >= 0; cpu--) {
char *nodename = g_strdup_printf("/cpus/cpu@%d", cpu);
ARMCPU *armcpu = ARM_CPU(qemu_get_cpu(cpu));
CPUState *cs = CPU(armcpu);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename, "device_type", "cpu");
qemu_fdt_setprop_string(vms->fdt, nodename, "compatible",
armcpu->dtb_compatible);
if (vms->psci_conduit != QEMU_PSCI_CONDUIT_DISABLED
&& vms->smp_cpus > 1) {
qemu_fdt_setprop_string(vms->fdt, nodename,
"enable-method", "psci");
}
if (addr_cells == 2) {
qemu_fdt_setprop_u64(vms->fdt, nodename, "reg",
armcpu->mp_affinity);
} else {
qemu_fdt_setprop_cell(vms->fdt, nodename, "reg",
armcpu->mp_affinity);
}
if (ms->possible_cpus->cpus[cs->cpu_index].props.has_node_id) {
qemu_fdt_setprop_cell(vms->fdt, nodename, "numa-node-id",
ms->possible_cpus->cpus[cs->cpu_index].props.node_id);
}
g_free(nodename);
}
}
static void fdt_add_its_gic_node(VirtMachineState *vms)
{
char *nodename;
vms->msi_phandle = qemu_fdt_alloc_phandle(vms->fdt);
nodename = g_strdup_printf("/intc/its@%" PRIx64,
vms->memmap[VIRT_GIC_ITS].base);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename, "compatible",
"arm,gic-v3-its");
qemu_fdt_setprop(vms->fdt, nodename, "msi-controller", NULL, 0);
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, vms->memmap[VIRT_GIC_ITS].base,
2, vms->memmap[VIRT_GIC_ITS].size);
qemu_fdt_setprop_cell(vms->fdt, nodename, "phandle", vms->msi_phandle);
g_free(nodename);
}
static void fdt_add_v2m_gic_node(VirtMachineState *vms)
{
char *nodename;
nodename = g_strdup_printf("/intc/v2m@%" PRIx64,
vms->memmap[VIRT_GIC_V2M].base);
vms->msi_phandle = qemu_fdt_alloc_phandle(vms->fdt);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename, "compatible",
"arm,gic-v2m-frame");
qemu_fdt_setprop(vms->fdt, nodename, "msi-controller", NULL, 0);
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, vms->memmap[VIRT_GIC_V2M].base,
2, vms->memmap[VIRT_GIC_V2M].size);
qemu_fdt_setprop_cell(vms->fdt, nodename, "phandle", vms->msi_phandle);
g_free(nodename);
}
static void fdt_add_gic_node(VirtMachineState *vms)
{
char *nodename;
vms->gic_phandle = qemu_fdt_alloc_phandle(vms->fdt);
qemu_fdt_setprop_cell(vms->fdt, "/", "interrupt-parent", vms->gic_phandle);
nodename = g_strdup_printf("/intc@%" PRIx64,
vms->memmap[VIRT_GIC_DIST].base);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_cell(vms->fdt, nodename, "#interrupt-cells", 3);
qemu_fdt_setprop(vms->fdt, nodename, "interrupt-controller", NULL, 0);
qemu_fdt_setprop_cell(vms->fdt, nodename, "#address-cells", 0x2);
qemu_fdt_setprop_cell(vms->fdt, nodename, "#size-cells", 0x2);
qemu_fdt_setprop(vms->fdt, nodename, "ranges", NULL, 0);
if (vms->gic_version == 3) {
int nb_redist_regions = virt_gicv3_redist_region_count(vms);
qemu_fdt_setprop_string(vms->fdt, nodename, "compatible",
"arm,gic-v3");
qemu_fdt_setprop_cell(vms->fdt, nodename,
"#redistributor-regions", nb_redist_regions);
if (nb_redist_regions == 1) {
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, vms->memmap[VIRT_GIC_DIST].base,
2, vms->memmap[VIRT_GIC_DIST].size,
2, vms->memmap[VIRT_GIC_REDIST].base,
2, vms->memmap[VIRT_GIC_REDIST].size);
} else {
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, vms->memmap[VIRT_GIC_DIST].base,
2, vms->memmap[VIRT_GIC_DIST].size,
2, vms->memmap[VIRT_GIC_REDIST].base,
2, vms->memmap[VIRT_GIC_REDIST].size,
2, vms->memmap[VIRT_HIGH_GIC_REDIST2].base,
2, vms->memmap[VIRT_HIGH_GIC_REDIST2].size);
}
if (vms->virt) {
qemu_fdt_setprop_cells(vms->fdt, nodename, "interrupts",
GIC_FDT_IRQ_TYPE_PPI, ARCH_GIC_MAINT_IRQ,
GIC_FDT_IRQ_FLAGS_LEVEL_HI);
}
} else {
/* 'cortex-a15-gic' means 'GIC v2' */
qemu_fdt_setprop_string(vms->fdt, nodename, "compatible",
"arm,cortex-a15-gic");
if (!vms->virt) {
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, vms->memmap[VIRT_GIC_DIST].base,
2, vms->memmap[VIRT_GIC_DIST].size,
2, vms->memmap[VIRT_GIC_CPU].base,
2, vms->memmap[VIRT_GIC_CPU].size);
} else {
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, vms->memmap[VIRT_GIC_DIST].base,
2, vms->memmap[VIRT_GIC_DIST].size,
2, vms->memmap[VIRT_GIC_CPU].base,
2, vms->memmap[VIRT_GIC_CPU].size,
2, vms->memmap[VIRT_GIC_HYP].base,
2, vms->memmap[VIRT_GIC_HYP].size,
2, vms->memmap[VIRT_GIC_VCPU].base,
2, vms->memmap[VIRT_GIC_VCPU].size);
qemu_fdt_setprop_cells(vms->fdt, nodename, "interrupts",
GIC_FDT_IRQ_TYPE_PPI, ARCH_GIC_MAINT_IRQ,
GIC_FDT_IRQ_FLAGS_LEVEL_HI);
}
}
qemu_fdt_setprop_cell(vms->fdt, nodename, "phandle", vms->gic_phandle);
g_free(nodename);
}
static void fdt_add_pmu_nodes(const VirtMachineState *vms)
{
CPUState *cpu;
ARMCPU *armcpu;
uint32_t irqflags = GIC_FDT_IRQ_FLAGS_LEVEL_HI;
CPU_FOREACH(cpu) {
armcpu = ARM_CPU(cpu);
if (!arm_feature(&armcpu->env, ARM_FEATURE_PMU)) {
return;
}
if (kvm_enabled()) {
if (kvm_irqchip_in_kernel()) {
kvm_arm_pmu_set_irq(cpu, PPI(VIRTUAL_PMU_IRQ));
}
kvm_arm_pmu_init(cpu);
}
}
if (vms->gic_version == 2) {
irqflags = deposit32(irqflags, GIC_FDT_IRQ_PPI_CPU_START,
GIC_FDT_IRQ_PPI_CPU_WIDTH,
(1 << vms->smp_cpus) - 1);
}
armcpu = ARM_CPU(qemu_get_cpu(0));
qemu_fdt_add_subnode(vms->fdt, "/pmu");
if (arm_feature(&armcpu->env, ARM_FEATURE_V8)) {
const char compat[] = "arm,armv8-pmuv3";
qemu_fdt_setprop(vms->fdt, "/pmu", "compatible",
compat, sizeof(compat));
qemu_fdt_setprop_cells(vms->fdt, "/pmu", "interrupts",
GIC_FDT_IRQ_TYPE_PPI, VIRTUAL_PMU_IRQ, irqflags);
}
}
static inline DeviceState *create_acpi_ged(VirtMachineState *vms, qemu_irq *pic)
{
DeviceState *dev;
MachineState *ms = MACHINE(vms);
int irq = vms->irqmap[VIRT_ACPI_GED];
uint32_t event = ACPI_GED_PWR_DOWN_EVT;
if (ms->ram_slots) {
event |= ACPI_GED_MEM_HOTPLUG_EVT;
}
dev = qdev_create(NULL, TYPE_ACPI_GED);
qdev_prop_set_uint32(dev, "ged-event", event);
sysbus_mmio_map(SYS_BUS_DEVICE(dev), 0, vms->memmap[VIRT_ACPI_GED].base);
sysbus_mmio_map(SYS_BUS_DEVICE(dev), 1, vms->memmap[VIRT_PCDIMM_ACPI].base);
sysbus_connect_irq(SYS_BUS_DEVICE(dev), 0, pic[irq]);
qdev_init_nofail(dev);
return dev;
}
static void create_its(VirtMachineState *vms, DeviceState *gicdev)
{
const char *itsclass = its_class_name();
DeviceState *dev;
if (!itsclass) {
/* Do nothing if not supported */
return;
}
dev = qdev_create(NULL, itsclass);
object_property_set_link(OBJECT(dev), OBJECT(gicdev), "parent-gicv3",
&error_abort);
qdev_init_nofail(dev);
sysbus_mmio_map(SYS_BUS_DEVICE(dev), 0, vms->memmap[VIRT_GIC_ITS].base);
fdt_add_its_gic_node(vms);
}
static void create_v2m(VirtMachineState *vms, qemu_irq *pic)
{
int i;
int irq = vms->irqmap[VIRT_GIC_V2M];
DeviceState *dev;
dev = qdev_create(NULL, "arm-gicv2m");
sysbus_mmio_map(SYS_BUS_DEVICE(dev), 0, vms->memmap[VIRT_GIC_V2M].base);
qdev_prop_set_uint32(dev, "base-spi", irq);
qdev_prop_set_uint32(dev, "num-spi", NUM_GICV2M_SPIS);
qdev_init_nofail(dev);
for (i = 0; i < NUM_GICV2M_SPIS; i++) {
sysbus_connect_irq(SYS_BUS_DEVICE(dev), i, pic[irq + i]);
}
fdt_add_v2m_gic_node(vms);
}
static void create_gic(VirtMachineState *vms, qemu_irq *pic)
{
MachineState *ms = MACHINE(vms);
/* We create a standalone GIC */
DeviceState *gicdev;
SysBusDevice *gicbusdev;
const char *gictype;
int type = vms->gic_version, i;
unsigned int smp_cpus = ms->smp.cpus;
uint32_t nb_redist_regions = 0;
gictype = (type == 3) ? gicv3_class_name() : gic_class_name();
gicdev = qdev_create(NULL, gictype);
qdev_prop_set_uint32(gicdev, "revision", type);
qdev_prop_set_uint32(gicdev, "num-cpu", smp_cpus);
/* Note that the num-irq property counts both internal and external
* interrupts; there are always 32 of the former (mandated by GIC spec).
*/
qdev_prop_set_uint32(gicdev, "num-irq", NUM_IRQS + 32);
if (!kvm_irqchip_in_kernel()) {
qdev_prop_set_bit(gicdev, "has-security-extensions", vms->secure);
}
if (type == 3) {
uint32_t redist0_capacity =
vms->memmap[VIRT_GIC_REDIST].size / GICV3_REDIST_SIZE;
uint32_t redist0_count = MIN(smp_cpus, redist0_capacity);
nb_redist_regions = virt_gicv3_redist_region_count(vms);
qdev_prop_set_uint32(gicdev, "len-redist-region-count",
nb_redist_regions);
qdev_prop_set_uint32(gicdev, "redist-region-count[0]", redist0_count);
if (nb_redist_regions == 2) {
uint32_t redist1_capacity =
vms->memmap[VIRT_HIGH_GIC_REDIST2].size / GICV3_REDIST_SIZE;
qdev_prop_set_uint32(gicdev, "redist-region-count[1]",
MIN(smp_cpus - redist0_count, redist1_capacity));
}
} else {
if (!kvm_irqchip_in_kernel()) {
qdev_prop_set_bit(gicdev, "has-virtualization-extensions",
vms->virt);
}
}
qdev_init_nofail(gicdev);
gicbusdev = SYS_BUS_DEVICE(gicdev);
sysbus_mmio_map(gicbusdev, 0, vms->memmap[VIRT_GIC_DIST].base);
if (type == 3) {
sysbus_mmio_map(gicbusdev, 1, vms->memmap[VIRT_GIC_REDIST].base);
if (nb_redist_regions == 2) {
sysbus_mmio_map(gicbusdev, 2,
vms->memmap[VIRT_HIGH_GIC_REDIST2].base);
}
} else {
sysbus_mmio_map(gicbusdev, 1, vms->memmap[VIRT_GIC_CPU].base);
if (vms->virt) {
sysbus_mmio_map(gicbusdev, 2, vms->memmap[VIRT_GIC_HYP].base);
sysbus_mmio_map(gicbusdev, 3, vms->memmap[VIRT_GIC_VCPU].base);
}
}
/* Wire the outputs from each CPU's generic timer and the GICv3
* maintenance interrupt signal to the appropriate GIC PPI inputs,
* and the GIC's IRQ/FIQ/VIRQ/VFIQ interrupt outputs to the CPU's inputs.
*/
for (i = 0; i < smp_cpus; i++) {
DeviceState *cpudev = DEVICE(qemu_get_cpu(i));
int ppibase = NUM_IRQS + i * GIC_INTERNAL + GIC_NR_SGIS;
int irq;
/* Mapping from the output timer irq lines from the CPU to the
* GIC PPI inputs we use for the virt board.
*/
const int timer_irq[] = {
[GTIMER_PHYS] = ARCH_TIMER_NS_EL1_IRQ,
[GTIMER_VIRT] = ARCH_TIMER_VIRT_IRQ,
[GTIMER_HYP] = ARCH_TIMER_NS_EL2_IRQ,
[GTIMER_SEC] = ARCH_TIMER_S_EL1_IRQ,
};
for (irq = 0; irq < ARRAY_SIZE(timer_irq); irq++) {
qdev_connect_gpio_out(cpudev, irq,
qdev_get_gpio_in(gicdev,
ppibase + timer_irq[irq]));
}
if (type == 3) {
qemu_irq irq = qdev_get_gpio_in(gicdev,
ppibase + ARCH_GIC_MAINT_IRQ);
qdev_connect_gpio_out_named(cpudev, "gicv3-maintenance-interrupt",
0, irq);
} else if (vms->virt) {
qemu_irq irq = qdev_get_gpio_in(gicdev,
ppibase + ARCH_GIC_MAINT_IRQ);
sysbus_connect_irq(gicbusdev, i + 4 * smp_cpus, irq);
}
qdev_connect_gpio_out_named(cpudev, "pmu-interrupt", 0,
qdev_get_gpio_in(gicdev, ppibase
+ VIRTUAL_PMU_IRQ));
sysbus_connect_irq(gicbusdev, i, qdev_get_gpio_in(cpudev, ARM_CPU_IRQ));
sysbus_connect_irq(gicbusdev, i + smp_cpus,
qdev_get_gpio_in(cpudev, ARM_CPU_FIQ));
sysbus_connect_irq(gicbusdev, i + 2 * smp_cpus,
qdev_get_gpio_in(cpudev, ARM_CPU_VIRQ));
sysbus_connect_irq(gicbusdev, i + 3 * smp_cpus,
qdev_get_gpio_in(cpudev, ARM_CPU_VFIQ));
}
for (i = 0; i < NUM_IRQS; i++) {
pic[i] = qdev_get_gpio_in(gicdev, i);
}
fdt_add_gic_node(vms);
if (type == 3 && vms->its) {
create_its(vms, gicdev);
} else if (type == 2) {
create_v2m(vms, pic);
}
}
static void create_uart(const VirtMachineState *vms, qemu_irq *pic, int uart,
MemoryRegion *mem, Chardev *chr)
{
char *nodename;
hwaddr base = vms->memmap[uart].base;
hwaddr size = vms->memmap[uart].size;
int irq = vms->irqmap[uart];
const char compat[] = "arm,pl011\0arm,primecell";
const char clocknames[] = "uartclk\0apb_pclk";
DeviceState *dev = qdev_create(NULL, "pl011");
SysBusDevice *s = SYS_BUS_DEVICE(dev);
qdev_prop_set_chr(dev, "chardev", chr);
qdev_init_nofail(dev);
memory_region_add_subregion(mem, base,
sysbus_mmio_get_region(s, 0));
sysbus_connect_irq(s, 0, pic[irq]);
nodename = g_strdup_printf("/pl011@%" PRIx64, base);
qemu_fdt_add_subnode(vms->fdt, nodename);
/* Note that we can't use setprop_string because of the embedded NUL */
qemu_fdt_setprop(vms->fdt, nodename, "compatible",
compat, sizeof(compat));
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, base, 2, size);
qemu_fdt_setprop_cells(vms->fdt, nodename, "interrupts",
GIC_FDT_IRQ_TYPE_SPI, irq,
GIC_FDT_IRQ_FLAGS_LEVEL_HI);
qemu_fdt_setprop_cells(vms->fdt, nodename, "clocks",
vms->clock_phandle, vms->clock_phandle);
qemu_fdt_setprop(vms->fdt, nodename, "clock-names",
clocknames, sizeof(clocknames));
if (uart == VIRT_UART) {
qemu_fdt_setprop_string(vms->fdt, "/chosen", "stdout-path", nodename);
} else {
/* Mark as not usable by the normal world */
qemu_fdt_setprop_string(vms->fdt, nodename, "status", "disabled");
qemu_fdt_setprop_string(vms->fdt, nodename, "secure-status", "okay");
qemu_fdt_add_subnode(vms->fdt, "/secure-chosen");
qemu_fdt_setprop_string(vms->fdt, "/secure-chosen", "stdout-path",
nodename);
}
g_free(nodename);
}
static void create_rtc(const VirtMachineState *vms, qemu_irq *pic)
{
char *nodename;
hwaddr base = vms->memmap[VIRT_RTC].base;
hwaddr size = vms->memmap[VIRT_RTC].size;
int irq = vms->irqmap[VIRT_RTC];
const char compat[] = "arm,pl031\0arm,primecell";
sysbus_create_simple("pl031", base, pic[irq]);
nodename = g_strdup_printf("/pl031@%" PRIx64, base);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop(vms->fdt, nodename, "compatible", compat, sizeof(compat));
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, base, 2, size);
qemu_fdt_setprop_cells(vms->fdt, nodename, "interrupts",
GIC_FDT_IRQ_TYPE_SPI, irq,
GIC_FDT_IRQ_FLAGS_LEVEL_HI);
qemu_fdt_setprop_cell(vms->fdt, nodename, "clocks", vms->clock_phandle);
qemu_fdt_setprop_string(vms->fdt, nodename, "clock-names", "apb_pclk");
g_free(nodename);
}
static DeviceState *gpio_key_dev;
static void virt_powerdown_req(Notifier *n, void *opaque)
{
VirtMachineState *s = container_of(n, VirtMachineState, powerdown_notifier);
if (s->acpi_dev) {
acpi_send_event(s->acpi_dev, ACPI_POWER_DOWN_STATUS);
} else {
/* use gpio Pin 3 for power button event */
qemu_set_irq(qdev_get_gpio_in(gpio_key_dev, 0), 1);
}
}
static void create_gpio(const VirtMachineState *vms, qemu_irq *pic)
{
char *nodename;
DeviceState *pl061_dev;
hwaddr base = vms->memmap[VIRT_GPIO].base;
hwaddr size = vms->memmap[VIRT_GPIO].size;
int irq = vms->irqmap[VIRT_GPIO];
const char compat[] = "arm,pl061\0arm,primecell";
pl061_dev = sysbus_create_simple("pl061", base, pic[irq]);
uint32_t phandle = qemu_fdt_alloc_phandle(vms->fdt);
nodename = g_strdup_printf("/pl061@%" PRIx64, base);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, base, 2, size);
qemu_fdt_setprop(vms->fdt, nodename, "compatible", compat, sizeof(compat));
qemu_fdt_setprop_cell(vms->fdt, nodename, "#gpio-cells", 2);
qemu_fdt_setprop(vms->fdt, nodename, "gpio-controller", NULL, 0);
qemu_fdt_setprop_cells(vms->fdt, nodename, "interrupts",
GIC_FDT_IRQ_TYPE_SPI, irq,
GIC_FDT_IRQ_FLAGS_LEVEL_HI);
qemu_fdt_setprop_cell(vms->fdt, nodename, "clocks", vms->clock_phandle);
qemu_fdt_setprop_string(vms->fdt, nodename, "clock-names", "apb_pclk");
qemu_fdt_setprop_cell(vms->fdt, nodename, "phandle", phandle);
gpio_key_dev = sysbus_create_simple("gpio-key", -1,
qdev_get_gpio_in(pl061_dev, 3));
qemu_fdt_add_subnode(vms->fdt, "/gpio-keys");
qemu_fdt_setprop_string(vms->fdt, "/gpio-keys", "compatible", "gpio-keys");
qemu_fdt_setprop_cell(vms->fdt, "/gpio-keys", "#size-cells", 0);
qemu_fdt_setprop_cell(vms->fdt, "/gpio-keys", "#address-cells", 1);
qemu_fdt_add_subnode(vms->fdt, "/gpio-keys/poweroff");
qemu_fdt_setprop_string(vms->fdt, "/gpio-keys/poweroff",
"label", "GPIO Key Poweroff");
qemu_fdt_setprop_cell(vms->fdt, "/gpio-keys/poweroff", "linux,code",
KEY_POWER);
qemu_fdt_setprop_cells(vms->fdt, "/gpio-keys/poweroff",
"gpios", phandle, 3, 0);
g_free(nodename);
}
static void create_virtio_devices(const VirtMachineState *vms, qemu_irq *pic)
{
int i;
hwaddr size = vms->memmap[VIRT_MMIO].size;
/* We create the transports in forwards order. Since qbus_realize()
* prepends (not appends) new child buses, the incrementing loop below will
* create a list of virtio-mmio buses with decreasing base addresses.
*
* When a -device option is processed from the command line,
* qbus_find_recursive() picks the next free virtio-mmio bus in forwards
* order. The upshot is that -device options in increasing command line
* order are mapped to virtio-mmio buses with decreasing base addresses.
*
* When this code was originally written, that arrangement ensured that the
* guest Linux kernel would give the lowest "name" (/dev/vda, eth0, etc) to
* the first -device on the command line. (The end-to-end order is a
* function of this loop, qbus_realize(), qbus_find_recursive(), and the
* guest kernel's name-to-address assignment strategy.)
*
* Meanwhile, the kernel's traversal seems to have been reversed; see eg.
* the message, if not necessarily the code, of commit 70161ff336.
* Therefore the loop now establishes the inverse of the original intent.
*
* Unfortunately, we can't counteract the kernel change by reversing the
* loop; it would break existing command lines.
*
* In any case, the kernel makes no guarantee about the stability of
* enumeration order of virtio devices (as demonstrated by it changing
* between kernel versions). For reliable and stable identification
* of disks users must use UUIDs or similar mechanisms.
*/
for (i = 0; i < NUM_VIRTIO_TRANSPORTS; i++) {
int irq = vms->irqmap[VIRT_MMIO] + i;
hwaddr base = vms->memmap[VIRT_MMIO].base + i * size;
sysbus_create_simple("virtio-mmio", base, pic[irq]);
}
/* We add dtb nodes in reverse order so that they appear in the finished
* device tree lowest address first.
*
* Note that this mapping is independent of the loop above. The previous
* loop influences virtio device to virtio transport assignment, whereas
* this loop controls how virtio transports are laid out in the dtb.
*/
for (i = NUM_VIRTIO_TRANSPORTS - 1; i >= 0; i--) {
char *nodename;
int irq = vms->irqmap[VIRT_MMIO] + i;
hwaddr base = vms->memmap[VIRT_MMIO].base + i * size;
nodename = g_strdup_printf("/virtio_mmio@%" PRIx64, base);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename,
"compatible", "virtio,mmio");
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, base, 2, size);
qemu_fdt_setprop_cells(vms->fdt, nodename, "interrupts",
GIC_FDT_IRQ_TYPE_SPI, irq,
GIC_FDT_IRQ_FLAGS_EDGE_LO_HI);
qemu_fdt_setprop(vms->fdt, nodename, "dma-coherent", NULL, 0);
g_free(nodename);
}
}
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
#define VIRT_FLASH_SECTOR_SIZE (256 * KiB)
static PFlashCFI01 *virt_flash_create1(VirtMachineState *vms,
const char *name,
const char *alias_prop_name)
{
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
/*
* Create a single flash device. We use the same parameters as
* the flash devices on the Versatile Express board.
*/
DeviceState *dev = qdev_create(NULL, TYPE_PFLASH_CFI01);
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
qdev_prop_set_uint64(dev, "sector-length", VIRT_FLASH_SECTOR_SIZE);
qdev_prop_set_uint8(dev, "width", 4);
qdev_prop_set_uint8(dev, "device-width", 2);
qdev_prop_set_bit(dev, "big-endian", false);
qdev_prop_set_uint16(dev, "id0", 0x89);
qdev_prop_set_uint16(dev, "id1", 0x18);
qdev_prop_set_uint16(dev, "id2", 0x00);
qdev_prop_set_uint16(dev, "id3", 0x00);
qdev_prop_set_string(dev, "name", name);
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
object_property_add_child(OBJECT(vms), name, OBJECT(dev),
&error_abort);
object_property_add_alias(OBJECT(vms), alias_prop_name,
OBJECT(dev), "drive", &error_abort);
return PFLASH_CFI01(dev);
}
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
static void virt_flash_create(VirtMachineState *vms)
{
vms->flash[0] = virt_flash_create1(vms, "virt.flash0", "pflash0");
vms->flash[1] = virt_flash_create1(vms, "virt.flash1", "pflash1");
}
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
static void virt_flash_map1(PFlashCFI01 *flash,
hwaddr base, hwaddr size,
MemoryRegion *sysmem)
{
DeviceState *dev = DEVICE(flash);
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
assert(size % VIRT_FLASH_SECTOR_SIZE == 0);
assert(size / VIRT_FLASH_SECTOR_SIZE <= UINT32_MAX);
qdev_prop_set_uint32(dev, "num-blocks", size / VIRT_FLASH_SECTOR_SIZE);
qdev_init_nofail(dev);
memory_region_add_subregion(sysmem, base,
sysbus_mmio_get_region(SYS_BUS_DEVICE(dev),
0));
}
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
static void virt_flash_map(VirtMachineState *vms,
MemoryRegion *sysmem,
MemoryRegion *secure_sysmem)
{
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
/*
* Map two flash devices to fill the VIRT_FLASH space in the memmap.
* sysmem is the system memory space. secure_sysmem is the secure view
* of the system, and the first flash device should be made visible only
* there. The second flash device is visible to both secure and nonsecure.
* If sysmem == secure_sysmem this means there is no separate Secure
* address space and both flash devices are generally visible.
*/
hwaddr flashsize = vms->memmap[VIRT_FLASH].size / 2;
hwaddr flashbase = vms->memmap[VIRT_FLASH].base;
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
virt_flash_map1(vms->flash[0], flashbase, flashsize,
secure_sysmem);
virt_flash_map1(vms->flash[1], flashbase + flashsize, flashsize,
sysmem);
}
static void virt_flash_fdt(VirtMachineState *vms,
MemoryRegion *sysmem,
MemoryRegion *secure_sysmem)
{
hwaddr flashsize = vms->memmap[VIRT_FLASH].size / 2;
hwaddr flashbase = vms->memmap[VIRT_FLASH].base;
char *nodename;
if (sysmem == secure_sysmem) {
/* Report both flash devices as a single node in the DT */
nodename = g_strdup_printf("/flash@%" PRIx64, flashbase);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename, "compatible", "cfi-flash");
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, flashbase, 2, flashsize,
2, flashbase + flashsize, 2, flashsize);
qemu_fdt_setprop_cell(vms->fdt, nodename, "bank-width", 4);
g_free(nodename);
} else {
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
/*
* Report the devices as separate nodes so we can mark one as
* only visible to the secure world.
*/
nodename = g_strdup_printf("/secflash@%" PRIx64, flashbase);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename, "compatible", "cfi-flash");
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, flashbase, 2, flashsize);
qemu_fdt_setprop_cell(vms->fdt, nodename, "bank-width", 4);
qemu_fdt_setprop_string(vms->fdt, nodename, "status", "disabled");
qemu_fdt_setprop_string(vms->fdt, nodename, "secure-status", "okay");
g_free(nodename);
nodename = g_strdup_printf("/flash@%" PRIx64, flashbase);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename, "compatible", "cfi-flash");
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, flashbase + flashsize, 2, flashsize);
qemu_fdt_setprop_cell(vms->fdt, nodename, "bank-width", 4);
g_free(nodename);
}
}
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
static bool virt_firmware_init(VirtMachineState *vms,
MemoryRegion *sysmem,
MemoryRegion *secure_sysmem)
{
int i;
BlockBackend *pflash_blk0;
/* Map legacy -drive if=pflash to machine properties */
for (i = 0; i < ARRAY_SIZE(vms->flash); i++) {
pflash_cfi01_legacy_drive(vms->flash[i],
drive_get(IF_PFLASH, 0, i));
}
virt_flash_map(vms, sysmem, secure_sysmem);
pflash_blk0 = pflash_cfi01_get_blk(vms->flash[0]);
if (bios_name) {
char *fname;
MemoryRegion *mr;
int image_size;
if (pflash_blk0) {
error_report("The contents of the first flash device may be "
"specified with -bios or with -drive if=pflash... "
"but you cannot use both options at once");
exit(1);
}
/* Fall back to -bios */
fname = qemu_find_file(QEMU_FILE_TYPE_BIOS, bios_name);
if (!fname) {
error_report("Could not find ROM image '%s'", bios_name);
exit(1);
}
mr = sysbus_mmio_get_region(SYS_BUS_DEVICE(vms->flash[0]), 0);
image_size = load_image_mr(fname, mr);
g_free(fname);
if (image_size < 0) {
error_report("Could not load ROM image '%s'", bios_name);
exit(1);
}
}
return pflash_blk0 || bios_name;
}
static FWCfgState *create_fw_cfg(const VirtMachineState *vms, AddressSpace *as)
{
MachineState *ms = MACHINE(vms);
hwaddr base = vms->memmap[VIRT_FW_CFG].base;
hwaddr size = vms->memmap[VIRT_FW_CFG].size;
FWCfgState *fw_cfg;
char *nodename;
fw_cfg = fw_cfg_init_mem_wide(base + 8, base, 8, base + 16, as);
fw_cfg_add_i16(fw_cfg, FW_CFG_NB_CPUS, (uint16_t)ms->smp.cpus);
nodename = g_strdup_printf("/fw-cfg@%" PRIx64, base);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename,
"compatible", "qemu,fw-cfg-mmio");
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, base, 2, size);
qemu_fdt_setprop(vms->fdt, nodename, "dma-coherent", NULL, 0);
g_free(nodename);
return fw_cfg;
}
static void create_pcie_irq_map(const VirtMachineState *vms,
uint32_t gic_phandle,
int first_irq, const char *nodename)
{
int devfn, pin;
uint32_t full_irq_map[4 * 4 * 10] = { 0 };
uint32_t *irq_map = full_irq_map;
for (devfn = 0; devfn <= 0x18; devfn += 0x8) {
for (pin = 0; pin < 4; pin++) {
int irq_type = GIC_FDT_IRQ_TYPE_SPI;
int irq_nr = first_irq + ((pin + PCI_SLOT(devfn)) % PCI_NUM_PINS);
int irq_level = GIC_FDT_IRQ_FLAGS_LEVEL_HI;
int i;
uint32_t map[] = {
devfn << 8, 0, 0, /* devfn */
pin + 1, /* PCI pin */
gic_phandle, 0, 0, irq_type, irq_nr, irq_level }; /* GIC irq */
/* Convert map to big endian */
for (i = 0; i < 10; i++) {
irq_map[i] = cpu_to_be32(map[i]);
}
irq_map += 10;
}
}
qemu_fdt_setprop(vms->fdt, nodename, "interrupt-map",
full_irq_map, sizeof(full_irq_map));
qemu_fdt_setprop_cells(vms->fdt, nodename, "interrupt-map-mask",
0x1800, 0, 0, /* devfn (PCI_SLOT(3)) */
0x7 /* PCI irq */);
}
static void create_smmu(const VirtMachineState *vms, qemu_irq *pic,
PCIBus *bus)
{
char *node;
const char compat[] = "arm,smmu-v3";
int irq = vms->irqmap[VIRT_SMMU];
int i;
hwaddr base = vms->memmap[VIRT_SMMU].base;
hwaddr size = vms->memmap[VIRT_SMMU].size;
const char irq_names[] = "eventq\0priq\0cmdq-sync\0gerror";
DeviceState *dev;
if (vms->iommu != VIRT_IOMMU_SMMUV3 || !vms->iommu_phandle) {
return;
}
dev = qdev_create(NULL, "arm-smmuv3");
object_property_set_link(OBJECT(dev), OBJECT(bus), "primary-bus",
&error_abort);
qdev_init_nofail(dev);
sysbus_mmio_map(SYS_BUS_DEVICE(dev), 0, base);
for (i = 0; i < NUM_SMMU_IRQS; i++) {
sysbus_connect_irq(SYS_BUS_DEVICE(dev), i, pic[irq + i]);
}
node = g_strdup_printf("/smmuv3@%" PRIx64, base);
qemu_fdt_add_subnode(vms->fdt, node);
qemu_fdt_setprop(vms->fdt, node, "compatible", compat, sizeof(compat));
qemu_fdt_setprop_sized_cells(vms->fdt, node, "reg", 2, base, 2, size);
qemu_fdt_setprop_cells(vms->fdt, node, "interrupts",
GIC_FDT_IRQ_TYPE_SPI, irq , GIC_FDT_IRQ_FLAGS_EDGE_LO_HI,
GIC_FDT_IRQ_TYPE_SPI, irq + 1, GIC_FDT_IRQ_FLAGS_EDGE_LO_HI,
GIC_FDT_IRQ_TYPE_SPI, irq + 2, GIC_FDT_IRQ_FLAGS_EDGE_LO_HI,
GIC_FDT_IRQ_TYPE_SPI, irq + 3, GIC_FDT_IRQ_FLAGS_EDGE_LO_HI);
qemu_fdt_setprop(vms->fdt, node, "interrupt-names", irq_names,
sizeof(irq_names));
qemu_fdt_setprop_cell(vms->fdt, node, "clocks", vms->clock_phandle);
qemu_fdt_setprop_string(vms->fdt, node, "clock-names", "apb_pclk");
qemu_fdt_setprop(vms->fdt, node, "dma-coherent", NULL, 0);
qemu_fdt_setprop_cell(vms->fdt, node, "#iommu-cells", 1);
qemu_fdt_setprop_cell(vms->fdt, node, "phandle", vms->iommu_phandle);
g_free(node);
}
static void create_pcie(VirtMachineState *vms, qemu_irq *pic)
{
hwaddr base_mmio = vms->memmap[VIRT_PCIE_MMIO].base;
hwaddr size_mmio = vms->memmap[VIRT_PCIE_MMIO].size;
hwaddr base_mmio_high = vms->memmap[VIRT_HIGH_PCIE_MMIO].base;
hwaddr size_mmio_high = vms->memmap[VIRT_HIGH_PCIE_MMIO].size;
hwaddr base_pio = vms->memmap[VIRT_PCIE_PIO].base;
hwaddr size_pio = vms->memmap[VIRT_PCIE_PIO].size;
hwaddr base_ecam, size_ecam;
hwaddr base = base_mmio;
int nr_pcie_buses;
int irq = vms->irqmap[VIRT_PCIE];
MemoryRegion *mmio_alias;
MemoryRegion *mmio_reg;
MemoryRegion *ecam_alias;
MemoryRegion *ecam_reg;
DeviceState *dev;
char *nodename;
int i, ecam_id;
PCIHostState *pci;
dev = qdev_create(NULL, TYPE_GPEX_HOST);
qdev_init_nofail(dev);
ecam_id = VIRT_ECAM_ID(vms->highmem_ecam);
base_ecam = vms->memmap[ecam_id].base;
size_ecam = vms->memmap[ecam_id].size;
nr_pcie_buses = size_ecam / PCIE_MMCFG_SIZE_MIN;
/* Map only the first size_ecam bytes of ECAM space */
ecam_alias = g_new0(MemoryRegion, 1);
ecam_reg = sysbus_mmio_get_region(SYS_BUS_DEVICE(dev), 0);
memory_region_init_alias(ecam_alias, OBJECT(dev), "pcie-ecam",
ecam_reg, 0, size_ecam);
memory_region_add_subregion(get_system_memory(), base_ecam, ecam_alias);
/* Map the MMIO window into system address space so as to expose
* the section of PCI MMIO space which starts at the same base address
* (ie 1:1 mapping for that part of PCI MMIO space visible through
* the window).
*/
mmio_alias = g_new0(MemoryRegion, 1);
mmio_reg = sysbus_mmio_get_region(SYS_BUS_DEVICE(dev), 1);
memory_region_init_alias(mmio_alias, OBJECT(dev), "pcie-mmio",
mmio_reg, base_mmio, size_mmio);
memory_region_add_subregion(get_system_memory(), base_mmio, mmio_alias);
if (vms->highmem) {
/* Map high MMIO space */
MemoryRegion *high_mmio_alias = g_new0(MemoryRegion, 1);
memory_region_init_alias(high_mmio_alias, OBJECT(dev), "pcie-mmio-high",
mmio_reg, base_mmio_high, size_mmio_high);
memory_region_add_subregion(get_system_memory(), base_mmio_high,
high_mmio_alias);
}
/* Map IO port space */
sysbus_mmio_map(SYS_BUS_DEVICE(dev), 2, base_pio);
for (i = 0; i < GPEX_NUM_IRQS; i++) {
sysbus_connect_irq(SYS_BUS_DEVICE(dev), i, pic[irq + i]);
gpex_set_irq_num(GPEX_HOST(dev), i, irq + i);
}
pci = PCI_HOST_BRIDGE(dev);
if (pci->bus) {
for (i = 0; i < nb_nics; i++) {
NICInfo *nd = &nd_table[i];
if (!nd->model) {
nd->model = g_strdup("virtio");
}
pci_nic_init_nofail(nd, pci->bus, nd->model, NULL);
}
}
nodename = g_strdup_printf("/pcie@%" PRIx64, base);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename,
"compatible", "pci-host-ecam-generic");
qemu_fdt_setprop_string(vms->fdt, nodename, "device_type", "pci");
qemu_fdt_setprop_cell(vms->fdt, nodename, "#address-cells", 3);
qemu_fdt_setprop_cell(vms->fdt, nodename, "#size-cells", 2);
qemu_fdt_setprop_cell(vms->fdt, nodename, "linux,pci-domain", 0);
qemu_fdt_setprop_cells(vms->fdt, nodename, "bus-range", 0,
nr_pcie_buses - 1);
qemu_fdt_setprop(vms->fdt, nodename, "dma-coherent", NULL, 0);
if (vms->msi_phandle) {
qemu_fdt_setprop_cells(vms->fdt, nodename, "msi-parent",
vms->msi_phandle);
}
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg",
2, base_ecam, 2, size_ecam);
if (vms->highmem) {
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "ranges",
1, FDT_PCI_RANGE_IOPORT, 2, 0,
2, base_pio, 2, size_pio,
1, FDT_PCI_RANGE_MMIO, 2, base_mmio,
2, base_mmio, 2, size_mmio,
1, FDT_PCI_RANGE_MMIO_64BIT,
2, base_mmio_high,
2, base_mmio_high, 2, size_mmio_high);
} else {
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "ranges",
1, FDT_PCI_RANGE_IOPORT, 2, 0,
2, base_pio, 2, size_pio,
1, FDT_PCI_RANGE_MMIO, 2, base_mmio,
2, base_mmio, 2, size_mmio);
}
qemu_fdt_setprop_cell(vms->fdt, nodename, "#interrupt-cells", 1);
create_pcie_irq_map(vms, vms->gic_phandle, irq, nodename);
if (vms->iommu) {
vms->iommu_phandle = qemu_fdt_alloc_phandle(vms->fdt);
create_smmu(vms, pic, pci->bus);
qemu_fdt_setprop_cells(vms->fdt, nodename, "iommu-map",
0x0, vms->iommu_phandle, 0x0, 0x10000);
}
g_free(nodename);
}
static void create_platform_bus(VirtMachineState *vms, qemu_irq *pic)
{
DeviceState *dev;
SysBusDevice *s;
int i;
MemoryRegion *sysmem = get_system_memory();
dev = qdev_create(NULL, TYPE_PLATFORM_BUS_DEVICE);
dev->id = TYPE_PLATFORM_BUS_DEVICE;
arm/boot: split load_dtb() from arm_load_kernel() load_dtb() depends on arm_load_kernel() to figure out place in RAM where it should be loaded, but it's not required for arm_load_kernel() to work. Sometimes it's neccesary for devices added with -device/device_add to be enumerated in DTB as well, which's lead to [1] and surrounding commits to add 2 more machine_done notifiers with non obvious ordering to make dynamic sysbus devices initialization happen in the right order. However instead of moving whole arm_load_kernel() in to machine_done, it's sufficient to move only load_dtb() into virt_machine_done() notifier and remove ArmLoadKernelNotifier/ /PlatformBusFDTNotifierParams notifiers, which saves us ~90LOC and simplifies code flow quite a bit. Later would allow to consolidate DTB generation within one function for 'mach-virt' board and make it reentrant so it could generate updated DTB in device hotplug secenarios. While at it rename load_dtb() to arm_load_dtb() since it's public now. Add additional field skip_dtb_autoload to struct arm_boot_info to allow manual DTB load later in mach-virt and to avoid touching all other boards to explicitly call arm_load_dtb(). 1) (ac9d32e hw/arm/boot: arm_load_kernel implemented as a machine init done notifier) Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Reviewed-by: Andrew Jones <drjones@redhat.com> Message-id: 1525691524-32265-4-git-send-email-imammedo@redhat.com Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2018-05-11 01:10:56 +08:00
qdev_prop_set_uint32(dev, "num_irqs", PLATFORM_BUS_NUM_IRQS);
qdev_prop_set_uint32(dev, "mmio_size", vms->memmap[VIRT_PLATFORM_BUS].size);
qdev_init_nofail(dev);
vms->platform_bus_dev = dev;
arm/boot: split load_dtb() from arm_load_kernel() load_dtb() depends on arm_load_kernel() to figure out place in RAM where it should be loaded, but it's not required for arm_load_kernel() to work. Sometimes it's neccesary for devices added with -device/device_add to be enumerated in DTB as well, which's lead to [1] and surrounding commits to add 2 more machine_done notifiers with non obvious ordering to make dynamic sysbus devices initialization happen in the right order. However instead of moving whole arm_load_kernel() in to machine_done, it's sufficient to move only load_dtb() into virt_machine_done() notifier and remove ArmLoadKernelNotifier/ /PlatformBusFDTNotifierParams notifiers, which saves us ~90LOC and simplifies code flow quite a bit. Later would allow to consolidate DTB generation within one function for 'mach-virt' board and make it reentrant so it could generate updated DTB in device hotplug secenarios. While at it rename load_dtb() to arm_load_dtb() since it's public now. Add additional field skip_dtb_autoload to struct arm_boot_info to allow manual DTB load later in mach-virt and to avoid touching all other boards to explicitly call arm_load_dtb(). 1) (ac9d32e hw/arm/boot: arm_load_kernel implemented as a machine init done notifier) Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Reviewed-by: Andrew Jones <drjones@redhat.com> Message-id: 1525691524-32265-4-git-send-email-imammedo@redhat.com Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2018-05-11 01:10:56 +08:00
s = SYS_BUS_DEVICE(dev);
for (i = 0; i < PLATFORM_BUS_NUM_IRQS; i++) {
int irqn = vms->irqmap[VIRT_PLATFORM_BUS] + i;
sysbus_connect_irq(s, i, pic[irqn]);
}
memory_region_add_subregion(sysmem,
arm/boot: split load_dtb() from arm_load_kernel() load_dtb() depends on arm_load_kernel() to figure out place in RAM where it should be loaded, but it's not required for arm_load_kernel() to work. Sometimes it's neccesary for devices added with -device/device_add to be enumerated in DTB as well, which's lead to [1] and surrounding commits to add 2 more machine_done notifiers with non obvious ordering to make dynamic sysbus devices initialization happen in the right order. However instead of moving whole arm_load_kernel() in to machine_done, it's sufficient to move only load_dtb() into virt_machine_done() notifier and remove ArmLoadKernelNotifier/ /PlatformBusFDTNotifierParams notifiers, which saves us ~90LOC and simplifies code flow quite a bit. Later would allow to consolidate DTB generation within one function for 'mach-virt' board and make it reentrant so it could generate updated DTB in device hotplug secenarios. While at it rename load_dtb() to arm_load_dtb() since it's public now. Add additional field skip_dtb_autoload to struct arm_boot_info to allow manual DTB load later in mach-virt and to avoid touching all other boards to explicitly call arm_load_dtb(). 1) (ac9d32e hw/arm/boot: arm_load_kernel implemented as a machine init done notifier) Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Reviewed-by: Andrew Jones <drjones@redhat.com> Message-id: 1525691524-32265-4-git-send-email-imammedo@redhat.com Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2018-05-11 01:10:56 +08:00
vms->memmap[VIRT_PLATFORM_BUS].base,
sysbus_mmio_get_region(s, 0));
}
static void create_secure_ram(VirtMachineState *vms,
MemoryRegion *secure_sysmem)
{
MemoryRegion *secram = g_new(MemoryRegion, 1);
char *nodename;
hwaddr base = vms->memmap[VIRT_SECURE_MEM].base;
hwaddr size = vms->memmap[VIRT_SECURE_MEM].size;
memory_region_init_ram(secram, NULL, "virt.secure-ram", size,
&error_fatal);
memory_region_add_subregion(secure_sysmem, base, secram);
nodename = g_strdup_printf("/secram@%" PRIx64, base);
qemu_fdt_add_subnode(vms->fdt, nodename);
qemu_fdt_setprop_string(vms->fdt, nodename, "device_type", "memory");
qemu_fdt_setprop_sized_cells(vms->fdt, nodename, "reg", 2, base, 2, size);
qemu_fdt_setprop_string(vms->fdt, nodename, "status", "disabled");
qemu_fdt_setprop_string(vms->fdt, nodename, "secure-status", "okay");
g_free(nodename);
}
static void *machvirt_dtb(const struct arm_boot_info *binfo, int *fdt_size)
{
const VirtMachineState *board = container_of(binfo, VirtMachineState,
bootinfo);
*fdt_size = board->fdt_size;
return board->fdt;
}
static void virt_build_smbios(VirtMachineState *vms)
{
MachineClass *mc = MACHINE_GET_CLASS(vms);
VirtMachineClass *vmc = VIRT_MACHINE_GET_CLASS(vms);
uint8_t *smbios_tables, *smbios_anchor;
size_t smbios_tables_len, smbios_anchor_len;
const char *product = "QEMU Virtual Machine";
if (kvm_enabled()) {
product = "KVM Virtual Machine";
}
smbios_set_defaults("QEMU", product,
vmc->smbios_old_sys_ver ? "1.0" : mc->name, false,
true, SMBIOS_ENTRY_POINT_30);
smbios_get_tables(MACHINE(vms), NULL, 0, &smbios_tables, &smbios_tables_len,
&smbios_anchor, &smbios_anchor_len);
if (smbios_anchor) {
fw_cfg_add_file(vms->fw_cfg, "etc/smbios/smbios-tables",
smbios_tables, smbios_tables_len);
fw_cfg_add_file(vms->fw_cfg, "etc/smbios/smbios-anchor",
smbios_anchor, smbios_anchor_len);
}
}
static
void virt_machine_done(Notifier *notifier, void *data)
{
VirtMachineState *vms = container_of(notifier, VirtMachineState,
machine_done);
MachineState *ms = MACHINE(vms);
arm/boot: split load_dtb() from arm_load_kernel() load_dtb() depends on arm_load_kernel() to figure out place in RAM where it should be loaded, but it's not required for arm_load_kernel() to work. Sometimes it's neccesary for devices added with -device/device_add to be enumerated in DTB as well, which's lead to [1] and surrounding commits to add 2 more machine_done notifiers with non obvious ordering to make dynamic sysbus devices initialization happen in the right order. However instead of moving whole arm_load_kernel() in to machine_done, it's sufficient to move only load_dtb() into virt_machine_done() notifier and remove ArmLoadKernelNotifier/ /PlatformBusFDTNotifierParams notifiers, which saves us ~90LOC and simplifies code flow quite a bit. Later would allow to consolidate DTB generation within one function for 'mach-virt' board and make it reentrant so it could generate updated DTB in device hotplug secenarios. While at it rename load_dtb() to arm_load_dtb() since it's public now. Add additional field skip_dtb_autoload to struct arm_boot_info to allow manual DTB load later in mach-virt and to avoid touching all other boards to explicitly call arm_load_dtb(). 1) (ac9d32e hw/arm/boot: arm_load_kernel implemented as a machine init done notifier) Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Reviewed-by: Andrew Jones <drjones@redhat.com> Message-id: 1525691524-32265-4-git-send-email-imammedo@redhat.com Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2018-05-11 01:10:56 +08:00
ARMCPU *cpu = ARM_CPU(first_cpu);
struct arm_boot_info *info = &vms->bootinfo;
AddressSpace *as = arm_boot_address_space(cpu, info);
/*
* If the user provided a dtb, we assume the dynamic sysbus nodes
* already are integrated there. This corresponds to a use case where
* the dynamic sysbus nodes are complex and their generation is not yet
* supported. In that case the user can take charge of the guest dt
* while qemu takes charge of the qom stuff.
*/
if (info->dtb_filename == NULL) {
platform_bus_add_all_fdt_nodes(vms->fdt, "/intc",
vms->memmap[VIRT_PLATFORM_BUS].base,
vms->memmap[VIRT_PLATFORM_BUS].size,
vms->irqmap[VIRT_PLATFORM_BUS]);
}
if (arm_load_dtb(info->dtb_start, info, info->dtb_limit, as, ms) < 0) {
arm/boot: split load_dtb() from arm_load_kernel() load_dtb() depends on arm_load_kernel() to figure out place in RAM where it should be loaded, but it's not required for arm_load_kernel() to work. Sometimes it's neccesary for devices added with -device/device_add to be enumerated in DTB as well, which's lead to [1] and surrounding commits to add 2 more machine_done notifiers with non obvious ordering to make dynamic sysbus devices initialization happen in the right order. However instead of moving whole arm_load_kernel() in to machine_done, it's sufficient to move only load_dtb() into virt_machine_done() notifier and remove ArmLoadKernelNotifier/ /PlatformBusFDTNotifierParams notifiers, which saves us ~90LOC and simplifies code flow quite a bit. Later would allow to consolidate DTB generation within one function for 'mach-virt' board and make it reentrant so it could generate updated DTB in device hotplug secenarios. While at it rename load_dtb() to arm_load_dtb() since it's public now. Add additional field skip_dtb_autoload to struct arm_boot_info to allow manual DTB load later in mach-virt and to avoid touching all other boards to explicitly call arm_load_dtb(). 1) (ac9d32e hw/arm/boot: arm_load_kernel implemented as a machine init done notifier) Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Reviewed-by: Andrew Jones <drjones@redhat.com> Message-id: 1525691524-32265-4-git-send-email-imammedo@redhat.com Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2018-05-11 01:10:56 +08:00
exit(1);
}
virt_acpi_setup(vms);
virt_build_smbios(vms);
}
static uint64_t virt_cpu_mp_affinity(VirtMachineState *vms, int idx)
{
uint8_t clustersz = ARM_DEFAULT_CPUS_PER_CLUSTER;
VirtMachineClass *vmc = VIRT_MACHINE_GET_CLASS(vms);
if (!vmc->disallow_affinity_adjustment) {
/* Adjust MPIDR like 64-bit KVM hosts, which incorporate the
* GIC's target-list limitations. 32-bit KVM hosts currently
* always create clusters of 4 CPUs, but that is expected to
* change when they gain support for gicv3. When KVM is enabled
* it will override the changes we make here, therefore our
* purposes are to make TCG consistent (with 64-bit KVM hosts)
* and to improve SGI efficiency.
*/
if (vms->gic_version == 3) {
clustersz = GICV3_TARGETLIST_BITS;
} else {
clustersz = GIC_TARGETLIST_BITS;
}
}
return arm_cpu_mp_affinity(idx, clustersz);
}
static void virt_set_memmap(VirtMachineState *vms)
{
MachineState *ms = MACHINE(vms);
hwaddr base, device_memory_base, device_memory_size;
int i;
vms->memmap = extended_memmap;
for (i = 0; i < ARRAY_SIZE(base_memmap); i++) {
vms->memmap[i] = base_memmap[i];
}
if (ms->ram_slots > ACPI_MAX_RAM_SLOTS) {
error_report("unsupported number of memory slots: %"PRIu64,
ms->ram_slots);
exit(EXIT_FAILURE);
}
/*
* We compute the base of the high IO region depending on the
* amount of initial and device memory. The device memory start/size
* is aligned on 1GiB. We never put the high IO region below 256GiB
* so that if maxram_size is < 255GiB we keep the legacy memory map.
* The device region size assumes 1GiB page max alignment per slot.
*/
device_memory_base =
ROUND_UP(vms->memmap[VIRT_MEM].base + ms->ram_size, GiB);
device_memory_size = ms->maxram_size - ms->ram_size + ms->ram_slots * GiB;
/* Base address of the high IO region */
base = device_memory_base + ROUND_UP(device_memory_size, GiB);
if (base < device_memory_base) {
error_report("maxmem/slots too huge");
exit(EXIT_FAILURE);
}
if (base < vms->memmap[VIRT_MEM].base + LEGACY_RAMLIMIT_BYTES) {
base = vms->memmap[VIRT_MEM].base + LEGACY_RAMLIMIT_BYTES;
}
for (i = VIRT_LOWMEMMAP_LAST; i < ARRAY_SIZE(extended_memmap); i++) {
hwaddr size = extended_memmap[i].size;
base = ROUND_UP(base, size);
vms->memmap[i].base = base;
vms->memmap[i].size = size;
base += size;
}
vms->highest_gpa = base - 1;
if (device_memory_size > 0) {
ms->device_memory = g_malloc0(sizeof(*ms->device_memory));
ms->device_memory->base = device_memory_base;
memory_region_init(&ms->device_memory->mr, OBJECT(vms),
"device-memory", device_memory_size);
}
}
static void machvirt_init(MachineState *machine)
{
VirtMachineState *vms = VIRT_MACHINE(machine);
VirtMachineClass *vmc = VIRT_MACHINE_GET_CLASS(machine);
MachineClass *mc = MACHINE_GET_CLASS(machine);
const CPUArchIdList *possible_cpus;
qemu_irq pic[NUM_IRQS];
MemoryRegion *sysmem = get_system_memory();
MemoryRegion *secure_sysmem = NULL;
int n, virt_max_cpus;
MemoryRegion *ram = g_new(MemoryRegion, 1);
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
bool firmware_loaded;
bool aarch64 = true;
bool has_ged = !vmc->no_ged;
unsigned int smp_cpus = machine->smp.cpus;
unsigned int max_cpus = machine->smp.max_cpus;
/*
* In accelerated mode, the memory map is computed earlier in kvm_type()
* to create a VM with the right number of IPA bits.
*/
if (!vms->memmap) {
virt_set_memmap(vms);
}
/* We can probe only here because during property set
* KVM is not available yet
*/
if (vms->gic_version <= 0) {
/* "host" or "max" */
if (!kvm_enabled()) {
if (vms->gic_version == 0) {
error_report("gic-version=host requires KVM");
exit(1);
} else {
/* "max": currently means 3 for TCG */
vms->gic_version = 3;
}
} else {
vms->gic_version = kvm_arm_vgic_probe();
if (!vms->gic_version) {
error_report(
"Unable to determine GIC version supported by host");
exit(1);
}
}
}
arm: drop intermediate cpu_model -> cpu type parsing and use cpu type directly there are 2 use cases to deal with: 1: fixed CPU models per board/soc 2: boards with user configurable cpu_model and fallback to default cpu_model if user hasn't specified one explicitly For the 1st drop intermediate cpu_model parsing and use const cpu type directly, which replaces: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) object_new(typename) with object_new(FOO_CPU_TYPE_NAME) or cpu_generic_init(BASE_CPU_TYPE, "my cpu model") with cpu_create(FOO_CPU_TYPE_NAME) as result 1st use case doesn't have to invoke not necessary translation and not needed code is removed. For the 2nd 1: set default cpu type with MachineClass::default_cpu_type and 2: use generic cpu_model parsing that done before machine_init() is run and: 2.1: drop custom cpu_model parsing where pattern is: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) [parse_features(typename, cpu_model, &err) ] 2.2: or replace cpu_generic_init() which does what 2.1 does + create_cpu(typename) with just create_cpu(machine->cpu_type) as result cpu_name -> cpu_type translation is done using generic machine code one including parsing optional features if supported/present (removes a bunch of duplicated cpu_model parsing code) and default cpu type is defined in an uniform way within machine_class_init callbacks instead of adhoc places in boadr's machine_init code. Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Eduardo Habkost <ehabkost@redhat.com> Message-Id: <1505318697-77161-6-git-send-email-imammedo@redhat.com> Reviewed-by: Alistair Francis <alistair.francis@xilinx.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Signed-off-by: Eduardo Habkost <ehabkost@redhat.com>
2017-09-14 00:04:57 +08:00
if (!cpu_type_valid(machine->cpu_type)) {
error_report("mach-virt: CPU type %s not supported", machine->cpu_type);
exit(1);
}
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
if (vms->secure) {
if (kvm_enabled()) {
error_report("mach-virt: KVM does not support Security extensions");
exit(1);
}
/*
* The Secure view of the world is the same as the NonSecure,
* but with a few extra devices. Create it as a container region
* containing the system memory at low priority; any secure-only
* devices go in at higher priority and take precedence.
*/
secure_sysmem = g_new(MemoryRegion, 1);
memory_region_init(secure_sysmem, OBJECT(machine), "secure-memory",
UINT64_MAX);
memory_region_add_subregion_overlap(secure_sysmem, 0, sysmem, -1);
}
firmware_loaded = virt_firmware_init(vms, sysmem,
secure_sysmem ?: sysmem);
/* If we have an EL3 boot ROM then the assumption is that it will
* implement PSCI itself, so disable QEMU's internal implementation
* so it doesn't get in the way. Instead of starting secondary
* CPUs in PSCI powerdown state we will start them all running and
* let the boot ROM sort them out.
* The usual case is that we do use QEMU's PSCI implementation;
* if the guest has EL2 then we will use SMC as the conduit,
* and otherwise we will use HVC (for backwards compatibility and
* because if we're using KVM then we must use HVC).
*/
if (vms->secure && firmware_loaded) {
vms->psci_conduit = QEMU_PSCI_CONDUIT_DISABLED;
} else if (vms->virt) {
vms->psci_conduit = QEMU_PSCI_CONDUIT_SMC;
} else {
vms->psci_conduit = QEMU_PSCI_CONDUIT_HVC;
}
/* The maximum number of CPUs depends on the GIC version, or on how
* many redistributors we can fit into the memory map.
*/
if (vms->gic_version == 3) {
virt_max_cpus =
vms->memmap[VIRT_GIC_REDIST].size / GICV3_REDIST_SIZE;
virt_max_cpus +=
vms->memmap[VIRT_HIGH_GIC_REDIST2].size / GICV3_REDIST_SIZE;
} else {
virt_max_cpus = GIC_NCPU;
}
if (max_cpus > virt_max_cpus) {
error_report("Number of SMP CPUs requested (%d) exceeds max CPUs "
"supported by machine 'mach-virt' (%d)",
max_cpus, virt_max_cpus);
exit(1);
}
vms->smp_cpus = smp_cpus;
if (vms->virt && kvm_enabled()) {
error_report("mach-virt: KVM does not support providing "
"Virtualization extensions to the guest CPU");
exit(1);
}
create_fdt(vms);
possible_cpus = mc->possible_cpu_arch_ids(machine);
for (n = 0; n < possible_cpus->len; n++) {
Object *cpuobj;
CPUState *cs;
if (n >= smp_cpus) {
break;
}
cpuobj = object_new(possible_cpus->cpus[n].type);
object_property_set_int(cpuobj, possible_cpus->cpus[n].arch_id,
"mp-affinity", NULL);
cs = CPU(cpuobj);
cs->cpu_index = n;
numa_cpu_pre_plug(&possible_cpus->cpus[cs->cpu_index], DEVICE(cpuobj),
&error_fatal);
aarch64 &= object_property_get_bool(cpuobj, "aarch64", NULL);
if (!vms->secure) {
object_property_set_bool(cpuobj, false, "has_el3", NULL);
}
if (!vms->virt && object_property_find(cpuobj, "has_el2", NULL)) {
object_property_set_bool(cpuobj, false, "has_el2", NULL);
}
if (vms->psci_conduit != QEMU_PSCI_CONDUIT_DISABLED) {
object_property_set_int(cpuobj, vms->psci_conduit,
"psci-conduit", NULL);
/* Secondary CPUs start in PSCI powered-down state */
if (n > 0) {
object_property_set_bool(cpuobj, true,
"start-powered-off", NULL);
}
}
if (vmc->no_pmu && object_property_find(cpuobj, "pmu", NULL)) {
object_property_set_bool(cpuobj, false, "pmu", NULL);
}
if (object_property_find(cpuobj, "reset-cbar", NULL)) {
object_property_set_int(cpuobj, vms->memmap[VIRT_CPUPERIPHS].base,
"reset-cbar", &error_abort);
}
object_property_set_link(cpuobj, OBJECT(sysmem), "memory",
&error_abort);
if (vms->secure) {
object_property_set_link(cpuobj, OBJECT(secure_sysmem),
"secure-memory", &error_abort);
}
object_property_set_bool(cpuobj, true, "realized", &error_fatal);
object_unref(cpuobj);
}
fdt_add_timer_nodes(vms);
fdt_add_cpu_nodes(vms);
if (!kvm_enabled()) {
ARMCPU *cpu = ARM_CPU(first_cpu);
bool aarch64 = object_property_get_bool(OBJECT(cpu), "aarch64", NULL);
if (aarch64 && vms->highmem) {
int requested_pa_size, pamax = arm_pamax(cpu);
requested_pa_size = 64 - clz64(vms->highest_gpa);
if (pamax < requested_pa_size) {
error_report("VCPU supports less PA bits (%d) than requested "
"by the memory map (%d)", pamax, requested_pa_size);
exit(1);
}
}
}
memory_region_allocate_system_memory(ram, NULL, "mach-virt.ram",
machine->ram_size);
memory_region_add_subregion(sysmem, vms->memmap[VIRT_MEM].base, ram);
if (machine->device_memory) {
memory_region_add_subregion(sysmem, machine->device_memory->base,
&machine->device_memory->mr);
}
virt_flash_fdt(vms, sysmem, secure_sysmem ?: sysmem);
create_gic(vms, pic);
fdt_add_pmu_nodes(vms);
create_uart(vms, pic, VIRT_UART, sysmem, serial_hd(0));
if (vms->secure) {
create_secure_ram(vms, secure_sysmem);
create_uart(vms, pic, VIRT_SECURE_UART, secure_sysmem, serial_hd(1));
}
vms->highmem_ecam &= vms->highmem && (!firmware_loaded || aarch64);
create_rtc(vms, pic);
create_pcie(vms, pic);
if (has_ged && aarch64 && firmware_loaded && acpi_enabled) {
vms->acpi_dev = create_acpi_ged(vms, pic);
} else {
create_gpio(vms, pic);
}
/* connect powerdown request */
vms->powerdown_notifier.notify = virt_powerdown_req;
qemu_register_powerdown_notifier(&vms->powerdown_notifier);
/* Create mmio transports, so the user can create virtio backends
* (which will be automatically plugged in to the transports). If
* no backend is created the transport will just sit harmlessly idle.
*/
create_virtio_devices(vms, pic);
vms->fw_cfg = create_fw_cfg(vms, &address_space_memory);
rom_set_fw(vms->fw_cfg);
arm/boot: split load_dtb() from arm_load_kernel() load_dtb() depends on arm_load_kernel() to figure out place in RAM where it should be loaded, but it's not required for arm_load_kernel() to work. Sometimes it's neccesary for devices added with -device/device_add to be enumerated in DTB as well, which's lead to [1] and surrounding commits to add 2 more machine_done notifiers with non obvious ordering to make dynamic sysbus devices initialization happen in the right order. However instead of moving whole arm_load_kernel() in to machine_done, it's sufficient to move only load_dtb() into virt_machine_done() notifier and remove ArmLoadKernelNotifier/ /PlatformBusFDTNotifierParams notifiers, which saves us ~90LOC and simplifies code flow quite a bit. Later would allow to consolidate DTB generation within one function for 'mach-virt' board and make it reentrant so it could generate updated DTB in device hotplug secenarios. While at it rename load_dtb() to arm_load_dtb() since it's public now. Add additional field skip_dtb_autoload to struct arm_boot_info to allow manual DTB load later in mach-virt and to avoid touching all other boards to explicitly call arm_load_dtb(). 1) (ac9d32e hw/arm/boot: arm_load_kernel implemented as a machine init done notifier) Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Reviewed-by: Andrew Jones <drjones@redhat.com> Message-id: 1525691524-32265-4-git-send-email-imammedo@redhat.com Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2018-05-11 01:10:56 +08:00
create_platform_bus(vms, pic);
vms->bootinfo.ram_size = machine->ram_size;
vms->bootinfo.nb_cpus = smp_cpus;
vms->bootinfo.board_id = -1;
vms->bootinfo.loader_start = vms->memmap[VIRT_MEM].base;
vms->bootinfo.get_dtb = machvirt_dtb;
arm/boot: split load_dtb() from arm_load_kernel() load_dtb() depends on arm_load_kernel() to figure out place in RAM where it should be loaded, but it's not required for arm_load_kernel() to work. Sometimes it's neccesary for devices added with -device/device_add to be enumerated in DTB as well, which's lead to [1] and surrounding commits to add 2 more machine_done notifiers with non obvious ordering to make dynamic sysbus devices initialization happen in the right order. However instead of moving whole arm_load_kernel() in to machine_done, it's sufficient to move only load_dtb() into virt_machine_done() notifier and remove ArmLoadKernelNotifier/ /PlatformBusFDTNotifierParams notifiers, which saves us ~90LOC and simplifies code flow quite a bit. Later would allow to consolidate DTB generation within one function for 'mach-virt' board and make it reentrant so it could generate updated DTB in device hotplug secenarios. While at it rename load_dtb() to arm_load_dtb() since it's public now. Add additional field skip_dtb_autoload to struct arm_boot_info to allow manual DTB load later in mach-virt and to avoid touching all other boards to explicitly call arm_load_dtb(). 1) (ac9d32e hw/arm/boot: arm_load_kernel implemented as a machine init done notifier) Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Reviewed-by: Andrew Jones <drjones@redhat.com> Message-id: 1525691524-32265-4-git-send-email-imammedo@redhat.com Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2018-05-11 01:10:56 +08:00
vms->bootinfo.skip_dtb_autoload = true;
vms->bootinfo.firmware_loaded = firmware_loaded;
arm_load_kernel(ARM_CPU(first_cpu), machine, &vms->bootinfo);
arm/boot: split load_dtb() from arm_load_kernel() load_dtb() depends on arm_load_kernel() to figure out place in RAM where it should be loaded, but it's not required for arm_load_kernel() to work. Sometimes it's neccesary for devices added with -device/device_add to be enumerated in DTB as well, which's lead to [1] and surrounding commits to add 2 more machine_done notifiers with non obvious ordering to make dynamic sysbus devices initialization happen in the right order. However instead of moving whole arm_load_kernel() in to machine_done, it's sufficient to move only load_dtb() into virt_machine_done() notifier and remove ArmLoadKernelNotifier/ /PlatformBusFDTNotifierParams notifiers, which saves us ~90LOC and simplifies code flow quite a bit. Later would allow to consolidate DTB generation within one function for 'mach-virt' board and make it reentrant so it could generate updated DTB in device hotplug secenarios. While at it rename load_dtb() to arm_load_dtb() since it's public now. Add additional field skip_dtb_autoload to struct arm_boot_info to allow manual DTB load later in mach-virt and to avoid touching all other boards to explicitly call arm_load_dtb(). 1) (ac9d32e hw/arm/boot: arm_load_kernel implemented as a machine init done notifier) Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Reviewed-by: Andrew Jones <drjones@redhat.com> Message-id: 1525691524-32265-4-git-send-email-imammedo@redhat.com Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2018-05-11 01:10:56 +08:00
vms->machine_done.notify = virt_machine_done;
qemu_add_machine_init_done_notifier(&vms->machine_done);
}
static bool virt_get_secure(Object *obj, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
return vms->secure;
}
static void virt_set_secure(Object *obj, bool value, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
vms->secure = value;
}
static bool virt_get_virt(Object *obj, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
return vms->virt;
}
static void virt_set_virt(Object *obj, bool value, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
vms->virt = value;
}
static bool virt_get_highmem(Object *obj, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
return vms->highmem;
}
static void virt_set_highmem(Object *obj, bool value, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
vms->highmem = value;
}
static bool virt_get_its(Object *obj, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
return vms->its;
}
static void virt_set_its(Object *obj, bool value, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
vms->its = value;
}
static char *virt_get_gic_version(Object *obj, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
const char *val = vms->gic_version == 3 ? "3" : "2";
return g_strdup(val);
}
static void virt_set_gic_version(Object *obj, const char *value, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
if (!strcmp(value, "3")) {
vms->gic_version = 3;
} else if (!strcmp(value, "2")) {
vms->gic_version = 2;
} else if (!strcmp(value, "host")) {
vms->gic_version = 0; /* Will probe later */
} else if (!strcmp(value, "max")) {
vms->gic_version = -1; /* Will probe later */
} else {
error_setg(errp, "Invalid gic-version value");
error_append_hint(errp, "Valid values are 3, 2, host, max.\n");
}
}
static char *virt_get_iommu(Object *obj, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
switch (vms->iommu) {
case VIRT_IOMMU_NONE:
return g_strdup("none");
case VIRT_IOMMU_SMMUV3:
return g_strdup("smmuv3");
default:
g_assert_not_reached();
}
}
static void virt_set_iommu(Object *obj, const char *value, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
if (!strcmp(value, "smmuv3")) {
vms->iommu = VIRT_IOMMU_SMMUV3;
} else if (!strcmp(value, "none")) {
vms->iommu = VIRT_IOMMU_NONE;
} else {
error_setg(errp, "Invalid iommu value");
error_append_hint(errp, "Valid values are none, smmuv3.\n");
}
}
static CpuInstanceProperties
virt_cpu_index_to_props(MachineState *ms, unsigned cpu_index)
{
MachineClass *mc = MACHINE_GET_CLASS(ms);
const CPUArchIdList *possible_cpus = mc->possible_cpu_arch_ids(ms);
assert(cpu_index < possible_cpus->len);
return possible_cpus->cpus[cpu_index].props;
}
static int64_t virt_get_default_cpu_node_id(const MachineState *ms, int idx)
{
return idx % ms->numa_state->num_nodes;
}
static const CPUArchIdList *virt_possible_cpu_arch_ids(MachineState *ms)
{
int n;
unsigned int max_cpus = ms->smp.max_cpus;
VirtMachineState *vms = VIRT_MACHINE(ms);
if (ms->possible_cpus) {
assert(ms->possible_cpus->len == max_cpus);
return ms->possible_cpus;
}
ms->possible_cpus = g_malloc0(sizeof(CPUArchIdList) +
sizeof(CPUArchId) * max_cpus);
ms->possible_cpus->len = max_cpus;
for (n = 0; n < ms->possible_cpus->len; n++) {
ms->possible_cpus->cpus[n].type = ms->cpu_type;
ms->possible_cpus->cpus[n].arch_id =
virt_cpu_mp_affinity(vms, n);
ms->possible_cpus->cpus[n].props.has_thread_id = true;
ms->possible_cpus->cpus[n].props.thread_id = n;
}
return ms->possible_cpus;
}
static void virt_memory_pre_plug(HotplugHandler *hotplug_dev, DeviceState *dev,
Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(hotplug_dev);
const bool is_nvdimm = object_dynamic_cast(OBJECT(dev), TYPE_NVDIMM);
if (is_nvdimm) {
error_setg(errp, "nvdimm is not yet supported");
return;
}
if (!vms->acpi_dev) {
error_setg(errp,
"memory hotplug is not enabled: missing acpi-ged device");
return;
}
pc_dimm_pre_plug(PC_DIMM(dev), MACHINE(hotplug_dev), NULL, errp);
}
static void virt_memory_plug(HotplugHandler *hotplug_dev,
DeviceState *dev, Error **errp)
{
HotplugHandlerClass *hhc;
VirtMachineState *vms = VIRT_MACHINE(hotplug_dev);
Error *local_err = NULL;
pc_dimm_plug(PC_DIMM(dev), MACHINE(vms), &local_err);
if (local_err) {
goto out;
}
hhc = HOTPLUG_HANDLER_GET_CLASS(vms->acpi_dev);
hhc->plug(HOTPLUG_HANDLER(vms->acpi_dev), dev, &error_abort);
out:
error_propagate(errp, local_err);
}
static void virt_machine_device_pre_plug_cb(HotplugHandler *hotplug_dev,
DeviceState *dev, Error **errp)
{
if (object_dynamic_cast(OBJECT(dev), TYPE_PC_DIMM)) {
virt_memory_pre_plug(hotplug_dev, dev, errp);
}
}
static void virt_machine_device_plug_cb(HotplugHandler *hotplug_dev,
DeviceState *dev, Error **errp)
{
VirtMachineState *vms = VIRT_MACHINE(hotplug_dev);
if (vms->platform_bus_dev) {
if (object_dynamic_cast(OBJECT(dev), TYPE_SYS_BUS_DEVICE)) {
platform_bus_link_device(PLATFORM_BUS_DEVICE(vms->platform_bus_dev),
SYS_BUS_DEVICE(dev));
}
}
if (object_dynamic_cast(OBJECT(dev), TYPE_PC_DIMM)) {
virt_memory_plug(hotplug_dev, dev, errp);
}
}
static void virt_machine_device_unplug_request_cb(HotplugHandler *hotplug_dev,
DeviceState *dev, Error **errp)
{
error_setg(errp, "device unplug request for unsupported device"
" type: %s", object_get_typename(OBJECT(dev)));
}
static HotplugHandler *virt_machine_get_hotplug_handler(MachineState *machine,
DeviceState *dev)
{
if (object_dynamic_cast(OBJECT(dev), TYPE_SYS_BUS_DEVICE) ||
(object_dynamic_cast(OBJECT(dev), TYPE_PC_DIMM))) {
return HOTPLUG_HANDLER(machine);
}
return NULL;
}
/*
* for arm64 kvm_type [7-0] encodes the requested number of bits
* in the IPA address space
*/
static int virt_kvm_type(MachineState *ms, const char *type_str)
{
VirtMachineState *vms = VIRT_MACHINE(ms);
int max_vm_pa_size = kvm_arm_get_max_vm_ipa_size(ms);
int requested_pa_size;
/* we freeze the memory map to compute the highest gpa */
virt_set_memmap(vms);
requested_pa_size = 64 - clz64(vms->highest_gpa);
if (requested_pa_size > max_vm_pa_size) {
error_report("-m and ,maxmem option values "
"require an IPA range (%d bits) larger than "
"the one supported by the host (%d bits)",
requested_pa_size, max_vm_pa_size);
exit(1);
}
/*
* By default we return 0 which corresponds to an implicit legacy
* 40b IPA setting. Otherwise we return the actual requested PA
* logsize
*/
return requested_pa_size > 40 ? requested_pa_size : 0;
}
static void virt_machine_class_init(ObjectClass *oc, void *data)
{
MachineClass *mc = MACHINE_CLASS(oc);
HotplugHandlerClass *hc = HOTPLUG_HANDLER_CLASS(oc);
mc->init = machvirt_init;
/* Start with max_cpus set to 512, which is the maximum supported by KVM.
* The value may be reduced later when we have more information about the
* configuration of the particular instance.
*/
mc->max_cpus = 512;
machine_class_allow_dynamic_sysbus_dev(mc, TYPE_VFIO_CALXEDA_XGMAC);
machine_class_allow_dynamic_sysbus_dev(mc, TYPE_VFIO_AMD_XGBE);
machine_class_allow_dynamic_sysbus_dev(mc, TYPE_RAMFB_DEVICE);
machine_class_allow_dynamic_sysbus_dev(mc, TYPE_VFIO_PLATFORM);
mc->block_default_type = IF_VIRTIO;
mc->no_cdrom = 1;
mc->pci_allow_0_address = true;
/* We know we will never create a pre-ARMv7 CPU which needs 1K pages */
mc->minimum_page_bits = 12;
mc->possible_cpu_arch_ids = virt_possible_cpu_arch_ids;
mc->cpu_index_to_instance_props = virt_cpu_index_to_props;
arm: drop intermediate cpu_model -> cpu type parsing and use cpu type directly there are 2 use cases to deal with: 1: fixed CPU models per board/soc 2: boards with user configurable cpu_model and fallback to default cpu_model if user hasn't specified one explicitly For the 1st drop intermediate cpu_model parsing and use const cpu type directly, which replaces: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) object_new(typename) with object_new(FOO_CPU_TYPE_NAME) or cpu_generic_init(BASE_CPU_TYPE, "my cpu model") with cpu_create(FOO_CPU_TYPE_NAME) as result 1st use case doesn't have to invoke not necessary translation and not needed code is removed. For the 2nd 1: set default cpu type with MachineClass::default_cpu_type and 2: use generic cpu_model parsing that done before machine_init() is run and: 2.1: drop custom cpu_model parsing where pattern is: typename = object_class_get_name( cpu_class_by_name(TYPE_ARM_CPU, cpu_model)) [parse_features(typename, cpu_model, &err) ] 2.2: or replace cpu_generic_init() which does what 2.1 does + create_cpu(typename) with just create_cpu(machine->cpu_type) as result cpu_name -> cpu_type translation is done using generic machine code one including parsing optional features if supported/present (removes a bunch of duplicated cpu_model parsing code) and default cpu type is defined in an uniform way within machine_class_init callbacks instead of adhoc places in boadr's machine_init code. Signed-off-by: Igor Mammedov <imammedo@redhat.com> Reviewed-by: Eduardo Habkost <ehabkost@redhat.com> Message-Id: <1505318697-77161-6-git-send-email-imammedo@redhat.com> Reviewed-by: Alistair Francis <alistair.francis@xilinx.com> Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org> Signed-off-by: Eduardo Habkost <ehabkost@redhat.com>
2017-09-14 00:04:57 +08:00
mc->default_cpu_type = ARM_CPU_TYPE_NAME("cortex-a15");
mc->get_default_cpu_node_id = virt_get_default_cpu_node_id;
mc->kvm_type = virt_kvm_type;
assert(!mc->get_hotplug_handler);
mc->get_hotplug_handler = virt_machine_get_hotplug_handler;
hc->pre_plug = virt_machine_device_pre_plug_cb;
hc->plug = virt_machine_device_plug_cb;
hc->unplug_request = virt_machine_device_unplug_request_cb;
mc->numa_mem_supported = true;
mc->auto_enable_numa_with_memhp = true;
}
static void virt_instance_init(Object *obj)
{
VirtMachineState *vms = VIRT_MACHINE(obj);
VirtMachineClass *vmc = VIRT_MACHINE_GET_CLASS(vms);
/* EL3 is disabled by default on virt: this makes us consistent
* between KVM and TCG for this board, and it also allows us to
* boot UEFI blobs which assume no TrustZone support.
*/
vms->secure = false;
object_property_add_bool(obj, "secure", virt_get_secure,
virt_set_secure, NULL);
object_property_set_description(obj, "secure",
"Set on/off to enable/disable the ARM "
"Security Extensions (TrustZone)",
NULL);
/* EL2 is also disabled by default, for similar reasons */
vms->virt = false;
object_property_add_bool(obj, "virtualization", virt_get_virt,
virt_set_virt, NULL);
object_property_set_description(obj, "virtualization",
"Set on/off to enable/disable emulating a "
"guest CPU which implements the ARM "
"Virtualization Extensions",
NULL);
/* High memory is enabled by default */
vms->highmem = true;
object_property_add_bool(obj, "highmem", virt_get_highmem,
virt_set_highmem, NULL);
object_property_set_description(obj, "highmem",
"Set on/off to enable/disable using "
"physical address space above 32 bits",
NULL);
/* Default GIC type is v2 */
vms->gic_version = 2;
object_property_add_str(obj, "gic-version", virt_get_gic_version,
virt_set_gic_version, NULL);
object_property_set_description(obj, "gic-version",
"Set GIC version. "
"Valid values are 2, 3 and host", NULL);
vms->highmem_ecam = !vmc->no_highmem_ecam;
if (vmc->no_its) {
vms->its = false;
} else {
/* Default allows ITS instantiation */
vms->its = true;
object_property_add_bool(obj, "its", virt_get_its,
virt_set_its, NULL);
object_property_set_description(obj, "its",
"Set on/off to enable/disable "
"ITS instantiation",
NULL);
}
/* Default disallows iommu instantiation */
vms->iommu = VIRT_IOMMU_NONE;
object_property_add_str(obj, "iommu", virt_get_iommu, virt_set_iommu, NULL);
object_property_set_description(obj, "iommu",
"Set the IOMMU type. "
"Valid values are none and smmuv3",
NULL);
vms->irqmap = a15irqmap;
hw/arm/virt: Support firmware configuration with -blockdev The ARM virt machines put firmware in flash memory. To configure it, you use -drive if=pflash,unit=0,... and optionally -drive if=pflash,unit=1,... Why two -drive? This permits setting up one part of the flash memory read-only, and the other part read/write. It also makes upgrading firmware on the host easier. Below the hood, we get two separate flash devices, because we were too lazy to improve our flash device models to support sector protection. The problem at hand is to do the same with -blockdev somehow, as one more step towards deprecating -drive. We recently solved this problem for x86 PC machines, in commit ebc29e1beab. See the commit message for design rationale. This commit solves it for ARM virt basically the same way: new machine properties pflash0, pflash1 forward to the onboard flash devices' properties. Requires creating the onboard devices in the .instance_init() method virt_instance_init(). The existing code to pick up drives defined with -drive if=pflash is replaced by code to desugar into the machine properties. There are a few behavioral differences, though: * The flash devices are always present (x86: only present if configured) * Flash base addresses and sizes are fixed (x86: sizes depend on images, mapped back to back below a fixed address) * -bios configures contents of first pflash (x86: -bios configures ROM contents) * -bios is rejected when first pflash is also configured with -machine pflash0=... (x86: bios is silently ignored then) * -machine pflash1=... does not require -machine pflash0=... (x86: it does). The actual code is a bit simpler than for x86 mostly due to the first two differences. Before the patch, all the action is in create_flash(), called from the machine's .init() method machvirt_init(): main() machine_run_board_init() machvirt_init() create_flash() create_one_flash() for flash[0] create configure includes obeying -drive if=pflash,unit=0 realize map fall back to -bios create_one_flash() for flash[1] create configure includes obeying -drive if=pflash,unit=1 realize map update FDT To make the machine properties work, we need to move device creation to its .instance_init() method virt_instance_init(). Another complication is machvirt_init()'s computation of @firmware_loaded: it predicts what create_flash() will do. Instead of predicting what create_flash()'s replacement virt_firmware_init() will do, I decided to have virt_firmware_init() return what it did. Requires calling it a bit earlier. Resulting call tree: main() current_machine = object_new() ... virt_instance_init() virt_flash_create() virt_flash_create1() for flash[0] create configure: set defaults become child of machine [NEW] add machine prop pflash0 as alias for drive [NEW] virt_flash_create1() for flash[1] create configure: set defaults become child of machine [NEW] add machine prop pflash1 as alias for drive [NEW] for all machine props from the command line: machine_set_property() ... property_set_alias() for machine props pflash0, pflash1 ... set_drive() for cfi.pflash01 prop drive this is how -machine pflash0=... etc set machine_run_board_init(current_machine); virt_firmware_init() pflash_cfi01_legacy_drive() legacy -drive if=pflash,unit=0 and =1 [NEW] virt_flash_map() virt_flash_map1() for flash[0] configure: num-blocks realize map virt_flash_map1() for flash[1] configure: num-blocks realize map fall back to -bios virt_flash_fdt() update FDT You have László to thank for making me explain this in detail. Signed-off-by: Markus Armbruster <armbru@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com> Message-id: 20190416091348.26075-4-armbru@redhat.com Reviewed-by: Peter Maydell <peter.maydell@linaro.org> Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2019-05-07 19:55:02 +08:00
virt_flash_create(vms);
}
static const TypeInfo virt_machine_info = {
.name = TYPE_VIRT_MACHINE,
.parent = TYPE_MACHINE,
.abstract = true,
.instance_size = sizeof(VirtMachineState),
.class_size = sizeof(VirtMachineClass),
.class_init = virt_machine_class_init,
.instance_init = virt_instance_init,
.interfaces = (InterfaceInfo[]) {
{ TYPE_HOTPLUG_HANDLER },
{ }
},
};
static void machvirt_machine_init(void)
{
type_register_static(&virt_machine_info);
}
type_init(machvirt_machine_init);
static void virt_machine_4_2_options(MachineClass *mc)
{
compat_props_add(mc->compat_props, hw_compat_4_2, hw_compat_4_2_len);
}
DEFINE_VIRT_MACHINE_AS_LATEST(4, 2)
static void virt_machine_4_1_options(MachineClass *mc)
{
VirtMachineClass *vmc = VIRT_MACHINE_CLASS(OBJECT_CLASS(mc));
virt_machine_4_2_options(mc);
compat_props_add(mc->compat_props, hw_compat_4_1, hw_compat_4_1_len);
vmc->no_ged = true;
mc->auto_enable_numa_with_memhp = false;
}
DEFINE_VIRT_MACHINE(4, 1)
static void virt_machine_4_0_options(MachineClass *mc)
{
virt_machine_4_1_options(mc);
compat_props_add(mc->compat_props, hw_compat_4_0, hw_compat_4_0_len);
}
DEFINE_VIRT_MACHINE(4, 0)
static void virt_machine_3_1_options(MachineClass *mc)
{
virt_machine_4_0_options(mc);
compat_props_add(mc->compat_props, hw_compat_3_1, hw_compat_3_1_len);
}
DEFINE_VIRT_MACHINE(3, 1)
static void virt_machine_3_0_options(MachineClass *mc)
{
virt_machine_3_1_options(mc);
compat_props_add(mc->compat_props, hw_compat_3_0, hw_compat_3_0_len);
}
DEFINE_VIRT_MACHINE(3, 0)
static void virt_machine_2_12_options(MachineClass *mc)
{
VirtMachineClass *vmc = VIRT_MACHINE_CLASS(OBJECT_CLASS(mc));
virt_machine_3_0_options(mc);
compat_props_add(mc->compat_props, hw_compat_2_12, hw_compat_2_12_len);
vmc->no_highmem_ecam = true;
mc->max_cpus = 255;
}
DEFINE_VIRT_MACHINE(2, 12)
static void virt_machine_2_11_options(MachineClass *mc)
{
VirtMachineClass *vmc = VIRT_MACHINE_CLASS(OBJECT_CLASS(mc));
virt_machine_2_12_options(mc);
compat_props_add(mc->compat_props, hw_compat_2_11, hw_compat_2_11_len);
vmc->smbios_old_sys_ver = true;
}
DEFINE_VIRT_MACHINE(2, 11)
static void virt_machine_2_10_options(MachineClass *mc)
{
virt_machine_2_11_options(mc);
compat_props_add(mc->compat_props, hw_compat_2_10, hw_compat_2_10_len);
2018-10-08 21:55:02 +08:00
/* before 2.11 we never faulted accesses to bad addresses */
mc->ignore_memory_transaction_failures = true;
}
DEFINE_VIRT_MACHINE(2, 10)
static void virt_machine_2_9_options(MachineClass *mc)
{
virt_machine_2_10_options(mc);
compat_props_add(mc->compat_props, hw_compat_2_9, hw_compat_2_9_len);
}
DEFINE_VIRT_MACHINE(2, 9)
static void virt_machine_2_8_options(MachineClass *mc)
{
VirtMachineClass *vmc = VIRT_MACHINE_CLASS(OBJECT_CLASS(mc));
virt_machine_2_9_options(mc);
compat_props_add(mc->compat_props, hw_compat_2_8, hw_compat_2_8_len);
/* For 2.8 and earlier we falsely claimed in the DT that
* our timers were edge-triggered, not level-triggered.
*/
vmc->claim_edge_triggered_timers = true;
}
DEFINE_VIRT_MACHINE(2, 8)
static void virt_machine_2_7_options(MachineClass *mc)
{
VirtMachineClass *vmc = VIRT_MACHINE_CLASS(OBJECT_CLASS(mc));
virt_machine_2_8_options(mc);
compat_props_add(mc->compat_props, hw_compat_2_7, hw_compat_2_7_len);
/* ITS was introduced with 2.8 */
vmc->no_its = true;
/* Stick with 1K pages for migration compatibility */
mc->minimum_page_bits = 0;
}
DEFINE_VIRT_MACHINE(2, 7)
static void virt_machine_2_6_options(MachineClass *mc)
{
VirtMachineClass *vmc = VIRT_MACHINE_CLASS(OBJECT_CLASS(mc));
virt_machine_2_7_options(mc);
compat_props_add(mc->compat_props, hw_compat_2_6, hw_compat_2_6_len);
vmc->disallow_affinity_adjustment = true;
/* Disable PMU for 2.6 as PMU support was first introduced in 2.7 */
vmc->no_pmu = true;
}
DEFINE_VIRT_MACHINE(2, 6)