include/hw/boards.h - qemu - Git at Google

 /* Declarations for use by board files for creating devices.  */

 #ifndef HW_BOARDS_H
 #define HW_BOARDS_H

 #include "sysemu/blockdev.h"
 #include "sysemu/accel.h"
 #include "hw/qdev.h"
 #include "qom/object.h"
 #include "qom/cpu.h"

 /**
  * memory_region_allocate_system_memory - Allocate a board's main memory
  * @mr: the #MemoryRegion to be initialized
  * @owner: the object that tracks the region's reference count
  * @name: name of the memory region
  * @ram_size: size of the region in bytes
  *
  * This function allocates the main memory for a board model, and
  * initializes @mr appropriately. It also arranges for the memory
  * to be migrated (by calling vmstate_register_ram_global()).
  *
  * Memory allocated via this function will be backed with the memory
  * backend the user provided using "-mem-path" or "-numa node,memdev=..."
  * if appropriate; this is typically used to cause host huge pages to be
  * used. This function should therefore be called by a board exactly once,
  * for the primary or largest RAM area it implements.
  *
  * For boards where the major RAM is split into two parts in the memory
  * map, you can deal with this by calling memory_region_allocate_system_memory()
  * once to get a MemoryRegion with enough RAM for both parts, and then
  * creating alias MemoryRegions via memory_region_init_alias() which
  * alias into different parts of the RAM MemoryRegion and can be mapped
  * into the memory map in the appropriate places.
  *
  * Smaller pieces of memory (display RAM, static RAMs, etc) don't need
  * to be backed via the -mem-path memory backend and can simply
  * be created via memory_region_init_ram().
  */
 void memory_region_allocate_system_memory(MemoryRegion *mr, Object *owner,
                                           const char *name,
                                           uint64_t ram_size);

 #define TYPE_MACHINE_SUFFIX "-machine"

 /* Machine class name that needs to be used for class-name-based machine
  * type lookup to work.
  */
 #define MACHINE_TYPE_NAME(machinename) (machinename TYPE_MACHINE_SUFFIX)

 #define TYPE_MACHINE "machine"
 #undef MACHINE  /* BSD defines it and QEMU does not use it */
 #define MACHINE(obj) \
     OBJECT_CHECK(MachineState, (obj), TYPE_MACHINE)
 #define MACHINE_GET_CLASS(obj) \
     OBJECT_GET_CLASS(MachineClass, (obj), TYPE_MACHINE)
 #define MACHINE_CLASS(klass) \
     OBJECT_CLASS_CHECK(MachineClass, (klass), TYPE_MACHINE)

 MachineClass *find_default_machine(void);
 extern MachineState *current_machine;

 void machine_run_board_init(MachineState *machine);
 bool machine_usb(MachineState *machine);
 bool machine_kernel_irqchip_allowed(MachineState *machine);
 bool machine_kernel_irqchip_required(MachineState *machine);
 bool machine_kernel_irqchip_split(MachineState *machine);
 int machine_kvm_shadow_mem(MachineState *machine);
 int machine_phandle_start(MachineState *machine);
 bool machine_dump_guest_core(MachineState *machine);
 bool machine_mem_merge(MachineState *machine);
 HotpluggableCPUList *machine_query_hotpluggable_cpus(MachineState *machine);
 void machine_set_cpu_numa_node(MachineState *machine,
                                const CpuInstanceProperties *props,
                                Error **errp);

 void machine_class_allow_dynamic_sysbus_dev(MachineClass *mc, const char *type);


 /**
  * CPUArchId:
  * @arch_id - architecture-dependent CPU ID of present or possible CPU
  * @cpu - pointer to corresponding CPU object if it's present on NULL otherwise
  * @type - QOM class name of possible @cpu object
  * @props - CPU object properties, initialized by board
  * #vcpus_count - number of threads provided by @cpu object
  */
 typedef struct {
     uint64_t arch_id;
     int64_t vcpus_count;
     CpuInstanceProperties props;
     Object *cpu;
     const char *type;
 } CPUArchId;

 /**
  * CPUArchIdList:
  * @len - number of @CPUArchId items in @cpus array
  * @cpus - array of present or possible CPUs for current machine configuration
  */
 typedef struct {
     int len;
     CPUArchId cpus[0];
 } CPUArchIdList;

 /**
  * MachineClass:
  * @deprecation_reason: If set, the machine is marked as deprecated. The
  *    string should provide some clear information about what to use instead.
  * @max_cpus: maximum number of CPUs supported. Default: 1
  * @min_cpus: minimum number of CPUs supported. Default: 1
  * @default_cpus: number of CPUs instantiated if none are specified. Default: 1
  * @get_hotplug_handler: this function is called during bus-less
  *    device hotplug. If defined it returns pointer to an instance
  *    of HotplugHandler object, which handles hotplug operation
  *    for a given @dev. It may return NULL if @dev doesn't require
  *    any actions to be performed by hotplug handler.
  * @cpu_index_to_instance_props:
  *    used to provide @cpu_index to socket/core/thread number mapping, allowing
  *    legacy code to perform maping from cpu_index to topology properties
  *    Returns: tuple of socket/core/thread ids given cpu_index belongs to.
  *    used to provide @cpu_index to socket number mapping, allowing
  *    a machine to group CPU threads belonging to the same socket/package
  *    Returns: socket number given cpu_index belongs to.
  * @hw_version:
  *    Value of QEMU_VERSION when the machine was added to QEMU.
  *    Set only by old machines because they need to keep
  *    compatibility on code that exposed QEMU_VERSION to guests in
  *    the past (and now use qemu_hw_version()).
  * @possible_cpu_arch_ids:
  *    Returns an array of @CPUArchId architecture-dependent CPU IDs
  *    which includes CPU IDs for present and possible to hotplug CPUs.
  *    Caller is responsible for freeing returned list.
  * @get_default_cpu_node_id:
  *    returns default board specific node_id value for CPU slot specified by
  *    index @idx in @ms->possible_cpus[]
  * @has_hotpluggable_cpus:
  *    If true, board supports CPUs creation with -device/device_add.
  * @default_cpu_type:
  *    specifies default CPU_TYPE, which will be used for parsing target
  *    specific features and for creating CPUs if CPU name wasn't provided
  *    explicitly at CLI
  * @minimum_page_bits:
  *    If non-zero, the board promises never to create a CPU with a page size
  *    smaller than this, so QEMU can use a more efficient larger page
  *    size than the target architecture's minimum. (Attempting to create
  *    such a CPU will fail.) Note that changing this is a migration
  *    compatibility break for the machine.
  * @ignore_memory_transaction_failures:
  *    If this is flag is true then the CPU will ignore memory transaction
  *    failures which should cause the CPU to take an exception due to an
  *    access to an unassigned physical address; the transaction will instead
  *    return zero (for a read) or be ignored (for a write). This should be
  *    set only by legacy board models which rely on the old RAZ/WI behaviour
  *    for handling devices that QEMU does not yet model. New board models
  *    should instead use "unimplemented-device" for all memory ranges where
  *    the guest will attempt to probe for a device that QEMU doesn't
  *    implement and a stub device is required.
  * @kvm_type:
  *    Return the type of KVM corresponding to the kvm-type string option or
  *    computed based on other criteria such as the host kernel capabilities.
  */
 struct MachineClass {
     /*< private >*/
     ObjectClass parent_class;
     /*< public >*/

     const char *family; /* NULL iff @name identifies a standalone machtype */
     char *name;
     const char *alias;
     const char *desc;
     const char *deprecation_reason;

     void (*init)(MachineState *state);
     void (*reset)(void);
     void (*hot_add_cpu)(const int64_t id, Error **errp);
     int (*kvm_type)(MachineState *machine, const char *arg);

     BlockInterfaceType block_default_type;
     int units_per_default_bus;
     int max_cpus;
     int min_cpus;
     int default_cpus;
     unsigned int no_serial:1,
         no_parallel:1,
         no_floppy:1,
         no_cdrom:1,
         no_sdcard:1,
         pci_allow_0_address:1,
         legacy_fw_cfg_order:1;
     int is_default;
     const char *default_machine_opts;
     const char *default_boot_order;
     const char *default_display;
     GPtrArray *compat_props;
     const char *hw_version;
     ram_addr_t default_ram_size;
     const char *default_cpu_type;
     bool default_kernel_irqchip_split;
     bool option_rom_has_mr;
     bool rom_file_has_mr;
     int minimum_page_bits;
     bool has_hotpluggable_cpus;
     bool ignore_memory_transaction_failures;
     int numa_mem_align_shift;
     const char **valid_cpu_types;
     strList *allowed_dynamic_sysbus_devices;
     bool auto_enable_numa_with_memhp;
     void (*numa_auto_assign_ram)(MachineClass *mc, NodeInfo *nodes,
                                  int nb_nodes, ram_addr_t size);
     bool ignore_boot_device_suffixes;
     bool smbus_no_migration_support;

     HotplugHandler *(*get_hotplug_handler)(MachineState *machine,
                                            DeviceState *dev);
     CpuInstanceProperties (*cpu_index_to_instance_props)(MachineState *machine,
                                                          unsigned cpu_index);
     const CPUArchIdList *(*possible_cpu_arch_ids)(MachineState *machine);
     int64_t (*get_default_cpu_node_id)(const MachineState *ms, int idx);
 };

 /**
  * DeviceMemoryState:
  * @base: address in guest physical address space where the memory
  * address space for memory devices starts
  * @mr: address space container for memory devices
  */
 typedef struct DeviceMemoryState {
     hwaddr base;
     MemoryRegion mr;
 } DeviceMemoryState;

 /**
  * MachineState:
  */
 struct MachineState {
     /*< private >*/
     Object parent_obj;
     Notifier sysbus_notifier;

     /*< public >*/

     char *accel;
     bool kernel_irqchip_allowed;
     bool kernel_irqchip_required;
     bool kernel_irqchip_split;
     int kvm_shadow_mem;
     char *dtb;
     char *dumpdtb;
     int phandle_start;
     char *dt_compatible;
     bool dump_guest_core;
     bool mem_merge;
     bool usb;
     bool usb_disabled;
     bool igd_gfx_passthru;
     char *firmware;
     bool iommu;
     bool suppress_vmdesc;
     bool enforce_config_section;
     bool enable_graphics;
     char *memory_encryption;
     DeviceMemoryState *device_memory;

     ram_addr_t ram_size;
     ram_addr_t maxram_size;
     uint64_t   ram_slots;
     const char *boot_order;
     char *kernel_filename;
     char *kernel_cmdline;
     char *initrd_filename;
     const char *cpu_type;
     AccelState *accelerator;
     CPUArchIdList *possible_cpus;
 };

 #define DEFINE_MACHINE(namestr, machine_initfn) \
     static void machine_initfn##_class_init(ObjectClass *oc, void *data) \
     { \
         MachineClass *mc = MACHINE_CLASS(oc); \
         machine_initfn(mc); \
     } \
     static const TypeInfo machine_initfn##_typeinfo = { \
         .name       = MACHINE_TYPE_NAME(namestr), \
         .parent     = TYPE_MACHINE, \
         .class_init = machine_initfn##_class_init, \
     }; \
     static void machine_initfn##_register_types(void) \
     { \
         type_register_static(&machine_initfn##_typeinfo); \
     } \
     type_init(machine_initfn##_register_types)

 extern GlobalProperty hw_compat_3_1[];
 extern const size_t hw_compat_3_1_len;

 extern GlobalProperty hw_compat_3_0[];
 extern const size_t hw_compat_3_0_len;

 extern GlobalProperty hw_compat_2_12[];
 extern const size_t hw_compat_2_12_len;

 extern GlobalProperty hw_compat_2_11[];
 extern const size_t hw_compat_2_11_len;

 extern GlobalProperty hw_compat_2_10[];
 extern const size_t hw_compat_2_10_len;

 extern GlobalProperty hw_compat_2_9[];
 extern const size_t hw_compat_2_9_len;

 extern GlobalProperty hw_compat_2_8[];
 extern const size_t hw_compat_2_8_len;

 extern GlobalProperty hw_compat_2_7[];
 extern const size_t hw_compat_2_7_len;

 extern GlobalProperty hw_compat_2_6[];
 extern const size_t hw_compat_2_6_len;

 extern GlobalProperty hw_compat_2_5[];
 extern const size_t hw_compat_2_5_len;

 extern GlobalProperty hw_compat_2_4[];
 extern const size_t hw_compat_2_4_len;

 extern GlobalProperty hw_compat_2_3[];
 extern const size_t hw_compat_2_3_len;

 extern GlobalProperty hw_compat_2_2[];
 extern const size_t hw_compat_2_2_len;

 extern GlobalProperty hw_compat_2_1[];
 extern const size_t hw_compat_2_1_len;

 #endif
	/* Declarations for use by board files for creating devices. */

	#ifndef HW_BOARDS_H
	#define HW_BOARDS_H

	#include "sysemu/blockdev.h"
	#include "sysemu/accel.h"
	#include "hw/qdev.h"
	#include "qom/object.h"
	#include "qom/cpu.h"

	/**
	* memory_region_allocate_system_memory - Allocate a board's main memory
	* @mr: the #MemoryRegion to be initialized
	* @owner: the object that tracks the region's reference count
	* @name: name of the memory region
	* @ram_size: size of the region in bytes
	*
	* This function allocates the main memory for a board model, and
	* initializes @mr appropriately. It also arranges for the memory
	* to be migrated (by calling vmstate_register_ram_global()).
	*
	* Memory allocated via this function will be backed with the memory
	* backend the user provided using "-mem-path" or "-numa node,memdev=..."
	* if appropriate; this is typically used to cause host huge pages to be
	* used. This function should therefore be called by a board exactly once,
	* for the primary or largest RAM area it implements.
	*
	* For boards where the major RAM is split into two parts in the memory
	* map, you can deal with this by calling memory_region_allocate_system_memory()
	* once to get a MemoryRegion with enough RAM for both parts, and then
	* creating alias MemoryRegions via memory_region_init_alias() which
	* alias into different parts of the RAM MemoryRegion and can be mapped
	* into the memory map in the appropriate places.
	*
	* Smaller pieces of memory (display RAM, static RAMs, etc) don't need
	* to be backed via the -mem-path memory backend and can simply
	* be created via memory_region_init_ram().
	*/
	void memory_region_allocate_system_memory(MemoryRegion mr, Object owner,
	const char *name,
	uint64_t ram_size);

	#define TYPE_MACHINE_SUFFIX "-machine"

	/* Machine class name that needs to be used for class-name-based machine
	* type lookup to work.
	*/
	#define MACHINE_TYPE_NAME(machinename) (machinename TYPE_MACHINE_SUFFIX)

	#define TYPE_MACHINE "machine"
	#undef MACHINE /* BSD defines it and QEMU does not use it */
	#define MACHINE(obj) \
	OBJECT_CHECK(MachineState, (obj), TYPE_MACHINE)
	#define MACHINE_GET_CLASS(obj) \
	OBJECT_GET_CLASS(MachineClass, (obj), TYPE_MACHINE)
	#define MACHINE_CLASS(klass) \
	OBJECT_CLASS_CHECK(MachineClass, (klass), TYPE_MACHINE)

	MachineClass *find_default_machine(void);
	extern MachineState *current_machine;

	void machine_run_board_init(MachineState *machine);
	bool machine_usb(MachineState *machine);
	bool machine_kernel_irqchip_allowed(MachineState *machine);
	bool machine_kernel_irqchip_required(MachineState *machine);
	bool machine_kernel_irqchip_split(MachineState *machine);
	int machine_kvm_shadow_mem(MachineState *machine);
	int machine_phandle_start(MachineState *machine);
	bool machine_dump_guest_core(MachineState *machine);
	bool machine_mem_merge(MachineState *machine);
	HotpluggableCPUList machine_query_hotpluggable_cpus(MachineState machine);
	void machine_set_cpu_numa_node(MachineState *machine,
	const CpuInstanceProperties *props,
	Error **errp);

	void machine_class_allow_dynamic_sysbus_dev(MachineClass mc, const char type);


	/**
	* CPUArchId:
	* @arch_id - architecture-dependent CPU ID of present or possible CPU
	* @cpu - pointer to corresponding CPU object if it's present on NULL otherwise
	* @type - QOM class name of possible @cpu object
	* @props - CPU object properties, initialized by board
	* #vcpus_count - number of threads provided by @cpu object
	*/
	typedef struct {
	uint64_t arch_id;
	int64_t vcpus_count;
	CpuInstanceProperties props;
	Object *cpu;
	const char *type;
	} CPUArchId;

	/**
	* CPUArchIdList:
	* @len - number of @CPUArchId items in @cpus array
	* @cpus - array of present or possible CPUs for current machine configuration
	*/
	typedef struct {
	int len;
	CPUArchId cpus[0];
	} CPUArchIdList;

	/**
	* MachineClass:
	* @deprecation_reason: If set, the machine is marked as deprecated. The
	* string should provide some clear information about what to use instead.
	* @max_cpus: maximum number of CPUs supported. Default: 1
	* @min_cpus: minimum number of CPUs supported. Default: 1
	* @default_cpus: number of CPUs instantiated if none are specified. Default: 1
	* @get_hotplug_handler: this function is called during bus-less
	* device hotplug. If defined it returns pointer to an instance
	* of HotplugHandler object, which handles hotplug operation
	* for a given @dev. It may return NULL if @dev doesn't require
	* any actions to be performed by hotplug handler.
	* @cpu_index_to_instance_props:
	* used to provide @cpu_index to socket/core/thread number mapping, allowing
	* legacy code to perform maping from cpu_index to topology properties
	* Returns: tuple of socket/core/thread ids given cpu_index belongs to.
	* used to provide @cpu_index to socket number mapping, allowing
	* a machine to group CPU threads belonging to the same socket/package
	* Returns: socket number given cpu_index belongs to.
	* @hw_version:
	* Value of QEMU_VERSION when the machine was added to QEMU.
	* Set only by old machines because they need to keep
	* compatibility on code that exposed QEMU_VERSION to guests in
	* the past (and now use qemu_hw_version()).
	* @possible_cpu_arch_ids:
	* Returns an array of @CPUArchId architecture-dependent CPU IDs
	* which includes CPU IDs for present and possible to hotplug CPUs.
	* Caller is responsible for freeing returned list.
	* @get_default_cpu_node_id:
	* returns default board specific node_id value for CPU slot specified by
	* index @idx in @ms->possible_cpus[]
	* @has_hotpluggable_cpus:
	* If true, board supports CPUs creation with -device/device_add.
	* @default_cpu_type:
	* specifies default CPU_TYPE, which will be used for parsing target
	* specific features and for creating CPUs if CPU name wasn't provided
	* explicitly at CLI
	* @minimum_page_bits:
	* If non-zero, the board promises never to create a CPU with a page size
	* smaller than this, so QEMU can use a more efficient larger page
	* size than the target architecture's minimum. (Attempting to create
	* such a CPU will fail.) Note that changing this is a migration
	* compatibility break for the machine.
	* @ignore_memory_transaction_failures:
	* If this is flag is true then the CPU will ignore memory transaction
	* failures which should cause the CPU to take an exception due to an
	* access to an unassigned physical address; the transaction will instead
	* return zero (for a read) or be ignored (for a write). This should be
	* set only by legacy board models which rely on the old RAZ/WI behaviour
	* for handling devices that QEMU does not yet model. New board models
	* should instead use "unimplemented-device" for all memory ranges where
	* the guest will attempt to probe for a device that QEMU doesn't
	* implement and a stub device is required.
	* @kvm_type:
	* Return the type of KVM corresponding to the kvm-type string option or
	* computed based on other criteria such as the host kernel capabilities.
	*/
	struct MachineClass {
	/< private >/
	ObjectClass parent_class;
	/< public >/

	const char family; / NULL iff @name identifies a standalone machtype */
	char *name;
	const char *alias;
	const char *desc;
	const char *deprecation_reason;

	void (init)(MachineState state);
	void (*reset)(void);
	void (hot_add_cpu)(const int64_t id, Error *errp);
	int (kvm_type)(MachineState machine, const char *arg);

	BlockInterfaceType block_default_type;
	int units_per_default_bus;
	int max_cpus;
	int min_cpus;
	int default_cpus;
	unsigned int no_serial:1,
	no_parallel:1,
	no_floppy:1,
	no_cdrom:1,
	no_sdcard:1,
	pci_allow_0_address:1,
	legacy_fw_cfg_order:1;
	int is_default;
	const char *default_machine_opts;
	const char *default_boot_order;
	const char *default_display;
	GPtrArray *compat_props;
	const char *hw_version;
	ram_addr_t default_ram_size;
	const char *default_cpu_type;
	bool default_kernel_irqchip_split;
	bool option_rom_has_mr;
	bool rom_file_has_mr;
	int minimum_page_bits;
	bool has_hotpluggable_cpus;
	bool ignore_memory_transaction_failures;
	int numa_mem_align_shift;
	const char **valid_cpu_types;
	strList *allowed_dynamic_sysbus_devices;
	bool auto_enable_numa_with_memhp;
	void (numa_auto_assign_ram)(MachineClass mc, NodeInfo *nodes,
	int nb_nodes, ram_addr_t size);
	bool ignore_boot_device_suffixes;
	bool smbus_no_migration_support;

	HotplugHandler (get_hotplug_handler)(MachineState *machine,
	DeviceState *dev);
	CpuInstanceProperties (cpu_index_to_instance_props)(MachineState machine,
	unsigned cpu_index);
	const CPUArchIdList (possible_cpu_arch_ids)(MachineState *machine);
	int64_t (get_default_cpu_node_id)(const MachineState ms, int idx);
	};

	/**
	* DeviceMemoryState:
	* @base: address in guest physical address space where the memory
	* address space for memory devices starts
	* @mr: address space container for memory devices
	*/
	typedef struct DeviceMemoryState {
	hwaddr base;
	MemoryRegion mr;
	} DeviceMemoryState;

	/**
	* MachineState:
	*/
	struct MachineState {
	/< private >/
	Object parent_obj;
	Notifier sysbus_notifier;

	/< public >/

	char *accel;
	bool kernel_irqchip_allowed;
	bool kernel_irqchip_required;
	bool kernel_irqchip_split;
	int kvm_shadow_mem;
	char *dtb;
	char *dumpdtb;
	int phandle_start;
	char *dt_compatible;
	bool dump_guest_core;
	bool mem_merge;
	bool usb;
	bool usb_disabled;
	bool igd_gfx_passthru;
	char *firmware;
	bool iommu;
	bool suppress_vmdesc;
	bool enforce_config_section;
	bool enable_graphics;
	char *memory_encryption;
	DeviceMemoryState *device_memory;

	ram_addr_t ram_size;
	ram_addr_t maxram_size;
	uint64_t ram_slots;
	const char *boot_order;
	char *kernel_filename;
	char *kernel_cmdline;
	char *initrd_filename;
	const char *cpu_type;
	AccelState *accelerator;
	CPUArchIdList *possible_cpus;
	};

	#define DEFINE_MACHINE(namestr, machine_initfn) \
	static void machine_initfn##_class_init(ObjectClass oc, void data) \
	{ \
	MachineClass *mc = MACHINE_CLASS(oc); \
	machine_initfn(mc); \
	} \
	static const TypeInfo machine_initfn##_typeinfo = { \
	.name = MACHINE_TYPE_NAME(namestr), \
	.parent = TYPE_MACHINE, \
	.class_init = machine_initfn##_class_init, \
	}; \
	static void machine_initfn##_register_types(void) \
	{ \
	type_register_static(&machine_initfn##_typeinfo); \
	} \
	type_init(machine_initfn##_register_types)

	extern GlobalProperty hw_compat_3_1[];
	extern const size_t hw_compat_3_1_len;

	extern GlobalProperty hw_compat_3_0[];
	extern const size_t hw_compat_3_0_len;

	extern GlobalProperty hw_compat_2_12[];
	extern const size_t hw_compat_2_12_len;

	extern GlobalProperty hw_compat_2_11[];
	extern const size_t hw_compat_2_11_len;

	extern GlobalProperty hw_compat_2_10[];
	extern const size_t hw_compat_2_10_len;

	extern GlobalProperty hw_compat_2_9[];
	extern const size_t hw_compat_2_9_len;

	extern GlobalProperty hw_compat_2_8[];
	extern const size_t hw_compat_2_8_len;

	extern GlobalProperty hw_compat_2_7[];
	extern const size_t hw_compat_2_7_len;

	extern GlobalProperty hw_compat_2_6[];
	extern const size_t hw_compat_2_6_len;

	extern GlobalProperty hw_compat_2_5[];
	extern const size_t hw_compat_2_5_len;

	extern GlobalProperty hw_compat_2_4[];
	extern const size_t hw_compat_2_4_len;

	extern GlobalProperty hw_compat_2_3[];
	extern const size_t hw_compat_2_3_len;

	extern GlobalProperty hw_compat_2_2[];
	extern const size_t hw_compat_2_2_len;

	extern GlobalProperty hw_compat_2_1[];
	extern const size_t hw_compat_2_1_len;

	#endif