// Copyright 2016 The Fuchsia Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef ZIRCON_SYSCALLS_OBJECT_H_
#define ZIRCON_SYSCALLS_OBJECT_H_
#include <zircon/types.h>
__BEGIN_CDECLS
// ask clang format not to mess up the indentation:
// clang-format off
// Valid topics for zx_object_get_info.
typedef uint32_t zx_object_info_topic_t;
#define ZX_INFO_NONE ((zx_object_info_topic_t) 0u)
#define ZX_INFO_HANDLE_VALID ((zx_object_info_topic_t) 1u)
#define ZX_INFO_HANDLE_BASIC ((zx_object_info_topic_t) 2u) // zx_info_handle_basic_t[1]
#define ZX_INFO_PROCESS ((zx_object_info_topic_t) 3u) // zx_info_process_t[1]
#define ZX_INFO_PROCESS_THREADS ((zx_object_info_topic_t) 4u) // zx_koid_t[n]
#define ZX_INFO_VMAR ((zx_object_info_topic_t) 7u) // zx_info_vmar_t[1]
#define ZX_INFO_JOB_CHILDREN ((zx_object_info_topic_t) 8u) // zx_koid_t[n]
#define ZX_INFO_JOB_PROCESSES ((zx_object_info_topic_t) 9u) // zx_koid_t[n]
#define ZX_INFO_THREAD ((zx_object_info_topic_t) 10u) // zx_info_thread_t[1]
#define ZX_INFO_THREAD_EXCEPTION_REPORT ((zx_object_info_topic_t) 11u) // zx_exception_report_t[1]
#define ZX_INFO_TASK_STATS ((zx_object_info_topic_t) 12u) // zx_info_task_stats_t[1]
#define ZX_INFO_PROCESS_MAPS ((zx_object_info_topic_t) 13u) // zx_info_maps_t[n]
#define ZX_INFO_PROCESS_VMOS ((zx_object_info_topic_t) 14u) // zx_info_vmo_t[n]
#define ZX_INFO_THREAD_STATS ((zx_object_info_topic_t) 15u) // zx_info_thread_stats_t[1]
#define ZX_INFO_CPU_STATS ((zx_object_info_topic_t) 16u) // zx_info_cpu_stats_t[n]
#define ZX_INFO_KMEM_STATS ((zx_object_info_topic_t) 17u) // zx_info_kmem_stats_t[1]
#define ZX_INFO_RESOURCE ((zx_object_info_topic_t) 18u) // zx_info_resource_t[1]
#define ZX_INFO_HANDLE_COUNT ((zx_object_info_topic_t) 19u) // zx_info_handle_count_t[1]
#define ZX_INFO_BTI ((zx_object_info_topic_t) 20u) // zx_info_bti_t[1]
#define ZX_INFO_PROCESS_HANDLE_STATS ((zx_object_info_topic_t) 21u) // zx_info_process_handle_stats_t[1]
#define ZX_INFO_SOCKET ((zx_object_info_topic_t) 22u) // zx_info_socket_t[1]
#define ZX_INFO_VMO ((zx_object_info_topic_t) 23u) // zx_info_vmo_t[1]
typedef uint32_t zx_obj_props_t;
#define ZX_OBJ_PROP_NONE ((zx_obj_props_t)0u)
#define ZX_OBJ_PROP_WAITABLE ((zx_obj_props_t)1u)
typedef struct zx_info_handle_basic {
// The unique id assigned by kernel to the object referenced by the
// handle.
zx_koid_t koid;
// The immutable rights assigned to the handle. Two handles that
// have the same koid and the same rights are equivalent and
// interchangeable.
zx_rights_t rights;
// The object type: channel, event, socket, etc.
zx_obj_type_t type;
// If the object referenced by the handle is related to another (such
// as the other end of a channel, or the parent of a job) then
// |related_koid| is the koid of that object, otherwise it is zero.
// This relationship is immutable: an object's |related_koid| does
// not change even if the related object no longer exists.
zx_koid_t related_koid;
// Set to ZX_OBJ_PROP_WAITABLE if the object referenced by the
// handle can be waited on; zero otherwise.
zx_obj_props_t props;
} zx_info_handle_basic_t;
typedef struct zx_info_handle_count {
// The number of outstanding handles to a kernel object.
uint32_t handle_count;
} zx_info_handle_count_t;
typedef struct zx_info_process_handle_stats {
// The number of outstanding handles to kernel objects of each type.
uint32_t handle_count[64];
} zx_info_process_handle_stats_t;
typedef struct zx_info_process {
// The process's return code; only valid if |exited| is true.
// Guaranteed to be non-zero if the process was killed by |zx_task_kill|.
int64_t return_code;
// True if the process has ever left the initial creation state,
// even if it has exited as well.
bool started;
// If true, the process has exited and |return_code| is valid.
bool exited;
// True if a debugger is attached to the process.
bool debugger_attached;
} zx_info_process_t;
typedef uint32_t zx_thread_state_t;
typedef struct zx_info_thread {
// One of ZX_THREAD_STATE_* values.
zx_thread_state_t state;
// If |state| is ZX_THREAD_STATE_BLOCKED_EXCEPTION, the thread has gotten
// an exception and is waiting for the exception to be handled by the
// specified port.
// The value is one of ZX_EXCEPTION_PORT_TYPE_*.
uint32_t wait_exception_port_type;
} zx_info_thread_t;
typedef struct zx_info_thread_stats {
// Total accumulated running time of the thread.
zx_duration_t total_runtime;
} zx_info_thread_stats_t;
// Statistics about resources (e.g., memory) used by a task. Can be relatively
// expensive to gather.
typedef struct zx_info_task_stats {
// The total size of mapped memory ranges in the task.
// Not all will be backed by physical memory.
size_t mem_mapped_bytes;
// For the fields below, a byte is considered committed if it's backed by
// physical memory. Some of the memory may be double-mapped, and thus
// double-counted.
// Committed memory that is only mapped into this task.
size_t mem_private_bytes;
// Committed memory that is mapped into this and at least one other task.
size_t mem_shared_bytes;
// A number that estimates the fraction of mem_shared_bytes that this
// task is responsible for keeping alive.
//
// An estimate of:
// For each shared, committed byte:
// mem_scaled_shared_bytes += 1 / (number of tasks mapping this byte)
//
// This number is strictly smaller than mem_shared_bytes.
size_t mem_scaled_shared_bytes;
} zx_info_task_stats_t;
typedef struct zx_info_vmar {
// Base address of the region.
uintptr_t base;
// Length of the region, in bytes.
size_t len;
} zx_info_vmar_t;
typedef struct zx_info_bti {
// zx_bti_pin will always be able to return addresses that are contiguous for at
// least this many bytes. E.g. if this returns 1MB, then a call to
// zx_bti_pin() with a size of 2MB will return at most two physically-contiguous runs.
// If the size were 2.5MB, it will return at most three physically-contiguous runs.
uint64_t minimum_contiguity;
// The number of bytes in the device's address space (UINT64_MAX if 2^64).
uint64_t aspace_size;
} zx_info_bti_t;
typedef struct zx_info_socket {
// The options passed to zx_socket_create().
uint32_t options;
// The maximum size of the receive buffer of a socket, in bytes.
//
// The receive buffer may become full at a capacity less than the maximum
// due to overhead.
size_t rx_buf_max;
// The size of the receive buffer of a socket, in bytes.
size_t rx_buf_size;
// The amount of data, in bytes, that is available for reading in a single
// zx_socket_read call.
//
// For stream sockets, this value will match |rx_buf_size|. For datagram
// sockets, this value will be the size of the next datagram in the receive
// buffer.
size_t rx_buf_available;
// The maximum size of the transmit buffer of a socket, in bytes.
//
// The transmit buffer may become full at a capacity less than the maximum
// due to overhead.
//
// Will be zero if the peer endpoint is closed.
size_t tx_buf_max;
// The size of the transmit buffer of a socket, in bytes.
//
// Will be zero if the peer endpoint is closed.
size_t tx_buf_size;
} zx_info_socket_t;
// Types and values used by ZX_INFO_PROCESS_MAPS.
// Describes a VM mapping.
typedef struct zx_info_maps_mapping {
// MMU flags for the mapping.
// Bitwise OR of ZX_VM_PERM_{READ,WRITE,EXECUTE} values.
zx_vm_option_t mmu_flags;
// koid of the mapped VMO.
zx_koid_t vmo_koid;
// Offset into the above VMO.
uint64_t vmo_offset;
// The number of PAGE_SIZE pages in the mapped region of the VMO
// that are backed by physical memory.
size_t committed_pages;
} zx_info_maps_mapping_t;
// Types of entries represented by zx_info_maps_t.
// Can't use zx_obj_type_t because not all of these are
// user-visible kernel object types.
typedef uint32_t zx_info_maps_type_t;
#define ZX_INFO_MAPS_TYPE_NONE ((zx_info_maps_type_t) 0u)
#define ZX_INFO_MAPS_TYPE_ASPACE ((zx_info_maps_type_t) 1u)
#define ZX_INFO_MAPS_TYPE_VMAR ((zx_info_maps_type_t) 2u)
#define ZX_INFO_MAPS_TYPE_MAPPING ((zx_info_maps_type_t) 3u)
// Describes a node in the aspace/vmar/mapping hierarchy for a user process.
typedef struct zx_info_maps {
// Name if available; empty string otherwise.
char name[ZX_MAX_NAME_LEN];
// Base address.
zx_vaddr_t base;
// Size in bytes.
size_t size;
// The depth of this node in the tree.
// Can be used for indentation, or to rebuild the tree from an array
// of zx_info_maps_t entries, which will be in depth-first pre-order.
size_t depth;
// The type of this entry; indicates which union entry is valid.
zx_info_maps_type_t type;
union {
zx_info_maps_mapping_t mapping;
// No additional fields for other types.
} u;
} zx_info_maps_t;
// Values and types used by ZX_INFO_PROCESS_VMOS.
// The VMO is backed by RAM, consuming memory.
// Mutually exclusive with ZX_INFO_VMO_TYPE_PHYSICAL.
// See ZX_INFO_VMO_TYPE(flags)
#define ZX_INFO_VMO_TYPE_PAGED (1u<<0)
// The VMO points to a physical address range, and does not consume memory.
// Typically used to access memory-mapped hardware.
// Mutually exclusive with ZX_INFO_VMO_TYPE_PAGED.
// See ZX_INFO_VMO_TYPE(flags)
#define ZX_INFO_VMO_TYPE_PHYSICAL (0u<<0)
// Returns a VMO's type based on its flags, allowing for checks like
// if (ZX_INFO_VMO_TYPE(f) == ZX_INFO_VMO_TYPE_PAGED)
#define ZX_INFO_VMO_TYPE(flags) ((flags) & (1u<<0))
// The VMO is a clone, and is a copy-on-write clone.
#define ZX_INFO_VMO_IS_COW_CLONE (1u<<2)
// When reading a list of VMOs pointed to by a process, indicates that the
// process has a handle to the VMO, which isn't necessarily mapped.
#define ZX_INFO_VMO_VIA_HANDLE (1u<<3)
// When reading a list of VMOs pointed to by a process, indicates that the
// process maps the VMO into a VMAR, but doesn't necessarily have a handle to
// the VMO.
#define ZX_INFO_VMO_VIA_MAPPING (1u<<4)
// Describes a VMO. For mapping information, see |zx_info_maps_t|.
typedef struct zx_info_vmo {
// The koid of this VMO.
zx_koid_t koid;
// The name of this VMO.
char name[ZX_MAX_NAME_LEN];
// The size of this VMO; i.e., the amount of virtual address space it
// would consume if mapped.
uint64_t size_bytes;
// If this VMO is a clone, the koid of its parent. Otherwise, zero.
// See |flags| for the type of clone.
zx_koid_t parent_koid;
// The number of clones of this VMO, if any.
size_t num_children;
// The number of times this VMO is currently mapped into VMARs.
// Note that the same process will often map the same VMO twice,
// and both mappings will be counted here. (I.e., this is not a count
// of the number of processes that map this VMO; see share_count.)
size_t num_mappings;
// An estimate of the number of unique address spaces that
// this VMO is mapped into. Every process has its own address space,
// and so does the kernel.
size_t share_count;
// Bitwise OR of ZX_INFO_VMO_* values.
uint32_t flags;
// If |ZX_INFO_VMO_TYPE(flags) == ZX_INFO_VMO_TYPE_PAGED|, the amount of
// memory currently allocated to this VMO; i.e., the amount of physical
// memory it consumes. Undefined otherwise.
uint64_t committed_bytes;
// If |flags & ZX_INFO_VMO_VIA_HANDLE|, the handle rights.
// Undefined otherwise.
zx_rights_t handle_rights;
// VMO creation options. This is a bitmask of
// kResizable = (1u << 0);
// kContiguous = (1u << 1);
uint32_t create_options;
// VMO mapping cache policy. One of ZX_CACHE_POLICY_*
uint32_t cache_policy;
} zx_info_vmo_t;
// kernel statistics per cpu
// TODO(cpu), expose the deprecated stats via a new syscall.
typedef struct zx_info_cpu_stats {
uint32_t cpu_number;
uint32_t flags;
zx_duration_t idle_time;
// kernel scheduler counters
uint64_t reschedules;
uint64_t context_switches;
uint64_t irq_preempts;
uint64_t preempts;
uint64_t yields;
// cpu level interrupts and exceptions
uint64_t ints; // hardware interrupts, minus timer interrupts or inter-processor interrupts
uint64_t timer_ints; // timer interrupts
uint64_t timers; // timer callbacks
uint64_t page_faults; // (deprecated, returns 0) page faults
uint64_t exceptions; // (deprecated, returns 0) exceptions such as undefined opcode
uint64_t syscalls;
// inter-processor interrupts
uint64_t reschedule_ipis;
uint64_t generic_ipis;
} zx_info_cpu_stats_t;
// Information about kernel memory usage.
// Can be expensive to gather.
typedef struct zx_info_kmem_stats {
// The total amount of physical memory available to the system.
uint64_t total_bytes;
// The amount of unallocated memory.
uint64_t free_bytes;
// The amount of memory reserved by and mapped into the kernel for reasons
// not covered by other fields in this struct. Typically for readonly data
// like the ram disk and kernel image, and for early-boot dynamic memory.
uint64_t wired_bytes;
// The amount of memory allocated to the kernel heap.
uint64_t total_heap_bytes;
// The portion of |total_heap_bytes| that is not in use.
uint64_t free_heap_bytes;
// The amount of memory committed to VMOs, both kernel and user.
// A superset of all userspace memory.
// Does not include certain VMOs that fall under |wired_bytes|.
//
// TODO(dbort): Break this into at least two pieces: userspace VMOs that
// have koids, and kernel VMOs that don't. Or maybe look at VMOs
// mapped into the kernel aspace vs. everything else.
uint64_t vmo_bytes;
// The amount of memory used for architecture-specific MMU metadata
// like page tables.
uint64_t mmu_overhead_bytes;
// The amount of memory in use by IPC.
uint64_t ipc_bytes;
// Non-free memory that isn't accounted for in any other field.
uint64_t other_bytes;
} zx_info_kmem_stats_t;
typedef struct zx_info_resource {
// The resource kind; resource object kinds are detailed in the resource.md
uint32_t kind;
// Resource's creation flags
uint32_t flags;
// Resource's base value (inclusive)
uint64_t base;
// Resource's length value
size_t size;
char name[ZX_MAX_NAME_LEN];
} zx_info_resource_t;
#define ZX_INFO_CPU_STATS_FLAG_ONLINE (1u<<0)
// Object properties.
// Argument is a char[ZX_MAX_NAME_LEN].
#define ZX_PROP_NAME ((uint32_t) 3u)
#if __x86_64__
// Argument is a uintptr_t.
#define ZX_PROP_REGISTER_GS ((uint32_t) 2u)
#define ZX_PROP_REGISTER_FS ((uint32_t) 4u)
#endif
// Argument is the value of ld.so's _dl_debug_addr, a uintptr_t. If the
// property is set to the magic value of ZX_PROCESS_DEBUG_ADDR_BREAK_ON_SET
// on process startup, ld.so will trigger a debug breakpoint immediately after
// setting the property to the correct value.
#define ZX_PROP_PROCESS_DEBUG_ADDR ((uint32_t) 5u)
#define ZX_PROCESS_DEBUG_ADDR_BREAK_ON_SET ((uintptr_t) 1u)
// Argument is the base address of the vDSO mapping (or zero), a uintptr_t.
#define ZX_PROP_PROCESS_VDSO_BASE_ADDRESS ((uint32_t) 6u)
// Argument is a size_t.
#define ZX_PROP_SOCKET_RX_THRESHOLD 12u
#define ZX_PROP_SOCKET_TX_THRESHOLD 13u
// Terminate this job if the system is low on memory.
#define ZX_PROP_JOB_KILL_ON_OOM 15u
// Basic thread states, in zx_info_thread_t.state.
#define ZX_THREAD_STATE_NEW ((zx_thread_state_t) 0x0000u)
#define ZX_THREAD_STATE_RUNNING ((zx_thread_state_t) 0x0001u)
#define ZX_THREAD_STATE_SUSPENDED ((zx_thread_state_t) 0x0002u)
// ZX_THREAD_STATE_BLOCKED is never returned by itself.
// It is always returned with a more precise reason.
// See ZX_THREAD_STATE_BLOCKED_* below.
#define ZX_THREAD_STATE_BLOCKED ((zx_thread_state_t) 0x0003u)
#define ZX_THREAD_STATE_DYING ((zx_thread_state_t) 0x0004u)
#define ZX_THREAD_STATE_DEAD ((zx_thread_state_t) 0x0005u)
// More precise thread states.
#define ZX_THREAD_STATE_BLOCKED_EXCEPTION ((zx_thread_state_t) 0x0103u)
#define ZX_THREAD_STATE_BLOCKED_SLEEPING ((zx_thread_state_t) 0x0203u)
#define ZX_THREAD_STATE_BLOCKED_FUTEX ((zx_thread_state_t) 0x0303u)
#define ZX_THREAD_STATE_BLOCKED_PORT ((zx_thread_state_t) 0x0403u)
#define ZX_THREAD_STATE_BLOCKED_CHANNEL ((zx_thread_state_t) 0x0503u)
#define ZX_THREAD_STATE_BLOCKED_WAIT_ONE ((zx_thread_state_t) 0x0603u)
#define ZX_THREAD_STATE_BLOCKED_WAIT_MANY ((zx_thread_state_t) 0x0703u)
#define ZX_THREAD_STATE_BLOCKED_INTERRUPT ((zx_thread_state_t) 0x0803u)
// Reduce possibly-more-precise state to a basic state.
// Useful if, for example, you want to check for BLOCKED on anything.
#define ZX_THREAD_STATE_BASIC(n) ((n) & 0xff)
__END_CDECLS
#endif // ZIRCON_SYSCALLS_OBJECT_H_