| .. _kernelobjects: |
| |
| Kernel Objects |
| ############## |
| |
| A kernel object can be one of three classes of data: |
| |
| * A core kernel object, such as a semaphore, thread, pipe, etc. |
| * A thread stack, which is an array of :c:struct:`z_thread_stack_element` |
| and declared with :c:macro:`K_THREAD_STACK_DEFINE()` |
| * A device driver instance (const struct device) that belongs to one of a defined |
| set of subsystems |
| |
| The set of known kernel objects and driver subsystems is defined in |
| include/kernel.h as :c:enum:`k_objects`. |
| |
| Kernel objects are completely opaque to user threads. User threads work |
| with addresses to kernel objects when making API calls, but may never |
| dereference these addresses, doing so will cause a memory protection fault. |
| All kernel objects must be placed in memory that is not accessible by |
| user threads. |
| |
| Since user threads may not directly manipulate kernel objects, all use of |
| them must go through system calls. In order to perform a system call on |
| a kernel object, checks are performed by system call handler functions |
| that the kernel object address is valid and that the calling thread |
| has sufficient permissions to work with it. |
| |
| Permission on an object also has the semantics of a reference to an object. |
| This is significant for certain object APIs which do temporary allocations, |
| or objects which themselves have been allocated from a runtime memory pool. |
| |
| If an object loses all references, two events may happen: |
| |
| * If the object has an associated cleanup function, the cleanup function |
| may be called to release any runtime-allocated buffers the object was using. |
| |
| * If the object itself was dynamically allocated, the memory for the object |
| will be freed. |
| |
| Object Placement |
| **************** |
| |
| Kernel objects that are only used by supervisor threads have no restrictions |
| and can be located anywhere in the binary, or even declared on stacks. However, |
| to prevent accidental or intentional corruption by user threads, they must |
| not be located in any memory that user threads have direct access to. |
| |
| In order for a static kernel object to be usable by a user thread via system |
| call APIs, several conditions must be met on how the kernel object is declared: |
| |
| * The object must be declared as a top-level global at build time, such that it |
| appears in the ELF symbol table. It is permitted to declare kernel objects |
| with static scope. The post-build script :ref:`gen_kobject_list.py` scans the |
| generated ELF file to find kernel objects and places their memory addresses |
| in a special table of kernel object metadata. Kernel objects may be members |
| of arrays or embedded within other data structures. |
| |
| * Kernel objects must be located in memory reserved for the kernel. They |
| must not be located in any memory partitions that are user-accessible. |
| |
| * Any memory reserved for a kernel object must be used exclusively for that |
| object. Kernel objects may not be members of a union data type. |
| |
| Kernel objects that are found but do not meet the above conditions will not be |
| included in the generated table that is used to validate kernel object pointers |
| passed in from user mode. |
| |
| The debug output of the :ref:`gen_kobject_list.py` script may be useful when |
| debugging why some object was unexpectedly not being tracked. This |
| information will be printed if the script is run with the ``--verbose`` flag, |
| or if the build system is invoked with verbose output. |
| |
| Dynamic Objects |
| *************** |
| |
| Kernel objects may also be allocated at runtime if |
| :option:`CONFIG_DYNAMIC_OBJECTS` is enabled. In this case, the |
| :c:func:`k_object_alloc` API may be used to instantiate an object from |
| the calling thread's resource pool. Such allocations may be freed in two |
| ways: |
| |
| * Supervisor threads may call :c:func:`k_object_free` to force a dynamic |
| object to be released. |
| |
| * If an object's references drop to zero (which happens when no threads have |
| permissions on it) the object will be automatically freed. User threads |
| may drop their own permission on an object with |
| :c:func:`k_object_release`, and their permissions are automatically |
| cleared when a thread terminates. Supervisor threads may additionally |
| revoke references for another thread using |
| :c:func:`k_object_access_revoke`. |
| |
| Because permissions are also used for reference counting, it is important for |
| supervisor threads to acquire permissions on objects they are using even though |
| the access control aspects of the permission system are not enforced. |
| |
| Implementation Details |
| ====================== |
| |
| The :ref:`gen_kobject_list.py` script is a post-build step which finds all the |
| valid kernel object instances in the binary. It accomplishes this by parsing |
| the DWARF debug information present in the generated ELF file for the kernel. |
| |
| Any instances of structs or arrays corresponding to kernel objects that meet |
| the object placement criteria will have their memory addresses placed in a |
| special perfect hash table of kernel objects generated by the 'gperf' tool. |
| When a system call is made and the kernel is presented with a memory address |
| of what may or may not be a valid kernel object, the address can be validated |
| with a constant-time lookup in this table. |
| |
| Drivers are a special case. All drivers are instances of :c:struct:`device`, but |
| it is important to know what subsystem a driver belongs to so that |
| incorrect operations, such as calling a UART API on a sensor driver object, can |
| be prevented. When a device struct is found, its API pointer is examined to |
| determine what subsystem the driver belongs to. |
| |
| The table itself maps kernel object memory addresses to instances of |
| :c:struct:`z_object`, which has all the metadata for that object. This |
| includes: |
| |
| * A bitfield indicating permissions on that object. All threads have a |
| numerical ID assigned to them at build time, used to index the permission |
| bitfield for an object to see if that thread has permission on it. The size |
| of this bitfield is controlled by the :option:`CONFIG_MAX_THREAD_BYTES` |
| option and the build system will generate an error if this value is too low. |
| * A type field indicating what kind of object this is, which is some |
| instance of :c:enum:`k_objects`. |
| * A set of flags for that object. This is currently used to track |
| initialization state and whether an object is public or not. |
| * An extra data field. The semantics of this field vary by object type, see |
| the definition of :c:union:`z_object_data`. |
| |
| Dynamic objects allocated at runtime are tracked in a runtime red/black tree |
| which is used in parallel to the gperf table when validating object pointers. |
| |
| Supervisor Thread Access Permission |
| *********************************** |
| |
| Supervisor threads can access any kernel object. However, permissions for |
| supervisor threads are still tracked for two reasons: |
| |
| * If a supervisor thread calls :c:func:`k_thread_user_mode_enter`, the |
| thread will then run in user mode with any permissions it had been granted |
| (in many cases, by itself) when it was a supervisor thread. |
| |
| * If a supervisor thread creates a user thread with the |
| :c:macro:`K_INHERIT_PERMS` option, the child thread will be granted the |
| same permissions as the parent thread, except the parent thread object. |
| |
| User Thread Access Permission |
| ***************************** |
| |
| By default, when a user thread is created, it will only have access permissions |
| on its own thread object. Other kernel objects by default are not usable. |
| Access to them needs to be explicitly or implicitly granted. There are several |
| ways to do this. |
| |
| * If a thread is created with the :c:macro:`K_INHERIT_PERMS`, that thread |
| will inherit all the permissions of the parent thread, except the parent |
| thread object. |
| |
| * A thread that has permission on an object, or is running in supervisor mode, |
| may grant permission on that object to another thread via the |
| :c:func:`k_object_access_grant` API. The convenience pseudo-function |
| :c:func:`k_thread_access_grant` may also be used, which accepts an arbitrary |
| number of pointers to kernel objects and calls |
| :c:func:`k_object_access_grant` on each of them. The thread being granted |
| permission, or the object whose access is being granted, do not need to be |
| in an initialized state. If the caller is from user mode, the caller must |
| have permissions on both the kernel object and the target thread object. |
| |
| * Supervisor threads may declare a particular kernel object to be a public |
| object, usable by all current and future threads with the |
| :c:func:`k_object_access_all_grant` API. You must assume that any |
| untrusted or exploited code will then be able to access the object. Use |
| this API with caution! |
| |
| * If a thread was declared statically with :c:macro:`K_THREAD_DEFINE()`, |
| then the :c:macro:`K_THREAD_ACCESS_GRANT()` may be used to grant that thread |
| access to a set of kernel objects at boot time. |
| |
| Once a thread has been granted access to an object, such access may be |
| removed with the :c:func:`k_object_access_revoke` API. This API is not |
| available to user threads, however user threads may use |
| :c:func:`k_object_release` to relinquish their own permissions on an |
| object. |
| |
| API calls from supervisor mode to set permissions on kernel objects that are |
| not being tracked by the kernel will be no-ops. Doing the same from user mode |
| will result in a fatal error for the calling thread. |
| |
| Objects allocated with :c:func:`k_object_alloc` implicitly grant |
| permission on the allocated object to the calling thread. |
| |
| Initialization State |
| ******************** |
| |
| Most operations on kernel objects will fail if the object is considered to be |
| in an uninitialized state. The appropriate init function for the object must |
| be performed first. |
| |
| Some objects will be implicitly initialized at boot: |
| |
| * Kernel objects that were declared with static initialization macros |
| (such as :c:macro:`K_SEM_DEFINE` for semaphores) will be in an initialized |
| state at build time. |
| |
| * Device driver objects are considered initialized after their init function |
| is run by the kernel early in the boot process. |
| |
| If a kernel object is initialized with a private static initializer, the object |
| must have :c:func:`z_object_init` called on it at some point by a supervisor |
| thread, otherwise the kernel will consider the object uninitialized if accessed |
| by a user thread. This is very uncommon, typically only for kernel objects that |
| are embedded within some larger struct and initialized statically. |
| |
| .. code-block:: c |
| |
| struct foo { |
| struct k_sem sem; |
| ... |
| }; |
| |
| struct foo my_foo = { |
| .sem = Z_SEM_INITIALIZER(my_foo.sem, 0, 1), |
| ... |
| }; |
| |
| ... |
| z_object_init(&my_foo.sem); |
| ... |
| |
| |
| Creating New Kernel Object Types |
| ******************************** |
| |
| When implementing new kernel features or driver subsystems, it may be necessary |
| to define some new kernel object types. There are different steps needed |
| for creating core kernel objects and new driver subsystems. |
| |
| Creating New Core Kernel Objects |
| ================================ |
| |
| * In ``scripts/gen_kobject_list.py``, add the name of the struct to the |
| :py:data:`kobjects` list. |
| |
| Instances of the new struct should now be tracked. |
| |
| Creating New Driver Subsystem Kernel Objects |
| ============================================ |
| |
| All driver instances are :c:struct:`device`. They are differentiated by |
| what API struct they are set to. |
| |
| * In ``scripts/gen_kobject_list.py``, add the name of the API struct for the |
| new subsystem to the :py:data:`subsystems` list. |
| |
| Driver instances of the new subsystem should now be tracked. |
| |
| Configuration Options |
| ********************* |
| |
| Related configuration options: |
| |
| * :option:`CONFIG_USERSPACE` |
| * :option:`CONFIG_MAX_THREAD_BYTES` |
| |
| API Reference |
| ************* |
| |
| .. doxygengroup:: usermode_apis |
| :project: Zephyr |