| .. SPDX-License-Identifier: GPL-2.0+ |
| |
| .. |ssam_controller| replace:: :c:type:`struct ssam_controller <ssam_controller>` |
| .. |ssam_device| replace:: :c:type:`struct ssam_device <ssam_device>` |
| .. |ssam_device_driver| replace:: :c:type:`struct ssam_device_driver <ssam_device_driver>` |
| .. |ssam_client_bind| replace:: :c:func:`ssam_client_bind` |
| .. |ssam_client_link| replace:: :c:func:`ssam_client_link` |
| .. |ssam_get_controller| replace:: :c:func:`ssam_get_controller` |
| .. |ssam_controller_get| replace:: :c:func:`ssam_controller_get` |
| .. |ssam_controller_put| replace:: :c:func:`ssam_controller_put` |
| .. |ssam_device_alloc| replace:: :c:func:`ssam_device_alloc` |
| .. |ssam_device_add| replace:: :c:func:`ssam_device_add` |
| .. |ssam_device_remove| replace:: :c:func:`ssam_device_remove` |
| .. |ssam_device_driver_register| replace:: :c:func:`ssam_device_driver_register` |
| .. |ssam_device_driver_unregister| replace:: :c:func:`ssam_device_driver_unregister` |
| .. |module_ssam_device_driver| replace:: :c:func:`module_ssam_device_driver` |
| .. |SSAM_DEVICE| replace:: :c:func:`SSAM_DEVICE` |
| .. |ssam_notifier_register| replace:: :c:func:`ssam_notifier_register` |
| .. |ssam_notifier_unregister| replace:: :c:func:`ssam_notifier_unregister` |
| .. |ssam_device_notifier_register| replace:: :c:func:`ssam_device_notifier_register` |
| .. |ssam_device_notifier_unregister| replace:: :c:func:`ssam_device_notifier_unregister` |
| .. |ssam_request_sync| replace:: :c:func:`ssam_request_sync` |
| .. |ssam_event_mask| replace:: :c:type:`enum ssam_event_mask <ssam_event_mask>` |
| |
| |
| ====================== |
| Writing Client Drivers |
| ====================== |
| |
| For the API documentation, refer to: |
| |
| .. toctree:: |
| :maxdepth: 2 |
| |
| client-api |
| |
| |
| Overview |
| ======== |
| |
| Client drivers can be set up in two main ways, depending on how the |
| corresponding device is made available to the system. We specifically |
| differentiate between devices that are presented to the system via one of |
| the conventional ways, e.g. as platform devices via ACPI, and devices that |
| are non-discoverable and instead need to be explicitly provided by some |
| other mechanism, as discussed further below. |
| |
| |
| Non-SSAM Client Drivers |
| ======================= |
| |
| All communication with the SAM EC is handled via the |ssam_controller| |
| representing that EC to the kernel. Drivers targeting a non-SSAM device (and |
| thus not being a |ssam_device_driver|) need to explicitly establish a |
| connection/relation to that controller. This can be done via the |
| |ssam_client_bind| function. Said function returns a reference to the SSAM |
| controller, but, more importantly, also establishes a device link between |
| client device and controller (this can also be done separate via |
| |ssam_client_link|). It is important to do this, as it, first, guarantees |
| that the returned controller is valid for use in the client driver for as |
| long as this driver is bound to its device, i.e. that the driver gets |
| unbound before the controller ever becomes invalid, and, second, as it |
| ensures correct suspend/resume ordering. This setup should be done in the |
| driver's probe function, and may be used to defer probing in case the SSAM |
| subsystem is not ready yet, for example: |
| |
| .. code-block:: c |
| |
| static int client_driver_probe(struct platform_device *pdev) |
| { |
| struct ssam_controller *ctrl; |
| |
| ctrl = ssam_client_bind(&pdev->dev); |
| if (IS_ERR(ctrl)) |
| return PTR_ERR(ctrl) == -ENODEV ? -EPROBE_DEFER : PTR_ERR(ctrl); |
| |
| // ... |
| |
| return 0; |
| } |
| |
| The controller may be separately obtained via |ssam_get_controller| and its |
| lifetime be guaranteed via |ssam_controller_get| and |ssam_controller_put|. |
| Note that none of these functions, however, guarantee that the controller |
| will not be shut down or suspended. These functions essentially only operate |
| on the reference, i.e. only guarantee a bare minimum of accessibility |
| without any guarantees at all on practical operability. |
| |
| |
| Adding SSAM Devices |
| =================== |
| |
| If a device does not already exist/is not already provided via conventional |
| means, it should be provided as |ssam_device| via the SSAM client device |
| hub. New devices can be added to this hub by entering their UID into the |
| corresponding registry. SSAM devices can also be manually allocated via |
| |ssam_device_alloc|, subsequently to which they have to be added via |
| |ssam_device_add| and eventually removed via |ssam_device_remove|. By |
| default, the parent of the device is set to the controller device provided |
| for allocation, however this may be changed before the device is added. Note |
| that, when changing the parent device, care must be taken to ensure that the |
| controller lifetime and suspend/resume ordering guarantees, in the default |
| setup provided through the parent-child relation, are preserved. If |
| necessary, by use of |ssam_client_link| as is done for non-SSAM client |
| drivers and described in more detail above. |
| |
| A client device must always be removed by the party which added the |
| respective device before the controller shuts down. Such removal can be |
| guaranteed by linking the driver providing the SSAM device to the controller |
| via |ssam_client_link|, causing it to unbind before the controller driver |
| unbinds. Client devices registered with the controller as parent are |
| automatically removed when the controller shuts down, but this should not be |
| relied upon, especially as this does not extend to client devices with a |
| different parent. |
| |
| |
| SSAM Client Drivers |
| =================== |
| |
| SSAM client device drivers are, in essence, no different than other device |
| driver types. They are represented via |ssam_device_driver| and bind to a |
| |ssam_device| via its UID (:c:type:`struct ssam_device.uid <ssam_device>`) |
| member and the match table |
| (:c:type:`struct ssam_device_driver.match_table <ssam_device_driver>`), |
| which should be set when declaring the driver struct instance. Refer to the |
| |SSAM_DEVICE| macro documentation for more details on how to define members |
| of the driver's match table. |
| |
| The UID for SSAM client devices consists of a ``domain``, a ``category``, |
| a ``target``, an ``instance``, and a ``function``. The ``domain`` is used |
| differentiate between physical SAM devices |
| (:c:type:`SSAM_DOMAIN_SERIALHUB <ssam_device_domain>`), i.e. devices that can |
| be accessed via the Surface Serial Hub, and virtual ones |
| (:c:type:`SSAM_DOMAIN_VIRTUAL <ssam_device_domain>`), such as client-device |
| hubs, that have no real representation on the SAM EC and are solely used on |
| the kernel/driver-side. For physical devices, ``category`` represents the |
| target category, ``target`` the target ID, and ``instance`` the instance ID |
| used to access the physical SAM device. In addition, ``function`` references |
| a specific device functionality, but has no meaning to the SAM EC. The |
| (default) name of a client device is generated based on its UID. |
| |
| A driver instance can be registered via |ssam_device_driver_register| and |
| unregistered via |ssam_device_driver_unregister|. For convenience, the |
| |module_ssam_device_driver| macro may be used to define module init- and |
| exit-functions registering the driver. |
| |
| The controller associated with a SSAM client device can be found in its |
| :c:type:`struct ssam_device.ctrl <ssam_device>` member. This reference is |
| guaranteed to be valid for at least as long as the client driver is bound, |
| but should also be valid for as long as the client device exists. Note, |
| however, that access outside of the bound client driver must ensure that the |
| controller device is not suspended while making any requests or |
| (un-)registering event notifiers (and thus should generally be avoided). This |
| is guaranteed when the controller is accessed from inside the bound client |
| driver. |
| |
| |
| Making Synchronous Requests |
| =========================== |
| |
| Synchronous requests are (currently) the main form of host-initiated |
| communication with the EC. There are a couple of ways to define and execute |
| such requests, however, most of them boil down to something similar as shown |
| in the example below. This example defines a write-read request, meaning |
| that the caller provides an argument to the SAM EC and receives a response. |
| The caller needs to know the (maximum) length of the response payload and |
| provide a buffer for it. |
| |
| Care must be taken to ensure that any command payload data passed to the SAM |
| EC is provided in little-endian format and, similarly, any response payload |
| data received from it is converted from little-endian to host endianness. |
| |
| .. code-block:: c |
| |
| int perform_request(struct ssam_controller *ctrl, u32 arg, u32 *ret) |
| { |
| struct ssam_request rqst; |
| struct ssam_response resp; |
| int status; |
| |
| /* Convert request argument to little-endian. */ |
| __le32 arg_le = cpu_to_le32(arg); |
| __le32 ret_le = cpu_to_le32(0); |
| |
| /* |
| * Initialize request specification. Replace this with your values. |
| * The rqst.payload field may be NULL if rqst.length is zero, |
| * indicating that the request does not have any argument. |
| * |
| * Note: The request parameters used here are not valid, i.e. |
| * they do not correspond to an actual SAM/EC request. |
| */ |
| rqst.target_category = SSAM_SSH_TC_SAM; |
| rqst.target_id = 0x01; |
| rqst.command_id = 0x02; |
| rqst.instance_id = 0x03; |
| rqst.flags = SSAM_REQUEST_HAS_RESPONSE; |
| rqst.length = sizeof(arg_le); |
| rqst.payload = (u8 *)&arg_le; |
| |
| /* Initialize request response. */ |
| resp.capacity = sizeof(ret_le); |
| resp.length = 0; |
| resp.pointer = (u8 *)&ret_le; |
| |
| /* |
| * Perform actual request. The response pointer may be null in case |
| * the request does not have any response. This must be consistent |
| * with the SSAM_REQUEST_HAS_RESPONSE flag set in the specification |
| * above. |
| */ |
| status = ssam_request_sync(ctrl, &rqst, &resp); |
| |
| /* |
| * Alternatively use |
| * |
| * ssam_request_sync_onstack(ctrl, &rqst, &resp, sizeof(arg_le)); |
| * |
| * to perform the request, allocating the message buffer directly |
| * on the stack as opposed to allocation via kzalloc(). |
| */ |
| |
| /* |
| * Convert request response back to native format. Note that in the |
| * error case, this value is not touched by the SSAM core, i.e. |
| * 'ret_le' will be zero as specified in its initialization. |
| */ |
| *ret = le32_to_cpu(ret_le); |
| |
| return status; |
| } |
| |
| Note that |ssam_request_sync| in its essence is a wrapper over lower-level |
| request primitives, which may also be used to perform requests. Refer to its |
| implementation and documentation for more details. |
| |
| An arguably more user-friendly way of defining such functions is by using |
| one of the generator macros, for example via: |
| |
| .. code-block:: c |
| |
| SSAM_DEFINE_SYNC_REQUEST_W(__ssam_tmp_perf_mode_set, __le32, { |
| .target_category = SSAM_SSH_TC_TMP, |
| .target_id = 0x01, |
| .command_id = 0x03, |
| .instance_id = 0x00, |
| }); |
| |
| This example defines a function |
| |
| .. code-block:: c |
| |
| static int __ssam_tmp_perf_mode_set(struct ssam_controller *ctrl, const __le32 *arg); |
| |
| executing the specified request, with the controller passed in when calling |
| said function. In this example, the argument is provided via the ``arg`` |
| pointer. Note that the generated function allocates the message buffer on |
| the stack. Thus, if the argument provided via the request is large, these |
| kinds of macros should be avoided. Also note that, in contrast to the |
| previous non-macro example, this function does not do any endianness |
| conversion, which has to be handled by the caller. Apart from those |
| differences the function generated by the macro is similar to the one |
| provided in the non-macro example above. |
| |
| The full list of such function-generating macros is |
| |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_N` for requests without return value and |
| without argument. |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_R` for requests with return value but no |
| argument. |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_W` for requests without return value but |
| with argument. |
| |
| Refer to their respective documentation for more details. For each one of |
| these macros, a special variant is provided, which targets request types |
| applicable to multiple instances of the same device type: |
| |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_MD_N` |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_MD_R` |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_MD_W` |
| |
| The difference of those macros to the previously mentioned versions is, that |
| the device target and instance IDs are not fixed for the generated function, |
| but instead have to be provided by the caller of said function. |
| |
| Additionally, variants for direct use with client devices, i.e. |
| |ssam_device|, are also provided. These can, for example, be used as |
| follows: |
| |
| .. code-block:: c |
| |
| SSAM_DEFINE_SYNC_REQUEST_CL_R(ssam_bat_get_sta, __le32, { |
| .target_category = SSAM_SSH_TC_BAT, |
| .command_id = 0x01, |
| }); |
| |
| This invocation of the macro defines a function |
| |
| .. code-block:: c |
| |
| static int ssam_bat_get_sta(struct ssam_device *sdev, __le32 *ret); |
| |
| executing the specified request, using the device IDs and controller given |
| in the client device. The full list of such macros for client devices is: |
| |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_CL_N` |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_CL_R` |
| - :c:func:`SSAM_DEFINE_SYNC_REQUEST_CL_W` |
| |
| |
| Handling Events |
| =============== |
| |
| To receive events from the SAM EC, an event notifier must be registered for |
| the desired event via |ssam_notifier_register|. The notifier must be |
| unregistered via |ssam_notifier_unregister| once it is not required any |
| more. For |ssam_device| type clients, the |ssam_device_notifier_register| and |
| |ssam_device_notifier_unregister| wrappers should be preferred as they properly |
| handle hot-removal of client devices. |
| |
| Event notifiers are registered by providing (at minimum) a callback to call |
| in case an event has been received, the registry specifying how the event |
| should be enabled, an event ID specifying for which target category and, |
| optionally and depending on the registry used, for which instance ID events |
| should be enabled, and finally, flags describing how the EC will send these |
| events. If the specific registry does not enable events by instance ID, the |
| instance ID must be set to zero. Additionally, a priority for the respective |
| notifier may be specified, which determines its order in relation to any |
| other notifier registered for the same target category. |
| |
| By default, event notifiers will receive all events for the specific target |
| category, regardless of the instance ID specified when registering the |
| notifier. The core may be instructed to only call a notifier if the target |
| ID or instance ID (or both) of the event match the ones implied by the |
| notifier IDs (in case of target ID, the target ID of the registry), by |
| providing an event mask (see |ssam_event_mask|). |
| |
| In general, the target ID of the registry is also the target ID of the |
| enabled event (with the notable exception being keyboard input events on the |
| Surface Laptop 1 and 2, which are enabled via a registry with target ID 1, |
| but provide events with target ID 2). |
| |
| A full example for registering an event notifier and handling received |
| events is provided below: |
| |
| .. code-block:: c |
| |
| u32 notifier_callback(struct ssam_event_notifier *nf, |
| const struct ssam_event *event) |
| { |
| int status = ... |
| |
| /* Handle the event here ... */ |
| |
| /* Convert return value and indicate that we handled the event. */ |
| return ssam_notifier_from_errno(status) | SSAM_NOTIF_HANDLED; |
| } |
| |
| int setup_notifier(struct ssam_device *sdev, |
| struct ssam_event_notifier *nf) |
| { |
| /* Set priority wrt. other handlers of same target category. */ |
| nf->base.priority = 1; |
| |
| /* Set event/notifier callback. */ |
| nf->base.fn = notifier_callback; |
| |
| /* Specify event registry, i.e. how events get enabled/disabled. */ |
| nf->event.reg = SSAM_EVENT_REGISTRY_KIP; |
| |
| /* Specify which event to enable/disable */ |
| nf->event.id.target_category = sdev->uid.category; |
| nf->event.id.instance = sdev->uid.instance; |
| |
| /* |
| * Specify for which events the notifier callback gets executed. |
| * This essentially tells the core if it can skip notifiers that |
| * don't have target or instance IDs matching those of the event. |
| */ |
| nf->event.mask = SSAM_EVENT_MASK_STRICT; |
| |
| /* Specify event flags. */ |
| nf->event.flags = SSAM_EVENT_SEQUENCED; |
| |
| return ssam_notifier_register(sdev->ctrl, nf); |
| } |
| |
| Multiple event notifiers can be registered for the same event. The event |
| handler core takes care of enabling and disabling events when notifiers are |
| registered and unregistered, by keeping track of how many notifiers for a |
| specific event (combination of registry, event target category, and event |
| instance ID) are currently registered. This means that a specific event will |
| be enabled when the first notifier for it is being registered and disabled |
| when the last notifier for it is being unregistered. Note that the event |
| flags are therefore only used on the first registered notifier, however, one |
| should take care that notifiers for a specific event are always registered |
| with the same flag and it is considered a bug to do otherwise. |