/* SPDX-License-Identifier: GPL-2.0+ */ /* * Events provide a general-purpose way to react to / subscribe to changes * within U-Boot * * Copyright 2021 Google LLC * Written by Simon Glass */ #ifndef __event_h #define __event_h #include #include /** * enum event_t - Types of events supported by U-Boot * * @EVT_DM_PRE_PROBE: Device is about to be probed */ enum event_t { /** * @EVT_NONE: This zero value is not used for events. */ EVT_NONE = 0, /** * @EVT_TEST: This event is used in unit tests. */ EVT_TEST, /** * @EVT_DM_POST_INIT_F: * This event is triggered after pre-relocation initialization of the * driver model. Its parameter is NULL. * A non-zero return code from the event handler let's the boot process * fail. */ EVT_DM_POST_INIT_F, /** * @EVT_DM_POST_INIT_R: * This event is triggered after post-relocation initialization of the * driver model. Its parameter is NULL. * A non-zero return code from the event handler let's the boot process * fail. */ EVT_DM_POST_INIT_R, /** * @EVT_DM_PRE_PROBE: * This event is triggered before probing a device. Its parameter is the * device to be probed. * A non-zero return code from the event handler lets the device not * being probed. */ EVT_DM_PRE_PROBE, /** * @EVT_DM_POST_PROBE: * This event is triggered after probing a device. Its parameter is the * device that was probed. * A non-zero return code from the event handler leaves the device in * the unprobed state and therefore not usable. */ EVT_DM_POST_PROBE, /** * @EVT_DM_PRE_REMOVE: * This event is triggered after removing a device. Its parameter is * the device to be removed. * A non-zero return code from the event handler stops the removal of * the device before any changes. */ EVT_DM_PRE_REMOVE, /** * @EVT_DM_POST_REMOVE: * This event is triggered before removing a device. Its parameter is * the device that was removed. * A non-zero return code stops from the event handler the removal of * the device after all removal changes. The previous state is not * restored. All children will be gone and the device may not be * functional. */ EVT_DM_POST_REMOVE, /** * @EVT_MISC_INIT_F: * This event is triggered during the initialization sequence before * relocation. Its parameter is NULL. * A non-zero return code from the event handler let's the boot process * fail. */ EVT_MISC_INIT_F, /** * @EVT_FSP_INIT_F: * This event is triggered before relocation to set up Firmware Support * Package. * Where U-Boot relies on binary blobs to handle part of the system * init, this event can be used to set up the blobs. This is used on * some Intel platforms */ EVT_FSP_INIT_F, /** * @EVT_LAST_STAGE_INIT: * This event is triggered just before jumping to the main loop. * Some boards need to perform initialisation immediately before control * is passed to the command-line interpreter (e.g. for init that depend * on later phases in the init sequence). * * Some parts can be only initialized if all others (like Interrupts) * are up and running (e.g. the PC-style ISA keyboard). */ EVT_LAST_STAGE_INIT, /** * @EVT_FPGA_LOAD: * The FPGA load hook is called after loading an FPGA with a new binary. * Its parameter is of type struct event_fpga_load and contains * information about the loaded image. */ EVT_FPGA_LOAD, /** * @EVT_FT_FIXUP: * This event is triggered during device-tree fix up after all * other device-tree fixups have been executed. * Its parameter is of type struct event_ft_fixup which contains * the address of the device-tree to fix up and the list of images to be * booted. * A non-zero return code from the event handler let's booting the * images fail. */ EVT_FT_FIXUP, /** * @EVT_MAIN_LOOP: * This event is triggered immediately before calling main_loop() which * is the entry point of the command line. Its parameter is NULL. * A non-zero return value causes the boot to fail. */ EVT_MAIN_LOOP, /** * @EVT_COUNT: * This constants holds the maximum event number + 1 and is used when * looping over all event classes. */ EVT_COUNT }; union event_data { /** * struct event_data_test - test data * * @signal: A value to update the state with */ struct event_data_test { int signal; } test; /** * struct event_dm - driver model event * * @dev: Device this event relates to */ struct event_dm { struct udevice *dev; } dm; /** * struct event_fpga_load - fpga load event * * @buf: The buffer that was loaded into the fpga * @bsize: The size of the buffer that was loaded into the fpga * @result: Result of the load operation */ struct event_fpga_load { const void *buf; size_t bsize; int result; } fpga_load; /** * struct event_ft_fixup - FDT fixup before booting * * @tree: tree to update * @images: images which are being booted */ struct event_ft_fixup { oftree tree; struct bootm_headers *images; } ft_fixup; }; /** * struct event - an event that can be sent and received * * @type: Event type * @data: Data for this particular event */ struct event { enum event_t type; union event_data data; }; /* Flags for event spy */ enum evspy_flags { EVSPYF_SIMPLE = 1 << 0, }; /** Function type for event handlers */ typedef int (*event_handler_t)(void *ctx, struct event *event); /** Function type for simple event handlers */ typedef int (*event_handler_simple_t)(void); /** * struct evspy_info - information about an event spy * * @func: Function to call when the event is activated (must be first) * @type: Event type * @flags: Flags for this spy * @id: Event id string */ struct evspy_info { event_handler_t func; u8 type; u8 flags; #if CONFIG_IS_ENABLED(EVENT_DEBUG) const char *id; #endif }; /** * struct evspy_info_simple - information about an event spy * * THis is the 'simple' record, the only difference being the handler function * * @func: Function to call when the event is activated (must be first) * @type: Event type * @flags: Flags for this spy * @id: Event id string */ struct evspy_info_simple { event_handler_simple_t func; u8 type; u8 flags; #if CONFIG_IS_ENABLED(EVENT_DEBUG) const char *id; #endif }; /* Declare a new event spy */ #if CONFIG_IS_ENABLED(EVENT_DEBUG) #define _ESPY_REC(_type, _func) { _func, _type, 0, #_func, } #define _ESPY_REC_SIMPLE(_type, _func) { _func, _type, EVSPYF_SIMPLE, #_func, } #else #define _ESPY_REC(_type, _func) { _func, _type, } #define _ESPY_REC_SIMPLE(_type, _func) { _func, _type, EVSPYF_SIMPLE } #endif static inline const char *event_spy_id(struct evspy_info *spy) { #if CONFIG_IS_ENABLED(EVENT_DEBUG) return spy->id; #else return "?"; #endif } /* * It seems that LTO will drop list entries if it decides they are not used, * although the conditions that cause this are unclear. * * The example found is the following: * * static int sandbox_misc_init_f(void *ctx, struct event *event) * { * return sandbox_early_getopt_check(); * } * EVENT_SPY(EVT_MISC_INIT_F, sandbox_misc_init_f); * * where EVENT_SPY uses ll_entry_declare() * * In this case, LTO decides to drop the sandbox_misc_init_f() function * (which is fine) but then drops the linker-list entry too. This means * that the code no longer works, in this case sandbox no-longer checks its * command-line arguments properly. * * Without LTO, the KEEP() command in the .lds file is enough to keep the * entry around. But with LTO it seems that the entry has already been * dropped before the link script is considered. * * The only solution I can think of is to mark linker-list entries as 'used' * using an attribute. This should be safe, since we don't actually want to drop * any of these. However this does slightly limit LTO's optimisation choices. * * Another issue has come up, only with clang: using 'static' makes it throw * away the linker-list entry sometimes, e.g. with the EVT_FT_FIXUP entry in * vbe_simple.c - so for now, make it global. */ #define EVENT_SPY_FULL(_type, _func) \ __used ll_entry_declare(struct evspy_info, _type ## _3_ ## _func, \ evspy_info) = _ESPY_REC(_type, _func) /* Simple spy with no function arguemnts */ #define EVENT_SPY_SIMPLE(_type, _func) \ __used ll_entry_declare(struct evspy_info_simple, \ _type ## _3_ ## _func, \ evspy_info) = _ESPY_REC_SIMPLE(_type, _func) /** * event_register - register a new spy * * @id: Spy ID * @type: Event type to subscribe to * @func: Function to call when the event is sent * @ctx: Context to pass to the function * @return 0 if OK, -ve on error */ int event_register(const char *id, enum event_t type, event_handler_t func, void *ctx); /** event_show_spy_list( - Show a list of event spies */ void event_show_spy_list(void); /** * event_type_name() - Get the name of an event type * * @type: Type to check * Return: Name of event, or "(unknown)" if not known */ const char *event_type_name(enum event_t type); /** * event_notify() - notify spies about an event * * It is possible to pass in union event_data here but that may not be * convenient if the data is elsewhere, or is one of the members of the union. * So this uses a void * for @data, with a separate @size. * * @type: Event type * @data: Event data to be sent (e.g. union_event_data) * @size: Size of data in bytes * @return 0 if OK, -ve on error */ int event_notify(enum event_t type, void *data, int size); #if CONFIG_IS_ENABLED(EVENT) /** * event_notify_null() - notify spies about an event * * Data is NULL and the size is 0 * * @type: Event type * @return 0 if OK, -ve on error */ int event_notify_null(enum event_t type); #else static inline int event_notify_null(enum event_t type) { return 0; } #endif #if CONFIG_IS_ENABLED(EVENT_DYNAMIC) /** * event_uninit() - Clean up dynamic events * * This removes all dynamic event handlers */ int event_uninit(void); /** * event_uninit() - Set up dynamic events * * Init a list of dynamic event handlers, so that these can be added as * needed */ int event_init(void); #else static inline int event_uninit(void) { return 0; } static inline int event_init(void) { return 0; } #endif #endif