Hello Anish, On 10/26/24 23:22, anish kumar wrote: > Added details as below: > 1. added sysfs information > 2. verbose details about remoteproc driver/framework > responsibilites. > 3. example for resource request > > Signed-off-by: anish kumar <yesanishhere@xxxxxxxxx> > --- > V5: > based on comment from mathieu poirier, remove all files > and combined that in the original file and as he adviced > nothing with respect to old documentation was changed. > > V4: > Fixed compilation errors and moved documentation to > driver-api directory. > > V3: > Seperated out the patches further to make the intention > clear for each patch. > > V2: > Reported-by: kernel test robot <lkp@xxxxxxxxx> > Closes: https://lore.kernel.org/oe-kbuild-all/202410161444.jOKMsoGS-lkp@xxxxxxxxx/ > > Documentation/staging/remoteproc.rst | 483 +++++++++++++++++++++++++++ > 1 file changed, 483 insertions(+) > > diff --git a/Documentation/staging/remoteproc.rst b/Documentation/staging/remoteproc.rst > index 348ee7e508ac..1c15f4d1b9eb 100644 > --- a/Documentation/staging/remoteproc.rst > +++ b/Documentation/staging/remoteproc.rst > @@ -29,6 +29,68 @@ remoteproc will add those devices. This makes it possible to reuse the > existing virtio drivers with remote processor backends at a minimal development > cost. > > +The primary purpose of the remoteproc framework is to download firmware > +for remote processors and manage their lifecycle. The framework consists > +of several key components: > + > +- **Character Driver**: Provides userspace access to control the remote > + processor. > +- **ELF Utility**: Offers functions for handling ELF files and managing > + resources requested by the remote processor. > +- **Remoteproc Core**: Manages firmware downloads and recovery actions > + in case of a remote processor crash. > +- **Coredump**: Provides facilities for coredumping and tracing from > + the remote processor in the event of a crash. > +- **Userspace Interaction**: Uses sysfs and debugfs to manage the > + lifecycle and status of the remote processor. Seems that there is a duplication with Character Driver. What about merging both and creating a separate bullet for the debug interface? - **Userspace Interaction**: Uses sysfs and/or the character driver to manage the lifecycle and status of the remote processor. - **Debug Interface**: Uses debugfs for trace, coredump, and information on associated resources (resource table, carveout memories, etc.). > +- **Virtio Support**: Facilitates interaction with the virtio and > + rpmsg bus. > + > +Remoteproc framework Responsibilities > +===================================== > + > +The framework begins by gathering information about the firmware file > +to be downloaded through the request_firmware function. It supports > +the ELF format and parses the firmware image to identify the physical > +addresses that need to be populated from the corresponding ELF sections. By default it supports the ELF format, but the rproc_ops struct allows drivers to support some other formats. > +The framework also requires knowledge of the logical or I/O-mapped > +addresses in the application processor. Once this information is > +obtained from the driver, the framework transfers the data to the I suppose here that data is the firmware image, right? what about "The framework loads the firmware image in the remote procesor memories ans starts..."? > +specified addresses and starts the remote, along with > +any devices physically or logically connected to it. > + > +Dependent devices, referred to as `subdevices` within the framework, > +are also managed post-registration by their respective drivers. > +Subdevices can register themselves using `rproc_(add/remove)_subdev`. > +Non-remoteproc drivers can use subdevices as a way to logically connect > +to remote and get lifecycle notifications of the remote. > + > +The framework oversees the lifecycle of the remote and > +provides the `rproc_report_crash` function, which the driver invokes > +upon receiving a crash notification from the remote. The > +notification method can differ based on the design of the remote > +processor and its communication with the application processor. For > +instance, if the remote is a DSP equipped with a watchdog, > +unresponsive behavior triggers the watchdog, generating an interrupt > +that routes to the application processor, allowing it to call > +`rproc_report_crash` in the driver's interrupt context. > + > +During crash handling, the framework performs the following actions: > + > +a. Sends a request to stop the remote and any connected or > + dependent subdevices. > +b. Generates a coredump, dumping all `resources` requested by the > + remote alongside relevant debugging information. Resources are > + explained below. > +c. Reloads the firmware and restarts the remote. we could mention that the recovery mechanism can be blocked using the 'recovery_disabled' rproc field. > + > +If the `RPROC_FEAT_ATTACH_ON_RECOVERY` flag is set, the detach and > +attach callbacks of the driver are invoked without reloading the > +firmware. This is useful when the remote requires no > +assistance for recovery, or when the application processor can restart > +independently. After recovery, the application processor can reattach > +to the remote. > + > User API > ======== > > @@ -107,6 +169,239 @@ Typical usage > API for implementors > ==================== > > +It describes the API that can be used by remote processor Drivers s/Drivers/drivers/ > +that want to use the remote processor Driver Core Framework. This Is there any reason to have uppercase in "Driver Core Framework"? > +framework provides all interfacing towards user space so that the > +same code does not have to be reproduced each time. This also means > +that a remote processor driver then only needs to provide the different > +routines(operations) that control the remote processor. > + > +Each remote processor driver that wants to use the remote processor Driver Core > +must #include <linux/remoteproc.h> (you would have to do this anyway when > +writing a rproc device driver). This include file contains following > +register routine:: > + > + int devm_rproc_add(struct device *dev, struct rproc *rproc) > + > +The devm_rproc_add routine registers a remote processor device. > +The parameter of this routine is a pointer to a rproc device structure. > +This routine returns zero on success and a negative errno code for failure. > + > +The rproc device structure looks like this:: > + > + struct rproc { > + struct list_head node; > + struct iommu_domain *domain; > + const char *name; > + const char *firmware; > + void *priv; > + struct rproc_ops *ops; > + struct device dev; > + atomic_t power; > + unsigned int state; > + enum rproc_dump_mechanism dump_conf; > + struct mutex lock; > + struct dentry *dbg_dir; > + struct list_head traces; > + int num_traces; > + struct list_head carveouts; > + struct list_head mappings; > + u64 bootaddr; > + struct list_head rvdevs; > + struct list_head subdevs; > + struct idr notifyids; > + int index; > + struct work_struct crash_handler; > + unsigned int crash_cnt; > + bool recovery_disabled; > + int max_notifyid; > + struct resource_table *table_ptr; > + struct resource_table *clean_table; > + struct resource_table *cached_table; > + size_t table_sz; > + bool has_iommu; > + bool auto_boot; > + bool sysfs_read_only; > + struct list_head dump_segments; > + int nb_vdev; > + u8 elf_class; > + u16 elf_machine; > + struct cdev cdev; > + bool cdev_put_on_release; > + DECLARE_BITMAP(features, RPROC_MAX_FEATURES); > + }; > + > +It contains following fields: > + > +* node: list node of this rproc object > +* domain: iommu domain > +* name: human readable name of the rproc > +* firmware: name of firmware file to be loaded > +* priv: private data which belongs to the platform-specific rproc module > +* ops: platform-specific start/stop rproc handlers > +* dev: virtual device for refcounting and common remoteproc behavior > +* power: refcount of users who need this rproc powered up > +* state: state of the device > +* dump_conf: Currently selected coredump configuration > +* lock: lock which protects concurrent manipulations of the rproc > +* dbg_dir: debugfs directory of this rproc device > +* traces: list of trace buffers > +* num_traces: number of trace buffers > +* carveouts: list of physically contiguous memory allocations > +* mappings: list of iommu mappings we initiated, needed on shutdown > +* bootaddr: address of first instruction to boot rproc with (optional) > +* rvdevs: list of remote virtio devices > +* subdevs: list of subdevices, to following the running state > +* notifyids: idr for dynamically assigning rproc-wide unique notify ids > +* index: index of this rproc device > +* crash_handler: workqueue for handling a crash > +* crash_cnt: crash counter > +* recovery_disabled: flag that state if recovery was disabled > +* max_notifyid: largest allocated notify id. > +* table_ptr: pointer to the resource table in effect > +* clean_table: copy of the resource table without modifications. Used > +* when a remote processor is attached or detached from the core > +* cached_table: copy of the resource table > +* table_sz: size of @cached_table > +* has_iommu: flag to indicate if remote processor is behind an MMU > +* auto_boot: flag to indicate if remote processor should be auto-started > +* sysfs_read_only: flag to make remoteproc sysfs files read only > +* dump_segments: list of segments in the firmware > +* nb_vdev: number of vdev currently handled by rproc > +* elf_class: firmware ELF class > +* elf_machine: firmware ELF machine > +* cdev: character device of the rproc > +* cdev_put_on_release: flag to indicate if remoteproc should be shutdown on @char_dev release > +* features: indicate remoteproc features > + > +The list of rproc operations is defined as:: > + > + struct rproc_ops { > + int (*prepare)(struct rproc *rproc); > + int (*unprepare)(struct rproc *rproc); > + int (*start)(struct rproc *rproc); > + int (*stop)(struct rproc *rproc); > + int (*attach)(struct rproc *rproc); > + int (*detach)(struct rproc *rproc); > + void (*kick)(struct rproc *rproc, int vqid); > + void * (*da_to_va)(struct rproc *rproc, u64 da, size_t len, bool *is_iomem); > + int (*parse_fw)(struct rproc *rproc, const struct firmware *fw); > + int (*handle_rsc)(struct rproc *rproc, u32 rsc_type, void *rsc, > + int offset, int avail); > + struct resource_table *(*find_loaded_rsc_table)( > + struct rproc *rproc, const struct firmware *fw); > + struct resource_table *(*get_loaded_rsc_table)( > + struct rproc *rproc, size_t *size); > + int (*load)(struct rproc *rproc, const struct firmware *fw); > + int (*sanity_check)(struct rproc *rproc, const struct firmware *fw); > + u64 (*get_boot_addr)(struct rproc *rproc, const struct firmware *fw); > + unsigned long (*panic)(struct rproc *rproc); > + void (*coredump)(struct rproc *rproc); > + }; > + > +Most of the operations are optional. Currently in the implementation > +there are no mandatory operations, however from the practical standpoint > +minimum ops are: > + > +* start: this is a pointer to the routine that starts the remote processor > + device. > + The routine needs a pointer to the remote processor device structure as a > + parameter. It returns zero on success or a negative errno code for failure. > + > +* stop: with this routine the remote processor device is being stopped. > + > + The routine needs a pointer to the remote processor device structure as a > + parameter. It returns zero on success or a negative errno code for failure. > + > +* da_to_va: this is the routine that needs to translate device address to > + application processor virtual address that it can copy code to. > + > + The routine needs a pointer to the remote processor device structure as a > + parameter. It returns zero on success or a negative errno code for failure. > + > + The routine provides the device address it finds in the ELF firmware and asks > + the driver to convert that to virtual address. > + > +All other callbacks are optional in case of ELF provided firmware. > + > +* load: this is to load the firmware on to the remote device. > + > + The routine needs firmware file that it needs to load on to the remote processor. > + If the driver overrides this callback then default ELF loader will not get used. > + Otherwise default framework provided loader gets used. > + > + load = rproc_elf_load_segments; > + parse_fw = rproc_elf_load_rsc_table; > + find_loaded_rsc_table = rproc_elf_find_loaded_rsc_table; > + sanity_check = rproc_elf_sanity_check; > + get_boot_addr = rproc_elf_get_boot_addr; > + > +* parse_fw: this routing parses the provided firmware. In case of ELF format, > + framework provided rproc_elf_load_rsc_table function can be used. > + > +* sanity_check: Check the format of the firmware. > + > +* coredump: If the driver prefers to manage coredumps independently, it can > + implement its own coredump handling. However, the framework offers a default > + implementation for the ELF format by assigning this callback to > + rproc_coredump, unless the driver has overridden it. > + > +* get_boot_addr: In case the bootaddr defined in ELF firmware is different, driver > + can use this callback to set a different boot address for remote processor to > + starts its reset vector from. > + > +* find_loaded_rsc_table: this routine gets the loaded resource table from the firmware. > + > + resource table should have a section named (.resource_table) for the framework > + to understand and interpret its content. Resource table is a way for remote > + processor to ask for resources such as memory for dumping and logging. Look > + at core documentation to know how to create the ELF section for the same. > + > +* get_loaded_rsc_table: Driver can customize passing the resource table by overriding > + this callback. Framework doesn't provide any default implementation for the same. > + > +The driver must provide the following information to the core: > + > +a. Translate device addresses (physical addresses) found in the ELF > + firmware to virtual addresses in Linux using the `da_to_va` > + callback. This allows the framework to copy ELF firmware from the > + filesystem to the addresses expected by the remote since > + the framework cannot directly access those physical addresses. > +b. Prepare/unprepare the remote prior to firmware loading, > + which may involve allocating carveout and reserved memory regions. > +c. Implement methods for starting and stopping the remote, > + whether by setting registers or sending explicit interrupts, > + depending on the hardware design. > +d. Provide attach and detach callbacks to start the remote > + without loading the firmware. This is beneficial when the remote > + processor is already loaded and running. > +e. Implement a load callback for firmware loading, typically using > + the ELF loader provided by the framework; currently, only ELF > + format is supported. > +f. Invoke the framework's crash handler API upon detecting a remote > + crash. > + > +Drivers must fill the `rproc_ops` structure and call `rproc_alloc` > +to register themselves with the framework. > + > +.. code-block:: c > + > + struct rproc_ops { > + int (*prepare)(struct rproc *rproc); > + int (*unprepare)(struct rproc *rproc); > + int (*start)(struct rproc *rproc); > + int (*stop)(struct rproc *rproc); > + int (*attach)(struct rproc *rproc); > + int (*detach)(struct rproc *rproc); > + void * (*da_to_va)(struct rproc *rproc, u64 da, size_t len, > + bool *is_iomem); > + int (*parse_fw)(struct rproc *rproc, const struct firmware *fw); > + int (*handle_rsc)(struct rproc *rproc, u32 rsc_type, > + void *rsc, int offset, int avail); > + int (*load)(struct rproc *rproc, const struct firmware *fw); > + //snip > + }; > + > :: > > struct rproc *rproc_alloc(struct device *dev, const char *name, > @@ -190,6 +485,35 @@ platform specific rproc implementation. This should not be called from a > non-remoteproc driver. This function can be called from atomic/interrupt > context. > > +To add a subdev corresponding driver can call > + > +:: > + > + void rproc_add_subdev(struct rproc *rproc, struct rproc_subdev *subdev) > + > +To remove a subdev, driver can call. > + > +:: > + > + void rproc_remove_subdev(struct rproc *rproc, struct rproc_subdev *subdev) > + > +To work with ELF coredump below function can be called > + > +:: > + > + void rproc_coredump_cleanup(struct rproc *rproc) > + void rproc_coredump(struct rproc *rproc) > + void rproc_coredump_using_sections(struct rproc *rproc) > + int rproc_coredump_add_segment(struct rproc *rproc, dma_addr_t da, size_t size) > + int rproc_coredump_add_custom_segment(struct rproc *rproc, > + dma_addr_t da, size_t size, > + void (*dumpfn)(struct rproc *rproc, > + struct rproc_dump_segment *segment, > + void *dest, size_t offset, > + size_t size)) > + > +Remember that coredump functions provided by the framework only works with ELF format. > + > Implementation callbacks > ======================== > > @@ -228,6 +552,123 @@ the exact virtqueue index to look in is optional: it is easy (and not > too expensive) to go through the existing virtqueues and look for new buffers > in the used rings. > > +Userspace control methods > +========================== > + > +At times, userspace may need to check the state of the remote processor to > +prevent other processes from using it. For instance, if the remote processor > +is a DSP used for playback, there may be situations where the DSP is > +undergoing recovery and cannot be used. In such cases, attempts to access the > +DSP for playback should be blocked. The rproc framework provides sysfs APIs > +to inform userspace of the processor's current status which should be utilised > +to achieve the same. > + > +Additionally, there are scenarios where userspace applications need to explicitly > +control the rproc. In these cases, rproc also offers the file descriptors. > + > +Below set of commands can be used to start and stop the rproc > +where 'X' refers to instance of associated remoteproc. There can be systems > +where there are more than one rprocs such as multiple DSP's > +connected to application processors running Linux. > + > +.. code-block:: c > + > + echo start > /sys/class/remoteproc/remoteprocX/state > + echo stop > /sys/class/remoteproc/remoteprocX/state > + > +To know the state of rproc: > + > +.. code-block:: c > + > + cat /sys/class/remoteproc/remoteprocX/state > + > + > +To dynamically replace firmware, execute the following commands: > + > +.. code-block:: c > + > + echo stop > /sys/class/remoteproc/remoteprocX/state > + echo -n <firmware_name> > > + /sys/class/remoteproc/remoteprocX/firmware > + echo start > /sys/class/remoteproc/remoteprocX/state > + Only the command to select the firmware image to load seems important above, I would reorder the descriptions. +By default the firmware image file should be stored in /lib/firmware. +To select the firmware image to load: + +.. code-block:: c + + echo -n <firmware_name> > /sys/class/remoteproc/remoteprocX/firmware + +To control the remote processor: + +.. code-block:: c + + echo start > /sys/class/remoteproc/remoteprocX/state + echo stop > /sys/class/remoteproc/remoteprocX/state + +To know the state of the remote processor: + +.. code-block:: c + + cat /sys/class/remoteproc/remoteprocX/state + > +To simulate a remote crash, execute: > + > +.. code-block:: c > + > + echo 1 > /sys/kernel/debug/remoteproc/remoteprocX/crash > + > +To get the trace logs, execute > + > +.. code-block:: c > + > + cat /sys/kernel/debug/remoteproc/remoteprocX/crashX > + > +where X will be 0 or 1 if there are 2 resources. Also, this > +file will only exist if resources are defined in ELF firmware > +file. > + > +The coredump feature can be disabled with the following command: > + > +.. code-block:: c > + > + echo disabled > /sys/kernel/debug/remoteproc/remoteprocX/coredump > + The descriptions above concern debugfs, not sysfs, and should be part of a separate chapter. Regards, Arnaud > +Userspace can also control start/stop of rproc by using a > +remoteproc Character Device, it can open the open a file descriptor > +and write `start` to initiate it, and `stop` to terminate it. > +Below set of api's can be used to start and stop the rproc > +where 'X' refers to instance of associated remoteproc. There can be systems > +where there are more than one rprocs such as multiple DSP's > +connected to application processors running Linux. > + > +.. code-block:: c > + > + echo start > /sys/class/remoteproc/remoteprocX/state > + echo stop > /sys/class/remoteproc/remoteprocX/state > + > +To know the state of rproc: > + > +.. code-block:: c > + > + cat /sys/class/remoteproc/remoteprocX/state > + > + > +To dynamically replace firmware, execute the following commands: > + > +.. code-block:: c > + > + echo stop > /sys/class/remoteproc/remoteprocX/state > + echo -n <firmware_name> > > + /sys/class/remoteproc/remoteprocX/firmware > + echo start > /sys/class/remoteproc/remoteprocX/state > + > +To simulate a remote crash, execute: > + > +.. code-block:: c > + > + echo 1 > /sys/kernel/debug/remoteproc/remoteprocX/crash > + > +To get the trace logs, execute > + > +.. code-block:: c > + > + cat /sys/kernel/debug/remoteproc/remoteprocX/crashX > + > +where X will be 0 or 1 if there are 2 resources. Also, this > +file will only exist if resources are defined in ELF firmware > +file. > + > +The coredump feature can be disabled with the following command: > + > +.. code-block:: c > + > + echo disabled > /sys/kernel/debug/remoteproc/remoteprocX/coredump > + > +Userspace can also control start/stop of rproc by using a > +remoteproc Character Device, it can open the open a file descriptor > +and write `start` to initiate it, and `stop` to terminate it. > + > Binary Firmware Structure > ========================= > > @@ -340,6 +781,48 @@ We also expect that platform-specific resource entries will show up > at some point. When that happens, we could easily add a new RSC_PLATFORM > type, and hand those resources to the platform-specific rproc driver to handle. > > +if the remote requests both `RSC_TRACE` and `RSC_CARVEOUT` for memory > +allocation, the ELF firmware can be structured as follows: > + > +.. code-block:: c > + > + #define MAX_SHARED_RESOURCE 2 > + #define LOG_BUF_SIZE 1000 > + #define CARVEOUT_DUMP_PA 0x12345678 > + #define CARVEOUT_DUMP_SIZE 2000 > + > + struct shared_resource_table { > + u32 ver; > + u32 num; > + u32 reserved[2]; > + u32 offset[MAX_SHARED_RESOURCE]; > + struct fw_rsc_trace log_trace; > + struct fw_rsc_carveout dump_carveout; > + }; > + > + volatile struct shared_resource_table table = { > + .ver = 1, > + .num = 2, > + .reserved = {0, 0}, > + .offset = { > + offsetof(struct resource_table, log_trace), > + offsetof(struct resource_table, dump_carveout), > + }, > + .log_trace = { > + RSC_TRACE, > + (u32)log_buf, LOG_BUF_SIZE, 0, "log_trace", > + }, > + .dump_carveout = { > + RSC_CARVEOUT, > + (u32)FW_RSC_ADDR_ANY, CARVEOUT_PA, 0, "carveout_dump", > + }, > + }; > + > +The framework creates a sysfs file when it encounters the `RSC_TRACE` > +type to expose log information to userspace. Other resource types are > +handled accordingly. In the example above, `CARVEOUT_DUMP_SIZE` bytes > +of DMA memory will be allocated starting from `CARVEOUT_DUMP_PA`. > + > Virtio and remoteproc > ===================== >