| Introduction |
| ============ |
| |
| BIF (Battery Interface) is a MIPI (Mobile Industry Processor Interface) |
| Alliance specification for a serial interface between a host device and a |
| battery pack. It provides a means to handle smart battery packs which can |
| communicate over BIF as well as low cost battery packs which provide no |
| serial communication interface. |
| |
| The BIF bus supports 1 master and up to 256 slaves. It supports data rates |
| up to 250 kbps. The master is in charge of initiating all bus |
| communications. Slaves may only respond asynchronously when they need to |
| signal the master that they have an interrupt pending and when the bus is |
| configured for interrupt mode. |
| |
| The BIF framework consists of a core into which BIF controller drivers |
| register. At runtime, consumers are notified of various events (e.g. battery |
| insertion and battery removal) via a notifier. Various framework functions are |
| available for consumers to read and write slave registers as well as to send |
| arbitrary BIF commands on the bus. |
| |
| Hardware description |
| ==================== |
| |
| The BIF bus is a 1-wire wired-or interface. The bus signal is referred to as |
| the battery communication line (BCL). The BCL is pulled high by a resistor on |
| the host side and is driven low when the master or one of the slaves is |
| communicating. Additionally, there is a pull down resistor in the battery |
| pack which is used to identify whether or not the battery pack has BIF slaves. |
| Battery removal detection is achieved by comparing the analog voltage of the BCL |
| when idle to the host side reference voltage. If these voltages are within a |
| certain threshold, then a battery pack is not present. |
| |
| Slaves are addressed on the BIF bus using an 8-bit device address (DEV_ADR). |
| Notably, it is possible for no slaves to have defined DEV_ADR. In this case, |
| slave addressing is achieved via the always present unique ID (UID). The UID |
| of a slave is 80 bits long and guaranteed to be globally unique. A UID search |
| algorithm can be followed in order determine the UID of all slaves on the bus. |
| |
| BIF slaves come in two varieties: primary and secondary. A single primary |
| slave may be present on the battery pack and a single primary slave may be |
| present on the host. A battery pack primary slave has DEV_ADR=0x01. The |
| DEV_ADR of a host primary slave is set by the manufacturer. A given primary |
| slave contains a list of the UIDs of all secondary slaves in the same |
| subsystem. This provides a fast mechanism to determine the address of all |
| slaves without having to resort to the lengthy UID search algorithm. |
| |
| Each slave has a 64 kB address space. Part of this address space consists of |
| generic DDB L1 and L2 data structures at known addresses. This allows for |
| runtime discovery of supported battery properties and functions of a given |
| smart battery pack. |
| |
| System Diagram: |
| +-------------------------------+ +---------------------------------+ |
| | Host | | Smart Battery Pack | |
| | | | | |
| | Vbat-<+>-------<+>----------------------------+ | |
| | | | | | |
| | +--------------+ | | +--------------+ | | |
| | | Master BIF<+>-+---------<+>--BCL--<+>------+-<+>BIF Primary | | | |
| | | | | | | | | Slave | | | |
| | +--------------+ | | | | +--------------+ | | |
| | | | | | | | |
| | + - - - - - - -+ | | | | + - - - - - - -+ | | |
| | | Primary BIF<+>-+ | | +-<+>BIF Secondary| | | |
| | | Slave | | | | | | Slave | | | |
| | +- - - - - - - + | | | | +-- - - - - - -+ | | |
| | | | | | | | |
| | + - - - - - - -+ | | | | + - - - - - - -+ | | |
| | |Secondary BIF<+>-+ | | +-<+>BIF Secondary| | | |
| | |Slave | | | | | | Slave | | | |
| | +- - - - - - - + | | | | +-- - - - - - -+ | | |
| | / | | / | | |
| | Vref \ Rpu | | Rid \ ---- | |
| | ___ / | | / Battery -- | |
| | | \ | | \ Cell ---- | |
| | +-------+ | | | -- | |
| | | | | | | |
| | GND-<+>-------<+>------+---------------------+ | |
| | | | | |
| +-------------------------------+ +---------------------------------+ |
| |
| An overview of BIF is available at: |
| http://mipi.org/specifications/battery-interface |
| |
| Software description |
| ==================== |
| |
| A given BIF hardware interface driver registers as a BIF controller in the |
| BIF framework during its probe function. The controller specifies a set of |
| callback functions which are used by the BIF framework to initiate bus |
| transactions (e.g. register read, register write, wait for slave interrupt) |
| and to configure the bus. The framework exposes a small API to controllers |
| which is used to notify the framework about asynchronous events such as |
| battery pack insertion/removal and slave interrupts. |
| |
| A given BIF consumer is linked to a BIF controller by specifying a property |
| in the consumer's device tree node which takes as its value the phandle of |
| the BIF controller's device tree node. |
| |
| A consumer driver calls a get function during its probe function with its |
| device pointer in order to get a handle to the BIF controller if it has probed. |
| If it hasn't, then ERR_PTR(-EPROBE_DEFER) is returned. The controller handle |
| can be used directly by the consumer to issue raw bus transactions if needed. |
| The controller handle can then be used to query which slaves are currently |
| present on the bus, if any. Handles to these slaves may be used by a consumer |
| driver in high level framework APIs such as register read and register write |
| which are slave oriented. All BIF framework API functions are synchronous, |
| blocking, and can sleep. |
| |
| Consumer drivers may also register a notifier function which is called when |
| certain bus activities occur such as battery pack insertion and removal. |
| Additionally, consumer drivers may register a notifier function which is called |
| when a specified slave interrupt fires. |
| |
| The framework maintains several linked-lists. One list contains all controllers |
| that have been registered. A second list contains all slaves that have been |
| seen since the system booted as well as a flag to indicate if they are currently |
| present or not. This scheme is used to avoid issues with slave handles existing |
| after a slave is removed and also so that function and object values do not have |
| to be searched when a slave is reinserted in the system since slaves are |
| globally unique and these features are read-only. Two further lists are |
| maintained inside slave device structures which contain BIF functions and |
| objects found in the slave. API functions are provided so that consumers can |
| find functions supported by slaves. |
| |
| Design |
| ====== |
| |
| Design Goals: |
| One major goal of the BIF framework is to provide a uniform API for BIF |
| consumers to communicate with battery packs. This ensures that consumers are |
| unaffected by changes in the controller driver which actually interfaces with |
| the BCL at a hardware level. |
| |
| Another goal of the framework is to ensure the BIF bus can be shared between |
| multiple consumers in a simple and functionally correct way. Locking is used |
| inside of the framework to provide mutual exclusion on the bus. |
| |
| The framework also exposes features that almost all consumers will need, such |
| as BIF slave identification and BIF function enumeration within a given slave. |
| |
| The framework allows consumers to issue very specific bus commands which may |
| not be used within high level APIs. This provides maximum flexibility so |
| that consumers can make use of manufacturer defined bus commands which cannot be |
| handled in a generic fashion. |
| |
| Design Trade-offs: |
| The choice to not treat BIF like a traditional Linux bus was made because |
| there is nothing within BIF that naturally maps to a device on the bus for a |
| driver to manage. Slave devices would be a good candidate except that |
| consumers will not be managing slaves so much as functions exposed within |
| slaves. Bus matching could then instead be made at a BIF slave function |
| level. Unfortunately, the BIF specification allows for manufacturer specific |
| features to reside at any non-defined addresses. Additionally, consumers may |
| wish only to read and make policy decisions based on BIF non-volatile memory |
| (NVM) objects read out of memory. Thus, there are use-cases that require |
| consumers to utilize the bus without having a particular function to match to. |
| |
| Another trade-off was the choice to use custom interrupt handling functions |
| instead of the Linux interrupt framework. This choice was made because there is |
| no obvious way to handle IRQ chip registration given the dynamic nature of BIF |
| slaves (i.e. slaves may come and go at runtime if battery packs are swapped). |
| |
| Software layering: |
| BIF controller drivers register a set of callback functions with the BIF |
| framework which implement various BIF transaction primitives. These |
| callbacks ensure that tight timing constraints are met such as when receiving |
| a bus query response immediately after issuing a command. Such actions |
| cannot be carried out at the framework level as timing requirements are on |
| the order of 32 us when using the maximum data rate. |
| |
| The BIF framework provides easy access to standard BIF features such as |
| slave, functions, and interrupts. The framework also ensures mutual exclusion |
| between different BIF consumers. |
| |
| BIF consumer drivers make use of the API exposed by the framework in order |
| utilize functionality found on smart battery packs. One example of a |
| consumer driver is a temperature monitoring driver which reads the |
| temperature reported by the BIF temperature function on a BIF slave and |
| reports it to the Linux thermal framework. |
| |
| Power Management |
| ================ |
| |
| The framework does not perform any special actions during system suspend and |
| resume. Controller drivers may choose to enter low power states during |
| suspend if they wish as long as it does not affect the logical state of the |
| bus. |
| |
| SMP/multi-core |
| ============== |
| |
| Various linked lists are maintained inside of the framework which are |
| protected by mutexes. Mutex locks are also used during transactions at a bus |
| level in order to ensure mutual exclusion between consumers of the bus. |
| |
| Performance |
| =========== |
| |
| The BIF bus is inherently slow. Consumers should expect transactions to take |
| a long time to execute. Consumers are responsible for blocking suspend if |
| their transactions must be completed before the system enters suspend. |
| |
| Interface - BIF Consumer API |
| ============================ |
| |
| BIF framework structs, enums, and functions used by BIF consumers are defined in |
| include/linux/bif/consumer.h |
| |
| Detailed descriptions of the BIF framework functions can be found in: |
| drivers/bif/bif-core.c |
| |
| Get/put handle for a BIF controller: |
| ------------------------------------ |
| |
| struct bif_ctrl *bif_ctrl_get(struct device *consumer_dev); |
| |
| void bif_ctrl_put(struct bif_ctrl *ctrl); |
| |
| int bif_ctrl_count(void); |
| |
| struct bif_ctrl *bif_ctrl_get_by_id(unsigned int id); |
| |
| The function bif_ctrl_get() is intended to be the primary way to get a consumer |
| BIF controller handle. It relies upon the consumer device specifying a |
| "qcom,bif-ctrl" property in its device tree node which points to the phandle of |
| the BIF controller it wishes to use. |
| |
| A secondary mechanism is also provided for drivers without device tree support. |
| bif_ctrl_count() returns the number of BIF controllers currently registered. |
| bif_ctrl_get_by_id() returns a handle to the id'th controller enumerated in |
| registration order. |
| |
| Get/put handle for a BIF slave: |
| ------------------------------- |
| |
| int bif_slave_match_count(const struct bif_ctrl *ctrl, |
| const struct bif_match_criteria *match_criteria); |
| |
| struct bif_slave *bif_slave_match_get(const struct bif_ctrl *ctrl, |
| unsigned int id, const struct bif_match_criteria *match_criteria); |
| |
| void bif_slave_put(struct bif_slave *slave); |
| |
| A consumer finds a slave attached to a given BIF controller by specifying a set |
| of matching criteria. The criteria can include such quantities as manufacturer |
| ID, product ID, function type or function version. It is possible that multiple |
| slaves will match the criteria. bif_slave_match_count() returns how many slaves |
| match the specified criteria. bif_slave_match_get() returns the id'th slave |
| which matches the criteria in an arbitrary, but fixed order (for a constant set |
| of slaves). Consumer drivers need to be able to handle the case of multiple |
| slaves matching the criteria. |
| |
| Additionally, if a battery pack is inserted or removed, then the output of |
| bif_slave_match_count() and bif_slave_match_get() could change. A consumer |
| driver can register to receive notification of battery pack insertion and |
| removal using the bif_ctrl_notifier_register() function listed below. |
| |
| Check if slave handle is still meaningful: |
| ------------------------------------------ |
| |
| int bif_slave_is_present(struct bif_slave *slave); |
| |
| If a battery pack is removed, then the handles for its slaves will no longer be |
| meaningful. All transactions using a handle for a slave that isn't present will |
| fail. The function bif_slave_is_present() allows a consumer to determine if |
| a given slave is still physically present in the system. |
| |
| Get access to the controller handle present in a slave handle: |
| -------------------------------------------------------------- |
| |
| struct bif_ctrl *bif_get_ctrl_handle(struct bif_slave *slave); |
| |
| This function is useful if a consumer wishes to only store a slave handle but |
| also has need to call bus oriented BIF framework functions. |
| |
| Get version and register offset of a BIF function if it is present in a slave: |
| ------------------------------------------------------------------------------ |
| |
| int bif_slave_find_function(struct bif_slave *slave, u8 function, u8 *version, |
| u16 *function_pointer); |
| |
| This function is used by consumers who wish to support given BIF functions |
| (e.g. temperature measurement, authentication, etc.) found inside of slaves. |
| |
| Receive notification upon battery insertion and removal: |
| -------------------------------------------------------- |
| |
| int bif_ctrl_notifier_register(struct bif_ctrl *ctrl, |
| struct notifier_block *nb); |
| |
| int bif_ctrl_notifier_unregister(struct bif_ctrl *ctrl, |
| struct notifier_block *nb); |
| |
| |
| Read or write BIF slave registers: |
| ---------------------------------- |
| |
| int bif_slave_read(struct bif_slave *slave, u16 addr, u8 *buf, int len); |
| |
| int bif_slave_write(struct bif_slave *slave, u16 addr, u8 *buf, int len); |
| |
| |
| Get or set the BIF bus state or period: |
| --------------------------------------- |
| |
| int bif_ctrl_get_bus_state(struct bif_ctrl *ctrl); |
| |
| int bif_ctrl_set_bus_state(struct bif_ctrl *ctrl, enum bif_bus_state state); |
| |
| int bif_ctrl_get_bus_period(struct bif_ctrl *ctrl); |
| |
| int bif_ctrl_set_bus_period(struct bif_ctrl *ctrl, int period_ns); |
| |
| Bus states include: active for communication, active waiting for interrupt, |
| standby, and power down. The MIPI-BIF specification defines the allowed range |
| of bus periods as 2000 ns to 153000 ns. Individual controllers may further |
| restrict the range of allowed periods. When bif_ctrl_set_bus_period() is called |
| the first supported period that greater than or equal to the specified period |
| will be set. |
| |
| Measure battery pack resistance: |
| -------------------------------- |
| |
| int bif_ctrl_measure_rid(struct bif_ctrl *ctrl); |
| |
| This function returns an estimate of the battery pack resistance in ohms. If |
| no battery pack is connected, then the output of this function is undefined. |
| |
| Utilize BIF slave tasks and interrupts: |
| --------------------------------------- |
| |
| int bif_request_irq(struct bif_slave *slave, unsigned int task, |
| struct notifier_block *nb); |
| |
| int bif_free_irq(struct bif_slave *slave, unsigned int task, |
| struct notifier_block *nb); |
| |
| int bif_trigger_task(struct bif_slave *slave, unsigned int task); |
| |
| int bif_task_is_busy(struct bif_slave *slave, unsigned int task); |
| |
| A consumer can request a slave interrupt and specify a notifier to call when the |
| interrupt is triggered. Once the interrupt is requested the consumer will need |
| to call bif_trigger_task() in order to start the task associated with the |
| interrupt (both are identified by the same index). Polling for task completion |
| is also supported via the bif_task_is_busy() function. |
| |
| Raw BIF bus transactions: |
| ------------------------- |
| |
| void bif_ctrl_bus_lock(struct bif_ctrl *ctrl); |
| |
| void bif_ctrl_bus_unlock(struct bif_ctrl *ctrl); |
| |
| int bif_ctrl_raw_transaction(struct bif_ctrl *ctrl, int transaction, u8 data); |
| |
| int bif_ctrl_raw_transaction_read(struct bif_ctrl *ctrl, int transaction, |
| u8 data, int *response); |
| |
| int bif_ctrl_raw_transaction_query(struct bif_ctrl *ctrl, int transaction, |
| u8 data, bool *query_response); |
| |
| int bif_slave_is_selected(struct bif_slave *slave); |
| |
| int bif_slave_select(struct bif_slave *slave); |
| |
| The function bif_ctrl_bus_lock() locks the BIF bus for exclusive use by the |
| consumer. No other transactions will be allowed on the bus including those |
| that would arise from battery insertion/removal or slave interrupt reception. |
| This lock is primarily intended to be used along with the raw transaction |
| functions. These functions allow a consumer to issue any BIF transaction |
| including manufacturer specific bus commands not handled by the BIF framework. |
| |
| While performing raw transactions, features normally performed transparently by |
| the core, such as device selection, are not available. The functions |
| bif_slave_select() and bif_slave_is_selected() can be used to fill in this gap |
| so that raw transactions are performed on the desired slave. |
| |
| Notify the BIF core that a battery has been inserted or removed: |
| ---------------------------------------------------------------- |
| |
| int bif_ctrl_signal_battery_changed(struct bif_ctrl *ctrl); |
| |
| This function should only be called on systems where the BIF controller driver |
| is architecturally unable to detect battery insertion and removal on its own. |
| |
| Perform BIF object CRC using CRC-CCITT algorithm: |
| ------------------------------------------------- |
| |
| u16 bif_crc_ccitt(const u8 *buffer, int len); |
| |
| Interface - BIF Controller API |
| ============================== |
| |
| BIF framework structs and functions used by BIF controllers are defined in: |
| include/linux/bif/driver.h |
| |
| Ops found in struct bif_ctrl_ops: |
| --------------------------------- |
| |
| int (*bus_transaction) (struct bif_ctrl_dev *bdev, int transaction, u8 data); |
| |
| int (*bus_transaction_query) (struct bif_ctrl_dev *bdev, int transaction, |
| u8 data, bool *query_response); |
| |
| int (*bus_transaction_read) (struct bif_ctrl_dev *bdev, int transaction, |
| u8 data, int *response); |
| |
| int (*read_slave_registers) (struct bif_ctrl_dev *bdev, u16 addr, |
| u8 *data, int len); |
| |
| int (*write_slave_registers) (struct bif_ctrl_dev *bdev, u16 addr, |
| const u8 *data, int len); |
| |
| int (*get_bus_period) (struct bif_ctrl_dev *bdev); |
| |
| int (*set_bus_period) (struct bif_ctrl_dev *bdev, int period_ns); |
| |
| int (*get_battery_presence) (struct bif_ctrl_dev *bdev); |
| |
| int (*get_battery_rid) (struct bif_ctrl_dev *bdev); |
| |
| int (*get_bus_state) (struct bif_ctrl_dev *bdev); |
| |
| int (*set_bus_state) (struct bif_ctrl_dev *bdev, int state); |
| |
| A BIF controller driver registers a set of call back functions which instantiate |
| these ops. The BIF framework then calls these functions based on internal and |
| consumer needs. |
| |
| The ops bus_transaction(), bus_transaction_query(), and bus_transaction_read() |
| carry out the controller hardware specific actions to perform BIF transactions |
| on the BIF bus. These transactions result in no slave response, a pulse in |
| response, or a word in response respectively. The ops read_slave_registers() |
| and write_slave_registers() internally must perform all transactions necessary |
| to read and write to BIF slave registers. These ops exist so that burst reads |
| and writes can take place since these activities have very tight timing |
| constraints that the BIF core cannot handle. |
| |
| The ops get_bus_period() and set_bus_period() return the current bus clock base |
| period in nanoseconds and change the period to a new value respectively. The |
| ops get_bus_state() and set_bus_state() allow for monitoring and controlling the |
| bus state (i.e. active for communication, active waiting for interrupt, standby, |
| or power down). The op get_battery_presence() returns if any battery pack |
| (smart or low cost) is currently connected to the BCL. The op get_battery_rid() |
| returns a best estimate of the Rid battery pack pull down ID resistance in ohms |
| which can be used to determine if the battery pack is smart or low cost. |
| |
| Register/unregister a BIF controller: |
| ------------------------------------- |
| |
| struct bif_ctrl_dev *bif_ctrl_register(struct bif_ctrl_desc *bif_desc, |
| struct device *dev, void *driver_data, struct device_node *of_node); |
| |
| void bif_ctrl_unregister(struct bif_ctrl_dev *bdev); |
| |
| Notify the BIF framework that a battery has been inserted or removed: |
| --------------------------------------------------------------------- |
| |
| int bif_ctrl_notify_battery_changed(struct bif_ctrl_dev *bdev); |
| |
| The BIF core will then call the get_battery_presence() op internally to |
| determine if the event is an insertion or removal. |
| |
| Notify the BIF framework that a slave interrupt has been received: |
| ------------------------------------------------------------------ |
| |
| int bif_ctrl_notify_slave_irq(struct bif_ctrl_dev *bdev); |
| |
| Upon receiving this call, the BIF core interrogates each slave to determine |
| which slaves have pending interrupts. It then iterates through all interrupts |
| on those slaves clearing all pending interrupts and notifying any consumers |
| waiting for the interrupts. |
| |
| Get BIF controller private data: |
| -------------------------------- |
| |
| void *bdev_get_drvdata(struct bif_ctrl_dev *bdev); |
| |
| Config options |
| ============== |
| |
| CONFIG_BIF - Enables BIF framework support. |
| |
| User space utilities |
| ==================== |
| |
| No user space interface is provided in the BIF framework. Therefore, user |
| space will not be able to directly use it. |
| |
| To do |
| ===== |
| |
| It is conceivable that the BIF framework should take some action during |
| system suspend and resume. However, it is not clear exactly what should be |
| done given that the BCL would still need to be active in order to detect |
| battery removal while suspended. |
| |
| sysfs nodes could be added which describe slaves as well as functions and |
| objects within the slaves. However these nodes would be read-only and would |
| really only be useful for descriptive as opposed to control purposes. |
| |
| The exact time at which slave searching, function enumeration, and object |
| loading takes place could be optimized in order to improve performance to |
| some degree. It could also be made configurable at a controller level if |
| needed. |