361 lines
14 KiB
ReStructuredText
361 lines
14 KiB
ReStructuredText
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==================================
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PMBus core driver and internal API
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==================================
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Introduction
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============
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[from pmbus.org] The Power Management Bus (PMBus) is an open standard
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power-management protocol with a fully defined command language that facilitates
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communication with power converters and other devices in a power system. The
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protocol is implemented over the industry-standard SMBus serial interface and
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enables programming, control, and real-time monitoring of compliant power
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conversion products. This flexible and highly versatile standard allows for
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communication between devices based on both analog and digital technologies, and
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provides true interoperability which will reduce design complexity and shorten
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time to market for power system designers. Pioneered by leading power supply and
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semiconductor companies, this open power system standard is maintained and
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promoted by the PMBus Implementers Forum (PMBus-IF), comprising 30+ adopters
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with the objective to provide support to, and facilitate adoption among, users.
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Unfortunately, while PMBus commands are standardized, there are no mandatory
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commands, and manufacturers can add as many non-standard commands as they like.
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Also, different PMBUs devices act differently if non-supported commands are
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executed. Some devices return an error, some devices return 0xff or 0xffff and
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set a status error flag, and some devices may simply hang up.
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Despite all those difficulties, a generic PMBus device driver is still useful
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and supported since kernel version 2.6.39. However, it was necessary to support
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device specific extensions in addition to the core PMBus driver, since it is
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simply unknown what new device specific functionality PMBus device developers
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come up with next.
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To make device specific extensions as scalable as possible, and to avoid having
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to modify the core PMBus driver repeatedly for new devices, the PMBus driver was
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split into core, generic, and device specific code. The core code (in
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pmbus_core.c) provides generic functionality. The generic code (in pmbus.c)
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provides support for generic PMBus devices. Device specific code is responsible
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for device specific initialization and, if needed, maps device specific
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functionality into generic functionality. This is to some degree comparable
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to PCI code, where generic code is augmented as needed with quirks for all kinds
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of devices.
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PMBus device capabilities auto-detection
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========================================
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For generic PMBus devices, code in pmbus.c attempts to auto-detect all supported
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PMBus commands. Auto-detection is somewhat limited, since there are simply too
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many variables to consider. For example, it is almost impossible to autodetect
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which PMBus commands are paged and which commands are replicated across all
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pages (see the PMBus specification for details on multi-page PMBus devices).
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For this reason, it often makes sense to provide a device specific driver if not
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all commands can be auto-detected. The data structures in this driver can be
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used to inform the core driver about functionality supported by individual
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chips.
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Some commands are always auto-detected. This applies to all limit commands
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(lcrit, min, max, and crit attributes) as well as associated alarm attributes.
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Limits and alarm attributes are auto-detected because there are simply too many
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possible combinations to provide a manual configuration interface.
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PMBus internal API
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==================
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The API between core and device specific PMBus code is defined in
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drivers/hwmon/pmbus/pmbus.h. In addition to the internal API, pmbus.h defines
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standard PMBus commands and virtual PMBus commands.
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Standard PMBus commands
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-----------------------
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Standard PMBus commands (commands values 0x00 to 0xff) are defined in the PMBUs
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specification.
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Virtual PMBus commands
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----------------------
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Virtual PMBus commands are provided to enable support for non-standard
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functionality which has been implemented by several chip vendors and is thus
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desirable to support.
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Virtual PMBus commands start with command value 0x100 and can thus easily be
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distinguished from standard PMBus commands (which can not have values larger
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than 0xff). Support for virtual PMBus commands is device specific and thus has
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to be implemented in device specific code.
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Virtual commands are named PMBUS_VIRT_xxx and start with PMBUS_VIRT_BASE. All
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virtual commands are word sized.
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There are currently two types of virtual commands.
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- READ commands are read-only; writes are either ignored or return an error.
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- RESET commands are read/write. Reading reset registers returns zero
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(used for detection), writing any value causes the associated history to be
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reset.
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Virtual commands have to be handled in device specific driver code. Chip driver
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code returns non-negative values if a virtual command is supported, or a
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negative error code if not. The chip driver may return -ENODATA or any other
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Linux error code in this case, though an error code other than -ENODATA is
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handled more efficiently and thus preferred. Either case, the calling PMBus
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core code will abort if the chip driver returns an error code when reading
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or writing virtual registers (in other words, the PMBus core code will never
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send a virtual command to a chip).
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PMBus driver information
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------------------------
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PMBus driver information, defined in struct pmbus_driver_info, is the main means
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for device specific drivers to pass information to the core PMBus driver.
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Specifically, it provides the following information.
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- For devices supporting its data in Direct Data Format, it provides coefficients
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for converting register values into normalized data. This data is usually
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provided by chip manufacturers in device datasheets.
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- Supported chip functionality can be provided to the core driver. This may be
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necessary for chips which react badly if non-supported commands are executed,
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and/or to speed up device detection and initialization.
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- Several function entry points are provided to support overriding and/or
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augmenting generic command execution. This functionality can be used to map
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non-standard PMBus commands to standard commands, or to augment standard
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command return values with device specific information.
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PEC Support
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===========
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Many PMBus devices support SMBus PEC (Packet Error Checking). If supported
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by both the I2C adapter and by the PMBus chip, it is by default enabled.
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If PEC is supported, the PMBus core driver adds an attribute named 'pec' to
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the I2C device. This attribute can be used to control PEC support in the
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communication with the PMBus chip.
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API functions
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=============
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Functions provided by chip driver
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---------------------------------
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All functions return the command return value (read) or zero (write) if
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successful. A return value of -ENODATA indicates that there is no manufacturer
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specific command, but that a standard PMBus command may exist. Any other
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negative return value indicates that the commands does not exist for this
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chip, and that no attempt should be made to read or write the standard
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command.
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As mentioned above, an exception to this rule applies to virtual commands,
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which *must* be handled in driver specific code. See "Virtual PMBus Commands"
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above for more details.
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Command execution in the core PMBus driver code is as follows::
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if (chip_access_function) {
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status = chip_access_function();
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if (status != -ENODATA)
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return status;
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}
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if (command >= PMBUS_VIRT_BASE) /* For word commands/registers only */
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return -EINVAL;
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return generic_access();
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Chip drivers may provide pointers to the following functions in struct
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pmbus_driver_info. All functions are optional.
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::
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int (*read_byte_data)(struct i2c_client *client, int page, int reg);
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Read byte from page <page>, register <reg>.
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<page> may be -1, which means "current page".
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::
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int (*read_word_data)(struct i2c_client *client, int page, int phase,
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int reg);
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Read word from page <page>, phase <phase>, register <reg>. If the chip does not
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support multiple phases, the phase parameter can be ignored. If the chip
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supports multiple phases, a phase value of 0xff indicates all phases.
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::
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int (*write_word_data)(struct i2c_client *client, int page, int reg,
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u16 word);
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Write word to page <page>, register <reg>.
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::
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int (*write_byte)(struct i2c_client *client, int page, u8 value);
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Write byte to page <page>, register <reg>.
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<page> may be -1, which means "current page".
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::
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int (*identify)(struct i2c_client *client, struct pmbus_driver_info *info);
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Determine supported PMBus functionality. This function is only necessary
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if a chip driver supports multiple chips, and the chip functionality is not
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pre-determined. It is currently only used by the generic pmbus driver
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(pmbus.c).
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Functions exported by core driver
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---------------------------------
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Chip drivers are expected to use the following functions to read or write
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PMBus registers. Chip drivers may also use direct I2C commands. If direct I2C
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commands are used, the chip driver code must not directly modify the current
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page, since the selected page is cached in the core driver and the core driver
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will assume that it is selected. Using pmbus_set_page() to select a new page
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is mandatory.
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::
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int pmbus_set_page(struct i2c_client *client, u8 page, u8 phase);
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Set PMBus page register to <page> and <phase> for subsequent commands.
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If the chip does not support multiple phases, the phase parameter is
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ignored. Otherwise, a phase value of 0xff selects all phases.
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::
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int pmbus_read_word_data(struct i2c_client *client, u8 page, u8 phase,
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u8 reg);
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Read word data from <page>, <phase>, <reg>. Similar to
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i2c_smbus_read_word_data(), but selects page and phase first. If the chip does
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not support multiple phases, the phase parameter is ignored. Otherwise, a phase
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value of 0xff selects all phases.
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::
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int pmbus_write_word_data(struct i2c_client *client, u8 page, u8 reg,
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u16 word);
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Write word data to <page>, <reg>. Similar to i2c_smbus_write_word_data(), but
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selects page first.
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::
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int pmbus_read_byte_data(struct i2c_client *client, int page, u8 reg);
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Read byte data from <page>, <reg>. Similar to i2c_smbus_read_byte_data(), but
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selects page first. <page> may be -1, which means "current page".
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::
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int pmbus_write_byte(struct i2c_client *client, int page, u8 value);
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Write byte data to <page>, <reg>. Similar to i2c_smbus_write_byte(), but
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selects page first. <page> may be -1, which means "current page".
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::
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void pmbus_clear_faults(struct i2c_client *client);
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Execute PMBus "Clear Fault" command on all chip pages.
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This function calls the device specific write_byte function if defined.
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Therefore, it must _not_ be called from that function.
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::
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bool pmbus_check_byte_register(struct i2c_client *client, int page, int reg);
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Check if byte register exists. Return true if the register exists, false
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otherwise.
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This function calls the device specific write_byte function if defined to
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obtain the chip status. Therefore, it must _not_ be called from that function.
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::
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bool pmbus_check_word_register(struct i2c_client *client, int page, int reg);
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Check if word register exists. Return true if the register exists, false
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otherwise.
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This function calls the device specific write_byte function if defined to
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obtain the chip status. Therefore, it must _not_ be called from that function.
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::
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int pmbus_do_probe(struct i2c_client *client, struct pmbus_driver_info *info);
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Execute probe function. Similar to standard probe function for other drivers,
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with the pointer to struct pmbus_driver_info as additional argument. Calls
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identify function if supported. Must only be called from device probe
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function.
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::
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const struct pmbus_driver_info
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*pmbus_get_driver_info(struct i2c_client *client);
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Return pointer to struct pmbus_driver_info as passed to pmbus_do_probe().
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PMBus driver platform data
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==========================
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PMBus platform data is defined in include/linux/pmbus.h. Platform data
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currently provides a flags field with four bits used::
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#define PMBUS_SKIP_STATUS_CHECK BIT(0)
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#define PMBUS_WRITE_PROTECTED BIT(1)
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#define PMBUS_NO_CAPABILITY BIT(2)
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#define PMBUS_READ_STATUS_AFTER_FAILED_CHECK BIT(3)
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struct pmbus_platform_data {
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u32 flags; /* Device specific flags */
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/* regulator support */
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int num_regulators;
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struct regulator_init_data *reg_init_data;
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};
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Flags
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-----
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PMBUS_SKIP_STATUS_CHECK
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During register detection, skip checking the status register for
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communication or command errors.
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Some PMBus chips respond with valid data when trying to read an unsupported
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register. For such chips, checking the status register is mandatory when
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trying to determine if a chip register exists or not.
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Other PMBus chips don't support the STATUS_CML register, or report
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communication errors for no explicable reason. For such chips, checking the
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status register must be disabled.
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Some i2c controllers do not support single-byte commands (write commands with
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no data, i2c_smbus_write_byte()). With such controllers, clearing the status
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register is impossible, and the PMBUS_SKIP_STATUS_CHECK flag must be set.
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PMBUS_WRITE_PROTECTED
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Set if the chip is write protected and write protection is not determined
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by the standard WRITE_PROTECT command.
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PMBUS_NO_CAPABILITY
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Some PMBus chips don't respond with valid data when reading the CAPABILITY
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register. For such chips, this flag should be set so that the PMBus core
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driver doesn't use CAPABILITY to determine it's behavior.
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PMBUS_READ_STATUS_AFTER_FAILED_CHECK
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Read the STATUS register after each failed register check.
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Some PMBus chips end up in an undefined state when trying to read an
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unsupported register. For such chips, it is necessary to reset the
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chip pmbus controller to a known state after a failed register check.
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This can be done by reading a known register. By setting this flag the
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driver will try to read the STATUS register after each failed
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register check. This read may fail, but it will put the chip into a
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known state.
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