提交 b8265621 编写于 作者: J Jacob Keller 提交者: David S. Miller

Add pldmfw library for PLDM firmware update

The pldmfw library is used to implement common logic needed to flash
devices based on firmware files using the format described by the PLDM
for Firmware Update standard.

This library consists of logic to parse the PLDM file format from
a firmware file object, as well as common logic for sending the relevant
PLDM header data to the device firmware.

A simple ops table is provided so that device drivers can implement
device specific hardware interactions while keeping the common logic to
the pldmfw library.

This library will be used by the Intel ice networking driver as part of
implementing device flash update via devlink. The library aims to be
vendor and device agnostic. For this reason, it has been placed in
lib/pldmfw, in the hopes that other devices which use the PLDM firmware
file format may benefit from it in the future. However, do note that not
all features defined in the PLDM standard have been implemented.
Signed-off-by: NJacob Keller <jacob.e.keller@intel.com>
Signed-off-by: NDavid S. Miller <davem@davemloft.net>
上级 323410ef
......@@ -95,6 +95,7 @@ available subsections can be seen below.
phy/index
pti_intel_mid
pwm
pldmfw/index
rfkill
serial/index
sm501
......
.. SPDX-License-Identifier: GPL-2.0-only
=========================
Driver-specific callbacks
=========================
The ``pldmfw`` module relies on the device driver for implementing device
specific behavior using the following operations.
``.match_record``
-----------------
The ``.match_record`` operation is used to determine whether a given PLDM
record matches the device being updated. This requires comparing the record
descriptors in the record with information from the device. Many record
descriptors are defined by the PLDM standard, but it is also allowed for
devices to implement their own descriptors.
The ``.match_record`` operation should return true if a given record matches
the device.
``.send_package_data``
----------------------
The ``.send_package_data`` operation is used to send the device-specific
package data in a record to the device firmware. If the matching record
provides package data, ``pldmfw`` will call the ``.send_package_data``
function with a pointer to the package data and with the package data
length. The device driver should send this data to firmware.
``.send_component_table``
-------------------------
The ``.send_component_table`` operation is used to forward component
information to the device. It is called once for each applicable component,
that is, for each component indicated by the matching record. The
device driver should send the component information to the device firmware,
and wait for a response. The provided transfer flag indicates whether this
is the first, last, or a middle component, and is expected to be forwarded
to firmware as part of the component table information. The driver should an
error in the case when the firmware indicates that the component cannot be
updated, or return zero if the component can be updated.
``.flash_component``
--------------------
The ``.flash_component`` operation is used to inform the device driver to
flash a given component. The driver must perform any steps necessary to send
the component data to the device.
``.finalize_update``
--------------------
The ``.finalize_update`` operation is used by the ``pldmfw`` library in
order to allow the device driver to perform any remaining device specific
logic needed to finish the update.
.. SPDX-License-Identifier: GPL-2.0-only
==================================
PLDM Firmware file format overview
==================================
A PLDM firmware package is a binary file which contains a header that
describes the contents of the firmware package. This includes an initial
package header, one or more firmware records, and one or more components
describing the actual flash contents to program.
This diagram provides an overview of the file format::
overall file layout
+----------------------+
| |
| Package Header |
| |
+----------------------+
| |
| Device Records |
| |
+----------------------+
| |
| Component Info |
| |
+----------------------+
| |
| Package Header CRC |
| |
+----------------------+
| |
| Component Image 1 |
| |
+----------------------+
| |
| Component Image 2 |
| |
+----------------------+
| |
| ... |
| |
+----------------------+
| |
| Component Image N |
| |
+----------------------+
Package Header
==============
The package header begins with the UUID of the PLDM file format, and
contains information about the version of the format that the file uses. It
also includes the total header size, a release date, the size of the
component bitmap, and an overall package version.
The following diagram provides an overview of the package header::
header layout
+-------------------------+
| PLDM UUID |
+-------------------------+
| Format Revision |
+-------------------------+
| Header Size |
+-------------------------+
| Release Date |
+-------------------------+
| Component Bitmap Length |
+-------------------------+
| Package Version Info |
+-------------------------+
Device Records
==============
The device firmware records area starts with a count indicating the total
number of records in the file, followed by each record. A single device
record describes what device matches this record. All valid PLDM firmware
files must contain at least one record, but optionally may contain more than
one record if they support multiple devices.
Each record will identify the device it supports via TLVs that describe the
device, such as the PCI device and vendor information. It will also indicate
which set of components that are used by this device. It is possible that
only subset of provided components will be used by a given record. A record
may also optionally contain device-specific package data that will be used
by the device firmware during the update process.
The following diagram provides an overview of the device record area::
area layout
+---------------+
| |
| Record Count |
| |
+---------------+
| |
| Record 1 |
| |
+---------------+
| |
| Record 2 |
| |
+---------------+
| |
| ... |
| |
+---------------+
| |
| Record N |
| |
+---------------+
record layout
+-----------------------+
| Record Length |
+-----------------------+
| Descriptor Count |
+-----------------------+
| Option Flags |
+-----------------------+
| Version Settings |
+-----------------------+
| Package Data Length |
+-----------------------+
| Applicable Components |
+-----------------------+
| Version String |
+-----------------------+
| Descriptor TLVs |
+-----------------------+
| Package Data |
+-----------------------+
Component Info
==============
The component information area begins with a count of the number of
components. Following this count is a description for each component. The
component information points to the location in the file where the component
data is stored, and includes version data used to identify the version of
the component.
The following diagram provides an overview of the component area::
area layout
+-----------------+
| |
| Component Count |
| |
+-----------------+
| |
| Component 1 |
| |
+-----------------+
| |
| Component 2 |
| |
+-----------------+
| |
| ... |
| |
+-----------------+
| |
| Component N |
| |
+-----------------+
component layout
+------------------------+
| Classification |
+------------------------+
| Component Identifier |
+------------------------+
| Comparison Stamp |
+------------------------+
| Component Options |
+------------------------+
| Activation Method |
+------------------------+
| Location Offset |
+------------------------+
| Component Size |
+------------------------+
| Component Version Info |
+------------------------+
| Package Data |
+------------------------+
Package Header CRC
==================
Following the component information is a short 4-byte CRC calculated over
the contents of all of the header information.
Component Images
================
The component images follow the package header information in the PLDM
firmware file. Each of these is simply a binary chunk with its start and
size defined by the matching component structure in the component info area.
.. SPDX-License-Identifier: GPL-2.0-only
==================================
PLDM Firmware Flash Update Library
==================================
``pldmfw`` implements functionality for updating the flash on a device using
the PLDM for Firmware Update standard
<https://www.dmtf.org/documents/pmci/pldm-firmware-update-specification-100>.
.. toctree::
:maxdepth: 1
file-format
driver-ops
==================================
Overview of the ``pldmfw`` library
==================================
The ``pldmfw`` library is intended to be used by device drivers for
implementing device flash update based on firmware files following the PLDM
firwmare file format.
It is implemented using an ops table that allows device drivers to provide
the underlying device specific functionality.
``pldmfw`` implements logic to parse the packed binary format of the PLDM
firmware file into data structures, and then uses the provided function
operations to determine if the firmware file is a match for the device. If
so, it sends the record and component data to the firmware using the device
specific implementations provided by device drivers. Once the device
firmware indicates that the update may be performed, the firmware data is
sent to the device for programming.
Parsing the PLDM file
=====================
The PLDM file format uses packed binary data, with most multi-byte fields
stored in the Little Endian format. Several pieces of data are variable
length, including version strings and the number of records and components.
Due to this, it is not straight forward to index the record, record
descriptors, or components.
To avoid proliferating access to the packed binary data, the ``pldmfw``
library parses and extracts this data into simpler structures for ease of
access.
In order to safely process the firmware file, care is taken to avoid
unaligned access of multi-byte fields, and to properly convert from Little
Endian to CPU host format. Additionally the records, descriptors, and
components are stored in linked lists.
Performing a flash update
=========================
To perform a flash update, the ``pldmfw`` module performs the following
steps
1. Parse the firmware file for record and component information
2. Scan through the records and determine if the device matches any record
in the file. The first matched record will be used.
3. If the matching record provides package data, send this package data to
the device.
4. For each component that the record indicates, send the component data to
the device. For each component, the firmware may respond with an
indication of whether the update is suitable or not. If any component is
not suitable, the update is canceled.
5. For each component, send the binary data to the device firmware for
updating.
6. After all components are programmed, perform any final device-specific
actions to finalize the update.
......@@ -13604,6 +13604,13 @@ S: Maintained
F: Documentation/devicetree/bindings/iio/chemical/plantower,pms7003.yaml
F: drivers/iio/chemical/pms7003.c
PLDMFW LIBRARY
M: Jacob Keller <jacob.e.keller@intel.com>
S: Maintained
F: Documentation/driver-api/pldmfw/
F: include/linux/pldmfw.h
F: lib/pldmfw/
PLX DMA DRIVER
M: Logan Gunthorpe <logang@deltatee.com>
S: Maintained
......
/* SPDX-License-Identifier: GPL-2.0 */
/* Copyright (C) 2018-2019, Intel Corporation. */
#ifndef _PLDMFW_H_
#define _PLDMFW_H_
#include <linux/list.h>
#include <linux/firmware.h>
#define PLDM_DEVICE_UPDATE_CONTINUE_AFTER_FAIL BIT(0)
#define PLDM_STRING_TYPE_UNKNOWN 0
#define PLDM_STRING_TYPE_ASCII 1
#define PLDM_STRING_TYPE_UTF8 2
#define PLDM_STRING_TYPE_UTF16 3
#define PLDM_STRING_TYPE_UTF16LE 4
#define PLDM_STRING_TYPE_UTF16BE 5
struct pldmfw_record {
struct list_head entry;
/* List of descriptor TLVs */
struct list_head descs;
/* Component Set version string*/
const u8 *version_string;
u8 version_type;
u8 version_len;
/* Package Data length */
u16 package_data_len;
/* Bitfield of Device Update Flags */
u32 device_update_flags;
/* Package Data block */
const u8 *package_data;
/* Bitmap of components applicable to this record */
unsigned long *component_bitmap;
u16 component_bitmap_len;
};
/* Standard descriptor TLV identifiers */
#define PLDM_DESC_ID_PCI_VENDOR_ID 0x0000
#define PLDM_DESC_ID_IANA_ENTERPRISE_ID 0x0001
#define PLDM_DESC_ID_UUID 0x0002
#define PLDM_DESC_ID_PNP_VENDOR_ID 0x0003
#define PLDM_DESC_ID_ACPI_VENDOR_ID 0x0004
#define PLDM_DESC_ID_PCI_DEVICE_ID 0x0100
#define PLDM_DESC_ID_PCI_SUBVENDOR_ID 0x0101
#define PLDM_DESC_ID_PCI_SUBDEV_ID 0x0102
#define PLDM_DESC_ID_PCI_REVISION_ID 0x0103
#define PLDM_DESC_ID_PNP_PRODUCT_ID 0x0104
#define PLDM_DESC_ID_ACPI_PRODUCT_ID 0x0105
#define PLDM_DESC_ID_VENDOR_DEFINED 0xFFFF
struct pldmfw_desc_tlv {
struct list_head entry;
const u8 *data;
u16 type;
u16 size;
};
#define PLDM_CLASSIFICATION_UNKNOWN 0x0000
#define PLDM_CLASSIFICATION_OTHER 0x0001
#define PLDM_CLASSIFICATION_DRIVER 0x0002
#define PLDM_CLASSIFICATION_CONFIG_SW 0x0003
#define PLDM_CLASSIFICATION_APP_SW 0x0004
#define PLDM_CLASSIFICATION_INSTRUMENTATION 0x0005
#define PLDM_CLASSIFICATION_BIOS 0x0006
#define PLDM_CLASSIFICATION_DIAGNOSTIC_SW 0x0007
#define PLDM_CLASSIFICATION_OS 0x0008
#define PLDM_CLASSIFICATION_MIDDLEWARE 0x0009
#define PLDM_CLASSIFICATION_FIRMWARE 0x000A
#define PLDM_CLASSIFICATION_CODE 0x000B
#define PLDM_CLASSIFICATION_SERVICE_PACK 0x000C
#define PLDM_CLASSIFICATION_SOFTWARE_BUNDLE 0x000D
#define PLDM_ACTIVATION_METHOD_AUTO BIT(0)
#define PLDM_ACTIVATION_METHOD_SELF_CONTAINED BIT(1)
#define PLDM_ACTIVATION_METHOD_MEDIUM_SPECIFIC BIT(2)
#define PLDM_ACTIVATION_METHOD_REBOOT BIT(3)
#define PLDM_ACTIVATION_METHOD_DC_CYCLE BIT(4)
#define PLDM_ACTIVATION_METHOD_AC_CYCLE BIT(5)
#define PLDMFW_COMPONENT_OPTION_FORCE_UPDATE BIT(0)
#define PLDMFW_COMPONENT_OPTION_USE_COMPARISON_STAMP BIT(1)
struct pldmfw_component {
struct list_head entry;
/* component identifier */
u16 classification;
u16 identifier;
u16 options;
u16 activation_method;
u32 comparison_stamp;
u32 component_size;
const u8 *component_data;
/* Component version string */
const u8 *version_string;
u8 version_type;
u8 version_len;
/* component index */
u8 index;
};
/* Transfer flag used for sending components to the firmware */
#define PLDM_TRANSFER_FLAG_START BIT(0)
#define PLDM_TRANSFER_FLAG_MIDDLE BIT(1)
#define PLDM_TRANSFER_FLAG_END BIT(2)
struct pldmfw_ops;
/* Main entry point to the PLDM firmware update engine. Device drivers
* should embed this in a private structure and use container_of to obtain
* a pointer to their own data, used to implement the device specific
* operations.
*/
struct pldmfw {
const struct pldmfw_ops *ops;
struct device *dev;
};
bool pldmfw_op_pci_match_record(struct pldmfw *context, struct pldmfw_record *record);
/* Operations invoked by the generic PLDM firmware update engine. Used to
* implement device specific logic.
*
* @match_record: check if the device matches the given record. For
* convenience, a standard implementation is provided for PCI devices.
*
* @send_package_data: send the package data associated with the matching
* record to firmware.
*
* @send_component_table: send the component data associated with a given
* component to firmware. Called once for each applicable component.
*
* @flash_component: Flash the data for a given component to the device.
* Called once for each applicable component, after all component tables have
* been sent.
*
* @finalize_update: (optional) Finish the update. Called after all components
* have been flashed.
*/
struct pldmfw_ops {
bool (*match_record)(struct pldmfw *context, struct pldmfw_record *record);
int (*send_package_data)(struct pldmfw *context, const u8 *data, u16 length);
int (*send_component_table)(struct pldmfw *context, struct pldmfw_component *component,
u8 transfer_flag);
int (*flash_component)(struct pldmfw *context, struct pldmfw_component *component);
int (*finalize_update)(struct pldmfw *context);
};
int pldmfw_flash_image(struct pldmfw *context, const struct firmware *fw);
#endif
......@@ -676,3 +676,7 @@ config GENERIC_LIB_CMPDI2
config GENERIC_LIB_UCMPDI2
bool
config PLDMFW
bool
default n
......@@ -315,6 +315,9 @@ obj-$(CONFIG_GENERIC_LIB_CMPDI2) += cmpdi2.o
obj-$(CONFIG_GENERIC_LIB_UCMPDI2) += ucmpdi2.o
obj-$(CONFIG_OBJAGG) += objagg.o
# pldmfw library
obj-$(CONFIG_PLDMFW) += pldmfw/
# KUnit tests
obj-$(CONFIG_LIST_KUNIT_TEST) += list-test.o
obj-$(CONFIG_LINEAR_RANGES_TEST) += test_linear_ranges.o
# SPDX-License-Identifier: GPL-2.0-only
obj-$(CONFIG_PLDMFW) += pldmfw.o
此差异已折叠。
/* SPDX-License-Identifier: GPL-2.0 */
/* Copyright (C) 2018-2019, Intel Corporation. */
#ifndef _PLDMFW_PRIVATE_H_
#define _PLDMFW_PRIVATE_H_
/* The following data structures define the layout of a firmware binary
* following the "PLDM For Firmware Update Specification", DMTF standard
* #DSP0267.
*
* pldmfw.c uses these structures to implement a simple engine that will parse
* a fw binary file in this format and perform a firmware update for a given
* device.
*
* Due to the variable sized data layout, alignment of fields within these
* structures is not guaranteed when reading. For this reason, all multi-byte
* field accesses should be done using the unaligned access macros.
* Additionally, the standard specifies that multi-byte fields are in
* LittleEndian format.
*
* The structure definitions are not made public, in order to keep direct
* accesses within code that is prepared to deal with the limitation of
* unaligned access.
*/
/* UUID for PLDM firmware packages: f018878c-cb7d-4943-9800-a02f059aca02 */
static const uuid_t pldm_firmware_header_id =
UUID_INIT(0xf018878c, 0xcb7d, 0x4943,
0x98, 0x00, 0xa0, 0x2f, 0x05, 0x9a, 0xca, 0x02);
/* Revision number of the PLDM header format this code supports */
#define PACKAGE_HEADER_FORMAT_REVISION 0x01
/* timestamp104 structure defined in PLDM Base specification */
#define PLDM_TIMESTAMP_SIZE 13
struct __pldm_timestamp {
u8 b[PLDM_TIMESTAMP_SIZE];
} __packed __aligned(1);
/* Package Header Information */
struct __pldm_header {
uuid_t id; /* PackageHeaderIdentifier */
u8 revision; /* PackageHeaderFormatRevision */
__le16 size; /* PackageHeaderSize */
struct __pldm_timestamp release_date; /* PackageReleaseDateTime */
__le16 component_bitmap_len; /* ComponentBitmapBitLength */
u8 version_type; /* PackageVersionStringType */
u8 version_len; /* PackageVersionStringLength */
/*
* DSP0267 also includes the following variable length fields at the
* end of this structure:
*
* PackageVersionString, length is version_len.
*
* The total size of this section is
* sizeof(pldm_header) + version_len;
*/
u8 version_string[]; /* PackageVersionString */
} __packed __aligned(1);
/* Firmware Device ID Record */
struct __pldmfw_record_info {
__le16 record_len; /* RecordLength */
u8 descriptor_count; /* DescriptorCount */
__le32 device_update_flags; /* DeviceUpdateOptionFlags */
u8 version_type; /* ComponentImageSetVersionType */
u8 version_len; /* ComponentImageSetVersionLength */
__le16 package_data_len; /* FirmwareDevicePackageDataLength */
/*
* DSP0267 also includes the following variable length fields at the
* end of this structure:
*
* ApplicableComponents, length is component_bitmap_len from header
* ComponentImageSetVersionString, length is version_len
* RecordDescriptors, a series of TLVs with 16bit type and length
* FirmwareDevicePackageData, length is package_data_len
*
* The total size of each record is
* sizeof(pldmfw_record_info) +
* component_bitmap_len (converted to bytes!) +
* version_len +
* <length of RecordDescriptors> +
* package_data_len
*/
u8 variable_record_data[];
} __packed __aligned(1);
/* Firmware Descriptor Definition */
struct __pldmfw_desc_tlv {
__le16 type; /* DescriptorType */
__le16 size; /* DescriptorSize */
u8 data[]; /* DescriptorData */
} __aligned(1);
/* Firmware Device Identification Area */
struct __pldmfw_record_area {
u8 record_count; /* DeviceIDRecordCount */
/* This is not a struct type because the size of each record varies */
u8 records[];
} __aligned(1);
/* Individual Component Image Information */
struct __pldmfw_component_info {
__le16 classification; /* ComponentClassfication */
__le16 identifier; /* ComponentIdentifier */
__le32 comparison_stamp; /* ComponentComparisonStamp */
__le16 options; /* componentOptions */
__le16 activation_method; /* RequestedComponentActivationMethod */
__le32 location_offset; /* ComponentLocationOffset */
__le32 size; /* ComponentSize */
u8 version_type; /* ComponentVersionStringType */
u8 version_len; /* ComponentVersionStringLength */
/*
* DSP0267 also includes the following variable length fields at the
* end of this structure:
*
* ComponentVersionString, length is version_len
*
* The total size of this section is
* sizeof(pldmfw_component_info) + version_len;
*/
u8 version_string[]; /* ComponentVersionString */
} __packed __aligned(1);
/* Component Image Information Area */
struct __pldmfw_component_area {
__le16 component_image_count;
/* This is not a struct type because the component size varies */
u8 components[];
} __aligned(1);
/**
* pldm_first_desc_tlv
* @start: byte offset of the start of the descriptor TLVs
*
* Converts the starting offset of the descriptor TLVs into a pointer to the
* first descriptor.
*/
#define pldm_first_desc_tlv(start) \
((const struct __pldmfw_desc_tlv *)(start))
/**
* pldm_next_desc_tlv
* @desc: pointer to a descriptor TLV
*
* Finds the pointer to the next descriptor following a given descriptor
*/
#define pldm_next_desc_tlv(desc) \
((const struct __pldmfw_desc_tlv *)((desc)->data + \
get_unaligned_le16(&(desc)->size)))
/**
* pldm_for_each_desc_tlv
* @i: variable to store descriptor index
* @desc: variable to store descriptor pointer
* @start: byte offset of the start of the descriptors
* @count: the number of descriptors
*
* for loop macro to iterate over all of the descriptors of a given PLDM
* record.
*/
#define pldm_for_each_desc_tlv(i, desc, start, count) \
for ((i) = 0, (desc) = pldm_first_desc_tlv(start); \
(i) < (count); \
(i)++, (desc) = pldm_next_desc_tlv(desc))
/**
* pldm_first_record
* @start: byte offset of the start of the PLDM records
*
* Converts a starting offset of the PLDM records into a pointer to the first
* record.
*/
#define pldm_first_record(start) \
((const struct __pldmfw_record_info *)(start))
/**
* pldm_next_record
* @record: pointer to a PLDM record
*
* Finds a pointer to the next record following a given record
*/
#define pldm_next_record(record) \
((const struct __pldmfw_record_info *) \
((const u8 *)(record) + get_unaligned_le16(&(record)->record_len)))
/**
* pldm_for_each_record
* @i: variable to store record index
* @record: variable to store record pointer
* @start: byte offset of the start of the records
* @count: the number of records
*
* for loop macro to iterate over all of the records of a PLDM file.
*/
#define pldm_for_each_record(i, record, start, count) \
for ((i) = 0, (record) = pldm_first_record(start); \
(i) < (count); \
(i)++, (record) = pldm_next_record(record))
/**
* pldm_first_component
* @start: byte offset of the start of the PLDM components
*
* Convert a starting offset of the PLDM components into a pointer to the
* first component
*/
#define pldm_first_component(start) \
((const struct __pldmfw_component_info *)(start))
/**
* pldm_next_component
* @component: pointer to a PLDM component
*
* Finds a pointer to the next component following a given component
*/
#define pldm_next_component(component) \
((const struct __pldmfw_component_info *)((component)->version_string + \
(component)->version_len))
/**
* pldm_for_each_component
* @i: variable to store component index
* @component: variable to store component pointer
* @start: byte offset to the start of the first component
* @count: the number of components
*
* for loop macro to iterate over all of the components of a PLDM file.
*/
#define pldm_for_each_component(i, component, start, count) \
for ((i) = 0, (component) = pldm_first_component(start); \
(i) < (count); \
(i)++, (component) = pldm_next_component(component))
#endif
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