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-rw-r--r--doc/driver-model/UDM-block.txt278
-rw-r--r--doc/driver-model/UDM-cores.txt126
-rw-r--r--doc/driver-model/UDM-design.txt315
-rw-r--r--doc/driver-model/UDM-fpga.txt115
-rw-r--r--doc/driver-model/UDM-gpio.txt106
-rw-r--r--doc/driver-model/UDM-hwmon.txt118
-rw-r--r--doc/driver-model/UDM-keyboard.txt47
-rw-r--r--doc/driver-model/UDM-mmc.txt319
-rw-r--r--doc/driver-model/UDM-net.txt428
-rw-r--r--doc/driver-model/UDM-pci.txt253
-rw-r--r--doc/driver-model/UDM-pcmcia.txt78
-rw-r--r--doc/driver-model/UDM-power.txt88
-rw-r--r--doc/driver-model/UDM-rtc.txt253
-rw-r--r--doc/driver-model/UDM-serial.txt155
-rw-r--r--doc/driver-model/UDM-spi.txt200
-rw-r--r--doc/driver-model/UDM-stdio.txt191
-rw-r--r--doc/driver-model/UDM-tpm.txt48
-rw-r--r--doc/driver-model/UDM-twserial.txt47
-rw-r--r--doc/driver-model/UDM-usb.txt94
-rw-r--r--doc/driver-model/UDM-video.txt74
-rw-r--r--doc/driver-model/UDM-watchdog.txt329
21 files changed, 0 insertions, 3662 deletions
diff --git a/doc/driver-model/UDM-block.txt b/doc/driver-model/UDM-block.txt
deleted file mode 100644
index 0437d9bb9c..0000000000
--- a/doc/driver-model/UDM-block.txt
+++ /dev/null
@@ -1,278 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Block device subsystem analysis
-===============================
-
-Pavel Herrmann <morpheus.ibis@gmail.com>
-2012-03-08
-
-I) Overview
------------
-
- U-Boot currently implements several distinct APIs for block devices - some
- drivers use the SATA API, some drivers use the IDE API, sym53c8xx and
- AHCI use the SCSI API, mg_disk has a separate API, and systemace also has a
- separate API. There are also MMC and USB APIs used outside of drivers/block,
- those will be detailed in their specific documents.
-
- Block devices are described by block_dev_desc structure, that holds, among
- other things, the read/write/erase callbacks. Block device structures are
- stored in any way depending on the API, but can be accessed by
-
- block_dev_desc_t * $api_get_dev(int dev)
-
- function, as seen in disk/part.c.
-
- 1) SATA interface
- -----------------
-
- The SATA interface drivers implement the following functions:
-
- int init_sata(int dev)
- int scan_sata(int dev)
- ulong sata_read(int dev, ulong blknr, ulong blkcnt, void *buffer)
- ulong sata_write(int dev, ulong blknr, ulong blkcnt, const void *buffer)
-
- Block devices are kept in sata_dev_desc[], which is prefilled with values
- common to all SATA devices in cmd_sata.c, and then modified in init_sata
- function in the drivers. Callbacks of the block device use SATA API
- directly. The sata_get_dev function is defined in cmd_sata.c.
-
- 2) SCSI interface
- -----------------
-
- The SCSI interface drivers implement the following functions:
-
- void scsi_print_error(ccb *pccb)
- int scsi_exec(ccb *pccb)
- void scsi_bus_reset(void)
- void scsi_low_level_init(int busdevfunc)
-
- The SCSI API works through the scsi_exec function, the actual operation
- requested is found in the ccb structure.
-
- Block devices are kept in scsi_dev_desc[], which lives only in cmd_scsi.c.
- Callbacks of the block device use functions from cmd_scsi.c, which in turn
- call scsi_exec of the controller. The scsi_get_dev function is also defined
- in cmd_scsi.c.
-
- 3) mg_disk interface
- --------------------
-
- The mg_disk interface drivers implement the following functions:
-
- struct mg_drv_data* mg_get_drv_data (void)
- uint mg_disk_init (void)
- uint mg_disk_read (u32 addr, u8 *buff, u32 len)
- uint mg_disk_write(u32 addr, u8 *buff, u32 len)
- uint mg_disk_write_sects(void *buff, u32 sect_num, u32 sect_cnt)
- uint mg_disk_read_sects(void *buff, u32 sect_num, u32 sect_cnt)
-
- The mg_get_drv_data function is to be overridden per-board, but there are no
- board in-tree that do this.
-
- Only one driver for this API exists, and it only supports one block device.
- Callbacks for this device are implemented in mg_disk.c and call the mg_disk
- API. The mg_disk_get_dev function is defined in mg_disk.c and ignores the
- device number, always returning the same device.
-
- 4) systemace interface
- ----------------------
-
- The systemace interface does not define any driver API, and has no command
- itself. The single defined function is systemace_get_devs() from
- systemace.c, which returns a single static structure for the only supported
- block device. Callbacks for this device are also implemented in systemace.c.
-
- 5) IDE interface
- ----------------
-
- The IDE interface drivers implement the following functions, but only if
- CONFIG_IDE_AHB is set:
-
- uchar ide_read_register(int dev, unsigned int port);
- void ide_write_register(int dev, unsigned int port, unsigned char val);
- void ide_read_data(int dev, ulong *sect_buf, int words);
- void ide_write_data(int dev, const ulong *sect_buf, int words);
-
- The first two functions are called from ide_inb()/ide_outb(), and will
- default to direct memory access if CONFIG_IDE_AHB is not set, or
- ide_inb()/ide_outb() functions will get overridden by the board altogether.
-
- The second two functions are called from input_data()/output_data()
- functions, and also default to direct memory access, but cannot be
- overridden by the board.
-
- One function shared by IDE drivers (but not defined in ide.h) is
- int ide_preinit(void)
- This function gets called from ide_init in cmd_ide.c if CONFIG_IDE_PREINIT
- is defined, and will do the driver-specific initialization of the device.
-
- Block devices are kept in ide_dev_desc[], which is filled in cmd_ide.c.
- Callbacks of the block device are defined in cmd_ide.c, and use the
- ide_inb()/ide_outb()/input_data()/output_data() functions mentioned above.
- The ide_get_dev function is defined in cmd_ide.c.
-
-II) Approach
-------------
-
- A new block controller core and an associated API will be created to mimic the
- current SATA API, its drivers will have the following ops:
-
- struct block_ctrl_ops {
- int scan(instance *i);
- int reset(instance *i, int port);
- lbaint_t read(instance *i, int port, lbaint_t start, lbatin_t length,
- void *buffer);
- lbaint_t write(instance *i, int port, lbaint_t start, lbatin_t length,
- void*buffer);
- }
-
- The current sata_init() function will be changed into the driver probe()
- function. The read() and write() functions should never be called directly,
- instead they should be called by block device driver for disks.
-
- Other block APIs would either be transformed into this API, or be kept as
- legacy for old drivers, or be dropped altogether.
-
- Legacy driver APIs will each have its own driver core that will contain the
- shared logic, which is currently located mostly in cmd_* files. Callbacks for
- block device drivers will then probably be implemented as a part of the core
- logic, and will use the driver ops (which will copy current state of
- respective APIs) to do the work.
-
- All drivers will be cleaned up, most ifdefs should be converted into
- platform_data, to enable support for multiple devices with different settings.
-
- A new block device core will also be created, and will keep track of all
- block devices on all interfaces.
-
- Current block_dev_desc structure will be changed to fit the driver model, all
- identification and configuration will be placed in private data, and
- a single accessor and modifier will be defined, to accommodate the need for
- different sets of options for different interfaces, while keeping the
- structure small. The new block device drivers will have the following ops
- structure (lbaint_t is either 32bit or 64bit unsigned, depending on
- CONFIG_LBA48):
-
- struct blockdev_ops {
- lbaint_t (*block_read)(struct instance *i, lbaint_t start, lbaint_t blkcnt,
- void *buffer);
- lbaint_t (*block_write)(struct instance *i, lbaint_t start, lbaint_t blkcnt,
- void *buffer);
- lbaint_t (*block_erase)(struct instance *i, lbaint_t start, lbaint_t blkcnt
- );
- int (*get_option)(struct instance *i, enum blockdev_option_code op,
- struct option *res);
- int (*set_option)(struct instance *i, enum blockdev_option_code op,
- struct option *val);
- }
-
- struct option {
- uint32_t flags
- union data {
- uint64_t data_u;
- char* data_s;
- void* data_p;
- }
- }
-
- enum blockdev_option_code {
- BLKD_OPT_IFTYPE=0,
- BLKD_OPT_TYPE,
- BLKD_OPT_BLOCKSIZE,
- BLKD_OPT_BLOCKCOUNT,
- BLKD_OPT_REMOVABLE,
- BLKD_OPT_LBA48,
- BLKD_OPT_VENDOR,
- BLKD_OPT_PRODICT,
- BLKD_OPT_REVISION,
- BLKD_OPT_SCSILUN,
- BLKD_OPT_SCSITARGET,
- BLKD_OPT_OFFSET
- }
-
- Flags in option above will contain the type of returned data (which should be
- checked against what is expected, even though the option requested should
- specify it), and a flag to indicate whether the returned pointer needs to be
- free()'d.
-
- The block device core will contain the logic now located in disk/part.c and
- related files, and will be used to forward requests to block devices. The API
- for the block device core will copy the ops of a block device (with a string
- identifier instead of instance pointer). This means that partitions will also
- be handled by the block device core, and exported as block devices, making
- them transparent to the rest of the code.
-
- Sadly, this will change how file systems can access the devices, and thus will
- affect a lot of places. However, these changes should be localized and easy to
- implement.
-
- AHCI driver will be rewritten to fit the new unified block controller API,
- making SCSI API easy to merge with sym53c8xx, or remove it once the device
- driver has died.
-
- Optionally, IDE core may be changed into one driver with unified block
- controller API, as most of it is already in one place and device drivers are
- just sets of hooks. Additionally, mg_disk driver is unused and may be removed
- in near future.
-
-
-III) Analysis of in-tree drivers
---------------------------------
-
- ahci.c
- ------
- SCSI API, will be rewritten for a different API.
-
- ata_piix.c
- ----------
- SATA API, easy to port.
-
- fsl_sata.c
- ----------
- SATA API, few CONFIG macros, easy to port.
-
- ftide020.c
- ----------
- IDE API, defines CONFIG_IDE_AHB and ide_preinit hook functions.
-
- mg_disk.c
- ---------
- Single driver with mg_disk API, not much to change, easy to port.
-
- mvsata_ide.c
- ------------
- IDE API, only defines ide_preinit hook function.
-
- mxc_ata.c
- ---------
- IDE API, only defines ide_preinit hook function.
-
- pata_bfin.c
- -----------
- SATA API, easy to port.
-
- sata_dwc.c
- ----------
- SATA API, easy to port.
-
- sata_sil3114.c
- --------------
- SATA API, easy to port.
-
- sata_sil.c
- ----------
- SATA API, easy to port.
-
- sil680.c
- --------
- IDE API, only defines ide_preinit hook function.
-
- sym53c8xx.c
- -----------
- SCSI API, may be merged with code from cmd_scsi.
-
- systemace.c
- -----------
- Single driver with systemace API, not much to change, easy to port.
diff --git a/doc/driver-model/UDM-cores.txt b/doc/driver-model/UDM-cores.txt
deleted file mode 100644
index 60323335b8..0000000000
--- a/doc/driver-model/UDM-cores.txt
+++ /dev/null
@@ -1,126 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Driver cores API document
-=========================
-
-Pavel Herrmann <morpheus.ibis@gmail.com>
-
-1) Overview
------------
- Driver cores will be used as a wrapper for devices of the same type, and as
- an abstraction for device driver APIs. For each driver API (which roughly
- correspond to device types), there will be one driver core. Each driver core
- will implement three APIs - a driver API (which will be the same as API of
- drivers the core wraps around), a core API (which will be implemented by all
- cores) and a command API (core-specific API which will be exposed to
- commands).
-
- A) Command API
- The command API will provide access to shared functionality for a specific
- device, which is currently located mostly in commands. Commands will be
- rewritten to be more lightweight by using this API. As this API will be
- different for each core, it is out of scope of this document.
-
- B) Driver API
- The driver API will act as a wrapper around actual device drivers,
- providing a single entrypoint for device access. All functions in this API
- have an instance* argument (probably called "this" or "i"), which will be
- examined by the core, and a correct function for the specified driver will
- get called.
-
- If the core gets called with a group instance pointer (as discussed in
- design), it will automatically select the instance that is associated
- with this core, and use it as target of the call. if the group contains
- multiple instances of a single type, the caller must explicitly use an
- accessor to select the correct instance.
-
- This accessor will look like:
- struct instance *get_instance_from_group(struct instance *group, int i)
-
- When called with a non-group instance, it will simply return the instance.
-
- C) Core API
- The core API will be implemented by all cores, and will provide
- functionality for getting driver instances from non-driver code. This API
- will consist of following functions:
-
- int get_count(struct instance *core);
- struct instance* get_instance(struct instance *core, int index);
- int init(struct instance *core);
- int bind(struct instance *core, struct instance *dev, void *ops,
- void *hint);
- int unbind(struct instance *core, instance *dev);
- int replace(struct instance *core, struct_instance *new_dev,
- struct instance *old_dev);
- int destroy(struct instance *core);
- int reloc(struct instance *new_core, struct instance *old_core);
-
- The 'hint' parameter of bind() serves for additional data a driver can
- pass to the core, to help it create the correct internal state for this
- instance. the replace() function will get called during instance
- relocation, and will replace the old instance with the new one, keeping
- the internal state untouched.
-
-
-2) Lifetime of a driver core
-----------------------------
- Driver cores will be initialized at runtime, to limit memory footprint in
- early-init stage, when we have to fit into ~1KB of memory. All active cores
- will be stored in a tree structure (referenced as "Core tree") in global data,
- which provides good tradeoff between size and access time.
- Every core will have a number constant associated with it, which will be used
- to find the instance in Core tree, and to refer to the core in all calls
- working with the Core tree.
- The Core Tree should be implemented using B-tree (or a similar structure)
- to guarantee acceptable time overhead in all cases.
-
- Code for working with the core (i2c in this example) follows:
-
- core_init(CORE_I2C);
- This will check whether we already have a i2c core, and if not it creates
- a new instance and adds it into the Core tree. This will not be exported,
- all code should depend on get_core_instance to init the core when
- necessary.
-
- get_core_instance(CORE_I2C);
- This is an accessor into the Core tree, which will return the instance
- of i2c core, creating it if necessary
-
- core_bind(CORE_I2C, instance, driver_ops);
- This will get called in bind() function of a driver, and will add the
- instance into cores internal list of devices. If the core is not found, it
- will get created.
-
- driver_activate(instance *inst);
- This call will recursively activate all devices necessary for using the
- specified device. the code could be simplified as:
- {
- if (is_activated(inst))
- return;
- driver_activate(inst->bus);
- get_driver(inst)->probe(inst);
- }
-
- The case with multiple parents will need to be handled here as well.
- get_driver is an accessor to available drivers, which will get struct
- driver based on a name in the instance.
-
- i2c_write(instance *inst, ...);
- An actual call to some method of the driver. This code will look like:
- {
- driver_activate(inst);
- struct instance *core = get_core_instance(CORE_I2C);
- device_ops = get_ops(inst);
- device_ops->write(...);
- }
-
- get_ops will not be an exported function, it will be internal and specific
- to the core, as it needs to know how are the ops stored, and what type
- they are.
-
- Please note that above examples represent the algorithm, not the actual code,
- as they are missing checks for validity of return values.
-
- core_init() function will get called the first time the core is requested,
- either by core_link() or core_get_instance(). This way, the cores will get
- created only when they are necessary, which will reduce our memory footprint.
diff --git a/doc/driver-model/UDM-design.txt b/doc/driver-model/UDM-design.txt
deleted file mode 100644
index 9f03bbaad3..0000000000
--- a/doc/driver-model/UDM-design.txt
+++ /dev/null
@@ -1,315 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Design document
-===============
-Marek Vasut <marek.vasut@gmail.com>
-Pavel Herrmann <morpheus.ibis@gmail.com>
-2012-05-17
-
-I) The modular concept
-----------------------
-
-The driver core design is done with modularity in mind. The long-term plan is to
-extend this modularity to allow loading not only drivers, but various other
-objects into U-Boot at runtime -- like commands, support for other boards etc.
-
-II) Driver core initialization stages
--------------------------------------
-
-The drivers have to be initialized in two stages, since the U-Boot bootloader
-runs in two stages itself. The first stage is the one which is executed before
-the bootloader itself is relocated. The second stage then happens after
-relocation.
-
- 1) First stage
- --------------
-
- The first stage runs after the bootloader did very basic hardware init. This
- means the stack pointer was configured, caches disabled and that's about it.
- The problem with this part is the memory management isn't running at all. To
- make things even worse, at this point, the RAM is still likely uninitialized
- and therefore unavailable.
-
- 2) Second stage
- ---------------
-
- At this stage, the bootloader has initialized RAM and is running from it's
- final location. Dynamic memory allocations are working at this point. Most of
- the driver initialization is executed here.
-
-III) The drivers
-----------------
-
- 1) The structure of a driver
- ----------------------------
-
- The driver will contain a structure located in a separate section, which
- will allow linker to create a list of compiled-in drivers at compile time.
- Let's call this list "driver_list".
-
- struct driver __attribute__((section(driver_list))) {
- /* The name of the driver */
- char name[STATIC_CONFIG_DRIVER_NAME_LENGTH];
-
- /*
- * This function should connect this driver with cores it depends on and
- * with other drivers, likely bus drivers
- */
- int (*bind)(struct instance *i);
-
- /* This function actually initializes the hardware. */
- int (*probe)(struct instance *i);
-
- /*
- * The function of the driver called when U-Boot finished relocation.
- * This is particularly important to eg. move pointers to DMA buffers
- * and such from the location before relocation to their final location.
- */
- int (*reloc)(struct instance *i);
-
- /*
- * This is called when the driver is shuting down, to deinitialize the
- * hardware.
- */
- int (*remove)(struct instance *i);
-
- /* This is called to remove the driver from the driver tree */
- int (*unbind)(struct instance *i);
-
- /* This is a list of cores this driver depends on */
- struct driver *cores[];
- };
-
- The cores[] array in here is very important. It allows u-boot to figure out,
- in compile-time, which possible cores can be activated at runtime. Therefore
- if there are cores that won't be ever activated, GCC LTO might remove them
- from the final binary. Actually, this information might be used to drive build
- of the cores.
-
- FIXME: Should *cores[] be really struct driver, pointing to drivers that
- represent the cores? Shouldn't it be core instance pointer?
-
- 2) Instantiation of a driver
- ----------------------------
-
- The driver is instantiated by calling:
-
- driver_bind(struct instance *bus, const struct driver_info *di)
-
- The "struct instance *bus" is a pointer to a bus with which this driver should
- be registered with. The "root" bus pointer is supplied to the board init
- functions.
-
- FIXME: We need some functions that will return list of busses of certain type
- registered with the system so the user can find proper instance even if
- he has no bus pointer (this will come handy if the user isn't
- registering the driver from board init function, but somewhere else).
-
- The "const struct driver_info *di" pointer points to a structure defining the
- driver to be registered. The structure is defined as follows:
-
- struct driver_info {
- char name[STATIC_CONFIG_DRIVER_NAME_LENGTH];
- void *platform_data;
- }
-
- The instantiation of a driver by calling driver_bind() creates an instance
- of the driver by allocating "struct driver_instance". Note that only struct
- instance is passed to the driver. The wrapping struct driver_instance is there
- for purposes of the driver core:
-
- struct driver_instance {
- uint32_t flags;
- struct instance i;
- };
-
- struct instance {
- /* Pointer to a driver information passed by driver_register() */
- const struct driver_info *info;
- /* Pointer to a bus this driver is bound with */
- struct instance *bus;
- /* Pointer to this driver's own private data */
- void *private_data;
- /* Pointer to the first block of successor nodes (optional) */
- struct successor_block *succ;
- }
-
- The instantiation of a driver does not mean the hardware is initialized. The
- driver_bind() call only creates the instance of the driver, fills in the "bus"
- pointer and calls the drivers' .bind() function. The .bind() function of the
- driver should hook the driver with the remaining cores and/or drivers it
- depends on.
-
- It's important to note here, that in case the driver instance has multiple
- parents, such parent can be connected with this instance by calling:
-
- driver_link(struct instance *parent, struct instance *dev);
-
- This will connect the other parent driver with the newly instantiated driver.
- Note that this must be called after driver_bind() and before driver_acticate()
- (driver_activate() will be explained below). To allow struct instance to have
- multiple parent pointer, the struct instance *bus will utilize it's last bit
- to indicate if this is a pointer to struct instance or to an array if
- instances, struct successor block. The approach is similar as the approach to
- *succ in struct instance, described in the following paragraph.
-
- The last pointer of the struct instance, the pointer to successor nodes, is
- used only in case of a bus driver. Otherwise the pointer contains NULL value.
- The last bit of this field indicates if this is a bus having a single child
- node (so the last bit is 0) or if this bus has multiple child nodes (the last
- bit is 1). In the former case, the driver core should clear the last bit and
- this pointer points directly to the child node. In the later case of a bus
- driver, the pointer points to an instance of structure:
-
- struct successor_block {
- /* Array of pointers to instances of devices attached to this bus */
- struct instance *dev[BLOCKING_FACTOR];
- /* Pointer to next block of successors */
- struct successor_block *next;
- }
-
- Some of the *dev[] array members might be NULL in case there are no more
- devices attached. The *next is NULL in case the list of attached devices
- doesn't continue anymore. The BLOCKING_FACTOR is used to allocate multiple
- slots for successor devices at once to avoid fragmentation of memory.
-
- 3) The bind() function of a driver
- ----------------------------------
-
- The bind function of a driver connects the driver with various cores the
- driver provides functions for. The driver model related part will look like
- the following example for a bus driver:
-
- int driver_bind(struct instance *in)
- {
- ...
- core_bind(&core_i2c_static_instance, in, i2c_bus_funcs);
- ...
- }
-
- FIXME: What if we need to run-time determine, depending on some hardware
- register, what kind of i2c_bus_funcs to pass?
-
- This makes the i2c core aware of a new bus. The i2c_bus_funcs is a constant
- structure of functions any i2c bus driver must provide to work. This will
- allow the i2c command operate with the bus. The core_i2c_static_instance is
- the pointer to the instance of a core this driver provides function to.
-
- FIXME: Maybe replace "core-i2c" with CORE_I2C global pointer to an instance of
- the core?
-
- 4) The instantiation of a core driver
- -------------------------------------
-
- The core driver is special in the way that it's single-instance driver. It is
- always present in the system, though it might not be activated. The fact that
- it's single instance allows it to be instantiated at compile time.
-
- Therefore, all possible structures of this driver can be in read-only memory,
- especially struct driver and struct driver_instance. But the successor list,
- which needs special treatment.
-
- To solve the problem with a successor list and the core driver flags, a new
- entry in struct gd (global data) will be introduced. This entry will point to
- runtime allocated array of struct driver_instance. It will be possible to
- allocate the exact amount of struct driver_instance necessary, as the number
- of cores that might be activated will be known at compile time. The cores will
- then behave like any usual driver.
-
- Pointers to the struct instance of cores can be computed at compile time,
- therefore allowing the resulting u-boot binary to save some overhead.
-
- 5) The probe() function of a driver
- -----------------------------------
-
- The probe function of a driver allocates necessary resources and does required
- initialization of the hardware itself. This is usually called only when the
- driver is needed, as a part of the defered probe mechanism.
-
- The driver core should implement a function called
-
- int driver_activate(struct instance *in);
-
- which should call the .probe() function of the driver and then configure the
- state of the driver instance to "ACTIVATED". This state of a driver instance
- should be stored in a wrap-around structure for the structure instance, the
- struct driver_instance.
-
- 6) The command side interface to a driver
- -----------------------------------------
-
- The U-Boot command shall communicate only with the specific driver core. The
- driver core in turn exports necessary API towards the command.
-
- 7) Demonstration imaginary board
- --------------------------------
-
- Consider the following computer:
-
- *
- |
- +-- System power management logic
- |
- +-- CPU clock controlling logc
- |
- +-- NAND controller
- | |
- | +-- NAND flash chip
- |
- +-- 128MB of DDR DRAM
- |
- +-- I2C bus #0
- | |
- | +-- RTC
- | |
- | +-- EEPROM #0
- | |
- | +-- EEPROM #1
- |
- +-- USB host-only IP core
- | |
- | +-- USB storage device
- |
- +-- USB OTG-capable IP core
- | |
- | +-- connection to the host PC
- |
- +-- GPIO
- | |
- | +-- User LED #0
- | |
- | +-- User LED #1
- |
- +-- UART0
- |
- +-- UART1
- |
- +-- Ethernet controller #0
- |
- +-- Ethernet controller #1
- |
- +-- Audio codec
- |
- +-- PCI bridge
- | |
- | +-- Ethernet controller #2
- | |
- | +-- SPI host card
- | | |
- | | +-- Audio amplifier (must be operational before codec)
- | |
- | +-- GPIO host card
- | |
- | +-- User LED #2
- |
- +-- LCD controller
- |
- +-- PWM controller (must be enabled after LCD controller)
- |
- +-- SPI host controller
- | |
- | +-- SD/MMC connected via SPI
- | |
- | +-- SPI flash
- |
- +-- CPLD/FPGA with stored configuration of the board
diff --git a/doc/driver-model/UDM-fpga.txt b/doc/driver-model/UDM-fpga.txt
deleted file mode 100644
index 4f9df940ed..0000000000
--- a/doc/driver-model/UDM-fpga.txt
+++ /dev/null
@@ -1,115 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-I/O system analysis
-===================
-Marek Vasut <marek.vasut@gmail.com>
-2012-02-21
-
-I) Overview
------------
-
-The current FPGA implementation is handled by command "fpga". This command in
-turn calls the following functions:
-
-fpga_info()
-fpga_load()
-fpga_dump()
-
-These functions are implemented by what appears to be FPGA multiplexer, located
-in drivers/fpga/fpga.c . This code determines which device to operate with
-depending on the device ID.
-
-The fpga_info() function is multiplexer of the functions providing information
-about the particular FPGA device. These functions are implemented in the drivers
-for the particular FPGA device:
-
-xilinx_info()
-altera_info()
-lattice_info()
-
-Similar approach is used for fpga_load(), which multiplexes "xilinx_load()",
-"altera_load()" and "lattice_load()" and is used to load firmware into the FPGA
-device.
-
-The fpga_dump() function, which prints the contents of the FPGA device, is no
-different either, by multiplexing "xilinx_dump()", "altera_dump()" and
-"lattice_dump()" functions.
-
-Finally, each new FPGA device is registered by calling "fpga_add()" function.
-This function takes two arguments, the second one being particularly important,
-because it's basically what will become platform_data. Currently, it's data that
-are passed to the driver from the board/platform code.
-
-II) Approach
-------------
-
-The path to conversion of the FPGA subsystem will be very straightforward, since
-the FPGA subsystem is already quite dynamic. Multiple things will need to be
-modified though.
-
-First is the registration of the new FPGA device towards the FPGA core. This
-will be achieved by calling:
-
- fpga_device_register(struct instance *i, const struct fpga_ops *ops);
-
-The particularly interesting part is the struct fpga_ops, which contains
-operations supported by the FPGA device. These are basically the already used
-calls in the current implementation:
-
-struct fpga_ops {
- int info(struct instance *i);
- int load(struct instance *i, const char *buf, size_t size);
- int dump(struct instance *i, const char *buf, size_t size);
-}
-
-The other piece that'll have to be modified is how the devices are tracked.
-It'll be necessary to introduce a linked list of devices within the FPGA core
-instead of tracking them by ID number.
-
-Next, the "Xilinx_desc", "Lattice_desc" and "Altera_desc" structures will have
-to be moved to driver's private_data. Finally, structures passed from the board
-and/or platform files, like "Xilinx_Virtex2_Slave_SelectMap_fns" would be passed
-via platform_data to the driver.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- 1) Altera driver
- ----------------
- The driver is realized using the following files:
-
- drivers/fpga/altera.c
- drivers/fpga/ACEX1K.c
- drivers/fpga/cyclon2.c
- drivers/fpga/stratixII.c
-
- All of the sub-drivers implement basically the same info-load-dump interface
- and there's no expected problem during the conversion. The driver itself will
- be realised by altera.c and all the sub-drivers will be linked in. The
- distinction will be done by passing different platform data.
-
- 2) Lattice driver
- -----------------
- The driver is realized using the following files:
-
- drivers/fpga/lattice.c
- drivers/fpga/ivm_core.c
-
- This driver also implements the standard interface, but to realise the
- operations with the FPGA device, uses functions from "ivm_core.c" file. This
- file implements the main communications logic and has to be linked in together
- with "lattice.c". No problem converting is expected here.
-
- 3) Xilinx driver
- ----------------
- The driver is realized using the following files:
-
- drivers/fpga/xilinx.c
- drivers/fpga/spartan2.c
- drivers/fpga/spartan3.c
- drivers/fpga/virtex2.c
-
- This set of sub-drivers is special by defining a big set of macros in
- "include/spartan3.h" and similar files. These macros would need to be either
- rewritten or replaced. Otherwise, there are no problems expected during the
- conversion process.
diff --git a/doc/driver-model/UDM-gpio.txt b/doc/driver-model/UDM-gpio.txt
deleted file mode 100644
index 585d45868c..0000000000
--- a/doc/driver-model/UDM-gpio.txt
+++ /dev/null
@@ -1,106 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-GPIO analysis
-=============
-Viktor Krivak <viktor.krivak@gmail.com>
-2012-02-24
-
-I) Overview
------------
-
- At this moment U-Boot provides standard API that consists of 7 functions.
-
- int gpio_request(unsigned gpio, const char *label)
- int gpio_free(unsigned gpio)
- int gpio_direction_input(unsigned gpio)
- int gpio_direction_output(unsigned gpio, int value)
- int gpio_get_value(unsigned gpio)
- void gpio_set_value(unsigned gpio, int value)
-
- Methods "gpio_request()" and "gpio_free()" are used for claiming and releasing
- GPIOs. First one should check if the desired pin exists and if the pin wasn't
- requested already elsewhere. The method also has a label argument that can be
- used for debug purposes. The label argument should be copied into the internal
- memory, but only if the DEBUG macro is set. The "gpio_free()" is the exact
- opposite. It releases the particular pin. Other methods are used for setting
- input or output direction and obtaining or setting values of the pins.
-
-II) Approach
-------------
-
- 1) Request and free GPIO
- ------------------------
-
- The "gpio_request()" implementation is basically the same for all boards.
- The function checks if the particular GPIO is correct and checks if the
- GPIO pin is still free. If the conditions are met, the method marks the
- GPIO claimed in it's internal structure. If macro DEBUG is defined, the
- function also copies the label argument to the structure. If the pin is
- already locked, the function returns -1 and if DEBUG is defined, certain
- debug output is generated, including the contents of the label argument.
- The "gpio_free()" function releases the lock and eventually deallocates
- data used by the copied label argument.
-
- 2) Internal data
- ----------------
-
- Internal data are driver specific. They have to contain some mechanism to
- realise the locking though. This can be done for example using a bit field.
-
- 3) Operations provided by the driver
- ------------------------------------
-
- The driver operations basically meet API that is already defined and used.
- Except for "gpio_request()" and "gpio_free()", all methods can be converted in
- a simple manner. The driver provides the following structure:
-
- struct gpio_driver_ops {
- int (*gpio_request)(struct instance *i, unsigned gpio,
- const char *label);
- int (*gpio_free)(struct instance *i, unsigned gpio);
- int (*gpio_direction_input)(struct instance *i, unsigned gpio);
- int (*gpio_direction_output)(struct instance *i, unsigned gpio,
- int value);
- int (*gpio_get_value)(struct instance *i, unsigned gpio);
- void (*gpio_set_value)(struct instance *i, unsigned gpio, int value);
- }
-
-III) Analysis of in-tree drivers
---------------------------------
-
- altera_pio.c
- ------------
- Meets standard API. Implements gpio_request() properly. Simple conversion
- possible.
-
- at91_gpio.c
- -----------
- Don't meet standard API. Need some other methods to implement.
-
- da8xx_gpio.c
- ------------
- Meets standard API. Implements gpio_request() properly. Simple conversion
- possible.
-
- kw_gpio.c
- ---------
- Doesn't meet standard API. Needs some other methods to implement and move some
- methods to another file.
-
- mpc83xx_gpio.c
- --------------
- Meets standard API. Doesn't implement gpio_request() properly (only checks
- if the pin is valid). Simple conversion possible.
-
- mvgpio.c
- --------
- Meets standard API. Doesn't implement gpio_request() properly (only checks
- if the pin is valid). Simple conversion possible.
-
- mvgpio.h
- --------
- Wrong placement. Will be moved to another location.
-
- mvmfp.c
- -------
- Wrong placement. Will be moved to another location.
diff --git a/doc/driver-model/UDM-hwmon.txt b/doc/driver-model/UDM-hwmon.txt
deleted file mode 100644
index 03a96a057a..0000000000
--- a/doc/driver-model/UDM-hwmon.txt
+++ /dev/null
@@ -1,118 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Hwmon device subsystem analysis
-===============================
-
-Tomas Hlavacek <tmshlvck@gmail.com>
-2012-03-02
-
-I) Overview
------------
-
-U-Boot currently implements one API for HW monitoring devices. The
-interface is defined in include/dtt.h and comprises of functions:
-
- void dtt_init(void);
- int dtt_init_one(int);
- int dtt_read(int sensor, int reg);
- int dtt_write(int sensor, int reg, int val);
- int dtt_get_temp(int sensor);
-
-The functions are implemented by a proper device driver in drivers/hwmon
-directory and the driver to be compiled in is selected in a Makefile.
-Drivers are mutually exclusive.
-
-Drivers depends on I2O code and naturally on board specific data. There are
-few ad-hoc constants put in dtt.h file and driver headers and code. This
-has to be consolidated into board specific data or driver headers if those
-constants makes sense globally.
-
-
-II) Approach
-------------
-
- 1) New API
- ----------
- In the UDM each hwmon driver would register itself by a function
-
- int hwmon_device_register(struct instance *i,
- struct hwmon_device_ops *o);
-
- The structure being defined as follows:
-
- struct hwmon_device_ops {
- int (*read)(struct instance *i, int sensor, int reg);
- int (*write)(struct instance *i, int sensor, int reg,
- int val);
- int (*get_temp)(struct instance *i, int sensor);
- };
-
-
- 2) Conversion thougths
- ----------------------
- U-Boot hwmon drivers exports virtually the same functions (with exceptions)
- and we are considering low number of drivers and code anyway. The interface
- is already similar and unified by the interface defined in dtt.h.
- Current initialization functions dtt_init() and dtt_init_one() will be
- converted into probe() and hwmon_device_register(), so the funcionality will
- be kept in more proper places. Besides implementing core registration and
- initialization we need to do code cleanup, especially separate
- driver-specific and HW specific constants.
-
- 3) Special consideration due to early initialization
- ----------------------------------------------------
- The dtt_init() function call is used during early initialization in
- board/gdsys/405ex/io64.c for starting up fans. The dtt code is perfectly
- usable in the early stage because it uses only local variables and no heap
- memory is required at this level. However the underlying code of I2C has to
- keep the same properties with regard to possibility of running in early
- initialization stage.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- drivers/hwmon/lm81.c
- --------------------
- The driver is standard dtt. Simple conversion is possible.
-
-
- drivers/hwmon/ds1722.c
- ----------------------
- The driver is not standard dtt, but interface is similar to dtt.
- The interface has to be changed in order to comply to above mentioned
- specification.
-
-
- drivers/hwmon/ds1775.c
- ----------------------
- The driver is standard dtt. Simple conversion is possible.
-
-
- drivers/hwmon/lm73.c
- --------------------
- The driver is standard dtt. Simple conversion is possible.
-
-
- drivers/hwmon/lm63.c
- --------------------
- The driver is standard dtt. Simple conversion is possible.
-
-
- drivers/hwmon/adt7460.c
- -----------------------
- The driver is standard dtt. Simple conversion is possible.
-
-
- drivers/hwmon/lm75.c
- --------------------
- The driver is standard dtt. Simple conversion is possible.
-
-
- drivers/hwmon/ds1621.c
- ----------------------
- The driver is standard dtt. Simple conversion is possible.
-
-
- drivers/hwmon/adm1021.c
- -----------------------
- The driver is standard dtt. Simple conversion is possible.
diff --git a/doc/driver-model/UDM-keyboard.txt b/doc/driver-model/UDM-keyboard.txt
deleted file mode 100644
index 5babfc55f1..0000000000
--- a/doc/driver-model/UDM-keyboard.txt
+++ /dev/null
@@ -1,47 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Keyboard input analysis
-=======================
-Marek Vasut <marek.vasut@gmail.com>
-2012-02-20
-
-I) Overview
------------
-
-The keyboard drivers are most often registered with STDIO subsystem. There are
-components of the keyboard drivers though, which operate in severe ad-hoc
-manner, often being related to interrupt-driven keypress reception. This
-components will require the most sanitization of all parts of keyboard input
-subsystem.
-
-Otherwise, the keyboard is no different from other standard input but with the
-necessity to decode scancodes. These are decoded using tables provided by
-keyboard drivers. These tables are often driver specific.
-
-II) Approach
-------------
-
-The most problematic part is the interrupt driven keypress reception. For this,
-the buffers that are currently shared throughout the whole U-Boot would need to
-be converted into driver's private data.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- board/mpl/common/kbd.c
- ----------------------
- This driver is a classic STDIO driver, no problem with conversion is expected.
- Only necessary change will be to move this driver to a proper location.
-
- board/rbc823/kbd.c
- ------------------
- This driver is a classic STDIO driver, no problem with conversion is expected.
- Only necessary change will be to move this driver to a proper location.
-
- drivers/input/keyboard.c
- ------------------------
- This driver is special in many ways. Firstly because this is a universal stub
- driver for converting scancodes from i8042 and the likes. Secondly because the
- buffer is filled by various other ad-hoc implementations of keyboard input by
- using this buffer as an extern. This will need to be fixed by allowing drivers
- to pass certain routines to this driver via platform data.
diff --git a/doc/driver-model/UDM-mmc.txt b/doc/driver-model/UDM-mmc.txt
deleted file mode 100644
index 97f83a7776..0000000000
--- a/doc/driver-model/UDM-mmc.txt
+++ /dev/null
@@ -1,319 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-MMC system analysis
-===================
-Marek Vasut <marek.vasut@gmail.com>
-2012-02-25
-
-I) Overview
------------
-
-The MMC subsystem is already quite dynamic in it's nature. It's only necessary
-to flip the subsystem to properly defined API.
-
-The probing process of MMC drivers start by calling "mmc_initialize()",
-implemented by MMC framework, from the architecture initialization file. The
-"mmc_initialize()" function in turn calls "board_mmc_init()" function and if
-this doesn't succeed, "cpu_mmc_init()" function is called. It is important to
-note that both of the "*_mmc_init()" functions have weak aliases to functions
-which automatically fail.
-
-Both of the "*_mmc_init()" functions though serve only one purpose. To call
-driver specific probe function, which in turn actually registers the driver with
-MMC subsystem. Each of the driver specific probe functions is currently done in
-very ad-hoc manner.
-
-The registration with the MMC subsystem is done by calling "mmc_register()",
-whose argument is a runtime configured structure of information about the MMC
-driver. Currently, the information structure is intermixed with driver's internal
-data. The description of the structure follows:
-
-struct mmc {
- /*
- * API: Allows this driver to be a member of the linked list of all MMC drivers
- * registered with MMC subsystem
- */
- struct list_head link;
-
- /* DRIVER: Name of the registered driver */
- char name[32];
-
- /* DRIVER: Driver's private data */
- void *priv;
-
- /* DRIVER: Voltages the host bus can provide */
- uint voltages;
-
- /* API: Version of the card */
- uint version;
-
- /* API: Test if the driver was already initialized */
- uint has_init;
-
- /* DRIVER: Minimum frequency the host bus can provide */
- uint f_min;
-
- /* DRIVER: Maximum frequency the host bus can provide */
- uint f_max;
-
- /* API: Is the card SDHC */
- int high_capacity;
-
- /* API: Actual width of the bus used by the current card */
- uint bus_width;
-
- /*
- * DRIVER: Clock frequency to be configured on the host bus, this is read-only
- * for the driver.
- */
- uint clock;
-
- /* API: Capabilities of the card */
- uint card_caps;
-
- /* DRIVER: MMC bus capabilities */
- uint host_caps;
-
- /* API: Configuration and ID data retrieved from the card */
- uint ocr;
- uint scr[2];
- uint csd[4];
- uint cid[4];
- ushort rca;
-
- /* API: Partition configuration */
- char part_config;
-
- /* API: Number of partitions */
- char part_num;
-
- /* API: Transmission speed */
- uint tran_speed;
-
- /* API: Read block length */
- uint read_bl_len;
-
- /* API: Write block length */
- uint write_bl_len;
-
- /* API: Erase group size */
- uint erase_grp_size;
-
- /* API: Capacity of the card */
- u64 capacity;
-
- /* API: Descriptor of this block device */
- block_dev_desc_t block_dev;
-
- /* DRIVER: Function used to submit command to the card */
- int (*send_cmd)(struct mmc *mmc,
- struct mmc_cmd *cmd, struct mmc_data *data);
-
- /* DRIVER: Function used to configure the host */
- void (*set_ios)(struct mmc *mmc);
-
- /* DRIVER: Function used to initialize the host */
- int (*init)(struct mmc *mmc);
-
- /* DRIVER: Function used to report the status of Card Detect pin */
- int (*getcd)(struct mmc *mmc);
-
- /*
- * DRIVER: Maximum amount of blocks sent during multiblock xfer,
- * set to 0 to autodetect.
- */
- uint b_max;
-};
-
-The API above is the new API used by most of the drivers. There're still drivers
-in the tree that use old, legacy API though.
-
-2) Approach
------------
-
-To convert the MMC subsystem to a proper driver model, the "struct mmc"
-structure will have to be properly split in the first place. The result will
-consist of multiple parts, first will be the structure defining operations
-provided by the MMC driver:
-
-struct mmc_driver_ops {
- /* Function used to submit command to the card */
- int (*send_cmd)(struct mmc *mmc,
- struct mmc_cmd *cmd, struct mmc_data *data);
- /* DRIVER: Function used to configure the host */
- void (*set_ios)(struct mmc *mmc);
- /* Function used to initialize the host */
- int (*init)(struct mmc *mmc);
- /* Function used to report the status of Card Detect pin */
- int (*getcd)(struct mmc *mmc);
-}
-
-The second part will define the parameters of the MMC driver:
-
-struct mmc_driver_params {
- /* Voltages the host bus can provide */
- uint32_t voltages;
- /* Minimum frequency the host bus can provide */
- uint32_t f_min;
- /* Maximum frequency the host bus can provide */
- uint32_t f_max;
- /* MMC bus capabilities */
- uint32_t host_caps;
- /*
- * Maximum amount of blocks sent during multiblock xfer,
- * set to 0 to autodetect.
- */
- uint32_t b_max;
-}
-
-And finally, the internal per-card data of the MMC subsystem core:
-
-struct mmc_card_props {
- /* Version of the card */
- uint32_t version;
- /* Test if the driver was already initializes */
- bool has_init;
- /* Is the card SDHC */
- bool high_capacity;
- /* Actual width of the bus used by the current card */
- uint8_t bus_width;
- /* Capabilities of the card */
- uint32_t card_caps;
- /* Configuration and ID data retrieved from the card */
- uint32_t ocr;
- uint32_t scr[2];
- uint32_t csd[4];
- uint32_t cid[4];
- uint16_t rca;
- /* Partition configuration */
- uint8_t part_config;
- /* Number of partitions */
- uint8_t part_num;
- /* Transmission speed */
- uint32_t tran_speed;
- /* Read block length */
- uint32_t read_bl_len;
- /* Write block length */
- uint32_t write_bl_len;
- /* Erase group size */
- uint32_t erase_grp_size;
- /* Capacity of the card */
- uint64_t capacity;
- /* Descriptor of this block device */
- block_dev_desc_t block_dev;
-}
-
-The probe() function will then register the MMC driver by calling:
-
- mmc_device_register(struct instance *i, struct mmc_driver_ops *o,
- struct mmc_driver_params *p);
-
-The struct mmc_driver_params will have to be dynamic in some cases, but the
-driver shouldn't modify it's contents elsewhere than in probe() call.
-
-Next, since the MMC drivers will now be consistently registered into the driver
-tree from board file, the functions "board_mmc_init()" and "cpu_mmc_init()" will
-disappear altogether.
-
-As for the legacy drivers, these will either be converted or removed altogether.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- arm_pl180_mmci.c
- ----------------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- atmel_mci.c
- -----------
- This driver uses the legacy API and should be removed unless converted. It is
- probably possbible to replace this driver with gen_atmel_mci.c . No conversion
- will be done on this driver.
-
- bfin_sdh.c
- ----------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- davinci_mmc.c
- -------------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- fsl_esdhc.c
- -----------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple, unless some problem appears due to the FDT
- component of the driver.
-
- ftsdc010_esdhc.c
- ----------------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- gen_atmel_mci.c
- ---------------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- mmc_spi.c
- ---------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- mv_sdhci.c
- ----------
- This is a component of the SDHCI support, allowing it to run on Marvell
- Kirkwood chip. It is probable the SDHCI support will have to be modified to
- allow calling functions from this file based on information passed via
- platform_data.
-
- mxcmmc.c
- --------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- mxsmmc.c
- --------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- omap_hsmmc.c
- ------------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- pxa_mmc.c
- ---------
- This driver uses the legacy API and is written in a severely ad-hoc manner.
- This driver will be removed in favor of pxa_mmc_gen.c, which is proved to work
- better and is already well tested. No conversion will be done on this driver
- anymore.
-
- pxa_mmc_gen.c
- -------------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- s5p_mmc.c
- ---------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- sdhci.c
- -------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple, though it'd be necessary to modify this driver
- to also support the Kirkwood series and probably also Tegra series of CPUs.
- See the respective parts of this section for details.
-
- sh_mmcif.c
- ----------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
-
- tegra2_mmc.c
- ------------
- Follows the new API and also has a good encapsulation of the whole driver. The
- conversion here will be simple.
diff --git a/doc/driver-model/UDM-net.txt b/doc/driver-model/UDM-net.txt
deleted file mode 100644
index 097ed69600..0000000000
--- a/doc/driver-model/UDM-net.txt
+++ /dev/null
@@ -1,428 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Net system analysis
-===================
-Marek Vasut <marek.vasut@gmail.com>
-2012-03-03
-
-I) Overview
------------
-
-The networking subsystem already supports multiple devices. Therefore the
-conversion shall not be very hard.
-
-The network subsystem is operated from net/eth.c, which tracks all registered
-ethernet interfaces and calls their particular functions registered via
-eth_register().
-
-The eth_register() is called from the network driver initialization function,
-which in turn is called most often either from "board_net_init()" or
-"cpu_net_init()". This function has one important argument, which is the
-"struct eth_device", defined at include/net.h:
-
-struct eth_device {
- /* DRIVER: Name of the device */
- char name[NAMESIZE];
- /* DRIVER: MAC address */
- unsigned char enetaddr[6];
- /* DRIVER: Register base address */
- int iobase;
- /* CORE: state of the device */
- int state;
-
- /* DRIVER: Device initialization function */
- int (*init) (struct eth_device*, bd_t*);
- /* DRIVER: Function for sending packets */
- int (*send) (struct eth_device*, volatile void* packet, int length);
- /* DRIVER: Function for receiving packets */
- int (*recv) (struct eth_device*);
- /* DRIVER: Function to cease operation of the device */
- void (*halt) (struct eth_device*);
- /* DRIVER: Function to send multicast packet (OPTIONAL) */
- int (*mcast) (struct eth_device*, u32 ip, u8 set);
- /* DRIVER: Function to change ethernet MAC address */
- int (*write_hwaddr) (struct eth_device*);
- /* CORE: Next device in the linked list of devices managed by net core */
- struct eth_device *next;
- /* CORE: Device index */
- int index;
- /* DRIVER: Driver's private data */
- void *priv;
-};
-
-This structure defines the particular driver, though also contains elements that
-should not be exposed to the driver, like core state.
-
-Small, but important part of the networking subsystem is the PHY management
-layer, whose drivers are contained in drivers/net/phy. These drivers register in
-a very similar manner to network drivers, by calling "phy_register()" with the
-argument of "struct phy_driver":
-
-struct phy_driver {
- /* DRIVER: Name of the PHY driver */
- char *name;
- /* DRIVER: UID of the PHY driver */
- unsigned int uid;
- /* DRIVER: Mask for UID of the PHY driver */
- unsigned int mask;
- /* DRIVER: MMDS of the PHY driver */
- unsigned int mmds;
- /* DRIVER: Features the PHY driver supports */
- u32 features;
- /* DRIVER: Initialize the PHY hardware */
- int (*probe)(struct phy_device *phydev);
- /* DRIVER: Reconfigure the PHY hardware */
- int (*config)(struct phy_device *phydev);
- /* DRIVER: Turn on the PHY hardware, allow it to send/receive */
- int (*startup)(struct phy_device *phydev);
- /* DRIVER: Turn off the PHY hardware */
- int (*shutdown)(struct phy_device *phydev);
- /* CORE: Allows this driver to be part of list of drivers */
- struct list_head list;
-};
-
-II) Approach
-------------
-
-To convert the elements of network subsystem to proper driver model method, the
-"struct eth_device" will have to be split into multiple components. The first
-will be a structure defining the driver operations:
-
-struct eth_driver_ops {
- int (*init)(struct instance*, bd_t*);
- int (*send)(struct instance*, void *packet, int length);
- int (*recv)(struct instance*);
- void (*halt)(struct instance*);
- int (*mcast)(struct instance*, u32 ip, u8 set);
- int (*write_hwaddr)(struct instance*);
-};
-
-Next, there'll be platform data which will be per-driver and will replace the
-"priv" part of "struct eth_device". Last part will be the per-device core state.
-
-With regards to the PHY part of the API, the "struct phy_driver" is almost ready
-to be used with the new driver model approach. The only change will be the
-replacement of per-driver initialization functions and removal of
-"phy_register()" function in favor or driver model approach.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- drivers/net/4xx_enet.c
- ----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/altera_tse.c
- ------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/armada100_fec.c
- ---------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/at91_emac.c
- -----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/ax88180.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/ax88796.c
- ---------------------
-
- This file contains a components of the NE2000 driver, implementing only
- different parts on the NE2000 clone AX88796. This being no standalone driver,
- no conversion will be done here.
-
- drivers/net/bfin_mac.c
- ----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/calxedaxgmac.c
- --------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/cs8900.c
- --------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/davinci_emac.c
- --------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/dc2114x.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/designware.c
- ------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/dm9000x.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/dnet.c
- ------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/e1000.c
- -------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/e1000_spi.c
- -----------------------
-
- Driver for the SPI bus integrated on the Intel E1000. This is not part of the
- network stack.
-
- drivers/net/eepro100.c
- ----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/enc28j60.c
- ----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/ep93xx_eth.c
- ------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/ethoc.c
- -------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/fec_mxc.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/fsl_mcdmafec.c
- --------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/fsl_mdio.c
- ----------------------
-
- This file contains driver for FSL MDIO interface, which is not part of the
- networking stack.
-
- drivers/net/ftgmac100.c
- -----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/ftmac100.c
- ----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/greth.c
- -------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/inca-ip_sw.c
- ------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/ks8695eth.c
- -----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/lan91c96.c
- ----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/macb.c
- ------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/mcffec.c
- --------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/mcfmii.c
- --------------------
-
- This file contains MII interface driver for MCF FEC.
-
- drivers/net/mpc512x_fec.c
- -------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/mpc5xxx_fec.c
- -------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/mvgbe.c
- -------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/natsemi.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/ne2000_base.c
- -------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process. This driver contains the core
- implementation of NE2000, which needs a few external functions, implemented by
- AX88796, NE2000 etc.
-
- drivers/net/ne2000.c
- --------------------
-
- This file implements external functions necessary for native NE2000 compatible
- networking card to work.
-
- drivers/net/netconsole.c
- ------------------------
-
- This is actually an STDIO driver.
-
- drivers/net/ns8382x.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/pcnet.c
- -------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/plb2800_eth.c
- -------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/rtl8139.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/rtl8169.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/sh_eth.c
- --------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/smc91111.c
- ----------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/smc911x.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/tsec.c
- ------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/tsi108_eth.c
- ------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/uli526x.c
- ---------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/vsc7385.c
- ---------------------
-
- This is a driver that only uploads firmware to a switch. This is not subject
- of conversion.
-
- drivers/net/xilinx_axi_emac.c
- -----------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
-
- drivers/net/xilinx_emaclite.c
- -----------------------------
-
- This driver uses the standard new networking API, therefore there should be no
- obstacles throughout the conversion process.
diff --git a/doc/driver-model/UDM-pci.txt b/doc/driver-model/UDM-pci.txt
deleted file mode 100644
index 1dce99de3d..0000000000
--- a/doc/driver-model/UDM-pci.txt
+++ /dev/null
@@ -1,253 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-PCI subsystem analysis
-======================
-
-Pavel Herrmann <morpheus.ibis@gmail.com>
-2012-03-17
-
-I) Overview
------------
-
- U-Boot already supports multiple PCI busses, stored in a linked-list of
- pci_controller structures. This structure contains generic driver data, bus
- interface operations and private data for the driver.
-
- Bus interface operations for PCI are (names are self-explanatory):
-
- read_byte()
- read_word()
- read_dword()
- write_byte()
- write_word()
- write_dword()
-
- Each driver has to implement dword operations, and either implement word and
- byte operations, or use shared $operation_config_$type_via_dword (eg.
- read_config_byte_via_dword and similar) function. These functions are used
- for config space I/O (read_config_dword and similar functions of the PCI
- subsystem), which is used to configure the connected devices for standard MMIO
- operations. All data transfers by respective device drivers are then done by
- MMIO
-
- Each driver also defines a separate init function, which has unique symbol
- name, and thus more drivers can be compiled in without colliding. This init
- function is typically called from pci_init_board(), different for each
- particular board.
-
- Some boards also define a function called fixup_irq, which gets called after
- scanning the PCI bus for devices, and should dismiss any interrupts.
-
- Several drivers are also located in arch/ and should be moved to drivers/pci.
-
-II) Approach
-------------
-
- The pci_controller structure needs to be broken down to fit the new driver
- model. Due to a large number of members, this will be done through three
- distinct accessors, one for memory regions, one for config table and one for
- everything else. That will make the pci_ops structure look like this:
-
- struct pci_ops {
- int (*read_byte)(struct instance *bus, pci_dev_t *dev, int addr,
- u8 *buf);
- int (*read_word)(struct instance *bus, pci_dev_t *dev, int addr,
- u16 *buf);
- int (*read_dword)(struct instance *bus, pci_dev_t *dev, int addr,
- u32 *buf);
- int (*write_byte)(struct instance *bus, pci_dev_t *dev, int addr,
- u8 val);
- int (*write_byte)(struct instance *bus, pci_dev_t *dev, int addr,
- u8 val);
- int (*write_dword)(struct instance *bus, pci_dev_t *dev, int addr,
- u32 val);
- void (*fixup_irq)(struct instance *bus, pci_dev_t *dev);
- struct pci_region* (*get_region)(struct instance *, uint num);
- struct pci_config_table* (*get_cfg_table)(struct instance *bus);
- uint (*get_option)(struct instance * bus, enum pci_option_code op);
- }
-
- enum pci_option_code {
- PCI_OPT_BUS_NUMBER=0,
- PCI_OPT_REGION_COUNT,
- PCI_OPT_INDIRECT_TYPE,
- PCI_OPT_AUTO_MEM,
- PCI_OPT_AUTO_IO,
- PCI_OPT_AUTO_PREFETCH,
- PCI_OPT_AUTO_FB,
- PCI_OPT_CURRENT_BUS,
- PCI_OPT_CFG_ADDR,
- }
-
- The return value for get_option will be an unsigned integer value for any
- option code. If the option currently is a pointer to pci_region, it will
- return an index for get_region function. Special case has to be made for
- PCI_OPT_CFG_ADDR, which should be interpreted as a pointer, but it is only
- used for equality in find_hose_by_cfg_addr, and thus can be returned as an
- uint. Other function using cfg_addr value are read/write functions for
- specific drivers (especially ops for indirect bridges), and thus have access
- to private_data of the driver instance.
-
- The config table accessor will return a pointer to a NULL-terminated array of
- pci_config_table, which is supplied by the board in platform_data, or NULL if
- the board didn't specify one. This table is used to override PnP
- auto-initialization, or to specific initialization functions for non-PNP
- devices.
-
- Transparent PCI-PCI bridges will get their own driver, and will forward all
- operations to operations of their parent bus. This however makes it
- impossible to use instances to identify devices, as not all devices will be
- directly visible to the respective bus driver.
-
- Init functions of controller drivers will be moved to their respective
- probe() functions, in accordance to the driver model.
-
- The PCI core will handle all mapping functions currently found in pci.c, as
- well as proxy functions for read/write operations of the drivers. The PCI
- core will also handle bus scanning and device configuration.
-
- The PnP helper functions currently in pci_auto.c will also be a part of PCI
- core, but they will be exposed only to PCI controller drivers, not to other
- device drivers.
-
- The PCI API for device drivers will remain largely unchanged, most drivers
- will require no changes at all, and all modifications will be limited to
- changing the pci_controlle into instance*.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- A) drivers in drivers/pci/
- --------------------------
-
- pci_indirect.c
- --------------
- Shared driver for indirect PCI bridges, several CONFIG macros - will
- require significant cleanup.
-
- pci_sh4.c
- ---------
- Shared init function for SH4 drivers, uses dword for read/write ops.
-
- pci_sh7751.c
- ------------
- Standard driver, uses SH4 shared init.
-
- pci_sh7780.c
- ------------
- Standard driver, uses SH4 shared init.
-
- tsi108_pci.c
- ------------
- Standard driver, uses dword for read/write ops.
-
- fsl_pci_init.c
- --------------
- Driver for PCI and PCI-e, uses indirect functions.
-
- pci_ftpci100.c
- --------------
- Standard driver, uses indirect functions, has separate scan/setup
- functions.
-
- B) driver in arch/
- ------------------
-
- x86/lib/pci_type1.c
- -------------------
- Standard driver, specifies all read/write functions separately.
-
- m68k/cpu/mcf5445x/pci.c
- -----------------------
- Standard driver, specifies all read/write functions separately.
-
- m68k/cpu/mcf547x_8x/pci.c
- -------------------------
- Standard driver, specifies all read/write functions separately.
-
- powerpc/cpu/mpc824x/pci.c
- -------------------------
- Standard driver, uses indirect functions, does not setup HW.
-
- powerpc/cpu/mpc8260/pci.c
- -------------------------
- Standard driver, uses indirect functions.
-
- powerpc/cpu/ppc4xx/4xx_pci.c
- ----------------------------
- Standard driver, uses indirect functions.
-
- powerpc/cpu/ppc4xx/4xx_pcie.c
- -----------------------------
- PCI-e driver, specifies all read/write functions separately.
-
- powerpc/cpu/mpc83xx/pci.c
- -------------------------
- Standard driver, uses indirect functions.
-
- powerpc/cpu/mpc83xx/pcie.c
- --------------------------
- PCI-e driver, specifies all read/write functions separately.
-
- powerpc/cpu/mpc5xxx/pci_mpc5200.c
- ---------------------------------
- Standard driver, uses dword for read/write ops.
-
- powerpc/cpu/mpc512x/pci.c
- -------------------------
- Standard driver, uses indirect functions.
-
- powerpc/cpu/mpc85xx/pci.c
- -------------------------
- Standard driver, uses indirect functions, has two busses.
-
- C) drivers in board/
- --------------------
-
- eltec/elppc/pci.c
- -----------------
- Standard driver, uses indirect functions.
-
- amirix/ap1000/pci.c
- -------------------
- Standard driver, specifies all read/write functions separately.
-
- prodrive/p3mx/pci.c
- -------------------
- Standard driver, uses dword for read/write ops, has two busses.
-
- esd/cpci750/pci.c
- -----------------
- Standard driver, uses dword for read/write ops, has two busses.
-
- esd/common/pci.c
- ----------------
- Standard driver, uses dword for read/write ops.
-
- dave/common/pci.c
- -----------------
- Standard driver, uses dword for read/write ops.
-
- ppmc7xx/pci.c
- -------------
- Standard driver, uses indirect functions.
-
- Marvell/db64360/pci.c
- ---------------------
- Standard driver, uses dword for read/write ops, has two busses.
-
- Marvell/db64460/pci.c
- ---------------------
- Standard driver, uses dword for read/write ops, has two busses.
-
- evb64260/pci.c
- --------------
- Standard driver, uses dword for read/write ops, has two busses.
-
- armltd/integrator/pci.c
- -----------------------
- Standard driver, specifies all read/write functions separately.
-
- All drivers will be moved to drivers/pci. Several drivers seem
- similar/identical, especially those located under board, and may be merged
- into one.
diff --git a/doc/driver-model/UDM-pcmcia.txt b/doc/driver-model/UDM-pcmcia.txt
deleted file mode 100644
index d55e89df6a..0000000000
--- a/doc/driver-model/UDM-pcmcia.txt
+++ /dev/null
@@ -1,78 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-PCMCIA analysis
-===============
-Viktor Krivak <viktor.krivak@gmail.com>
-2012-03-17
-
-I) Overview
------------
-
- U-boot implements only 2 methods to interoperate with pcmcia. One to turn
- device on and other to turn device off. Names of these methods are usually
- pcmcia_on() and pcmcia_off() without any parameters. Some files in driver
- directory implements only internal API. These methods aren't used outside
- driver directory and they are not converted to new driver model.
-
-II) Approach
------------
-
- 1) New API
- ----------
-
- Current API is preserved and all internal methods are hiden.
-
- struct ops {
- void (*pcmcia_on)(struct instance *i);
- void (*pcmcia_off)(struct instance *i);
- }
-
- 2) Conversion
- -------------
-
- In header file pcmcia.h are some other variables which are used for
- additional configuration. But all have to be moved to platform data or to
- specific driver implementation.
-
- 3) Platform data
- ----------------
-
- Many boards have custom implementation of internal API. Pointers to these
- methods are stored in platform_data. But the most implementations for Intel
- 82365 and compatible PC Card controllers and Yenta-compatible
- PCI-to-CardBus controllers implement whole API per board. In these cases
- pcmcia_on() and pcmcia_off() behave only as wrappers and call specific
- board methods.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- i82365.c
- --------
- Driver methods have different name i82365_init() and i82365_exit but
- all functionality is the same. Board files board/atc/ti113x.c and
- board/cpc45/pd67290.c use their own implementation of these method.
- In this case all methods in driver behave only as wrappers.
-
- marubun_pcmcia.c
- ----------------
- Meets standard API behaviour. Simple conversion.
-
- mpc8xx_pcmcia.c
- ---------------
- Meets standard API behaviour. Simple conversion.
-
- rpx_pcmcia.c
- ------------
- Implements only internal API used in other drivers. Non of methods
- implemented here are used outside driver model.
-
- ti_pci1410a.c
- -------------
- Has different API but methods in this file are never called. Probably
- dead code.
-
- tqm8xx_pcmcia.c
- ---------------
- Implements only internal API used in other drivers. Non of methods
- implemented here are used outside driver model.
diff --git a/doc/driver-model/UDM-power.txt b/doc/driver-model/UDM-power.txt
deleted file mode 100644
index 666d55305f..0000000000
--- a/doc/driver-model/UDM-power.txt
+++ /dev/null
@@ -1,88 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-POWER analysis
-==============
-Viktor Krivak <viktor.krivak@gmail.com>
-2012-03-09
-
-I) Overview
------------
-
- 1) Actual state
- ---------------
-
- At this moment power doesn't contain API. There are many methods for
- initialization of some board specific functions but only few does what is
- expected. Basically only one file contains something meaningful for this
- driver.
-
- 2) Current implementation
- -------------------------
-
- In file twl6030.c are methods twl6030_stop_usb_charging() and
- twl6030_start_usb_charging() for start and stop charging from USB. There are
- also methods to get information about battery state and initialization of
- battery charging. Only these methods are used in converted API.
-
-
-II) Approach
-------------
-
- 1) New API
- ----------
-
- New API implements only functions specific for managing power. All board
- specific init methods are moved to other files. Name of methods are
- self-explanatory.
-
- struct ops {
- void (*start_usb_charging)(struct instance *i);
- void (*stop_usb_charging)(struct instance *i);
- int (*get_battery_current)(struct instance *i);
- int (*get_battery_voltage)(struct instance *i);
- void (*init_battery_charging)(struct instance *i);
- }
-
- 2) Conversions of other methods
- -------------------------------
-
- Methods that can't be converted to new API are moved to board file or to
- special file for board hacks.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- ftpmu010.c
- ----------
- All methods of this file are moved to another location.
- void ftpmu010_32768osc_enable(void): Move to boards hacks
- void ftpmu010_mfpsr_select_dev(unsigned int dev): Move to board file
- arch/nds32/lib/board.c
- void ftpmu010_mfpsr_diselect_dev(unsigned int dev): Dead code
- void ftpmu010_dlldis_disable(void): Dead code
- void ftpmu010_sdram_clk_disable(unsigned int cr0): Move to board file
- arch/nds32/lib/board.c
- void ftpmu010_sdramhtc_set(unsigned int val): Move to board file
- arch/nds32/lib/board.c
-
- twl4030.c
- ---------
- All methods of this file are moved to another location.
- void twl4030_power_reset_init(void): Move to board hacks
- void twl4030_pmrecv_vsel_cfg(u8 vsel_reg, u8 vsel_val, u8 dev_grp,
- u8 dev_grp_sel): Move to board hacks
- void twl4030_power_init(void): Move to board hacks
- void twl4030_power_mmc_init(void): Move to board hacks
-
- twl6030.c
- ---------
- Some methods are converted to new API and rest are moved to another location.
- void twl6030_stop_usb_charging(void): Convert to new API
- void twl6030_start_usb_charging(void): Convert to new API
- int twl6030_get_battery_current(void): Convert to new API
- int twl6030_get_battery_voltage(void): Convert to new API
- void twl6030_init_battery_charging(void): Convert to new API
- void twl6030_power_mmc_init(): Move to board file
- drivers/mmc/omap_hsmmc.c
- void twl6030_usb_device_settings(): Move to board file
- drivers/usb/musb/omap3.c
diff --git a/doc/driver-model/UDM-rtc.txt b/doc/driver-model/UDM-rtc.txt
deleted file mode 100644
index 3640d24c28..0000000000
--- a/doc/driver-model/UDM-rtc.txt
+++ /dev/null
@@ -1,253 +0,0 @@
-=============================
-RTC device subsystem analysis
-=============================
-
-Tomas Hlavacek <tmshlvck@gmail.com>
-2012-03-10
-
-I) Overview
------------
-
-U-Boot currently implements one common API for RTC devices. The interface
-is defined in include/rtc.h and comprises of functions and structures:
-
- struct rtc_time {
- int tm_sec;
- int tm_min;
- int tm_hour;
- int tm_mday;
- int tm_mon;
- int tm_year;
- int tm_wday;
- int tm_yday;
- int tm_isdst;
- };
-
- int rtc_get (struct rtc_time *);
- int rtc_set (struct rtc_time *);
- void rtc_reset (void);
-
-The functions are implemented by a proper device driver in drivers/rtc
-directory and the driver to be compiled in is selected in a Makefile.
-Drivers are mutually exclusive.
-
-Drivers depends on date code in drivers/rtc/date.c and naturally on board
-specific data.
-
-II) Approach
-------------
-
- 1) New API
- ----------
- In the UDM each rtc driver would register itself by a function
-
- int rtc_device_register(struct instance *i,
- struct rtc_device_ops *o);
-
- The structure being defined as follows:
-
- struct rtc_device_ops {
- int (*get_time)(struct instance *i, struct rtc_time *t);
- int (*set_time)(struct instance *i, struct rtc_time *t);
- int (*reset)(struct instance *i);
- };
-
-
- 2) Conversion thougths
- ----------------------
- U-Boot RTC drivers exports the same functions and therefore the conversion
- of the drivers is straight-forward. There is no initialization needed.
-
-
-III) Analysis of in-tree drivers
---------------------------------
-
- drivers/rtc/rv3029.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/s3c24x0_rtc.c
- -------------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/pt7c4338.c
- ----------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/mvrtc.c
- -------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ftrtc010.c
- ----------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/mpc5xxx.c
- ---------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds164x.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/rs5c372.c
- ---------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/m41t94.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/mc13xxx-rtc.c
- -------------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/mcfrtc.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/davinci.c
- ---------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/rx8025.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/bfin_rtc.c
- ----------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/m41t62.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds1306.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/mpc8xx.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds3231.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds12887.c
- ---------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds1302.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds1374.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds174x.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/m41t60.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/m48t35ax.c
- ----------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/pl031.c
- -------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/x1205.c
- -------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/m41t11.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/pcf8563.c
- ---------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/mk48t59.c
- ---------------------
- Macros needs cleanup. Besides that the driver is standard rtc.
- Simple conversion is possible.
-
-
- drivers/rtc/mxsrtc.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds1307.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds1556.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/rtc4543.c
- ---------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/ds1337.c
- --------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/isl1208.c
- ---------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/max6900.c
- ---------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/mc146818.c
- ----------------------
- The driver is standard rtc. Simple conversion is possible.
-
-
- drivers/rtc/at91sam9_rtt.c
- --------------------------
- The driver is standard rtc. Simple conversion is possible.
diff --git a/doc/driver-model/UDM-serial.txt b/doc/driver-model/UDM-serial.txt
deleted file mode 100644
index ed804a8e7e..0000000000
--- a/doc/driver-model/UDM-serial.txt
+++ /dev/null
@@ -1,155 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Serial I/O analysis
-===================
-Marek Vasut <marek.vasut@gmail.com>
-2012-02-20
-
-I) Overview
------------
-
-The serial port support currently requires the driver to export the following
-functions:
-
- serial_putc() ...... Output a character
- serial_puts() ...... Output string, often done using serial_putc()
- serial_tstc() ...... Test if incoming character is in a buffer
- serial_getc() ...... Retrieve incoming character
- serial_setbrg() .... Configure port options
- serial_init() ...... Initialize the hardware
-
-The simpliest implementation, supporting only one port, simply defines these six
-functions and calls them. Such calls are scattered all around U-Boot, especiall
-serial_putc(), serial_puts(), serial_tstc() and serial_getc(). The serial_init()
-and serial_setbrg() are often called from platform-dependent places.
-
-It's important to consider current implementation of CONFIG_SERIAL_MULTI though.
-This resides in common/serial.c and behaves as a multiplexer for serial ports.
-This, by calling serial_assign(), allows user to switch I/O from one serial port
-to another. Though the environmental variables "stdin", "stdout", "stderr"
-remain set to "serial".
-
-These variables are managed by the IOMUX. This resides in common/iomux.c and
-manages all console input/output from U-Boot. For serial port, only one IOMUX is
-always registered, called "serial" and the switching of different serial ports
-is done by code in common/serial.c.
-
-On a final note, it's important to mention function default_serial_console(),
-which is platform specific and reports the default serial console for the
-platform, unless proper environment variable overrides this.
-
-II) Approach
-------------
-
-Drivers not using CONFIG_SERIAL_MULTI already will have to be converted to
-similar approach. The probe() function of a driver will call a function
-registering the driver with a STDIO subsystem core, stdio_device_register().
-
-The serial_init() function will now be replaced by probe() function of the
-driver, the rest of the components of the driver will be converted to standard
-STDIO driver calls. See [ UDM-stdio.txt ] for details.
-
-The serial_setbrg() function depends on global data pointer. This is wrong,
-since there is likely to be user willing to configure different baudrate on two
-different serial ports. The function will be replaced with STDIO's "conf()"
-call, with STDIO_CONFIG_SERIAL_BAUDRATE argument.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- altera_jtag_uart.c
- ------------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- altera_uart.c
- -------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- arm_dcc.c
- ---------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible, unless used
- with CONFIG_ARM_DCC_MULTI. Then it registers another separate IOMUX.
-
- atmel_usart.c
- -------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- mcfuart.c
- ---------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- ns16550.c
- ---------
- This driver seems complicated and certain consideration will need to be made
- during conversion. This driver is implemented in very universal manner,
- therefore it'll be necessary to properly design it's platform_data.
-
- opencores_yanu.c
- ----------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- sandbox.c
- ---------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- serial.c
- --------
- This is a complementary part of NS16550 UART driver, see above.
-
- serial_imx.c
- ------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible. This driver
- might be removed in favor of serial_mxc.c .
-
- serial_ks8695.c
- ---------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- serial_max3100.c
- ----------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- serial_mxc.c
- ------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- serial_pl01x.c
- --------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible, though this
- driver in fact contains two drivers in total.
-
- serial_pxa.c
- ------------
- This driver is a bit complicated, but due to clean support for
- CONFIG_SERIAL_MULTI, there are no expected obstructions throughout the
- conversion process.
-
- serial_s3c24x0.c
- ----------------
- This driver, being quite ad-hoc might need some work to bring back to shape.
-
- serial_s5p.c
- ------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- serial_sa1100.c
- ---------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- serial_sh.c
- -----------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- serial_xuartlite.c
- ------------------
- No support for CONFIG_SERIAL_MULTI. Simple conversion possible.
-
- usbtty.c
- --------
- This driver seems very complicated and entangled with USB framework. The
- conversion might be complicated here.
-
- arch/powerpc/cpu/mpc512x/serial.c
- ---------------------------------
- This driver supports CONFIG_SERIAL_MULTI. This driver will need to be moved to
- proper place.
diff --git a/doc/driver-model/UDM-spi.txt b/doc/driver-model/UDM-spi.txt
deleted file mode 100644
index 9ba0f841ef..0000000000
--- a/doc/driver-model/UDM-spi.txt
+++ /dev/null
@@ -1,200 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-SPI analysis
-============
-Viktor Krivak <viktor.krivak@gmail.com>
-2012-03-03
-
-I) Overview
------------
-
- 1) The SPI driver
- -----------------
-
- At this moment U-Boot provides standard API that consist of 7 functions:
-
- void spi_init(void);
- struct spi_slave *spi_setup_slave(unsigned int bus, unsigned int cs,
- unsigned int max_hz, unsigned int mode);
- void spi_free_slave(struct spi_slave *slave);
- int spi_claim_bus(struct spi_slave *slave);
- void spi_release_bus(struct spi_slave *slave);
- int spi_xfer(struct spi_slave *slave, unsigned int bitlen,
- const void *dout, void *din, unsigned long flags);
- int spi_cs_is_valid(unsigned int bus, unsigned int cs);
- void spi_cs_activate(struct spi_slave *slave);
- void spi_cs_deactivate(struct spi_slave *slave);
- void spi_set_speed(struct spi_slave *slave, uint hz);
-
- Method spi_init() is usually empty. All necessary configuration are sets by
- spi_setup_slave(). But this configuration is usually stored only in memory.
- No real hardware sets are made. All hardware settings are provided by method
- spi_claim_bus(). This method claims the bus and it can't be claimed again
- until it's release. That's mean all calls of method spi_claim_bus() will
- fail. But lots of cpu implementation don't meet this behaviour.
- Method spi_release_bus() does exact opposite. It release bus directly by
- some hardware sets. spi_free_slave() only free memory allocated by
- spi_setup_slave(). Method spi_xfer() do actually read and write operation
- throw specified bus and cs. Other methods are self explanatory.
-
- 2) Current limitations
- ----------------------
-
- Theoretically at this moment api allows use more then one bus per device at
- the time. But in real this can be achieved only when all buses have their
- own base addresses in memory.
-
-
-II) Approach
-------------
-
- 1) Claiming bus
- ---------------
-
- The current api cannot be used because struct spi_slave have to be in
- private data. In that case user are prohibited to use different bus on one
- device at same time. But when base memory address for bus are different.
- It's possible make more instance of this driver. Otherwise it can't can be
- done because of hardware limitation.
-
- 2) API change
- -------------
-
- Method spi_init() is moved to probe. Methods spi_setup_slave() and
- spi_claim_bus() are joined to one method. This method checks if desired bus
- exists and is available then configure necessary hardware and claims bus.
- Method spi_release_bus() and spi_free_slave() are also joined to meet this
- new approach. Other function remain same. Only struct spi_slave was change
- to instance.
-
- struct ops {
- int (*spi_request_bus)(struct instance *i, unsigned int bus,
- unsigned int cs, unsigned int max_hz,
- unsigned int mode);
- void (*spi_release_bus)(struct instance *i);
- int (*spi_xfer) (struct instance *i, unsigned int bitlen,
- const void *dout, void *din, unsigned long flags);
- int (*spi_cs_is_valid)(struct instance *i, unsigned int bus,
- unsigned int cs);
- void (*spi_cs_activate)(struct instance *i);
- void (*spi_cs_deactivate)(struct instance *i);
- void (*spi_set_speed)(struct instance *i, uint hz);
- }
-
- 3) Legacy API
- -------------
-
- To easy conversion of the whole driver. Original and new api can exist next
- to each other. New API is designed to be only a wrapper that extracts
- necessary information from private_data and use old api. When driver can
- use more than one bus at the time. New API require multiple instance. One
- for each bus. In this case spi_slave have to be copied in each instance.
-
- 4) Conversion TIME-LINE
- -----------------------
-
- To prevent build corruption api conversion have to be processed in several
- independent steps. In first step all old API methods are renamed. After that
- new API and core function are implemented. Next step is conversion of all
- board init methods to set platform data. After all these steps it is possible
- to start conversion of all remaining calls. This procedure guarantees that
- build procedure and binaries are never broken.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- altera_spi.c
- ------------
- All methods have designated structure. Simple conversion possible.
-
- andes_spi.c
- -----------
- All methods have designated structure. Simple conversion possible.
-
- andes_spi.h
- -----------
- Support file for andes_spi.c. No conversion is needed.
-
- armada100_spi.c
- ---------------
- All methods have designated structure. Simple conversion possible.
-
- atmel_dataflash_spi.c
- ---------------------
- Wrong placement. Will be moved to another location.
-
- atmel_spi.c
- -----------
- Supports more than one bus. Need some minor change.
-
- atmel_spi.h
- -----------
- Support file for andes_spi.c. No conversion is needed.
-
- bfin_spi.c
- ----------
- Supports more than one bus. Need some minor change.
-
- cf_spi.c
- --------
- Cooperate with some cpu specific methods from other files. Hard conversion.
-
- davinci_spi.c
- -------------
- All methods have designated structure. Simple conversion possible.
-
- davinci_spi.h
- -------------
- Support file for davinci_spi.h. No conversion is needed.
-
- fsl_espi.c
- ----------
- All methods have designated structure. Simple conversion possible.
-
- kirkwood_spi.c
- --------------
- All methods have designated structure. Simple conversion possible.
-
- mpc8xxx_spi.c
- -------------
- All methods have designated structure. Simple conversion possible.
-
- mpc52xx_spi.c
- -------------
- All methods have designated structure. Simple conversion possible.
-
- mxc_spi.c
- ---------
- All methods have designated structure. Simple conversion possible.
-
- mxs_spi.c
- ---------
- All methods have designated structure. Simple conversion possible.
-
- oc_tiny_spi.c
- -------------
- Supports more than one bus. Need some minor change.
-
- omap3_spi.c
- -----------
- Supports more than one bus. Need some minor change.
-
- omap3_spi.h
- -----------
- Support file for omap3_spi.c. No conversion is needed.
-
- sh_spi.c
- --------
- All methods have designated structure. Simple conversion possible.
-
- sh_spi.h
- --------
- Support file for sh_spi.h. No conversion is needed.
-
- soft_spi.c
- ----------
- Use many board specific method linked from other files. Need careful debugging.
-
- tegra2_spi.c
- ------------
- Some hardware specific problem when releasing bus.
diff --git a/doc/driver-model/UDM-stdio.txt b/doc/driver-model/UDM-stdio.txt
deleted file mode 100644
index 156627b515..0000000000
--- a/doc/driver-model/UDM-stdio.txt
+++ /dev/null
@@ -1,191 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-I/O system analysis
-===================
-Marek Vasut <marek.vasut@gmail.com>
-2012-02-20
-
-I) Overview
------------
-
-The console input and output is currently done using the STDIO subsystem in
-U-Boot. The design of this subsystem is already flexible enough to be easily
-converted to new driver model approach. Minor changes will need to be done
-though.
-
-Each device that wants to register with STDIO subsystem has to define struct
-stdio_dev, defined in include/stdio_dev.h and containing the following fields:
-
-struct stdio_dev {
- int flags; /* Device flags: input/output/system */
- int ext; /* Supported extensions */
- char name[16]; /* Device name */
-
-/* GENERAL functions */
-
- int (*start) (void); /* To start the device */
- int (*stop) (void); /* To stop the device */
-
-/* OUTPUT functions */
-
- void (*putc) (const char c); /* To put a char */
- void (*puts) (const char *s); /* To put a string (accelerator) */
-
-/* INPUT functions */
-
- int (*tstc) (void); /* To test if a char is ready... */
- int (*getc) (void); /* To get that char */
-
-/* Other functions */
-
- void *priv; /* Private extensions */
- struct list_head list;
-};
-
-Currently used flags are DEV_FLAGS_INPUT, DEV_FLAGS_OUTPUT and DEV_FLAGS_SYSTEM,
-extensions being only one, the DEV_EXT_VIDEO.
-
-The private extensions are now used as a per-device carrier of private data and
-finally list allows this structure to be a member of linked list of STDIO
-devices.
-
-The STDIN, STDOUT and STDERR routing is handled by environment variables
-"stdin", "stdout" and "stderr". By configuring the variable to the name of a
-driver, functions of such driver are called to execute that particular
-operation.
-
-II) Approach
-------------
-
- 1) Similarity of serial, video and keyboard drivers
- ---------------------------------------------------
-
- All of these drivers can be unified under the STDIO subsystem if modified
- slightly. The serial drivers basically define both input and output functions
- and need function to configure baudrate. The keyboard drivers provide only
- input. On the other hand, video drivers provide output, but need to be
- configured in certain way. This configuration might be dynamic, therefore the
- STDIO has to be modified to provide such flexibility.
-
- 2) Unification of serial, video and keyboard drivers
- ----------------------------------------------------
-
- Every STDIO device would register a structure containing operation it supports
- with the STDIO core by calling:
-
- int stdio_device_register(struct instance *i, struct stdio_device_ops *o);
-
- The structure being defined as follows:
-
- struct stdio_device_ops {
- void (*putc)(struct instance *i, const char c);
- void (*puts)(struct instance *i, const char *s); /* OPTIONAL */
-
- int (*tstc)(struct instance *i);
- int (*getc)(struct instance *i);
-
- int (*init)(struct instance *i);
- int (*exit)(struct instance *i);
- int (*conf)(struct instance *i, enum stdio_config c, const void *data);
- };
-
- The "putc()" function will emit a character, the "puts()" function will emit a
- string. If both of these are set to NULL, the device is considered STDIN only,
- aka input only device.
-
- The "getc()" retrieves a character from a STDIN device, while "tstc()" tests
- if there is a character in the buffer of STDIN device. In case these two are
- set to NULL, this device is STDOUT / STDERR device.
-
- Setting all "putc()", "puts()", "getc()" and "tstc()" calls to NULL isn't an
- error condition, though such device does nothing. By instroducing tests for
- these functions being NULL, the "flags" and "ext" fields from original struct
- stdio_dev can be eliminated.
-
- The "init()" and "exit()" calls are replacement for "start()" and "exit()"
- calls in the old approach. The "priv" part of the old struct stdio_dev will be
- replaced by common private data in the driver model and the struct list_head
- list will be eliminated by introducing common STDIO core, that tracks all the
- STDIO devices.
-
- Lastly, the "conf()" call will allow the user to configure various options of
- the driver. The enum stdio_config contains all possible configuration options
- available to the STDIO devices, const void *data being the argument to be
- configured. Currently, the enum stdio_config will contain at least the
- following options:
-
- enum stdio_config {
- STDIO_CONFIG_SERIAL_BAUDRATE,
- };
-
- 3) Transformation of stdio routing
- ----------------------------------
-
- By allowing multiple instances of drivers, the environment variables "stdin",
- "stdout" and "stderr" can no longer be set to the name of the driver.
- Therefore the STDIO core, tracking all of the STDIO devices in the system will
- need to have a small amount of internal data for each device:
-
- struct stdio_device_node {
- struct instance *i;
- struct stdio_device_ops *ops;
- uint8_t id;
- uint8_t flags;
- struct list_head list;
- }
-
- The "id" is the order of the instance of the same driver. The "flags" variable
- allows multiple drivers to be used at the same time and even for different
- purpose. The following flags will be defined:
-
- STDIO_FLG_STDIN ..... This device will be used as an input device. All input
- from all devices with this flag set will be received
- and passed to the upper layers.
- STDIO_FLG_STDOUT .... This device will be used as an output device. All
- output sent to stdout will be routed to all devices
- with this flag set.
- STDIO_FLG_STDERR .... This device will be used as an standard error output
- device. All output sent to stderr will be routed to
- all devices with this flag set.
-
- The "list" member of this structure allows to have a linked list of all
- registered STDIO devices.
-
-III) Analysis of in-tree drivers
---------------------------------
-
-For in-depth analysis of serial port drivers, refer to [ UDM-serial.txt ].
-For in-depth analysis of keyboard drivers, refer to [ UDM-keyboard.txt ].
-For in-depth analysis of video drivers, refer to [ UDM-video.txt ].
-
- arch/blackfin/cpu/jtag-console.c
- --------------------------------
- This driver is a classic STDIO driver, no problem with conversion is expected.
-
- board/mpl/pati/pati.c
- ---------------------
- This driver registers with the STDIO framework, though it uses a lot of ad-hoc
- stuff which will need to be sorted out.
-
- board/netphone/phone_console.c
- ------------------------------
- This driver is a classic STDIO driver, no problem with conversion is expected.
-
- drivers/net/netconsole.c
- ------------------------
- This driver is a classic STDIO driver, no problem with conversion is expected.
-
-IV) Other involved files (To be removed)
-----------------------------------------
-
-common/cmd_console.c
-common/cmd_log.c
-common/cmd_terminal.c
-common/console.c
-common/fdt_support.c
-common/iomux.c
-common/lcd.c
-common/serial.c
-common/stdio.c
-common/usb_kbd.c
-doc/README.iomux
diff --git a/doc/driver-model/UDM-tpm.txt b/doc/driver-model/UDM-tpm.txt
deleted file mode 100644
index 0beff4a857..0000000000
--- a/doc/driver-model/UDM-tpm.txt
+++ /dev/null
@@ -1,48 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-TPM system analysis
-===================
-Marek Vasut <marek.vasut@gmail.com>
-2012-02-23
-
-I) Overview
------------
-
-There is currently only one TPM chip driver available and therefore the API
-controlling it is very much based on this. The API is very simple:
-
- int tis_open(void);
- int tis_close(void);
- int tis_sendrecv(const u8 *sendbuf, size_t send_size,
- u8 *recvbuf, size_t *recv_len);
-
-The command operating the TPM chip only provides operations to send and receive
-bytes from the chip.
-
-II) Approach
-------------
-
-The API can't be generalised too much considering there's only one TPM chip
-supported. But it's a good idea to split the tis_sendrecv() function in two
-functions. Therefore the new API will use register the TPM chip by calling:
-
- tpm_device_register(struct instance *i, const struct tpm_ops *ops);
-
-And the struct tpm_ops will contain the following members:
-
- struct tpm_ops {
- int (*tpm_open)(struct instance *i);
- int (*tpm_close)(struct instance *i);
- int (*tpm_send)(const uint8_t *buf, const size_t size);
- int (*tpm_recv)(uint8_t *buf, size_t *size);
- };
-
-The behaviour of "tpm_open()" and "tpm_close()" will basically copy the
-behaviour of "tis_open()" and "tis_close()". The "tpm_send()" will be based on
-the "tis_senddata()" and "tis_recv()" will be based on "tis_readresponse()".
-
-III) Analysis of in-tree drivers
---------------------------------
-
-There is only one in-tree driver present, the "drivers/tpm/generic_lpc_tpm.c",
-which will be simply converted as outlined in previous chapter.
diff --git a/doc/driver-model/UDM-twserial.txt b/doc/driver-model/UDM-twserial.txt
deleted file mode 100644
index 5f2c5a3d40..0000000000
--- a/doc/driver-model/UDM-twserial.txt
+++ /dev/null
@@ -1,47 +0,0 @@
-==================================
-TWserial device subsystem analysis
-==================================
-
-Tomas Hlavacek<tmshlvck@gmail.com>
-2012-03-21
-
-I) Overview
------------
-
-U-Boot currently implements one common API for TWSerial devices. The interface
-is defined in include/tws.h and comprises of functions:
-
- int tws_read(uchar *buffer, int len);
- int tws_write(uchar *buffer, int len);
-
-The functions are implemented by a proper device driver in drivers/twserial
-directory and the driver to be compiled in is selected in a Makefile. There is
-only one driver present now.
-
-The driver depends on ad-hoc code in board specific data, namely functions:
-
- void tws_ce(unsigned bit);
- void tws_wr(unsigned bit);
- void tws_clk(unsigned bit);
- void tws_data(unsigned bit);
- unsigned tws_data_read(void);
- void tws_data_config_output(unsigned output);
-
-implemented in include/configs/inka4x0.h .
-
-II) Approach
-------------
-
- U-Boot TWserial drivers exports two simple functions and therefore the conversion
- of the driver and creating a core for it is not needed. It should be consolidated
- with include/configs/inka4x0.h and taken to the misc/ dir.
-
-
-III) Analysis of in-tree drivers
---------------------------------
-
- drivers/twserial/soft_tws.c
- ---------------------------
- The driver is the only TWserial driver. The ad-hoc part in
- include/configs/inka4x0.h and the core soft_tws driver should be consolidated
- to one compact driver and moved to misc/ .
diff --git a/doc/driver-model/UDM-usb.txt b/doc/driver-model/UDM-usb.txt
deleted file mode 100644
index 5ce85b5d60..0000000000
--- a/doc/driver-model/UDM-usb.txt
+++ /dev/null
@@ -1,94 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-USB analysis
-============
-Marek Vasut <marek.vasut@gmail.com>
-2012-02-16
-
-I) Overview
------------
-
- 1) The USB Host driver
- ----------------------
- There are basically four or five USB host drivers. All such drivers currently
- provide at least the following fuctions:
-
- usb_lowlevel_init() ... Do the initialization of the USB controller hardware
- usb_lowlevel_stop() ... Do the shutdown of the USB controller hardware
-
- usb_event_poll() ...... Poll interrupt from USB device, often used by KBD
-
- submit_control_msg() .. Submit message via Control endpoint
- submit_int_msg() ...... Submit message via Interrupt endpoint
- submit_bulk_msg() ..... Submit message via Bulk endpoint
-
-
- This allows for the host driver to be easily abstracted.
-
- 2) The USB hierarchy
- --------------------
-
- In the current implementation, the USB Host driver provides operations to
- communicate via the USB bus. This is realised by providing access to a USB
- root port to which an USB root hub is attached. The USB bus is scanned and for
- each newly found device, a struct usb_device is allocated. See common/usb.c
- and include/usb.h for details.
-
-II) Approach
-------------
-
- 1) The USB Host driver
- ----------------------
-
- Converting the host driver will follow the classic driver model consideration.
- Though, the host driver will have to call a function that registers a root
- port with the USB core in it's probe() function, let's call this function
-
- usb_register_root_port(&ops);
-
- This will allow the USB core to track all available root ports. The ops
- parameter will contain structure describing operations supported by the root
- port:
-
- struct usb_port_ops {
- void (*usb_event_poll)();
- int (*submit_control_msg)();
- int (*submit_int_msg)();
- int (*submit_bulk_msg)();
- }
-
- 2) The USB hierarchy and hub drivers
- ------------------------------------
-
- Converting the USB heirarchy should be fairy simple, considering the already
- dynamic nature of the implementation. The current usb_hub_device structure
- will have to be converted to a struct instance. Every such instance will
- contain components of struct usb_device and struct usb_hub_device in it's
- private data, providing only accessors in order to properly encapsulate the
- driver.
-
- By registering the root port, the USB framework will instantiate a USB hub
- driver, which is always present, the root hub. The root hub and any subsequent
- hub instance is represented by struct instance and it's private data contain
- amongst others common bits from struct usb_device.
-
- Note the USB hub driver is partly defying the usual method of registering a
- set of callbacks to a particular core driver. Instead, a static set of
- functions is defined and the USB hub instance is passed to those. This creates
- certain restrictions as of how the USB hub driver looks, but considering the
- specification for USB hub is given and a different type of USB hub won't ever
- exist, this approach is ok:
-
- - Report how many ports does this hub have:
- uint get_nr_ports(struct instance *hub);
- - Get pointer to device connected to a port:
- struct instance *(*get_child)(struct instance *hub, int port);
- - Instantiate and configure device on port:
- struct instance *(*enum_dev_on_port)(struct instance *hub, int port);
-
- 3) USB device drivers
- ---------------------
-
- The USB device driver, in turn, will have to register various ops structures
- with certain cores. For example, USB disc driver will have to register it's
- ops with core handling USB discs etc.
diff --git a/doc/driver-model/UDM-video.txt b/doc/driver-model/UDM-video.txt
deleted file mode 100644
index e67e9e41b4..0000000000
--- a/doc/driver-model/UDM-video.txt
+++ /dev/null
@@ -1,74 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Video output analysis
-=====================
-Marek Vasut <marek.vasut@gmail.com>
-2012-02-20
-
-I) Overview
------------
-
-The video drivers are most often registered with video subsystem. This subsystem
-often expects to be allowed access to framebuffer of certain parameters. This
-subsystem also provides calls for STDIO subsystem to allow it to output
-characters on the screen. For this part, see [ UDM-stdio.txt ].
-
-Therefore the API has two parts, the video driver part and the part where the
-video driver core registers with STDIO API.
-
-The video driver part will follow the current cfb_console approach, though
-allowing it to be more dynamic.
-
-II) Approach
-------------
-
-Registering the video driver into the video driver core is done by calling the
-following function from the driver probe() function:
-
- video_device_register(struct instance *i, GraphicDevice *gd);
-
-Because the video driver core is in charge or rendering characters as well as
-bitmaps on the screen, it will in turn call stdio_device_register(i, so), where
-"i" is the same instance as the video driver's one. But "so" will be special
-static struct stdio_device_ops handling the character output.
-
-
-III) Analysis of in-tree drivers
---------------------------------
-
- arch/powerpc/cpu/mpc8xx/video.c
- -------------------------------
- This driver copies the cfb_console [ see drivers/video/cfb_console.c ]
- approach and acts only as a STDIO device. Therefore there are currently two
- possible approaches, first being the conversion of this driver to usual STDIO
- device and second, long-term one, being conversion of this driver to video
- driver that provides console.
-
- arch/x86/lib/video.c
- --------------------
- This driver registers two separate STDIO devices and should be therefore
- converted as such.
-
- board/bf527-ezkit/video.c
- -------------------------
- This driver seems bogus as it behaves as STDIO device, but provides no input
- or output capabilities. It relies on DEV_EXT_VIDEO, which is no longer in use
- or present otherwise than as a dead code/define.
-
- board/bf533-stamp/video.c
- -------------------------
- This driver seems bogus as it behaves as STDIO device, but provides no input
- or output capabilities. It relies on DEV_EXT_VIDEO, which is no longer in use
- or present otherwise than as a dead code/define.
-
- board/bf548-ezkit/video.c
- -------------------------
- This driver seems bogus as it behaves as STDIO device, but provides no input
- or output capabilities. It relies on DEV_EXT_VIDEO, which is no longer in use
- or present otherwise than as a dead code/define.
-
- board/cm-bf548/video.c
- ----------------------
- This driver seems bogus as it behaves as STDIO device, but provides no input
- or output capabilities. It relies on DEV_EXT_VIDEO, which is no longer in use
- or present otherwise than as a dead code/define.
diff --git a/doc/driver-model/UDM-watchdog.txt b/doc/driver-model/UDM-watchdog.txt
deleted file mode 100644
index 3f130635dc..0000000000
--- a/doc/driver-model/UDM-watchdog.txt
+++ /dev/null
@@ -1,329 +0,0 @@
-The U-Boot Driver Model Project
-===============================
-Watchdog device subsystem analysis
-==================================
-
-Tomas Hlavacek <tmshlvck@gmail.com>
-2012-03-09
-
-I) Overview
------------
-
-U-Boot currently implements an API for HW watchdog devices as explicit drivers
-in drivers/watchdog directory. There are also drivers for both hardware and
-software watchdog on particular CPUs implemented in arch/*/cpu/*/cpu.c. There
-are macros in include/watchdog.h that selects between SW and HW watchdog and
-assembly SW implementation.
-
-The current common interface comprises of one set out of these two possible
-variants:
-
- 1)
- void watchdog_reset(void);
- int watchdog_disable(void);
- int watchdog_init(void);
-
- 2)
- void hw_watchdog_reset(void);
- void hw_watchdog_init(void);
-
-The watchdog implementations are also spread through board/*/*.c that in
-some cases. The API and semantics is in most cases same as the above
-mentioned common functions.
-
-
-II) Approach
-------------
-
- 1) New API
- ----------
-
- In the UDM each watchdog driver would register itself by a function
-
- int watchdog_device_register(struct instance *i,
- const struct watchdog_device_ops *o);
-
- The structure being defined as follows:
-
- struct watchdog_device_ops {
- int (*disable)(struct instance *i);
- void (*reset)(struct instance *i);
- };
-
- The watchdog_init() function will be dissolved into probe() function.
-
- 2) Conversion thougths
- ----------------------
-
- Conversion of watchdog implementations to a new API could be divided
- to three subsections: a) HW implementations, which are mostly compliant
- to the above mentioned API; b) SW implementations, which are compliant
- to the above mentioned API and c) SW implementations that are not compliant
- to the API and has to be rectified or partially rewritten.
-
-III) Analysis of in-tree drivers
---------------------------------
-
- drivers/watchdog/at91sam9_wdt.c
- -------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- drivers/watchdog/ftwdt010_wdt.c
- -------------------------------
- The driver is ad-hoc HW watchdog. Conversion has to take into account
- driver parts spread in include/faraday/*. Restructuring the driver and
- code cleanup has to be considered.
-
-
- arch/arm/cpu/arm1136/mx31/timer.c
- ---------------------------------
- The driver is semi-standard ad-hoc HW watchdog. Conversion has to take
- into account driver parts spread in the timer.c file.
-
-
- arch/arm/cpu/arm926ejs/davinci/timer.c
- --------------------------------------
- The driver is ad-hoc semi-standard HW watchdog. Conversion has to take
- into account driver parts spread in the timer.c file.
-
-
- arch/arm/cpu/armv7/omap-common/hwinit-common.c
- ----------------------------------------------
- The driver is non-standard ad-hoc HW watchdog. Conversion is possible
- but functions has to be renamed and constants moved to another places.
-
-
- arch/arm/cpu/armv7/omap3/board.c
- --------------------------------
- The driver is non-standard ad-hoc HW watchdog. Conversion is possible
- but functions has to be renamed and constants moved to another places.
-
-
- arch/blackfin/cpu/watchdog.c
- ----------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/m68k/cpu/mcf523x/cpu.c
- ---------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/m68k/cpu/mcf52x2/cpu.c
- ---------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/m68k/cpu/mcf532x/cpu.c
- ---------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/m68k/cpu/mcf547x_8x/cpu.c
- ------------------------------
- The driver is standard HW watchdog (there is slight naming convention
- violation that has to be rectified). Simple conversion is possible.
-
-
- arch/powerpc/cpu/74xx_7xx/cpu.c
- -------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/mpc512x/cpu.c
- ------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/mpc5xx/cpu.c
- -----------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/mpc5xxx/cpu.c
- ------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/mpc8260/cpu.c
- ------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/mpc83xx/cpu.c
- ------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/mpc85xx/cpu.c
- ------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/mpc86xx/cpu.c
- ------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/mpc8xx/cpu.c
- -----------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/powerpc/cpu/ppc4xx/cpu.c
- -----------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/sh/cpu/sh2/watchdog.c
- --------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/sh/cpu/sh3/watchdog.c
- --------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- arch/sh/cpu/sh4/watchdog.c
- --------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/amcc/luan/luan.c
- ----------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/amcc/yosemite/yosemite.c
- ------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/apollon/apollon.c
- -----------------------
- The driver is standard HW watchdog however the watchdog_init()
- function is called in early initialization. Simple conversion is possible.
-
-
- board/bmw/m48t59y.c
- -------------------
- Special watchdog driver. Dead code. To be removed.
-
-
- board/davedenx/qong/qong.c
- --------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/dvlhost/watchdog.c
- ------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/eNET/eNET.c
- -----------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/eltec/elppc/elppc.c
- -------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/enbw/enbw_cmc/enbw_cmc.c
- ------------------------------
- Only function proxy call. Code cleanup needed.
-
-
- board/freescale/mx31pdk/mx31pdk.c
- ---------------------------------
- Only function proxy call. Code cleanup needed.
-
-
- board/gth2/gth2.c
- -----------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/lwmon5/lwmon5.c
- ---------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/manroland/mucmc52/mucmc52.c
- ---------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/manroland/uc101/uc101.c
- -----------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/mousse/m48t59y.c
- ----------------------
- Special watchdog driver. Dead code. To be removed.
-
-
- board/mvblue/mvblue.c
- ---------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/netphone/netphone.c
- -------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/netta/netta.c
- -------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/netta2/netta2.c
- ---------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/omicron/calimain/calimain.c
- ---------------------------------
- Only function proxy call. Code cleanup needed.
-
-
- board/pcs440ep/pcs440ep.c
- -------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/stx/stxxtc/stxxtc.c
- -------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/ti/omap2420h4/omap2420h4.c
- --------------------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/ttcontrol/vision2/vision2.c
- ---------------------------------
- The driver is standard HW watchdog but namespace is polluted by
- non-standard macros. Simple conversion is possible, code cleanup
- needed.
-
-
- board/v38b/v38b.c
- -----------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/ve8313/ve8313.c
- ---------------------
- The driver is standard HW watchdog. Simple conversion is possible.
-
-
- board/w7o/watchdog.c
- --------------------
- The driver is standard HW watchdog. Simple conversion is possible.