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author | Marek Vasut <marek.vasut@gmail.com> | 2012-08-08 01:42:17 +0000 |
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committer | Wolfgang Denk <wd@denx.de> | 2012-09-02 17:55:53 +0200 |
commit | 15c6935b0c8267d0cd70e18a0cf6e31345f50266 (patch) | |
tree | 65df664daf670c2e7d97a9cc409ec825da401b83 | |
parent | c20dbf64a976a40d39694a991d3bf51985cb35f6 (diff) | |
download | u-boot-imx-15c6935b0c8267d0cd70e18a0cf6e31345f50266.zip u-boot-imx-15c6935b0c8267d0cd70e18a0cf6e31345f50266.tar.gz u-boot-imx-15c6935b0c8267d0cd70e18a0cf6e31345f50266.tar.bz2 |
dm: Initial import of design documents
This patch contains UDM-design.txt, which is document containing
general description of the driver model. The remaining files contains
descriptions of conversion process of particular subsystems.
Signed-off-by: Marek Vasut <marek.vasut@gmail.com>
-rw-r--r-- | doc/driver-model/UDM-design.txt | 315 | ||||
-rw-r--r-- | doc/driver-model/UDM-fpga.txt | 115 | ||||
-rw-r--r-- | doc/driver-model/UDM-keyboard.txt | 47 | ||||
-rw-r--r-- | doc/driver-model/UDM-serial.txt | 191 | ||||
-rw-r--r-- | doc/driver-model/UDM-stdio.txt | 191 | ||||
-rw-r--r-- | doc/driver-model/UDM-tpm.txt | 48 | ||||
-rw-r--r-- | doc/driver-model/UDM-usb.txt | 94 | ||||
-rw-r--r-- | doc/driver-model/UDM-video.txt | 74 |
8 files changed, 1075 insertions, 0 deletions
diff --git a/doc/driver-model/UDM-design.txt b/doc/driver-model/UDM-design.txt new file mode 100644 index 0000000..185f477 --- /dev/null +++ b/doc/driver-model/UDM-design.txt @@ -0,0 +1,315 @@ +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 new file mode 100644 index 0000000..4f9df94 --- /dev/null +++ b/doc/driver-model/UDM-fpga.txt @@ -0,0 +1,115 @@ +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-keyboard.txt b/doc/driver-model/UDM-keyboard.txt new file mode 100644 index 0000000..ef3761d --- /dev/null +++ b/doc/driver-model/UDM-keyboard.txt @@ -0,0 +1,47 @@ +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 +-------------------------------- + + 1) 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. + + 2) 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. + + 3) 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-serial.txt b/doc/driver-model/UDM-serial.txt new file mode 100644 index 0000000..e9c274d --- /dev/null +++ b/doc/driver-model/UDM-serial.txt @@ -0,0 +1,191 @@ +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 +-------------------------------- + + 1) altera_jtag_uart.c + --------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 2) altera_uart.c + ---------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 3) 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. + + 4) atmel_usart.c + ---------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 5) mcfuart.c + ------------ + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 6) 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. + + 7) ns9750_serial.c + ------------------ + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 8) opencores_yanu.c + ------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 9) s3c4510b_uart.c + ------------------ + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 10) s3c64xx.c + ------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 11) sandbox.c + ------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 12) serial.c + ------------ + This is a complementary part of NS16550 UART driver, see above. + + 13) serial_clps7111.c + --------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 14) serial_imx.c + ---------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. This driver + might be removed in favor of serial_mxc.c . + + 15) serial_ixp.c + ---------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 16) serial_ks8695.c + ------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 17) serial_lh7a40x.c + -------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 18) serial_lpc2292.c + -------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 19) serial_max3100.c + -------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 20) serial_mxc.c + ---------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 21) serial_netarm.c + ------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 22) serial_pl01x.c + ------------------ + No support for CONFIG_SERIAL_MULTI. Simple conversion possible, though this + driver in fact contains two drivers in total. + + 23) 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. + + 24) serial_s3c24x0.c + -------------------- + This driver, being quite ad-hoc might need some work to bring back to shape. + + 25) serial_s3c44b0.c + -------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 26) serial_s5p.c + ---------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 27) serial_sa1100.c + ------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 28) serial_sh.c + --------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 29) serial_xuartlite.c + ---------------------- + No support for CONFIG_SERIAL_MULTI. Simple conversion possible. + + 30) usbtty.c + ------------ + This driver seems very complicated and entangled with USB framework. The + conversion might be complicated here. + + 31) 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-stdio.txt b/doc/driver-model/UDM-stdio.txt new file mode 100644 index 0000000..a6c484f --- /dev/null +++ b/doc/driver-model/UDM-stdio.txt @@ -0,0 +1,191 @@ +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 ]. + + 1) arch/blackfin/cpu/jtag-console.c + ----------------------------------- + This driver is a classic STDIO driver, no problem with conversion is expected. + + 2) 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. + + 3) board/netphone/phone_console.c + --------------------------------- + This driver is a classic STDIO driver, no problem with conversion is expected. + + 4) 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 new file mode 100644 index 0000000..91a953a --- /dev/null +++ b/doc/driver-model/UDM-tpm.txt @@ -0,0 +1,48 @@ +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-usb.txt b/doc/driver-model/UDM-usb.txt new file mode 100644 index 0000000..5ce85b5 --- /dev/null +++ b/doc/driver-model/UDM-usb.txt @@ -0,0 +1,94 @@ +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 new file mode 100644 index 0000000..342aeee --- /dev/null +++ b/doc/driver-model/UDM-video.txt @@ -0,0 +1,74 @@ +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 +-------------------------------- + + 1) 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. + + 2) arch/x86/lib/video.c + ----------------------- + This driver registers two separate STDIO devices and should be therefore + converted as such. + + 3) 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. + + 4) 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. + + 5) 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. + + 6) 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. |