1 # SPDX-License-Identifier: GPL-2.0+
3 # (C) Copyright 2000 - 2013
4 # Wolfgang Denk, DENX Software Engineering, wd@denx.de.
9 This directory contains the source code for U-Boot, a boot loader for
10 Embedded boards based on PowerPC, ARM, MIPS and several other
11 processors, which can be installed in a boot ROM and used to
12 initialize and test the hardware or to download and run application
15 The development of U-Boot is closely related to Linux: some parts of
16 the source code originate in the Linux source tree, we have some
17 header files in common, and special provision has been made to
18 support booting of Linux images.
20 Some attention has been paid to make this software easily
21 configurable and extendable. For instance, all monitor commands are
22 implemented with the same call interface, so that it's very easy to
23 add new commands. Also, instead of permanently adding rarely used
24 code (for instance hardware test utilities) to the monitor, you can
25 load and run it dynamically.
31 In general, all boards for which a default configuration file exists in the
32 configs/ directory have been tested to some extent and can be considered
33 "working". In fact, many of them are used in production systems.
35 In case of problems you can use
37 scripts/get_maintainer.pl <path>
39 to identify the people or companies responsible for various boards and
40 subsystems. Or have a look at the git log.
46 In case you have questions about, problems with or contributions for
47 U-Boot, you should send a message to the U-Boot mailing list at
48 <u-boot@lists.denx.de>. There is also an archive of previous traffic
49 on the mailing list - please search the archive before asking FAQ's.
50 Please see https://lists.denx.de/pipermail/u-boot and
51 https://marc.info/?l=u-boot
53 Where to get source code:
54 =========================
56 The U-Boot source code is maintained in the Git repository at
57 https://source.denx.de/u-boot/u-boot.git ; you can browse it online at
58 https://source.denx.de/u-boot/u-boot
60 The "Tags" links on this page allow you to download tarballs of
61 any version you might be interested in. Official releases are also
62 available from the DENX file server through HTTPS or FTP.
63 https://ftp.denx.de/pub/u-boot/
64 ftp://ftp.denx.de/pub/u-boot/
70 - start from 8xxrom sources
71 - create PPCBoot project (https://sourceforge.net/projects/ppcboot)
73 - make it easier to add custom boards
74 - make it possible to add other [PowerPC] CPUs
75 - extend functions, especially:
76 * Provide extended interface to Linux boot loader
79 * ATA disk / SCSI ... boot
80 - create ARMBoot project (https://sourceforge.net/projects/armboot)
81 - add other CPU families (starting with ARM)
82 - create U-Boot project (https://sourceforge.net/projects/u-boot)
83 - current project page: see https://www.denx.de/wiki/U-Boot
89 The "official" name of this project is "Das U-Boot". The spelling
90 "U-Boot" shall be used in all written text (documentation, comments
91 in source files etc.). Example:
93 This is the README file for the U-Boot project.
95 File names etc. shall be based on the string "u-boot". Examples:
97 include/asm-ppc/u-boot.h
99 #include <asm/u-boot.h>
101 Variable names, preprocessor constants etc. shall be either based on
102 the string "u_boot" or on "U_BOOT". Example:
104 U_BOOT_VERSION u_boot_logo
105 IH_OS_U_BOOT u_boot_hush_start
108 Software Configuration:
109 =======================
111 Selection of Processor Architecture and Board Type:
112 ---------------------------------------------------
114 For all supported boards there are ready-to-use default
115 configurations available; just type "make <board_name>_defconfig".
117 Example: For a TQM823L module type:
120 make TQM823L_defconfig
122 Note: If you're looking for the default configuration file for a board
123 you're sure used to be there but is now missing, check the file
124 doc/README.scrapyard for a list of no longer supported boards.
129 U-Boot can be built natively to run on a Linux host using the 'sandbox'
130 board. This allows feature development which is not board- or architecture-
131 specific to be undertaken on a native platform. The sandbox is also used to
132 run some of U-Boot's tests.
134 See doc/arch/sandbox/sandbox.rst for more details.
137 Board Initialisation Flow:
138 --------------------------
140 This is the intended start-up flow for boards. This should apply for both
141 SPL and U-Boot proper (i.e. they both follow the same rules).
143 Note: "SPL" stands for "Secondary Program Loader," which is explained in
144 more detail later in this file.
146 At present, SPL mostly uses a separate code path, but the function names
147 and roles of each function are the same. Some boards or architectures
148 may not conform to this. At least most ARM boards which use
149 CONFIG_SPL_FRAMEWORK conform to this.
151 Execution typically starts with an architecture-specific (and possibly
152 CPU-specific) start.S file, such as:
154 - arch/arm/cpu/armv7/start.S
155 - arch/powerpc/cpu/mpc83xx/start.S
156 - arch/mips/cpu/start.S
158 and so on. From there, three functions are called; the purpose and
159 limitations of each of these functions are described below.
162 - purpose: essential init to permit execution to reach board_init_f()
163 - no global_data or BSS
164 - there is no stack (ARMv7 may have one but it will soon be removed)
165 - must not set up SDRAM or use console
166 - must only do the bare minimum to allow execution to continue to
168 - this is almost never needed
169 - return normally from this function
172 - purpose: set up the machine ready for running board_init_r():
173 i.e. SDRAM and serial UART
174 - global_data is available
176 - BSS is not available, so you cannot use global/static variables,
177 only stack variables and global_data
179 Non-SPL-specific notes:
180 - dram_init() is called to set up DRAM. If already done in SPL this
184 - you can override the entire board_init_f() function with your own
186 - preloader_console_init() can be called here in extremis
187 - should set up SDRAM, and anything needed to make the UART work
188 - there is no need to clear BSS, it will be done by crt0.S
189 - for specific scenarios on certain architectures an early BSS *can*
190 be made available (via CONFIG_SPL_EARLY_BSS by moving the clearing
191 of BSS prior to entering board_init_f()) but doing so is discouraged.
192 Instead it is strongly recommended to architect any code changes
193 or additions such to not depend on the availability of BSS during
194 board_init_f() as indicated in other sections of this README to
195 maintain compatibility and consistency across the entire code base.
196 - must return normally from this function (don't call board_init_r()
199 Here the BSS is cleared. For SPL, if CONFIG_SPL_STACK_R is defined, then at
200 this point the stack and global_data are relocated to below
201 CONFIG_SPL_STACK_R_ADDR. For non-SPL, U-Boot is relocated to run at the top of
205 - purpose: main execution, common code
206 - global_data is available
208 - BSS is available, all static/global variables can be used
209 - execution eventually continues to main_loop()
211 Non-SPL-specific notes:
212 - U-Boot is relocated to the top of memory and is now running from
216 - stack is optionally in SDRAM, if CONFIG_SPL_STACK_R is defined and
217 CONFIG_SYS_FSL_HAS_CCI400
219 Defined For SoC that has cache coherent interconnect
222 CONFIG_SYS_FSL_HAS_CCN504
224 Defined for SoC that has cache coherent interconnect CCN-504
226 The following options need to be configured:
228 - CPU Type: Define exactly one, e.g. CONFIG_MPC85XX.
230 - Board Type: Define exactly one, e.g. CONFIG_MPC8540ADS.
235 Specifies that the core is a 64-bit PowerPC implementation (implements
236 the "64" category of the Power ISA). This is necessary for ePAPR
237 compliance, among other possible reasons.
239 CONFIG_SYS_FSL_ERRATUM_A004510
241 Enables a workaround for erratum A004510. If set,
242 then CONFIG_SYS_FSL_ERRATUM_A004510_SVR_REV and
243 CFG_SYS_FSL_CORENET_SNOOPVEC_COREONLY must be set.
245 CONFIG_SYS_FSL_ERRATUM_A004510_SVR_REV
246 CONFIG_SYS_FSL_ERRATUM_A004510_SVR_REV2 (optional)
248 Defines one or two SoC revisions (low 8 bits of SVR)
249 for which the A004510 workaround should be applied.
251 The rest of SVR is either not relevant to the decision
252 of whether the erratum is present (e.g. p2040 versus
253 p2041) or is implied by the build target, which controls
254 whether CONFIG_SYS_FSL_ERRATUM_A004510 is set.
256 See Freescale App Note 4493 for more information about
259 CFG_SYS_FSL_CORENET_SNOOPVEC_COREONLY
261 This is the value to write into CCSR offset 0x18600
262 according to the A004510 workaround.
264 CONFIG_SYS_FSL_SINGLE_SOURCE_CLK
265 Single Source Clock is clocking mode present in some of FSL SoC's.
266 In this mode, a single differential clock is used to supply
267 clocks to the sysclock, ddrclock and usbclock.
269 - Generic CPU options:
272 Freescale DDR driver in use. This type of DDR controller is
273 found in mpc83xx, mpc85xx as well as some ARM core SoCs.
276 Freescale DDR memory-mapped register base.
278 CONFIG_SYS_FSL_IFC_CLK_DIV
279 Defines divider of platform clock(clock input to IFC controller).
281 CONFIG_SYS_FSL_LBC_CLK_DIV
282 Defines divider of platform clock(clock input to eLBC controller).
284 CFG_SYS_FSL_DDR_SDRAM_BASE_PHY
285 Physical address from the view of DDR controllers. It is the
286 same as CFG_SYS_DDR_SDRAM_BASE for all Power SoCs. But
287 it could be different for ARM SoCs.
290 CFG_SYS_EXCEPTION_VECTORS_HIGH
292 Select high exception vectors of the ARM core, e.g., do not
293 clear the V bit of the c1 register of CP15.
296 Generic timer clock source frequency.
298 COUNTER_FREQUENCY_REAL
299 Generic timer clock source frequency if the real clock is
300 different from COUNTER_FREQUENCY, and can only be determined
304 CONFIG_TEGRA_SUPPORT_NON_SECURE
306 Support executing U-Boot in non-secure (NS) mode. Certain
307 impossible actions will be skipped if the CPU is in NS mode,
308 such as ARM architectural timer initialization.
310 - Linux Kernel Interface:
313 New kernel versions are expecting firmware settings to be
314 passed using flattened device trees (based on open firmware
318 * New libfdt-based support
319 * Adds the "fdt" command
320 * The bootm command automatically updates the fdt
322 OF_TBCLK - The timebase frequency.
324 boards with QUICC Engines require OF_QE to set UCC MAC
329 U-Boot can detect if an IDE device is present or not.
330 If not, and this new config option is activated, U-Boot
331 removes the ATA node from the DTS before booting Linux,
332 so the Linux IDE driver does not probe the device and
333 crash. This is needed for buggy hardware (uc101) where
334 no pull down resistor is connected to the signal IDE5V_DD7.
336 - vxWorks boot parameters:
338 bootvx constructs a valid bootline using the following
339 environments variables: bootdev, bootfile, ipaddr, netmask,
340 serverip, gatewayip, hostname, othbootargs.
341 It loads the vxWorks image pointed bootfile.
343 Note: If a "bootargs" environment is defined, it will override
344 the defaults discussed just above.
346 - Cache Configuration for ARM:
347 CFG_SYS_PL310_BASE - Physical base address of PL310
348 controller register space
353 If you have Amba PrimeCell PL011 UARTs, set this variable to
354 the clock speed of the UARTs.
358 If you have Amba PrimeCell PL010 or PL011 UARTs on your board,
359 define this to a list of base addresses for each (supported)
360 port. See e.g. include/configs/versatile.h
362 CONFIG_SERIAL_HW_FLOW_CONTROL
364 Define this variable to enable hw flow control in serial driver.
365 Current user of this option is drivers/serial/nsl16550.c driver
367 - Removal of commands
368 If no commands are needed to boot, you can disable
369 CONFIG_CMDLINE to remove them. In this case, the command line
370 will not be available, and when U-Boot wants to execute the
371 boot command (on start-up) it will call board_run_command()
372 instead. This can reduce image size significantly for very
373 simple boot procedures.
375 - Regular expression support:
377 If this variable is defined, U-Boot is linked against
378 the SLRE (Super Light Regular Expression) library,
379 which adds regex support to some commands, as for
380 example "env grep" and "setexpr".
383 CFG_SYS_WATCHDOG_FREQ
384 Some platforms automatically call WATCHDOG_RESET()
385 from the timer interrupt handler every
386 CFG_SYS_WATCHDOG_FREQ interrupts. If not set by the
387 board configuration file, a default of CONFIG_SYS_HZ/2
388 (i.e. 500) is used. Setting CFG_SYS_WATCHDOG_FREQ
389 to 0 disables calling WATCHDOG_RESET() from the timer
393 The CFG_SYS_I2C_PCA953X_WIDTH option specifies a list of
394 chip-ngpio pairs that tell the PCA953X driver the number of
395 pins supported by a particular chip.
397 Note that if the GPIO device uses I2C, then the I2C interface
398 must also be configured. See I2C Support, below.
401 When CONFIG_IO_TRACE is selected, U-Boot intercepts all I/O
402 accesses and can checksum them or write a list of them out
403 to memory. See the 'iotrace' command for details. This is
404 useful for testing device drivers since it can confirm that
405 the driver behaves the same way before and after a code
406 change. Currently this is supported on sandbox and arm. To
407 add support for your architecture, add '#include <iotrace.h>'
408 to the bottom of arch/<arch>/include/asm/io.h and test.
410 Example output from the 'iotrace stats' command is below.
411 Note that if the trace buffer is exhausted, the checksum will
412 still continue to operate.
415 Start: 10000000 (buffer start address)
416 Size: 00010000 (buffer size)
417 Offset: 00000120 (current buffer offset)
418 Output: 10000120 (start + offset)
419 Count: 00000018 (number of trace records)
420 CRC32: 9526fb66 (CRC32 of all trace records)
424 When CONFIG_TIMESTAMP is selected, the timestamp
425 (date and time) of an image is printed by image
426 commands like bootm or iminfo. This option is
427 automatically enabled when you select CONFIG_CMD_DATE .
429 - Partition Labels (disklabels) Supported:
430 Zero or more of the following:
431 CONFIG_MAC_PARTITION Apple's MacOS partition table.
432 CONFIG_ISO_PARTITION ISO partition table, used on CDROM etc.
433 CONFIG_EFI_PARTITION GPT partition table, common when EFI is the
434 bootloader. Note 2TB partition limit; see
436 CONFIG_SCSI) you must configure support for at
437 least one non-MTD partition type as well.
439 - NETWORK Support (PCI):
441 Utility code for direct access to the SPI bus on Intel 8257x.
442 This does not do anything useful unless you set at least one
443 of CONFIG_CMD_E1000 or CONFIG_E1000_SPI_GENERIC.
446 Support for National dp83815 chips.
449 Support for National dp8382[01] gigabit chips.
451 - NETWORK Support (other):
453 Support for the Calxeda XGMAC device
456 Support for SMSC's LAN91C96 chips.
458 CONFIG_LAN91C96_USE_32_BIT
459 Define this to enable 32 bit addressing
461 CFG_SYS_DAVINCI_EMAC_PHY_COUNT
462 Define this if you have more then 3 PHYs.
465 Support for Faraday's FTGMAC100 Gigabit SoC Ethernet
467 CONFIG_FTGMAC100_EGIGA
468 Define this to use GE link update with gigabit PHY.
469 Define this if FTGMAC100 is connected to gigabit PHY.
470 If your system has 10/100 PHY only, it might not occur
471 wrong behavior. Because PHY usually return timeout or
472 useless data when polling gigabit status and gigabit
473 control registers. This behavior won't affect the
474 correctnessof 10/100 link speed update.
477 Support for Renesas on-chip Ethernet controller
479 CFG_SH_ETHER_USE_PORT
480 Define the number of ports to be used
482 CFG_SH_ETHER_PHY_ADDR
483 Define the ETH PHY's address
485 CFG_SH_ETHER_CACHE_WRITEBACK
486 If this option is set, the driver enables cache flush.
492 CONFIG_TPM_TIS_INFINEON
493 Support for Infineon i2c bus TPM devices. Only one device
494 per system is supported at this time.
496 CONFIG_TPM_TIS_I2C_BURST_LIMITATION
497 Define the burst count bytes upper limit
500 Support for STMicroelectronics TPM devices. Requires DM_TPM support.
502 CONFIG_TPM_ST33ZP24_I2C
503 Support for STMicroelectronics ST33ZP24 I2C devices.
504 Requires TPM_ST33ZP24 and I2C.
506 CONFIG_TPM_ST33ZP24_SPI
507 Support for STMicroelectronics ST33ZP24 SPI devices.
508 Requires TPM_ST33ZP24 and SPI.
511 Support for Atmel TWI TPM device. Requires I2C support.
514 Support for generic parallel port TPM devices. Only one device
515 per system is supported at this time.
518 Define this to enable the TPM support library which provides
519 functional interfaces to some TPM commands.
520 Requires support for a TPM device.
522 CONFIG_TPM_AUTH_SESSIONS
523 Define this to enable authorized functions in the TPM library.
524 Requires CONFIG_TPM and CONFIG_SHA1.
527 At the moment only the UHCI host controller is
528 supported (PIP405, MIP405); define
529 CONFIG_USB_UHCI to enable it.
530 define CONFIG_USB_KEYBOARD to enable the USB Keyboard
531 and define CONFIG_USB_STORAGE to enable the USB
534 Supported are USB Keyboards and USB Floppy drives
537 CONFIG_USB_DWC2_REG_ADDR the physical CPU address of the DWC2
541 Define the below if you wish to use the USB console.
542 Once firmware is rebuilt from a serial console issue the
543 command "setenv stdin usbtty; setenv stdout usbtty" and
544 attach your USB cable. The Unix command "dmesg" should print
545 it has found a new device. The environment variable usbtty
546 can be set to gserial or cdc_acm to enable your device to
547 appear to a USB host as a Linux gserial device or a
548 Common Device Class Abstract Control Model serial device.
549 If you select usbtty = gserial you should be able to enumerate
551 # modprobe usbserial vendor=0xVendorID product=0xProductID
552 else if using cdc_acm, simply setting the environment
553 variable usbtty to be cdc_acm should suffice. The following
554 might be defined in YourBoardName.h
556 If you have a USB-IF assigned VendorID then you may wish to
557 define your own vendor specific values either in BoardName.h
558 or directly in usbd_vendor_info.h. If you don't define
559 CONFIG_USBD_MANUFACTURER, CONFIG_USBD_PRODUCT_NAME,
560 CONFIG_USBD_VENDORID and CONFIG_USBD_PRODUCTID, then U-Boot
561 should pretend to be a Linux device to it's target host.
563 CONFIG_USBD_MANUFACTURER
564 Define this string as the name of your company for
565 - CONFIG_USBD_MANUFACTURER "my company"
567 CONFIG_USBD_PRODUCT_NAME
568 Define this string as the name of your product
569 - CONFIG_USBD_PRODUCT_NAME "acme usb device"
572 Define this as your assigned Vendor ID from the USB
573 Implementors Forum. This *must* be a genuine Vendor ID
574 to avoid polluting the USB namespace.
575 - CONFIG_USBD_VENDORID 0xFFFF
577 CONFIG_USBD_PRODUCTID
578 Define this as the unique Product ID
580 - CONFIG_USBD_PRODUCTID 0xFFFF
582 - ULPI Layer Support:
583 The ULPI (UTMI Low Pin (count) Interface) PHYs are supported via
584 the generic ULPI layer. The generic layer accesses the ULPI PHY
585 via the platform viewport, so you need both the genric layer and
586 the viewport enabled. Currently only Chipidea/ARC based
587 viewport is supported.
588 To enable the ULPI layer support, define CONFIG_USB_ULPI and
589 CONFIG_USB_ULPI_VIEWPORT in your board configuration file.
590 If your ULPI phy needs a different reference clock than the
591 standard 24 MHz then you have to define CFG_ULPI_REF_CLK to
592 the appropriate value in Hz.
596 Support for Renesas on-chip MMCIF controller
599 Define the base address of MMCIF registers
602 Define the clock frequency for MMCIF
604 - USB Device Firmware Update (DFU) class support:
606 This enables the USB portion of the DFU USB class
609 This enables support for exposing NAND devices via DFU.
612 This enables support for exposing RAM via DFU.
613 Note: DFU spec refer to non-volatile memory usage, but
614 allow usages beyond the scope of spec - here RAM usage,
615 one that would help mostly the developer.
617 CONFIG_SYS_DFU_DATA_BUF_SIZE
618 Dfu transfer uses a buffer before writing data to the
619 raw storage device. Make the size (in bytes) of this buffer
620 configurable. The size of this buffer is also configurable
621 through the "dfu_bufsiz" environment variable.
623 CONFIG_SYS_DFU_MAX_FILE_SIZE
624 When updating files rather than the raw storage device,
625 we use a static buffer to copy the file into and then write
626 the buffer once we've been given the whole file. Define
627 this to the maximum filesize (in bytes) for the buffer.
628 Default is 4 MiB if undefined.
630 DFU_DEFAULT_POLL_TIMEOUT
631 Poll timeout [ms], is the timeout a device can send to the
632 host. The host must wait for this timeout before sending
633 a subsequent DFU_GET_STATUS request to the device.
635 DFU_MANIFEST_POLL_TIMEOUT
636 Poll timeout [ms], which the device sends to the host when
637 entering dfuMANIFEST state. Host waits this timeout, before
638 sending again an USB request to the device.
641 See Kconfig help for available keyboard drivers.
644 CONFIG_PHY_CLOCK_FREQ (ppc4xx)
646 The clock frequency of the MII bus
648 CONFIG_PHY_CMD_DELAY (ppc4xx)
650 Some PHY like Intel LXT971A need extra delay after
651 command issued before MII status register can be read
653 - BOOTP Recovery Mode:
654 CONFIG_BOOTP_RANDOM_DELAY
656 If you have many targets in a network that try to
657 boot using BOOTP, you may want to avoid that all
658 systems send out BOOTP requests at precisely the same
659 moment (which would happen for instance at recovery
660 from a power failure, when all systems will try to
661 boot, thus flooding the BOOTP server. Defining
662 CONFIG_BOOTP_RANDOM_DELAY causes a random delay to be
663 inserted before sending out BOOTP requests. The
664 following delays are inserted then:
666 1st BOOTP request: delay 0 ... 1 sec
667 2nd BOOTP request: delay 0 ... 2 sec
668 3rd BOOTP request: delay 0 ... 4 sec
670 BOOTP requests: delay 0 ... 8 sec
672 CFG_BOOTP_ID_CACHE_SIZE
674 BOOTP packets are uniquely identified using a 32-bit ID. The
675 server will copy the ID from client requests to responses and
676 U-Boot will use this to determine if it is the destination of
677 an incoming response. Some servers will check that addresses
678 aren't in use before handing them out (usually using an ARP
679 ping) and therefore take up to a few hundred milliseconds to
680 respond. Network congestion may also influence the time it
681 takes for a response to make it back to the client. If that
682 time is too long, U-Boot will retransmit requests. In order
683 to allow earlier responses to still be accepted after these
684 retransmissions, U-Boot's BOOTP client keeps a small cache of
685 IDs. The CFG_BOOTP_ID_CACHE_SIZE controls the size of this
686 cache. The default is to keep IDs for up to four outstanding
687 requests. Increasing this will allow U-Boot to accept offers
688 from a BOOTP client in networks with unusually high latency.
690 - DHCP Advanced Options:
692 - Link-local IP address negotiation:
693 Negotiate with other link-local clients on the local network
694 for an address that doesn't require explicit configuration.
695 This is especially useful if a DHCP server cannot be guaranteed
696 to exist in all environments that the device must operate.
698 See doc/README.link-local for more information.
700 - MAC address from environment variables
702 FDT_SEQ_MACADDR_FROM_ENV
704 Fix-up device tree with MAC addresses fetched sequentially from
705 environment variables. This config work on assumption that
706 non-usable ethernet node of device-tree are either not present
707 or their status has been marked as "disabled".
712 The device id used in CDP trigger frames.
714 CONFIG_CDP_DEVICE_ID_PREFIX
716 A two character string which is prefixed to the MAC address
721 A printf format string which contains the ascii name of
722 the port. Normally is set to "eth%d" which sets
723 eth0 for the first Ethernet, eth1 for the second etc.
725 CONFIG_CDP_CAPABILITIES
727 A 32bit integer which indicates the device capabilities;
728 0x00000010 for a normal host which does not forwards.
732 An ascii string containing the version of the software.
736 An ascii string containing the name of the platform.
740 A 32bit integer sent on the trigger.
742 CONFIG_CDP_POWER_CONSUMPTION
744 A 16bit integer containing the power consumption of the
745 device in .1 of milliwatts.
747 CONFIG_CDP_APPLIANCE_VLAN_TYPE
749 A byte containing the id of the VLAN.
751 - Status LED: CONFIG_LED_STATUS
753 Several configurations allow to display the current
754 status using a LED. For instance, the LED will blink
755 fast while running U-Boot code, stop blinking as
756 soon as a reply to a BOOTP request was received, and
757 start blinking slow once the Linux kernel is running
758 (supported by a status LED driver in the Linux
759 kernel). Defining CONFIG_LED_STATUS enables this
764 CONFIG_LED_STATUS_GPIO
765 The status LED can be connected to a GPIO pin.
766 In such cases, the gpio_led driver can be used as a
767 status LED backend implementation. Define CONFIG_LED_STATUS_GPIO
768 to include the gpio_led driver in the U-Boot binary.
770 CFG_GPIO_LED_INVERTED_TABLE
771 Some GPIO connected LEDs may have inverted polarity in which
772 case the GPIO high value corresponds to LED off state and
773 GPIO low value corresponds to LED on state.
774 In such cases CFG_GPIO_LED_INVERTED_TABLE may be defined
775 with a list of GPIO LEDs that have inverted polarity.
778 CFG_SYS_NUM_I2C_BUSES
779 Hold the number of i2c buses you want to use.
781 CFG_SYS_I2C_DIRECT_BUS
782 define this, if you don't use i2c muxes on your hardware.
783 if CFG_SYS_I2C_MAX_HOPS is not defined or == 0 you can
787 define how many muxes are maximal consecutively connected
788 on one i2c bus. If you not use i2c muxes, omit this
792 hold a list of buses you want to use, only used if
793 CFG_SYS_I2C_DIRECT_BUS is not defined, for example
794 a board with CFG_SYS_I2C_MAX_HOPS = 1 and
795 CFG_SYS_NUM_I2C_BUSES = 9:
797 CFG_SYS_I2C_BUSES {{0, {I2C_NULL_HOP}}, \
798 {0, {{I2C_MUX_PCA9547, 0x70, 1}}}, \
799 {0, {{I2C_MUX_PCA9547, 0x70, 2}}}, \
800 {0, {{I2C_MUX_PCA9547, 0x70, 3}}}, \
801 {0, {{I2C_MUX_PCA9547, 0x70, 4}}}, \
802 {0, {{I2C_MUX_PCA9547, 0x70, 5}}}, \
803 {1, {I2C_NULL_HOP}}, \
804 {1, {{I2C_MUX_PCA9544, 0x72, 1}}}, \
805 {1, {{I2C_MUX_PCA9544, 0x72, 2}}}, \
809 bus 0 on adapter 0 without a mux
810 bus 1 on adapter 0 with a PCA9547 on address 0x70 port 1
811 bus 2 on adapter 0 with a PCA9547 on address 0x70 port 2
812 bus 3 on adapter 0 with a PCA9547 on address 0x70 port 3
813 bus 4 on adapter 0 with a PCA9547 on address 0x70 port 4
814 bus 5 on adapter 0 with a PCA9547 on address 0x70 port 5
815 bus 6 on adapter 1 without a mux
816 bus 7 on adapter 1 with a PCA9544 on address 0x72 port 1
817 bus 8 on adapter 1 with a PCA9544 on address 0x72 port 2
819 If you do not have i2c muxes on your board, omit this define.
821 - Legacy I2C Support:
822 If you use the software i2c interface (CONFIG_SYS_I2C_SOFT)
823 then the following macros need to be defined (examples are
824 from include/configs/lwmon.h):
828 (Optional). Any commands necessary to enable the I2C
829 controller or configure ports.
831 eg: #define I2C_INIT (immr->im_cpm.cp_pbdir |= PB_SCL)
835 The code necessary to make the I2C data line active
836 (driven). If the data line is open collector, this
839 eg: #define I2C_ACTIVE (immr->im_cpm.cp_pbdir |= PB_SDA)
843 The code necessary to make the I2C data line tri-stated
844 (inactive). If the data line is open collector, this
847 eg: #define I2C_TRISTATE (immr->im_cpm.cp_pbdir &= ~PB_SDA)
851 Code that returns true if the I2C data line is high,
854 eg: #define I2C_READ ((immr->im_cpm.cp_pbdat & PB_SDA) != 0)
858 If <bit> is true, sets the I2C data line high. If it
859 is false, it clears it (low).
861 eg: #define I2C_SDA(bit) \
862 if(bit) immr->im_cpm.cp_pbdat |= PB_SDA; \
863 else immr->im_cpm.cp_pbdat &= ~PB_SDA
867 If <bit> is true, sets the I2C clock line high. If it
868 is false, it clears it (low).
870 eg: #define I2C_SCL(bit) \
871 if(bit) immr->im_cpm.cp_pbdat |= PB_SCL; \
872 else immr->im_cpm.cp_pbdat &= ~PB_SCL
876 This delay is invoked four times per clock cycle so this
877 controls the rate of data transfer. The data rate thus
878 is 1 / (I2C_DELAY * 4). Often defined to be something
881 #define I2C_DELAY udelay(2)
883 CONFIG_SOFT_I2C_GPIO_SCL / CONFIG_SOFT_I2C_GPIO_SDA
885 If your arch supports the generic GPIO framework (asm/gpio.h),
886 then you may alternatively define the two GPIOs that are to be
887 used as SCL / SDA. Any of the previous I2C_xxx macros will
888 have GPIO-based defaults assigned to them as appropriate.
890 You should define these to the GPIO value as given directly to
891 the generic GPIO functions.
895 This option allows the use of multiple I2C buses, each of which
896 must have a controller. At any point in time, only one bus is
897 active. To switch to a different bus, use the 'i2c dev' command.
898 Note that bus numbering is zero-based.
902 This option specifies a list of I2C devices that will be skipped
903 when the 'i2c probe' command is issued.
906 #define CFG_SYS_I2C_NOPROBES {0x50,0x68}
908 will skip addresses 0x50 and 0x68 on a board with one I2C bus
912 If defined, then this indicates the I2C bus number for the RTC.
913 If not defined, then U-Boot assumes that RTC is on I2C bus 0.
915 CONFIG_SOFT_I2C_READ_REPEATED_START
917 defining this will force the i2c_read() function in
918 the soft_i2c driver to perform an I2C repeated start
919 between writing the address pointer and reading the
920 data. If this define is omitted the default behaviour
921 of doing a stop-start sequence will be used. Most I2C
922 devices can use either method, but some require one or
925 - SPI Support: CONFIG_SPI
927 Enables SPI driver (so far only tested with
928 SPI EEPROM, also an instance works with Crystal A/D and
929 D/As on the SACSng board)
932 Timeout for waiting until spi transfer completed.
933 default: (CONFIG_SYS_HZ/100) /* 10 ms */
935 - FPGA Support: CONFIG_FPGA
937 Enables FPGA subsystem.
941 Enables support for specific chip vendors.
946 Enables support for FPGA family.
947 (SPARTAN2, SPARTAN3, VIRTEX2, CYCLONE2, ACEX1K, ACEX)
949 CONFIG_SYS_FPGA_CHECK_BUSY
951 Enable checks on FPGA configuration interface busy
952 status by the configuration function. This option
953 will require a board or device specific function to
958 If defined, a function that provides delays in the FPGA
959 configuration driver.
961 CFG_SYS_FPGA_CHECK_ERROR
963 Check for configuration errors during FPGA bitfile
964 loading. For example, abort during Virtex II
965 configuration if the INIT_B line goes low (which
966 indicated a CRC error).
968 CFG_SYS_FPGA_WAIT_INIT
970 Maximum time to wait for the INIT_B line to de-assert
971 after PROB_B has been de-asserted during a Virtex II
972 FPGA configuration sequence. The default time is 500
975 CFG_SYS_FPGA_WAIT_BUSY
977 Maximum time to wait for BUSY to de-assert during
978 Virtex II FPGA configuration. The default is 5 ms.
980 CFG_SYS_FPGA_WAIT_CONFIG
982 Time to wait after FPGA configuration. The default is
985 - Vendor Parameter Protection:
987 U-Boot considers the values of the environment
988 variables "serial#" (Board Serial Number) and
989 "ethaddr" (Ethernet Address) to be parameters that
990 are set once by the board vendor / manufacturer, and
991 protects these variables from casual modification by
992 the user. Once set, these variables are read-only,
993 and write or delete attempts are rejected. You can
994 change this behaviour:
996 If CONFIG_ENV_OVERWRITE is #defined in your config
997 file, the write protection for vendor parameters is
998 completely disabled. Anybody can change or delete
1001 The same can be accomplished in a more flexible way
1002 for any variable by configuring the type of access
1003 to allow for those variables in the ".flags" variable
1004 or define CFG_ENV_FLAGS_LIST_STATIC.
1009 Define this variable to enable the reservation of
1010 "protected RAM", i. e. RAM which is not overwritten
1011 by U-Boot. Define CFG_PRAM to hold the number of
1012 kB you want to reserve for pRAM. You can overwrite
1013 this default value by defining an environment
1014 variable "pram" to the number of kB you want to
1015 reserve. Note that the board info structure will
1016 still show the full amount of RAM. If pRAM is
1017 reserved, a new environment variable "mem" will
1018 automatically be defined to hold the amount of
1019 remaining RAM in a form that can be passed as boot
1020 argument to Linux, for instance like that:
1022 setenv bootargs ... mem=\${mem}
1025 This way you can tell Linux not to use this memory,
1026 either, which results in a memory region that will
1027 not be affected by reboots.
1029 *WARNING* If your board configuration uses automatic
1030 detection of the RAM size, you must make sure that
1031 this memory test is non-destructive. So far, the
1032 following board configurations are known to be
1035 IVMS8, IVML24, SPD8xx,
1036 HERMES, IP860, RPXlite, LWMON,
1042 In the current implementation, the local variables
1043 space and global environment variables space are
1044 separated. Local variables are those you define by
1045 simply typing `name=value'. To access a local
1046 variable later on, you have write `$name' or
1047 `${name}'; to execute the contents of a variable
1048 directly type `$name' at the command prompt.
1050 Global environment variables are those you use
1051 setenv/printenv to work with. To run a command stored
1052 in such a variable, you need to use the run command,
1053 and you must not use the '$' sign to access them.
1055 To store commands and special characters in a
1056 variable, please use double quotation marks
1057 surrounding the whole text of the variable, instead
1058 of the backslashes before semicolons and special
1061 - Default Environment:
1062 CFG_EXTRA_ENV_SETTINGS
1064 Define this to contain any number of null terminated
1065 strings (variable = value pairs) that will be part of
1066 the default environment compiled into the boot image.
1068 For example, place something like this in your
1069 board's config file:
1071 #define CFG_EXTRA_ENV_SETTINGS \
1075 Warning: This method is based on knowledge about the
1076 internal format how the environment is stored by the
1077 U-Boot code. This is NOT an official, exported
1078 interface! Although it is unlikely that this format
1079 will change soon, there is no guarantee either.
1080 You better know what you are doing here.
1082 Note: overly (ab)use of the default environment is
1083 discouraged. Make sure to check other ways to preset
1084 the environment like the "source" command or the
1087 CONFIG_DELAY_ENVIRONMENT
1089 Normally the environment is loaded when the board is
1090 initialised so that it is available to U-Boot. This inhibits
1091 that so that the environment is not available until
1092 explicitly loaded later by U-Boot code. With CONFIG_OF_CONTROL
1093 this is instead controlled by the value of
1094 /config/load-environment.
1096 - Automatic software updates via TFTP server
1098 CONFIG_UPDATE_TFTP_CNT_MAX
1099 CONFIG_UPDATE_TFTP_MSEC_MAX
1101 These options enable and control the auto-update feature;
1102 for a more detailed description refer to doc/README.update.
1104 - MTD Support (mtdparts command, UBI support)
1105 CONFIG_MTD_UBI_WL_THRESHOLD
1106 This parameter defines the maximum difference between the highest
1107 erase counter value and the lowest erase counter value of eraseblocks
1108 of UBI devices. When this threshold is exceeded, UBI starts performing
1109 wear leveling by means of moving data from eraseblock with low erase
1110 counter to eraseblocks with high erase counter.
1112 The default value should be OK for SLC NAND flashes, NOR flashes and
1113 other flashes which have eraseblock life-cycle 100000 or more.
1114 However, in case of MLC NAND flashes which typically have eraseblock
1115 life-cycle less than 10000, the threshold should be lessened (e.g.,
1116 to 128 or 256, although it does not have to be power of 2).
1120 CONFIG_MTD_UBI_BEB_LIMIT
1121 This option specifies the maximum bad physical eraseblocks UBI
1122 expects on the MTD device (per 1024 eraseblocks). If the
1123 underlying flash does not admit of bad eraseblocks (e.g. NOR
1124 flash), this value is ignored.
1126 NAND datasheets often specify the minimum and maximum NVM
1127 (Number of Valid Blocks) for the flashes' endurance lifetime.
1128 The maximum expected bad eraseblocks per 1024 eraseblocks
1129 then can be calculated as "1024 * (1 - MinNVB / MaxNVB)",
1130 which gives 20 for most NANDs (MaxNVB is basically the total
1131 count of eraseblocks on the chip).
1133 To put it differently, if this value is 20, UBI will try to
1134 reserve about 1.9% of physical eraseblocks for bad blocks
1135 handling. And that will be 1.9% of eraseblocks on the entire
1136 NAND chip, not just the MTD partition UBI attaches. This means
1137 that if you have, say, a NAND flash chip admits maximum 40 bad
1138 eraseblocks, and it is split on two MTD partitions of the same
1139 size, UBI will reserve 40 eraseblocks when attaching a
1144 CONFIG_MTD_UBI_FASTMAP
1145 Fastmap is a mechanism which allows attaching an UBI device
1146 in nearly constant time. Instead of scanning the whole MTD device it
1147 only has to locate a checkpoint (called fastmap) on the device.
1148 The on-flash fastmap contains all information needed to attach
1149 the device. Using fastmap makes only sense on large devices where
1150 attaching by scanning takes long. UBI will not automatically install
1151 a fastmap on old images, but you can set the UBI parameter
1152 CONFIG_MTD_UBI_FASTMAP_AUTOCONVERT to 1 if you want so. Please note
1153 that fastmap-enabled images are still usable with UBI implementations
1154 without fastmap support. On typical flash devices the whole fastmap
1155 fits into one PEB. UBI will reserve PEBs to hold two fastmaps.
1157 CONFIG_MTD_UBI_FASTMAP_AUTOCONVERT
1158 Set this parameter to enable fastmap automatically on images
1162 CONFIG_MTD_UBI_FM_DEBUG
1163 Enable UBI fastmap debug
1168 Enable building of SPL globally.
1170 CONFIG_SPL_PANIC_ON_RAW_IMAGE
1171 When defined, SPL will panic() if the image it has
1172 loaded does not have a signature.
1173 Defining this is useful when code which loads images
1174 in SPL cannot guarantee that absolutely all read errors
1176 An example is the LPC32XX MLC NAND driver, which will
1177 consider that a completely unreadable NAND block is bad,
1178 and thus should be skipped silently.
1180 CONFIG_SPL_DISPLAY_PRINT
1181 For ARM, enable an optional function to print more information
1182 about the running system.
1184 CONFIG_SPL_MPC83XX_WAIT_FOR_NAND
1185 Set this for NAND SPL on PPC mpc83xx targets, so that
1186 start.S waits for the rest of the SPL to load before
1187 continuing (the hardware starts execution after just
1188 loading the first page rather than the full 4K).
1191 Support for a lightweight UBI (fastmap) scanner and
1194 CONFIG_SYS_NAND_5_ADDR_CYCLE, CONFIG_SYS_NAND_PAGE_COUNT,
1195 CONFIG_SYS_NAND_PAGE_SIZE, CONFIG_SYS_NAND_OOBSIZE,
1196 CONFIG_SYS_NAND_BLOCK_SIZE, CONFIG_SYS_NAND_BAD_BLOCK_POS,
1197 CFG_SYS_NAND_ECCPOS, CFG_SYS_NAND_ECCSIZE,
1198 CFG_SYS_NAND_ECCBYTES
1199 Defines the size and behavior of the NAND that SPL uses
1202 CFG_SYS_NAND_U_BOOT_DST
1203 Location in memory to load U-Boot to
1205 CFG_SYS_NAND_U_BOOT_SIZE
1206 Size of image to load
1208 CFG_SYS_NAND_U_BOOT_START
1209 Entry point in loaded image to jump to
1211 CONFIG_SPL_RAM_DEVICE
1212 Support for running image already present in ram, in SPL binary
1214 CONFIG_SPL_FIT_PRINT
1215 Printing information about a FIT image adds quite a bit of
1216 code to SPL. So this is normally disabled in SPL. Use this
1217 option to re-enable it. This will affect the output of the
1218 bootm command when booting a FIT image.
1220 - Interrupt support (PPC):
1222 There are common interrupt_init() and timer_interrupt()
1223 for all PPC archs. interrupt_init() calls interrupt_init_cpu()
1224 for CPU specific initialization. interrupt_init_cpu()
1225 should set decrementer_count to appropriate value. If
1226 CPU resets decrementer automatically after interrupt
1227 (ppc4xx) it should set decrementer_count to zero.
1228 timer_interrupt() calls timer_interrupt_cpu() for CPU
1229 specific handling. If board has watchdog / status_led
1230 / other_activity_monitor it works automatically from
1231 general timer_interrupt().
1234 Board initialization settings:
1235 ------------------------------
1237 During Initialization u-boot calls a number of board specific functions
1238 to allow the preparation of board specific prerequisites, e.g. pin setup
1239 before drivers are initialized. To enable these callbacks the
1240 following configuration macros have to be defined. Currently this is
1241 architecture specific, so please check arch/your_architecture/lib/board.c
1242 typically in board_init_f() and board_init_r().
1244 - CONFIG_BOARD_EARLY_INIT_F: Call board_early_init_f()
1245 - CONFIG_BOARD_EARLY_INIT_R: Call board_early_init_r()
1246 - CONFIG_BOARD_LATE_INIT: Call board_late_init()
1248 Configuration Settings:
1249 -----------------------
1251 - MEM_SUPPORT_64BIT_DATA: Defined automatically if compiled as 64-bit.
1252 Optionally it can be defined to support 64-bit memory commands.
1254 - CONFIG_SYS_LONGHELP: Defined when you want long help messages included;
1255 undefine this when you're short of memory.
1257 - CFG_SYS_HELP_CMD_WIDTH: Defined when you want to override the default
1258 width of the commands listed in the 'help' command output.
1260 - CONFIG_SYS_PROMPT: This is what U-Boot prints on the console to
1261 prompt for user input.
1263 - CFG_SYS_BAUDRATE_TABLE:
1264 List of legal baudrate settings for this board.
1266 - CFG_SYS_MEM_RESERVE_SECURE
1267 Only implemented for ARMv8 for now.
1268 If defined, the size of CFG_SYS_MEM_RESERVE_SECURE memory
1269 is substracted from total RAM and won't be reported to OS.
1270 This memory can be used as secure memory. A variable
1271 gd->arch.secure_ram is used to track the location. In systems
1272 the RAM base is not zero, or RAM is divided into banks,
1273 this variable needs to be recalcuated to get the address.
1275 - CFG_SYS_SDRAM_BASE:
1276 Physical start address of SDRAM. _Must_ be 0 here.
1278 - CFG_SYS_FLASH_BASE:
1279 Physical start address of Flash memory.
1281 - CONFIG_SYS_MALLOC_LEN:
1282 Size of DRAM reserved for malloc() use.
1284 - CONFIG_SYS_MALLOC_F_LEN
1285 Size of the malloc() pool for use before relocation. If
1286 this is defined, then a very simple malloc() implementation
1287 will become available before relocation. The address is just
1288 below the global data, and the stack is moved down to make
1291 This feature allocates regions with increasing addresses
1292 within the region. calloc() is supported, but realloc()
1293 is not available. free() is supported but does nothing.
1294 The memory will be freed (or in fact just forgotten) when
1295 U-Boot relocates itself.
1297 - CONFIG_SYS_MALLOC_SIMPLE
1298 Provides a simple and small malloc() and calloc() for those
1299 boards which do not use the full malloc in SPL (which is
1300 enabled with CONFIG_SYS_SPL_MALLOC).
1302 - CFG_SYS_BOOTMAPSZ:
1303 Maximum size of memory mapped by the startup code of
1304 the Linux kernel; all data that must be processed by
1305 the Linux kernel (bd_info, boot arguments, FDT blob if
1306 used) must be put below this limit, unless "bootm_low"
1307 environment variable is defined and non-zero. In such case
1308 all data for the Linux kernel must be between "bootm_low"
1309 and "bootm_low" + CFG_SYS_BOOTMAPSZ. The environment
1310 variable "bootm_mapsize" will override the value of
1311 CFG_SYS_BOOTMAPSZ. If CFG_SYS_BOOTMAPSZ is undefined,
1312 then the value in "bootm_size" will be used instead.
1314 - CONFIG_SYS_BOOT_GET_CMDLINE:
1315 Enables allocating and saving kernel cmdline in space between
1316 "bootm_low" and "bootm_low" + BOOTMAPSZ.
1318 - CONFIG_SYS_BOOT_GET_KBD:
1319 Enables allocating and saving a kernel copy of the bd_info in
1320 space between "bootm_low" and "bootm_low" + BOOTMAPSZ.
1322 - CONFIG_SYS_FLASH_PROTECTION
1323 If defined, hardware flash sectors protection is used
1324 instead of U-Boot software protection.
1326 - CONFIG_SYS_FLASH_CFI:
1327 Define if the flash driver uses extra elements in the
1328 common flash structure for storing flash geometry.
1330 - CONFIG_FLASH_CFI_DRIVER
1331 This option also enables the building of the cfi_flash driver
1332 in the drivers directory
1334 - CONFIG_FLASH_CFI_MTD
1335 This option enables the building of the cfi_mtd driver
1336 in the drivers directory. The driver exports CFI flash
1339 - CONFIG_SYS_FLASH_USE_BUFFER_WRITE
1340 Use buffered writes to flash.
1342 - CONFIG_ENV_FLAGS_LIST_DEFAULT
1343 - CFG_ENV_FLAGS_LIST_STATIC
1344 Enable validation of the values given to environment variables when
1345 calling env set. Variables can be restricted to only decimal,
1346 hexadecimal, or boolean. If CONFIG_CMD_NET is also defined,
1347 the variables can also be restricted to IP address or MAC address.
1349 The format of the list is:
1350 type_attribute = [s|d|x|b|i|m]
1351 access_attribute = [a|r|o|c]
1352 attributes = type_attribute[access_attribute]
1353 entry = variable_name[:attributes]
1356 The type attributes are:
1357 s - String (default)
1360 b - Boolean ([1yYtT|0nNfF])
1364 The access attributes are:
1370 - CONFIG_ENV_FLAGS_LIST_DEFAULT
1371 Define this to a list (string) to define the ".flags"
1372 environment variable in the default or embedded environment.
1374 - CFG_ENV_FLAGS_LIST_STATIC
1375 Define this to a list (string) to define validation that
1376 should be done if an entry is not found in the ".flags"
1377 environment variable. To override a setting in the static
1378 list, simply add an entry for the same variable name to the
1381 If CONFIG_REGEX is defined, the variable_name above is evaluated as a
1382 regular expression. This allows multiple variables to define the same
1383 flags without explicitly listing them for each variable.
1385 The following definitions that deal with the placement and management
1386 of environment data (variable area); in general, we support the
1387 following configurations:
1389 BE CAREFUL! The first access to the environment happens quite early
1390 in U-Boot initialization (when we try to get the setting of for the
1391 console baudrate). You *MUST* have mapped your NVRAM area then, or
1394 Please note that even with NVRAM we still use a copy of the
1395 environment in RAM: we could work on NVRAM directly, but we want to
1396 keep settings there always unmodified except somebody uses "saveenv"
1397 to save the current settings.
1399 BE CAREFUL! For some special cases, the local device can not use
1400 "saveenv" command. For example, the local device will get the
1401 environment stored in a remote NOR flash by SRIO or PCIE link,
1402 but it can not erase, write this NOR flash by SRIO or PCIE interface.
1404 - CONFIG_NAND_ENV_DST
1406 Defines address in RAM to which the nand_spl code should copy the
1407 environment. If redundant environment is used, it will be copied to
1408 CONFIG_NAND_ENV_DST + CONFIG_ENV_SIZE.
1410 Please note that the environment is read-only until the monitor
1411 has been relocated to RAM and a RAM copy of the environment has been
1412 created; also, when using EEPROM you will have to use env_get_f()
1413 until then to read environment variables.
1415 The environment is protected by a CRC32 checksum. Before the monitor
1416 is relocated into RAM, as a result of a bad CRC you will be working
1417 with the compiled-in default environment - *silently*!!! [This is
1418 necessary, because the first environment variable we need is the
1419 "baudrate" setting for the console - if we have a bad CRC, we don't
1420 have any device yet where we could complain.]
1422 Note: once the monitor has been relocated, then it will complain if
1423 the default environment is used; a new CRC is computed as soon as you
1424 use the "saveenv" command to store a valid environment.
1426 - CONFIG_SYS_FAULT_MII_ADDR:
1427 MII address of the PHY to check for the Ethernet link state.
1429 - CONFIG_DISPLAY_BOARDINFO
1430 Display information about the board that U-Boot is running on
1431 when U-Boot starts up. The board function checkboard() is called
1434 - CONFIG_DISPLAY_BOARDINFO_LATE
1435 Similar to the previous option, but display this information
1436 later, once stdio is running and output goes to the LCD, if
1439 Low Level (hardware related) configuration options:
1440 ---------------------------------------------------
1442 - CONFIG_SYS_CACHELINE_SIZE:
1443 Cache Line Size of the CPU.
1445 - CONFIG_SYS_CCSRBAR_DEFAULT:
1446 Default (power-on reset) physical address of CCSR on Freescale
1450 Virtual address of CCSR. On a 32-bit build, this is typically
1451 the same value as CONFIG_SYS_CCSRBAR_DEFAULT.
1453 - CFG_SYS_CCSRBAR_PHYS:
1454 Physical address of CCSR. CCSR can be relocated to a new
1455 physical address, if desired. In this case, this macro should
1456 be set to that address. Otherwise, it should be set to the
1457 same value as CONFIG_SYS_CCSRBAR_DEFAULT. For example, CCSR
1458 is typically relocated on 36-bit builds. It is recommended
1459 that this macro be defined via the _HIGH and _LOW macros:
1461 #define CFG_SYS_CCSRBAR_PHYS ((CFG_SYS_CCSRBAR_PHYS_HIGH
1462 * 1ull) << 32 | CFG_SYS_CCSRBAR_PHYS_LOW)
1464 - CFG_SYS_CCSRBAR_PHYS_HIGH:
1465 Bits 33-36 of CFG_SYS_CCSRBAR_PHYS. This value is typically
1466 either 0 (32-bit build) or 0xF (36-bit build). This macro is
1467 used in assembly code, so it must not contain typecasts or
1468 integer size suffixes (e.g. "ULL").
1470 - CFG_SYS_CCSRBAR_PHYS_LOW:
1471 Lower 32-bits of CFG_SYS_CCSRBAR_PHYS. This macro is
1472 used in assembly code, so it must not contain typecasts or
1473 integer size suffixes (e.g. "ULL").
1475 - CONFIG_SYS_IMMR: Physical address of the Internal Memory.
1476 DO NOT CHANGE unless you know exactly what you're
1477 doing! (11-4) [MPC8xx systems only]
1479 - CFG_SYS_INIT_RAM_ADDR:
1481 Start address of memory area that can be used for
1482 initial data and stack; please note that this must be
1483 writable memory that is working WITHOUT special
1484 initialization, i. e. you CANNOT use normal RAM which
1485 will become available only after programming the
1486 memory controller and running certain initialization
1489 U-Boot uses the following memory types:
1490 - MPC8xx: IMMR (internal memory of the CPU)
1492 - CONFIG_SYS_SCCR: System Clock and reset Control Register (15-27)
1494 - CONFIG_SYS_OR_TIMING_SDRAM:
1497 - CONFIG_SYS_SRIOn_MEM_VIRT:
1498 Virtual Address of SRIO port 'n' memory region
1500 - CONFIG_SYS_SRIOn_MEM_PHYxS:
1501 Physical Address of SRIO port 'n' memory region
1503 - CONFIG_SYS_SRIOn_MEM_SIZE:
1504 Size of SRIO port 'n' memory region
1506 - CONFIG_SYS_NAND_BUSWIDTH_16BIT
1507 Defined to tell the NAND controller that the NAND chip is using
1509 Not all NAND drivers use this symbol.
1510 Example of drivers that use it:
1511 - drivers/mtd/nand/raw/ndfc.c
1512 - drivers/mtd/nand/raw/mxc_nand.c
1514 - CONFIG_SYS_NDFC_EBC0_CFG
1515 Sets the EBC0_CFG register for the NDFC. If not defined
1516 a default value will be used.
1518 - CONFIG_SYS_SPD_BUS_NUM
1519 If SPD EEPROM is on an I2C bus other than the first
1520 one, specify here. Note that the value must resolve
1521 to something your driver can deal with.
1523 - CONFIG_FSL_DDR_INTERACTIVE
1524 Enable interactive DDR debugging. See doc/README.fsl-ddr.
1526 - CONFIG_FSL_DDR_SYNC_REFRESH
1527 Enable sync of refresh for multiple controllers.
1529 - CONFIG_FSL_DDR_BIST
1530 Enable built-in memory test for Freescale DDR controllers.
1533 Enable RMII mode for all FECs.
1534 Note that this is a global option, we can't
1535 have one FEC in standard MII mode and another in RMII mode.
1537 - CONFIG_CRC32_VERIFY
1538 Add a verify option to the crc32 command.
1541 => crc32 -v <address> <count> <crc32>
1543 Where address/count indicate a memory area
1544 and crc32 is the correct crc32 which the
1548 Add the "loopw" memory command. This only takes effect if
1549 the memory commands are activated globally (CONFIG_CMD_MEMORY).
1551 - CONFIG_CMD_MX_CYCLIC
1552 Add the "mdc" and "mwc" memory commands. These are cyclic
1557 This command will print 4 bytes (10,11,12,13) each 500 ms.
1559 => mwc.l 100 12345678 10
1560 This command will write 12345678 to address 100 all 10 ms.
1562 This only takes effect if the memory commands are activated
1563 globally (CONFIG_CMD_MEMORY).
1566 Set when the currently-running compilation is for an artifact
1567 that will end up in the SPL (as opposed to the TPL or U-Boot
1568 proper). Code that needs stage-specific behavior should check
1572 Set when the currently-running compilation is for an artifact
1573 that will end up in the TPL (as opposed to the SPL or U-Boot
1574 proper). Code that needs stage-specific behavior should check
1577 - CONFIG_ARCH_MAP_SYSMEM
1578 Generally U-Boot (and in particular the md command) uses
1579 effective address. It is therefore not necessary to regard
1580 U-Boot address as virtual addresses that need to be translated
1581 to physical addresses. However, sandbox requires this, since
1582 it maintains its own little RAM buffer which contains all
1583 addressable memory. This option causes some memory accesses
1584 to be mapped through map_sysmem() / unmap_sysmem().
1586 - CONFIG_X86_RESET_VECTOR
1587 If defined, the x86 reset vector code is included. This is not
1588 needed when U-Boot is running from Coreboot.
1590 Freescale QE/FMAN Firmware Support:
1591 -----------------------------------
1593 The Freescale QUICCEngine (QE) and Frame Manager (FMAN) both support the
1594 loading of "firmware", which is encoded in the QE firmware binary format.
1595 This firmware often needs to be loaded during U-Boot booting, so macros
1596 are used to identify the storage device (NOR flash, SPI, etc) and the address
1599 - CONFIG_SYS_FMAN_FW_ADDR
1600 The address in the storage device where the FMAN microcode is located. The
1601 meaning of this address depends on which CONFIG_SYS_QE_FMAN_FW_IN_xxx macro
1604 - CONFIG_SYS_QE_FW_ADDR
1605 The address in the storage device where the QE microcode is located. The
1606 meaning of this address depends on which CONFIG_SYS_QE_FMAN_FW_IN_xxx macro
1609 - CONFIG_SYS_QE_FMAN_FW_LENGTH
1610 The maximum possible size of the firmware. The firmware binary format
1611 has a field that specifies the actual size of the firmware, but it
1612 might not be possible to read any part of the firmware unless some
1613 local storage is allocated to hold the entire firmware first.
1615 - CONFIG_SYS_QE_FMAN_FW_IN_NOR
1616 Specifies that QE/FMAN firmware is located in NOR flash, mapped as
1617 normal addressable memory via the LBC. CONFIG_SYS_FMAN_FW_ADDR is the
1618 virtual address in NOR flash.
1620 - CONFIG_SYS_QE_FMAN_FW_IN_NAND
1621 Specifies that QE/FMAN firmware is located in NAND flash.
1622 CONFIG_SYS_FMAN_FW_ADDR is the offset within NAND flash.
1624 - CONFIG_SYS_QE_FMAN_FW_IN_MMC
1625 Specifies that QE/FMAN firmware is located on the primary SD/MMC
1626 device. CONFIG_SYS_FMAN_FW_ADDR is the byte offset on that device.
1628 - CONFIG_SYS_QE_FMAN_FW_IN_REMOTE
1629 Specifies that QE/FMAN firmware is located in the remote (master)
1630 memory space. CONFIG_SYS_FMAN_FW_ADDR is a virtual address which
1631 can be mapped from slave TLB->slave LAW->slave SRIO or PCIE outbound
1632 window->master inbound window->master LAW->the ucode address in
1633 master's memory space.
1635 Freescale Layerscape Management Complex Firmware Support:
1636 ---------------------------------------------------------
1637 The Freescale Layerscape Management Complex (MC) supports the loading of
1639 This firmware often needs to be loaded during U-Boot booting, so macros
1640 are used to identify the storage device (NOR flash, SPI, etc) and the address
1643 - CONFIG_FSL_MC_ENET
1644 Enable the MC driver for Layerscape SoCs.
1646 Freescale Layerscape Debug Server Support:
1647 -------------------------------------------
1648 The Freescale Layerscape Debug Server Support supports the loading of
1649 "Debug Server firmware" and triggering SP boot-rom.
1650 This firmware often needs to be loaded during U-Boot booting.
1652 - CONFIG_SYS_MC_RSV_MEM_ALIGN
1653 Define alignment of reserved memory MC requires
1656 Building the Software:
1657 ======================
1659 Building U-Boot has been tested in several native build environments
1660 and in many different cross environments. Of course we cannot support
1661 all possibly existing versions of cross development tools in all
1662 (potentially obsolete) versions. In case of tool chain problems we
1663 recommend to use the ELDK (see https://www.denx.de/wiki/DULG/ELDK)
1664 which is extensively used to build and test U-Boot.
1666 If you are not using a native environment, it is assumed that you
1667 have GNU cross compiling tools available in your path. In this case,
1668 you must set the environment variable CROSS_COMPILE in your shell.
1669 Note that no changes to the Makefile or any other source files are
1670 necessary. For example using the ELDK on a 4xx CPU, please enter:
1672 $ CROSS_COMPILE=ppc_4xx-
1673 $ export CROSS_COMPILE
1675 U-Boot is intended to be simple to build. After installing the
1676 sources you must configure U-Boot for one specific board type. This
1681 where "NAME_defconfig" is the name of one of the existing configu-
1682 rations; see configs/*_defconfig for supported names.
1684 Note: for some boards special configuration names may exist; check if
1685 additional information is available from the board vendor; for
1686 instance, the TQM823L systems are available without (standard)
1687 or with LCD support. You can select such additional "features"
1688 when choosing the configuration, i. e.
1690 make TQM823L_defconfig
1691 - will configure for a plain TQM823L, i. e. no LCD support
1693 make TQM823L_LCD_defconfig
1694 - will configure for a TQM823L with U-Boot console on LCD
1699 Finally, type "make all", and you should get some working U-Boot
1700 images ready for download to / installation on your system:
1702 - "u-boot.bin" is a raw binary image
1703 - "u-boot" is an image in ELF binary format
1704 - "u-boot.srec" is in Motorola S-Record format
1706 By default the build is performed locally and the objects are saved
1707 in the source directory. One of the two methods can be used to change
1708 this behavior and build U-Boot to some external directory:
1710 1. Add O= to the make command line invocations:
1712 make O=/tmp/build distclean
1713 make O=/tmp/build NAME_defconfig
1714 make O=/tmp/build all
1716 2. Set environment variable KBUILD_OUTPUT to point to the desired location:
1718 export KBUILD_OUTPUT=/tmp/build
1723 Note that the command line "O=" setting overrides the KBUILD_OUTPUT environment
1726 User specific CPPFLAGS, AFLAGS and CFLAGS can be passed to the compiler by
1727 setting the according environment variables KCPPFLAGS, KAFLAGS and KCFLAGS.
1728 For example to treat all compiler warnings as errors:
1730 make KCFLAGS=-Werror
1732 Please be aware that the Makefiles assume you are using GNU make, so
1733 for instance on NetBSD you might need to use "gmake" instead of
1737 If the system board that you have is not listed, then you will need
1738 to port U-Boot to your hardware platform. To do this, follow these
1741 1. Create a new directory to hold your board specific code. Add any
1742 files you need. In your board directory, you will need at least
1743 the "Makefile" and a "<board>.c".
1744 2. Create a new configuration file "include/configs/<board>.h" for
1746 3. If you're porting U-Boot to a new CPU, then also create a new
1747 directory to hold your CPU specific code. Add any files you need.
1748 4. Run "make <board>_defconfig" with your new name.
1749 5. Type "make", and you should get a working "u-boot.srec" file
1750 to be installed on your target system.
1751 6. Debug and solve any problems that might arise.
1752 [Of course, this last step is much harder than it sounds.]
1755 Testing of U-Boot Modifications, Ports to New Hardware, etc.:
1756 ==============================================================
1758 If you have modified U-Boot sources (for instance added a new board
1759 or support for new devices, a new CPU, etc.) you are expected to
1760 provide feedback to the other developers. The feedback normally takes
1761 the form of a "patch", i.e. a context diff against a certain (latest
1762 official or latest in the git repository) version of U-Boot sources.
1764 But before you submit such a patch, please verify that your modifi-
1765 cation did not break existing code. At least make sure that *ALL* of
1766 the supported boards compile WITHOUT ANY compiler warnings. To do so,
1767 just run the buildman script (tools/buildman/buildman), which will
1768 configure and build U-Boot for ALL supported system. Be warned, this
1769 will take a while. Please see the buildman README, or run 'buildman -H'
1773 See also "U-Boot Porting Guide" below.
1776 Monitor Commands - Overview:
1777 ============================
1779 go - start application at address 'addr'
1780 run - run commands in an environment variable
1781 bootm - boot application image from memory
1782 bootp - boot image via network using BootP/TFTP protocol
1783 bootz - boot zImage from memory
1784 tftpboot- boot image via network using TFTP protocol
1785 and env variables "ipaddr" and "serverip"
1786 (and eventually "gatewayip")
1787 tftpput - upload a file via network using TFTP protocol
1788 rarpboot- boot image via network using RARP/TFTP protocol
1789 diskboot- boot from IDE devicebootd - boot default, i.e., run 'bootcmd'
1790 loads - load S-Record file over serial line
1791 loadb - load binary file over serial line (kermit mode)
1792 loadm - load binary blob from source address to destination address
1794 mm - memory modify (auto-incrementing)
1795 nm - memory modify (constant address)
1796 mw - memory write (fill)
1799 cmp - memory compare
1800 crc32 - checksum calculation
1801 i2c - I2C sub-system
1802 sspi - SPI utility commands
1803 base - print or set address offset
1804 printenv- print environment variables
1805 pwm - control pwm channels
1806 seama - load SEAMA NAND image
1807 setenv - set environment variables
1808 saveenv - save environment variables to persistent storage
1809 protect - enable or disable FLASH write protection
1810 erase - erase FLASH memory
1811 flinfo - print FLASH memory information
1812 nand - NAND memory operations (see doc/README.nand)
1813 bdinfo - print Board Info structure
1814 iminfo - print header information for application image
1815 coninfo - print console devices and informations
1816 ide - IDE sub-system
1817 loop - infinite loop on address range
1818 loopw - infinite write loop on address range
1819 mtest - simple RAM test
1820 icache - enable or disable instruction cache
1821 dcache - enable or disable data cache
1822 reset - Perform RESET of the CPU
1823 echo - echo args to console
1824 version - print monitor version
1825 help - print online help
1826 ? - alias for 'help'
1829 Monitor Commands - Detailed Description:
1830 ========================================
1834 For now: just type "help <command>".
1837 Note for Redundant Ethernet Interfaces:
1838 =======================================
1840 Some boards come with redundant Ethernet interfaces; U-Boot supports
1841 such configurations and is capable of automatic selection of a
1842 "working" interface when needed. MAC assignment works as follows:
1844 Network interfaces are numbered eth0, eth1, eth2, ... Corresponding
1845 MAC addresses can be stored in the environment as "ethaddr" (=>eth0),
1846 "eth1addr" (=>eth1), "eth2addr", ...
1848 If the network interface stores some valid MAC address (for instance
1849 in SROM), this is used as default address if there is NO correspon-
1850 ding setting in the environment; if the corresponding environment
1851 variable is set, this overrides the settings in the card; that means:
1853 o If the SROM has a valid MAC address, and there is no address in the
1854 environment, the SROM's address is used.
1856 o If there is no valid address in the SROM, and a definition in the
1857 environment exists, then the value from the environment variable is
1860 o If both the SROM and the environment contain a MAC address, and
1861 both addresses are the same, this MAC address is used.
1863 o If both the SROM and the environment contain a MAC address, and the
1864 addresses differ, the value from the environment is used and a
1867 o If neither SROM nor the environment contain a MAC address, an error
1868 is raised. If CONFIG_NET_RANDOM_ETHADDR is defined, then in this case
1869 a random, locally-assigned MAC is used.
1871 If Ethernet drivers implement the 'write_hwaddr' function, valid MAC addresses
1872 will be programmed into hardware as part of the initialization process. This
1873 may be skipped by setting the appropriate 'ethmacskip' environment variable.
1874 The naming convention is as follows:
1875 "ethmacskip" (=>eth0), "eth1macskip" (=>eth1) etc.
1880 U-Boot is capable of booting (and performing other auxiliary operations on)
1881 images in two formats:
1883 New uImage format (FIT)
1884 -----------------------
1886 Flexible and powerful format based on Flattened Image Tree -- FIT (similar
1887 to Flattened Device Tree). It allows the use of images with multiple
1888 components (several kernels, ramdisks, etc.), with contents protected by
1889 SHA1, MD5 or CRC32. More details are found in the doc/uImage.FIT directory.
1895 Old image format is based on binary files which can be basically anything,
1896 preceded by a special header; see the definitions in include/image.h for
1897 details; basically, the header defines the following image properties:
1899 * Target Operating System (Provisions for OpenBSD, NetBSD, FreeBSD,
1900 4.4BSD, Linux, SVR4, Esix, Solaris, Irix, SCO, Dell, NCR, VxWorks,
1901 LynxOS, pSOS, QNX, RTEMS, INTEGRITY;
1902 Currently supported: Linux, NetBSD, VxWorks, QNX, RTEMS, INTEGRITY).
1903 * Target CPU Architecture (Provisions for Alpha, ARM, Intel x86,
1904 IA64, MIPS, Nios II, PowerPC, IBM S390, SuperH, Sparc, Sparc 64 Bit;
1905 Currently supported: ARM, Intel x86, MIPS, Nios II, PowerPC).
1906 * Compression Type (uncompressed, gzip, bzip2)
1912 The header is marked by a special Magic Number, and both the header
1913 and the data portions of the image are secured against corruption by
1920 Although U-Boot should support any OS or standalone application
1921 easily, the main focus has always been on Linux during the design of
1924 U-Boot includes many features that so far have been part of some
1925 special "boot loader" code within the Linux kernel. Also, any
1926 "initrd" images to be used are no longer part of one big Linux image;
1927 instead, kernel and "initrd" are separate images. This implementation
1928 serves several purposes:
1930 - the same features can be used for other OS or standalone
1931 applications (for instance: using compressed images to reduce the
1932 Flash memory footprint)
1934 - it becomes much easier to port new Linux kernel versions because
1935 lots of low-level, hardware dependent stuff are done by U-Boot
1937 - the same Linux kernel image can now be used with different "initrd"
1938 images; of course this also means that different kernel images can
1939 be run with the same "initrd". This makes testing easier (you don't
1940 have to build a new "zImage.initrd" Linux image when you just
1941 change a file in your "initrd"). Also, a field-upgrade of the
1942 software is easier now.
1948 Porting Linux to U-Boot based systems:
1949 ---------------------------------------
1951 U-Boot cannot save you from doing all the necessary modifications to
1952 configure the Linux device drivers for use with your target hardware
1953 (no, we don't intend to provide a full virtual machine interface to
1956 But now you can ignore ALL boot loader code (in arch/powerpc/mbxboot).
1958 Just make sure your machine specific header file (for instance
1959 include/asm-ppc/tqm8xx.h) includes the same definition of the Board
1960 Information structure as we define in include/asm-<arch>/u-boot.h,
1961 and make sure that your definition of IMAP_ADDR uses the same value
1962 as your U-Boot configuration in CONFIG_SYS_IMMR.
1964 Note that U-Boot now has a driver model, a unified model for drivers.
1965 If you are adding a new driver, plumb it into driver model. If there
1966 is no uclass available, you are encouraged to create one. See
1970 Configuring the Linux kernel:
1971 -----------------------------
1973 No specific requirements for U-Boot. Make sure you have some root
1974 device (initial ramdisk, NFS) for your target system.
1977 Building a Linux Image:
1978 -----------------------
1980 With U-Boot, "normal" build targets like "zImage" or "bzImage" are
1981 not used. If you use recent kernel source, a new build target
1982 "uImage" will exist which automatically builds an image usable by
1983 U-Boot. Most older kernels also have support for a "pImage" target,
1984 which was introduced for our predecessor project PPCBoot and uses a
1985 100% compatible format.
1989 make TQM850L_defconfig
1994 The "uImage" build target uses a special tool (in 'tools/mkimage') to
1995 encapsulate a compressed Linux kernel image with header information,
1996 CRC32 checksum etc. for use with U-Boot. This is what we are doing:
1998 * build a standard "vmlinux" kernel image (in ELF binary format):
2000 * convert the kernel into a raw binary image:
2002 ${CROSS_COMPILE}-objcopy -O binary \
2003 -R .note -R .comment \
2004 -S vmlinux linux.bin
2006 * compress the binary image:
2010 * package compressed binary image for U-Boot:
2012 mkimage -A ppc -O linux -T kernel -C gzip \
2013 -a 0 -e 0 -n "Linux Kernel Image" \
2014 -d linux.bin.gz uImage
2017 The "mkimage" tool can also be used to create ramdisk images for use
2018 with U-Boot, either separated from the Linux kernel image, or
2019 combined into one file. "mkimage" encapsulates the images with a 64
2020 byte header containing information about target architecture,
2021 operating system, image type, compression method, entry points, time
2022 stamp, CRC32 checksums, etc.
2024 "mkimage" can be called in two ways: to verify existing images and
2025 print the header information, or to build new images.
2027 In the first form (with "-l" option) mkimage lists the information
2028 contained in the header of an existing U-Boot image; this includes
2029 checksum verification:
2031 tools/mkimage -l image
2032 -l ==> list image header information
2034 The second form (with "-d" option) is used to build a U-Boot image
2035 from a "data file" which is used as image payload:
2037 tools/mkimage -A arch -O os -T type -C comp -a addr -e ep \
2038 -n name -d data_file image
2039 -A ==> set architecture to 'arch'
2040 -O ==> set operating system to 'os'
2041 -T ==> set image type to 'type'
2042 -C ==> set compression type 'comp'
2043 -a ==> set load address to 'addr' (hex)
2044 -e ==> set entry point to 'ep' (hex)
2045 -n ==> set image name to 'name'
2046 -d ==> use image data from 'datafile'
2048 Right now, all Linux kernels for PowerPC systems use the same load
2049 address (0x00000000), but the entry point address depends on the
2052 - 2.2.x kernels have the entry point at 0x0000000C,
2053 - 2.3.x and later kernels have the entry point at 0x00000000.
2055 So a typical call to build a U-Boot image would read:
2057 -> tools/mkimage -n '2.4.4 kernel for TQM850L' \
2058 > -A ppc -O linux -T kernel -C gzip -a 0 -e 0 \
2059 > -d /opt/elsk/ppc_8xx/usr/src/linux-2.4.4/arch/powerpc/coffboot/vmlinux.gz \
2060 > examples/uImage.TQM850L
2061 Image Name: 2.4.4 kernel for TQM850L
2062 Created: Wed Jul 19 02:34:59 2000
2063 Image Type: PowerPC Linux Kernel Image (gzip compressed)
2064 Data Size: 335725 Bytes = 327.86 kB = 0.32 MB
2065 Load Address: 0x00000000
2066 Entry Point: 0x00000000
2068 To verify the contents of the image (or check for corruption):
2070 -> tools/mkimage -l examples/uImage.TQM850L
2071 Image Name: 2.4.4 kernel for TQM850L
2072 Created: Wed Jul 19 02:34:59 2000
2073 Image Type: PowerPC Linux Kernel Image (gzip compressed)
2074 Data Size: 335725 Bytes = 327.86 kB = 0.32 MB
2075 Load Address: 0x00000000
2076 Entry Point: 0x00000000
2078 NOTE: for embedded systems where boot time is critical you can trade
2079 speed for memory and install an UNCOMPRESSED image instead: this
2080 needs more space in Flash, but boots much faster since it does not
2081 need to be uncompressed:
2083 -> gunzip /opt/elsk/ppc_8xx/usr/src/linux-2.4.4/arch/powerpc/coffboot/vmlinux.gz
2084 -> tools/mkimage -n '2.4.4 kernel for TQM850L' \
2085 > -A ppc -O linux -T kernel -C none -a 0 -e 0 \
2086 > -d /opt/elsk/ppc_8xx/usr/src/linux-2.4.4/arch/powerpc/coffboot/vmlinux \
2087 > examples/uImage.TQM850L-uncompressed
2088 Image Name: 2.4.4 kernel for TQM850L
2089 Created: Wed Jul 19 02:34:59 2000
2090 Image Type: PowerPC Linux Kernel Image (uncompressed)
2091 Data Size: 792160 Bytes = 773.59 kB = 0.76 MB
2092 Load Address: 0x00000000
2093 Entry Point: 0x00000000
2096 Similar you can build U-Boot images from a 'ramdisk.image.gz' file
2097 when your kernel is intended to use an initial ramdisk:
2099 -> tools/mkimage -n 'Simple Ramdisk Image' \
2100 > -A ppc -O linux -T ramdisk -C gzip \
2101 > -d /LinuxPPC/images/SIMPLE-ramdisk.image.gz examples/simple-initrd
2102 Image Name: Simple Ramdisk Image
2103 Created: Wed Jan 12 14:01:50 2000
2104 Image Type: PowerPC Linux RAMDisk Image (gzip compressed)
2105 Data Size: 566530 Bytes = 553.25 kB = 0.54 MB
2106 Load Address: 0x00000000
2107 Entry Point: 0x00000000
2109 The "dumpimage" tool can be used to disassemble or list the contents of images
2110 built by mkimage. See dumpimage's help output (-h) for details.
2112 Installing a Linux Image:
2113 -------------------------
2115 To downloading a U-Boot image over the serial (console) interface,
2116 you must convert the image to S-Record format:
2118 objcopy -I binary -O srec examples/image examples/image.srec
2120 The 'objcopy' does not understand the information in the U-Boot
2121 image header, so the resulting S-Record file will be relative to
2122 address 0x00000000. To load it to a given address, you need to
2123 specify the target address as 'offset' parameter with the 'loads'
2126 Example: install the image to address 0x40100000 (which on the
2127 TQM8xxL is in the first Flash bank):
2129 => erase 40100000 401FFFFF
2135 ## Ready for S-Record download ...
2136 ~>examples/image.srec
2137 1 2 3 4 5 6 7 8 9 10 11 12 13 ...
2139 15989 15990 15991 15992
2140 [file transfer complete]
2142 ## Start Addr = 0x00000000
2145 You can check the success of the download using the 'iminfo' command;
2146 this includes a checksum verification so you can be sure no data
2147 corruption happened:
2151 ## Checking Image at 40100000 ...
2152 Image Name: 2.2.13 for initrd on TQM850L
2153 Image Type: PowerPC Linux Kernel Image (gzip compressed)
2154 Data Size: 335725 Bytes = 327 kB = 0 MB
2155 Load Address: 00000000
2156 Entry Point: 0000000c
2157 Verifying Checksum ... OK
2163 The "bootm" command is used to boot an application that is stored in
2164 memory (RAM or Flash). In case of a Linux kernel image, the contents
2165 of the "bootargs" environment variable is passed to the kernel as
2166 parameters. You can check and modify this variable using the
2167 "printenv" and "setenv" commands:
2170 => printenv bootargs
2171 bootargs=root=/dev/ram
2173 => setenv bootargs root=/dev/nfs rw nfsroot=10.0.0.2:/LinuxPPC nfsaddrs=10.0.0.99:10.0.0.2
2175 => printenv bootargs
2176 bootargs=root=/dev/nfs rw nfsroot=10.0.0.2:/LinuxPPC nfsaddrs=10.0.0.99:10.0.0.2
2179 ## Booting Linux kernel at 40020000 ...
2180 Image Name: 2.2.13 for NFS on TQM850L
2181 Image Type: PowerPC Linux Kernel Image (gzip compressed)
2182 Data Size: 381681 Bytes = 372 kB = 0 MB
2183 Load Address: 00000000
2184 Entry Point: 0000000c
2185 Verifying Checksum ... OK
2186 Uncompressing Kernel Image ... OK
2187 Linux version 2.2.13 (wd@denx.local.net) (gcc version 2.95.2 19991024 (release)) #1 Wed Jul 19 02:35:17 MEST 2000
2188 Boot arguments: root=/dev/nfs rw nfsroot=10.0.0.2:/LinuxPPC nfsaddrs=10.0.0.99:10.0.0.2
2189 time_init: decrementer frequency = 187500000/60
2190 Calibrating delay loop... 49.77 BogoMIPS
2191 Memory: 15208k available (700k kernel code, 444k data, 32k init) [c0000000,c1000000]
2194 If you want to boot a Linux kernel with initial RAM disk, you pass
2195 the memory addresses of both the kernel and the initrd image (PPBCOOT
2196 format!) to the "bootm" command:
2198 => imi 40100000 40200000
2200 ## Checking Image at 40100000 ...
2201 Image Name: 2.2.13 for initrd on TQM850L
2202 Image Type: PowerPC Linux Kernel Image (gzip compressed)
2203 Data Size: 335725 Bytes = 327 kB = 0 MB
2204 Load Address: 00000000
2205 Entry Point: 0000000c
2206 Verifying Checksum ... OK
2208 ## Checking Image at 40200000 ...
2209 Image Name: Simple Ramdisk Image
2210 Image Type: PowerPC Linux RAMDisk Image (gzip compressed)
2211 Data Size: 566530 Bytes = 553 kB = 0 MB
2212 Load Address: 00000000
2213 Entry Point: 00000000
2214 Verifying Checksum ... OK
2216 => bootm 40100000 40200000
2217 ## Booting Linux kernel at 40100000 ...
2218 Image Name: 2.2.13 for initrd on TQM850L
2219 Image Type: PowerPC Linux Kernel Image (gzip compressed)
2220 Data Size: 335725 Bytes = 327 kB = 0 MB
2221 Load Address: 00000000
2222 Entry Point: 0000000c
2223 Verifying Checksum ... OK
2224 Uncompressing Kernel Image ... OK
2225 ## Loading RAMDisk Image at 40200000 ...
2226 Image Name: Simple Ramdisk Image
2227 Image Type: PowerPC Linux RAMDisk Image (gzip compressed)
2228 Data Size: 566530 Bytes = 553 kB = 0 MB
2229 Load Address: 00000000
2230 Entry Point: 00000000
2231 Verifying Checksum ... OK
2232 Loading Ramdisk ... OK
2233 Linux version 2.2.13 (wd@denx.local.net) (gcc version 2.95.2 19991024 (release)) #1 Wed Jul 19 02:32:08 MEST 2000
2234 Boot arguments: root=/dev/ram
2235 time_init: decrementer frequency = 187500000/60
2236 Calibrating delay loop... 49.77 BogoMIPS
2238 RAMDISK: Compressed image found at block 0
2239 VFS: Mounted root (ext2 filesystem).
2243 Boot Linux and pass a flat device tree:
2246 First, U-Boot must be compiled with the appropriate defines. See the section
2247 titled "Linux Kernel Interface" above for a more in depth explanation. The
2248 following is an example of how to start a kernel and pass an updated
2254 oft=oftrees/mpc8540ads.dtb
2255 => tftp $oftaddr $oft
2256 Speed: 1000, full duplex
2258 TFTP from server 192.168.1.1; our IP address is 192.168.1.101
2259 Filename 'oftrees/mpc8540ads.dtb'.
2260 Load address: 0x300000
2263 Bytes transferred = 4106 (100a hex)
2264 => tftp $loadaddr $bootfile
2265 Speed: 1000, full duplex
2267 TFTP from server 192.168.1.1; our IP address is 192.168.1.2
2269 Load address: 0x200000
2270 Loading:############
2272 Bytes transferred = 1029407 (fb51f hex)
2277 => bootm $loadaddr - $oftaddr
2278 ## Booting image at 00200000 ...
2279 Image Name: Linux-2.6.17-dirty
2280 Image Type: PowerPC Linux Kernel Image (gzip compressed)
2281 Data Size: 1029343 Bytes = 1005.2 kB
2282 Load Address: 00000000
2283 Entry Point: 00000000
2284 Verifying Checksum ... OK
2285 Uncompressing Kernel Image ... OK
2286 Booting using flat device tree at 0x300000
2287 Using MPC85xx ADS machine description
2288 Memory CAM mapping: CAM0=256Mb, CAM1=256Mb, CAM2=0Mb residual: 0Mb
2292 More About U-Boot Image Types:
2293 ------------------------------
2295 U-Boot supports the following image types:
2297 "Standalone Programs" are directly runnable in the environment
2298 provided by U-Boot; it is expected that (if they behave
2299 well) you can continue to work in U-Boot after return from
2300 the Standalone Program.
2301 "OS Kernel Images" are usually images of some Embedded OS which
2302 will take over control completely. Usually these programs
2303 will install their own set of exception handlers, device
2304 drivers, set up the MMU, etc. - this means, that you cannot
2305 expect to re-enter U-Boot except by resetting the CPU.
2306 "RAMDisk Images" are more or less just data blocks, and their
2307 parameters (address, size) are passed to an OS kernel that is
2309 "Multi-File Images" contain several images, typically an OS
2310 (Linux) kernel image and one or more data images like
2311 RAMDisks. This construct is useful for instance when you want
2312 to boot over the network using BOOTP etc., where the boot
2313 server provides just a single image file, but you want to get
2314 for instance an OS kernel and a RAMDisk image.
2316 "Multi-File Images" start with a list of image sizes, each
2317 image size (in bytes) specified by an "uint32_t" in network
2318 byte order. This list is terminated by an "(uint32_t)0".
2319 Immediately after the terminating 0 follow the images, one by
2320 one, all aligned on "uint32_t" boundaries (size rounded up to
2321 a multiple of 4 bytes).
2323 "Firmware Images" are binary images containing firmware (like
2324 U-Boot or FPGA images) which usually will be programmed to
2327 "Script files" are command sequences that will be executed by
2328 U-Boot's command interpreter; this feature is especially
2329 useful when you configure U-Boot to use a real shell (hush)
2330 as command interpreter.
2332 Booting the Linux zImage:
2333 -------------------------
2335 On some platforms, it's possible to boot Linux zImage. This is done
2336 using the "bootz" command. The syntax of "bootz" command is the same
2337 as the syntax of "bootm" command.
2339 Note, defining the CONFIG_SUPPORT_RAW_INITRD allows user to supply
2340 kernel with raw initrd images. The syntax is slightly different, the
2341 address of the initrd must be augmented by it's size, in the following
2342 format: "<initrd addres>:<initrd size>".
2348 One of the features of U-Boot is that you can dynamically load and
2349 run "standalone" applications, which can use some resources of
2350 U-Boot like console I/O functions or interrupt services.
2352 Two simple examples are included with the sources:
2357 'examples/hello_world.c' contains a small "Hello World" Demo
2358 application; it is automatically compiled when you build U-Boot.
2359 It's configured to run at address 0x00040004, so you can play with it
2363 ## Ready for S-Record download ...
2364 ~>examples/hello_world.srec
2365 1 2 3 4 5 6 7 8 9 10 11 ...
2366 [file transfer complete]
2368 ## Start Addr = 0x00040004
2370 => go 40004 Hello World! This is a test.
2371 ## Starting application at 0x00040004 ...
2382 Hit any key to exit ...
2384 ## Application terminated, rc = 0x0
2386 Another example, which demonstrates how to register a CPM interrupt
2387 handler with the U-Boot code, can be found in 'examples/timer.c'.
2388 Here, a CPM timer is set up to generate an interrupt every second.
2389 The interrupt service routine is trivial, just printing a '.'
2390 character, but this is just a demo program. The application can be
2391 controlled by the following keys:
2393 ? - print current values og the CPM Timer registers
2394 b - enable interrupts and start timer
2395 e - stop timer and disable interrupts
2396 q - quit application
2399 ## Ready for S-Record download ...
2400 ~>examples/timer.srec
2401 1 2 3 4 5 6 7 8 9 10 11 ...
2402 [file transfer complete]
2404 ## Start Addr = 0x00040004
2407 ## Starting application at 0x00040004 ...
2410 tgcr @ 0xfff00980, tmr @ 0xfff00990, trr @ 0xfff00994, tcr @ 0xfff00998, tcn @ 0xfff0099c, ter @ 0xfff009b0
2413 [q, b, e, ?] Set interval 1000000 us
2416 [q, b, e, ?] ........
2417 tgcr=0x1, tmr=0xff1c, trr=0x3d09, tcr=0x0, tcn=0xef6, ter=0x0
2420 tgcr=0x1, tmr=0xff1c, trr=0x3d09, tcr=0x0, tcn=0x2ad4, ter=0x0
2423 tgcr=0x1, tmr=0xff1c, trr=0x3d09, tcr=0x0, tcn=0x1efc, ter=0x0
2426 tgcr=0x1, tmr=0xff1c, trr=0x3d09, tcr=0x0, tcn=0x169d, ter=0x0
2428 [q, b, e, ?] ...Stopping timer
2430 [q, b, e, ?] ## Application terminated, rc = 0x0
2433 Implementation Internals:
2434 =========================
2436 The following is not intended to be a complete description of every
2437 implementation detail. However, it should help to understand the
2438 inner workings of U-Boot and make it easier to port it to custom
2442 Initial Stack, Global Data:
2443 ---------------------------
2445 The implementation of U-Boot is complicated by the fact that U-Boot
2446 starts running out of ROM (flash memory), usually without access to
2447 system RAM (because the memory controller is not initialized yet).
2448 This means that we don't have writable Data or BSS segments, and BSS
2449 is not initialized as zero. To be able to get a C environment working
2450 at all, we have to allocate at least a minimal stack. Implementation
2451 options for this are defined and restricted by the CPU used: Some CPU
2452 models provide on-chip memory (like the IMMR area on MPC8xx and
2453 MPC826x processors), on others (parts of) the data cache can be
2454 locked as (mis-) used as memory, etc.
2456 Chris Hallinan posted a good summary of these issues to the
2457 U-Boot mailing list:
2459 Subject: RE: [U-Boot-Users] RE: More On Memory Bank x (nothingness)?
2460 From: "Chris Hallinan" <clh@net1plus.com>
2461 Date: Mon, 10 Feb 2003 16:43:46 -0500 (22:43 MET)
2464 Correct me if I'm wrong, folks, but the way I understand it
2465 is this: Using DCACHE as initial RAM for Stack, etc, does not
2466 require any physical RAM backing up the cache. The cleverness
2467 is that the cache is being used as a temporary supply of
2468 necessary storage before the SDRAM controller is setup. It's
2469 beyond the scope of this list to explain the details, but you
2470 can see how this works by studying the cache architecture and
2471 operation in the architecture and processor-specific manuals.
2473 OCM is On Chip Memory, which I believe the 405GP has 4K. It
2474 is another option for the system designer to use as an
2475 initial stack/RAM area prior to SDRAM being available. Either
2476 option should work for you. Using CS 4 should be fine if your
2477 board designers haven't used it for something that would
2478 cause you grief during the initial boot! It is frequently not
2481 CFG_SYS_INIT_RAM_ADDR should be somewhere that won't interfere
2482 with your processor/board/system design. The default value
2483 you will find in any recent u-boot distribution in
2484 walnut.h should work for you. I'd set it to a value larger
2485 than your SDRAM module. If you have a 64MB SDRAM module, set
2486 it above 400_0000. Just make sure your board has no resources
2487 that are supposed to respond to that address! That code in
2488 start.S has been around a while and should work as is when
2489 you get the config right.
2494 It is essential to remember this, since it has some impact on the C
2495 code for the initialization procedures:
2497 * Initialized global data (data segment) is read-only. Do not attempt
2500 * Do not use any uninitialized global data (or implicitly initialized
2501 as zero data - BSS segment) at all - this is undefined, initiali-
2502 zation is performed later (when relocating to RAM).
2504 * Stack space is very limited. Avoid big data buffers or things like
2507 Having only the stack as writable memory limits means we cannot use
2508 normal global data to share information between the code. But it
2509 turned out that the implementation of U-Boot can be greatly
2510 simplified by making a global data structure (gd_t) available to all
2511 functions. We could pass a pointer to this data as argument to _all_
2512 functions, but this would bloat the code. Instead we use a feature of
2513 the GCC compiler (Global Register Variables) to share the data: we
2514 place a pointer (gd) to the global data into a register which we
2515 reserve for this purpose.
2517 When choosing a register for such a purpose we are restricted by the
2518 relevant (E)ABI specifications for the current architecture, and by
2519 GCC's implementation.
2521 For PowerPC, the following registers have specific use:
2523 R2: reserved for system use
2524 R3-R4: parameter passing and return values
2525 R5-R10: parameter passing
2526 R13: small data area pointer
2530 (U-Boot also uses R12 as internal GOT pointer. r12
2531 is a volatile register so r12 needs to be reset when
2532 going back and forth between asm and C)
2534 ==> U-Boot will use R2 to hold a pointer to the global data
2536 Note: on PPC, we could use a static initializer (since the
2537 address of the global data structure is known at compile time),
2538 but it turned out that reserving a register results in somewhat
2539 smaller code - although the code savings are not that big (on
2540 average for all boards 752 bytes for the whole U-Boot image,
2541 624 text + 127 data).
2543 On ARM, the following registers are used:
2545 R0: function argument word/integer result
2546 R1-R3: function argument word
2547 R9: platform specific
2548 R10: stack limit (used only if stack checking is enabled)
2549 R11: argument (frame) pointer
2550 R12: temporary workspace
2553 R15: program counter
2555 ==> U-Boot will use R9 to hold a pointer to the global data
2557 Note: on ARM, only R_ARM_RELATIVE relocations are supported.
2559 On Nios II, the ABI is documented here:
2560 https://www.altera.com/literature/hb/nios2/n2cpu_nii51016.pdf
2562 ==> U-Boot will use gp to hold a pointer to the global data
2564 Note: on Nios II, we give "-G0" option to gcc and don't use gp
2565 to access small data sections, so gp is free.
2567 On RISC-V, the following registers are used:
2569 x0: hard-wired zero (zero)
2570 x1: return address (ra)
2571 x2: stack pointer (sp)
2572 x3: global pointer (gp)
2573 x4: thread pointer (tp)
2574 x5: link register (t0)
2575 x8: frame pointer (fp)
2576 x10-x11: arguments/return values (a0-1)
2577 x12-x17: arguments (a2-7)
2578 x28-31: temporaries (t3-6)
2579 pc: program counter (pc)
2581 ==> U-Boot will use gp to hold a pointer to the global data
2586 U-Boot runs in system state and uses physical addresses, i.e. the
2587 MMU is not used either for address mapping nor for memory protection.
2589 The available memory is mapped to fixed addresses using the memory
2590 controller. In this process, a contiguous block is formed for each
2591 memory type (Flash, SDRAM, SRAM), even when it consists of several
2592 physical memory banks.
2594 U-Boot is installed in the first 128 kB of the first Flash bank (on
2595 TQM8xxL modules this is the range 0x40000000 ... 0x4001FFFF). After
2596 booting and sizing and initializing DRAM, the code relocates itself
2597 to the upper end of DRAM. Immediately below the U-Boot code some
2598 memory is reserved for use by malloc() [see CONFIG_SYS_MALLOC_LEN
2599 configuration setting]. Below that, a structure with global Board
2600 Info data is placed, followed by the stack (growing downward).
2602 Additionally, some exception handler code is copied to the low 8 kB
2603 of DRAM (0x00000000 ... 0x00001FFF).
2605 So a typical memory configuration with 16 MB of DRAM could look like
2608 0x0000 0000 Exception Vector code
2611 0x0000 2000 Free for Application Use
2617 0x00FB FF20 Monitor Stack (Growing downward)
2618 0x00FB FFAC Board Info Data and permanent copy of global data
2619 0x00FC 0000 Malloc Arena
2622 0x00FE 0000 RAM Copy of Monitor Code
2623 ... eventually: LCD or video framebuffer
2624 ... eventually: pRAM (Protected RAM - unchanged by reset)
2625 0x00FF FFFF [End of RAM]
2628 System Initialization:
2629 ----------------------
2631 In the reset configuration, U-Boot starts at the reset entry point
2632 (on most PowerPC systems at address 0x00000100). Because of the reset
2633 configuration for CS0# this is a mirror of the on board Flash memory.
2634 To be able to re-map memory U-Boot then jumps to its link address.
2635 To be able to implement the initialization code in C, a (small!)
2636 initial stack is set up in the internal Dual Ported RAM (in case CPUs
2637 which provide such a feature like), or in a locked part of the data
2638 cache. After that, U-Boot initializes the CPU core, the caches and
2641 Next, all (potentially) available memory banks are mapped using a
2642 preliminary mapping. For example, we put them on 512 MB boundaries
2643 (multiples of 0x20000000: SDRAM on 0x00000000 and 0x20000000, Flash
2644 on 0x40000000 and 0x60000000, SRAM on 0x80000000). Then UPM A is
2645 programmed for SDRAM access. Using the temporary configuration, a
2646 simple memory test is run that determines the size of the SDRAM
2649 When there is more than one SDRAM bank, and the banks are of
2650 different size, the largest is mapped first. For equal size, the first
2651 bank (CS2#) is mapped first. The first mapping is always for address
2652 0x00000000, with any additional banks following immediately to create
2653 contiguous memory starting from 0.
2655 Then, the monitor installs itself at the upper end of the SDRAM area
2656 and allocates memory for use by malloc() and for the global Board
2657 Info data; also, the exception vector code is copied to the low RAM
2658 pages, and the final stack is set up.
2660 Only after this relocation will you have a "normal" C environment;
2661 until that you are restricted in several ways, mostly because you are
2662 running from ROM, and because the code will have to be relocated to a
2669 The U-Boot projects depends on contributions from the user community.
2670 If you want to participate, please, have a look at the 'General'
2671 section of https://u-boot.readthedocs.io/en/latest/develop/index.html
2672 where we describe coding standards and the patch submission process.