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When U-Boot started using SPDX tags we were among the early adopters and there weren't a lot of other examples to borrow from. So we picked the area of the file that usually had a full license text and replaced it with an appropriate SPDX-License-Identifier: entry. Since then, the Linux Kernel has adopted SPDX tags and they place it as the very first line in a file (except where shebangs are used, then it's second line) and with slightly different comment styles than us. In part due to community overlap, in part due to better tag visibility and in part for other minor reasons, switch over to that style. This commit changes all instances where we have a single declared license in the tag as both the before and after are identical in tag contents. There's also a few places where I found we did not have a tag and have introduced one. Signed-off-by: Tom Rini <trini@konsulko.com> |
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sandbox.c |
/* SPDX-License-Identifier: GPL-2.0+ */ /* * Copyright (c) 2014 The Chromium OS Authors. */ Native Execution of U-Boot ========================== The 'sandbox' architecture is designed to allow U-Boot to run under Linux on almost any hardware. To achieve this it builds U-Boot (so far as possible) as a normal C application with a main() and normal C libraries. All of U-Boot's architecture-specific code therefore cannot be built as part of the sandbox U-Boot. The purpose of running U-Boot under Linux is to test all the generic code, not specific to any one architecture. The idea is to create unit tests which we can run to test this upper level code. CONFIG_SANDBOX is defined when building a native board. The board name is 'sandbox' but the vendor name is unset, so there is a single board in board/sandbox. CONFIG_SANDBOX_BIG_ENDIAN should be defined when running on big-endian machines. There are two versions of the sandbox: One using 32-bit-wide integers, and one using 64-bit-wide integers. The 32-bit version can be build and run on either 32 or 64-bit hosts by either selecting or deselecting CONFIG_SANDBOX_32BIT; by default, the sandbox it built for a 32-bit host. The sandbox using 64-bit-wide integers can only be built on 64-bit hosts. Note that standalone/API support is not available at present. Basic Operation --------------- To run sandbox U-Boot use something like: make sandbox_defconfig all ./u-boot Note: If you get errors about 'sdl-config: Command not found' you may need to install libsdl1.2-dev or similar to get SDL support. Alternatively you can build sandbox without SDL (i.e. no display/keyboard support) by removing the CONFIG_SANDBOX_SDL line in include/configs/sandbox.h or using: make sandbox_defconfig all NO_SDL=1 ./u-boot U-Boot will start on your computer, showing a sandbox emulation of the serial console: U-Boot 2014.04 (Mar 20 2014 - 19:06:00) DRAM: 128 MiB Using default environment In: serial Out: lcd Err: lcd => You can issue commands as your would normally. If the command you want is not supported you can add it to include/configs/sandbox.h. To exit, type 'reset' or press Ctrl-C. Console / LCD support --------------------- Assuming that CONFIG_SANDBOX_SDL is defined when building, you can run the sandbox with LCD and keyboard emulation, using something like: ./u-boot -d u-boot.dtb -l This will start U-Boot with a window showing the contents of the LCD. If that window has the focus then you will be able to type commands as you would on the console. You can adjust the display settings in the device tree file - see arch/sandbox/dts/sandbox.dts. Command-line Options -------------------- Various options are available, mostly for test purposes. Use -h to see available options. Some of these are described below. The terminal is normally in what is called 'raw-with-sigs' mode. This means that you can use arrow keys for command editing and history, but if you press Ctrl-C, U-Boot will exit instead of handling this as a keypress. Other options are 'raw' (so Ctrl-C is handled within U-Boot) and 'cooked' (where the terminal is in cooked mode and cursor keys will not work, Ctrl-C will exit). As mentioned above, -l causes the LCD emulation window to be shown. A device tree binary file can be provided with -d. If you edit the source (it is stored at arch/sandbox/dts/sandbox.dts) you must rebuild U-Boot to recreate the binary file. To execute commands directly, use the -c option. You can specify a single command, or multiple commands separated by a semicolon, as is normal in U-Boot. Be careful with quoting as the shell will normally process and swallow quotes. When -c is used, U-Boot exits after the command is complete, but you can force it to go to interactive mode instead with -i. Memory Emulation ---------------- Memory emulation is supported, with the size set by CONFIG_SYS_SDRAM_SIZE. The -m option can be used to read memory from a file on start-up and write it when shutting down. This allows preserving of memory contents across test runs. You can tell U-Boot to remove the memory file after it is read (on start-up) with the --rm_memory option. To access U-Boot's emulated memory within the code, use map_sysmem(). This function is used throughout U-Boot to ensure that emulated memory is used rather than the U-Boot application memory. This provides memory starting at 0 and extending to the size of the emulation. Storing State ------------- With sandbox you can write drivers which emulate the operation of drivers on real devices. Some of these drivers may want to record state which is preserved across U-Boot runs. This is particularly useful for testing. For example, the contents of a SPI flash chip should not disappear just because U-Boot exits. State is stored in a device tree file in a simple format which is driver- specific. You then use the -s option to specify the state file. Use -r to make U-Boot read the state on start-up (otherwise it starts empty) and -w to write it on exit (otherwise the stored state is left unchanged and any changes U-Boot made will be lost). You can also use -n to tell U-Boot to ignore any problems with missing state. This is useful when first running since the state file will be empty. The device tree file has one node for each driver - the driver can store whatever properties it likes in there. See 'Writing Sandbox Drivers' below for more details on how to get drivers to read and write their state. Running and Booting ------------------- Since there is no machine architecture, sandbox U-Boot cannot actually boot a kernel, but it does support the bootm command. Filesystems, memory commands, hashing, FIT images, verified boot and many other features are supported. When 'bootm' runs a kernel, sandbox will exit, as U-Boot does on a real machine. Of course in this case, no kernel is run. It is also possible to tell U-Boot that it has jumped from a temporary previous U-Boot binary, with the -j option. That binary is automatically removed by the U-Boot that gets the -j option. This allows you to write tests which emulate the action of chain-loading U-Boot, typically used in a situation where a second 'updatable' U-Boot is stored on your board. It is very risky to overwrite or upgrade the only U-Boot on a board, since a power or other failure will brick the board and require return to the manufacturer in the case of a consumer device. Supported Drivers ----------------- U-Boot sandbox supports these emulations: - Block devices - Chrome OS EC - GPIO - Host filesystem (access files on the host from within U-Boot) - I2C - Keyboard (Chrome OS) - LCD - Network - Serial (for console only) - Sound (incomplete - see sandbox_sdl_sound_init() for details) - SPI - SPI flash - TPM (Trusted Platform Module) A wide range of commands are implemented. Filesystems which use a block device are supported. Also sandbox supports driver model (CONFIG_DM) and associated commands. Linux RAW Networking Bridge --------------------------- The sandbox_eth_raw driver bridges traffic between the bottom of the network stack and the RAW sockets API in Linux. This allows much of the U-Boot network functionality to be tested in sandbox against real network traffic. For Ethernet network adapters, the bridge utilizes the RAW AF_PACKET API. This is needed to get access to the lowest level of the network stack in Linux. This means that all of the Ethernet frame is included. This allows the U-Boot network stack to be fully used. In other words, nothing about the Linux network stack is involved in forming the packets that end up on the wire. To receive the responses to packets sent from U-Boot the network interface has to be set to promiscuous mode so that the network card won't filter out packets not destined for its configured (on Linux) MAC address. The RAW sockets Ethernet API requires elevated privileges in Linux. You can either run as root, or you can add the capability needed like so: sudo /sbin/setcap "CAP_NET_RAW+ep" /path/to/u-boot The default device tree for sandbox includes an entry for eth0 on the sandbox host machine whose alias is "eth1". The following are a few examples of network operations being tested on the eth0 interface. sudo /path/to/u-boot -D DHCP .... set autoload no set ethact eth1 dhcp PING .... set autoload no set ethact eth1 dhcp ping $gatewayip TFTP .... set autoload no set ethact eth1 dhcp set serverip WWW.XXX.YYY.ZZZ tftpboot u-boot.bin The bridge also supports (to a lesser extent) the localhost interface, 'lo'. The 'lo' interface cannot use the RAW AF_PACKET API because the lo interface doesn't support Ethernet-level traffic. It is a higher-level interface that is expected only to be used at the AF_INET level of the API. As such, the most raw we can get on that interface is the RAW AF_INET API on UDP. This allows us to set the IP_HDRINCL option to include everything except the Ethernet header in the packets we send and receive. Because only UDP is supported, ICMP traffic will not work, so expect that ping commands will time out. The default device tree for sandbox includes an entry for lo on the sandbox host machine whose alias is "eth5". The following is an example of a network operation being tested on the lo interface. TFTP .... set ethact eth5 tftpboot u-boot.bin SPI Emulation ------------- Sandbox supports SPI and SPI flash emulation. This is controlled by the spi_sf argument, the format of which is: bus:cs:device:file bus - SPI bus number cs - SPI chip select number device - SPI device emulation name file - File on disk containing the data For example: dd if=/dev/zero of=spi.bin bs=1M count=4 ./u-boot --spi_sf 0:0:M25P16:spi.bin With this setup you can issue SPI flash commands as normal: =>sf probe SF: Detected M25P16 with page size 64 KiB, total 2 MiB =>sf read 0 0 10000 SF: 65536 bytes @ 0x0 Read: OK => Since this is a full SPI emulation (rather than just flash), you can also use low-level SPI commands: =>sspi 0:0 32 9f FF202015 This is issuing a READ_ID command and getting back 20 (ST Micro) part 0x2015 (the M25P16). Drivers are connected to a particular bus/cs using sandbox's state structure (see the 'spi' member). A set of operations must be provided for each driver. Configuration settings for the curious are: CONFIG_SANDBOX_SPI_MAX_BUS The maximum number of SPI buses supported by the driver (default 1). CONFIG_SANDBOX_SPI_MAX_CS The maximum number of chip selects supported by the driver (default 10). CONFIG_SPI_IDLE_VAL The idle value on the SPI bus Block Device Emulation ---------------------- U-Boot can use raw disk images for block device emulation. To e.g. list the contents of the root directory on the second partion of the image "disk.raw", you can use the following commands: =>host bind 0 ./disk.raw =>ls host 0:2 A disk image can be created using the following commands: $> truncate -s 1200M ./disk.raw $> echo -e "label: gpt\n,64M,U\n,,L" | /usr/sbin/sgdisk ./disk.raw $> lodev=`sudo losetup -P -f --show ./disk.raw` $> sudo mkfs.vfat -n EFI -v ${lodev}p1 $> sudo mkfs.ext4 -L ROOT -v ${lodev}p2 or utilize the device described in test/py/make_test_disk.py: #!/usr/bin/python import make_test_disk make_test_disk.makeDisk() Writing Sandbox Drivers ----------------------- Generally you should put your driver in a file containing the word 'sandbox' and put it in the same directory as other drivers of its type. You can then implement the same hooks as the other drivers. To access U-Boot's emulated memory, use map_sysmem() as mentioned above. If your driver needs to store configuration or state (such as SPI flash contents or emulated chip registers), you can use the device tree as described above. Define handlers for this with the SANDBOX_STATE_IO macro. See arch/sandbox/include/asm/state.h for documentation. In short you provide a node name, compatible string and functions to read and write the state. Since writing the state can expand the device tree, you may need to use state_setprop() which does this automatically and avoids running out of space. See existing code for examples. Testing ------- U-Boot sandbox can be used to run various tests, mostly in the test/ directory. These include: command_ut - Unit tests for command parsing and handling compression - Unit tests for U-Boot's compression algorithms, useful for security checking. It supports gzip, bzip2, lzma and lzo. driver model - Run this pytest ./test/py/test.py --bd sandbox --build -k ut_dm -v image - Unit tests for images: test/image/test-imagetools.sh - multi-file images test/image/test-fit.py - FIT images tracing - test/trace/test-trace.sh tests the tracing system (see README.trace) verified boot - See test/vboot/vboot_test.sh for this If you change or enhance any of the above subsystems, you shold write or expand a test and include it with your patch series submission. Test coverage in U-Boot is limited, as we need to work to improve it. Note that many of these tests are implemented as commands which you can run natively on your board if desired (and enabled). It would be useful to have a central script to run all of these. -- Simon Glass <sjg@chromium.org> Updated 22-Mar-14