ARM Trusted Firmware User Guide =============================== Contents : 1. Introduction 2. Using the Software 3. Firmware Design 4. References 1. Introduction ---------------- The ARM Trusted Firmware implements a subset of the Trusted Board Boot Requirements (TBBR) Platform Design Document (PDD) [1] for ARM reference platforms. The TBB sequence starts when the platform is powered on and runs up to the stage where it hands-off control to firmware running in the normal world in DRAM. This is the cold boot path. The ARM Trusted Firmware also implements the Power State Coordination Interface ([PSCI]) PDD [2] as a runtime service. PSCI is the interface from normal world software to firmware implementing power management use-cases (for example, secondary CPU boot, hotplug and idle). Normal world software can access ARM Trusted Firmware runtime services via the ARM SMC (Secure Monitor Call) instruction. The SMC instruction must be used as mandated by the [SMC Calling Convention PDD][SMCCC] [3]. 2. Using the Software ---------------------- ### Host machine requirements The minimum recommended machine specification is an Intel Core2Duo clocking at 2.6GHz or above, and 12GB RAM. For best performance, use a machine with Intel Core i7 (SandyBridge) and 16GB of RAM. ### Tools The following tools are required to use the ARM Trusted Firmware: * Ubuntu desktop OS. The software has been tested on Ubuntu 12.04.02 (64-bit). The following packages are also needed: * `ia32-libs` package. * `make` and `uuid-dev` packages for building UEFI. * `bc` and `ncurses-dev` packages for building Linux. * Baremetal GNU GCC tools. Verified packages can be downloaded from [Linaro] [Linaro Toolchain]. The rest of this document assumes that the `gcc-linaro-aarch64-none-elf-4.8-2013.09-01_linux.tar.xz` tools are used. wget http://releases.linaro.org/13.09/components/toolchain/binaries/gcc-linaro-aarch64-none-elf-4.8-2013.09-01_linux.tar.xz tar -xf gcc-linaro-aarch64-none-elf-4.8-2013.09-01_linux.tar.xz * The Device Tree Compiler (DTC) included with Linux kernel 3.12-rc4 is used to build the Flattened Device Tree (FDT) source files (`.dts` files) provided with this release. * (Optional) For debugging, ARM [Development Studio 5 (DS-5)][DS-5] v5.16. ### Building the Trusted Firmware To build the software for the Base FVPs, follow these steps: 1. Clone the ARM Trusted Firmware repository from Github: git clone https://github.com/ARM-software/arm-trusted-firmware.git 2. Change to the trusted firmware directory: cd arm-trusted-firmware 3. Set the compiler path and build: CROSS_COMPILE=/aarch64-none-elf- make By default this produces a release version of the build. To produce a debug version instead, refer to the "Debugging options" section below. The build creates ELF and raw binary files in the current directory. It generates the following boot loader binary files from the ELF files: * `bl1.bin` * `bl2.bin` * `bl31.bin` 4. Copy the above 3 boot loader binary files to the directory where the FVPs are launched from. Symbolic links of the same names may be created instead. 5. (Optional) To clean the build directory use make distclean #### Debugging options To compile a debug version and make the build more verbose use CROSS_COMPILE=/aarch64-none-elf- make DEBUG=1 V=1 AArch64 GCC uses DWARF version 4 debugging symbols by default. Some tools (for example DS-5) might not support this and may need an older version of DWARF symbols to be emitted by GCC. This can be achieved by using the `-gdwarf-` flag, with the version being set to 2 or 3. Setting the version to 2 is recommended for DS-5 versions older than 5.16. When debugging logic problems it might also be useful to disable all compiler optimizations by using `-O0`. NOTE: Using `-O0` could cause output images to be larger and base addresses might need to be recalculated (see the later memory layout section). Extra debug options can be passed to the build system by setting `CFLAGS`: CFLAGS='-O0 -gdwarf-2' CROSS_COMPILE=/aarch64-none-elf- make DEBUG=1 V=1 ### Obtaining the normal world software #### Obtaining UEFI Download an archive of the [EDK2 (EFI Development Kit 2) source code][EDK2] supporting the Base FVPs. EDK2 is an open source implementation of the UEFI specification: wget http://sourceforge.net/projects/edk2/files/ARM/aarch64-uefi-rev14582.tgz/download -O aarch64-uefi-rev14582.tgz tar -xf aarch64-uefi-rev14582.tgz To build the software for the Base FVPs, follow these steps: 1. Change into the unpacked EDK2 source directory cd uefi 2. Copy build config templates to local workspace export EDK_TOOLS_PATH=$(pwd)/BaseTools . edksetup.sh $(pwd)/BaseTools/ 3. Rebuild EDK2 host tools make -C "$EDK_TOOLS_PATH" clean make -C "$EDK_TOOLS_PATH" 4. Build the software AARCH64GCC_TOOLS_PATH=/bin/ \ build -v -d3 -a AARCH64 -t ARMGCC \ -p ArmPlatformPkg/ArmVExpressPkg/ArmVExpress-FVP-AArch64.dsc The EDK2 binary for use with the ARM Trusted Firmware can then be found here: Build/ArmVExpress-FVP-AArch64/DEBUG_ARMGCC/FV/FVP_AARCH64_EFI.fd This will build EDK2 for the default settings as used by the FVPs. To boot Linux using a VirtioBlock file-system, the command line passed from EDK2 to the Linux kernel must be modified as described in the "Obtaining a File-system" section below. If legacy GICv2 locations are used, the EDK2 platform description must be updated. This is required as EDK2 does not support probing for the GIC location. To do this, open the `ArmPlatformPkg/ArmVExpressPkg/ArmVExpress-FVP-AArch64.dsc` file for editing and make the modifications as below. Rebuild EDK2 after doing a `clean`. gArmTokenSpaceGuid.PcdGicDistributorBase|0x2C001000 gArmTokenSpaceGuid.PcdGicInterruptInterfaceBase|0x2C002000 The EDK2 binary `FVP_AARCH64_EFI.fd` should be loaded into FVP FLASH0 via model parameters as described in the "Running the Software" section below. #### Obtaining a Linux kernel The software has been verified using Linux kernel version 3.12-rc4. Patches have been applied to the kernel in order to enable CPU hotplug. Preparing a Linux kernel for use on the FVPs with hotplug support can be done as follows (GICv2 support only): 1. Clone Linux: git clone git://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git The CPU hotplug features are not yet included in the mainline kernel. To use these, add the patches from Mark Rutland's kernel, based on Linux 3.12-rc4: cd linux git remote add -f --tags markr git://linux-arm.org/linux-mr.git git checkout -b hotplug arm64-cpu-hotplug-20131023 2. Build with the Linaro GCC tools. # in linux/ make mrproper make ARCH=arm64 defconfig # Enable Hotplug make ARCH=arm64 menuconfig # Kernel Features ---> [*] Support for hot-pluggable CPUs CROSS_COMPILE=/path/to/aarch64-none-elf- make -j6 ARCH=arm64 3. Copy the Linux image `arch/arm64/boot/Image` to the working directory from where the FVP is launched. A symbolic link may also be created instead. #### Obtaining the Flattened Device Trees Depending on the FVP configuration and Linux configuration used, different FDT files are required. FDTs for the Base FVP can be found in the Trusted Firmware source directory under `fdts`. * `fvp-base-gicv2-psci.dtb` (Default) For use with both AEMv8 and Cortex-A57-A53 Base FVPs with default memory map configuration. * `fvp-base-gicv2legacy-psci.dtb` For use with both AEMv8 and Cortex-A57-A53 Base FVPs with legacy GICv2 memory map configuration. * `fvp-base-gicv3-psci.dtb` For use with AEMv8 Base FVP with default memory map configuration and Linux GICv3 support. Copy the chosen FDT blob as `fdt.dtb` to the directory from which the FVP is launched. A symbolic link may also be created instead. #### Obtaining a File-system To prepare a Linaro LAMP based Open Embedded file-system, the following instructions can be used as a guide. The file-system can be provided to Linux via VirtioBlock or as a RAM-disk. Both methods are described below. ##### Prepare VirtioBlock To prepare a VirtioBlock file-system, do the following: 1. Download and unpack the disk image. NOTE: The unpacked disk image grows to 2 GiB in size. wget http://releases.linaro.org/13.09/openembedded/aarch64/vexpress64-openembedded_lamp-armv8_20130927-7.img.gz gunzip vexpress64-openembedded_lamp-armv8_20130927-7.img.gz 2. Make sure the Linux kernel has Virtio support enabled using `make ARCH=arm64 menuconfig`. Device Drivers ---> Virtio drivers ---> <*> Platform bus driver for memory mapped virtio devices Device Drivers ---> [*] Block devices ---> <*> Virtio block driver File systems ---> <*> The Extended 4 (ext4) filesystem If some of these configurations are missing, enable them, save the kernel configuration, then rebuild the kernel image using the instructions provided in the section "Obtaining a Linux kernel". 3. Change the Kernel command line to include `root=/dev/vda2`. This can either be done in the EDK2 boot menu or in the platform file. Editing the platform file and rebuilding EDK2 will make the change persist. To do this: 1. In EDK, edit the following file: ArmPlatformPkg/ArmVExpressPkg/ArmVExpress-FVP-AArch64.dsc 2. Add `root=/dev/vda2` to: gArmPlatformTokenSpaceGuid.PcdDefaultBootArgument|"" 3. Remove the entry: gArmPlatformTokenSpaceGuid.PcdDefaultBootInitrdPath|"" 4. Rebuild EDK2 (see "Obtaining UEFI" section above). 4. The file-system image file should be provided to the model environment by passing it the correct command line option. In the Base FVP the following option should be provided in addition to the ones described in the "Running the software" section below. NOTE: A symbolic link to this file cannot be used with the FVP; the path to the real file must be provided. -C bp.virtioblockdevice.image_path="vexpress64-openembedded_lamp-armv8_20130927-7.img" 5. Ensure that the FVP doesn't output any error messages. If the following error message is displayed: ERROR: BlockDevice: Failed to open "vexpress64-openembedded_lamp-armv8_20130927-7.img"! then make sure the path to the file-system image in the model parameter is correct and that read permission is correctly set on the file-system image file. ##### Prepare RAM-disk NOTE: The RAM-disk option does not currently work with the Linux kernel version described above; use the VirtioBlock method instead. For further information please see the "Known issues" section in the [Change Log]. To Prepare a RAM-disk file-system, do the following: 1. Download the file-system image: wget http://releases.linaro.org/13.09/openembedded/aarch64/linaro-image-lamp-genericarmv8-20130912-487.rootfs.tar.gz 2. Modify the Linaro image: # Prepare for use as RAM-disk. Normally use MMC, NFS or VirtioBlock. # Be careful, otherwise you could damage your host file-system. mkdir tmp; cd tmp sudo sh -c "zcat ../linaro-image-lamp-genericarmv8-20130912-487.rootfs.tar.gz | cpio -id" sudo ln -s sbin/init . sudo ln -s S35mountall.sh etc/rcS.d/S03mountall.sh sudo sh -c "echo 'devtmpfs /dev devtmpfs mode=0755,nosuid 0 0' >> etc/fstab" sudo sh -c "find . | cpio --quiet -H newc -o | gzip -3 -n > ../filesystem.cpio.gz" cd .. 3. Copy the resultant `filesystem.cpio.gz` to the directory where the FVP is launched from. A symbolic link may also be created instead. ### Running the software This release of the ARM Trusted Firmware has been tested on the following ARM FVPs (64-bit versions only). * `FVP_Base_AEMv8A-AEMv8A` (Version 5.1 build 8) * `FVP_Base_Cortex-A57x4-A53x4` (Version 5.1 build 8) Please refer to the FVP documentation for a detailed description of the model parameter options. A brief description of the important ones that affect the ARM Trusted Firmware and normal world software behavior is provided below. #### Running on the AEMv8 Base FVP The following `FVP_Base_AEMv8A-AEMv8A` parameters should be used to boot Linux with 8 CPUs using the ARM Trusted Firmware. NOTE: Using `cache_state_modelled=1` makes booting very slow. The software will still work (and run much faster) without this option but this will hide any cache maintenance defects in the software. NOTE: Using the `-C bp.virtioblockdevice.image_path` parameter is not necessary if a Linux RAM-disk file-system is used (see the "Obtaining a File-system" section above). FVP_Base_AEMv8A-AEMv8A \ -C pctl.startup=0.0.0.0 \ -C bp.secure_memory=0 \ -C cluster0.NUM_CORES=4 \ -C cluster1.NUM_CORES=4 \ -C cache_state_modelled=1 \ -C bp.pl011_uart0.untimed_fifos=1 \ -C bp.secureflashloader.fname= \ -C bp.flashloader0.fname= \ -C bp.virtioblockdevice.image_path="vexpress64-openembedded_lamp-armv8_20130927-7.img" #### Running on the Cortex-A57-A53 Base FVP The following `FVP_Base_Cortex-A57x4-A53x4` model parameters should be used to boot Linux with 8 CPUs using the ARM Trusted Firmware. NOTE: Using `cache_state_modelled=1` makes booting very slow. The software will still work (and run much faster) without this option but this will hide any cache maintenance defects in the software. NOTE: Using the `-C bp.virtioblockdevice.image_path` parameter is not necessary if a Linux RAM-disk file-system is used (see the "Obtaining a File-system" section above). FVP_Base_Cortex-A57x4-A53x4 \ -C pctl.startup=0.0.0.0 \ -C bp.secure_memory=0 \ -C cache_state_modelled=1 \ -C bp.pl011_uart0.untimed_fifos=1 \ -C bp.secureflashloader.fname= \ -C bp.flashloader0.fname= \ -C bp.virtioblockdevice.image_path="vexpress64-openembedded_lamp-armv8_20130927-7.img" ### Configuring the GICv2 memory map The Base FVP models support GICv2 with the default model parameters at the following addresses. GICv2 Distributor Interface 0x2f000000 GICv2 CPU Interface 0x2c000000 GICv2 Virtual CPU Interface 0x2c010000 GICv2 Hypervisor Interface 0x2c02f000 The models can be configured to support GICv2 at addresses corresponding to the legacy (Versatile Express) memory map as follows. GICv2 Distributor Interface 0x2c001000 GICv2 CPU Interface 0x2c002000 GICv2 Virtual CPU Interface 0x2c004000 GICv2 Hypervisor Interface 0x2c006000 The choice of memory map is reflected in the build field (bits[15:12]) in the `SYS_ID` register (Offset `0x0`) in the Versatile Express System registers memory map (`0x1c010000`). * `SYS_ID.Build[15:12]` `0x1` corresponds to the presence of the default GICv2 memory map. This is the default value. * `SYS_ID.Build[15:12]` `0x0` corresponds to the presence of the Legacy VE GICv2 memory map. This value can be configured as described in the next section. NOTE: If the legacy VE GICv2 memory map is used, then the corresponding FDT and UEFI images should be used. #### Configuring AEMv8 Base FVP for legacy VE memory map The following parameters configure the GICv2 memory map in legacy VE mode: NOTE: Using the `-C bp.virtioblockdevice.image_path` parameter is not necessary if a Linux RAM-disk file-system is used (see the "Obtaining a File-system" section above). FVP_Base_AEMv8A-AEMv8A \ -C cluster0.gic.GICD-offset=0x1000 \ -C cluster0.gic.GICC-offset=0x2000 \ -C cluster0.gic.GICH-offset=0x4000 \ -C cluster0.gic.GICH-other-CPU-offset=0x5000 \ -C cluster0.gic.GICV-offset=0x6000 \ -C cluster0.gic.PERIPH-size=0x8000 \ -C cluster1.gic.GICD-offset=0x1000 \ -C cluster1.gic.GICC-offset=0x2000 \ -C cluster1.gic.GICH-offset=0x4000 \ -C cluster1.gic.GICH-other-CPU-offset=0x5000 \ -C cluster1.gic.GICV-offset=0x6000 \ -C cluster1.gic.PERIPH-size=0x8000 \ -C gic_distributor.GICD-alias=0x2c001000 \ -C bp.variant=0x0 \ -C bp.virtioblockdevice.image_path="vexpress64-openembedded_lamp-armv8_20130927-7.img" The last parameter sets the build variant field of the `SYS_ID` register to `0x0`. This allows the ARM Trusted Firmware to detect the legacy VE memory map while configuring the GIC. #### Configuring Cortex-A57-A53 Base FVP for legacy VE memory map Configuration of the GICv2 as per the legacy VE memory map is controlled by the following parameter. In this case, separate configuration of the `SYS_ID` register is not required. NOTE: Using the `-C bp.virtioblockdevice.image_path` parameter is not necessary if a Linux RAM-disk file-system is used (see the "Obtaining a File-system" section above). FVP_Base_Cortex-A57x4-A53x4 \ -C legacy_gicv2_map=1 \ -C bp.virtioblockdevice.image_path="vexpress64-openembedded_lamp-armv8_20130927-7.img" 3. Firmware Design ------------------- The cold boot path starts when the platform is physically turned on. One of the CPUs released from reset is chosen as the primary CPU, and the remaining CPUs are considered secondary CPUs. The primary CPU is chosen through platform-specific means. The cold boot path is mainly executed by the primary CPU, other than essential CPU initialization executed by all CPUs. The secondary CPUs are kept in a safe platform-specific state until the primary CPU has performed enough initialization to boot them. The cold boot path in this implementation of the ARM Trusted Firmware is divided into three stages (in order of execution): * Boot Loader stage 1 (BL1) * Boot Loader stage 2 (BL2) * Boot Loader stage 3 (BL3-1). The '1' distinguishes this from other 3rd level boot loader stages. The ARM Fixed Virtual Platforms (FVPs) provide trusted ROM, trusted SRAM and trusted DRAM regions. Each boot loader stage uses one or more of these memories for its code and data. ### BL1 This stage begins execution from the platform's reset vector in trusted ROM at EL3. BL1 code starts at `0x00000000` (trusted ROM) in the FVP memory map. The BL1 data section is placed at the start of trusted SRAM, `0x04000000`. The functionality implemented by this stage is as follows. #### Determination of boot path Whenever a CPU is released from reset, BL1 needs to distinguish between a warm boot and a cold boot. This is done using a platform-specific mechanism. The ARM FVPs implement a simple power controller at `0x1c100000`. The `PSYS` register (`0x10`) is used to distinguish between a cold and warm boot. This information is contained in the `PSYS.WK[25:24]` field. Additionally, a per-CPU mailbox is maintained in trusted DRAM (`0x00600000`), to which BL1 writes an entrypoint. Each CPU jumps to this entrypoint upon warm boot. During cold boot, BL1 places the secondary CPUs in a safe platform-specific state while the primary CPU executes the remaining cold boot path as described in the following sections. #### Architectural initialization BL1 performs minimal architectural initialization as follows. * Exception vectors BL1 sets up simple exception vectors for both synchronous and asynchronous exceptions. The default behavior upon receiving an exception is to set a status code. In the case of the FVP this code is written to the Versatile Express System LED register in the following format: SYS_LED[0] - Security state (Secure=0/Non-Secure=1) SYS_LED[2:1] - Exception Level (EL3=0x3, EL2=0x2, EL1=0x1, EL0=0x0) SYS_LED[7:3] - Exception Class (Sync/Async & origin). The values for each exception class are: 0x0 : Synchronous exception from Current EL with SP_EL0 0x1 : IRQ exception from Current EL with SP_EL0 0x2 : FIQ exception from Current EL with SP_EL0 0x3 : System Error exception from Current EL with SP_EL0 0x4 : Synchronous exception from Current EL with SP_ELx 0x5 : IRQ exception from Current EL with SP_ELx 0x6 : FIQ exception from Current EL with SP_ELx 0x7 : System Error exception from Current EL with SP_ELx 0x8 : Synchronous exception from Lower EL using aarch64 0x9 : IRQ exception from Lower EL using aarch64 0xa : FIQ exception from Lower EL using aarch64 0xb : System Error exception from Lower EL using aarch64 0xc : Synchronous exception from Lower EL using aarch32 0xd : IRQ exception from Lower EL using aarch32 0xe : FIQ exception from Lower EL using aarch32 0xf : System Error exception from Lower EL using aarch32 A write to the LED register reflects in the System LEDs (S6LED0..7) in the CLCD window of the FVP. This behavior is because this boot loader stage does not expect to receive any exceptions other than the SMC exception. For the latter, BL1 installs a simple stub. The stub expects to receive only a single type of SMC (determined by its function ID in the general purpose register `X0`). This SMC is raised by BL2 to make BL1 pass control to BL3-1 (loaded by BL2) at EL3. Any other SMC leads to an assertion failure. * MMU setup BL1 sets up EL3 memory translation by creating page tables to cover the first 4GB of physical address space. This covers all the memories and peripherals needed by BL1. * Control register setup - `SCTLR_EL3`. Instruction cache is enabled by setting the `SCTLR_EL3.I` bit. Alignment and stack alignment checking is enabled by setting the `SCTLR_EL3.A` and `SCTLR_EL3.SA` bits. Exception endianness is set to little-endian by clearing the `SCTLR_EL3.EE` bit. - `CPUECTLR`. When the FVP includes a model of a specific ARM processor implementation (for example A57 or A53), then intra-cluster coherency is enabled by setting the `CPUECTLR.SMPEN` bit. The AEMv8 Base FVP is inherently coherent so does not implement `CPUECTLR`. - `SCR`. Use of the HVC instruction from EL1 is enabled by setting the `SCR.HCE` bit. FIQ exceptions are configured to be taken in EL3 by setting the `SCR.FIQ` bit. The register width of the next lower exception level is set to AArch64 by setting the `SCR.RW` bit. - `CPTR_EL3`. Accesses to the `CPACR` from EL1 or EL2, or the `CPTR_EL2` from EL2 are configured to not trap to EL3 by clearing the `CPTR_EL3.TCPAC` bit. Instructions that access the registers associated with Floating Point and Advanced SIMD execution are configured to not trap to EL3 by clearing the `CPTR_EL3.TFP` bit. - `CNTFRQ_EL0`. The `CNTFRQ_EL0` register is programmed with the base frequency of the system counter, which is retrieved from the first entry in the frequency modes table. - Generic Timer. The system level implementation of the generic timer is enabled through the memory mapped interface. #### Platform initialization BL1 enables issuing of snoop and DVM (Distributed Virtual Memory) requests from the CCI-400 slave interface corresponding to the cluster that includes the primary CPU. BL1 also initializes UART0 (PL011 console), which enables access to the `printf` family of functions. #### BL2 image load and execution BL1 execution continues as follows: 1. BL1 determines the amount of free trusted SRAM memory available by calculating the extent of its own data section, which also resides in trusted SRAM. BL1 loads a BL2 raw binary image through semi-hosting, at a platform-specific base address. The filename of the BL2 raw binary image on the host file system must be `bl2.bin`. If the BL2 image file is not present or if there is not enough free trusted SRAM the following error message is printed: "Failed to load boot loader stage 2 (BL2) firmware." If the load is successful, BL1 updates the limits of the remaining free trusted SRAM. It also populates information about the amount of trusted SRAM used by the BL2 image. The exact load location of the image is provided as a base address in the platform header. Further description of the memory layout can be found later in this document. 2. BL1 prints the following string from the primary CPU to indicate successful execution of the BL1 stage: "Booting trusted firmware boot loader stage 1" 3. BL1 passes control to the BL2 image at Secure EL1, starting from its load address. 4. BL1 also passes information about the amount of trusted SRAM used and available for use. This information is populated at a platform-specific memory address. ### BL2 BL1 loads and passes control to BL2 at Secure EL1. BL2 is linked against and loaded at a platform-specific base address (more information can found later in this document). The functionality implemented by BL2 is as follows. #### Architectural initialization BL2 performs minimal architectural initialization required for subsequent stages of the ARM Trusted Firmware and normal world software. It sets up Secure EL1 memory translation by creating page tables to address the first 4GB of the physical address space in a similar way to BL1. EL1 and EL0 are given access to Floating Point & Advanced SIMD registers by clearing the `CPACR.FPEN` bits. #### Platform initialization BL2 does not perform any platform initialization that affects subsequent stages of the ARM Trusted Firmware or normal world software. It copies the information regarding the trusted SRAM populated by BL1 using a platform-specific mechanism. It also calculates the limits of DRAM (main memory) to determine whether there is enough space to load the normal world software images. A platform defined base address is used to specify the load address for the BL3-1 image. #### Normal world image load BL2 loads a rich boot firmware image (UEFI). The image executes in the normal world. BL2 relies on BL3-1 to pass control to the normal world software image it loads. Hence, BL2 populates a platform-specific area of memory with the entrypoint and Current Program Status Register (`CPSR`) of the normal world software image. The entrypoint is the load address of the normal world software image. The `CPSR` is determined as specified in Section 5.13 of the [PSCI PDD] [PSCI]. This information is passed to BL3-1. ##### UEFI firmware load By default, BL2 assumes the UEFI image is present at the base of NOR flash0 (`0x08000000`), and arranges for BL3-1 to pass control to that location. As mentioned earlier, BL2 populates platform-specific memory with the entrypoint and `CPSR` of the UEFI image. #### BL3-1 image load and execution BL2 execution continues as follows: 1. BL2 loads the BL3-1 image into a platform-specific address in trusted SRAM. This is done using semi-hosting. The image is identified by the file `bl31.bin` on the host file-system. If there is not enough memory to load the image or the image is missing it leads to an assertion failure. If the BL3-1 image loads successfully, BL1 updates the amount of trusted SRAM used and available for use by BL3-1. This information is populated at a platform-specific memory address. 2. BL2 passes control back to BL1 by raising an SMC, providing BL1 with the BL3-1 entrypoint. The exception is handled by the SMC exception handler installed by BL1. 3. BL1 turns off the MMU and flushes the caches. It clears the `SCTLR_EL3.M/I/C` bits, flushes the data cache to the point of coherency and invalidates the TLBs. 4. BL1 passes control to BL3-1 at the specified entrypoint at EL3. ### BL3-1 The image for this stage is loaded by BL2 and BL1 passes control to BL3-1 at EL3. BL3-1 executes solely in trusted SRAM. BL3-1 is linked against and loaded at a platform-specific base address (more information can found later in this document). The functionality implemented by BL3-1 is as follows. #### Architectural initialization Currently, BL3-1 performs a similar architectural initialization to BL1 as far as system register settings are concerned. Since BL1 code resides in ROM, architectural initialization in BL3-1 allows override of any previous initialization done by BL1. BL3-1 creates page tables to address the first 4GB of physical address space and initializes the MMU accordingly. It replaces the exception vectors populated by BL1 with its own. BL3-1 exception vectors signal error conditions in the same way as BL1 does if an unexpected exception is raised. They implement more elaborate support for handling SMCs since this is the only mechanism to access the runtime services implemented by BL3-1 (PSCI for example). BL3-1 checks each SMC for validity as specified by the [SMC calling convention PDD][SMCCC] before passing control to the required SMC handler routine. #### Platform initialization BL3-1 performs detailed platform initialization, which enables normal world software to function correctly. It also retrieves entrypoint information for the normal world software image loaded by BL2 from the platform defined memory address populated by BL2. * GICv2 initialization: - Enable group0 interrupts in the GIC CPU interface. - Configure group0 interrupts to be asserted as FIQs. - Disable the legacy interrupt bypass mechanism. - Configure the priority mask register to allow interrupts of all priorities to be signaled to the CPU interface. - Mark SGIs 8-15, the secure physical timer interrupt (#29) and the trusted watchdog interrupt (#56) as group0 (secure). - Target the trusted watchdog interrupt to CPU0. - Enable these group0 interrupts in the GIC distributor. - Configure all other interrupts as group1 (non-secure). - Enable signaling of group0 interrupts in the GIC distributor. * GICv3 initialization: If a GICv3 implementation is available in the platform, BL3-1 initializes the GICv3 in GICv2 emulation mode with settings as described for GICv2 above. * Power management initialization: BL3-1 implements a state machine to track CPU and cluster state. The state can be one of `OFF`, `ON_PENDING`, `SUSPEND` or `ON`. All secondary CPUs are initially in the `OFF` state. The cluster that the primary CPU belongs to is `ON`; any other cluster is `OFF`. BL3-1 initializes the data structures that implement the state machine, including the locks that protect them. BL3-1 accesses the state of a CPU or cluster immediately after reset and before the MMU is enabled in the warm boot path. It is not currently possible to use 'exclusive' based spinlocks, therefore BL3-1 uses locks based on Lamport's Bakery algorithm instead. BL3-1 allocates these locks in device memory. They are accessible irrespective of MMU state. * Runtime services initialization: The only runtime service implemented by BL3-1 is PSCI. The complete PSCI API is not yet implemented. The following functions are currently implemented: - `PSCI_VERSION` - `CPU_OFF` - `CPU_ON` - `AFFINITY_INFO` The `CPU_ON` and `CPU_OFF` functions implement the warm boot path in ARM Trusted Firmware. These are the only functions which have been tested. `AFFINITY_INFO` & `PSCI_VERSION` are present but completely untested in this release. Unsupported PSCI functions that can return, return the `NOT_SUPPORTED` (`-1`) error code. Other unsupported PSCI functions that don't return, signal an assertion failure. BL3-1 returns the error code `-1` if an SMC is raised for any other runtime service. This behavior is mandated by the [SMC calling convention PDD] [SMCCC]. ### Normal world software execution BL3-1 uses the entrypoint information provided by BL2 to jump to the normal world software image at the highest available Exception Level (EL2 if available, otherwise EL1). ### Memory layout on Base FVP ### The current implementation of the image loader has some limitations. It is designed to load images dynamically, at a load address chosen to minimize memory fragmentation. The chosen image location can be either at the top or the bottom of free memory. However, until this feature is fully functional, the code also contains support for loading images at a link-time fixed address. The code that dynamically calculates the load address is bypassed and the load address is specified statically by the platform. BL1 is always loaded at address `0x0`. BL2 and BL3-1 are loaded at specified locations in Trusted SRAM. The lack of dynamic image loader support means these load addresses must currently be adjusted as the code grows. The individual images must be linked against their ultimate runtime locations. BL2 is loaded near the top of the Trusted SRAM. BL3-1 is loaded between BL1 and BL2. As a general rule, the following constraints must always be enforced: 1. `BL2_MAX_ADDR <= ()` 2. `BL31_BASE >= BL1_MAX_ADDR` 3. `BL2_BASE >= BL31_MAX_ADDR` Constraint 1 is enforced by BL2's linker script. If it is violated then the linker will report an error while building BL2 to indicate that it doesn't fit. For example: aarch64-none-elf-ld: address 0x40400c8 of bl2.elf section `.bss' is not within region `RAM' This error means that the BL2 base address needs to be moved down. Be sure that the new BL2 load address still obeys constraint 3. Constraints 2 & 3 must currently be checked by hand. To ensure they are enforced, first determine the maximum addresses used by BL1 and BL3-1. This can be deduced from the link map files of the different images. The BL1 link map file (`bl1.map`) gives these 2 values: * `FIRMWARE_RAM_COHERENT_START` * `FIRMWARE_RAM_COHERENT_SIZE` The maximum address used by BL1 can then be easily determined: BL1_MAX_ADDR = FIRMWARE_RAM_COHERENT_START + FIRMWARE_RAM_COHERENT_SIZE The BL3-1 link map file (`bl31.map`) gives the following value: * `BL31_DATA_STOP`. This is the the maximum address used by BL3-1. The current implementation can result in wasted space because a simplified `meminfo` structure represents the extents of free memory. For example, to load BL2 at address `0x04020000`, the resulting memory layout should be as follows: ------------ 0x04040000 | | <- Free space (1) |----------| | BL2 | |----------| BL2_BASE (0x0402D000) | | <- Free space (2) |----------| | BL1 | ------------ 0x04000000 In the current implementation, we need to specify whether BL2 is loaded at the top or bottom of the free memory. BL2 is top-loaded so in the example above, the free space (1) above BL2 is hidden, resulting in the following view of memory: ------------ 0x04040000 | | | | | BL2 | |----------| BL2_BASE (0x0402D000) | | <- Free space (2) |----------| | BL1 | ------------ 0x04000000 BL3-1 is bottom-loaded above BL1. For example, if BL3-1 is bottom-loaded at `0x0400E000`, the memory layout should look like this: ------------ 0x04040000 | | | | | BL2 | |----------| BL2_BASE (0x0402D000) | | <- Free space (2) | | |----------| | | | BL31 | |----------| BL31_BASE (0x0400E000) | | <- Free space (3) |----------| | BL1 | ------------ 0x04000000 But the free space (3) between BL1 and BL3-1 is wasted, resulting in the following view: ------------ 0x04040000 | | | | | BL2 | |----------| BL2_BASE (0x0402D000) | | <- Free space (2) | | |----------| | | | | | BL31 | BL31_BASE (0x0400E000) | | |----------| | BL1 | ------------ 0x04000000 ### Code Structure ### Trusted Firmware code is logically divided between the three boot loader stages mentioned in the previous sections. The code is also divided into the following categories (present as directories in the source code): * **Architecture specific.** This could be AArch32 or AArch64. * **Platform specific.** Choice of architecture specific code depends upon the platform. * **Common code.** This is platform and architecture agnostic code. * **Library code.** This code comprises of functionality commonly used by all other code. * **Stage specific.** Code specific to a boot stage. * **Drivers.** Each boot loader stage uses code from one or more of the above mentioned categories. Based upon the above, the code layout looks like this: Directory Used by BL1? Used by BL2? Used by BL3? bl1 Yes No No bl2 No Yes No bl31 No No Yes arch Yes Yes Yes plat Yes Yes Yes drivers Yes No Yes common Yes Yes Yes lib Yes Yes Yes All assembler files have the `.S` extension. The linker files for each boot stage has the `.ld.S` extension. These are processed by GCC to create the resultant `.ld` files used for linking. FDTs provide a description of the hardware platform and is used by the Linux kernel at boot time. These can be found in the `fdts` directory. 4. References -------------- 1. Trusted Board Boot Requirements CLIENT PDD (ARM DEN 0006B-5). Available under NDA through your ARM account representative. 2. [Power State Coordination Interface PDD (ARM DEN 0022B.b)][PSCI]. 3. [SMC Calling Convention PDD (ARM DEN 0028A)][SMCCC]. - - - - - - - - - - - - - - - - - - - - - - - - - - _Copyright (c) 2013 ARM Ltd. All rights reserved._ [Change Log]: change-log.md [Linaro Toolchain]: http://releases.linaro.org/13.09/components/toolchain/binaries/ [EDK2]: http://sourceforge.net/projects/edk2/files/ARM/aarch64-uefi-rev14582.tgz/download [DS-5]: http://www.arm.com/products/tools/software-tools/ds-5/index.php [PSCI]: http://infocenter.arm.com/help/topic/com.arm.doc.den0022b/index.html "Power State Coordination Interface PDD (ARM DEN 0022B.b)" [SMCCC]: http://infocenter.arm.com/help/topic/com.arm.doc.den0028a/index.html "SMC Calling Convention PDD (ARM DEN 0028A)"