mirror of
https://github.com/tillitis/tillitis-key1.git
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475 lines
16 KiB
Markdown
475 lines
16 KiB
Markdown
# Tillitis TKey software
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**NOTE:** Documentation migrated to dev.tillitis.se, this is kept for
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history. This is likely to be outdated.
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## Introduction
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This text is both an introduction to and a requirement specification
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of the TKey firmware, its protocol, and an overview of how TKey
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applications are supposed to work. For an overview of the TKey
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concepts, see [System Description](system_description.md).
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First, some definitions:
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- Firmware - software in ROM responsible for loading applications. The
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firmware is included as part of the FPGA bit stream.
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- Application or app - software supplied by the host machine which is
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received, loaded, measured, and started by the firmware.
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The TKey has two modes of software operation: firmware mode and
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application mode. The firmware mode has the responsibility of
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receiving, measuring, loading, and starting the application. When the
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firmware is about to start the application it switches to a more
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constrained environment, the application mode.
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The firmware and application uses a memory mapped input/output (MMIO)
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for communication with the hardware. The memory map is constrained
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when running in application mode, e.g. FW-RAM and UDS isn't readable,
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and several MMIO addresses are either not readable or not writable for
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the application.
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See table in the [System
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Description](system_description.md#memory-mapped-hardware-functions)
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for details about access rules control in the memory system and MMIO.
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The firmware (and optionally all software) on the TKey can communicate
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to the host via the `UART_{RX,TX}_{STATUS,DATA}` registers, using the
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framing protocol described in [Framing
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Protocol](../framing_protocol/framing_protocol.md).
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The firmware defines a protocol on top of this framing layer which is
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used to bootstrap the application. All commands are initiated by the
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host. All commands receive a reply. See [Firmware
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protocol](#firmware-protocol) for specific details.
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Applications define their own protocol used for communication with
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their host part. They may or may not be based on the Framing Protocol.
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## CPU
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The CPU is a PicoRV32, a 32-bit RISC-V processor (arch: RV32IC\_Zmmul)
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which runs the firmware and the application. The firmware and
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application both run in RISC-V machine mode. All types are
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little-endian.
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## Constraints
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- ROM: 6 kByte.
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- RAM: 128 kByte.
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## Firmware
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The purpose of the firmware is to bootstrap and measure an
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application.
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The TKey has 128 kilobyte RAM. Firmware loads the application at the
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start of RAM. The current C runtime (`crt0.S`) of apps in our [apps
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repo](https://github.com/tillitis/tillitis-key1-apps) sets up the
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stack to start just below the end of RAM. This means that a larger app
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comes at the compromise of it having a smaller stack.
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The firmware is part of FPGA bitstream (ROM), and is loaded at
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`0x0000_0000`.
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When the firmware starts it clears all RAM and then wait for commands
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coming in on `UART_RX`.
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Typical use scenario:
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1. The host sends the `FW_CMD_LOAD_APP` command with the size of the
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device app and the optional user-supplied secret as arguments and
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and gets a `FW_RSP_LOAD_APP` back. After using this it's not
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possible to restart the loading of an application.
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2. If the the host receive a sucessful response, it will send
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multiple `FW_CMD_LOAD_APP_DATA` commands, together containing the
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full application.
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3. On receiving`FW_CMD_LOAD_APP_DATA` commands the firmware places
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the data into `0x4000_0000` and upwards. The firmware replies
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with a `FW_RSP_LOAD_APP_DATA` response to the host for each
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received block except the last data block.
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4. When the final block of the application image is received with a
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`FW_CMD_LOAD_APP_DATA`, the firmware measure the application by
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computing a BLAKE2s digest over the entire application. Then
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firmware send back the `FW_RSP_LOAD_APP_DATA_READY` response
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containing the measurement.
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5. The Compound Device Identifier (CDI) is then computed by using
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the `UDS`, application digest, and the `USS`, and placed in
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`CDI`. (see [Compound Device Identifier
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computation](#compound-device-identifier-computation)) Then the
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start address of the device app, `0x4000_0000`, is written to
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`APP_ADDR` and the size to `APP_SIZE` to let the device
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application know where it is loaded and how large it is, if it
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wants to relocate in RAM.
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6. The firmware now clears the special `FW_RAM` where it keeps it
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stack. After this it does no more function calls and uses no more
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automatic variables.
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7. Firmware starts the application by first switching to application
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mode by writing to the `SWITCH_APP` register. In this mode the
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MMIO region is restricted, e.g. some registers are removed
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(`UDS`), and some are switched from read/write to read-only (see
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[memory
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map](system_description.md#memory-mapped-hardware-functions)).
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Then the firmware jumps to what's in `APP_ADDR` which starts
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the application.
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There is now no other means of getting back from application mode
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to firmware mode than resetting/power cycling the device.
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### Developing firmware
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Standing in `hw/application_fpga/` you can run `make firmware.elf` to
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build just the firmware. You don't need all the FPGA development tools
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mentioned in [Toolchain setup](../toolchain_setup.md).
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You need clang with 32 RISC-V support `-march=rv32iczmmul` which comes
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in clang 15. If you don't have version 15 you might get by with
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`-march=rv32imc` but things will break if you ever cause it to emit
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`div` instructions.
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You also need `llvm-ar`, `llvm-objcopy`, `llvm-size` and `lld`.
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Typically these are all available in packages called "clang", "llvm",
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"lld" or similar.
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If your available `objcopy` and `size` commands is anything other than
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the default `llvm-objcopy` and `llvm-size` define `OBJCOPY` and `SIZE`
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to whatever they're called on your system before calling `make
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firmware.elf`.
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If you want to use our emulator, clone the `tk1` branch of [our
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version of qemu](https://github.com/tillitis/qemu) and build:
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```
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$ git clone -b tk1 https://github.com/tillitis/qemu
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$ mkdir qemu/build
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$ cd qemu/build
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$ ../configure --target-list=riscv32-softmmu --disable-werror
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$ make -j $(nproc)
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```
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(Built with warnings-as-errors disabled, see [this
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issue](https://github.com/tillitis/qemu/issues/3).)
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Run it like this:
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```
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$ /path/to/qemu/build/qemu-system-riscv32 -nographic -M tk1,fifo=chrid -bios firmware.elf \
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-chardev pty,id=chrid
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```
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This attaches the FIFO to a tty, something like `/dev/pts/16` which
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you can use with host software to talk to the firmware.
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To quit QEMU you can use: `Ctrl-a x` (see `Ctrl-a ?` for other commands).
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Debugging? Use the HTIF console by removing `-DNOCONSOLE` from the
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`CFLAGS` and using the helper functions in `lib.c` like `htif_puts()`
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`htif_putinthex()` `htif_hexdump()` and friends for printf-like
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debugging.
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You can add `-d guest_errors` to the qemu commandline to make QEMU
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send errors from the TK1 machine to stderr, typically things like
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memory writes outside of mapped regions.
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You can also use the qemu monitor for debugging, e.g. `info
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registers`, or run qemu with `-d in_asm` or `-d trace:riscv_trap`.
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### Reset
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The PicoRV32 starts executing at `0x0000_0000`. We allow no `.data` or
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`.bss` sections. Our firmware starts at the `_start` symbol in
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`start.S` which first clears all RAM for any remaining data from
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previous applications, then initializes a stack starting at the top of
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`FW_RAM` at `0xd000_0800` and downwards and then calls `main`.
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When the initialization is finished, the firmware waits for incoming
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commands from the host, by busy-polling the `UART_RX_{STATUS,DATA}`
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registers. When a complete command is read, the firmware executes the
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command.
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### Firmware state machine
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States:
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- `initial` - At start.
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- `loading` - Expect application data.
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- `run` - Computes CDI and starts the application.
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- `fail` - Stops waiting for commands, flashes LED forever.
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Commands in state `initial`:
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| *command* | *next state* |
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|-----------------------|--------------|
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| `FW_CMD_NAME_VERSION` | unchanged |
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| `FW_CMD_GET_UDI` | unchanged |
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| `FW_CMD_LOAD_APP` | `loading` |
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Commands in state `loading`:
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| *command* | *next state* |
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|------------------------|----------------------------------|
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| `FW_CMD_LOAD_APP_DATA` | unchanged or `run` on last chunk |
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Commands in state `run`: None.
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Commands in state `fail`: None.
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See [Firmware protocol](#firmware-protocol) for the definition of the
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specific commands and their responses.
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### User-supplied Secret (USS)
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USS is a 32 bytes long secret provided by the user. Typically a host
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program gets a secret from the user and then does a key derivation
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function of some sort, for instance a BLAKE2s, to get 32 bytes which
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it sends to the firmware to be part of the CDI computation.
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### Compound Device Identifier computation
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The CDI is computed by:
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```
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CDI = blake2s(UDS, blake2s(app), USS)
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```
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In an ideal world, software would never be able to read UDS at all and
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we would have a BLAKE2s function in hardware that would be the only
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thing able to read the UDS. Unfortunately, we couldn't fit a BLAKE2s
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implementation in the FPGA at this time.
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The firmware instead does the CDI computation using the special
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firmware-only `FW_RAM` which is invisible after switching to app mode.
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We keep the entire firmware stack in `FW_RAM` and clear it just before
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switching to app mode just in case.
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We sleep for a random number of cycles before reading out the UDS,
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call `blake2s_update()` with it and then immediately call
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`blake2s_update()` again with the program digest, destroying the UDS
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stored in the internal context buffer. UDS should now not be in
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`FW_RAM` anymore. We can read UDS only once per power cycle so UDS
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should now not be available to firmware at all.
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Then we continue with the CDI computation by updating with an optional
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USS and then finalizing the hash, storing the resulting digest in
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`CDI`.
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### Firmware protocol
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The firmware commands and responses are built on top of the [Framing
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Protocol](../framing_protocol/framing_protocol.md).
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The commands look like this:
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| *name* | *size (bytes)* | *comment* |
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|------------------|----------------|------------------------------------------|
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| Header | 1 | Framing protocol header including length |
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| | | of the rest of the frame |
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| Command/Response | 1 | Any of the below commands or responses |
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| Data | n | Any additional data |
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The responses might include a one byte status field where 0 is
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`STATUS_OK` and 1 is `STATUS_BAD`.
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Note that the integer types are little-endian (LE).
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#### `FW_CMD_NAME_VERSION` (0x01)
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Get the name and version of the stick.
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#### `FW_RSP_NAME_VERSION` (0x02)
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| *name* | *size (bytes)* | *comment* |
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|---------|----------------|----------------------|
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| name0 | 4 | ASCII |
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| name1 | 4 | ASCII |
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| version | 4 | Integer version (LE) |
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In a bad response the fields will be zeroed.
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#### `FW_CMD_LOAD_APP` (0x03)
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| *name* | *size (bytes)* | *comment* |
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|--------------|----------------|---------------------|
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| size | 4 | Integer (LE) |
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| uss-provided | 1 | 0 = false, 1 = true |
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| uss | 32 | Ignored if above 0 |
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Start an application loading session by setting the size of the
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expected device application and a user-supplied secret, if
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`uss-provided` is 1. Otherwise `USS` is ignored.
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#### `FW_RSP_LOAD_APP` (0x04)
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Response to `FW_CMD_LOAD_APP`
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| *name* | *size (bytes)* | *comment* |
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|--------|----------------|-----------------------------|
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| status | 1 | `STATUS_OK` or `STATUS_BAD` |
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#### `FW_CMD_LOAD_APP_DATA` (0x05)
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| *name* | *size (bytes)* | *comment* |
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|--------|----------------|---------------------|
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| data | 127 | Raw binary app data |
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Load 127 bytes of raw app binary into device RAM. Should be sent
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consecutively over the complete raw binary. (128 == largest frame
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length minus the command byte).
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#### `FW_RSP_LOAD_APP_DATA` (0x06)
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Response to all but the ultimate `FW_CMD_LOAD_APP_DATA` commands.
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| *name* | *size (bytes)* | *comment* |
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|--------|----------------|--------------------------|
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| status | 1 | `STATUS_OK`/`STATUS_BAD` |
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#### `FW_RSP_LOAD_APP_DATA_READY` (0x07)
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The response to the last `FW_CMD_LOAD_APP_DATA` is an
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`FW_RSP_LOAD_APP_DATA_READY` with the un-keyed hash digest for the
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application that was loaded. It allows the host to verify that the
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application was correctly loaded. This means that the CDI calculated
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will be correct given that the UDS has not been modified.
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| *name* | *size (bytes)* | *comment* |
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|--------|----------------|--------------------------|
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| status | 1 | `STATUS_OK`/`STATUS_BAD` |
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| digest | 32 | BLAKE2s(app) |
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#### `FW_CMD_GET_UDI` (0x08)
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Ask for the Unique Device Identifier (UDI) of the device.
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#### `FW_RSP_GET_UDI` (0x09)
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Response to `FW_CMD_GET_UDI`.
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| *name* | *size (bytes)* | *comment* |
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|--------|----------------|-----------------------------------------------------|
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| status | 1 | `STATUS_OK`/`STATUS_BAD` |
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| udi | 4 | Integer (LE) with Reserved (4 bit), Vendor (2 byte),|
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| | | Product ID (6 bit), Product Revision (6 bit) |
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| udi | 4 | Integer serial number (LE) |
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#### Get the name and version of the device
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```
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host ->
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u8 CMD[1 + 1];
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CMD[0].len = 1 // command frame format
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CMD[1] = 0x01 // FW_CMD_NAME_VERSION
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host <-
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u8 RSP[1 + 32]
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RSP[0].len = 32 // command frame format
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RSP[1] = 0x02 // FW_RSP_NAME_VERSION
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RSP[2..6] = NAME0
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RSP[6..10] = NAME1
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RSP[10..14] = VERSION
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RSP[14..] = 0
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```
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#### Load an application
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```
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host ->
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u8 CMD[1 + 128];
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CMD[0].len = 128 // command frame format
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CMD[1] = 0x03 // FW_CMD_LOAD_APP
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CMD[2..6] = APP_SIZE
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CMD[6] = USS supplied? 0 = false, 1 = true
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CMD[7..39] = USS
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CMD[40..] = 0
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host <-
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u8 RSP[1 + 4];
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RSP[0].len = 4 // command frame format
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RSP[1] = 0x04 // FW_RSP_LOAD_APP
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RSP[2] = STATUS
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RSP[3..] = 0
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repeat ceil(APP_SIZE / 127) times:
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host ->
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u8 CMD[1 + 128];
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CMD[0].len = 128 // command frame format
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CMD[1] = 0x05 // FW_CMD_LOAD_APP_DATA
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CMD[2..] = APP_DATA (127 bytes of app data, pad with zeros)
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host <-
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u8 RSP[1 + 4]
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RSP[0].len = 4 // command frame format
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RSP[1] = 0x06 // FW_RSP_LOAD_APP_DATA
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RSP[2] = STATUS
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RSP[3..] = 0
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```
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Except response from last chunk of app data which is:
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```
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host <-
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u8 RSP[1 + 128]
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RSP[0].len = 128 // command frame format
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RSP[1] = 0x07 // FW_RSP_LOAD_APP_DATA_READY
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RSP[2] = STATUS
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RSP[3..35] = app digest
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RSP[36..] = 0
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```
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### Firmware services
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The firmware exposes a BLAKE2s function through a function pointer
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located in MMIO `BLAKE2S` (see [memory
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map](system_description.md#memory-mapped-hardware-functions)) with the
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with function signature:
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```c
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int blake2s(void *out, unsigned long outlen, const void *key,
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unsigned long keylen, const void *in, unsigned long inlen,
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blake2s_ctx *ctx);
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```
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where `blake2s_ctx` is:
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```c
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typedef struct {
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uint8_t b[64]; // input buffer
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uint32_t h[8]; // chained state
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uint32_t t[2]; // total number of bytes
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size_t c; // pointer for b[]
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size_t outlen; // digest size
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} blake2s_ctx;
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```
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The `libcommon` library in
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[tillitis-key1-apps](https://github.com/tillitis/tillitis-key1-apps/)
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has a wrapper for using this function called `blake2s()`.
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## Applications
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See [our apps repo](https://github.com/tillitis/tillitis-key1-apps)
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for examples of client and TKey apps as well as libraries for writing
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both.
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