rt-thread/bsp/bouffalo_lab/bl808
flyingcys 2d087c04a4 add bl808-d0 spi && i2c 2023-06-30 21:00:18 +08:00
..
builtin_imgs add bl60x/bl70x/bl61x/bl808 (#7063) 2023-03-19 14:41:18 +08:00
config add bl60x/bl70x/bl61x/bl808 (#7063) 2023-03-19 14:41:18 +08:00
d0 add bl808-d0 spi && i2c 2023-06-30 21:00:18 +08:00
figures [bsp/bouffalo_lab]add spi driver (#7435) 2023-05-04 11:49:38 +08:00
lp [bsp/bouffalo_lab]update sdio host driver (#7642) 2023-06-08 23:39:52 +08:00
m0 [bsp/bouffalo_lab]update sdio host driver (#7642) 2023-06-08 23:39:52 +08:00
tools [bsp][bl][tools] add dist function (#7278) 2023-05-12 00:14:55 -04:00
README.md add bl808-d0 spi && i2c 2023-06-30 21:00:18 +08:00
README_en.md add bl808-d0 spi && i2c 2023-06-30 21:00:18 +08:00
build_bl808_all.sh [bsp/bouffalo_lab]add bl808-d0 (#7373) 2023-04-26 08:50:03 +08:00
flash_prog_cfg.ini [bsp/bouffalo_lab]add bl808-d0 (#7373) 2023-04-26 08:50:03 +08:00

README_en.md

English | 中文

BL808 Board Support Package Documentation

1. Introduction

BL808 is a highly integrated AIoT chip with wireless connectivity units such as Wi-Fi/BT/BLE/Zigbee, multiple CPUs, audio and video codec, and AI hardware accelerator. It is suitable for various high-performance and low-power applications.

The BL808 chip consists of two subsystems: wireless and multimedia.

The wireless subsystem includes a RISC-V 32-bit high-performance CPU (m0) and integrated Wi-Fi/BT/Zigbee wireless subsystem, which enables various wireless connections and data transmission for diverse connectivity and user experiences. The multimedia subsystem includes a RISC-V 64-bit ultra-high-performance CPU (d0) and integrated DVP/CSI/H264/NPU video processing modules, which can be widely used in video surveillance, smart speakers, and other AI applications.

The components of the multimedia subsystem include:

  • NPU HW NN co-processor (BLAI-100) for AI applications
  • Camera interface
  • Audio codec
  • Video codec
  • Sensors
  • Display interface

The power management unit controls the low-power mode. It also supports various security features.

Peripheral interfaces include USB2.0, Ethernet, SD/MMC, SPI, UART, I2C, I2S, PWM, GPDAC/GPADC, ACOMP, PIR, Touch, IR remote, Display, and GPIO.

It supports flexible GPIO configuration, with a maximum of 40 GPIO pins.

The chip specifications are as follows:

Hardware Description
Chip Model bl808
CPU Three-core heterogeneous RISC-V CPUs:
RV64GCV 480MHz
RV32GCP 320MHz
RV32EMC 160MHz
RAM 768KB SRAM + 64MB UHS PSRAM
Peripherals Built-in AES and SHA256 algorithm accelerators
AI NN general hardware accelerator BLAI-100 for video/audio detection/recognition, 100GOPS computational power
Camera Interface DVP and MIPI-CSI
Display Interface SPI, DBI, DPI (RGB)
Wireless Supports Wi-Fi 802.11 b/g/n
Supports Bluetooth 5.x Dual-mode (BT+BLE)
Supports Wi-Fi/Bluetooth coexistence

2. RT-Thread Versions

BL808 is a three-core heterogeneous architecture, including m0, lp, and d0 cores. The current BSP supports all three cores running simultaneously and uses different RT-Thread versions for each core.

Name Core RT-Thread Version
M0 E907 RT-Thread Standard Edition
LP E902 RT-Thread Nano
D0 C906 RT-SMART

3. Compilation Instructions

BL808 is a three-core heterogeneous architecture, including m0, lp, and d0 cores. Each core needs to be compiled separately and burned to the corresponding location.

Flashing addresses:

Name Core Flash Address Description
M0 E907 0x00000
LP E902 0xC0000 Modify the lp flash address in bsp/bouffalo_lab/bl808/lp/board/linker_scripts/bl808_flash_lp.ld and bsp/bouffalo_lab/bl808/m0/board/board.h CONFIG_LP_FLASH_ADDR address
D0 C906 0x100000 Set in the SPL file. To adjust the d0 flash address, the SPL file and the packaged file bsp/bouffalo_lab/bl808/d0/merge_rtsmart.py need to be recompiled

3.1. m0/lp

  • Toolchain Download

Download the RISC-V toolchain from Download Link 1 or Download Link 2.

For Windows, use the [env tool][1] and extract the cross-compiler with the command tar -xvf Xuantie-900-gcc-elf-newlib-mingw-V2.6.1-20220906.tar.gz. Extracting the cross-compiler directly with Windows tools may cause compilation errors on Windows.

Add the path of the RISC-V toolchain to EXEC_PATH in rtconfig.py or specify the path using the RTT_EXEC_PATH environment variable.

Windows:

set RTT_EXEC_PATH=C:\Users\xxxx\Downloads\Xuantie-900-gcc-elf-newlib-x86_64-V2.6.1\bin

Linux:

export RTT_EXEC_PATH=/opt/Xuantie-900-gcc-elf-newlib-x86_64-V2.6.1/bin
  • Compilation

For Windows, it is recommended to use the [env tool][1]. Open the console and navigate to the bsp/bl808 directory, then select the core, m0 or lp, and run:

cd bsp/bl808/m0
menuconfig
pkgs --update

If you are using Linux, you can execute:

scons --menuconfig

It will automatically download the env-related scripts to the ~/.env directory, then execute:

source ~/.env/env.sh

cd bsp/bl808/m0
pkgs --update

After updating the software packages, use the command scons -j10 or scons -j10 --verbose to compile the board support package. Alternatively, you can use the scons --exec-path="GCC toolchain path" command to specify the toolchain path and compile at the same time.

If the compilation is successful, the rtthread.elf and rtthread_m0.bin files will be generated. The rtthread_m0.bin file needs to be burned into the device for execution.

  • Note

    Since BL808 is a three-core heterogeneous architecture, the lp and d0 cores are started through the m0 core. It is necessary to burn the m0 core correctly to enable all three cores to run properly.

    Configuration file for m0 flashing: bsp/bouffalo_lab/bl808/m0/flash_prog_cfg.ini

3.2. d0

bl808-d0 runs in S-mode and supports RT-Smart. The cross-compiler used is riscv64-unknown-linux-musl-gcc. Please refer to the Build Kernel Image for compilation instructions.

The starting address of the kernel virtual address is 0x50000000.

kernel_start

After the bl808-d0 is compiled, use the merge_rtsmart.py script to merge hw.dtb.5M, spl_bl808_d0.bin, opensbi_v0.6.bin, and rtthread_d0.bin into the final flash file whole_img_d0.bin, which should be burned at address 0x100000. Otherwise, the board will not be able to start.

The pre-compiled bin files are located in the bsp/bouffalo_lab/bl808/d0/pre_build_bin folder. If there are any modification requirements, you can download the Low-Starup-BL808 repository and modify it.

The separate flashing file for d0 is bsp/bouffalo_lab/bl808/d0/flash_prog_cfg.ini.

d0

3.3. Compilation and Flashing of Three Cores Simultaneously

  • You can run bsp/bouffalo_lab/bl808/build_bl808_all.sh to compile m0, lp, d0 cores one by one.
  • You can use the bsp/bouffalo_lab/bl808/flash_prog_cfg.ini flashing configuration file to flash m0, lp, and d0 cores simultaneously.

bl808

4. FAQ

  • In a Windows environment, when connecting the development board to the computer via the UART interface, only two USB converter devices are recognized, but the corresponding serial port device is not recognized.
    • Go to Device Manager, right-click on the corresponding USB converter device, go to Properties, and in the Advanced Settings, check the vcp option. After refreshing, you will see the corresponding serial port device.
    • Alternatively, you can install the following driver to solve the problem: https://dl.sipeed.com/shareURL/MAIX/tools/ftdi_vcp_driver
  • When connecting the computer to the board's UART port using a TypeC data cable, two serial ports will appear on the computer (if the mouse cannot move, unplug the USB and check Updating the board's bl702 firmware for a solution).