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This commit is contained in:
qitas 2021-05-17 11:27:15 +08:00
parent ecfb540ed3
commit ddea639a7b
12 changed files with 2200 additions and 2 deletions
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36
.github/workflows/linux-sdcc-4.0.0.yml vendored Normal file
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name: SDCC_4.0.0
on:
push:
branches:
- master
- github_actions
tags:
- '*'
pull_request:
branches:
- master
- github_actions
jobs:
build:
runs-on: ubuntu-latest
steps:
- name: Check out
uses: actions/checkout@v2
- name: Download SDCC
run: |
wget https://sourceforge.net/projects/sdcc/files/sdcc-linux-amd64/4.0.0/sdcc-4.0.0-amd64-unknown-linux2.5.tar.bz2
tar -xf sdcc-4.0.0-amd64-unknown-linux2.5.tar.bz2
echo `pwd`/sdcc-4.0.0/bin >> $GITHUB_PATH
- name: Build
working-directory: src/template
run: make
- uses: actions/upload-artifact@v2
with:
name: sdcc_template
path: src/template

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project/JTAG/Makefile Normal file
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CFLAGS=-mmcs51 --model-small --xram-size 0x0400 --xram-loc 0x0000 --code-size 0x3800
all:
sdcc $(CFLAGS) usbjtag.c -o usbjtag.hex
objcopy -I ihex -O binary usbjtag.hex usbjtag.bin
-@rm -rf *.asm *.lst *.rel *.rst *.sym *.lk *.map *.mem *.hex
flash:
-@python3 usbjtag.py -i
python3 ch55xtool.py -r -f usbjtag.bin
test:
python3 usbjtag.py -rcsv -f test.bin

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project/JTAG/ch552.h Normal file
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#ifndef __CH552_H__
#define __CH552_H__
#include <compiler.h>
//System SFRs
SFR(PSW, 0xD0);
SBIT(CY, 0xD0, 7);
SBIT(AC, 0xD0, 6);
SBIT(F0, 0xD0, 5);
SBIT(RS1, 0xD0, 4);
SBIT(RS0, 0xD0, 3);
SBIT(OV, 0xD0, 2);
SBIT(F1, 0xD0, 1);
SBIT(P, 0xD0, 0);
SFR(ACC, 0xE0);
SFR(B, 0xF0);
SFR(SP, 0x81);
SFR(DPL, 0x82);
SFR(DPH, 0x83);
SFR(SAFE_MOD, 0xA1);
SFR(GLOBAL_CFG, 0xB1);
SFR(PCON, 0x87);
SFR(CLOCK_CFG, 0xB9);
SFR(WAKE_CTRL, 0xA9);
SFR(RESET_KEEP, 0xFE);
SFR(WDOG_COUNT, 0xFF);
//Interrupt SFRs
SFR(IE, 0xA8);
SBIT(EA, 0xA8, 7);
SBIT(E_DIS, 0xA8, 6);
SBIT(ET2, 0xA8, 5);
SBIT(ES, 0xA8, 4);
SBIT(ET1, 0xA8, 3);
SBIT(EX1, 0xA8, 2);
SBIT(ET0, 0xA8, 1);
SBIT(EX0, 0xA8, 0);
SFR(IP, 0xB8);
SBIT(PH_FLAG, 0xB8, 7);
SBIT(PL_FLAG, 0xB8, 6);
SBIT(PT2, 0xB8, 5);
SBIT(PS, 0xB8, 4);
SBIT(PT1, 0xB8, 3);
SBIT(PX1, 0xB8, 2);
SBIT(PT0, 0xB8, 1);
SBIT(PX0, 0xB8, 0);
SFR(IE_EX, 0xE8);
SBIT(IE_WDOG, 0xE8, 7);
SBIT(IE_GPIO, 0xE8, 6);
SBIT(IE_PWMX, 0xE8, 5);
SBIT(IE_UART1, 0xE8, 4);
SBIT(IE_ADC, 0xE8, 3);
SBIT(IE_USB, 0xE8, 2);
SBIT(IE_TKEY, 0xE8, 1);
SBIT(IE_SPI0, 0xE8, 0);
SFR(IP_EX, 0xE9);
SFR(GPIO_IE, 0xC7);
//Flash SFRs
SFR16(ROM_ADDR, 0x84);
SFR(ROM_ADDR_L, 0x84);
SFR(ROM_ADDR_H, 0x85);
SFR16(ROM_DATA, 0x8E);
SFR(ROM_DATA_L, 0x8E);
SFR(ROM_DATA_H, 0x8F);
SFR(ROM_CTRL, 0x86);
//Port SFRs
SFR(P1, 0x90);
SBIT(P10, 0x90, 0);
SBIT(P11, 0x90, 1);
SBIT(P12, 0x90, 2);
SBIT(P13, 0x90, 3);
SBIT(P14, 0x90, 4);
SBIT(P15, 0x90, 5);
SBIT(P16, 0x90, 6);
SBIT(P17, 0x90, 7);
SFR(P1_MOD_OC, 0x92);
SFR(P1_DIR_PU, 0x93);
SFR(P2, 0xA0);
SFR(P3, 0xB0);
SBIT(P30, 0xB0, 0);
SBIT(P31, 0xB0, 1);
SBIT(P32, 0xB0, 2);
SBIT(P33, 0xB0, 3);
SBIT(P34, 0xB0, 4);
SBIT(P35, 0xB0, 5);
SBIT(P36, 0xB0, 6);
SBIT(P37, 0xB0, 7);
SFR(P3_MOD_OC, 0x96);
SFR(P3_DIR_PU, 0x97);
SFR(PIN_FUNC, 0xC6);
SFR(XBUS_AUX, 0xA2);
//Timer0/1 SFRs
SFR(TCON,0x88);
SBIT(TF1, 0x88, 7);
SBIT(TR1, 0x88, 6);
SBIT(TF0, 0x88, 5);
SBIT(TR0, 0x88, 4);
SBIT(IE1, 0x88, 3);
SBIT(IT1, 0x88, 2);
SBIT(IE0, 0x88, 1);
SBIT(IT0, 0x88, 0);
SFR(TMOD,0x89);
SFR(TL0,0x8A);
SFR(TL1,0x8B);
SFR(TH0,0x8C);
SFR(TH1,0x8D);
//Timer2 SFRs
SFR(T2CON, 0xC8);
SBIT(TF2, 0xC8, 7);
SBIT(CAP1F, 0xC8, 7);
SBIT(EXF2, 0xC8, 6);
SBIT(RCLK, 0xC8, 5);
SBIT(TCLK, 0xC8, 4);
SBIT(EXEN2, 0xC8, 3);
SBIT(TR2, 0xC8, 2);
SBIT(C_T2, 0xC8, 1);
SBIT(CP_RL2, 0xC8, 0);
SFR(T2MOD, 0xC9);
SFR16(RCAP2, 0xCA);
SFR(RCAP2L, 0xCA);
SFR(RCAP2H, 0xCB);
SFR16(T2COUNT, 0xCC);
SFR(TL2, 0xCC);
SFR(TH2, 0xCD);
SFR16(T2CAP1, 0xCE);
SFR(T2CAP1L, 0xCE);
SFR(T2CAP1H, 0xCF);
//PWM SFRs
SFR(PWM_DATA2, 0x9B);
SFR(PWM_DATA1, 0x9C);
SFR(PWM_CTRL, 0x9D);
SFR(PWM_CK_SE, 0x9E);
//UART0 SFRs
SFR(SCON, 0x98);
SBIT(SM0, 0x98, 7);
SBIT(SM0, 0x98, 7);
SBIT(SM1, 0x98, 6);
SBIT(SM2, 0x98, 5);
SBIT(REN, 0x98, 4);
SBIT(TB8, 0x98, 3);
SBIT(RB8, 0x98, 2);
SBIT(TI, 0x98, 1);
SBIT(RI, 0x98, 0);
SFR(SBUF, 0x99);
//UART1 SFRs
SFR(SCON1, 0xC0);
SBIT(U1SM0, 0xC0, 7);
SBIT(U1SMOD, 0xC0, 5);
SBIT(U1REN, 0xC0, 4);
SBIT(U1TB8, 0xC0, 3);
SBIT(U1RB8, 0xC0, 2);
SBIT(U1TI, 0xC0, 1);
SBIT(U1RI, 0xC0, 0);
SFR(SBUF1, 0xC1);
SFR(SBAUD1, 0xC2);
//SPI SFRs
SFR(SPI0_STAT, 0xF8);
SBIT(S0_FST_ACT, 0xF8, 7);
SBIT(S0_IF_OV, 0xF8, 6);
SBIT(S0_IF_FIRST, 0xF8, 5);
SBIT(S0_IF_BYTE, 0xF8, 4);
SBIT(S0_FREE, 0xF8, 3);
SBIT(S0_T_FIFO, 0xF8, 2);
SBIT(S0_R_FIFO, 0xF8, 0);
SFR(SPI0_DATA, 0xF9);
SFR(SPI0_CTRL, 0xFA);
SFR(SPI0_CK_SE, 0xFB);
SFR(SPI0_SETUP, 0xFC);
//ADC SFRs
SFR(ADC_CTRL, 0x80);
SBIT(CMPO, 0x80, 7);
SBIT(CMP_IF, 0x80, 6);
SBIT(ADC_IF, 0x80, 5);
SBIT(ADC_START, 0x80, 4);
SBIT(CMP_CHAN, 0x80, 3);
SBIT(ADC_CHAN1, 0x80, 1);
SBIT(ADC_CHAN0, 0x80, 0);
SFR(ADC_CFG, 0x9A);
SFR(ADC_DATA, 0x9F);
//Touch SFRs
SFR(TKEY_CTRL, 0xC3);
SFR16(TKEY_DAT, 0xC4);
SFR(TKEY_DATL, 0xC4);
SFR(TKEY_DATH, 0xC5);
//USB SFRs
SFR(USB_C_CTRL, 0x91);
SFR(USB_CTRL, 0xE2);
SFR(UDEV_CTRL, 0xD1);
SFR(USB_DEV_AD, 0xE3);
SFR(USB_MIS_ST, 0xDA);
SFR(USB_RX_LEN, 0xDB);
SFR(USB_INT_EN, 0xE1);
SFR(USB_INT_FG, 0xD8);
SBIT(U_IS_NAK, 0xD8, 7);
SBIT(U_TOG_OK, 0xD8, 6);
SBIT(U_SIE_FREE, 0xD8, 5);
SBIT(UIF_FIFO_OV, 0xD8, 4);
SBIT(UIF_HST_SOF, 0xD8, 3);
SBIT(UIF_SUSPEND, 0xD8, 2);
SBIT(UIF_TRANSFER, 0xD8, 1);
SBIT(UIF_DETECT, 0xD8, 0);
SBIT(UIF_BUS_RST, 0xD8, 0);
SFR(USB_INT_ST, 0xD9);
SFR(UEP4_1_MOD, 0xEA);
SFR(UEP2_3_MOD, 0xEB);
SFR(UEP0_CTRL, 0xDC);
SFR(UEP0_T_LEN, 0xDD);
SFR(UEP1_CTRL, 0xD2);
SFR(UEP1_T_LEN, 0xD3);
SFR(UEP2_CTRL, 0xD4);
SFR(UEP2_T_LEN, 0xD5);
SFR(UEP3_CTRL, 0xD6);
SFR(UEP3_T_LEN, 0xD7);
SFR(UEP4_CTRL, 0xDE);
SFR(UEP4_T_LEN, 0xDF);
SFR16(UEP0_DMA, 0xEC);
SFR(UEP0_DMA_L, 0xEC);
SFR(UEP0_DMA_H, 0xED);
SFR16(UEP1_DMA, 0xEE);
SFR(UEP1_DMA_L, 0xEE);
SFR(UEP1_DMA_H, 0xEF);
SFR16(UEP2_DMA, 0xE4);
SFR(UEP2_DMA_L, 0xE4);
SFR(UEP2_DMA_H, 0xE5);
SFR16(UEP3_DMA, 0xE6);
SFR(UEP3_DMA_L, 0xE6);
SFR(UEP3_DMA_H, 0xE7);
//Interrupt vectors
#define INT_NO_INT0 0
#define INT_NO_TMR0 1
#define INT_NO_INT1 2
#define INT_NO_TMR1 3
#define INT_NO_UART0 4
#define INT_NO_TMR2 5
#define INT_NO_SPI0 6
#define INT_NO_TKEY 7
#define INT_NO_USB 8
#define INT_NO_ADC 9
#define INT_NO_UART1 10
#define INT_NO_PWMX 11
#define INT_NO_GPIO 12
#define INT_NO_WDOG 13
#endif

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#!/usr/bin/env python3
# -*- coding: utf-8 -*-
import sys, os
import time
import array
import math
import argparse
import usb.core
import usb.util
#======= Some C-like static constants =======
DFU_ID_VENDOR = 0x4348
DFU_ID_PRODUCT = 0x55e0
EP_OUT_ADDR = 0x02
EP_IN_ADDR = 0x82
USB_MAX_TIMEOUT = 2000
DETECT_CHIP_CMD_V2 = [0xa1, 0x12, 0x00, 0x52, 0x11, 0x4d, 0x43, 0x55, 0x20, 0x49, 0x53,
0x50, 0x20, 0x26, 0x20, 0x57, 0x43, 0x48, 0x2e, 0x43, 0x4e]
END_FLASH_CMD_V2 = [0xa2, 0x01, 0x00, 0x00]
RESET_RUN_CMD_V2 = [0xa2, 0x01, 0x00, 0x01]
SEND_KEY_CMD_V20 = [0xa3, 0x30, 0x00]
SEND_KEY_CMD_V23 = [0xa3, 0x38, 0x00] + [0x00] * (0x38)
ERASE_CHIP_CMD_V2 = [0xa4, 0x01, 0x00, 0x08]
WRITE_CMD_V2 = [0xa5, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00]
VERIFY_CMD_V2 = [0xa6, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00]
READ_CFG_CMD_V2 = [0xa7, 0x02, 0x00, 0x1f, 0x00]
CH55X_IC_REF = {}
CH55X_IC_REF[0x51] = {'device_name': 'CH551', 'device_flash_size': 10240, 'device_dataflash_size': 128, 'chip_id': 0x51}
CH55X_IC_REF[0x52] = {'device_name': 'CH552', 'device_flash_size': 16384, 'device_dataflash_size': 128, 'chip_id': 0x52}
CH55X_IC_REF[0x53] = {'device_name': 'CH553', 'device_flash_size': 10240, 'device_dataflash_size': 128, 'chip_id': 0x53}
CH55X_IC_REF[0x54] = {'device_name': 'CH554', 'device_flash_size': 14336, 'device_dataflash_size': 128, 'chip_id': 0x54}
CH55X_IC_REF[0x59] = {'device_name': 'CH559', 'device_flash_size': 61440, 'device_dataflash_size': 128, 'chip_id': 0x59}
#=============================================
def __get_dfu_device(idVendor=DFU_ID_VENDOR, idProduct=DFU_ID_PRODUCT):
dev = usb.core.find(idVendor=idVendor, idProduct=idProduct)
if dev is None:
return (None, 'NO_DEV_FOUND')
try:
if dev.is_kernel_driver_active(0):
try:
dev.detach_kernel_driver(0)
except usb.core.USBError:
return (None, 'USB_ERROR_CANNOT_DETACH_KERNEL_DRIVER')
except:
pass #Windows dont need detach
try:
dev.set_configuration()
except usb.core.USBError:
return (None, 'USB_ERROR_CANNOT_SET_CONFIG')
try:
usb.util.claim_interface(dev, 0)
except usb.core.USBError:
return (None, 'USB_ERROR_CANNOT_CLAIM_INTERFACE')
return (dev, '')
def __detect_ch55x_v2(dev):
dev.write(EP_OUT_ADDR, DETECT_CHIP_CMD_V2)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
try:
return CH55X_IC_REF[ret[4]]
except KeyError:
return None
def __read_cfg_ch55x_v2(dev):
dev.write(EP_OUT_ADDR, READ_CFG_CMD_V2)
ret = dev.read(EP_IN_ADDR, 30, USB_MAX_TIMEOUT)
ver_str = 'V%d.%d%d' % (ret[19], ret[20], ret[21])
chk_sum = (ret[22] + ret[23] + ret[24] + ret[25]) % 256
return (ver_str, chk_sum)
def __write_key_ch55x_v20(dev, chk_sum):
SEND_KEY_CMD_V20 = SEND_KEY_CMD_V20 + [chk_sum] * 0x30
dev.write(EP_OUT_ADDR, SEND_KEY_CMD_V20)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
if ret[3] == 0:
return True
else:
return None
def __write_key_ch55x_v23(dev):
dev.write(EP_OUT_ADDR, SEND_KEY_CMD_V23)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
if ret[3] == 0:
return True
else:
return None
def __erase_chip_ch55x_v2(dev):
dev.write(EP_OUT_ADDR, ERASE_CHIP_CMD_V2)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
if ret[3] == 0:
return True
else:
return None
def __write_flash_ch55x_v20(dev, chk_sum, chip_id, payload):
payload = payload + [0] * ((math.ceil(len(payload) / 56) * 56) - len(payload)) # Payload needs to be padded, 56 is a good number
file_length = len(payload)
for index in range(file_length):
if index % 8 == 7:
payload[index] = (payload[index] ^ ((chk_sum + chip_id) % 256)) % 256
left_len = file_length
curr_addr = 0
while curr_addr < file_length:
if left_len >= 56:
pkt_length = 56
else:
pkt_length = left_len
__WRITE_CMD_V2 = WRITE_CMD_V2
__WRITE_CMD_V2[1] = pkt_length + 5
__WRITE_CMD_V2[3] = curr_addr % 256
__WRITE_CMD_V2[4] = (curr_addr >> 8) % 256
__WRITE_CMD_V2[7] = left_len % 256
__WRITE_CMD_V2 = __WRITE_CMD_V2 + payload[curr_addr:curr_addr+pkt_length]
dev.write(EP_OUT_ADDR, __WRITE_CMD_V2)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
curr_addr = curr_addr + pkt_length
left_len = left_len - pkt_length
if ret[4] != 0x00:
return None
return file_length
def __write_flash_ch55x_v23(dev, chk_sum, chip_id, payload):
payload = payload + [0] * ((math.ceil(len(payload) / 56) * 56) - len(payload)) # Payload needs to be padded, 56 is a good number
file_length = len(payload)
for index in range(file_length):
if index % 8 == 7:
payload[index] = (payload[index] ^ ((chk_sum + chip_id) % 256)) % 256
else:
payload[index] = (payload[index] ^ chk_sum) % 256
left_len = file_length
curr_addr = 0
while curr_addr < file_length:
if left_len >= 56:
pkt_length = 56
else:
pkt_length = left_len
__WRITE_CMD_V2 = WRITE_CMD_V2
__WRITE_CMD_V2[1] = pkt_length + 5
__WRITE_CMD_V2[3] = curr_addr % 256
__WRITE_CMD_V2[4] = (curr_addr >> 8) % 256
__WRITE_CMD_V2[7] = left_len % 256
__WRITE_CMD_V2 = __WRITE_CMD_V2 + payload[curr_addr:curr_addr+pkt_length]
dev.write(EP_OUT_ADDR, __WRITE_CMD_V2)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
curr_addr = curr_addr + pkt_length
left_len = left_len - pkt_length
if ret[4] != 0x00:
return None
return file_length
def __verify_flash_ch55x_v20(dev, chk_sum, chip_id, payload):
payload = payload + [0] * ((math.ceil(len(payload) / 56) * 56) - len(payload)) # Payload needs to be padded, 56 is a good number
file_length = len(payload)
for index in range(file_length):
if index % 8 == 7:
payload[index] = (payload[index] ^ ((chk_sum + chip_id) % 256)) % 256
left_len = file_length
curr_addr = 0
while curr_addr < file_length:
if left_len >= 56:
pkt_length = 56
else:
pkt_length = left_len
__VERIFY_CMD_V2 = VERIFY_CMD_V2
__VERIFY_CMD_V2[1] = pkt_length + 5
__VERIFY_CMD_V2[3] = curr_addr % 256
__VERIFY_CMD_V2[4] = (curr_addr >> 8) % 256
__VERIFY_CMD_V2[7] = left_len % 256
__VERIFY_CMD_V2 = __VERIFY_CMD_V2 + payload[curr_addr:curr_addr+pkt_length]
dev.write(EP_OUT_ADDR, __VERIFY_CMD_V2)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
curr_addr = curr_addr + pkt_length
left_len = left_len - pkt_length
if ret[4] != 0x00:
return None
return file_length
def __verify_flash_ch55x_v23(dev, chk_sum, chip_id, payload):
payload = payload + [0] * ((math.ceil(len(payload) / 56) * 56) - len(payload)) # Payload needs to be padded, 56 is a good number
file_length = len(payload)
for index in range(file_length):
if index % 8 == 7:
payload[index] = (payload[index] ^ ((chk_sum + chip_id) % 256)) % 256
else:
payload[index] = (payload[index] ^ chk_sum) % 256
left_len = file_length
curr_addr = 0
while curr_addr < file_length:
if left_len >= 56:
pkt_length = 56
else:
pkt_length = left_len
__VERIFY_CMD_V2 = VERIFY_CMD_V2
__VERIFY_CMD_V2[1] = pkt_length + 5
__VERIFY_CMD_V2[3] = curr_addr % 256
__VERIFY_CMD_V2[4] = (curr_addr >> 8) % 256
__VERIFY_CMD_V2[7] = left_len % 256
__VERIFY_CMD_V2 = __VERIFY_CMD_V2 + payload[curr_addr:curr_addr+pkt_length]
dev.write(EP_OUT_ADDR, __VERIFY_CMD_V2)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
curr_addr = curr_addr + pkt_length
left_len = left_len - pkt_length
if ret[4] != 0x00:
return None
return file_length
def __end_flash_ch55x_v2(dev):
dev.write(EP_OUT_ADDR, END_FLASH_CMD_V2)
ret = dev.read(EP_IN_ADDR, 6, USB_MAX_TIMEOUT)
if ret[4] != 0x00:
return None
else:
return True
def __restart_run_ch55x_v2(dev):
dev.write(EP_OUT_ADDR, RESET_RUN_CMD_V2)
def __main():
parser = argparse.ArgumentParser(description="USBISP Tool For WinChipHead CH55x.")
parser.add_argument('-f', '--file', type=str, default='', help="The target file to be flashed.")
parser.add_argument('-r', '--reset_after_flash', action='store_true', default=False, help="Reset after finsh flash.")
args = parser.parse_args()
ret = __get_dfu_device()
if ret[0] is None:
sys.exit(ret[1])
dev = ret[0]
ret = __detect_ch55x_v2(dev)
if ret is None:
print('Unable to detect CH55x.')
print('Found %s.' % ret['device_name'])
chip_id = ret['chip_id']
ret = __read_cfg_ch55x_v2(dev)
chk_sum = ret[1]
print('BTVER: %s.' % ret[0])
if args.file != '':
payload = list(open(args.file, 'rb').read())
if ret[0] in ['V2.30']:
ret = __write_key_ch55x_v20(dev, chk_sum)
if ret is None:
sys.exit('Failed to write key to CH55x.')
ret = __erase_chip_ch55x_v2(dev)
if ret is None:
sys.exit('Failed to erase CH55x.')
ret = __write_flash_ch55x_v20(dev, chk_sum, chip_id, payload)
if ret is None:
sys.exit('Failed to flash firmware of CH55x.')
ret = __verify_flash_ch55x_v20(dev, chk_sum, chip_id, payload)
if ret is None:
sys.exit('Failed to verify firmware of CH55x.')
else:
if ret[0] in ['V2.31', 'V2.40']:
ret = __write_key_ch55x_v23(dev)
if ret is None:
sys.exit('Failed to write key to CH55x.')
ret = __erase_chip_ch55x_v2(dev)
if ret is None:
sys.exit('Failed to erase CH55x.')
ret = __write_flash_ch55x_v23(dev, chk_sum, chip_id, payload)
if ret is None:
sys.exit('Failed to flash firmware of CH55x.')
ret = __verify_flash_ch55x_v23(dev, chk_sum, chip_id, payload)
if ret is None:
sys.exit('Failed to verify firmware of CH55x.')
else:
sys.exit('Bootloader version not supported.')
ret = __end_flash_ch55x_v2(dev)
if ret is None:
sys.exit('Failed to end flash process.')
print('Flash done.')
if args.reset_after_flash:
__restart_run_ch55x_v2(dev)
print('Restart and run.')
if __name__ == '__main__':
__main()

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/*
CH552 USB-JTAG Adapter
Copyright (c) 2020, Bo Gao <7zlaser@gmail.com>
Redistribution and use in source and binary forms, with or without modification,
are permitted provided that the following conditions are met:
1. Redistributions of source code must retain the above copyright notice, this list of
conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright notice, this list
of conditions and the following disclaimer in the documentation
and/or other materials provided with the distribution.
3. Neither the name of the copyright holder nor the names of its contributors may be
used to endorse or promote products derived from this software without specific
prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY
EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT
SHALL THE COPYRIGHT HOLDER BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THE
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <compiler.h>
#include <stdint.h>
#include "ch552.h"
//Pin map
#define TMS P14
#define TCK P17
#define TDI P15
#define TDO P16
#define ENA P33
#define RST P32
#define ISP P10 //Not used, pull down
//Helper macros
#define jtag_bit(mask) {TMS=tms&mask; TDI=tdi&mask; SAFE_MOD++; TCK=1; TCK=0;}
#define jtag_bit_read(mask) {TMS=tms&mask; TDI=tdi&mask; SAFE_MOD++; tdo|=TDO?mask:0; TCK=1; TCK=0;}
#define usb_txdesc(desc) {len=sizeof(desc); len=len>*slen?*slen:len; for(i=0;i<len;i++) buf_ep0[i]=desc[i];}
//USB descriptors
__code static uint8_t desc_dev[]={0x12, 0x01, 0x10, 0x01, 0xff, 0xff, 0xff, 0x40, 0xa0, 0x20, 0x09, 0x42, 0x00, 0x01, 0x00, 0x01, 0x00, 0x01};
__code static uint8_t desc_cfg[]={0x09, 0x02, 0x20, 0x00, 0x01, 0x01, 0x00, 0x80, 0xfa, 0x09, 0x04, 0x00, 0x00, 0x02, 0xff, 0xff, 0xff, 0x00, 0x07, 0x05, 0x81, 0x02, 0x40, 0x00, 0x00, 0x07, 0x05, 0x01, 0x02, 0x40, 0x00, 0x00};
__code static uint8_t desc_lng[]={0x04, 0x03, 0x09, 0x04};
__code static uint8_t desc_pro[]={0x12, 0x03, 'U', 0, 'S', 0, 'B', 0, '-', 0, 'J', 0, 'T', 0, 'A', 0, 'G', 0};
//Endpoint buffers
__xdata __at (0x0000) uint8_t buf_ep0[64];
__xdata __at (0x0040) uint8_t buf_ep1[128];
//Entry point
void main(void)
{
SAFE_MOD=0x55;
SAFE_MOD=0xAA;
CLOCK_CFG=CLOCK_CFG&~0x07|0x05; //16MHz
SAFE_MOD=0x00;
P1&=~(0x80|0x20|0x10|0x91); //TCK, TDI, TMS, ISP low
P1_DIR_PU&=~(0x40); //TDO IN
P1_MOD_OC&=~(0x80|0x40|0x20|0x10|0x01); //TCK, TDI, TMS, ISP PP, TDI IN
P3&=~(0x08|0x04); //ENA, RST low
P3_MOD_OC&=~(0x08|0x04); //RST, ENA PP
IE_USB=0;
USB_CTRL=0x00; //Deassert reset
UEP4_1_MOD=0xc0; //EP1 IN/OUT
UEP0_DMA=(uint16_t)buf_ep0;
UEP1_DMA=(uint16_t)buf_ep1;
UEP0_CTRL=0x02; //OUT ACK, IN NAK
UEP1_CTRL=0x12; //OUT ACK, IN NAK
USB_DEV_AD=0x00;
UDEV_CTRL=0x08; //Disable USB port
USB_CTRL=0x29; //ENA, auto NAK, DMA
UDEV_CTRL|=0x01; //Enable USB port
USB_INT_FG=0xff; //Clear all
USB_INT_EN=0x03; //XFER, RST
IE_USB=1;
SPI0_CK_SE=0x02; //SCK 8MHz
EA=1;
while(1);
}
//JTAG write N bytes
void jtag_write(uint8_t *mbuf, uint8_t *obuf, uint8_t N)
{
uint8_t i, tms, tdi;
for(i=0;i<N;i++)
{
tms=mbuf[i]; //XRAM access is slow
tdi=obuf[i];
jtag_bit(0x01) jtag_bit(0x02) jtag_bit(0x04) jtag_bit(0x08)
jtag_bit(0x10) jtag_bit(0x20) jtag_bit(0x40) jtag_bit(0x80)
}
}
//JTAG write and read N bytes
void jtag_write_read(uint8_t *mbuf, uint8_t *obuf, uint8_t *ibuf, uint8_t N)
{
uint8_t i, tms, tdi, tdo;
for(i=0;i<N;i++)
{
tms=mbuf[i]; //XRAM access is slow
tdi=obuf[i];
tdo=0;
jtag_bit_read(0x01) jtag_bit_read(0x02) jtag_bit_read(0x04) jtag_bit_read(0x08)
jtag_bit_read(0x10) jtag_bit_read(0x20) jtag_bit_read(0x40) jtag_bit_read(0x80)
ibuf[i]=tdo;
}
}
//SPI write N bytes
void spi_write(uint8_t *obuf, uint8_t N, uint8_t csena)
{
uint8_t i;
SPI0_CTRL=0x60;
if(csena) TMS=0;
for(i=0;i<N;i++)
{
SPI0_DATA=obuf[i];
while(!S0_FREE);
}
if(csena) TMS=1;
SPI0_CTRL=0x02;
}
//SPI write and read N bytes
void spi_write_read(uint8_t *obuf, uint8_t *ibuf, uint8_t N, uint8_t csena)
{
uint8_t i;
SPI0_CTRL=0x60;
if(csena) TMS=0;
for(i=0;i<N;i++)
{
SPI0_DATA=obuf[i];
while(!S0_FREE);
ibuf[i]=SPI0_DATA;
}
if(csena) TMS=1;
SPI0_CTRL=0x02;
}
//Finished receiving SETUP from EP0
inline void ep0_setup(uint8_t *scode, uint8_t *slen, uint8_t *config)
{
uint8_t len, i;
UEP0_CTRL&=~0x01; //STALL->NAK
if(USB_RX_LEN!=8) goto ep0_stall;
*slen=buf_ep0[6];
if(buf_ep0[7]) *slen=64;
len=0;
*scode=buf_ep0[1];
if((buf_ep0[0]&0x60)==0) //Standard request
if(*scode==0x06) //Get descriptor
{
if(buf_ep0[3]==0x01) usb_txdesc(desc_dev) //Device
else if(buf_ep0[3]==0x02) usb_txdesc(desc_cfg) //Config
else if(buf_ep0[3]==0x03) //String
{
if(buf_ep0[2]==0x00) usb_txdesc(desc_lng)
else if(buf_ep0[2]==0x01) usb_txdesc(desc_pro)
else goto ep0_stall;
}
else goto ep0_stall;
}
else if(*scode==0x05) *slen=buf_ep0[2]; //Set address
else if(*scode==0x08) {buf_ep0[0]=*config; len=*slen?1:0;} //Get config
else if(*scode==0x09) *config=buf_ep0[2]; //Set config
else if(*scode==0x0a) {buf_ep0[0]=0x00; len=*slen?1:0;} //Get interface
else if(*scode==0x00) //Get status
{
if(buf_ep0[0]==0x82 && buf_ep0[4]==0x81) buf_ep0[0]=(UEP1_CTRL&0x03)==0x03?1:0;
else if(buf_ep0[0]==0x82 && buf_ep0[4]==0x01) buf_ep0[0]=(UEP1_CTRL&0x0c)==0x0c?1:0;
else buf_ep0[0]=0;
buf_ep0[1]=0;
len=*slen>2?2:*slen;
}
else if(buf_ep0[0]==0x02 && *scode==0x03) //Set feature
if(buf_ep0[4]==0x81) UEP1_CTRL|=0x03;
else if(buf_ep0[4]==0x01) UEP1_CTRL|=0x0c;
else goto ep0_stall;
else if(buf_ep0[0]==0x02 && *scode==0x01) //Clear feature
if(buf_ep0[4]==0x81) UEP1_CTRL=(UEP1_CTRL&~0x43)|0x02;
else if(buf_ep0[4]==0x01) UEP1_CTRL=(UEP1_CTRL&~0x8c);
else goto ep0_stall;
else goto ep0_stall;
else
{
ep0_stall:
*slen=*scode=0x00;
UEP0_CTRL=0x03; //IN STALL, DATA1
return;
}
UEP0_T_LEN=len; //Max 64 bytes
UEP0_CTRL=0xc0; //DATA1
}
//Finished receiving from EP1
inline void ep1_out(void)
{
uint8_t len=USB_RX_LEN;
uint8_t cmd=buf_ep1[0];
if(!U_TOG_OK) return;
if(len<1) return;
if((cmd&0xf0)==0x00) {RST=cmd&0x01; ENA=cmd&0x02;} //Power control
else if((cmd&0xf0)==0x10 && len&1) //JTAG write
if(!(cmd&0x01)) jtag_write(&buf_ep1[1], &buf_ep1[1+len>>1], len>>1); //Write only
else //Write and read
{
jtag_write_read(&buf_ep1[1], &buf_ep1[1+len>>1], &buf_ep1[64], len>>1);
UEP1_T_LEN=len>>1;
UEP1_CTRL&=~0x02;
}
else if((cmd&0xf0)==0x20) //SPI write
if(!(cmd&0x01)) spi_write(&buf_ep1[1], len-1, cmd&0x02); //Write only
else //Write and read
{
spi_write_read(&buf_ep1[1], &buf_ep1[64], len-1, cmd&0x02);
UEP1_T_LEN=len-1;
UEP1_CTRL&=~0x02;
}
else if(cmd==0xff) //Enter ISP mode
{
EA=0;
USB_CTRL=0x06; //Reset USB
USB_INT_FG=0xff;
for(len=0;len<255;len++) //Delay
for(cmd=0;cmd<255;cmd++) {SAFE_MOD++; SAFE_MOD++; SAFE_MOD++; SAFE_MOD++;}
((void (*)(void))0x3800)(); //Jump to bootloader
}
}
//USB interrupt handler
void usb_isr(void) __interrupt (INT_NO_USB) __using 1
{
static uint8_t scode=0, slen=0, config=0;
uint8_t token;
if(UIF_TRANSFER) //Transfer done
{
token=USB_INT_ST&0x3f;
if(token==0x21) //EP1 IN
UEP1_CTRL|=0x02; //EP1 IN NAK
else if(token==0x01) //EP1 OUT
ep1_out();
else if(token==0x30) //EP0 SETUP
ep0_setup(&scode, &slen, &config);
else if(token==0x20) //EP0 IN
{
if(scode==0x05) USB_DEV_AD=slen;
UEP0_T_LEN=0; //Send ZLP
UEP0_CTRL=0x02; //IN NAK
}
else if(token==0x00) //EP0 OUT
UEP0_CTRL=0x02; //IN NAK
UIF_TRANSFER=0;
}
else if(UIF_BUS_RST) //Bus reset
{
UEP0_CTRL=0x02;
UEP1_CTRL=0x12;
USB_DEV_AD=0x00;
scode=slen=config=0;
USB_INT_FG=0xff;
}
else USB_INT_FG=0xff;
}

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#!/usr/bin/env python3
# Copyright (c) 2020, Bo Gao <7zlaser@gmail.com>
# Redistribution and use in source and binary forms, with or without modification,
# are permitted provided that the following conditions are met:
# 1. Redistributions of source code must retain the above copyright notice, this list of
# conditions and the following disclaimer.
# 2. Redistributions in binary form must reproduce the above copyright notice, this list
# of conditions and the following disclaimer in the documentation
# and/or other materials provided with the distribution.
# 3. Neither the name of the copyright holder nor the names of its contributors may be
# used to endorse or promote products derived from this software without specific
# prior written permission.
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY
# EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
# OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT
# SHALL THE COPYRIGHT HOLDER BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
# EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
# SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
# HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
# OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THE
# SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
import sys, usb, time, binascii
class GowinJTAG:
dev=None
# Open USB device
def __init__(self):
self.dev=usb.core.find(idVendor=0x20a0, idProduct=0x4209)
if self.dev is None:
print("Error: device not found")
sys.exit(-1)
self.dev.reset()
self.dev.set_configuration()
# Close USB device
def __del__(self):
try:
usb.util.dispose_resources(self.dev)
except Exception: pass
# Write JTAG command
def WriteCmd(self, cmd):
self.dev.write(0x01, [0x10, 0x30, 0x80, 0x01, 0x00, cmd&0xff, 0x00])
# Reset FPGA
def ResetPwr(self):
self.dev.write(0x01, [0x00])
time.sleep(0.01)
self.dev.write(0x01, [0x01])
# Reset JTAG
def ResetTap(self):
self.dev.write(0x01, [0x10, 0xff, 0x00, 0x00, 0x00])
# Reset SRAM
def ResetRam(self):
self.WriteCmd(0x15) # Enter config mode
self.WriteCmd(0x05) # Clear SRAM
self.WriteCmd(0x02) # Nop
time.sleep(0.01) # Wait for finish
self.WriteCmd(0x3a) # Exit config mode
self.WriteCmd(0x02) # Nop
# Read JTAG ID
def ReadId(self):
self.WriteCmd(0x11) # Read JTAG ID command
self.dev.write(0x01, [0x11, 0x20, 0x00, 0x00, 0x00, 0x80, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00])
ret=self.dev.read(0x81, 64, 100)
ret.reverse()
return bytes(ret[1:5]).hex()
# Write SRAM
def WriteRam(self, filename):
flen=0
self.WriteCmd(0x15) # Enter config mode
self.WriteCmd(0x17) # Write SRAM
self.dev.write(0x01, [0x10, 0x20, 0x00]) # Shift DR
with open(filename, "rb") as f:
while True:
dat=f.read(63)
if not dat:
break
# SPI mode, MSB first
self.dev.write(0x01, [0x20]+list(dat))
flen=f.tell()
self.dev.write(0x01, [0x10, 0x03, 0x00]) # Idle
self.WriteCmd(0x3a) # Exit config mode
self.WriteCmd(0x02) # Nop
return flen
# Enter ISP mode
def EnterIsp(self):
try: # Connection WILL break
self.dev.write(0x01, [0xff])
except Exception: pass
# Entry point
if __name__ == "__main__":
import argparse
import os
parser=argparse.ArgumentParser(description="USB JTAG programmer for Gowin FPGAs")
parser.add_argument("-r", action="store_true", default=False, dest="reset_fpga", help="Reset FPGA")
parser.add_argument("-c", action="store_true", default=False, dest="clear_sram", help="Clear SRAM content")
parser.add_argument("-s", action="store_true", default=False, dest="prog_sram", help="Program SRAM")
parser.add_argument("-f", action="store", dest="prog_filename", help="Specify SRAM filename")
parser.add_argument("-i", action="store_true", default=False, dest="isp_mode", help="Enter adapter ISP mode")
parser.add_argument("-v", action="store_true", default=False, dest="verbose_mode", help="Verbose output")
args=parser.parse_args()
jtag=GowinJTAG()
if args.isp_mode:
jtag.EnterIsp()
time.sleep(0.5)
sys.exit(0)
if args.reset_fpga:
jtag.ResetPwr()
jtag.ResetTap()
if args.verbose_mode:
print("Device ID is 0x"+jtag.ReadId())
if args.clear_sram or args.prog_sram:
jtag.ResetRam()
if args.prog_sram:
if args.prog_filename is None:
print("Error: filename not specified")
sys.exit(-1)
if not os.path.exists(args.prog_filename):
print("Error: cannot open file")
sys.exit(-1)
tbegin=time.time()
flen=jtag.WriteRam(args.prog_filename)
tend=time.time()
if args.verbose_mode:
print("Programming done in {0:.2f}s at {1:.2f}kB/s.".format(tend-tbegin, flen/(tend-tbegin)/1000.0))
sys.exit(0)

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# MCU Configuration
FREQ_SYS ?= 24000000
IRAM_SIZE ?= 0x100
XRAM_SIZE ?= 0x400
CODE_SIZE ?= 0x3800
SRC_DIR := ./src
OBJ_DIR := ./out
TMP_DIR := $(OBJ_DIR)/generated
# File containing "void main(void)" function
MAIN := $(SRC_DIR)/main.c
# Target file name, do not add an extension
TARGET := flashme
# Point to SDCC toolchain folder
TOOLCHAIN := ../sdcc-4.0.0/bin
CC := $(TOOLCHAIN)/sdcc
OBJCOPY = $(TOOLCHAIN)/sdobjcopy
CFLAGS := \
-mmcs51 \
--model-large \
--iram-size $(IRAM_SIZE) \
--xram-size $(XRAM_SIZE) \
--code-size $(CODE_SIZE) \
-DFREQ_SYS=$(FREQ_SYS)
LDFLAGS := $(CFLAGS)
SRCS := $(shell find $(SRC_DIR)/ -name *.c ! -wholename $(MAIN))
RELS := $(patsubst $(SRC_DIR)/%.c,$(TMP_DIR)/%.rel,$(SRCS))
INC_FLAGS := $(addprefix -I,$(shell find $(SRC_DIRS) -type d ! -regex '\(.*\/\.git.*\|.\)'))
.PHONY: all
all: $(OBJ_DIR)/$(TARGET).bin
$(OBJ_DIR)/$(TARGET).bin: $(TMP_DIR)/$(TARGET).ihx
$(OBJCOPY) -I ihex -O binary $< $@
$(TMP_DIR)/$(TARGET).ihx: $(MAIN) $(RELS) $(TMP_DIR)
$(CC) $< $(RELS) -o $@ $(LDFLAGS)
$(TMP_DIR)/%.rel: $(SRC_DIR)/%.c $(TMP_DIR)
$(CC) -c $(CFLAGS) $(INC_FLAGS) $< -o $(TMP_DIR)/
$(TMP_DIR):
mkdir -p $@
$(OBJ_DIR):
mkdir -p $@
.PHONY: clean
clean:
rm -rf $(TMP_DIR)
rm -rf $(OBJ_DIR)

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#include "ch552.h"
void init_clock(void) {
#if OSC_EN_XT
SAFE_MOD = 0x55;
SAFE_MOD = 0xAA;
CLOCK_CFG |= bOSC_EN_XT; // Enable external oscillator
CLOCK_CFG &= ~bOSC_EN_INT; // Disable internal oscillator
#endif
SAFE_MOD = 0x55;
SAFE_MOD = 0xAA;
#if FREQ_SYS == 24000000
CLOCK_CFG = (CLOCK_CFG & ~MASK_SYS_CK_SEL) | 0x06; // 24MHz
#endif
#if FREQ_SYS == 16000000
CLOCK_CFG = (CLOCK_CFG & ~MASK_SYS_CK_SEL) | 0x05; // 16MHz
#endif
#if FREQ_SYS == 12000000
CLOCK_CFG = (CLOCK_CFG & ~MASK_SYS_CK_SEL) | 0x04; // 12MHz
#endif
#if FREQ_SYS == 6000000
CLOCK_CFG = (CLOCK_CFG & ~MASK_SYS_CK_SEL) | 0x03; // 6MHz
#endif
#if FREQ_SYS == 3000000
CLOCK_CFG = (CLOCK_CFG & ~MASK_SYS_CK_SEL) | 0x02; // 3MHz
#endif
#if FREQ_SYS == 750000
CLOCK_CFG = (CLOCK_CFG & ~MASK_SYS_CK_SEL) | 0x01; // 750KHz
#endif
#if FREQ_SYS == 187500
CLOCK_CFG = (CLOCK_CFG & ~MASK_SYS_CK_SEL) | 0x00; // 187.5KHz
#endif
SAFE_MOD = 0x00;
}

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/*--------------------------------------------------------------------------
ch552.h
Header file for CH552 microcontrollers.
****************************************
** Copyright (C) W.ch 1999-2016 **
** Web: http://wch.cn **
** Translated and adapted for "compiler.h" by Iscle **
****************************************
--------------------------------------------------------------------------*/
#ifndef __CH552_H__
#define __CH552_H__
#ifdef __cplusplus
extern "C" {
#endif
#include <compiler.h>
/*----- SFR --------------------------------------------------------------*/
/* sbit are bit addressable, others are byte addressable */
/* System Registers */
SFR(PSW, 0xD0); // program status word
SBIT(CY, 0xD0, 7); // carry flag
SBIT(AC, 0xD0, 6); // auxiliary carry flag
SBIT(F0, 0xD0, 5); // bit addressable general purpose flag 0
SBIT(RS1, 0xD0, 4); // register R0-R7 bank selection high bit
SBIT(RS0, 0xD0, 3); // register R0-R7 bank selection low bit
#define MASK_PSW_RS 0x18 // bit mask of register R0-R7 bank selection
// RS1 & RS0: register R0-R7 bank selection
// 00 - bank 0, R0-R7 @ address 0x00-0x07
// 01 - bank 1, R0-R7 @ address 0x08-0x0F
// 10 - bank 2, R0-R7 @ address 0x10-0x17
// 11 - bank 3, R0-R7 @ address 0x18-0x1F
SBIT(OV, 0xD0, 2); // overflow flag
SBIT(F1, 0xD0, 1); // bit addressable general purpose flag 1
SBIT(P, 0xD0, 0); // ReadOnly: parity flag
SFR(ACC, 0xE0); // accumulator
SFR(B, 0xF0); // general purpose register B
SFR(SP, 0x81); // stack pointer
//SFR16(DPTR, 0x82); // DPTR pointer, little-endian
SFR(DPL, 0x82); // data pointer low
SFR(DPH, 0x83); // data pointer high
SFR(SAFE_MOD, 0xA1); // WriteOnly: writing safe mode
//SFR(CHIP_ID, 0xA1); // ReadOnly: reading chip ID
#define CHIP_ID SAFE_MOD
SFR(GLOBAL_CFG, 0xB1); // global config, Write@SafeMode
#define bBOOT_LOAD 0x20 // ReadOnly: boot loader status for discriminating BootLoader or Application: set 1 by power on reset, clear 0 by software reset
#define bSW_RESET 0x10 // software reset bit, auto clear by hardware
#define bCODE_WE 0x08 // enable flash-ROM (include code & Data-Flash) being program or erasing: 0=writing protect, 1=enable program and erase
#define bDATA_WE 0x04 // enable Data-Flash (flash-ROM data area) being program or erasing: 0=writing protect, 1=enable program and erase
#define bLDO3V3_OFF 0x02 // disable 5V->3.3V LDO: 0=enable LDO for USB and internal oscillator under 5V power, 1=disable LDO, V33 pin input external 3.3V power
#define bWDOG_EN 0x01 // enable watch-dog reset if watch-dog timer overflow: 0=as timer only, 1=enable reset if timer overflow
/* Clock and Sleep and Power Registers */
SFR(PCON, 0x87); // power control and reset flag
#define SMOD 0x80 // baud rate selection for UART0 mode 1/2/3: 0=slow(Fsys/128 @mode2, TF1/32 @mode1/3, no effect for TF2),
// 1=fast(Fsys/32 @mode2, TF1/16 @mode1/3, no effect for TF2)
#define bRST_FLAG1 0x20 // ReadOnly: recent reset flag high bit
#define bRST_FLAG0 0x10 // ReadOnly: recent reset flag low bit
#define MASK_RST_FLAG 0x30 // ReadOnly: bit mask of recent reset flag
#define RST_FLAG_SW 0x00
#define RST_FLAG_POR 0x10
#define RST_FLAG_WDOG 0x20
#define RST_FLAG_PIN 0x30
// bPC_RST_FLAG1 & bPC_RST_FLAG0: recent reset flag
// 00 - software reset, by bSW_RESET=1 @(bBOOT_LOAD=0 or bWDOG_EN=1)
// 01 - power on reset
// 10 - watch-dog timer overflow reset
// 11 - external input manual reset by RST pin
#define GF1 0x08 // general purpose flag bit 1
#define GF0 0x04 // general purpose flag bit 0
#define PD 0x02 // power-down enable bit, auto clear by wake-up hardware
SFR(CLOCK_CFG, 0xB9); // system clock config: lower 3 bits for system clock Fsys, Write@SafeMode
#define bOSC_EN_INT 0x80 // internal oscillator enable and original clock selection: 1=enable & select internal clock, 0=disable & select external clock
#define bOSC_EN_XT 0x40 // external oscillator enable, need quartz crystal or ceramic resonator between XI and XO pins
#define bWDOG_IF_TO 0x20 // ReadOnly: watch-dog timer overflow interrupt flag, cleared by reload watch-dog count or auto cleared when MCU enter interrupt routine
#define bROM_CLK_FAST 0x10 // flash-ROM clock frequency selection: 0=normal(for Fosc>=16MHz), 1=fast(for Fosc<16MHz)
#define bRST 0x08 // ReadOnly: pin RST input
#define bT2EX_ 0x08 // alternate pin for T2EX
#define bCAP2_ 0x08 // alternate pin for CAP2
#define MASK_SYS_CK_SEL 0x07 // bit mask of system clock Fsys selection
/*
Fxt = 24MHz(8MHz~25MHz for non-USB application), from external oscillator @XI&XO
Fosc = bOSC_EN_INT ? 24MHz : Fxt
Fpll = Fosc * 4 => 96MHz (32MHz~100MHz for non-USB application)
Fusb4x = Fpll / 2 => 48MHz (Fixed)
MASK_SYS_CK_SEL[2] [1] [0]
Fsys = Fpll / 3 = 32MHz: 1 1 1
Fsys = Fpll / 4 = 24MHz: 1 1 0
Fsys = Fpll / 6 = 16MHz: 1 0 1
Fsys = Fpll / 8 = 12MHz: 1 0 0
Fsys = Fpll / 16 = 6MHz: 0 1 1
Fsys = Fpll / 32 = 3MHz: 0 1 0
Fsys = Fpll / 128 = 750KHz: 0 0 1
Fsys = Fpll / 512 = 187.5KHz: 0 0 0
*/
SFR(WAKE_CTRL, 0xA9); // wake-up control, Write@SafeMode
#define bWAK_BY_USB 0x80 // enable wake-up by USB event
#define bWAK_RXD1_LO 0x40 // enable wake-up by RXD1 low level
#define bWAK_P1_5_LO 0x20 // enable wake-up by pin P1.5 low level
#define bWAK_P1_4_LO 0x10 // enable wake-up by pin P1.4 low level
#define bWAK_P1_3_LO 0x08 // enable wake-up by pin P1.3 low level
#define bWAK_RST_HI 0x04 // enable wake-up by pin RST high level
#define bWAK_P3_2E_3L 0x02 // enable wake-up by pin P3.2 (INT0) edge or pin P3.3 (INT1) low level
#define bWAK_RXD0_LO 0x01 // enable wake-up by RXD0 low level
SFR(RESET_KEEP, 0xFE); // value keeper during reset
SFR(WDOG_COUNT, 0xFF); // watch-dog count, count by clock frequency Fsys/65536
/* Interrupt Registers */
SFR(IE, 0xA8); // interrupt enable
SBIT(EA, 0xA8, 7); // enable global interrupts: 0=disable, 1=enable if E_DIS=0
SBIT(E_DIS, 0xA8, 6); // disable global interrupts, intend to inhibit interrupt during some flash-ROM operation: 0=enable if EA=1, 1=disable
SBIT(ET2, 0xA8, 5); // enable timer2 interrupt
SBIT(ES, 0xA8, 4); // enable UART0 interrupt
SBIT(ET1, 0xA8, 3); // enable timer1 interrupt
SBIT(EX1, 0xA8, 2); // enable external interrupt INT1
SBIT(ET0, 0xA8, 1); // enable timer0 interrupt
SBIT(EX0, 0xA8, 0); // enable external interrupt INT0
SFR(IP, 0xB8); // interrupt priority and current priority
SBIT(PH_FLAG, 0xB8, 7); // ReadOnly: high level priority action flag
SBIT(PL_FLAG, 0xB8, 6); // ReadOnly: low level priority action flag
// PH_FLAG & PL_FLAG: current interrupt priority
// 00 - no interrupt now
// 01 - low level priority interrupt action now
// 10 - high level priority interrupt action now
// 11 - unknown error
SBIT(PT2, 0xB8, 5); // timer2 interrupt priority level
SBIT(PS, 0xB8, 4); // UART0 interrupt priority level
SBIT(PT1, 0xB8, 3); // timer1 interrupt priority level
SBIT(PX1, 0xB8, 2); // external interrupt INT1 priority level
SBIT(PT0, 0xB8, 1); // timer0 interrupt priority level
SBIT(PX0, 0xB8, 0); // external interrupt INT0 priority level
SFR(IE_EX, 0xE8); // extend interrupt enable
SBIT(IE_WDOG, 0xE8, 7); // enable watch-dog timer interrupt
SBIT(IE_GPIO, 0xE8, 6); // enable GPIO input interrupt
SBIT(IE_PWMX, 0xE8, 5); // enable PWM1/2 interrupt
SBIT(IE_UART1, 0xE8, 4); // enable UART1 interrupt
SBIT(IE_ADC, 0xE8, 3); // enable ADC interrupt
SBIT(IE_USB, 0xE8, 2); // enable USB interrupt
SBIT(IE_TKEY, 0xE8, 1); // enable touch-key timer interrupt
SBIT(IE_SPI0, 0xE8, 0); // enable SPI0 interrupt
SFR(IP_EX, 0xE9); // extend interrupt priority
#define bIP_LEVEL 0x80 // ReadOnly: current interrupt nested level: 0=no interrupt or two levels, 1=one level
#define bIP_GPIO 0x40 // GPIO input interrupt priority level
#define bIP_PWMX 0x20 // PWM1/2 interrupt priority level
#define bIP_UART1 0x10 // UART1 interrupt priority level
#define bIP_ADC 0x08 // ADC interrupt priority level
#define bIP_USB 0x04 // USB interrupt priority level
#define bIP_TKEY 0x02 // touch-key timer interrupt priority level
#define bIP_SPI0 0x01 // SPI0 interrupt priority level
SFR(GPIO_IE, 0xC7); // GPIO interrupt enable
#define bIE_IO_EDGE 0x80 // enable GPIO edge interrupt: 0=low/high level, 1=falling/rising edge
#define bIE_RXD1_LO 0x40 // enable interrupt by RXD1 low level / falling edge
#define bIE_P1_5_LO 0x20 // enable interrupt by pin P1.5 low level / falling edge
#define bIE_P1_4_LO 0x10 // enable interrupt by pin P1.4 low level / falling edge
#define bIE_P1_3_LO 0x08 // enable interrupt by pin P1.3 low level / falling edge
#define bIE_RST_HI 0x04 // enable interrupt by pin RST high level / rising edge
#define bIE_P3_1_LO 0x02 // enable interrupt by pin P3.1 low level / falling edge
#define bIE_RXD0_LO 0x01 // enable interrupt by RXD0 low level / falling edge
/* FlashROM and Data-Flash Registers */
SFR16(ROM_ADDR, 0x84); // address for flash-ROM, little-endian
SFR(ROM_ADDR_L, 0x84); // address low byte for flash-ROM
SFR(ROM_ADDR_H, 0x85); // address high byte for flash-ROM
SFR16(ROM_DATA, 0x8E); // data for flash-ROM writing, little-endian
SFR(ROM_DATA_L, 0x8E); // data low byte for flash-ROM writing, data byte for Data-Flash reading/writing
SFR(ROM_DATA_H, 0x8F); // data high byte for flash-ROM writing
SFR(ROM_CTRL, 0x86); // WriteOnly: flash-ROM control
#define ROM_CMD_WRITE 0x9A // WriteOnly: flash-ROM word or Data-Flash byte write operation command
#define ROM_CMD_READ 0x8E // WriteOnly: Data-Flash byte read operation command
//SFR(ROM_STATUS, 0x86); // ReadOnly: flash-ROM status
#define ROM_STATUS ROM_CTRL
#define bROM_ADDR_OK 0x40 // ReadOnly: flash-ROM writing operation address valid flag, can be reviewed before or after operation: 0=invalid parameter, 1=address valid
#define bROM_CMD_ERR 0x02 // ReadOnly: flash-ROM operation command error flag: 0=command accepted, 1=unknown command
/* Port Registers */
SFR(P1, 0x90); // port 1 input & output
SBIT(SCK, 0x90, 7); // serial clock for SPI0
SBIT(TXD1, 0x90, 7); // TXD output for UART1
SBIT(TIN5, 0x90, 7); // TIN5 for Touch-Key
SBIT(MISO, 0x90, 6); // master serial data input or slave serial data output for SPI0
SBIT(RXD1, 0x90, 6); // RXD input for UART1
SBIT(TIN4, 0x90, 6); // TIN4 for Touch-Key
SBIT(MOSI, 0x90, 5); // master serial data output or slave serial data input for SPI0
SBIT(PWM1, 0x90, 5); // PWM output for PWM1
SBIT(TIN3, 0x90, 5); // TIN3 for Touch-Key
SBIT(UCC2, 0x90, 5); // CC2 for USB type-C
SBIT(AIN2, 0x90, 5); // AIN2 for ADC
SBIT(T2_, 0x90, 4); // alternate pin for T2
SBIT(CAP1_, 0x90, 4); // alternate pin for CAP1
SBIT(SCS, 0x90, 4); // slave chip-selection input for SPI0
SBIT(TIN2, 0x90, 4); // TIN2 for Touch-Key
SBIT(UCC1, 0x90, 4); // CC1 for USB type-C
SBIT(AIN1, 0x90, 4); // AIN1 for ADC
SBIT(TXD_, 0x90, 3); // alternate pin for TXD of UART0
SBIT(RXD_, 0x90, 2); // alternate pin for RXD of UART0
SBIT(T2EX, 0x90, 1); // external trigger input for timer2 reload & capture
SBIT(CAP2, 0x90, 1); // capture2 input for timer2
SBIT(TIN1, 0x90, 1); // TIN1 for Touch-Key
SBIT(VBUS2, 0x90, 1); // VBUS2 for USB type-C
SBIT(AIN0, 0x90, 1); // AIN0 for ADC
SBIT(T2, 0x90, 0); // external count input
SBIT(CAP1, 0x90, 0); // capture1 input for timer2
SBIT(TIN0, 0x90, 0); // TIN0 for Touch-Key
SFR(P1_MOD_OC, 0x92); // port 1 output mode: 0=push-pull, 1=open-drain
SFR(P1_DIR_PU, 0x93); // port 1 direction for push-pull or pullup enable for open-drain
// Pn_MOD_OC & Pn_DIR_PU: pin input & output configuration for Pn (n=1/3)
// 0 0: float input only, without pullup resistance
// 0 1: push-pull output, strong driving high level and low level
// 1 0: open-drain output and input without pullup resistance
// 1 1: quasi-bidirectional (standard 8051 mode), open-drain output and input with pullup resistance, just driving high level strongly for 2 clocks if turning output level from low to high
#define bSCK 0x80 // serial clock for SPI0
#define bTXD1 0x80 // TXD output for UART1
#define bMISO 0x40 // master serial data input or slave serial data output for SPI0
#define bRXD1 0x40 // RXD input for UART1
#define bMOSI 0x20 // master serial data output or slave serial data input for SPI0
#define bPWM1 0x20 // PWM output for PWM1
#define bUCC2 0x20 // CC2 for USB type-C
#define bAIN2 0x20 // AIN2 for ADC
#define bT2_ 0x10 // alternate pin for T2
#define bCAP1_ 0x10 // alternate pin for CAP1
#define bSCS 0x10 // slave chip-selection input for SPI0
#define bUCC1 0x10 // CC1 for USB type-C
#define bAIN1 0x10 // AIN1 for ADC
#define bTXD_ 0x08 // alternate pin for TXD of UART0
#define bRXD_ 0x04 // alternate pin for RXD of UART0
#define bT2EX 0x02 // external trigger input for timer2 reload & capture
#define bCAP2 bT2EX // capture2 input for timer2
#define bVBUS2 0x02 // VBUS2 for USB type-C
#define bAIN0 0x02 // AIN0 for ADC
#define bT2 0x01 // external count input or clock output for timer2
#define bCAP1 bT2 // capture1 input for timer2
SFR(P2, 0xA0); // port 2
SFR(P3, 0xB0); // port 3 input & output
SBIT(UDM, 0xB0, 7); // ReadOnly: pin UDM input
SBIT(UDP, 0xB0, 6); // ReadOnly: pin UDP input
SBIT(T1, 0xB0, 5); // external count input for timer1
SBIT(PWM2, 0xB0, 4); // PWM output for PWM2
SBIT(RXD1_, 0xB0, 4); // alternate pin for RXD1
SBIT(T0, 0xB0, 4); // external count input for timer0
SBIT(INT1, 0xB0, 3); // external interrupt 1 input
SBIT(TXD1_, 0xB0, 2); // alternate pin for TXD1
SBIT(INT0, 0xB0, 2); // external interrupt 0 input
SBIT(VBUS1, 0xB0, 2); // VBUS1 for USB type-C
SBIT(AIN3, 0xB0, 2); // AIN3 for ADC
SBIT(PWM2_, 0xB0, 1); // alternate pin for PWM2
SBIT(TXD, 0xB0, 1); // TXD output for UART0
SBIT(PWM1_, 0xB0, 0); // alternate pin for PWM1
SBIT(RXD, 0xB0, 0); // RXD input for UART0
SFR(P3_MOD_OC, 0x96); // port 3 output mode: 0=push-pull, 1=open-drain
SFR(P3_DIR_PU, 0x97); // port 3 direction for push-pull or pullup enable for open-drain
#define bUDM 0x80 // ReadOnly: pin UDM input
#define bUDP 0x40 // ReadOnly: pin UDP input
#define bT1 0x20 // external count input for timer1
#define bPWM2 0x10 // PWM output for PWM2
#define bRXD1_ 0x10 // alternate pin for RXD1
#define bT0 0x10 // external count input for timer0
#define bINT1 0x08 // external interrupt 1 input
#define bTXD1_ 0x04 // alternate pin for TXD1
#define bINT0 0x04 // external interrupt 0 input
#define bVBUS1 0x04 // VBUS1 for USB type-C
#define bAIN3 0x04 // AIN3 for ADC
#define bPWM2_ 0x02 // alternate pin for PWM2
#define bTXD 0x02 // TXD output for UART0
#define bPWM1_ 0x01 // alternate pin for PWM1
#define bRXD 0x01 // RXD input for UART0
SFR(PIN_FUNC, 0xC6); // pin function selection
#define bUSB_IO_EN 0x80 // USB UDP/UDM I/O pin enable: 0=P3.6/P3.7 as GPIO, 1=P3.6/P3.7 as USB
#define bIO_INT_ACT 0x40 // ReadOnly: GPIO interrupt request action status
#define bUART1_PIN_X 0x20 // UART1 alternate pin enable: 0=RXD1/TXD1 on P1.6/P1.7, 1=RXD1/TXD1 on P3.4/P3.2
#define bUART0_PIN_X 0x10 // UART0 alternate pin enable: 0=RXD0/TXD0 on P3.0/P3.1, 1=RXD0/TXD0 on P1.2/P1.3
#define bPWM2_PIN_X 0x08 // PWM2 alternate pin enable: 0=PWM2 on P3.4, 1=PWM2 on P3.1
#define bPWM1_PIN_X 0x04 // PWM1 alternate pin enable: 0=PWM1 on P1.5, 1=PWM1 on P3.0
#define bT2EX_PIN_X 0x02 // T2EX/CAP2 alternate pin enable: 0=T2EX/CAP2 on P1.1, 1=T2EX/CAP2 on RST
#define bT2_PIN_X 0x01 // T2/CAP1 alternate pin enable: 0=T2/CAP1 on P1.1, 1=T2/CAP1 on P1.4
SFR(XBUS_AUX, 0xA2); // xBUS auxiliary setting
#define bUART0_TX 0x80 // ReadOnly: indicate UART0 transmittal status
#define bUART0_RX 0x40 // ReadOnly: indicate UART0 receiving status
#define bSAFE_MOD_ACT 0x20 // ReadOnly: safe mode action status
#define GF2 0x08 // general purpose flag bit 2
#define bDPTR_AUTO_INC 0x04 // enable DPTR auto increase if finished MOVX_@DPTR instruction
#define DPS 0x01 // dual DPTR selection: 0=DPTR0 selected, 1=DPTR1 selected
/* Timer0/1 Registers */
SFR(TCON, 0x88); // timer 0/1 control and external interrupt control
SBIT(TF1, 0x88, 7); // timer1 overflow & interrupt flag, auto cleared when MCU enter interrupt routine
SBIT(TR1, 0x88, 6); // timer1 run enable
SBIT(TF0, 0x88, 5); // timer0 overflow & interrupt flag, auto cleared when MCU enter interrupt routine
SBIT(TR0, 0x88, 4); // timer0 run enable
SBIT(IE1, 0x88, 3); // INT1 interrupt flag, auto cleared when MCU enter interrupt routine
SBIT(IT1, 0x88, 2); // INT1 interrupt type: 0=low level action, 1=falling edge action
SBIT(IE0, 0x88, 1); // INT0 interrupt flag, auto cleared when MCU enter interrupt routine
SBIT(IT0, 0x88, 0); // INT0 interrupt type: 0=low level action, 1=falling edge action
SFR(TMOD, 0x89); // timer 0/1 mode
#define bT1_GATE 0x80 // gate control of timer1: 0=timer1 run enable while TR1=1, 1=timer1 run enable while P3.3 (INT1) pin is high and TR1=1
#define bT1_CT 0x40 // counter or timer mode selection for timer1: 0=timer, use internal clock, 1=counter, use P3.5 (T1) pin falling edge as clock
#define bT1_M1 0x20 // timer1 mode high bit
#define bT1_M0 0x10 // timer1 mode low bit
#define MASK_T1_MOD 0x30 // bit mask of timer1 mode
// bT1_M1 & bT1_M0: timer1 mode
// 00: mode 0, 13-bit timer or counter by cascaded TH1 and lower 5 bits of TL1, the upper 3 bits of TL1 are ignored
// 01: mode 1, 16-bit timer or counter by cascaded TH1 and TL1
// 10: mode 2, TL1 operates as 8-bit timer or counter, and TH1 provide initial value for TL1 auto-reload
// 11: mode 3, stop timer1
#define bT0_GATE 0x08 // gate control of timer0: 0=timer0 run enable while TR0=1, 1=timer0 run enable while P3.2 (INT0) pin is high and TR0=1
#define bT0_CT 0x04 // counter or timer mode selection for timer0: 0=timer, use internal clock, 1=counter, use P3.4 (T0) pin falling edge as clock
#define bT0_M1 0x02 // timer0 mode high bit
#define bT0_M0 0x01 // timer0 mode low bit
#define MASK_T0_MOD 0x03 // bit mask of timer0 mode
// bT0_M1 & bT0_M0: timer0 mode
// 00: mode 0, 13-bit timer or counter by cascaded TH0 and lower 5 bits of TL0, the upper 3 bits of TL0 are ignored
// 01: mode 1, 16-bit timer or counter by cascaded TH0 and TL0
// 10: mode 2, TL0 operates as 8-bit timer or counter, and TH0 provide initial value for TL0 auto-reload
// 11: mode 3, TL0 is 8-bit timer or counter controlled by standard timer0 bits, TH0 is 8-bit timer using TF1 and controlled by TR1, timer1 run enable if it is not mode 3
SFR(TL0, 0x8A); // low byte of timer 0 count
SFR(TL1, 0x8B); // low byte of timer 1 count
SFR(TH0, 0x8C); // high byte of timer 0 count
SFR(TH1, 0x8D); // high byte of timer 1 count
/* UART0 Registers */
SFR(SCON, 0x98); // UART0 control (serial port control)
SBIT(SM0, 0x98, 7); // UART0 mode bit0, selection data bit: 0=8 bits data, 1=9 bits data
SBIT(SM1, 0x98, 6); // UART0 mode bit1, selection baud rate: 0=fixed, 1=variable
// SM0 & SM1: UART0 mode
// 00 - mode 0, shift Register, baud rate fixed at: Fsys/12
// 01 - mode 1, 8-bit UART, baud rate = variable by timer1 or timer2 overflow rate
// 10 - mode 2, 9-bit UART, baud rate fixed at: Fsys/128@SMOD=0, Fsys/32@SMOD=1
// 11 - mode 3, 9-bit UART, baud rate = variable by timer1 or timer2 overflow rate
SBIT(SM2, 0x98, 5); // enable multi-device communication in mode 2/3
#define MASK_UART0_MOD 0xE0 // bit mask of UART0 mode
SBIT(REN, 0x98, 4); // enable UART0 receiving
SBIT(TB8, 0x98, 3); // the 9th transmitted data bit in mode 2/3
SBIT(RB8, 0x98, 2); // 9th data bit received in mode 2/3, or stop bit received for mode 1
SBIT(TI, 0x98, 1); // transmit interrupt flag, set by hardware after completion of a serial transmittal, need software clear
SBIT(RI, 0x98, 0); // receive interrupt flag, set by hardware after completion of a serial receiving, need software clear
SFR(SBUF, 0x99); // UART0 data buffer: reading for receiving, writing for transmittal
/* Timer2/Capture2 Registers */
SFR(T2CON, 0xC8); // timer 2 control
SBIT(TF2, 0xC8, 7); // timer2 overflow & interrupt flag, need software clear, the flag will not be set when either RCLK=1 or TCLK=1
SBIT(CAP1F, 0xC8, 7); // timer2 capture 1 interrupt flag, set by T2 edge trigger if bT2_CAP1_EN=1, need software clear
SBIT(EXF2, 0xC8, 6); // timer2 external flag, set by T2EX edge trigger if EXEN2=1, need software clear
SBIT(RCLK, 0xC8, 5); // selection UART0 receiving clock: 0=timer1 overflow pulse, 1=timer2 overflow pulse
SBIT(TCLK, 0xC8, 4); // selection UART0 transmittal clock: 0=timer1 overflow pulse, 1=timer2 overflow pulse
SBIT(EXEN2, 0xC8, 3); // enable T2EX trigger function: 0=ignore T2EX, 1=trigger reload or capture by T2EX edge
SBIT(TR2, 0xC8, 2); // timer2 run enable
SBIT(C_T2, 0xC8, 1); // timer2 clock source selection: 0=timer base internal clock, 1=external edge counter base T2 falling edge
SBIT(CP_RL2, 0xC8, 0); // timer2 function selection (force 0 if RCLK=1 or TCLK=1): 0=timer and auto reload if count overflow or T2EX edge, 1=capture by T2EX edge
SFR(T2MOD, 0xC9); // timer 2 mode and timer 0/1/2 clock mode
#define bTMR_CLK 0x80 // fastest internal clock mode for timer 0/1/2 under faster clock mode: 0=use divided clock, 1=use original Fsys as clock without dividing
#define bT2_CLK 0x40 // timer2 internal clock frequency selection: 0=standard clock, Fsys/12 for timer mode, Fsys/4 for UART0 clock mode,
// 1=faster clock, Fsys/4 @bTMR_CLK=0 or Fsys @bTMR_CLK=1 for timer mode, Fsys/2 @bTMR_CLK=0 or Fsys @bTMR_CLK=1 for UART0 clock mode
#define bT1_CLK 0x20 // timer1 internal clock frequency selection: 0=standard clock, Fsys/12, 1=faster clock, Fsys/4 if bTMR_CLK=0 or Fsys if bTMR_CLK=1
#define bT0_CLK 0x10 // timer0 internal clock frequency selection: 0=standard clock, Fsys/12, 1=faster clock, Fsys/4 if bTMR_CLK=0 or Fsys if bTMR_CLK=1
#define bT2_CAP_M1 0x08 // timer2 capture mode high bit
#define bT2_CAP_M0 0x04 // timer2 capture mode low bit
// bT2_CAP_M1 & bT2_CAP_M0: timer2 capture point selection
// x0: from falling edge to falling edge
// 01: from any edge to any edge (level changing)
// 11: from rising edge to rising edge
#define T2OE 0x02 // enable timer2 generated clock output: 0=disable output, 1=enable clock output at T2 pin, frequency = TF2/2
#define bT2_CAP1_EN 0x01 // enable T2 trigger function for capture 1 of timer2 if RCLK=0 & TCLK=0 & CP_RL2=1 & C_T2=0 & T2OE=0
SFR16(RCAP2, 0xCA); // reload & capture value, little-endian
SFR(RCAP2L, 0xCA); // low byte of reload & capture value
SFR(RCAP2H, 0xCB); // high byte of reload & capture value
SFR16(T2COUNT, 0xCC); // counter, little-endian
SFR(TL2, 0xCC); // low byte of timer 2 count
SFR(TH2, 0xCD); // high byte of timer 2 count
SFR16(T2CAP1, 0xCE); // ReadOnly: capture 1 value for timer2
SFR(T2CAP1L, 0xCE); // ReadOnly: capture 1 value low byte for timer2
SFR(T2CAP1H, 0xCF); // ReadOnly: capture 1 value high byte for timer2
/* PWM1/2 Registers */
SFR(PWM_DATA2, 0x9B); // PWM data for PWM2
SFR(PWM_DATA1, 0x9C); // PWM data for PWM1
SFR(PWM_CTRL, 0x9D); // PWM 1/2 control
#define bPWM_IE_END 0x80 // enable interrupt for PWM mode cycle end
#define bPWM2_POLAR 0x40 // PWM2 output polarity: 0=default low and high action, 1=default high and low action
#define bPWM1_POLAR 0x20 // PWM1 output polarity: 0=default low and high action, 1=default high and low action
#define bPWM_IF_END 0x10 // interrupt flag for cycle end, write 1 to clear or write PWM_CYCLE or load new data to clear
#define bPWM2_OUT_EN 0x08 // PWM2 output enable
#define bPWM1_OUT_EN 0x04 // PWM1 output enable
#define bPWM_CLR_ALL 0x02 // force clear FIFO and count of PWM1/2
SFR(PWM_CK_SE, 0x9E); // clock divisor setting
/* SPI0/Master0/Slave Registers */
SFR(SPI0_STAT, 0xF8); // SPI 0 status
SBIT(S0_FST_ACT, 0xF8, 7); // ReadOnly: indicate first byte received status for SPI0
SBIT(S0_IF_OV, 0xF8, 6); // interrupt flag for slave mode FIFO overflow, direct bit address clear or write 1 to clear
SBIT(S0_IF_FIRST, 0xF8, 5); // interrupt flag for first byte received, direct bit address clear or write 1 to clear
SBIT(S0_IF_BYTE, 0xF8, 4); // interrupt flag for a byte data exchanged, direct bit address clear or write 1 to clear or accessing FIFO to clear if bS0_AUTO_IF=1
SBIT(S0_FREE, 0xF8, 3); // ReadOnly: SPI0 free status
SBIT(S0_T_FIFO, 0xF8, 2); // ReadOnly: tx FIFO count for SPI0
SBIT(S0_R_FIFO, 0xF8, 0); // ReadOnly: rx FIFO count for SPI0
SFR(SPI0_DATA, 0xF9); // FIFO data port: reading for receiving, writing for transmittal
SFR(SPI0_CTRL, 0xFA); // SPI 0 control
#define bS0_MISO_OE 0x80 // SPI0 MISO output enable
#define bS0_MOSI_OE 0x40 // SPI0 MOSI output enable
#define bS0_SCK_OE 0x20 // SPI0 SCK output enable
#define bS0_DATA_DIR 0x10 // SPI0 data direction: 0=out(master_write), 1=in(master_read)
#define bS0_MST_CLK 0x08 // SPI0 master clock mode: 0=mode 0 with default low, 1=mode 3 with default high
#define bS0_2_WIRE 0x04 // enable SPI0 two wire mode: 0=3 wire (SCK+MOSI+MISO), 1=2 wire (SCK+MISO)
#define bS0_CLR_ALL 0x02 // force clear FIFO and count of SPI0
#define bS0_AUTO_IF 0x01 // enable FIFO accessing to auto clear S0_IF_BYTE interrupt flag
SFR(SPI0_CK_SE, 0xFB); // clock divisor setting
//SFR(SPI0_S_PRE, 0xFB); // preset value for SPI slave
#define SPI0_S_PRE SPI0_CK_SE
SFR(SPI0_SETUP, 0xFC); // SPI 0 setup
#define bS0_MODE_SLV 0x80 // SPI0 slave mode: 0=master, 1=slave
#define bS0_IE_FIFO_OV 0x40 // enable interrupt for slave mode FIFO overflow
#define bS0_IE_FIRST 0x20 // enable interrupt for first byte received for SPI0 slave mode
#define bS0_IE_BYTE 0x10 // enable interrupt for a byte received
#define bS0_BIT_ORDER 0x08 // SPI0 bit data order: 0=MSB first, 1=LSB first
#define bS0_SLV_SELT 0x02 // ReadOnly: SPI0 slave mode chip selected status: 0=unselected, 1=selected
#define bS0_SLV_PRELOAD 0x01 // ReadOnly: SPI0 slave mode data pre-loading status just after chip-selection
/* UART1 Registers */
SFR(SCON1, 0xC0); // UART1 control (serial port control)
SBIT(U1SM0, 0xC0, 7); // UART1 mode, selection data bit: 0=8 bits data, 1=9 bits data
SBIT(U1SMOD, 0xC0, 5); // UART1 2X baud rate selection: 0=slow(Fsys/32/(256-SBAUD1)), 1=fast(Fsys/16/(256-SBAUD1))
SBIT(U1REN, 0xC0, 4); // enable UART1 receiving
SBIT(U1TB8, 0xC0, 3); // the 9th transmitted data bit in 9 bits data mode
SBIT(U1RB8, 0xC0, 2); // 9th data bit received in 9 bits data mode, or stop bit received for 8 bits data mode
SBIT(U1TI, 0xC0, 1); // transmit interrupt flag, set by hardware after completion of a serial transmittal, need software clear
SBIT(U1RI, 0xC0, 0); // receive interrupt flag, set by hardware after completion of a serial receiving, need software clear
SFR(SBUF1, 0xC1); // UART1 data buffer: reading for receiving, writing for transmittal
SFR(SBAUD1, 0xC2); // UART1 baud rate setting
/* ADC and comparator Registers */
SFR(ADC_CTRL, 0x80); // ADC control
SBIT(CMPO, 0x80, 7); // ReadOnly: comparator result input
SBIT(CMP_IF, 0x80, 6); // flag for comparator result changed, direct bit address clear
SBIT(ADC_IF, 0x80, 5); // interrupt flag for ADC finished, direct bit address clear
SBIT(ADC_START, 0x80, 4); // set 1 to start ADC, auto cleared when ADC finished
SBIT(CMP_CHAN, 0x80, 3); // comparator IN- input channel selection: 0=AIN1, 1=AIN3
SBIT(ADC_CHAN1, 0x80, 1); // ADC/comparator IN+ channel selection high bit
SBIT(ADC_CHAN0, 0x80, 0); // ADC/comparator IN+ channel selection low bit
// ADC_CHAN1 & ADC_CHAN0: ADC/comparator IN+ channel selection
// 00: AIN0(P1.1)
// 01: AIN1(P1.4)
// 10: AIN2(P1.5)
// 11: AIN3(P3.2)
SFR(ADC_CFG, 0x9A); // ADC config
#define bADC_EN 0x08 // control ADC power: 0=shut down ADC, 1=enable power for ADC
#define bCMP_EN 0x04 // control comparator power: 0=shut down comparator, 1=enable power for comparator
#define bADC_CLK 0x01 // ADC clock frequency selection: 0=slow clock, 384 Fosc cycles for each ADC, 1=fast clock, 96 Fosc cycles for each ADC
SFR(ADC_DATA, 0x9F); // ReadOnly: ADC data
/* Touch-key timer Registers */
SFR(TKEY_CTRL, 0xC3); // touch-key control
#define bTKC_IF 0x80 // ReadOnly: interrupt flag for touch-key timer, cleared by writing touch-key control or auto cleared when start touch-key checking
#define bTKC_2MS 0x10 // touch-key timer cycle selection: 0=1mS, 1=2mS
#define bTKC_CHAN2 0x04 // touch-key channel selection high bit
#define bTKC_CHAN1 0x02 // touch-key channel selection middle bit
#define bTKC_CHAN0 0x01 // touch-key channel selection low bit
// bTKC_CHAN2 & bTKC_CHAN1 & bTKC_CHAN0: touch-key channel selection
// 000: disable touch-key
// 001: TIN0(P1.0)
// 010: TIN1(P1.1)
// 011: TIN2(P1.4)
// 100: TIN3(P1.5)
// 101: TIN4(P1.6)
// 110: TIN5(P1.7)
// 111: enable touch-key but disable all channel
SFR16(TKEY_DAT, 0xC4); // ReadOnly: touch-key data, little-endian
SFR(TKEY_DATL, 0xC4); // ReadOnly: low byte of touch-key data
SFR(TKEY_DATH, 0xC5); // ReadOnly: high byte of touch-key data
#define bTKD_CHG 0x80 // ReadOnly: indicate control changed, current data maybe invalid
/* USB Device Registers */
SFR(USB_C_CTRL, 0x91); // USB type-C control
#define bVBUS2_PD_EN 0x80 // USB VBUS2 10K pulldown resistance: 0=disable, 1=enable pullup
#define bUCC2_PD_EN 0x40 // USB CC2 5.1K pulldown resistance: 0=disable, 1=enable pulldown
#define bUCC2_PU1_EN 0x20 // USB CC2 pullup resistance control high bit
#define bUCC2_PU0_EN 0x10 // USB CC2 pullup resistance control low bit
#define bVBUS1_PD_EN 0x08 // USB VBUS1 10K pulldown resistance: 0=disable, 1=enable pullup
#define bUCC1_PD_EN 0x04 // USB CC1 5.1K pulldown resistance: 0=disable, 1=enable pulldown
#define bUCC1_PU1_EN 0x02 // USB CC1 pullup resistance control high bit
#define bUCC1_PU0_EN 0x01 // USB CC1 pullup resistance control low bit
// bUCC?_PU1_EN & bUCC?_PU0_EN: USB CC pullup resistance selection
// 00: disable pullup resistance
// 01: enable 56K pullup resistance for default USB power
// 10: enable 22K pullup resistance for 1.5A USB power
// 11: enable 10K pullup resistance for 3A USB power
SFR(UDEV_CTRL, 0xD1); // USB device physical port control
#define bUD_PD_DIS 0x80 // disable USB UDP/UDM pulldown resistance: 0=enable pulldown, 1=disable
#define bUD_DP_PIN 0x20 // ReadOnly: indicate current UDP pin level
#define bUD_DM_PIN 0x10 // ReadOnly: indicate current UDM pin level
#define bUD_LOW_SPEED 0x04 // enable USB physical port low speed: 0=full speed, 1=low speed
#define bUD_GP_BIT 0x02 // general purpose bit
#define bUD_PORT_EN 0x01 // enable USB physical port I/O: 0=disable, 1=enable
SFR(UEP1_CTRL, 0xD2); // endpoint 1 control
#define bUEP_R_TOG 0x80 // expected data toggle flag of USB endpoint X receiving (OUT): 0=DATA0, 1=DATA1
#define bUEP_T_TOG 0x40 // prepared data toggle flag of USB endpoint X transmittal (IN): 0=DATA0, 1=DATA1
#define bUEP_AUTO_TOG 0x10 // enable automatic toggle after successful transfer completion on endpoint 1/2/3: 0=manual toggle, 1=automatic toggle
#define bUEP_R_RES1 0x08 // handshake response type high bit for USB endpoint X receiving (OUT)
#define bUEP_R_RES0 0x04 // handshake response type low bit for USB endpoint X receiving (OUT)
#define MASK_UEP_R_RES 0x0C // bit mask of handshake response type for USB endpoint X receiving (OUT)
#define UEP_R_RES_ACK 0x00
#define UEP_R_RES_TOUT 0x04
#define UEP_R_RES_NAK 0x08
#define UEP_R_RES_STALL 0x0C
// bUEP_R_RES1 & bUEP_R_RES0: handshake response type for USB endpoint X receiving (OUT)
// 00: ACK (ready)
// 01: no response, time out to host, for non-zero endpoint isochronous transactions
// 10: NAK (busy)
// 11: STALL (error)
#define bUEP_T_RES1 0x02 // handshake response type high bit for USB endpoint X transmittal (IN)
#define bUEP_T_RES0 0x01 // handshake response type low bit for USB endpoint X transmittal (IN)
#define MASK_UEP_T_RES 0x03 // bit mask of handshake response type for USB endpoint X transmittal (IN)
#define UEP_T_RES_ACK 0x00
#define UEP_T_RES_TOUT 0x01
#define UEP_T_RES_NAK 0x02
#define UEP_T_RES_STALL 0x03
// bUEP_T_RES1 & bUEP_T_RES0: handshake response type for USB endpoint X transmittal (IN)
// 00: DATA0 or DATA1 then expecting ACK (ready)
// 01: DATA0 or DATA1 then expecting no response, time out from host, for non-zero endpoint isochronous transactions
// 10: NAK (busy)
// 11: STALL (error)
SFR(UEP1_T_LEN, 0xD3); // endpoint 1 transmittal length
SFR(UEP2_CTRL, 0xD4); // endpoint 2 control
SFR(UEP2_T_LEN, 0xD5); // endpoint 2 transmittal length
SFR(UEP3_CTRL, 0xD6); // endpoint 3 control
SFR(UEP3_T_LEN, 0xD7); // endpoint 3 transmittal length
SFR(USB_INT_FG, 0xD8); // USB interrupt flag
SBIT(U_IS_NAK, 0xD8, 7); // ReadOnly: indicate current USB transfer is NAK received
SBIT(U_TOG_OK, 0xD8, 6); // ReadOnly: indicate current USB transfer toggle is OK
SBIT(U_SIE_FREE, 0xD8, 5); // ReadOnly: indicate USB SIE free status
SBIT(UIF_FIFO_OV, 0xD8, 4); // FIFO overflow interrupt flag for USB, direct bit address clear or write 1 to clear
SBIT(UIF_SUSPEND, 0xD8, 2); // USB suspend or resume event interrupt flag, direct bit address clear or write 1 to clear
SBIT(UIF_TRANSFER, 0xD8, 1); // USB transfer completion interrupt flag, direct bit address clear or write 1 to clear
SBIT(UIF_BUS_RST, 0xD8, 0); // bus reset event interrupt flag, direct bit address clear or write 1 to clear
SFR(USB_INT_ST, 0xD9); // ReadOnly: USB interrupt status
#define bUIS_IS_NAK 0x80 // ReadOnly: indicate current USB transfer is NAK received
#define bUIS_TOG_OK 0x40 // ReadOnly: indicate current USB transfer toggle is OK
#define bUIS_TOKEN1 0x20 // ReadOnly: current token PID code bit 1 received
#define bUIS_TOKEN0 0x10 // ReadOnly: current token PID code bit 0 received
#define MASK_UIS_TOKEN 0x30 // ReadOnly: bit mask of current token PID code received
#define UIS_TOKEN_OUT 0x00
#define UIS_TOKEN_SOF 0x10
#define UIS_TOKEN_IN 0x20
#define UIS_TOKEN_SETUP 0x30
// bUIS_TOKEN1 & bUIS_TOKEN0: current token PID code received
// 00: OUT token PID received
// 01: SOF token PID received
// 10: IN token PID received
// 11: SETUP token PID received
#define MASK_UIS_ENDP 0x0F // ReadOnly: bit mask of current transfer endpoint number
SFR(USB_MIS_ST, 0xDA); // ReadOnly: USB miscellaneous status
#define bUMS_SIE_FREE 0x20 // ReadOnly: indicate USB SIE free status
#define bUMS_R_FIFO_RDY 0x10 // ReadOnly: indicate USB receiving FIFO ready status (not empty)
#define bUMS_BUS_RESET 0x08 // ReadOnly: indicate USB bus reset status
#define bUMS_SUSPEND 0x04 // ReadOnly: indicate USB suspend status
SFR(USB_RX_LEN, 0xDB); // ReadOnly: USB receiving length
SFR(UEP0_CTRL, 0xDC); // endpoint 0 control
SFR(UEP0_T_LEN, 0xDD); // endpoint 0 transmittal length
SFR(UEP4_CTRL, 0xDE); // endpoint 4 control
SFR(UEP4_T_LEN, 0xDF); // endpoint 4 transmittal length
SFR(USB_INT_EN, 0xE1); // USB interrupt enable
#define bUIE_DEV_SOF 0x80 // enable interrupt for SOF received
#define bUIE_DEV_NAK 0x40 // enable interrupt for NAK responded
#define bUIE_FIFO_OV 0x10 // enable interrupt for FIFO overflow
#define bUIE_SUSPEND 0x04 // enable interrupt for USB suspend or resume event
#define bUIE_TRANSFER 0x02 // enable interrupt for USB transfer completion
#define bUIE_BUS_RST 0x01 // enable interrupt for USB bus reset event
SFR(USB_CTRL, 0xE2); // USB base control
#define bUC_LOW_SPEED 0x40 // enable USB low speed: 0=full speed, 1=low speed
#define bUC_DEV_PU_EN 0x20 // USB device enable and internal pullup resistance enable
#define bUC_SYS_CTRL1 0x20 // USB system control high bit
#define bUC_SYS_CTRL0 0x10 // USB system control low bit
#define MASK_UC_SYS_CTRL 0x30 // bit mask of USB system control
// bUC_SYS_CTRL1 & bUC_SYS_CTRL0: USB system control
// 00: disable USB device and disable internal pullup resistance
// 01: enable USB device and disable internal pullup resistance, need external pullup resistance
// 1x: enable USB device and enable internal pullup resistance
#define bUC_INT_BUSY 0x08 // enable automatic responding busy during interrupt flag UIF_TRANSFER valid
#define bUC_RESET_SIE 0x04 // force reset USB SIE, need software clear
#define bUC_CLR_ALL 0x02 // force clear FIFO and count of USB
#define bUC_DMA_EN 0x01 // DMA enable and DMA interrupt enable for USB
SFR(USB_DEV_AD, 0xE3); // USB device address, lower 7 bits for USB device address
#define bUDA_GP_BIT 0x80 // general purpose bit
#define MASK_USB_ADDR 0x7F // bit mask for USB device address
SFR16(UEP2_DMA, 0xE4); // endpoint 2 buffer start address, little-endian
SFR(UEP2_DMA_L, 0xE4); // endpoint 2 buffer start address low byte
SFR(UEP2_DMA_H, 0xE5); // endpoint 2 buffer start address high byte
SFR16(UEP3_DMA, 0xE6); // endpoint 3 buffer start address, little-endian
SFR(UEP3_DMA_L, 0xE6); // endpoint 3 buffer start address low byte
SFR(UEP3_DMA_H, 0xE7); // endpoint 3 buffer start address high byte
SFR(UEP4_1_MOD, 0xEA); // endpoint 4/1 mode
#define bUEP1_RX_EN 0x80 // enable USB endpoint 1 receiving (OUT)
#define bUEP1_TX_EN 0x40 // enable USB endpoint 1 transmittal (IN)
#define bUEP1_BUF_MOD 0x10 // buffer mode of USB endpoint 1
// bUEPn_RX_EN & bUEPn_TX_EN & bUEPn_BUF_MOD: USB endpoint 1/2/3 buffer mode, buffer start address is UEPn_DMA
// 0 0 x: disable endpoint and disable buffer
// 1 0 0: 64 bytes buffer for receiving (OUT endpoint)
// 1 0 1: dual 64 bytes buffer by toggle bit bUEP_R_TOG selection for receiving (OUT endpoint), total=128bytes
// 0 1 0: 64 bytes buffer for transmittal (IN endpoint)
// 0 1 1: dual 64 bytes buffer by toggle bit bUEP_T_TOG selection for transmittal (IN endpoint), total=128bytes
// 1 1 0: 64 bytes buffer for receiving (OUT endpoint) + 64 bytes buffer for transmittal (IN endpoint), total=128bytes
// 1 1 1: dual 64 bytes buffer by bUEP_R_TOG selection for receiving (OUT endpoint) + dual 64 bytes buffer by bUEP_T_TOG selection for transmittal (IN endpoint), total=256bytes
#define bUEP4_RX_EN 0x08 // enable USB endpoint 4 receiving (OUT)
#define bUEP4_TX_EN 0x04 // enable USB endpoint 4 transmittal (IN)
// bUEP4_RX_EN & bUEP4_TX_EN: USB endpoint 4 buffer mode, buffer start address is UEP0_DMA
// 0 0: single 64 bytes buffer for endpoint 0 receiving & transmittal (OUT & IN endpoint)
// 1 0: single 64 bytes buffer for endpoint 0 receiving & transmittal (OUT & IN endpoint) + 64 bytes buffer for endpoint 4 receiving (OUT endpoint), total=128bytes
// 0 1: single 64 bytes buffer for endpoint 0 receiving & transmittal (OUT & IN endpoint) + 64 bytes buffer for endpoint 4 transmittal (IN endpoint), total=128bytes
// 1 1: single 64 bytes buffer for endpoint 0 receiving & transmittal (OUT & IN endpoint)
// + 64 bytes buffer for endpoint 4 receiving (OUT endpoint) + 64 bytes buffer for endpoint 4 transmittal (IN endpoint), total=192bytes
SFR(UEP2_3_MOD, 0xEB); // endpoint 2/3 mode
#define bUEP3_RX_EN 0x80 // enable USB endpoint 3 receiving (OUT)
#define bUEP3_TX_EN 0x40 // enable USB endpoint 3 transmittal (IN)
#define bUEP3_BUF_MOD 0x10 // buffer mode of USB endpoint 3
#define bUEP2_RX_EN 0x08 // enable USB endpoint 2 receiving (OUT)
#define bUEP2_TX_EN 0x04 // enable USB endpoint 2 transmittal (IN)
#define bUEP2_BUF_MOD 0x01 // buffer mode of USB endpoint 2
SFR16(UEP0_DMA, 0xEC); // endpoint 0 buffer start address, little-endian
SFR(UEP0_DMA_L, 0xEC); // endpoint 0 buffer start address low byte
SFR(UEP0_DMA_H, 0xED); // endpoint 0 buffer start address high byte
SFR16(UEP1_DMA, 0xEE); // endpoint 1 buffer start address, little-endian
SFR(UEP1_DMA_L, 0xEE); // endpoint 1 buffer start address low byte
SFR(UEP1_DMA_H, 0xEF); // endpoint 1 buffer start address high byte
/*----- XDATA: xRAM ------------------------------------------*/
#define XDATA_RAM_SIZE 0x0400 // size of expanded xRAM, xdata SRAM embedded chip
/*----- Reference Information --------------------------------------------*/
#define ID_CH552 0x52 // chip ID
#define ID_CH551 0x51 // chip ID
/* Interrupt routine address and interrupt number */
#define INT_ADDR_INT0 0x0003 // interrupt vector address for INT0
#define INT_ADDR_TMR0 0x000B // interrupt vector address for timer0
#define INT_ADDR_INT1 0x0013 // interrupt vector address for INT1
#define INT_ADDR_TMR1 0x001B // interrupt vector address for timer1
#define INT_ADDR_UART0 0x0023 // interrupt vector address for UART0
#define INT_ADDR_TMR2 0x002B // interrupt vector address for timer2
#define INT_ADDR_SPI0 0x0033 // interrupt vector address for SPI0
#define INT_ADDR_TKEY 0x003B // interrupt vector address for touch-key timer
#define INT_ADDR_USB 0x0043 // interrupt vector address for USB
#define INT_ADDR_ADC 0x004B // interrupt vector address for ADC
#define INT_ADDR_UART1 0x0053 // interrupt vector address for UART1
#define INT_ADDR_PWMX 0x005B // interrupt vector address for PWM1/2
#define INT_ADDR_GPIO 0x0063 // interrupt vector address for GPIO
#define INT_ADDR_WDOG 0x006B // interrupt vector address for watch-dog timer
#define INT_NO_INT0 0 // interrupt number for INT0
#define INT_NO_TMR0 1 // interrupt number for timer0
#define INT_NO_INT1 2 // interrupt number for INT1
#define INT_NO_TMR1 3 // interrupt number for timer1
#define INT_NO_UART0 4 // interrupt number for UART0
#define INT_NO_TMR2 5 // interrupt number for timer2
#define INT_NO_SPI0 6 // interrupt number for SPI0
#define INT_NO_TKEY 7 // interrupt number for touch-key timer
#define INT_NO_USB 8 // interrupt number for USB
#define INT_NO_ADC 9 // interrupt number for ADC
#define INT_NO_UART1 10 // interrupt number for UART1
#define INT_NO_PWMX 11 // interrupt number for PWM1/2
#define INT_NO_GPIO 12 // interrupt number for GPIO
#define INT_NO_WDOG 13 // interrupt number for watch-dog timer
/* Special Program Space */
#define DATA_FLASH_ADDR 0xC000 // start address of Data-Flash
#define BOOT_LOAD_ADDR 0x3800 // start address of boot loader program
#define ROM_CFG_ADDR 0x3FF8 // chip configuration information address
#define ROM_CHIP_ID_HX 0x3FFA // chip ID number highest byte (only low byte valid)
#define ROM_CHIP_ID_LO 0x3FFC // chip ID number low word
#define ROM_CHIP_ID_HI 0x3FFE // chip ID number high word
/*
New Instruction: MOVX @DPTR1,A
Instruction Code: 0xA5
Instruction Cycle: 1
Instruction Operation:
step-1. write ACC @DPTR1 into xdata SRAM embedded chip
step-2. increase DPTR1
ASM example:
INC XBUS_AUX
MOV DPTR,#TARGET_ADDR ;DPTR1
DEC XBUS_AUX
MOV DPTR,#SOURCE_ADDR ;DPTR0
MOV R7,#xxH
LOOP: MOVX A,@DPTR ;DPTR0
INC DPTR ;DPTR0, if need
DB 0A5H ;MOVX @DPTR1,A & INC DPTR1
DJNZ R7,LOOP
*/
void init_clock(void);
#ifdef __cplusplus
}
#endif
#endif // __CH552_H__

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/*--------------------------------------------------------------------------
ch552_usb.h
USB header file for CH552 microcontrollers.
****************************************
** Copyright (C) W.ch 1999-2016 **
** Web: http://wch.cn **
** Adapted by Iscle **
****************************************
--------------------------------------------------------------------------*/
#ifndef __CH552_USB_H__
#define __CH552_USB_H__
#ifdef __cplusplus
extern "C" {
#endif
#include <stdint.h>
/*----- USB constant and structure define --------------------------------*/
/* USB PID */
#ifndef USB_PID_SETUP
#define USB_PID_NULL 0x00 /* reserved PID */
#define USB_PID_SOF 0x05
#define USB_PID_SETUP 0x0D
#define USB_PID_IN 0x09
#define USB_PID_OUT 0x01
#define USB_PID_ACK 0x02
#define USB_PID_NAK 0x0A
#define USB_PID_STALL 0x0E
#define USB_PID_DATA0 0x03
#define USB_PID_DATA1 0x0B
#define USB_PID_PRE 0x0C
#endif
/* USB standard device request code */
#ifndef USB_GET_DESCRIPTOR
#define USB_GET_STATUS 0x00
#define USB_CLEAR_FEATURE 0x01
#define USB_SET_FEATURE 0x03
#define USB_SET_ADDRESS 0x05
#define USB_GET_DESCRIPTOR 0x06
#define USB_SET_DESCRIPTOR 0x07
#define USB_GET_CONFIGURATION 0x08
#define USB_SET_CONFIGURATION 0x09
#define USB_GET_INTERFACE 0x0A
#define USB_SET_INTERFACE 0x0B
#define USB_SYNCH_FRAME 0x0C
#endif
/* USB hub class request code */
#ifndef HUB_GET_DESCRIPTOR
#define HUB_GET_STATUS 0x00
#define HUB_CLEAR_FEATURE 0x01
#define HUB_GET_STATE 0x02
#define HUB_SET_FEATURE 0x03
#define HUB_GET_DESCRIPTOR 0x06
#define HUB_SET_DESCRIPTOR 0x07
#endif
/* USB HID class request code */
#ifndef HID_GET_REPORT
#define HID_GET_REPORT 0x01
#define HID_GET_IDLE 0x02
#define HID_GET_PROTOCOL 0x03
#define HID_SET_REPORT 0x09
#define HID_SET_IDLE 0x0A
#define HID_SET_PROTOCOL 0x0B
#endif
/* Bit define for USB request type */
#ifndef USB_REQ_TYP_MASK
#define USB_REQ_TYP_IN 0x80 /* control IN, device to host */
#define USB_REQ_TYP_OUT 0x00 /* control OUT, host to device */
#define USB_REQ_TYP_READ 0x80 /* control read, device to host */
#define USB_REQ_TYP_WRITE 0x00 /* control write, host to device */
#define USB_REQ_TYP_MASK 0x60 /* bit mask of request type */
#define USB_REQ_TYP_STANDARD 0x00
#define USB_REQ_TYP_CLASS 0x20
#define USB_REQ_TYP_VENDOR 0x40
#define USB_REQ_TYP_RESERVED 0x60
#define USB_REQ_RECIP_MASK 0x1F /* bit mask of request recipient */
#define USB_REQ_RECIP_DEVICE 0x00
#define USB_REQ_RECIP_INTERF 0x01
#define USB_REQ_RECIP_ENDP 0x02
#define USB_REQ_RECIP_OTHER 0x03
#endif
/* USB request type for hub class request */
#ifndef HUB_GET_HUB_DESCRIPTOR
#define HUB_CLEAR_HUB_FEATURE 0x20
#define HUB_CLEAR_PORT_FEATURE 0x23
#define HUB_GET_BUS_STATE 0xA3
#define HUB_GET_HUB_DESCRIPTOR 0xA0
#define HUB_GET_HUB_STATUS 0xA0
#define HUB_GET_PORT_STATUS 0xA3
#define HUB_SET_HUB_DESCRIPTOR 0x20
#define HUB_SET_HUB_FEATURE 0x20
#define HUB_SET_PORT_FEATURE 0x23
#endif
/* Hub class feature selectors */
#ifndef HUB_PORT_RESET
#define HUB_C_HUB_LOCAL_POWER 0
#define HUB_C_HUB_OVER_CURRENT 1
#define HUB_PORT_CONNECTION 0
#define HUB_PORT_ENABLE 1
#define HUB_PORT_SUSPEND 2
#define HUB_PORT_OVER_CURRENT 3
#define HUB_PORT_RESET 4
#define HUB_PORT_POWER 8
#define HUB_PORT_LOW_SPEED 9
#define HUB_C_PORT_CONNECTION 16
#define HUB_C_PORT_ENABLE 17
#define HUB_C_PORT_SUSPEND 18
#define HUB_C_PORT_OVER_CURRENT 19
#define HUB_C_PORT_RESET 20
#endif
/* USB descriptor type */
#ifndef USB_DESCR_TYP_DEVICE
#define USB_DESCR_TYP_DEVICE 0x01
#define USB_DESCR_TYP_CONFIG 0x02
#define USB_DESCR_TYP_STRING 0x03
#define USB_DESCR_TYP_INTERF 0x04
#define USB_DESCR_TYP_ENDP 0x05
#define USB_DESCR_TYP_QUALIF 0x06
#define USB_DESCR_TYP_SPEED 0x07
#define USB_DESCR_TYP_OTG 0x09
#define USB_DESCR_TYP_HID 0x21
#define USB_DESCR_TYP_REPORT 0x22
#define USB_DESCR_TYP_PHYSIC 0x23
#define USB_DESCR_TYP_CS_INTF 0x24
#define USB_DESCR_TYP_CS_ENDP 0x25
#define USB_DESCR_TYP_HUB 0x29
#endif
/* USB device class */
#ifndef USB_DEV_CLASS_HUB
#define USB_DEV_CLASS_RESERVED 0x00
#define USB_DEV_CLASS_AUDIO 0x01
#define USB_DEV_CLASS_COMMUNIC 0x02
#define USB_DEV_CLASS_HID 0x03
#define USB_DEV_CLASS_MONITOR 0x04
#define USB_DEV_CLASS_PHYSIC_IF 0x05
#define USB_DEV_CLASS_POWER 0x06
#define USB_DEV_CLASS_PRINTER 0x07
#define USB_DEV_CLASS_STORAGE 0x08
#define USB_DEV_CLASS_HUB 0x09
#define USB_DEV_CLASS_VEN_SPEC 0xFF
#endif
/* USB endpoint type and attributes */
#ifndef USB_ENDP_TYPE_MASK
#define USB_ENDP_DIR_MASK 0x80
#define USB_ENDP_ADDR_MASK 0x0F
#define USB_ENDP_TYPE_MASK 0x03
#define USB_ENDP_TYPE_CTRL 0x00
#define USB_ENDP_TYPE_ISOCH 0x01
#define USB_ENDP_TYPE_BULK 0x02
#define USB_ENDP_TYPE_INTER 0x03
#endif
#ifndef USB_DEVICE_ADDR
#define USB_DEVICE_ADDR 0x02 /* default USB device address */
#endif
#ifndef DEFAULT_ENDP0_SIZE
#define DEFAULT_ENDP0_SIZE 8 /* default maximum packet size for endpoint 0 */
#endif
#ifndef MAX_PACKET_SIZE
#define MAX_PACKET_SIZE 64 /* maximum packet size */
#endif
#ifndef USB_BO_CBW_SIZE
#define USB_BO_CBW_SIZE 0x1F /* total length of CBW command block */
#define USB_BO_CSW_SIZE 0x0D /* total length of CSW status block*/
#endif
#ifndef USB_BO_CBW_SIG0
#define USB_BO_CBW_SIG0 0x55 /* command block CBW 'USBC' identification flag */
#define USB_BO_CBW_SIG1 0x53
#define USB_BO_CBW_SIG2 0x42
#define USB_BO_CBW_SIG3 0x43
#define USB_BO_CSW_SIG0 0x55 /* command status CSW 'USBS' identification flag*/
#define USB_BO_CSW_SIG1 0x53
#define USB_BO_CSW_SIG2 0x42
#define USB_BO_CSW_SIG3 0x53
#endif
typedef struct _USB_SETUP_REQ {
uint8_t bRequestType;
uint8_t bRequest;
uint8_t wValueL;
uint8_t wValueH;
uint8_t wIndexL;
uint8_t wIndexH;
uint8_t wLengthL;
uint8_t wLengthH;
} USB_SETUP_REQ, *PUSB_SETUP_REQ;
typedef USB_SETUP_REQ xdata *PXUSB_SETUP_REQ;
typedef struct _USB_DEVICE_DESCR {
uint8_t bLength;
uint8_t bDescriptorType;
uint8_t bcdUSBL;
uint8_t bcdUSBH;
uint8_t bDeviceClass;
uint8_t bDeviceSubClass;
uint8_t bDeviceProtocol;
uint8_t bMaxPacketSize0;
uint8_t idVendorL;
uint8_t idVendorH;
uint8_t idProductL;
uint8_t idProductH;
uint8_t bcdDeviceL;
uint8_t bcdDeviceH;
uint8_t iManufacturer;
uint8_t iProduct;
uint8_t iSerialNumber;
uint8_t bNumConfigurations;
} USB_DEV_DESCR, *PUSB_DEV_DESCR;
typedef USB_DEV_DESCR xdata *PXUSB_DEV_DESCR;
typedef struct _USB_CONFIG_DESCR {
uint8_t bLength;
uint8_t bDescriptorType;
uint8_t wTotalLengthL;
uint8_t wTotalLengthH;
uint8_t bNumInterfaces;
uint8_t bConfigurationValue;
uint8_t iConfiguration;
uint8_t bmAttributes;
uint8_t MaxPower;
} USB_CFG_DESCR, *PUSB_CFG_DESCR;
typedef USB_CFG_DESCR xdata *PXUSB_CFG_DESCR;
typedef struct _USB_INTERF_DESCR {
uint8_t bLength;
uint8_t bDescriptorType;
uint8_t bInterfaceNumber;
uint8_t bAlternateSetting;
uint8_t bNumEndpoints;
uint8_t bInterfaceClass;
uint8_t bInterfaceSubClass;
uint8_t bInterfaceProtocol;
uint8_t iInterface;
} USB_ITF_DESCR, *PUSB_ITF_DESCR;
typedef USB_ITF_DESCR xdata *PXUSB_ITF_DESCR;
typedef struct _USB_ENDPOINT_DESCR {
uint8_t bLength;
uint8_t bDescriptorType;
uint8_t bEndpointAddress;
uint8_t bmAttributes;
uint8_t wMaxPacketSizeL;
uint8_t wMaxPacketSizeH;
uint8_t bInterval;
} USB_ENDP_DESCR, *PUSB_ENDP_DESCR;
typedef USB_ENDP_DESCR xdata *PXUSB_ENDP_DESCR;
typedef struct _USB_CONFIG_DESCR_LONG {
USB_CFG_DESCR cfg_descr;
USB_ITF_DESCR itf_descr;
USB_ENDP_DESCR endp_descr[1];
} USB_CFG_DESCR_LONG, *PUSB_CFG_DESCR_LONG;
typedef USB_CFG_DESCR_LONG xdata *PXUSB_CFG_DESCR_LONG;
typedef struct _USB_HUB_DESCR {
uint8_t bDescLength;
uint8_t bDescriptorType;
uint8_t bNbrPorts;
uint8_t wHubCharacteristicsL;
uint8_t wHubCharacteristicsH;
uint8_t bPwrOn2PwrGood;
uint8_t bHubContrCurrent;
uint8_t DeviceRemovable;
uint8_t PortPwrCtrlMask;
} USB_HUB_DESCR, *PUSB_HUB_DESCR;
typedef USB_HUB_DESCR xdata *PXUSB_HUB_DESCR;
typedef struct _USB_HID_DESCR {
uint8_t bLength;
uint8_t bDescriptorType;
uint8_t bcdHIDL;
uint8_t bcdHIDH;
uint8_t bCountryCode;
uint8_t bNumDescriptors;
uint8_t bDescriptorTypeX;
uint8_t wDescriptorLengthL;
uint8_t wDescriptorLengthH;
} USB_HID_DESCR, *PUSB_HID_DESCR;
typedef USB_HID_DESCR xdata *PXUSB_HID_DESCR;
typedef struct _UDISK_BOC_CBW { /* command of BulkOnly USB-FlashDisk */
uint8_t mCBW_Sig0;
uint8_t mCBW_Sig1;
uint8_t mCBW_Sig2;
uint8_t mCBW_Sig3;
uint8_t mCBW_Tag0;
uint8_t mCBW_Tag1;
uint8_t mCBW_Tag2;
uint8_t mCBW_Tag3;
uint8_t mCBW_DataLen0;
uint8_t mCBW_DataLen1;
uint8_t mCBW_DataLen2;
uint8_t mCBW_DataLen3; /* uppest byte of data length, always is 0 */
uint8_t mCBW_Flag; /* transfer direction and etc. */
uint8_t mCBW_LUN;
uint8_t mCBW_CB_Len; /* length of command block */
uint8_t mCBW_CB_Buf[16]; /* command block buffer */
} UDISK_BOC_CBW, *PUDISK_BOC_CBW;
typedef UDISK_BOC_CBW xdata *PXUDISK_BOC_CBW;
typedef struct _UDISK_BOC_CSW { /* status of BulkOnly USB-FlashDisk */
uint8_t mCSW_Sig0;
uint8_t mCSW_Sig1;
uint8_t mCSW_Sig2;
uint8_t mCSW_Sig3;
uint8_t mCSW_Tag0;
uint8_t mCSW_Tag1;
uint8_t mCSW_Tag2;
uint8_t mCSW_Tag3;
uint8_t mCSW_Residue0; /* return: remainder bytes */
uint8_t mCSW_Residue1;
uint8_t mCSW_Residue2;
uint8_t mCSW_Residue3; /* uppest byte of remainder length, always is 0 */
uint8_t mCSW_Status; /* return: result status */
} UDISK_BOC_CSW, *PUDISK_BOC_CSW;
typedef UDISK_BOC_CSW xdata *PXUDISK_BOC_CSW;
#ifdef __cplusplus
}
#endif
#endif // __USB_DEF__

11
src/template/src/main.c Normal file
View File

@ -0,0 +1,11 @@
#include "ch552.h"
void main(void) {
// Prepare the hardware here
init_clock();
while (1) {
// Do stuff here
}
}

7
tools/ch55xtool.py
View File

@ -1,3 +1,6 @@
#!/usr/bin/env python3
# -*- coding: utf-8 -*-
import sys, os
import time
import array
@ -286,7 +289,7 @@ def __main():
if args.file != '':
payload = list(open(args.file, 'rb').read())
if ret[0] == 'V2.30':
if ret[0] in ['V2.30']:
ret = __write_key_ch55x_v20(dev, chk_sum)
if ret is None:
sys.exit('Failed to write key to CH55x.')
@ -303,7 +306,7 @@ def __main():
if ret is None:
sys.exit('Failed to verify firmware of CH55x.')
else:
if ret[0] == 'V2.31':
if ret[0] in ['V2.31', 'V2.40']:
ret = __write_key_ch55x_v23(dev)
if ret is None:
sys.exit('Failed to write key to CH55x.')