#include <platform_opts.h>
#ifdef CONFIG_AT_SYS
#include "platform_stdlib.h"
//#include "platform_autoconf.h"
//#include "main.h"
#include "autoconf.h"
#include "hal_adc.h"
#include "gpio_api.h" // mbed
#include "sys_api.h"
#include "rtl8195a.h"
#include "flash_api.h"
#include "rtl_lib.h"
#include "build_info.h"
#include "analogin_api.h"
#include "log_service.h"
#include "atcmd_sys.h"
#include "osdep_api.h"
#include "atcmd_wifi.h"
#include "tcm_heap.h"
#if CONFIG_OTA_UPDATE
#include "update.h"
#endif
#ifndef ATCMD_VER
#define ATVER_1 1
#define ATVER_2 2
#define ATCMD_VER ATVER_2
#if CONFIG_EXAMPLE_UART_ATCMD
#define ATCMD_VER ATVER_2
#else
#define ATCMD_VER ATVER_1
#endif
#endif
#if defined(configUSE_WAKELOCK_PMU) && (configUSE_WAKELOCK_PMU == 1)
#include "freertos_pmu.h"
#endif
extern u32 ConfigDebugErr;
extern u32 ConfigDebugInfo;
extern u32 ConfigDebugWarn;
extern u32 CmdDumpWord(IN u16 argc, IN u8 *argv[]);
extern u32 CmdWriteWord(IN u16 argc, IN u8 *argv[]);
#if CONFIG_UART_XMODEM
extern void OTU_FW_Update(u8, u8, u32);
#endif
struct _dev_id2name {
u8 id;
u8 *name;
};
struct _dev_id2name dev_id2name[] = { { UART0, "UART0" }, { UART1, "UART1" }, {
UART2, "UART2" }, { SPI0, "SPI0" }, { SPI1, "SPI1" }, { SPI2, "SPI2" }, {
SPI0_MCS, "SPI0_MCS" }, { I2C0, "I2C0" }, { I2C1, "I2C1" }, { I2C2, "I2C2" }, {
I2C3, "I2C3" }, { I2S0, "I2S0" }, { I2S1, "I2S1" }, { PCM0, "PCM0" }, {
PCM1, "PCM1" }, { ADC0, "ADC0" }, { DAC0, "DAC0" }, { DAC1, "DAC1" }, {
SDIOD, "SDIOD" }, { SDIOH, "SDIOH" }, { USBOTG, "USBOTG" }, { MII, "MII" }, {
WL_LED, "WL_LED" }, { WL_ANT0, "WL_ANT0" }, { WL_ANT1, "WL_ANT1" }, {
WL_BTCOEX, "WL_BTCOEX" }, { WL_BTCMD, "WL_BTCMD" }, { NFC, "NFC" }, {
PWM0, "PWM0" }, { PWM1, "PWM1" }, { PWM2, "PWM2" }, { PWM3, "PWM3" }, {
ETE0, "ETE0" }, { ETE1, "ETE1" }, { ETE2, "ETE2" }, { ETE3, "ETE3" }, {
EGTIM, "EGTIM" }, { SPI_FLASH, "SPI_FLASH" }, { SDR, "SDR" }, { JTAG, "JTAG" },
{ TRACE, "TRACE" }, { LOG_UART, "LOG_UART" }, {
LOG_UART_IR, "LOG_UART_IR" }, { SIC, "SIC" }, { EEPROM, "EEPROM" }, {
DEBUG, "DEBUG" }, { 255, "" } };
void fATSI(void *arg) {
uint32 x = 0;
int i;
u8 * s;
for (i = 0; dev_id2name[i].id != 255; i++) {
ReadHWPwrState(dev_id2name[i].id, &x);
s = "?";
switch (x) {
case HWACT:
s = "ACT";
break;
case HWCG:
s = "CG";
break;
case HWINACT:
s = "WACT";
break;
case UNDEF:
s = "UNDEF";
break;
case ALLMET:
s = "ALLMET";
break;
}
printf("Dev %s, state = %s\n", dev_id2name[i].name, s);
}
for (i = 0; i < _PORT_MAX; i++)
printf("Port %c state: 0x%04x\n", i + 'A', GPIOState[i]);
}
//-------- AT SYS commands ---------------------------------------------------------------
void fATSD(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS,
"[ATSD]: _AT_SYSTEM_DUMP_REGISTER_");
if (!arg) {
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSD] Usage: ATSD=REGISTER");
return;
}
argc = parse_param(arg, argv);
if (argc == 2 || argc == 3)
CmdDumpWord(argc - 1, (unsigned char**) (argv + 1));
}
#if ATCMD_VER == ATVER_2
void fATXD(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
AT_DBG_MSG(AT_FLAG_EDIT, AT_DBG_ALWAYS,
"[ATXD]: _AT_SYSTEM_WRITE_REGISTER_");
if (!arg) {
AT_DBG_MSG(AT_FLAG_EDIT, AT_DBG_ALWAYS,
"[ATXD] Usage: ATXD=REGISTER,VALUE");
return;
}
argc = parse_param(arg, argv);
if (argc == 3)
CmdWriteWord(argc - 1, (unsigned char**) (argv + 1));
}
#endif
#if ATCMD_VER == ATVER_1
void fATSC(void *arg)
{
AT_DBG_MSG(AT_FLAG_OTA, AT_DBG_ALWAYS, "[ATSC]: _AT_SYSTEM_CLEAR_OTA_SIGNATURE_");
sys_clear_ota_signature();
}
void fATSR(void *arg)
{
AT_DBG_MSG(AT_FLAG_OTA, AT_DBG_ALWAYS, "[ATSR]: _AT_SYSTEM_RECOVER_OTA_SIGNATURE_");
sys_recover_ota_signature();
}
#if CONFIG_UART_XMODEM
void fATSY(void *arg)
{
if (HalGetChipId() < CHIP_ID_8195AM) {
OTU_FW_Update(0, 0, 115200);
} else {
// use xmodem to update, RX: PA_6, TX: PA_7, baudrate: 1M
OTU_FW_Update(0, 2, 115200);
}
}
#endif
#if SUPPORT_MP_MODE
void fATSA(void *arg)
{
u32 tConfigDebugInfo = ConfigDebugInfo;
int argc = 0, channel;
char *argv[MAX_ARGC] = {0}, *ptmp;
u16 offset, gain;
AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA]: _AT_SYSTEM_ADC_TEST_");
if(!arg) {
AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA] Usage: ATSA=CHANNEL(0~2)");
AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA] Usage: ATSA=k_get");
AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA] Usage: ATSA=k_set[offet(hex),gain(hex)]");
return;
}
argc = parse_param(arg, argv);
if(strcmp(argv[1], "k_get") == 0) {
sys_adc_calibration(0, &offset, &gain);
// AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA] offset = 0x%04X, gain = 0x%04X", offset, gain);
} else if(strcmp(argv[1], "k_set") == 0) {
if(argc != 4) {
AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA] Usage: ATSA=k_set[offet(hex),gain(hex)]");
return;
}
offset = strtoul(argv[2], &ptmp, 16);
gain = strtoul(argv[3], &ptmp, 16);
sys_adc_calibration(1, &offset, &gain);
// AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA] offset = 0x%04X, gain = 0x%04X", offset, gain);
} else {
channel = atoi(argv[1]);
if(channel < 0 || channel > 2) {
AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA] Usage: ATSA=CHANNEL(0~2)");
return;
}
analogin_t adc;
u16 adcdat;
// Remove debug info massage
ConfigDebugInfo = 0;
if(channel == 0)
analogin_init(&adc, AD_1);
else if(channel == 1)
analogin_init(&adc, AD_2);
else
analogin_init(&adc, AD_3);
adcdat = analogin_read_u16(&adc)>>4;
analogin_deinit(&adc);
// Recover debug info massage
ConfigDebugInfo = tConfigDebugInfo;
AT_DBG_MSG(AT_FLAG_ADC, AT_DBG_ALWAYS, "[ATSA] A%d = 0x%04X", channel, adcdat);
}
}
void fATSG(void *arg)
{
gpio_t gpio_test;
int argc = 0, val;
char *argv[MAX_ARGC] = {0}, port, num;
PinName pin = NC;
u32 tConfigDebugInfo = ConfigDebugInfo;
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSG]: _AT_SYSTEM_GPIO_TEST_");
if(!arg) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSG] Usage: ATSG=PINNAME(ex:A0)");
return;
} else {
argc = parse_param(arg, argv);
if(argc != 2) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSG] Usage: ATSG=PINNAME(ex:A0)");
return;
}
}
port = argv[1][0];
num = argv[1][1];
if(port >= 'a' && port <= 'z')
port -= ('a' - 'A');
if(num >= 'a' && num <= 'z')
num -= ('a' - 'A');
switch(port) {
case 'A':
switch(num) {
case '0': pin = PA_0; break; case '1': pin = PA_1; break; case '2': pin = PA_2; break; case '3': pin = PA_3; break;
case '4': pin = PA_4; break; case '5': pin = PA_5; break; case '6': pin = PA_6; break; case '7': pin = PA_7; break;
}
break;
case 'B':
switch(num) {
case '0': pin = PB_0; break; case '1': pin = PB_1; break; case '2': pin = PB_2; break; case '3': pin = PB_3; break;
case '4': pin = PB_4; break; case '5': pin = PB_5; break; case '6': pin = PB_6; break; case '7': pin = PB_7; break;
}
break;
case 'C':
switch(num) {
case '0': pin = PC_0; break; case '1': pin = PC_1; break; case '2': pin = PC_2; break; case '3': pin = PC_3; break;
case '4': pin = PC_4; break; case '5': pin = PC_5; break; case '6': pin = PC_6; break; case '7': pin = PC_7; break;
case '8': pin = PC_8; break; case '9': pin = PC_9; break;
}
break;
case 'D':
switch(num) {
case '0': pin = PD_0; break; case '1': pin = PD_1; break; case '2': pin = PD_2; break; case '3': pin = PD_3; break;
case '4': pin = PD_4; break; case '5': pin = PD_5; break; case '6': pin = PD_6; break; case '7': pin = PD_7; break;
case '8': pin = PD_8; break; case '9': pin = PD_9; break;
}
break;
case 'E':
switch(num) {
case '0': pin = PE_0; break; case '1': pin = PE_1; break; case '2': pin = PE_2; break; case '3': pin = PE_3; break;
case '4': pin = PE_4; break; case '5': pin = PE_5; break; case '6': pin = PE_6; break; case '7': pin = PE_7; break;
case '8': pin = PE_8; break; case '9': pin = PE_9; break; case 'A': pin = PE_A; break;
}
break;
case 'F':
switch(num) {
case '0': pin = PF_0; break; case '1': pin = PF_1; break; case '2': pin = PF_2; break; case '3': pin = PF_3; break;
case '4': pin = PF_4; break; case '5': pin = PF_5; break;
}
break;
case 'G':
switch(num) {
case '0': pin = PG_0; break; case '1': pin = PG_1; break; case '2': pin = PG_2; break; case '3': pin = PG_3; break;
case '4': pin = PG_4; break; case '5': pin = PG_5; break; case '6': pin = PG_6; break; case '7': pin = PG_7; break;
}
break;
case 'H':
switch(num) {
case '0': pin = PH_0; break; case '1': pin = PH_1; break; case '2': pin = PH_2; break; case '3': pin = PH_3; break;
case '4': pin = PH_4; break; case '5': pin = PH_5; break; case '6': pin = PH_6; break; case '7': pin = PH_7; break;
}
break;
case 'I':
switch(num) {
case '0': pin = PI_0; break; case '1': pin = PI_1; break; case '2': pin = PI_2; break; case '3': pin = PI_3; break;
case '4': pin = PI_4; break; case '5': pin = PI_5; break; case '6': pin = PI_6; break; case '7': pin = PI_7; break;
}
break;
case 'J':
switch(num) {
case '0': pin = PJ_0; break; case '1': pin = PJ_1; break; case '2': pin = PJ_2; break; case '3': pin = PJ_3; break;
case '4': pin = PJ_4; break; case '5': pin = PJ_5; break; case '6': pin = PJ_6; break;
}
break;
case 'K':
switch(num) {
case '0': pin = PK_0; break; case '1': pin = PK_1; break; case '2': pin = PK_2; break; case '3': pin = PK_3; break;
case '4': pin = PK_4; break; case '5': pin = PK_5; break; case '6': pin = PK_6; break;
}
break;
}
if(pin == NC) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSG]: Invalid Pin Name");
return;
}
// Remove debug info massage
ConfigDebugInfo = 0;
// Initial input control pin
gpio_init(&gpio_test, pin);
gpio_dir(&gpio_test, PIN_INPUT);// Direction: Input
gpio_mode(&gpio_test, PullUp);// Pull-High
val = gpio_read(&gpio_test);
// Recover debug info massage
ConfigDebugInfo = tConfigDebugInfo;
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSG] %c%c = %d", port, num, val);
}
void fATSP(void *arg)
{
int argc = 0;
char *argv[MAX_ARGC] = {0};
unsigned long timeout; // ms
unsigned long time_begin, time_current;
gpio_t gpiob_1;
int val_old, val_new;
int expected_zerocount, zerocount;
int test_result;
// parameter check
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSP]: _AT_SYSTEM_POWER_PIN_TEST_");
if(!arg) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSP]: Usage: ATSP=gpiob1[timeout,zerocount]");
} else {
argc = parse_param(arg, argv);
if (argc < 2) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSP]: Usage: ATSP=gpiob1[timeout,zerocount]");
return;
}
}
if ( strcmp(argv[1], "gpiob1" ) == 0 ) {
if (argc < 4) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSP]: Usage: ATSP=gpiob1[timeout,zerocount]");
return;
}
// init gpiob1 test
test_result = 0;
timeout = strtoul(argv[2], NULL, 10);
expected_zerocount = atoi(argv[3]);
zerocount = 0;
val_old = 1;
sys_log_uart_off();
gpio_init(&gpiob_1, PB_1);
gpio_dir(&gpiob_1, PIN_INPUT);
gpio_mode(&gpiob_1, PullDown);
// gpiob1 test ++
time_begin = time_current = xTaskGetTickCount();
while (time_current < time_begin + timeout) {
val_new = gpio_read(&gpiob_1);
if (val_new != val_old && val_new == 0) {
zerocount ++;
if (zerocount == expected_zerocount) {
test_result = 1;
break;
}
}
val_old = val_new;
time_current = xTaskGetTickCount();
}
// gpio test --
sys_log_uart_on();
if (test_result == 1) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSP]: success");
} else {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSP]: fail, it only got %d zeros", zerocount);
}
}
}
int write_otu_to_system_data(flash_t *flash, uint32_t otu_addr)
{
uint32_t data, i = 0;
flash_read_word(flash, FLASH_SYSTEM_DATA_ADDR+0xc, &data);
//printf("\n\r[%s] data 0x%x otu_addr 0x%x", __FUNCTION__, data, otu_addr);
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: data 0x%x otu_addr 0x%x", data, otu_addr);
if(data == ~0x0) {
flash_write_word(flash, FLASH_SYSTEM_DATA_ADDR+0xc, otu_addr);
} else {
//erase backup sector
flash_erase_sector(flash, FLASH_RESERVED_DATA_BASE);
//backup system data to backup sector
for(i = 0; i < 0x1000; i+= 4) {
flash_read_word(flash, FLASH_SYSTEM_DATA_ADDR + i, &data);
if(i == 0xc)
data = otu_addr;
flash_write_word(flash, FLASH_RESERVED_DATA_BASE + i,data);
}
//erase system data
flash_erase_sector(flash, FLASH_SYSTEM_DATA_ADDR);
//write data back to system data
for(i = 0; i < 0x1000; i+= 4) {
flash_read_word(flash, FLASH_RESERVED_DATA_BASE + i, &data);
flash_write_word(flash, FLASH_SYSTEM_DATA_ADDR + i,data);
}
//erase backup sector
flash_erase_sector(flash, FLASH_RESERVED_DATA_BASE);
}
return 0;
}
void fATSB(void *arg)
{
int argc = 0;
char *argv[MAX_ARGC] = {0};
u32 boot_gpio, rb_boot_gpio;
u8 gpio_pin;
u8 uart_port, uart_index;
u8 gpio_pin_bar;
u8 uart_port_bar;
flash_t flash;
// parameter check
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: _AT_SYSTEM_BOOT_OTU_PIN_SET_");
if(!arg) {
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: Usage: ATSB=[GPIO_PIN, TRIGER_MODE, UART]");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: GPIO_PIN: PB_1, PC_4 ....");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: TRIGER_MODE: low_trigger, high_trigger");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: UART: UART0, UART2");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: example: ATSB=[PC_2, low_trigger, UART2]");
} else {
argc = parse_param(arg, argv);
if (argc != 4 ) {
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: Usage: ATSB=[GPIO_PIN, TRIGER_MODE, UART]");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: GPIO_PIN: PB_1, PC_4 ....");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: TRIGER_MODE: low_trigger, high_trigger");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: UART: UART0, UART2");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: example: ATSB=[PC_2, low_trigger, UART2]");
return;
}
}
if ( strncmp(argv[1], "P", 1) == 0 && strlen(argv[1]) == 4
&& (strcmp(argv[2], "low_trigger") == 0 || strcmp(argv[2], "high_trigger") == 0)
&& strncmp(argv[3], "UART", 4) == 0 && strlen(argv[3]) == 5) {
if((0x41 <= argv[1][1] <= 0x45) && (0x30 <= argv[1][3] <= 0x39) &&(0x30 <= argv[1][4] <= 0x32)) {
if(strcmp(argv[2], "high_trigger") == 0)
gpio_pin = 1<< 7 | ((argv[1][1]-0x41)<<4) | (argv[1][3] - 0x30);
else
gpio_pin = ((argv[1][1]-0x41)<<4) | (argv[1][3] - 0x30);
gpio_pin_bar = ~gpio_pin;
uart_index = argv[3][4] - 0x30;
if(uart_index == 0)
uart_port = (uart_index<<4)|2;
else if(uart_index == 2)
uart_port = (uart_index<<4)|0;
else {
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: Input UART index error. Please choose UART0 or UART2.");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: example: ATSB=[PC_2, low_trigger, UART2]");
return;
}
uart_port_bar = ~uart_port;
boot_gpio = uart_port_bar<<24 | uart_port<<16 | gpio_pin_bar<<8 | gpio_pin;
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]:gpio_pin 0x%x", gpio_pin);
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]:gpio_pin_bar 0x%x", gpio_pin_bar);
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]:uart_port 0x%x", uart_port);
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]:uart_port_bar 0x%x", uart_port_bar);
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]:boot_gpio 0x%x", boot_gpio);
write_otu_to_system_data(&flash, boot_gpio);
flash_read_word(&flash, FLASH_SYSTEM_DATA_ADDR+0x0c, &rb_boot_gpio);
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]:Read 0x900c 0x%x", rb_boot_gpio);
} else {
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: Usage: ATSB=[GPIO_PIN, TRIGER_MODE, UART]");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: GPIO_PIN: PB_1, PC_4 ....");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: TRIGER_MODE: low_trigger, high_trigger");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: UART: UART0, UART2");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: example: ATSB=[PC_2, low_trigger, UART2]");
}
} else {
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: Usage: ATSB=[GPIO_PIN, TRIGER_MODE, UART]");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: GPIO_PIN: PB_1, PC_4 ....");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: TRIGER_MODE: low_trigger, high_trigger");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: UART: UART0, UART2");
AT_DBG_MSG(AT_FLAG_DUMP, AT_DBG_ALWAYS, "[ATSB]: example: ATSB=[PC_2, low_trigger, UART2]");
return;
}
}
#endif
#if (configGENERATE_RUN_TIME_STATS == 1)
void fATSS(void *arg) // Show CPU stats
{
AT_PRINTK("[ATSS]: _AT_SYSTEM_CPU_STATS_");
char *cBuffer = pvPortMalloc(512);
if(cBuffer != NULL) {
vTaskGetRunTimeStats((char *)cBuffer);
AT_PRINTK("%s", cBuffer);
}
vPortFree(cBuffer);
}
#endif
void fATSs(void *arg)
{
int argc = 0;
char *argv[MAX_ARGC] = {0};
AT_PRINTK("[ATS@]: _AT_SYSTEM_DBG_SETTING_");
if(!arg) {
AT_PRINTK("[ATS@] Usage: ATS@=[LEVLE,FLAG]");
} else {
argc = parse_param(arg, argv);
if(argc == 3) {
char *ptmp;
gDbgLevel = atoi(argv[1]);
gDbgFlag = strtoul(argv[2], &ptmp, 16);
}
}
AT_PRINTK("[ATS@] level = %d, flag = 0x%08X", gDbgLevel, gDbgFlag);
}
void fATSc(void *arg)
{
int argc = 0, config = 0;
char *argv[MAX_ARGC] = {0};
AT_PRINTK("[ATS!]: _AT_SYSTEM_CONFIG_SETTING_");
if(!arg) {
AT_PRINTK("[ATS!] Usage: ATS!=[CONFIG(0,1,2),FLAG]");
} else {
argc = parse_param(arg, argv);
if(argc == 3) {
char *ptmp;
config = atoi(argv[1]);
if(config == 0)
ConfigDebugErr = strtoul(argv[2], &ptmp, 16);
if(config == 1)
ConfigDebugInfo = strtoul(argv[2], &ptmp, 16);
if(config == 2)
ConfigDebugWarn = strtoul(argv[2], &ptmp, 16);
}
}
AT_PRINTK("[ATS!] ConfigDebugErr = 0x%08X", ConfigDebugErr);
AT_PRINTK("[ATS!] ConfigDebugInfo = 0x%08X", ConfigDebugInfo);
AT_PRINTK("[ATS!] ConfigDebugWarn = 0x%08X", ConfigDebugWarn);
}
#define SUPPORT_CP_TEST 0
#if SUPPORT_CP_TEST
extern void MFi_auth_test(void);
void fATSM(void *arg)
{
AT_PRINTK("[ATSM]: _AT_SYSTEM_CP_");
MFi_auth_test();
}
#endif
void fATSt(void *arg)
{
AT_PRINTK("[ATS#]: _AT_SYSTEM_TEST_");
DBG_8195A("\nCLK CPU\t\t%d Hz\nRAM heap\t%d bytes\nTCM heap\t%d bytes\n",
HalGetCpuClk(), xPortGetFreeHeapSize(), tcm_heap_freeSpace());
dump_mem_block_list();
tcm_heap_dump();
DBG_8195A("\n");
}
void fATSJ(void *arg)
{
int argc = 0, config = 0;
char *argv[MAX_ARGC] = {0};
AT_PRINTK("[ATSJ]: _AT_SYSTEM_JTAG_");
if(!arg) {
AT_PRINTK("[ATS!] Usage: ATSJ=off");
} else {
argc = parse_param(arg, argv);
if (strcmp(argv[1], "off" ) == 0)
sys_jtag_off();
else
AT_PRINTK("ATSL=%s is not supported!", argv[1]);
}
}
void fATSx(void *arg)
{
// uint32_t ability = 0;
char buf[64];
AT_PRINTK("[ATS?]: _AT_SYSTEM_HELP_");
AT_PRINTK("[ATS?]: COMPILE TIME: %s", RTL8195AFW_COMPILE_TIME);
// wifi_get_drv_ability(&ability);
strcpy(buf, "v");
// if(ability & 0x1)
// strcat(buf, "m");
strcat(buf, ".3.5." RTL8195AFW_COMPILE_DATE);
AT_PRINTK("[ATS?]: SW VERSION: %s", buf);
}
#elif ATCMD_VER == ATVER_2
#define ATCMD_VERSION "v2" //ATCMD MAJOR VERSION, AT FORMAT CHANGED
#define ATCMD_SUBVERSION "2" //ATCMD MINOR VERSION, NEW COMMAND ADDED
#define ATCMD_REVISION "2" //ATCMD FIX BUG REVISION
#define SDK_VERSION "v3.5" //SDK VERSION
extern void sys_reset(void);
void print_system_at(void *arg);
extern void print_wifi_at(void *arg);
extern void print_tcpip_at(void *arg);
// uart version 2 echo info
extern unsigned char gAT_Echo;
void fATS0(void *arg) {
at_printf("\r\n[AT] OK");
}
void fATSh(void *arg) {
// print common AT command
at_printf("\r\n[ATS?] ");
at_printf("\r\nCommon AT Command:");
print_system_at(arg);
#if CONFIG_WLAN
at_printf("\r\nWi-Fi AT Command:");
print_wifi_at(arg);
#endif
#if CONFIG_TRANSPORT
at_printf("\r\nTCP/IP AT Command:");
print_tcpip_at(arg);
#endif
at_printf("\r\n[ATS?] OK");
}
void fATSR(void *arg) {
at_printf("\r\n[ATSR] OK");
sys_reset();
}
void fATSV(void *arg) {
char at_buf[32];
char fw_buf[32];
char cspimode[4] = { 'S', 'D', 'Q', '?' };
if (fspic_isinit == 0) {
flash_turnon();
flash_init(&flashobj);
SpicDisableRtl8195A();
}
printf(
"DeviceID: %02X, Flash Size: %d bytes, FlashID: %02X%02X%02X/%d, SpicMode: %cIO\n",
HalGetChipId(), (u32) (1 << flashobj.SpicInitPara.id[2]),
flashobj.SpicInitPara.id[0], flashobj.SpicInitPara.id[1],
flashobj.SpicInitPara.id[2], flashobj.SpicInitPara.flashtype,
cspimode[flashobj.SpicInitPara.Mode.BitMode]);
// get at version
strcpy(at_buf, ATCMD_VERSION"."ATCMD_SUBVERSION"."ATCMD_REVISION);
// get fw version
strcpy(fw_buf, SDK_VERSION);
printf("%s,%s(%s)\n", at_buf, fw_buf, RTL8195AFW_COMPILE_TIME);
at_printf("\r\n[ATSV] OK:%s,%s(%s)", at_buf, fw_buf,
RTL8195AFW_COMPILE_TIME);
}
#if defined(configUSE_WAKELOCK_PMU) && (configUSE_WAKELOCK_PMU == 1)
void fATSP(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
uint32_t lock_id;
uint32_t bitmap;
if (!arg) {
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR,
"\r\n[ATSP] Usage: ATSP=<a/r/?>");
at_printf("\r\n[ATSP] ERROR:1");
return;
} else {
if ((argc = parse_param(arg, argv)) != 2) {
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR,
"\r\n[ATSP] Usage: ATSP=<a/r/?>");
at_printf("\r\n[ATSP] ERROR:1");
return;
}
}
switch (argv[1][0]) {
case 'a': // acquire
{
acquire_wakelock(WAKELOCK_OS);
//at_printf("\r\n[ATSP] wakelock:0x%08x", get_wakelock_status());
break;
}
case 'r': // release
{
release_wakelock(WAKELOCK_OS);
//at_printf("\r\n[ATSP] wakelock:0x%08x", get_wakelock_status());
break;
}
case '?': // get status
break;
default:
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR,
"\r\n[ATSP] Usage: ATSP=<a/r/?>");
at_printf("\r\n[ATSP] ERROR:2");
return;
}
bitmap = get_wakelock_status();
at_printf("\r\n[ATSP] OK:%s", (bitmap&WAKELOCK_OS)?"1":"0");
}
#endif
void fATSE(void *arg) {
int argc = 0;
int echo = 0, mask = gDbgFlag, dbg_lv = gDbgLevel;
char *argv[MAX_ARGC] = { 0 };
int err_no = 0;
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ALWAYS,
"[ATSE]: _AT_SYSTEM_ECHO_DBG_SETTING");
if (!arg) {
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR,
"[ATSE] Usage: ATSE=<echo>,<dbg_msk>,<dbg_lv>");
err_no = 1;
goto exit;
}
argc = parse_param(arg, argv);
if (argc < 2 || argc > 4) {
err_no = 2;
goto exit;
}
#if CONFIG_EXAMPLE_UART_ATCMD
if (argv[1] != NULL) {
echo = atoi(argv[1]);
if (echo > 1 || echo < 0) {
err_no = 3;
goto exit;
}
gAT_Echo = echo ? 1 : 0;
}
#endif
if ((argc > 2) && (argv[2] != NULL)) {
mask = strtoul(argv[2], NULL, 0);
at_set_debug_mask(mask);
}
if ((argc == 4) && (argv[3] != NULL)) {
dbg_lv = strtoul(argv[3], NULL, 0);
at_set_debug_level(dbg_lv);
}
exit: if (err_no)
at_printf("\r\n[ATSE] ERROR:%d", err_no);
else
at_printf("\r\n[ATSE] OK");
return;
}
#if CONFIG_WLAN
#if CONFIG_WEBSERVER
#include "wifi_structures.h"
#include "wifi_constants.h"
extern rtw_wifi_setting_t wifi_setting;
void fATSW(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = {0};
if (!arg) {
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR, "\r\n[ATSW] Usage: ATSW=<c/s>");
at_printf("\r\n[ATSW] ERROR:1");
return;
} else {
if((argc = parse_param(arg, argv)) != 2) {
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR, "\r\n[ATSW] Usage: ATSW=<c/s>");
at_printf("\r\n[ATSW] ERROR:1");
return;
}
}
if(argv[1][0]!='c'&&argv[1][0]!='s') {
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR, "\r\n[ATSW] Usage: ATSW=<c/s>");
at_printf("\r\n[ATSW] ERROR:2");
return;
}
// make sure AP mode
LoadWifiConfig();
if(wifi_setting.mode != RTW_MODE_AP) {
at_printf("\r\n[ATSW] ERROR:3");
return;
}
switch(argv[1][0]) {
case 'c': // create webserver
{
start_web_server();
break;
}
case 's': // stop webserver
{
stop_web_server();
break;
}
}
at_printf("\r\n[ATSW] OK");
}
#endif
extern int EraseApinfo();
//extern int Erase_Fastconnect_data();
void fATSY(void *arg) {
#if CONFIG_EXAMPLE_WLAN_FAST_CONNECT
// Erase_Fastconnect_data();
#endif
#if CONFIG_WEBSERVER
EraseApinfo();
#endif
#if CONFIG_EXAMPLE_UART_ATCMD
extern int reset_uart_atcmd_setting(void);
reset_uart_atcmd_setting();
#endif
#if CONFIG_OTA_UPDATE
// Reset ota image signature
cmd_ota_image(0);
#endif
at_printf("\r\n[ATSY] OK");
// reboot
sys_reset();
}
#if CONFIG_OTA_UPDATE
extern int wifi_is_connected_to_ap(void);
void fATSO(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
if (!arg) {
AT_DBG_MSG(AT_FLAG_OTA, AT_DBG_ERROR,
"\r\n[ATSO] Usage: ATSO=<ip>,<port>");
at_printf("\r\n[ATSO] ERROR:1");
return;
}
argv[0] = "update";
if ((argc = parse_param(arg, argv)) != 3) {
AT_DBG_MSG(AT_FLAG_OTA, AT_DBG_ERROR,
"\r\n[ATSO] Usage: ATSO=<ip>,<port>");
at_printf("\r\n[ATSO] ERROR:1");
return;
}
// check wifi connect first
if (wifi_is_connected_to_ap() == 0) {
cmd_update(argc, argv);
at_printf("\r\n[ATSO] OK");
} else {
at_printf("\r\n[ATSO] ERROR:3");
}
}
void fATSC(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
int cmd = 0;
if (!arg) {
AT_DBG_MSG(AT_FLAG_OTA, AT_DBG_ERROR, "\r\n[ATSC] Usage: ATSC=<0/1>");
at_printf("\r\n[ATSC] ERROR:1");
return;
}
if ((argc = parse_param(arg, argv)) != 2) {
AT_DBG_MSG(AT_FLAG_OTA, AT_DBG_ERROR, "\r\n[ATSC] Usage: ATSC=<0/1>");
at_printf("\r\n[ATSC] ERROR:1");
return;
}
cmd = atoi(argv[1]);
if ((cmd != 0) && (cmd != 1)) {
at_printf("\r\n[ATSC] ERROR:2");
return;
}
at_printf("\r\n[ATSC] OK");
if (cmd == 1) {
cmd_ota_image(1);
} else {
cmd_ota_image(0);
}
// reboot
sys_reset();
}
#endif
#if CONFIG_EXAMPLE_UART_ATCMD
extern const u32 log_uart_support_rate[];
void fATSU(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
u32 baud = 0;
u8 databits = 0;
u8 stopbits = 0;
u8 parity = 0;
u8 flowcontrol = 0;
u8 configmode = 0;
int i;
UART_LOG_CONF uartconf;
if (!arg) {
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR,
"[ATSU] Usage: ATSU=<baud>,<databits>,<stopbits>,<parity>,<flowcontrol>,<configmode>");
at_printf("\r\n[ATSU] ERROR:1");
return;
}
if ((argc = parse_param(arg, argv)) != 7) {
if(argv[1][0] == '?') {
read_uart_atcmd_setting_from_system_data(&uartconf);
at_printf("\r\n");
at_printf( "AT_UART_CONF: %d,%d,%d,%d,%d",
uartconf.BaudRate, uartconf.DataBits, uartconf.StopBits,
uartconf.Parity, uartconf.FlowControl);
// return;
}
else {
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ERROR,
"[ATSU] Usage: ATSU=<baud>,<databits>,<stopbits>,<parity>,<flowcontrol>,<configmode>");
at_printf("\r\n[ATSU] ERROR:1");
return;
}
}
else {
baud = atoi(argv[1]);
databits = atoi(argv[2]);
stopbits = atoi(argv[3]);
parity = atoi(argv[4]);
flowcontrol = atoi(argv[5]);
configmode = atoi(argv[6]);
/*
// Check Baud rate
for (i=0; log_uart_support_rate[i]!=0xFFFFFF; i++) {
if (log_uart_support_rate[i] == baud) {
break;
}
}
if (log_uart_support_rate[i]== 0xFFFFFF) {
at_printf("\r\n[ATSU] ERROR:2");
return;
}
*/
if (((databits < 5) || (databits > 8)) || ((stopbits < 1) || (stopbits > 2))
|| ((parity < 0) || (parity > 2))
|| ((flowcontrol < 0) || (flowcontrol > 1))
|| ((configmode < 0) || (configmode > 3)) ) {
at_printf("\r\n[ATSU] ERROR:2");
return;
}
memset((void*) &uartconf, 0, sizeof(UART_LOG_CONF));
uartconf.BaudRate = baud;
uartconf.DataBits = databits;
uartconf.StopBits = stopbits;
uartconf.Parity = parity;
uartconf.FlowControl = flowcontrol;
AT_DBG_MSG(AT_FLAG_COMMON, AT_DBG_ALWAYS, "AT_UART_CONF: %d,%d,%d,%d,%d",
uartconf.BaudRate, uartconf.DataBits, uartconf.StopBits,
uartconf.Parity, uartconf.FlowControl);
switch (configmode) {
case 0: // set current configuration, won't save
uart_atcmd_reinit(&uartconf);
break;
case 1: // set current configuration, and save
write_uart_atcmd_setting_to_system_data(&uartconf);
uart_atcmd_reinit(&uartconf);
break;
case 2: // set configuration, reboot to take effect
write_uart_atcmd_setting_to_system_data(&uartconf);
break;
}
}
at_printf("\r\n[ATSU] OK");
}
#endif //#if CONFIG_EXAMPLE_UART_ATCMD
#endif //#if CONFIG_WLAN
void fATSG(void *arg) {
gpio_t gpio_ctrl;
int argc = 0, val, error_no = 0;
char *argv[MAX_ARGC] = { 0 }, port, num;
PinName pin = NC;
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "[ATSG]: _AT_SYSTEM_GPIO_CTRL_");
if (!arg) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ERROR,
"[ATSG] Usage: ATSG=<R/W>,<PORT>,<DATA>,<DIR>,<PULL>");
error_no = 1;
goto exit;
}
if ((argc = parse_param(arg, argv)) < 3) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ERROR,
"[ATSG] Usage: ATSG=<R/W>,<PORT>,<DATA>,<DIR>,<PULL>");
error_no = 2;
goto exit;
}
port = argv[2][1];
num = strtoul(&argv[2][3], NULL, 0);
port -= 'A';
pin = (port << 4 | num);
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "PORT: %s[%d]", argv[2], pin);
if (gpio_set(pin) == 0xff) {
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ERROR, "[ATSG]: Invalid Pin Name [%d]",
pin);
error_no = 3;
goto exit;
}
gpio_init(&gpio_ctrl, pin);
if (argv[4]) {
int dir = atoi(argv[4]);
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "DIR: %s", argv[4]);
gpio_dir(&gpio_ctrl, dir);
}
if (argv[5]) {
int pull = atoi(argv[5]);
AT_DBG_MSG(AT_FLAG_GPIO, AT_DBG_ALWAYS, "PULL: %s", argv[5]);
gpio_mode(&gpio_ctrl, pull);
}
if (argv[1][0] == 'R') {
val = gpio_read(&gpio_ctrl);
} else {
val = atoi(argv[3]);
gpio_write(&gpio_ctrl, val);
}
exit: if (error_no) {
at_printf("\r\n[ATSG] ERROR:%d", error_no);
} else {
at_printf("\r\n[ATSG] OK:%d", val);
}
}
#endif //#elif ATCMD_VER == ATVER_2
#if defined(configUSE_WAKELOCK_PMU) && (configUSE_WAKELOCK_PMU == 1)
/*
* bitmask:
* bit0: OS
* bit1: WLAN
* bit2: LOGUART
* bit3: SDIO
*/
void fATSL(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
int err_no = 0;
uint32_t lock_id;
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS, "[ATSL]: _AT_SYS_WAKELOCK_TEST_");
if (!arg) {
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS,
"[ATSL] Usage ATSL=[a/r/?][bitmask]");
err_no = 1;
goto exit;
} else {
argc = parse_param(arg, argv);
if (argc < 2) {
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS,
"[ATSL] Usage ATSL=[a/r/?][bitmask]");
err_no = 2;
goto exit;
}
}
switch (argv[1][0]) {
case 'a': // acquire
{
if (argc == 3) {
lock_id = strtoul(argv[2], NULL, 16);
acquire_wakelock(lock_id);
}
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS, "[ATSL] wakelock:0x%08x",
get_wakelock_status());
break;
}
case 'r': // release
{
if (argc == 3) {
lock_id = strtoul(argv[2], NULL, 16);
release_wakelock(lock_id);
}
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS, "[ATSL] wakelock:0x%08x",
get_wakelock_status());
break;
}
case '?': // get status
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS, "[ATSL] wakelock:0x%08x",
get_wakelock_status());
#if (configGENERATE_RUN_TIME_STATS == 1)
char *cBuffer = pvPortMalloc(512);
if (cBuffer != NULL) {
get_wakelock_hold_stats((char *) cBuffer);
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS, "%s", cBuffer);
}
vPortFree(cBuffer);
#endif
break;
#if (configGENERATE_RUN_TIME_STATS == 1)
case 'c': // clean wakelock info (for recalculate wakelock hold time)
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS, "[ATSL] clean wakelock stat");
clean_wakelock_stat();
break;
#endif
default:
AT_DBG_MSG(AT_FLAG_OS, AT_DBG_ALWAYS,
"[ATSL] Usage ATSL=[a/r/?][bitmask]");
err_no = 3;
break;
}
exit:
#if ATCMD_VER == ATVER_2
if (err_no)
at_printf("\r\n[ATSL] ERROR:%d", err_no);
else
at_printf("\r\n[ATSL] OK:0x%08x", get_wakelock_status());
#endif
return;
}
#if CONFIG_UART_XMODEM
void fATSX(void *arg)
{
if (HalGetChipId() < CHIP_ID_8195AM) {
// use xmodem to update, RX: PC_0, TX: PC_3, baudrate: 1M
OTU_FW_Update(0, 0, 115200);
// use xmodem to update, RX: PE_3, TX: PE_0, baudrate: 1M
// JTAG Off!
// OTU_FW_Update(0, 1, 115200);
}
else {
// use xmodem to update, RX: PA_6, TX: PA_7, baudrate: 1M
OTU_FW_Update(0, 2, 115200);
};
at_printf("\r\n[ATSX] OK");
}
#endif
#endif
void print_hex_dump(uint8_t *buf, int len, unsigned char k) {
uint32_t ss[2];
ss[0] = 0x78323025; // "%02x"
ss[1] = k; // ","...'\0'
uint8_t * ptr = buf;
while (len--) {
if (len == 0)
ss[1] = 0;
printf((uint8_t *) &ss[0], *ptr++);
}
}
//ATFD - Flash Data Dump
void fATFD(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
#if DEBUG_AT_USER_LEVEL > 3
printf("ATFD: _AT_FLASH_DUMP_\n");
#endif
if (!arg) {
printf("Usage: ATFD=faddr(HEX),[size]\n");
} else {
argc = parse_param(arg, argv);
if (argc >= 1) {
int addr;
sscanf(argv[1], "%x", &addr);
int size = 0;
if (argc > 2)
size = atoi(argv[2]);
if (size <= 0 || size > 16384)
size = 1;
u32 symbs_line = 32;
u32 rdsize = 8 * symbs_line;
uint8_t *flash_data = (uint8_t *) malloc(rdsize);
while (size) {
if (size < rdsize)
rdsize = size;
else
rdsize = 8 * symbs_line;
flash_stream_read(&flashobj, addr, rdsize, flash_data);
uint8_t *ptr = flash_data;
while (ptr < flash_data + rdsize) {
if (symbs_line > size)
symbs_line = size;
printf("%08X ", addr);
print_hex_dump(ptr, symbs_line, ' ');
printf("\r\n");
addr += symbs_line;
ptr += symbs_line;
size -= symbs_line;
if (size == 0)
break;
}
}
free(flash_data);
}
}
}
void fATFO(void *arg) {
int argc = 0;
char *argv[MAX_ARGC] = { 0 };
#if DEBUG_AT_USER_LEVEL > 3
printf("ATFO: _AT_FLASH_OTP_DUMP_\n");
#endif
if (!arg) {
printf("Usage: ATFO=faddr(HEX),[size]\n");
} else {
argc = parse_param(arg, argv);
if (argc >= 1) {
int addr;
sscanf(argv[1], "%x", &addr);
int size = 0;
if (argc > 2)
size = atoi(argv[2]);
if (size <= 0 || size > 16384)
size = 1;
u32 symbs_line = 32;
u32 rdsize = 8 * symbs_line;
uint8_t *flash_data = (uint8_t *) malloc(rdsize);
while (size) {
if (size < rdsize)
rdsize = size;
else
rdsize = 8 * symbs_line;
flash_otp_read(&flashobj, addr, rdsize, flash_data);
uint8_t *ptr = flash_data;
while (ptr < flash_data + rdsize) {
if (symbs_line > size)
symbs_line = size;
printf("%08X ", addr);
print_hex_dump(ptr, symbs_line, ' ');
printf("\r\n");
addr += symbs_line;
ptr += symbs_line;
size -= symbs_line;
if (size == 0)
break;
}
}
free(flash_data);
}
}
}
// Mem info
void fATST(void *arg) {
extern void dump_mem_block_list(void); // heap_5.c
printf("\nCLK CPU\t\t%d Hz\nRAM heap\t%d bytes\nTCM heap\t%d bytes\n",
HalGetCpuClk(), xPortGetFreeHeapSize(), tcm_heap_freeSpace());
#if CONFIG_DEBUG_LOG > 1
dump_mem_block_list();
tcm_heap_dump();
#endif;
printf("\n");
#if (configGENERATE_RUN_TIME_STATS == 1)
char *cBuffer = pvPortMalloc(512);
if(cBuffer != NULL) {
vTaskGetRunTimeStats((char *)cBuffer);
printf("%s", cBuffer);
}
vPortFree(cBuffer);
#endif
}
#if 0
#include "wlan_lib.h"
#include "hal_com_reg.h"
// extern Rltk_wlan_t rltk_wlan_info[2];
void fATXT(void *arg)
{
#if DEBUG_AT_USER_LEVEL > 3
printf("ATWT: _AT_CFG_DUMP_\n");
#endif
int size = 512;
int addr = 0;
uint8_t *blk_data = (uint8_t *)malloc(size);
memset(blk_data, 0xff, size);
if(blk_data) {
uint8_t * ptr = blk_data;
Hal_ReadEFuse(*(_adapter **)(rltk_wlan_info->priv), 0, 0, 512, ptr, 1);
//rtw_flash_map_update(*(_adapter **)(rltk_wlan_info->priv), 512);
u32 symbs_line = 32;
while(addr < size) {
if(symbs_line > size) symbs_line = size;
printf("%08X ", addr);
print_hex_dump(ptr, symbs_line, ' ');
printf("\r\n");
addr += symbs_line;
ptr += symbs_line;
size -= symbs_line;
if(size == 0) break;
}
free(blk_data);
}
}
#endif
log_item_t at_sys_items[] = {
#if (ATCMD_VER == ATVER_1)
{ "ATSD", fATSD}, // Dump register
{ "ATSE", fATSE}, // Edit register
{ "ATSC", fATSC}, // Clear OTA signature
{ "ATSR", fATSR}, // Recover OTA signature
#if CONFIG_UART_XMODEM
{ "ATSY", fATSY}, // uart ymodem upgrade
#endif
#if SUPPORT_MP_MODE
{ "ATSA", fATSA}, // MP ADC test
{ "ATSG", fATSG}, // MP GPIO test
{ "ATSP", fATSP}, // MP Power related test
{ "ATSB", fATSB}, // OTU PIN setup
#endif
#if (configGENERATE_RUN_TIME_STATS == 1)
{ "ATSS", fATSS}, // Show CPU stats
#endif
#if SUPPORT_CP_TEST
{ "ATSM", fATSM}, // Apple CP test
#endif
{ "ATSJ", fATSJ}, //trun off JTAG
{ "ATS@", fATSs}, // Debug message setting
{ "ATS!", fATSc}, // Debug config setting
{ "ATS#", fATSt}, // test command
{ "ATS?", fATSx}, // Help
#elif ATCMD_VER == ATVER_2 //#if ATCMD_VER == ATVER_1
{ "AT", fATS0 }, // test AT command ready
{ "ATS?", fATSh }, // list all AT command
{ "ATSR", fATSR }, // system restart
{ "ATSV", fATSV }, // show version info
{ "ATSP", fATSP }, // power saving mode
{ "ATSE", fATSE }, // enable and disable echo
#if CONFIG_WLAN
#if CONFIG_WEBSERVER
{ "ATSW", fATSW}, // start webserver
#endif
{ "ATSY", fATSY }, // factory reset
#if CONFIG_OTA_UPDATE
{ "ATSO", fATSO }, // ota upgrate
{ "ATSC", fATSC }, // chose the activited image
#endif
#if CONFIG_EXAMPLE_UART_ATCMD
{ "ATSU", fATSU }, // AT uart configuration
#endif
#endif
{ "ATSG", fATSG }, // GPIO control
#if CONFIG_UART_XMODEM
{ "ATSX", fATSX}, // uart xmodem upgrade
#endif
{ "ATSD", fATSD }, // Dump register
{ "ATXD", fATXD }, // Write register
#endif // end of #if ATCMD_VER == ATVER_1
// Following commands exist in two versions
#if defined(configUSE_WAKELOCK_PMU) && (configUSE_WAKELOCK_PMU == 1)
{ "ATSL", fATSL }, // wakelock test
#endif
{ "ATFD", fATFD }, // Flash Data Damp
{ "ATFO", fATFO }, // Flash OTP Damp
{ "ATST", fATST }, // add pvvx: mem info
// { "ATXT", fATXT }, // add pvvx: cfg_wifi
{ "ATSI", fATSI } // Dev/Ports Info
};
#if ATCMD_VER == ATVER_2
void print_system_at(void *arg) {
int index;
int cmd_len = 0;
cmd_len = sizeof(at_sys_items) / sizeof(at_sys_items[0]);
for (index = 0; index < cmd_len; index++)
at_printf("\r\n%s", at_sys_items[index].log_cmd);
}
#endif
void at_sys_init(void) {
log_service_add_table(at_sys_items,
sizeof(at_sys_items) / sizeof(at_sys_items[0]));
}
#if SUPPORT_LOG_SERVICE
log_module_init(at_sys_init);
#endif
#endif //#ifdef CONFIG_AT_SYS