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Merge branch 'prepare_for_master' of https://gitlink.org.cn/xuos/xiuos into connection

This commit is contained in:
Liu_Weichao 2023-12-06 17:25:40 +08:00
parent 4c8df066b7 eb74a93b36
commit ad82f5beb7
103 changed files with 12142 additions and 344 deletions
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1
APP_Framework/Applications/Kconfig
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@ -20,4 +20,5 @@ menu "Applications"
source "$APP_DIR/Applications/sensor_app/Kconfig"
source "$APP_DIR/Applications/embedded_database_app/Kconfig"
source "$APP_DIR/Applications/webnet/Kconfig"
source "$APP_DIR/Applications/mongoose/Kconfig"
endmenu

4
APP_Framework/Applications/Makefile
View File

@ -39,6 +39,10 @@ ifeq ($(CONFIG_ADD_XIZI_FEATURES),y)
ifeq ($(CONFIG_APP_USING_WEBNET),y)
SRC_DIR += webnet
endif
ifeq ($(CONFIG_USE_MONGOOSE),y)
SRC_DIR += mongoose
endif
include $(KERNEL_ROOT)/compiler.mk
endif

15
APP_Framework/Applications/app_test/test_socket.c
View File

@ -76,10 +76,12 @@ struct IperfParam {
static void* TestIperfServer(void* param)
{
struct IperfParam* iperf_param = (struct IperfParam*)param;
int sock = socket(AF_INET, SOCK_STREAM, 0);
int sock = socket(AF_INET, SOCK_STREAM, 6);
if (sock < 0) {
printf("[%s] Err: Can't create socker.\n", __func__);
return NULL;
} else {
printf("[%s] Info Create server socket %d\n", __func__, sock);
}
uint8_t* recv_data = (uint8_t*)malloc(IPERF_BUFSZ);
@ -121,8 +123,9 @@ static void* TestIperfServer(void* param)
socklen_t sin_size = sizeof(struct sockaddr_in);
struct sockaddr_in client_addr;
int connection = accept(sock, (struct sockaddr*)&client_addr, &sin_size);
printf("[%s] Info: New client connected from (%s, %d)\n", __func__,
inet_ntoa(client_addr.sin_addr), ntohs(client_addr.sin_port));
printf("[%s] Info: New client connected from (%s, %d), connect: %d\n", __func__,
inet_ntoa(client_addr.sin_addr), ntohs(client_addr.sin_port),
connection);
int flag = 1;
setsockopt(connection,
@ -141,8 +144,8 @@ static void* TestIperfServer(void* param)
inet_ntoa(client_addr.sin_addr), ntohs(client_addr.sin_port));
break;
} else if (bytes_received < 0) {
KPrintf("recv error, client: (%s, %d)\n",
inet_ntoa(client_addr.sin_addr), ntohs(client_addr.sin_port));
KPrintf("recv error: %d, client: (%s, %d)\n",
bytes_received, inet_ntoa(client_addr.sin_addr), ntohs(client_addr.sin_port));
break;
}
@ -258,8 +261,6 @@ enum IperfParamEnum {
void TestSocket(int argc, char* argv[])
{
lwip_config_tcp(0, lwip_ipaddr, lwip_netmask, lwip_gwaddr);
static char usage_info[] = "Run either a iperf server or iperf client.";
static char program_info[] = "Lwip socket test task, a simple iperf.";
static const char* const usages[] = {

3
APP_Framework/Applications/mongoose/Kconfig Normal file
View File

@ -0,0 +1,3 @@
menuconfig USE_MONGOOSE
bool "Use mongoose as webserver"
default n

3
APP_Framework/Applications/mongoose/Makefile Normal file
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@ -0,0 +1,3 @@
SRC_FILES += project.c
include $(KERNEL_ROOT)/compiler.mk

3
APP_Framework/Applications/mongoose/lib/Makefile Normal file
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@ -0,0 +1,3 @@
SRC_FILES += mongoose.c
include $(KERNEL_ROOT)/compiler.mk

BIN
APP_Framework/Applications/mongoose/mongoose.a Normal file
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1757
APP_Framework/Applications/mongoose/mongoose.h Normal file
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File diff suppressed because it is too large Load Diff

142
APP_Framework/Applications/mongoose/project.c Normal file
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@ -0,0 +1,142 @@
// Copyright (c) 2022 Cesanta Software Limited
// All rights reserved
//
// UI example
// It implements the following endpoints:
// /api/config/get - respond with current config
// /api/config/set - POST a config change
// any other URI serves static files from s_root_dir
// Data and results are JSON strings
#include "ip_addr.h"
#include "mongoose.h"
#include "netdev.h"
char index_path[] = "login.html";
static const char* s_http_addr = "http://192.168.131.88:8000"; // HTTP port
static const char* s_root_dir = "webserver";
static const char* s_enable_hexdump = "no";
static const char* s_ssi_pattern = "#.html";
static const char* device_type = "Edu-ARM32";
static const char* web_version = "XUOS Webserver 1.0";
static int enable_4g = 0;
static struct netdev* p_netdev;
static struct config {
char *ip, *mask, *gw, *dns;
} s_config;
// Try to update a single configuration value
static void update_config(struct mg_str json, const char* path, char** value)
{
char* jval;
if ((jval = mg_json_get_str(json, path)) != NULL) {
free(*value);
*value = strdup(jval);
}
}
static void fn(struct mg_connection* c, int ev, void* ev_data, void* fn_data)
{
if (ev == MG_EV_HTTP_MSG) {
struct mg_http_message *hm = (struct mg_http_message*)ev_data, tmp = { 0 };
if (mg_http_match_uri(hm, "/getSystemInfo")) {
mg_http_reply(c, 200, "Content-Type: application/json\r\n",
"{%m:%m, %m:%m, %m:%m, %m:%m, %m:%m, %m:%d}\n",
MG_ESC("ip"), MG_ESC(s_config.ip),
MG_ESC("deviceType"), MG_ESC(device_type),
MG_ESC("deviceNo"), MG_ESC("0"),
MG_ESC("systemTime"), MG_ESC("YYYY:MM:DD hh:mm:ss"),
MG_ESC("webVersion"), MG_ESC(web_version),
MG_ESC("statusOf4g"), enable_4g);
} else if (mg_http_match_uri(hm, "/net/get4gInfo")) {
mg_http_reply(c, 200, "Content-Type: application/json\r\n",
"{%m:%m}\n",
MG_ESC("enable4g"), MG_ESC(enable_4g));
} else if (mg_http_match_uri(hm, "/net/set4gInfo")) {
struct mg_str json = hm->body;
enable_4g = mg_json_get_long(json, "$.enable4g", 0);
mg_http_reply(c, 200, "Content-Type: application/json\r\n", "{\"status\":\"success\"}\r\n");
printf("Get enable 4g setting: %d\n", enable_4g);
} else if (mg_http_match_uri(hm, "/net/getEthernetInfo")) {
mg_http_reply(c, 200, "Content-Type: application/json\r\n",
"{%m:%m, %m:%m, %m:%m, %m:%m}\n",
MG_ESC("ip"), MG_ESC(s_config.ip),
MG_ESC("netmask"), MG_ESC(s_config.mask),
MG_ESC("gateway"), MG_ESC(s_config.gw),
MG_ESC("dns"), MG_ESC(s_config.dns));
} else if (mg_http_match_uri(hm, "/net/setEthernetInfo")) {
struct mg_str json = hm->body;
printf("json: %s\n", json.ptr);
update_config(json, "$.ip", &s_config.ip);
update_config(json, "$.netmask", &s_config.mask);
update_config(json, "$.gateway", &s_config.gw);
update_config(json, "$.dns", &s_config.dns);
mg_http_reply(c, 200, "Content-Type: application/json\r\n", "{\"status\":\"success\"}\r\n");
ip_addr_t ipaddr, maskaddr, gwaddr;
inet_aton(s_config.ip, &ipaddr);
inet_aton(s_config.mask, &maskaddr);
inet_aton(s_config.gw, &gwaddr);
p_netdev->ops->set_addr_info(p_netdev, &ipaddr, &maskaddr, &gwaddr);
printf("Board Net Configuration changed to [IP: %s, Mask: %s, GW: %s, DNS: %s]\n",
s_config.ip,
s_config.mask,
s_config.gw,
s_config.dns);
} else {
struct mg_str unknown = mg_str_n("?", 1), *cl;
struct mg_http_serve_opts opts = { .root_dir = s_root_dir, .ssi_pattern = s_ssi_pattern };
mg_http_serve_dir(c, hm, &opts);
mg_http_parse((char*)c->send.buf, c->send.len, &tmp);
cl = mg_http_get_header(&tmp, "Content-Length");
if (cl == NULL)
cl = &unknown;
MG_INFO(("%.*s %.*s %.*s %.*s", (int)hm->method.len, hm->method.ptr,
(int)hm->uri.len, hm->uri.ptr, (int)tmp.uri.len, tmp.uri.ptr,
(int)cl->len, cl->ptr));
}
}
(void)fn_data;
}
static void* do_webserver_demo(void* none)
{
p_netdev = netdev_get_by_name("wz");
if (p_netdev == NULL) {
MG_INFO(("Did nto find wz netdev, use default.\n"));
p_netdev = NETDEV_DEFAULT;
}
MG_INFO(("Use Netdev %s", p_netdev->name));
s_config.ip = strdup(inet_ntoa(*p_netdev->ip_addr));
s_config.mask = strdup(inet_ntoa(*p_netdev->netmask));
s_config.gw = strdup(inet_ntoa(*p_netdev->gw));
s_config.dns = strdup(inet_ntoa(p_netdev->dns_servers[0]));
struct mg_mgr mgr; // Event manager
// mg_log_set(MG_LL_INFO); // Set to 3 to enable debug
mg_log_set(MG_LL_DEBUG); // Set to 3 to enable debug
mg_mgr_init(&mgr); // Initialise event manager
mg_http_listen(&mgr, s_http_addr, fn, NULL); // Create HTTP listener
for (;;)
mg_mgr_poll(&mgr, 50); // Infinite event loop
mg_mgr_free(&mgr);
return NULL;
}
int webserver_demo(int argc, char* argv[])
{
pthread_t tid = -1;
pthread_attr_t attr;
attr.schedparam.sched_priority = 30;
attr.stacksize = 0x2000;
PrivTaskCreate(&tid, &attr, do_webserver_demo, NULL);
return 0;
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0) | SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN) | SHELL_CMD_PARAM_NUM(5), Webserver, webserver_demo, webserver for project);

14
Ubiquitous/XiZi_IIoT/Makefile
View File

@ -50,6 +50,7 @@ export SRC_DIR:= $(SRC_APP_DIR) $(SRC_KERNEL_DIR)
export LIBCC
export MUSL_DIR := $(KERNEL_ROOT)/lib/musllib
export LWIP_DIR := $(KERNEL_ROOT)/resources/ethernet
export MONGOOSE_DIR := $(KERNEL_ROOT)/../../APP_Framework/Applications/mongoose/lib
PART:=
@ -74,6 +75,10 @@ ifeq ($(CONFIG_RESOURCES_LWIP), y)
PART += COMPILE_LWIP
endif
ifeq ($(CONFIG_USE_MONGOOSE), y)
# PART += COMPILE_MONGOOSE
endif
ifeq ($(CONFIG_MCUBOOT_BOOTLOADER), y)
PART += COMPILE_BOOTLOADER
else ifeq ($(CONFIG_MCUBOOT_APPLICATION), y)
@ -130,6 +135,15 @@ COMPILE_LWIP:
@cp build/liblwip.a $(KERNEL_ROOT)/resources/ethernet/LwIP/liblwip.a
@rm build/Makefile build/make.obj
COMPILE_MONGOOSE:
@for dir in $(MONGOOSE_DIR);do \
$(MAKE) -C $$dir COMPILE_TYPE=$@; \
done
@cp link_mongoose.mk build/Makefile
@$(MAKE) -C build TARGET=mongoose.a LINK_FLAGS=LFLAGS
@cp build/mongoose.a $(KERNEL_ROOT)/../../APP_Framework/Applications/mongoose/mongoose.a
@rm build/Makefile build/make.obj
COMPILE_KERNEL:
@for dir in $(SRC_KERNEL_DIR);do \
$(MAKE) -C $$dir; \

4
Ubiquitous/XiZi_IIoT/board/edu-arm32/config.mk
View File

@ -1,10 +1,10 @@
export CROSS_COMPILE ?=/usr/bin/arm-none-eabi-
export CFLAGS := -mcpu=cortex-m4 -mthumb -mfpu=fpv4-sp-d16 -mfloat-abi=softfp -ffunction-sections -fdata-sections -Dgcc -O0 -fgnu89-inline -Wa,-mimplicit-it=thumb -Werror -Wuninitialized
export CFLAGS := -mcpu=cortex-m4 -mthumb -mfpu=fpv4-sp-d16 -mfloat-abi=softfp -ffunction-sections -fdata-sections -Dgcc -O2 -gdwarf-2 -g -fgnu89-inline -Wa,-mimplicit-it=thumb
# export CFLAGS := -mcpu=cortex-m4 -mthumb -mfpu=fpv4-sp-d16 -mfloat-abi=softfp -ffunction-sections -fdata-sections -Dgcc -O0 -gdwarf-2 -g -fgnu89-inline -Wa,-mimplicit-it=thumb -Werror
export AFLAGS := -c -mcpu=cortex-m4 -mthumb -mfpu=fpv4-sp-d16 -mfloat-abi=softfp -ffunction-sections -fdata-sections -x assembler-with-cpp -Wa,-mimplicit-it=thumb -gdwarf-2
export LFLAGS := -mcpu=cortex-m4 -mthumb -mfpu=fpv4-sp-d16 -mfloat-abi=softfp -ffunction-sections -fdata-sections -Wl,--gc-sections,-Map=XiZi-edu-arm32.map,-cref,-u,Reset_Handler -T $(BSP_ROOT)/link.lds
export CXXFLAGS := -mcpu=cortex-m4 -mthumb -mfpu=fpv4-sp-d16 -mfloat-abi=softfp -ffunction-sections -fdata-sections -Dgcc -O0 -Werror
export CXXFLAGS := -mcpu=cortex-m4 -mthumb -mfpu=fpv4-sp-d16 -mfloat-abi=softfp -ffunction-sections -fdata-sections -Dgcc -O2 -Werror
# export CXXFLAGS := -mcpu=cortex-m4 -mthumb -mfpu=fpv4-sp-d16 -mfloat-abi=softfp -ffunction-sections -fdata-sections -Dgcc -O0 -gdwarf-2 -g -Werror
export APPLFLAGS :=

3
Ubiquitous/XiZi_IIoT/board/edu-arm32/third_party_driver/ethernet/eth_driver.c
View File

@ -278,10 +278,7 @@ struct pbuf* low_level_input(struct netif* netif)
return p;
}
extern void LwipSetIPTest(int argc, char* argv[]);
int HwEthInit(void)
{
// lwip_config_tcp(0, lwip_ipaddr, lwip_netmask, lwip_gwaddr);
LwipSetIPTest(1, NULL);
return EOK;
}

11
Ubiquitous/XiZi_IIoT/board/edu-arm32/third_party_driver/ethernet/eth_netdev.c
View File

@ -76,6 +76,7 @@ static int lwip_netdev_set_addr_info(struct netdev* netdev, ip_addr_t* ip_addr,
netif_set_gw((struct netif*)netdev->user_data, ip_2_ip4(gw));
}
}
return 0;
}
#ifdef LWIP_DNS
@ -92,7 +93,7 @@ static int lwip_netdev_set_dns_server(struct netdev* netdev, uint8_t dns_num, ip
}
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
static int lwip_netdev_set_dhcp(struct netdev* netdev, bool is_enabled)
{
netdev_low_level_set_dhcp_status(netdev, is_enabled);
@ -120,7 +121,7 @@ static const struct netdev_ops lwip_netdev_ops = {
#ifdef LWIP_DNS
.set_dns_server = lwip_netdev_set_dns_server,
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
.set_dhcp = lwip_netdev_set_dhcp,
#endif
.set_default = lwip_netdev_set_default,
@ -179,9 +180,9 @@ int lwip_netdev_add(struct netif* lwip_netif)
netdev->ops = &lwip_netdev_ops;
netdev->hwaddr_len = lwip_netif->hwaddr_len;
memcpy(netdev->hwaddr, lwip_netif->hwaddr, lwip_netif->hwaddr_len);
netdev->ip_addr = lwip_netif->ip_addr;
netdev->gw = lwip_netif->gw;
netdev->netmask = lwip_netif->netmask;
netdev->ip_addr = &lwip_netif->ip_addr;
netdev->gw = &lwip_netif->gw;
netdev->netmask = &lwip_netif->netmask;
return result;
}

2
Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/Makefile
View File

@ -1,4 +1,4 @@
# SRC_FILES := socket.c connect_w5500.c w5500.c wizchip_conf.c spi_interface.c wiz_ping.c connect_w5500_test.c wiz_iperf.c
SRC_FILES := socket.c connect_w5500.c w5500.c wizchip_conf.c spi_interface.c wiz_ping.c connect_w5500_test.c w5x00_lwip.c wiz_iperf.c
SRC_FILES := socket.c connect_w5500.c w5500.c wizchip_conf.c spi_interface.c w5x00_lwip.c
include $(KERNEL_ROOT)/compiler.mk

6
Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/connect_w5500.c
View File

@ -328,8 +328,12 @@ int HwWiznetInit(void)
setSHAR(wiz_mac);
ctlwizchip(CW_RESET_PHY, 0);
network_init();
wiz_interrupt_init(0, wiz_irq_handler);
network_init();
setSn_RXBUF_SIZE(0, 16);
setSn_TXBUF_SIZE(0, 16);
#define SOCK_ANY_PORT_NUM 0xC000
@ -349,7 +353,5 @@ int HwWiznetInit(void)
}
}
network_init();
return EOK;
}

0
Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/connect_w5500_test.c → Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/test/connect_w5500_test.c
View File

0
Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/wiz_iperf.c → Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/test/wiz_iperf.c
View File

0
Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/wiz_ping.c → Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/test/wiz_ping.c
View File

0
Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/wiz_ping.h → Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/ethernet/test/wiz_ping.h
View File

42
Ubiquitous/XiZi_IIoT/board/edu-riscv64/third_party_driver/spi/connect_spi.c
View File

@ -152,6 +152,9 @@ static uint32 SpiDrvConfigure(void *drv, struct BusConfigureInfo *configure_info
static uint32 SpiWriteData(struct SpiHardwareDevice *spi_dev, struct SpiDataStandard *spi_datacfg)
{
#define WRITE_BUF_SIZE 1600
static uint32_t write_buf[4 * WRITE_BUF_SIZE] = { 0 };
SpiDeviceParam *dev_param = (SpiDeviceParam *)(spi_dev->haldev.private_data);
uint8 device_id = dev_param->spi_slave_param->spi_slave_id;
@ -184,10 +187,15 @@ static uint32 SpiWriteData(struct SpiHardwareDevice *spi_dev, struct SpiDataStan
dmac_set_single_mode(dev_param->spi_dma_param->spi_dmac_txchannel, &dummy, (void *)(&spi_instance[device_master_id]->dr[0]), DMAC_ADDR_NOCHANGE, DMAC_ADDR_NOCHANGE,
DMAC_MSIZE_4, DMAC_TRANS_WIDTH_32, spi_datacfg->length);
} else {
tx_buff = x_malloc(spi_datacfg->length * 4);
if (!tx_buff) {
goto transfer_done;
if (spi_datacfg->length > WRITE_BUF_SIZE) {
tx_buff = x_malloc(spi_datacfg->length * 4);
if (!tx_buff) {
goto transfer_done;
}
} else {
tx_buff = write_buf;
}
for (i = 0; i < spi_datacfg->length; i++) {
tx_buff[i] = ((uint8_t *)spi_datacfg->tx_buff)[i];
}
@ -201,10 +209,10 @@ static uint32 SpiWriteData(struct SpiHardwareDevice *spi_dev, struct SpiDataStan
spi_instance[device_master_id]->ser = 0x00;
spi_instance[device_master_id]->ssienr = 0x00;
transfer_done:
if (tx_buff != NULL) {
x_free(tx_buff);
}
transfer_done:
if (tx_buff != NULL && spi_datacfg->length > WRITE_BUF_SIZE) {
x_free(tx_buff);
}
}
if (spi_datacfg->spi_cs_release) {
@ -219,6 +227,9 @@ static uint32 SpiWriteData(struct SpiHardwareDevice *spi_dev, struct SpiDataStan
static uint32 SpiReadData(struct SpiHardwareDevice *spi_dev, struct SpiDataStandard *spi_datacfg)
{
#define READ_BUF_SIZE 1600
static uint32_t read_buf[4 * READ_BUF_SIZE] = { 0 };
SpiDeviceParam *dev_param = (SpiDeviceParam *)(spi_dev->haldev.private_data);
uint32 spi_read_length = 0;;
@ -251,12 +262,15 @@ static uint32 SpiReadData(struct SpiHardwareDevice *spi_dev, struct SpiDataStand
dmac_set_single_mode(dev_param->spi_dma_param->spi_dmac_rxchannel, (void *)(&spi_instance[device_master_id]->dr[0]), &dummy, DMAC_ADDR_NOCHANGE, DMAC_ADDR_NOCHANGE,
DMAC_MSIZE_1, DMAC_TRANS_WIDTH_32, spi_datacfg->length);
} else {
rx_buff = x_calloc(spi_datacfg->length * 4, 1);
if(!rx_buff)
{
goto transfer_done;
if (spi_datacfg->length > READ_BUF_SIZE) {
rx_buff = x_calloc(spi_datacfg->length * 4, 1);
if (!rx_buff) {
goto transfer_done;
}
} else {
rx_buff = read_buf;
}
dmac_set_single_mode(dev_param->spi_dma_param->spi_dmac_rxchannel, (void *)(&spi_instance[device_master_id]->dr[0]), rx_buff, DMAC_ADDR_NOCHANGE, DMAC_ADDR_INCREMENT,
DMAC_MSIZE_1, DMAC_TRANS_WIDTH_32, spi_datacfg->length);
}
@ -273,8 +287,8 @@ static uint32 SpiReadData(struct SpiHardwareDevice *spi_dev, struct SpiDataStand
}
}
transfer_done:
if (rx_buff) {
transfer_done:
if (rx_buff && spi_datacfg->length > READ_BUF_SIZE) {
x_free(rx_buff);
}
}

11
Ubiquitous/XiZi_IIoT/board/imxrt1176-sbc/third_party_driver/ethernet/eth_netdev.c
View File

@ -76,6 +76,7 @@ static int lwip_netdev_set_addr_info(struct netdev* netdev, ip_addr_t* ip_addr,
netif_set_gw((struct netif*)netdev->user_data, ip_2_ip4(gw));
}
}
return 0;
}
#ifdef LWIP_DNS
@ -92,7 +93,7 @@ static int lwip_netdev_set_dns_server(struct netdev* netdev, uint8_t dns_num, ip
}
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
static int lwip_netdev_set_dhcp(struct netdev* netdev, bool is_enabled)
{
netdev_low_level_set_dhcp_status(netdev, is_enabled);
@ -120,7 +121,7 @@ static const struct netdev_ops lwip_netdev_ops = {
#ifdef LWIP_DNS
.set_dns_server = lwip_netdev_set_dns_server,
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
.set_dhcp = lwip_netdev_set_dhcp,
#endif
.set_default = lwip_netdev_set_default,
@ -180,9 +181,9 @@ int lwip_netdev_add(struct netif* lwip_netif)
netdev->ops = &lwip_netdev_ops;
netdev->hwaddr_len = lwip_netif->hwaddr_len;
memcpy(netdev->hwaddr, lwip_netif->hwaddr, lwip_netif->hwaddr_len);
netdev->ip_addr = lwip_netif->ip_addr;
netdev->gw = lwip_netif->gw;
netdev->netmask = lwip_netif->netmask;
netdev->ip_addr = &lwip_netif->ip_addr;
netdev->gw = &lwip_netif->gw;
netdev->netmask = &lwip_netif->netmask;
return result;
}

11
Ubiquitous/XiZi_IIoT/board/ok1052-c/third_party_driver/ethernet/eth_netdev.c
View File

@ -76,6 +76,7 @@ static int lwip_netdev_set_addr_info(struct netdev* netdev, ip_addr_t* ip_addr,
netif_set_gw((struct netif*)netdev->user_data, ip_2_ip4(gw));
}
}
return 0;
}
#ifdef LWIP_DNS
@ -92,7 +93,7 @@ static int lwip_netdev_set_dns_server(struct netdev* netdev, uint8_t dns_num, ip
}
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
static int lwip_netdev_set_dhcp(struct netdev* netdev, bool is_enabled)
{
netdev_low_level_set_dhcp_status(netdev, is_enabled);
@ -120,7 +121,7 @@ static const struct netdev_ops lwip_netdev_ops = {
#ifdef LWIP_DNS
.set_dns_server = lwip_netdev_set_dns_server,
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
.set_dhcp = lwip_netdev_set_dhcp,
#endif
.set_default = lwip_netdev_set_default,
@ -180,9 +181,9 @@ int lwip_netdev_add(struct netif* lwip_netif)
netdev->ops = &lwip_netdev_ops;
netdev->hwaddr_len = lwip_netif->hwaddr_len;
memcpy(netdev->hwaddr, lwip_netif->hwaddr, lwip_netif->hwaddr_len);
netdev->ip_addr = lwip_netif->ip_addr;
netdev->gw = lwip_netif->gw;
netdev->netmask = lwip_netif->netmask;
netdev->ip_addr = &lwip_netif->ip_addr;
netdev->gw = &lwip_netif->gw;
netdev->netmask = &lwip_netif->netmask;
return result;
}

2
Ubiquitous/XiZi_IIoT/board/xidatong-arm32/config.mk
View File

@ -30,7 +30,7 @@ export CXXFLAGS := -mcpu=cortex-m7 -mthumb -ffunction-sections -fdata-sections -
export APPLFLAGS := -mcpu=cortex-m7 -mthumb -ffunction-sections -fdata-sections -Wl,--gc-sections,-Map=XiZi-app.map,-cref,-u, -T $(BSP_ROOT)/link_userspace.lds
export DEFINES := -DHAVE_CCONFIG_H -DCPU_MIMXRT1052CVL5B -DSKIP_SYSCLK_INIT -DEVK_MCIMXRM -DFSL_SDK_ENABLE_DRIVER_CACHE_CONTROL=1 -DXIP_EXTERNAL_FLASH=1 -D__STARTUP_INITIALIZE_NONCACHEDATA -D__STARTUP_CLEAR_BSS
export DEFINES := -DHAVE_CCONFIG_H -DCPU_MIMXRT1052CVL5B -DSKIP_SYSCLK_INIT -DEVK_MCIMXRM -DFSL_SDK_ENABLE_DRIVER_CACHE_CONTROL=1 -DXIP_EXTERNAL_FLASH=1 -D__STARTUP_INITIALIZE_NONCACHEDATA -D__STARTUP_CLEAR_BSS -DCHECKSUM_BY_HARDWARE
ifeq ($(CONFIG_MCUBOOT_BOOTLOADER),y)
export DEFINES += -D__BOOTLOADER

11
Ubiquitous/XiZi_IIoT/board/xidatong-arm32/third_party_driver/ethernet/eth_netdev.c
View File

@ -76,6 +76,7 @@ static int lwip_netdev_set_addr_info(struct netdev* netdev, ip_addr_t* ip_addr,
netif_set_gw((struct netif*)netdev->user_data, ip_2_ip4(gw));
}
}
return 0;
}
#ifdef LWIP_DNS
@ -92,7 +93,7 @@ static int lwip_netdev_set_dns_server(struct netdev* netdev, uint8_t dns_num, ip
}
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
static int lwip_netdev_set_dhcp(struct netdev* netdev, bool is_enabled)
{
netdev_low_level_set_dhcp_status(netdev, is_enabled);
@ -120,7 +121,7 @@ static const struct netdev_ops lwip_netdev_ops = {
#ifdef LWIP_DNS
.set_dns_server = lwip_netdev_set_dns_server,
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
.set_dhcp = lwip_netdev_set_dhcp,
#endif
.set_default = lwip_netdev_set_default,
@ -180,9 +181,9 @@ int lwip_netdev_add(struct netif* lwip_netif)
netdev->ops = &lwip_netdev_ops;
netdev->hwaddr_len = lwip_netif->hwaddr_len;
memcpy(netdev->hwaddr, lwip_netif->hwaddr, lwip_netif->hwaddr_len);
netdev->ip_addr = lwip_netif->ip_addr;
netdev->gw = lwip_netif->gw;
netdev->netmask = lwip_netif->netmask;
netdev->ip_addr = &lwip_netif->ip_addr;
netdev->gw = &lwip_netif->gw;
netdev->netmask = &lwip_netif->netmask;
return result;
}

261
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/.defconfig Normal file
View File

@ -0,0 +1,261 @@
#
# Automatically generated file; DO NOT EDIT.
# XiZi_IIoT Project Configuration
#
CONFIG_BOARD_EDU_ARM32_EVB=y
CONFIG_ARCH_ARM=y
#
# hc32f4a0 feature
#
CONFIG_BSP_USING_UART=y
CONFIG_BSP_USING_UART3=y
CONFIG_SERIAL_BUS_NAME_3="usart3"
CONFIG_SERIAL_DRV_NAME_3="usart3_drv"
CONFIG_SERIAL_3_DEVICE_NAME_0="usart3_dev3"
CONFIG_BSP_USING_UART6=y
CONFIG_SERIAL_BUS_NAME_6="usart6"
CONFIG_SERIAL_DRV_NAME_6="usart6_drv"
CONFIG_SERIAL_6_DEVICE_NAME_0="usart6_dev6"
#
# config default board resources
#
#
# config board app name
#
CONFIG_BOARD_APP_NAME="/XiUOS_edu_arm32_app.bin"
#
# Hardware feature
#
CONFIG_RESOURCES_SERIAL=y
CONFIG_SERIAL_USING_DMA=y
CONFIG_SERIAL_RB_BUFSZ=128
#
# Kernel feature
#
#
# separate compile(choose none for compile once)
#
# CONFIG_SEPARATE_COMPILE is not set
# CONFIG_COMPILER_APP is not set
# CONFIG_APP_STARTUP_FROM_SDCARD is not set
CONFIG_APP_STARTUP_FROM_FLASH=y
# CONFIG_COMPILER_KERNEL is not set
#
# Memory Management
#
# CONFIG_KERNEL_MEMBLOCK is not set
CONFIG_MEM_ALIGN_SIZE=8
# CONFIG_MEM_EXTERN_SRAM is not set
CONFIG_MM_PAGE_SIZE=4096
#
# Using small memory allocator
#
CONFIG_KERNEL_SMALL_MEM_ALLOC=y
CONFIG_SMALL_NUMBER_32B=64
CONFIG_SMALL_NUMBER_64B=32
#
# Task feature
#
CONFIG_USER_APPLICATION=y
# CONFIG_TASK_ISOLATION is not set
#
# Inter-Task communication
#
CONFIG_KERNEL_SEMAPHORE=y
CONFIG_KERNEL_MUTEX=y
CONFIG_KERNEL_EVENT=y
CONFIG_KERNEL_MESSAGEQUEUE=y
CONFIG_KERNEL_SOFTTIMER=y
CONFIG_SCHED_POLICY_RR_REMAINSLICE=y
# CONFIG_SCHED_POLICY_RR is not set
# CONFIG_SCHED_POLICY_FIFO is not set
# CONFIG_KTASK_PRIORITY_8 is not set
CONFIG_KTASK_PRIORITY_32=y
# CONFIG_KTASK_PRIORITY_256 is not set
CONFIG_KTASK_PRIORITY_MAX=32
CONFIG_TICK_PER_SECOND=1000
CONFIG_KERNEL_STACK_OVERFLOW_CHECK=y
CONFIG_IDLE_KTASK_STACKSIZE=1024
CONFIG_ZOMBIE_KTASK_STACKSIZE=2048
#
# Kernel Console
#
CONFIG_KERNEL_CONSOLE=y
CONFIG_KERNEL_BANNER=y
CONFIG_KERNEL_CONSOLEBUF_SIZE=128
#
# Kernel Hook
#
# CONFIG_KERNEL_HOOK is not set
#
# Command shell
#
CONFIG_TOOL_SHELL=y
CONFIG_SHELL_ENTER_CR=y
CONFIG_SHELL_ENTER_LF=y
CONFIG_SHELL_ENTER_CR_AND_LF=y
# CONFIG_SHELL_ENTER_CRLF is not set
#
# Set shell user control
#
CONFIG_SHELL_DEFAULT_USER="letter"
CONFIG_SHELL_DEFAULT_USER_PASSWORD=""
CONFIG_SHELL_LOCK_TIMEOUT=10000
#
# Set shell config param
#
CONFIG_SHELL_TASK_STACK_SIZE=4096
CONFIG_SHELL_TASK_PRIORITY=20
CONFIG_SHELL_MAX_NUMBER=5
CONFIG_SHELL_PARAMETER_MAX_NUMBER=8
CONFIG_SHELL_HISTORY_MAX_NUMBER=5
CONFIG_SHELL_PRINT_BUFFER=128
CONFIG_SHELL_HELP_SHOW_PERMISSION=y
# CONFIG_SHELL_HELP_LIST_USER is not set
CONFIG_SHELL_HELP_LIST_VAR=y
# CONFIG_SHELL_HELP_LIST_KEY is not set
#
# Kernel data structure Manage
#
CONFIG_KERNEL_QUEUEMANAGE=y
CONFIG_KERNEL_WORKQUEUE=y
CONFIG_WORKQUEUE_KTASK_STACKSIZE=2048
CONFIG_WORKQUEUE_KTASK_PRIORITY=23
CONFIG_QUEUE_MAX=16
CONFIG_KERNEL_WAITQUEUE=y
CONFIG_KERNEL_DATAQUEUE=y
# CONFIG_KERNEL_CIRCULAR_AREA is not set
# CONFIG_KERNEL_AVL_TREE is not set
#
# Kernel components init
#
CONFIG_KERNEL_COMPONENTS_INIT=y
CONFIG_ENV_INIT_KTASK_STACK_SIZE=2048
CONFIG_KERNEL_USER_MAIN=y
CONFIG_NAME_NUM_MAX=32
# CONFIG_KERNEL_DEBUG is not set
# CONFIG_ARCH_SMP is not set
#
# hash table config
#
CONFIG_ID_HTABLE_SIZE=16
CONFIG_ID_NUM_MAX=128
# CONFIG_KERNEL_TEST is not set
#
# Lib
#
CONFIG_LIB=y
CONFIG_LIB_POSIX=y
CONFIG_LIB_NEWLIB=y
# CONFIG_LIB_MUSLLIB is not set
#
# C++ features
#
# CONFIG_LIB_CPLUSPLUS is not set
#
# File system
#
CONFIG_FS_VFS=y
CONFIG_VFS_USING_WORKDIR=y
CONFIG_FS_VFS_DEVFS=y
CONFIG_FS_VFS_FATFS=y
# CONFIG_FS_CH376 is not set
# CONFIG_FS_LWEXT4 is not set
#
# APP_Framework
#
#
# Framework
#
CONFIG_TRANSFORM_LAYER_ATTRIUBUTE=y
CONFIG_ADD_XIZI_FEATURES=y
# CONFIG_ADD_NUTTX_FEATURES is not set
# CONFIG_ADD_RTTHREAD_FEATURES is not set
# CONFIG_SUPPORT_SENSOR_FRAMEWORK is not set
# CONFIG_SUPPORT_CONNECTION_FRAMEWORK is not set
# CONFIG_SUPPORT_KNOWING_FRAMEWORK is not set
# CONFIG_SUPPORT_CONTROL_FRAMEWORK is not set
#
# Security
#
# CONFIG_CRYPTO is not set
#
# Applications
#
#
# config stack size and priority of main task
#
CONFIG_MAIN_KTASK_STACK_SIZE=1024
CONFIG_MAIN_KTASK_PRIORITY=16
#
# ota app
#
# CONFIG_APPLICATION_OTA is not set
#
# test app
#
# CONFIG_USER_TEST is not set
#
# connection app
#
# CONFIG_APPLICATION_CONNECTION is not set
#
# control app
#
#
# knowing app
#
# CONFIG_APPLICATION_KNOWING is not set
#
# sensor app
#
# CONFIG_APPLICATION_SENSOR is not set
# CONFIG_USING_EMBEDDED_DATABASE_APP is not set
# CONFIG_APP_USING_WEBNET is not set
#
# lib
#
CONFIG_APP_SELECT_NEWLIB=y
# CONFIG_APP_SELECT_OTHER_LIB is not set
# CONFIG_LIB_USING_CJSON is not set
# CONFIG_LIB_USING_QUEUE is not set
# CONFIG_LIB_LV is not set
#
# LVGL configuration
#
# CONFIG_LV_CONF_MINIMAL is not set
# CONFIG_USING_EMBEDDED_DATABASE is not set

4
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/config.mk
View File

@ -15,4 +15,8 @@ ifeq ($(CONFIG_RESOURCES_LWIP), y)
export LINK_LWIP := $(KERNEL_ROOT)/resources/ethernet/LwIP/liblwip.a
endif
ifeq ($(CONFIG_USE_MONGOOSE), y)
export LINK_MONGOOSE := $(KERNEL_ROOT)/../../APP_Framework/Applications/mongoose/mongoose.a
endif
export ARCH = arm

13
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/adc/Kconfig Normal file
View File

@ -0,0 +1,13 @@
if BSP_USING_ADC
config ADC1_BUS_NAME
string "adc 1 bus name"
default "adc1"
config ADC1_DRIVER_NAME
string "adc 1 driver name"
default "adc1_drv"
config ADC1_DEVICE_NAME
string "adc 1 bus device name"
default "adc1_dev"
endif

3
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/adc/Makefile Normal file
View File

@ -0,0 +1,3 @@
SRC_FILES := connect_adc.c
include $(KERNEL_ROOT)/compiler.mk

370
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/adc/connect_adc.c Normal file
View File

@ -0,0 +1,370 @@
/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_adc.c
* @brief support to register ADC pointer and function
* @version 1.1
* @author AIIT XUOS Lab
* @date 2023-02-09
*/
#include <connect_adc.h>
/*******************************************************************************
* Local pre-processor symbols/macros ('#define')
******************************************************************************/
/* The clock source of ADC. */
#define ADC_CLK_SYS_CLK (1U)
#define ADC_CLK_PLLH (2U)
#define ADC_CLK_PLLA (3U)
/*
* Selects a clock source according to the application requirements.
* PCLK4 is the clock for digital interface.
* PCLK2 is the clock for analog circuit.
* PCLK4 and PCLK2 are synchronous when the clock source is PLL.
* PCLK4 : PCLK2 = 1:1, 2:1, 4:1, 8:1, 1:2, 1:4.
* PCLK2 is in range [1MHz, 60MHz].
* If the system clock is selected as the ADC clock, macro 'ADC_ADC_CLK' can only be defined as 'CLK_PERIPHCLK_PCLK'.
* If PLLH is selected as the ADC clock, macro 'ADC_ADC_CLK' can be defined as 'CLK_PERIPHCLK_PLLx'(x=Q, R).
* If PLLA is selected as the ADC clock, macro 'ADC_ADC_CLK' can be defined as 'CLK_PERIPHCLK_PLLXx'(x=P, Q, R).
*/
#define ADC_CLK_SEL (ADC_CLK_SYS_CLK)
#if (ADC_CLK_SEL == ADC_CLK_SYS_CLK)
#define ADC_CLK (CLK_PERIPHCLK_PCLK)
#elif (ADC_CLK_SEL == ADC_CLK_PLLH)
#define ADC_CLK (CLK_PERIPHCLK_PLLQ)
#elif (ADC_CLK_SEL == ADC_CLK_PLLA)
#define ADC_CLK (CLK_PERIPHCLK_PLLXP)
#else
#error "The clock source your selected does not exist!!!"
#endif
/* ADC unit instance for this example. */
#define ADC_UNIT (CM_ADC1)
#define ADC_PERIPH_CLK (FCG3_PERIPH_ADC1)
/* Selects ADC channels that needed. */
#define ADC_CH_POTENTIOMETER (ADC_CH3)
#define ADC_CH (ADC_CH_POTENTIOMETER)
#define ADC_CH_PORT (GPIO_PORT_A)
#define ADC_CH_PIN (GPIO_PIN_03)
/* ADC sequence to be used. */
#define ADC_SEQ (ADC_SEQ_A)
/* Flag of conversion end. */
#define ADC_EOC_FLAG (ADC_FLAG_EOCA)
/* ADC reference voltage. The voltage of pin VREFH. */
#define ADC_VREF (3.3F)
/* ADC accuracy(according to the resolution of ADC). */
#define ADC_ACCURACY (1UL << 12U)
/* Calculate the voltage(mV). */
#define ADC_CAL_VOL(adcVal) (uint16_t)((((float32_t)(adcVal) * ADC_VREF) / ((float32_t)ADC_ACCURACY)) * 1000.F)
/* Timeout value. */
#define ADC_TIMEOUT_VAL (1000U)
/**
* @brief Set specified ADC pin to analog mode.
* @param None
* @retval None
*/
static void AdcSetPinAnalogMode(void)
{
stc_gpio_init_t stcGpioInit;
(void)GPIO_StructInit(&stcGpioInit);
stcGpioInit.u16PinAttr = PIN_ATTR_ANALOG;
(void)GPIO_Init(ADC_CH_PORT, ADC_CH_PIN, &stcGpioInit);
}
/**
* @brief Configures ADC clock.
* @param None
* @retval None
*/
static void AdcClockConfig(void)
{
#if (ADC_CLK_SEL == ADC_CLK_SYS_CLK)
/*
* 1. Configures the clock divider of PCLK2 and PCLK4 here or in the function of configuring the system clock.
* In this example, the system clock is MRC@8MHz.
* PCLK4 is the digital interface clock, and PCLK2 is the analog circuit clock.
* Make sure that PCLK2 and PCLK4 meet the following conditions:
* PCLK4 : PCLK2 = 1:1, 2:1, 4:1, 8:1, 1:2, 1:4.
* PCLK2 is in range [1MHz, 60MHz].
*/
CLK_SetClockDiv((CLK_BUS_PCLK2 | CLK_BUS_PCLK4), (CLK_PCLK2_DIV8 | CLK_PCLK4_DIV2));
#elif (ADC_CLK_SEL == ADC_CLK_PLLH)
/*
* 1. Configures PLLH and the divider of PLLHx(x=Q, R).
* PLLHx(x=Q, R) is used as both the digital interface clock and the analog circuit clock.
* PLLHx(x=Q, R) must be in range [1MHz, 60MHz] for ADC use.
* The input source of PLLH is XTAL(8MHz).
*/
stc_clock_pll_init_t stcPLLHInit;
stc_clock_xtal_init_t stcXtalInit;
/* Configures XTAL. PLLH input source is XTAL. */
(void)CLK_XtalStructInit(&stcXtalInit);
stcXtalInit.u8State = CLK_XTAL_ON;
stcXtalInit.u8Drv = CLK_XTAL_DRV_ULOW;
stcXtalInit.u8Mode = CLK_XTAL_MD_OSC;
stcXtalInit.u8StableTime = CLK_XTAL_STB_499US;
(void)CLK_XtalInit(&stcXtalInit);
(void)CLK_PLLStructInit(&stcPLLHInit);
/*
* PLLHx(x=Q, R) = ((PLL_source / PLLM) * PLLN) / PLLx
* PLLHQ = (8 / 1) * 80 /16 = 40MHz
* PLLHR = (8 / 1) * 80 /16 = 40MHz
*/
stcPLLHInit.u8PLLState = CLK_PLL_ON;
stcPLLHInit.PLLCFGR = 0UL;
stcPLLHInit.PLLCFGR_f.PLLM = (1UL - 1UL);
stcPLLHInit.PLLCFGR_f.PLLN = (80UL - 1UL);
stcPLLHInit.PLLCFGR_f.PLLP = (4UL - 1UL);
stcPLLHInit.PLLCFGR_f.PLLQ = (16UL - 1UL);
stcPLLHInit.PLLCFGR_f.PLLR = (16UL - 1UL);
/* stcPLLHInit.PLLCFGR_f.PLLSRC = CLK_PLL_SRC_XTAL; */
(void)CLK_PLLInit(&stcPLLHInit);
#elif (ADC_CLK_SEL == ADC_CLK_PLLA)
/*
* 1. Configures PLLA and the divider of PLLAx(x=P, Q, R).
* PLLAx(x=P, Q, R) is used as both the digital interface clock and the analog circuit clock.
* PLLAx(x=P, Q, R) must be in range [1MHz, 60MHz] for ADC use.
* The input source of PLLA is HRC(16MHz).
*/
stc_clock_pllx_init_t stcPLLAInit;
/* Enable HRC(16MHz) for PLLA. */
CLK_HrcCmd(ENABLE);
/* Specify the input source of PLLA. NOTE!!! PLLA and PLLH use the same input source. */
CLK_SetPLLSrc(CLK_PLL_SRC_HRC);
/* PLLA configuration */
(void)CLK_PLLxStructInit(&stcPLLAInit);
/*
* PLLAx(x=P, Q, R) = ((PLL_source / PLLM) * PLLN) / PLLx
* PLLAP = (16 / 2) * 40 / 8 = 40MHz
* PLLAQ = (16 / 2) * 40 / 10 = 32MHz
* PLLAR = (16 / 2) * 40 / 16 = 20MHz
*/
stcPLLAInit.u8PLLState = CLK_PLLX_ON;
stcPLLAInit.PLLCFGR = 0UL;
stcPLLAInit.PLLCFGR_f.PLLM = (2UL - 1UL);
stcPLLAInit.PLLCFGR_f.PLLN = (40UL - 1UL);
stcPLLAInit.PLLCFGR_f.PLLR = (8UL - 1UL);
stcPLLAInit.PLLCFGR_f.PLLQ = (10UL - 1UL);
stcPLLAInit.PLLCFGR_f.PLLP = (16UL - 1UL);
(void)CLK_PLLxInit(&stcPLLAInit);
#endif
/* 2. Specifies the clock source of ADC. */
CLK_SetPeriClockSrc(ADC_CLK);
}
/**
* @brief Initializes ADC.
* @param None
* @retval None
*/
static void AdcInitConfig(void)
{
stc_adc_init_t stcAdcInit;
/* 1. Enable ADC peripheral clock. */
FCG_Fcg3PeriphClockCmd(ADC_PERIPH_CLK, ENABLE);
/* 2. Modify the default value depends on the application. Not needed here. */
(void)ADC_StructInit(&stcAdcInit);
/* 3. Initializes ADC. */
(void)ADC_Init(ADC_UNIT, &stcAdcInit);
/* 4. ADC channel configuration. */
/* 4.1 Set the ADC pin to analog input mode. */
AdcSetPinAnalogMode();
/* 4.2 Enable ADC channels. Call ADC_ChCmd() again to enable more channels if needed. */
ADC_ChCmd(ADC_UNIT, ADC_SEQ, ADC_CH, ENABLE);
/* 5. Conversion data average calculation function, if needed.
Call ADC_ConvDataAverageChCmd() again to enable more average channels if needed. */
ADC_ConvDataAverageConfig(ADC_UNIT, ADC_AVG_CNT8);
ADC_ConvDataAverageChCmd(ADC_UNIT, ADC_CH, ENABLE);
}
/**
* @brief Use ADC in polling mode.
* @param None
* @retval uint16_t u16AdcValue
*/
static uint16_t AdcPolling(void)
{
uint16_t u16AdcValue = 0;
int32_t iRet = LL_ERR;
__IO uint32_t u32TimeCount = 0UL;
/* Can ONLY start sequence A conversion.
Sequence B needs hardware trigger to start conversion. */
ADC_Start(ADC_UNIT);
do {
if (ADC_GetStatus(ADC_UNIT, ADC_EOC_FLAG) == SET) {
ADC_ClearStatus(ADC_UNIT, ADC_EOC_FLAG);
iRet = LL_OK;
break;
}
} while (u32TimeCount++ < ADC_TIMEOUT_VAL);
if (iRet == LL_OK) {
/* Get any ADC value of sequence A channel that needed. */
u16AdcValue = ADC_GetValue(ADC_UNIT, ADC_CH);
KPrintf("The ADC value of potentiometer is %u, voltage is %u mV\r\n",
u16AdcValue, ADC_CAL_VOL(u16AdcValue));
} else {
ADC_Stop(ADC_UNIT);
KPrintf("ADC exception.\r\n");
}
return ADC_CAL_VOL(u16AdcValue);
}
static uint32 AdcOpen(void *dev)
{
x_err_t ret = EOK;
struct AdcHardwareDevice* adc_dev = (struct AdcHardwareDevice*)dev;
AdcClockConfig();
AdcInitConfig();
return ret;
}
static uint32 AdcClose(void *dev)
{
struct AdcHardwareDevice* adc_dev = (struct AdcHardwareDevice*)dev;
CM_ADC_TypeDef *ADCx= (CM_ADC_TypeDef *)adc_dev->private_data;
ADC_Stop(ADC_UNIT);
ADC_DeInit(ADCx);
return EOK;
}
static uint32 AdcRead(void *dev, struct BusBlockReadParam *read_param)
{
*(uint16 *)read_param->buffer = AdcPolling();
read_param->read_length = 2;
return EOK;
}
static uint32 AdcDrvConfigure(void *drv, struct BusConfigureInfo *configure_info)
{
NULL_PARAM_CHECK(drv);
NULL_PARAM_CHECK(configure_info);
x_err_t ret = EOK;
uint8 adc_channel;
struct AdcDriver *adc_drv = (struct AdcDriver *)drv;
struct AdcHardwareDevice *adc_dev = (struct AdcHardwareDevice *)adc_drv->driver.owner_bus->owner_haldev;
struct HwAdc *adc_cfg = (struct HwAdc *)adc_dev->haldev.private_data;
switch (configure_info->configure_cmd)
{
case OPE_CFG:
adc_cfg->adc_channel = *(uint8 *)configure_info->private_data;
if (adc_cfg->adc_channel != 1) {
KPrintf("AdcDrvConfigure set adc channel(1) %u error!", adc_cfg->adc_channel);
adc_cfg->adc_channel = 1;
ret = ERROR;
}
break;
default:
break;
}
return ret;
}
static const struct AdcDevDone dev_done =
{
AdcOpen,
AdcClose,
NONE,
AdcRead,
};
int HwAdcInit(void)
{
x_err_t ret = EOK;
#ifdef BSP_USING_ADC
static struct AdcBus adc1_bus;
static struct AdcDriver adc1_drv;
static struct AdcHardwareDevice adc1_dev;
static struct HwAdc adc1_cfg;
adc1_drv.configure = AdcDrvConfigure;
ret = AdcBusInit(&adc1_bus, ADC1_BUS_NAME);
if (ret != EOK) {
KPrintf("ADC1 bus init error %d\n", ret);
return ERROR;
}
ret = AdcDriverInit(&adc1_drv, ADC1_DRIVER_NAME);
if (ret != EOK) {
KPrintf("ADC1 driver init error %d\n", ret);
return ERROR;
}
ret = AdcDriverAttachToBus(ADC1_DRIVER_NAME, ADC1_BUS_NAME);
if (ret != EOK) {
KPrintf("ADC1 driver attach error %d\n", ret);
return ERROR;
}
adc1_dev.adc_dev_done = &dev_done;
adc1_cfg.ADCx = CM_ADC1;
adc1_cfg.adc_channel = 1;
ret = AdcDeviceRegister(&adc1_dev, (void *)&adc1_cfg, ADC1_DEVICE_NAME);
if (ret != EOK) {
KPrintf("ADC1 device register error %d\n", ret);
return ERROR;
}
ret = AdcDeviceAttachToBus(ADC1_DEVICE_NAME, ADC1_BUS_NAME);
if (ret != EOK) {
KPrintf("ADC1 device register error %d\n", ret);
return ERROR;
}
#endif
return ret;
}

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config CAN_BUS_NAME_2
string "can bus name"
default "can2"
config CAN_DRIVER_NAME_2
string "can driver name"
default "can2_drv"
config CAN_2_DEVICE_NAME_1
string "can bus 1 device 1 name"
default "can2_dev1"
config CAN_USING_INTERRUPT
bool "can interrupt open"
default n

4
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/can/Makefile Normal file
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SRC_FILES := connect_can.c
include $(KERNEL_ROOT)/compiler.mk

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Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/can/connect_can.c Normal file
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/*
* Copyright (c) Guangzhou Xingyi Electronic Technology Co., Ltd
*
* Change Logs:
* Date Author Notes
* 2014-7-4 alientek first version
*/
/**
* @file connect_can.c
* @brief support hc32f4a0 can function and register to bus framework
* @version 1.0
* @author AIIT XUOS Lab
* @date 2023-02-20
*/
/*************************************************
File name: connect_can.c
Description: support can configure and spi bus register function for hc32f4a0
Others: connect_can.c for references
*************************************************/
#include "connect_can.h"
#define CAN_X (CM_CAN2)
#define CAN_TX_PORT (GPIO_PORT_D)
#define CAN_TX_PIN (GPIO_PIN_07)
#define CAN_RX_PORT (GPIO_PORT_D)
#define CAN_RX_PIN (GPIO_PIN_06)
#define CAN_TX_PIN_FUNC (GPIO_FUNC_62)
#define CAN_RX_PIN_FUNC (GPIO_FUNC_63)
#define INTSEL_REG ((uint32_t)(&CM_INTC->SEL0))
#define CANX_IRQ_SRC INT_SRC_CAN2_HOST
#define CANX_IRQ_NUM 17
#define IRQ_NUM_OFFSET 16
#define CAN_AF1_ID (0x123UL)
#define CAN_AF1_ID_MSK (0xFFFUL)
#define CAN_AF1_MSK_TYPE CAN_ID_STD
#define CAN_AF2_ID (0x005UL)
#define CAN_AF2_ID_MSK (0x00FUL)
#define CAN_AF2_MSK_TYPE CAN_ID_STD
#define CAN_AF3_ID (0x23UL)
#define CAN_AF3_ID_MSK (0xFFUL)
#define CAN_AF3_MSK_TYPE CAN_ID_STD
#ifdef CAN_USING_INTERRUPT
void CanIrqHandler(int vector, void *param)
{
stc_can_error_info_t err_info;
uint32_t status = CAN_GetStatusValue(CAN_X);
uint32_t error = CAN_GetErrorInfo(CAN_X,&err_info);
KPrintf("Irq entered\n");
CAN_ClearStatus(CAN_X, status);
}
static void CanIrqConfig(void)
{
// register IRQ src in IRQn
__IO uint32_t *INTC_SELx = (__IO uint32_t *)(INTSEL_REG+ 4U * (uint32_t)(CANX_IRQ_NUM));
WRITE_REG32(*INTC_SELx, CANX_IRQ_SRC);
isrManager.done->registerIrq(CANX_IRQ_NUM+IRQ_NUM_OFFSET,CanIrqHandler,NULL);
isrManager.done->enableIrq(CANX_IRQ_NUM);
}
#endif
static void CanInit(struct CanDriverConfigure *can_drv_config)
{
stc_can_init_t stcInit;
stc_can_filter_config_t astcAFCfg[] = { \
{CAN_AF1_ID, CAN_AF1_ID_MSK, CAN_AF1_MSK_TYPE}, \
{CAN_AF2_ID, CAN_AF2_ID_MSK, CAN_AF2_MSK_TYPE}, \
{CAN_AF3_ID, CAN_AF3_ID_MSK, CAN_AF3_MSK_TYPE}, \
};
CLK_SetCANClockSrc(CLK_CAN2,CLK_CANCLK_SYSCLK_DIV4);
/* Set the function of CAN pins. */
GPIO_SetFunc(CAN_TX_PORT, CAN_TX_PIN, CAN_TX_PIN_FUNC);
GPIO_SetFunc(CAN_RX_PORT, CAN_RX_PIN, CAN_RX_PIN_FUNC);
/* Initializes CAN. */
(void)CAN_StructInit(&stcInit);
stcInit.pstcFilter = astcAFCfg;
stcInit.u16FilterSelect = (CAN_FILTER1 | CAN_FILTER2 | CAN_FILTER3);
// Driver's config
stcInit.stcBitCfg.u32SJW = can_drv_config->tsjw;
stcInit.stcBitCfg.u32Prescaler = can_drv_config->brp;
stcInit.stcBitCfg.u32TimeSeg1 = can_drv_config->tbs1;
stcInit.stcBitCfg.u32TimeSeg2 = can_drv_config->tbs2;
stcInit.u8WorkMode = can_drv_config->mode;
#ifdef CAN_USING_FD
stcInit.stcFDCfg.u8TDCSSP = 16U;
stcInit.stcFDCfg.u8CANFDMode = CAN_FD_MODE_ISO_11898;
stcInit.stcFDCfg.stcFBT.u32SEG1 = 16U;
stcInit.stcFDCfg.stcFBT.u32SEG2 = 4U;
stcInit.stcFDCfg.stcFBT.u32SJW = 4U;
stcInit.stcFDCfg.stcFBT.u32Prescaler = 1U;
(void)CAN_FD_Init(APP_CAN_UNIT, &stcInit);
#else
FCG_Fcg1PeriphClockCmd(PWC_FCG1_CAN2, ENABLE);
(void)CAN_Init(CAN_X, &stcInit);
#endif
CAN_ClearStatus(CAN_X, 0xFFFFFFFFU);
#ifdef CAN_USING_INTERRUPT
/* Configures the interrupts if needed. */
CAN_IntCmd(CAN_X, CAN_INT_RX, ENABLE);
CanIrqConfig();
#endif
}
static uint32 CanConfig(void *can_drv_config)
{
x_err_t ret = EOK;
return ret;
}
static uint32 CanDrvConfigure(void *drv, struct BusConfigureInfo *configure_info)
{
x_err_t ret = EOK;
NULL_PARAM_CHECK(drv);
NULL_PARAM_CHECK(configure_info);
struct CanDriverConfigure *can_drv_config;
switch (configure_info->configure_cmd)
{
case OPE_INT: // can basic init
can_drv_config = (struct CanDriverConfigure *)configure_info->private_data;
CanInit(can_drv_config);
break;
case OPE_CFG:
CanConfig(configure_info->private_data);
break;
default:
break;
}
return ret;
}
static uint32 CanWriteData(void * dev , struct BusBlockWriteParam *write_param)
{
x_err_t ret=EOK;
NULL_PARAM_CHECK(dev);
NULL_PARAM_CHECK(write_param);
struct CanSendConfigure *p_can_config = (struct CanSendConfigure*)write_param->buffer;
stc_can_tx_frame_t can_frame_obj;
memset(&can_frame_obj,0,sizeof(stc_can_tx_frame_t));
// configure CAN's flag bit
can_frame_obj.IDE = p_can_config->ide;
if(1==p_can_config->ide){
can_frame_obj.u32ID = p_can_config->exdid;
}else{
can_frame_obj.u32ID = p_can_config->stdid;
}
can_frame_obj.RTR = p_can_config->rtr;
memcpy(can_frame_obj.au8Data,p_can_config->data,p_can_config->data_lenth);
can_frame_obj.DLC = p_can_config->data_lenth;
//put frame_buffer in message queue
if(can_frame_obj.DLC){
ret = CAN_FillTxFrame(CAN_X,CAN_TX_BUF_STB,&can_frame_obj);
if(EOK != ret){
KPrintf("CAN fill tx frame failed(CODE:%d)!\n",ret);
return ERROR;
}
CAN_StartTx(CAN_X,CAN_TX_REQ_STB_ONE);
}
return ret;
}
static uint32 CanReadData(void *dev , struct BusBlockReadParam *databuf)
{
NULL_PARAM_CHECK(dev);
NULL_PARAM_CHECK(databuf);
x_err_t ret=EOK;
stc_can_rx_frame_t frame_received;
struct CanSendConfigure *p_can_config = (struct CanSendConfigure*)databuf->buffer;
memset(&frame_received,0,sizeof(stc_can_rx_frame_t));
ret = CAN_GetRxFrame(CAN_X, &frame_received);
if(EOK != ret){
// KPrintf("CAN recv frame failed(CODE:%d)!\n",ret);
p_can_config->data_lenth = 0;
return ERROR;
}
//put message in frame_buffer
p_can_config->ide = frame_received.IDE;
p_can_config->rtr = frame_received.RTR;
if(p_can_config->ide==1){
p_can_config->exdid = frame_received.u32ID ;
}else{
p_can_config->stdid = frame_received.u32ID;
p_can_config->exdid = frame_received.u32ID ;
}
p_can_config->data_lenth = frame_received.DLC;
for(int i=0;i<p_can_config->data_lenth;i++){
p_can_config->data[i] = frame_received.au8Data[i];
}
return frame_received.DLC;
}
static struct CanDevDone can_dev_done =
{
.open = NONE,
.close = NONE,
.write = CanWriteData,
.read = CanReadData
};
static int BoardCanBusInit(struct CanBus *can_bus, struct CanDriver *can_driver)
{
x_err_t ret = EOK;
/*Init the can bus */
ret = CanBusInit(can_bus, CAN_BUS_NAME_2);
if (EOK != ret) {
KPrintf("Board_can_init canBusInit error %d\n", ret);
return ERROR;
}
/*Init the can driver*/
ret = CanDriverInit(can_driver, CAN_DRIVER_NAME_2);
if (EOK != ret) {
KPrintf("Board_can_init canDriverInit error %d\n", ret);
return ERROR;
}
/*Attach the can driver to the can bus*/
ret = CanDriverAttachToBus(CAN_DRIVER_NAME_2, CAN_BUS_NAME_2);
if (EOK != ret) {
KPrintf("Board_can_init CanDriverAttachToBus error %d\n", ret);
return ERROR;
}
return ret;
}
/* Attach the can device to the can bus*/
static int BoardCanDevBend(void)
{
x_err_t ret = EOK;
static struct CanHardwareDevice can_device0;
memset(&can_device0, 0, sizeof(struct CanHardwareDevice));
can_device0.dev_done = &can_dev_done;
ret = CanDeviceRegister(&can_device0, NONE, CAN_2_DEVICE_NAME_1);
if (EOK != ret) {
KPrintf("board_can_init CanDeviceInit device %s error %d\n", CAN_2_DEVICE_NAME_1, ret);
return ERROR;
}
ret = CanDeviceAttachToBus(CAN_2_DEVICE_NAME_1, CAN_BUS_NAME_2);
if (EOK != ret) {
KPrintf("board_can_init CanDeviceAttachToBus device %s error %d\n", CAN_2_DEVICE_NAME_1, ret);
return ERROR;
}
return ret;
}
int HwCanInit(void)
{
x_err_t ret = EOK;
static struct CanBus can_bus;
memset(&can_bus, 0, sizeof(struct CanBus));
static struct CanDriver can_driver;
memset(&can_driver, 0, sizeof(struct CanDriver));
can_driver.configure = &(CanDrvConfigure);
ret = BoardCanBusInit(&can_bus, &can_driver);
if (EOK != ret) {
KPrintf(" can_bus_init %s error ret %u\n", CAN_BUS_NAME_2, ret);
return ERROR;
}
ret = BoardCanDevBend();
if (EOK != ret) {
KPrintf("board_can_init error ret %u\n", ret);
return ERROR;
}
return EOK;
}

17
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/dac/Kconfig Normal file
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if BSP_USING_DAC
config DAC_BUS_NAME
string "dac bus name"
default "dac"
config DAC_DRIVER_NAME
string "dac driver name"
default "dac_drv"
config DAC_DEVICE_NAME
string "dac bus device name"
default "dac_dev"
config DAC_GPIO_NUM
int "dac gpio pin num(only support 4 or 5)"
default "4"
endif

3
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/dac/Makefile Normal file
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SRC_FILES := connect_dac.c
include $(KERNEL_ROOT)/compiler.mk

398
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/dac/connect_dac.c Normal file
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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_dac.c
* @brief support to register DAC pointer and function
* @version 2.0
* @author AIIT XUOS Lab
* @date 2023-02-09
*/
#include <connect_dac.h>
/*******************************************************************************
* Local pre-processor symbols/macros ('#define')
******************************************************************************/
#define DAC_UNIT1_PORT (GPIO_PORT_A)
#define DAC_UNIT1_CHN1_PIN (GPIO_PIN_04)
#define VREFH (3.3F)
#define DAC_CHN1 (0U)
#define DAC_CHN2 (1U)
#define DAC_DATA_ALIGN_12b_R (0U)
#define DAC_DATA_ALIGN_12b_L (1U)
#define SUPPORT_AMP
#define SUPPORT_ADP
#define SINGLE_WAVE_DAC_CHN (DAC_CHN1)
#define DAC_DATA_ALIGN (DAC_DATA_ALIGN_12b_L)
#define SINE_DOT_NUMBER (4096U)
#define SINE_NEGATIVE_TO_POSITVE (1.0F)
/*******************************************************************************
* Local type definitions ('typedef')
******************************************************************************/
typedef enum {
DAC_Unit1,
DAC_Unit2,
DAC_Unit_Max,
}en_dac_unit_t;
typedef enum {
E_Dac_Single,
E_Dac_Dual,
}en_dac_cvt_t;
typedef struct {
CM_DAC_TypeDef *pUnit;
en_dac_cvt_t enCvtType;
uint16_t u16Ch;
} stc_dac_handle_t;
/*******************************************************************************
* Local variable definitions ('static')
******************************************************************************/
static stc_dac_handle_t m_stcDACHandle[DAC_Unit_Max] = {0};
static uint32_t gu32SinTable[SINE_DOT_NUMBER];
static stc_dac_handle_t *pSingleDac;
/*******************************************************************************
* Function implementation - global ('extern') and local ('static')
******************************************************************************/
/**
* @brief MAU Initialization
* @param None
* @retval None
*/
static void MauInit(void)
{
/* Enable MAU peripheral clock. */
FCG_Fcg0PeriphClockCmd(PWC_FCG0_MAU, ENABLE);
}
/**
* @brief MAU De-Initialization
* @param None
* @retval None
*/
static void MauDeinit(void)
{
/* Enable MAU peripheral clock. */
FCG_Fcg0PeriphClockCmd(PWC_FCG0_MAU, DISABLE);
}
/**
* @brief Sin table Initialization
* @param [in] pSinTable sin table
* @param [in] u32count number of pSinTable items
* @retval None
*/
static void SinTableInit(uint32_t pSinTable[], uint32_t u32count)
{
uint32_t i;
uint32_t u32AngAvg = (uint32_t)(float32_t)((float32_t)((float32_t)MAU_SIN_ANGIDX_TOTAL / (float32_t)u32count) + 0.5);
float32_t fSin;
for (i = 0U; i < u32count; i++) {
fSin = (((float32_t)MAU_Sin(CM_MAU, (uint16_t)(u32AngAvg * i))
/ (float32_t)MAU_SIN_Q15_SCALAR + SINE_NEGATIVE_TO_POSITVE) / VREFH) *
(float32_t)DAC_DATAREG_VALUE_MAX + 0.5F;
#if (DAC_DATA_ALIGN == DAC_DATA_ALIGN_12b_L)
{
pSinTable[i] = (uint32_t)fSin << 4;
}
#else
{
pSinTable[i] = (uint32_t)fSin;
}
#endif
}
}
/**
* @brief Enable DAC peripheral clock
* @param [in] enUnit The selected DAC unit
* @retval None
*/
static void DacPClkEnable(en_dac_unit_t enUnit)
{
uint32_t u32PClk;
switch (enUnit) {
case DAC_Unit1:
u32PClk = PWC_FCG3_DAC1;
break;
case DAC_Unit2:
u32PClk = PWC_FCG3_DAC2;
break;
default:
u32PClk = PWC_FCG3_DAC1 | PWC_FCG3_DAC2;
break;
}
/* Enable DAC peripheral clock. */
FCG_Fcg3PeriphClockCmd(u32PClk, ENABLE);
}
/**
* @brief Init DAC single channel
* @param [in] enUnit The selected DAC unit
* @retval A pointer of DAC handler
*/
static stc_dac_handle_t *DacSingleConversionInit(en_dac_unit_t enUnit)
{
uint8_t u8Port;
uint16_t u16Pin;
stc_dac_handle_t *pDac;
if (enUnit == DAC_Unit1) {
pDac = &m_stcDACHandle[DAC_Unit1];
pDac->pUnit = CM_DAC1;
} else {
pDac = &m_stcDACHandle[DAC_Unit2];
pDac->pUnit = CM_DAC2;
}
DacPClkEnable(enUnit);
pDac->enCvtType = E_Dac_Single;
#if (SINGLE_WAVE_DAC_CHN == DAC_CHN1)
pDac->u16Ch = DAC_CH1;
#else
pDac->u16Ch = DAC_CH2;
#endif
/* Init DAC by default value: source from data register and output enabled*/
DAC_DeInit(pDac->pUnit);
stc_dac_init_t stInit;
(void)DAC_StructInit(&stInit);
(void)DAC_Init(pDac->pUnit, pDac->u16Ch, &stInit);
#if (DAC_DATA_ALIGN == DAC_DATA_ALIGN_12b_L)
DAC_DataRegAlignConfig(pDac->pUnit, DAC_DATA_ALIGN_L);
#else
DAC_DataRegAlignConfig(pDac->pUnit, DAC_DATA_ALIGN_R);
#endif
/* Set DAC pin attribute to analog */
if (enUnit == DAC_Unit1) {
u8Port = DAC_UNIT1_PORT;
#if (SINGLE_WAVE_DAC_CHN == DAC_CHN1)
u16Pin = DAC_UNIT1_CHN1_PIN;
#endif
}
stc_gpio_init_t stcGpioInit;
(void)GPIO_StructInit(&stcGpioInit);
stcGpioInit.u16PinAttr = PIN_ATTR_ANALOG;
(void)GPIO_Init(u8Port, u16Pin, &stcGpioInit);
#ifdef SUPPORT_ADP
/* Set ADC first */
/* Enable ADC peripheral clock. */
FCG_Fcg3PeriphClockCmd(PWC_FCG3_ADC1 | PWC_FCG3_ADC2 | PWC_FCG3_ADC3, ENABLE);
if (CM_ADC1->STR == 0U) {
if (CM_ADC2->STR == 0U) {
if (CM_ADC3->STR == 0U) {
DAC_ADCPrioConfig(pDac->pUnit, DAC_ADP_SELECT_ALL, ENABLE);
DAC_ADCPrioCmd(pDac->pUnit, ENABLE);
}
}
}
#endif
return pDac;
}
/**
* @brief Start single DAC conversions
* @param [in] pDac A pointer of DAC handler
* @retval None
*/
static void DacStartSingleConversion(const stc_dac_handle_t *pDac)
{
/* Enalbe AMP */
#ifdef SUPPORT_AMP
(void)DAC_AMPCmd(pDac->pUnit, pDac->u16Ch, ENABLE);
#endif
(void)DAC_Start(pDac->pUnit, pDac->u16Ch);
#ifdef SUPPORT_AMP
/* delay 3us before setting data*/
DDL_DelayMS(1U);
#endif
}
/**
* @brief Convert data by single DAC channel
* @param [in] pDac A pointer of DAC handler
* @param [in] pDataTable The data table to be converted
* @param [in] u32count Number of data table items
* @retval None
*/
__STATIC_INLINE void DacSetSingleConversionData(const stc_dac_handle_t *pDac, uint32_t const pDataTable[], uint32_t u32count)
{
uint32_t i = 0U;
for (i = 0U; i < u32count; i++) {
#ifdef SUPPORT_ADP
uint32_t u32TryCount = 100U;
while (u32TryCount != 0U) {
u32TryCount--;
if (SET != DAC_GetChConvertState(pDac->pUnit, pDac->u16Ch)) {
break;
}
}
#endif
DAC_SetChData(pDac->pUnit, pDac->u16Ch, (uint16_t)pDataTable[i]);
}
}
/**
* @brief stop DAC conversion
* @param [in] pDac A pointer of DAC handler
* @retval None
*/
static void DAC_StopConversion(const stc_dac_handle_t *pDac)
{
if (NULL == pDac) {
DAC_DeInit(CM_DAC1);
DAC_DeInit(CM_DAC2);
} else if (pDac->enCvtType != E_Dac_Dual) {
(void)DAC_Stop(pDac->pUnit, pDac->u16Ch);
} else {
DAC_StopDualCh(pDac->pUnit);
}
}
static uint32 DacOpen(void *dev)
{
struct DacHardwareDevice *dac_dev = (struct DacHardwareDevice *)dev;
/* Init MAU for generating sine data*/
MauInit();
/* Init sine data table */
SinTableInit(gu32SinTable, SINE_DOT_NUMBER);
/* Init single DAC */
pSingleDac = DacSingleConversionInit(DAC_Unit1);
return EOK;
}
static uint32 DacClose(void *dev)
{
struct DacHardwareDevice *dac_dev = (struct DacHardwareDevice *)dev;
CM_DAC_TypeDef *DACx = (CM_DAC_TypeDef *)dac_dev->private_data;
DAC_StopConversion(pSingleDac);
DAC_DeInit(DACx);
MauDeinit();
memset(gu32SinTable, 0 , sizeof(gu32SinTable));
return EOK;
}
static uint32 DacWrite(void *dev, struct BusBlockWriteParam *write_param)
{
struct DacHardwareDevice *dac_dev = (struct DacHardwareDevice *)dev;
struct HwDac *dac_cfg = (struct HwDac *)dac_dev->haldev.private_data;
for (int i = 0; i < dac_cfg->digital_data; i ++) {
DacStartSingleConversion(pSingleDac);
DacSetSingleConversionData(pSingleDac, &gu32SinTable[i], 1U);
if (i > SINE_DOT_NUMBER) {
i = 0;
}
}
return EOK;
}
static uint32 DacDrvConfigure(void *drv, struct BusConfigureInfo *configure_info)
{
NULL_PARAM_CHECK(drv);
NULL_PARAM_CHECK(configure_info);
x_err_t ret = EOK;
struct DacDriver *dac_drv = (struct DacDriver *)drv;
struct DacHardwareDevice *dac_dev = (struct DacHardwareDevice *)dac_drv->driver.owner_bus->owner_haldev;
struct HwDac *dac_cfg = (struct HwDac *)dac_dev->haldev.private_data;
switch (configure_info->configure_cmd)
{
case OPE_CFG:
dac_cfg->digital_data = *(uint16 *)configure_info->private_data;
break;
default:
break;
}
return ret;
}
static const struct DacDevDone dev_done =
{
DacOpen,
DacClose,
DacWrite,
NONE,
};
int HwDacInit(void)
{
x_err_t ret = EOK;
#ifdef BSP_USING_DAC
static struct DacBus dac_bus;
static struct DacDriver dac_drv;
static struct DacHardwareDevice dac_dev;
static struct HwDac dac_cfg;
dac_drv.configure = DacDrvConfigure;
ret = DacBusInit(&dac_bus, DAC_BUS_NAME);
if (ret != EOK) {
KPrintf("DAC bus init error %d\n", ret);
return ERROR;
}
ret = DacDriverInit(&dac_drv, DAC_DRIVER_NAME);
if (ret != EOK) {
KPrintf("DAC driver init error %d\n", ret);
return ERROR;
}
ret = DacDriverAttachToBus(DAC_DRIVER_NAME, DAC_BUS_NAME);
if (ret != EOK) {
KPrintf("DAC driver attach error %d\n", ret);
return ERROR;
}
dac_dev.dac_dev_done = &dev_done;
dac_cfg.DACx = CM_DAC1;
dac_cfg.digital_data = 0;
ret = DacDeviceRegister(&dac_dev, (void *)&dac_cfg, DAC_DEVICE_NAME);
if (ret != EOK) {
KPrintf("DAC device register error %d\n", ret);
return ERROR;
}
ret = DacDeviceAttachToBus(DAC_DEVICE_NAME, DAC_BUS_NAME);
if (ret != EOK) {
KPrintf("DAC device register error %d\n", ret);
return ERROR;
}
#endif
return ret;
}

3
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/ethernet/eth_driver.c
View File

@ -277,10 +277,7 @@ struct pbuf* low_level_input(struct netif* netif)
return p;
}
extern void LwipSetIPTest(int argc, char* argv[]);
int HwEthInit(void)
{
// lwip_config_tcp(0, lwip_ipaddr, lwip_netmask, lwip_gwaddr);
LwipSetIPTest(1, NULL);
return EOK;
}

11
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/ethernet/eth_netdev.c
View File

@ -76,6 +76,7 @@ static int lwip_netdev_set_addr_info(struct netdev* netdev, ip_addr_t* ip_addr,
netif_set_gw((struct netif*)netdev->user_data, ip_2_ip4(gw));
}
}
return 0;
}
#ifdef LWIP_DNS
@ -92,7 +93,7 @@ static int lwip_netdev_set_dns_server(struct netdev* netdev, uint8_t dns_num, ip
}
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
static int lwip_netdev_set_dhcp(struct netdev* netdev, bool is_enabled)
{
netdev_low_level_set_dhcp_status(netdev, is_enabled);
@ -120,7 +121,7 @@ static const struct netdev_ops lwip_netdev_ops = {
#ifdef LWIP_DNS
.set_dns_server = lwip_netdev_set_dns_server,
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
.set_dhcp = lwip_netdev_set_dhcp,
#endif
.set_default = lwip_netdev_set_default,
@ -183,9 +184,9 @@ int lwip_netdev_add(struct netif* lwip_netif)
netdev->ops = &lwip_netdev_ops;
netdev->hwaddr_len = lwip_netif->hwaddr_len;
memcpy(netdev->hwaddr, lwip_netif->hwaddr, lwip_netif->hwaddr_len);
netdev->ip_addr = lwip_netif->ip_addr;
netdev->gw = lwip_netif->gw;
netdev->netmask = lwip_netif->netmask;
netdev->ip_addr = &lwip_netif->ip_addr;
netdev->gw = &lwip_netif->gw;
netdev->netmask = &lwip_netif->netmask;
return result;
}

1
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/ethernet/ethernetif.c
View File

@ -204,7 +204,6 @@ void ethernetif_input(void* netif_arg)
/* Move received packet into a new pbuf */
while (1) {
sys_arch_sem_wait(get_eth_recv_sem(), WAITING_FOREVER);
KPrintf("%s -->\n", netif->name);
while (1) {
p = low_level_input(netif);
#ifndef ETHERNET_LOOPBACK_TEST

6
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/ethernet_wiz/Kconfig
View File

@ -1,9 +1,5 @@
# Kconfig file
config BSP_WIZ_RST_PIN
int
default 13
config BSP_WIZ_INT_PIN
int
default 14
default 106

1
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/ethernet_wiz/w5x00_lwip.c
View File

@ -113,7 +113,6 @@ void ethernetif_input2(void* netif_arg)
struct pbuf* p = NULL;
for (;;) {
sys_arch_sem_wait(get_eth_recv_sem2(), WAITING_FOREVER);
KPrintf("%s -->\n", netif->name);
sys_mutex_lock(&wiz_trans_mtx);
while (1) {

22
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/i2c/Kconfig Normal file
View File

@ -0,0 +1,22 @@
config I2C_BUS_NAME_1
string "i2c 1 bus name"
default "i2c1"
config I2C_DRV_NAME_1
string "i2c bus 1 driver name"
default "i2c1_drv"
config I2C_1_DEVICE_NAME_0
string "i2c bus 1 device 0 name"
default "i2c1_dev0"
config I2C_DEVICE_MODE
bool "choose i2c device mode as master or slave"
default y
choice
prompt "choose i2c mode"
default I2C_DEVICE_MASTER
config I2C_DEVICE_MASTER
bool "set i2c master"
config I2C_DEVICE_SLAVE
bool "set i2c slave"
endchoice

3
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/i2c/Makefile Normal file
View File

@ -0,0 +1,3 @@
SRC_FILES := connect_i2c.c
include $(KERNEL_ROOT)/compiler.mk

491
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/i2c/connect_i2c.c Normal file
View File

@ -0,0 +1,491 @@
/*
*******************************************************************************
* Copyright (C) 2022, Xiaohua Semiconductor Co., Ltd. All rights reserved.
*
* This software component is licensed by XHSC under BSD 3-Clause license
* (the "License"); You may not use this file except in compliance with the
* License. You may obtain a copy of the License at:
* opensource.org/licenses/BSD-3-Clause
*
*******************************************************************************
*/
/**
* @file connect_i2c.c
* @brief support edu-arm32-board i2c function and register to bus framework
* @version 3.0
* @author AIIT XUOS Lab
* @date 2022-12-05
*/
/*************************************************
File name: connect_i2c.c
Description: support edu-arm32-board i2c configure and i2c bus register function
Others: take projects/ev_hc32f4a0_lqfp176/examples/i2c/i2c_master_polling/source/main.c for references
History:
1. Date: 2022-12-05
Author: AIIT XUOS Lab
Modification:
1. support edu-arm32-board i2c configure, write and read
2. support edu-arm32-board i2c bus device and driver register
*************************************************/
#include <connect_i2c.h>
#define I2C_UNIT (CM_I2C1)
#define I2C_FCG_USE (FCG1_PERIPH_I2C1)
#define I2C_TIMEOUT (0x40000UL)
#define I2C_BAUDRATE (400000UL)
/* Define port and pin for SDA and SCL */
#define I2C_SCL_PORT (GPIO_PORT_D)
#define I2C_SCL_PIN (GPIO_PIN_03)
#define I2C_SDA_PORT (GPIO_PORT_F)
#define I2C_SDA_PIN (GPIO_PIN_10)
#define I2C_GPIO_SCL_FUNC (GPIO_FUNC_49)
#define I2C_GPIO_SDA_FUNC (GPIO_FUNC_48)
static x_err_t I2cGpioInit(void)
{
GPIO_SetFunc(I2C_SDA_PORT, I2C_SDA_PIN, I2C_GPIO_SDA_FUNC);
GPIO_SetFunc(I2C_SCL_PORT, I2C_SCL_PIN, I2C_GPIO_SCL_FUNC);
return EOK;
}
static uint32 I2cInit(struct I2cDriver *i2c_drv, struct BusConfigureInfo *configure_info)
{
NULL_PARAM_CHECK(i2c_drv);
struct I2cHardwareDevice *i2c_dev = (struct I2cHardwareDevice *)i2c_drv->driver.owner_bus->owner_haldev;
stc_i2c_init_t i2c_init;
(void)I2C_StructInit(&i2c_init);
i2c_init.u32Baudrate = I2C_BAUDRATE;
i2c_init.u32SclTime = 3UL;
i2c_init.u32ClockDiv = I2C_CLK_DIV4;
if (configure_info->private_data) {
i2c_dev->i2c_dev_addr = *((uint16 *)configure_info->private_data);
} else {
KPrintf("I2cInit need set i2c dev addr\n");
return ERROR;
}
/* Configure I2C */
float32_t f32Error;
int32_t i32Ret = LL_ERR;
I2C_DeInit(I2C_UNIT);
i32Ret = I2C_Init(I2C_UNIT, &i2c_init, &f32Error);
#ifdef I2C_DEVICE_SLAVE
if (LL_OK == i32Ret) {
/* Set slave address */
I2C_SlaveAddrConfig(I2C_UNIT, I2C_ADDR0, I2C_ADDR_7BIT, i2c_dev->i2c_dev_addr);
}
#endif
if(i32Ret != LL_OK) {
return ERROR;
}
I2C_BusWaitCmd(I2C_UNIT, ENABLE);
return EOK;
}
static uint32 I2cDrvConfigure(void *drv, struct BusConfigureInfo *configure_info)
{
NULL_PARAM_CHECK(drv);
NULL_PARAM_CHECK(configure_info);
x_err_t ret = EOK;
struct I2cDriver *i2c_drv = (struct I2cDriver *)drv;
switch (configure_info->configure_cmd)
{
case OPE_INT:
ret = I2cInit(i2c_drv, configure_info);
break;
default:
break;
}
return ret;
}
static uint32 I2cMasterWriteData(struct I2cHardwareDevice *i2c_dev, struct I2cDataStandard *msg)
{
if (msg->len == 0) {
return EOK;
}
uint32 i32Ret;
I2C_Cmd(I2C_UNIT, ENABLE);
DDL_DelayMS(20UL);
I2C_SWResetCmd(I2C_UNIT, ENABLE);
I2C_SWResetCmd(I2C_UNIT, DISABLE);
DDL_DelayMS(20UL);
i32Ret = I2C_Start(I2C_UNIT, I2C_TIMEOUT);
if (LL_OK == i32Ret) {
i32Ret = I2C_TransAddr(I2C_UNIT, i2c_dev->i2c_dev_addr, I2C_DIR_TX, I2C_TIMEOUT);
if (i32Ret == LL_OK) {
i32Ret = I2C_TransData(I2C_UNIT, msg->buf, msg->len, I2C_TIMEOUT);
KPrintf("Master Send Success!\n");
}
}
(void)I2C_Stop(I2C_UNIT, I2C_TIMEOUT);
I2C_Cmd(I2C_UNIT, DISABLE);
return i32Ret;
}
static uint32 I2cMasterReadData(struct I2cHardwareDevice *i2c_dev, struct I2cDataStandard *msg)
{
uint32 i32Ret;
I2C_Cmd(I2C_UNIT, ENABLE);
I2C_SWResetCmd(I2C_UNIT, ENABLE);
I2C_SWResetCmd(I2C_UNIT, DISABLE);
i32Ret = I2C_Start(I2C_UNIT, I2C_TIMEOUT);
if (LL_OK == i32Ret) {
if (msg->len == 1U) {
I2C_AckConfig(I2C_UNIT, I2C_NACK);
}
i32Ret = I2C_TransAddr(I2C_UNIT, i2c_dev->i2c_dev_addr, I2C_DIR_RX, I2C_TIMEOUT);
if (LL_OK == i32Ret) {
i32Ret = I2C_MasterReceiveDataAndStop(I2C_UNIT, msg->buf, msg->len, I2C_TIMEOUT);
KPrintf("Master Receive Success!\n");
}
I2C_AckConfig(I2C_UNIT, I2C_ACK);
}
if (LL_OK != i32Ret) {
(void)I2C_Stop(I2C_UNIT, I2C_TIMEOUT);
}
I2C_Cmd(I2C_UNIT, DISABLE);
return i32Ret;
}
static uint32 I2cSlaveWriteData(struct I2cHardwareDevice *i2c_dev, struct I2cDataStandard *msg) {
if (msg->len == 0) {
return EOK;
}
uint32 i32Ret;
I2C_Cmd(I2C_UNIT, ENABLE);
/* Clear status */
I2C_ClearStatus(I2C_UNIT, I2C_CLR_STOPFCLR | I2C_CLR_NACKFCLR);
/* Wait slave address matched */
while (RESET == I2C_GetStatus(I2C_UNIT, I2C_FLAG_MATCH_ADDR0)) {
;
}
I2C_ClearStatus(I2C_UNIT, I2C_CLR_SLADDR0FCLR);
if (RESET == I2C_GetStatus(I2C_UNIT, I2C_FLAG_TRA)) {
i32Ret = LL_ERR;
} else {
i32Ret = I2C_TransData(I2C_UNIT, msg->buf, msg->len, I2C_TIMEOUT);
KPrintf("Slave send success!\r\n");
if ((LL_OK == i32Ret) || (LL_ERR_TIMEOUT == i32Ret)) {
/* Release SCL pin */
(void)I2C_ReadData(I2C_UNIT);
/* Wait stop condition */
i32Ret = I2C_WaitStatus(I2C_UNIT, I2C_FLAG_STOP, SET, I2C_TIMEOUT);
}
}
I2C_Cmd(I2C_UNIT, DISABLE);
return i32Ret;
}
static uint32 I2cSlaveReadData(struct I2cHardwareDevice *i2c_dev, struct I2cDataStandard *msg) {
uint32 i32Ret;
I2C_Cmd(I2C_UNIT, ENABLE);
/* Clear status */
I2C_ClearStatus(I2C_UNIT, I2C_CLR_STOPFCLR | I2C_CLR_NACKFCLR);
/* Wait slave address matched */
while (RESET == I2C_GetStatus(I2C_UNIT, I2C_FLAG_MATCH_ADDR0)) {
;
}
I2C_ClearStatus(I2C_UNIT, I2C_CLR_SLADDR0FCLR);
if (RESET == I2C_GetStatus(I2C_UNIT, I2C_FLAG_TRA)) {
/* Slave receive data*/
i32Ret = I2C_ReceiveData(I2C_UNIT, msg->buf, msg->len, I2C_TIMEOUT);
KPrintf("Slave receive success!\r\n");
if ((LL_OK == i32Ret) || (LL_ERR_TIMEOUT == i32Ret)) {
/* Wait stop condition */
i32Ret = I2C_WaitStatus(I2C_UNIT, I2C_FLAG_STOP, SET, I2C_TIMEOUT);
}
} else {
i32Ret = LL_ERR;
}
I2C_Cmd(I2C_UNIT, DISABLE);
return i32Ret;
}
/* manage the i2c device operations*/
static const struct I2cDevDone i2c_dev_done =
{
.dev_open = NONE,
.dev_close = NONE,
#ifdef I2C_DEVICE_SLAVE
.dev_write = I2cSlaveWriteData,
.dev_read = I2cSlaveReadData,
#else
.dev_write = I2cMasterWriteData,
.dev_read = I2cMasterReadData,
#endif
};
/* Init i2c bus */
static int BoardI2cBusInit(struct I2cBus *i2c_bus, struct I2cDriver *i2c_driver)
{
x_err_t ret = EOK;
/* Init the i2c bus */
ret = I2cBusInit(i2c_bus, I2C_BUS_NAME_1);
if (EOK != ret) {
KPrintf("board_i2c_init I2cBusInit error %d\n", ret);
return ERROR;
}
/* Init the i2c driver*/
ret = I2cDriverInit(i2c_driver, I2C_DRV_NAME_1);
if (EOK != ret) {
KPrintf("board_i2c_init I2cDriverInit error %d\n", ret);
return ERROR;
}
/* Attach the i2c driver to the i2c bus*/
ret = I2cDriverAttachToBus(I2C_DRV_NAME_1, I2C_BUS_NAME_1);
if (EOK != ret) {
KPrintf("board_i2c_init I2cDriverAttachToBus error %d\n", ret);
return ERROR;
}
return ret;
}
/* Attach the i2c device to the i2c bus*/
static int BoardI2cDevBend(void)
{
x_err_t ret = EOK;
static struct I2cHardwareDevice i2c_device0;
memset(&i2c_device0, 0, sizeof(struct I2cHardwareDevice));
i2c_device0.i2c_dev_done = &i2c_dev_done;
ret = I2cDeviceRegister(&i2c_device0, NONE, I2C_1_DEVICE_NAME_0);
if (EOK != ret) {
KPrintf("board_i2c_init I2cDeviceInit device %s error %d\n", I2C_1_DEVICE_NAME_0, ret);
return ERROR;
}
ret = I2cDeviceAttachToBus(I2C_1_DEVICE_NAME_0, I2C_BUS_NAME_1);
if (EOK != ret) {
KPrintf("board_i2c_init I2cDeviceAttachToBus device %s error %d\n", I2C_1_DEVICE_NAME_0, ret);
return ERROR;
}
return ret;
}
/* EDU-ARM32 BOARD I2C INIT*/
int HwI2cInit(void)
{
x_err_t ret = EOK;
static struct I2cBus i2c_bus;
memset(&i2c_bus, 0, sizeof(struct I2cBus));
static struct I2cDriver i2c_driver;
memset(&i2c_driver, 0, sizeof(struct I2cDriver));
I2cGpioInit();
/* Enable I2C Peripheral*/
FCG_Fcg1PeriphClockCmd(I2C_FCG_USE, ENABLE);
i2c_driver.configure = I2cDrvConfigure;
ret = BoardI2cBusInit(&i2c_bus, &i2c_driver);
if (ret != EOK) {
KPrintf("board_i2c_init error ret %u\n", ret);
return ERROR;
}
ret = BoardI2cDevBend();
if (EOK != ret) {
KPrintf("board_i2c_init error ret %u\n", ret);
return ERROR;
}
return ret;
}
// #define I2C_TEST
#ifdef I2C_TEST
#define USER_KEY_PORT (GPIO_PORT_I)
#define USER_KEY_PIN (GPIO_PIN_07)
#define DEVICE_ADDR (0x06U)
static struct Bus *bus1;
static struct I2cDriver *i2c_drv1;
void I2cInitTest(void)
{
x_err_t ret = EOK;
stc_gpio_init_t stcGpioInit;
/* KEY initialize */
(void)GPIO_StructInit(&stcGpioInit);
stcGpioInit.u16PinState = PIN_STAT_RST;
stcGpioInit.u16PinDir = PIN_DIR_IN;
(void)GPIO_Init(USER_KEY_PORT, USER_KEY_PIN, &stcGpioInit);
bus1 = BusFind(I2C_BUS_NAME_1);
bus1->owner_driver = BusFindDriver(bus1, I2C_DRV_NAME_1);
bus1->owner_haldev = BusFindDevice(bus1, I2C_1_DEVICE_NAME_0);
struct BusConfigureInfo configure_info;
configure_info.configure_cmd = OPE_INT;
configure_info.private_data = (void *)DEVICE_ADDR;
ret = I2cDrvConfigure(bus1->owner_driver, &configure_info);
if (ret != EOK) {
KPrintf("initialize %s failed!\n", I2C_UNIT);
return;
}
i2c_drv1 = (struct I2cDriver *)bus1->owner_driver;
return;
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0)|SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN),
I2cInitTest, I2cInitTest, i2c init);
void I2cMasterTest(void)
{
x_err_t ret = EOK;
struct I2cHardwareDevice *i2c_dev1 = (struct I2cHardwareDevice *)i2c_drv1->driver.owner_bus->owner_haldev;
struct I2cDataStandard msg;
uint8 u8TxBuf[256U] = {1, 2, 3, 4, 5};
uint8 u8RxBuf[256U];
(void)memset(u8RxBuf, 0, 256U);
msg.len = 5;
msg.buf = u8TxBuf;
while (SET == GPIO_ReadInputPins(USER_KEY_PORT, USER_KEY_PIN)) {
;
}
KPrintf("I2C send data\n");
ret = I2cMasterWriteData(i2c_dev1, &msg);
if (EOK != ret) {
KPrintf("I2C send failed! ret %d\n", ret);
return;
}
KPrintf("Master send data: ");
for (uint16 i = 0; i < msg.len; i++) {
KPrintf("%d ", (msg.buf)[i]);
}
KPrintf("\n");
/* 50mS delay for device*/
DDL_DelayMS(50UL);
msg.buf = u8RxBuf;
(void)I2cMasterReadData(i2c_dev1, &msg);
KPrintf("Master receive data: ");
for (uint16 i = 0; i < msg.len; i++) {
KPrintf("%d ", (msg.buf)[i]);
}
KPrintf("\n");
return;
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0)|SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN),
I2cMasterTest, I2cMasterTest, i2c master send and receive data);
void I2cSlaveTest(void)
{
x_err_t ret = EOK;
struct I2cHardwareDevice *i2c_dev1 = (struct I2cHardwareDevice *)i2c_drv1->driver.owner_bus->owner_haldev;
struct I2cDataStandard msg;
uint8 u8RxBuf[256U];
(void)memset(u8RxBuf, 0, 256U);
msg.len = 5;
msg.buf = u8RxBuf;
KPrintf("I2C receive data\n");
for (;;) {
ret = I2cSlaveReadData(i2c_dev1, &msg);
if (ret != EOK) {
KPrintf("I2C receive failed!\n");
break;
} else {
KPrintf("Slave receive data: ");
for (uint16 i = 0; i < msg.len; i++) {
KPrintf("%d ", (msg.buf)[i]);
}
KPrintf("\n");
}
ret = I2cSlaveWriteData(i2c_dev1, &msg);
if (ret != EOK) {
KPrintf("I2C send failed!\n");
break;
} else {
KPrintf("Slave send data: ");
for (uint16 i = 0; i < msg.len; i++) {
KPrintf("%d ", (msg.buf)[i]);
}
KPrintf("\n");
}
}
return;
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0)|SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN),
I2cSlaveTest, I2cSlaveTest, i2c slave receive and send data);
#endif

42
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/include/connect_adc.h Normal file
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@ -0,0 +1,42 @@
/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_uart.h
* @brief define edu-arm32-board usart function and struct
* @version 2.0
* @author AIIT XUOS Lab
* @date 2023-02-09
*/
#include <device.h>
#include <hardware_irq.h>
#include <hc32_ll_adc.h>
#ifdef __cplusplus
extern "C" {
#endif
struct HwAdc
{
CM_ADC_TypeDef *ADCx;
uint8 adc_channel;
};
int HwAdcInit(void);
#ifdef __cplusplus
}
#endif

40
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/include/connect_can.h Normal file
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@ -0,0 +1,40 @@
/*
* Copyright (c) 2021 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_can.h
* @brief define edu-arm32-board can function and struct
* @version 2.0
* @author AIIT XUOS Lab
* @date 2023-02-21
*/
#ifndef CONNECT_CAN_H
#define CONNECT_CAN_H
#include <device.h>
#include <hc32_ll_can.h>
#include <hc32_ll_clk.h>
#include <hc32_ll_gpio.h>
#include <hardware_irq.h>
#ifdef __cplusplus
extern "C" {
#endif
int HwCanInit(void);
#ifdef __cplusplus
}
#endif
#endif

43
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/include/connect_dac.h Normal file
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@ -0,0 +1,43 @@
/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_uart.h
* @brief define edu-arm32-board usart function and struct
* @version 2.0
* @author AIIT XUOS Lab
* @date 2023-02-09
*/
#include <device.h>
#include <hardware_irq.h>
#include <hc32_ll_fcg.h>
#include <hc32_ll_dac.h>
#include <hc32_ll_gpio.h>
#ifdef __cplusplus
extern "C" {
#endif
struct HwDac
{
CM_DAC_TypeDef *DACx;
uint16 digital_data;
};
int HwDacInit(void);
#ifdef __cplusplus
}
#endif

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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_flash.h
* @brief define edu-arm32-board qspi-flash function and struct
* @version 2.0
* @author AIIT XUOS Lab
* @date 2022-10-17
*/
#ifndef CONNECT_FLASH_H
#define CONNECT_FLASH_H
#include <device.h>
#include <hardware_irq.h>
#include <flash_spi.h>
#include <hc32_ll_qspi.h>
#include <hc32_ll_gpio.h>
#ifdef __cplusplus
extern "C" {
#endif
int FlashW25qxxSpiDeviceInit(void);
#ifdef __cplusplus
}
#endif
#endif

40
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/include/connect_hwtimer.h Normal file
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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_hwtimer.h
* @brief define edu-arm32-board hwtimer function and struct
* @version 2.0
* @author AIIT XUOS Lab
* @date 2023-02-16
*/
#ifndef CONNECT_HWTIMER_H
#define CONNECT_HWTIMER_H
#include <device.h>
#include <hc32f4a0.h>
#include <hardware_irq.h>
#include <hc32_ll_tmr0.h>
#include <hc32_ll_gpio.h>
#ifdef __cplusplus
extern "C" {
#endif
int HwTimerInit(void);
#ifdef __cplusplus
}
#endif
#endif

42
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/include/connect_i2c.h Normal file
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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_i2c.h
* @brief define edu-arm32-board i2c function and struct
* @version 3.0
* @author AIIT XUOS Lab
* @date 2022-12-05
*/
#ifndef CONNECT_I2C_H
#define CONNECT_I2C_H
#include <device.h>
#include <hc32_ll.h>
#include <hc32_ll_i2c.h>
#include <hc32_ll_utility.h>
#include <hc32_ll_fcg.h>
#include <hc32_ll_gpio.h>
#include <hc32_ll_def.h>
#ifdef __cplusplus
extern "C" {
#endif
int HwI2cInit(void);
#ifdef __cplusplus
}
#endif
#endif

37
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/include/connect_rtc.h Normal file
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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_rtc.h
* @brief define edu-arm32-board rtc function and struct
* @version 3.0
* @author AIIT XUOS Lab
* @date 2023-02-02
*/
#ifndef CONNECT_RTC_H
#define CONNECT_RTC_H
#include <device.h>
#include <hc32_ll_rtc.h>
#ifdef __cplusplus
extern "C" {
#endif
int HwRtcInit(void);
#ifdef __cplusplus
}
#endif
#endif

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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_spi_lora.h
* @brief define spi lora dev function and struct using bus driver framework
* @version 2.0
* @author AIIT XUOS Lab
* @date 2022-10-31
*/
#ifndef CONNECT_SPI_LORA_H
#define CONNECT_SPI_LORA_H
#include <device.h>
#include <hc32_ll_utility.h>
#include <connect_spi.h>
#include <radio.h>
#include <spi_lora_sx12xx.h>
#include <sx1276.h>
#include <sx1276-Hal.h>
#include <sx1276-LoRa.h>
#include <sx1276-LoRaMisc.h>
#ifdef __cplusplus
extern "C" {
#endif
//#define SPI_LORA_FREQUENCY 10000000
#define SPI_LORA_BUFFER_SIZE 256
typedef struct SpiLoraDevice *SpiLoraDeviceType;
struct LoraDevDone
{
uint32 (*open) (void *dev);
uint32 (*close) (void *dev);
uint32 (*write) (void *dev, struct BusBlockWriteParam *write_param);
uint32 (*read) (void *dev, struct BusBlockReadParam *read_param);
};
struct SpiLoraDevice
{
struct SpiHardwareDevice *spi_dev;
struct SpiHardwareDevice lora_dev;
};
#ifdef __cplusplus
}
#endif
#endif

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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_usb.h
* @brief define edu-arm32-board usb function and struct
* @version 2.0
* @author AIIT XUOS Lab
* @date 2022-11-07
*/
#ifndef CONNECT_USB_H
#define CONNECT_USB_H
#include <device.h>
#include <hc32_ll_utility.h>
#include <hc32_ll_gpio.h>
#include <usb_lib.h>
#include <usb_host_user.h>
#include <usb_host_driver.h>
#include <usb_host_core.h>
#include <usb_host_msc_class.h>
#include <usb_host_msc_scsi.h>
#include <usb_host_msc_bot.h>
#include <usb_host_int.h>
#if defined(FS_VFS)
#include <iot-vfs.h>
#endif
#ifdef __cplusplus
extern "C" {
#endif
#define USB_HOST_STACK_SIZE 4096
#define USB_SINGLE_BLOCK_SIZE 512
int HwUsbHostInit(void);
#ifdef __cplusplus
}
#endif
#endif

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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_wdt.h
* @brief define edu-arm32-board watchdog function and struct
* @version 3.0
* @author AIIT XUOS Lab
* @date 2023-02-02
*/
#ifndef CONNECT_WDT_H
#define CONNECT_WDT_H
#include <device.h>
#include <hc32_ll_wdt.h>
#ifdef __cplusplus
extern "C" {
#endif
int HwWdtInit(void);
#ifdef __cplusplus
}
#endif
#endif

11
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/rtc/Kconfig Normal file
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if BSP_USING_RTC
config RTC_BUS_NAME
string "rtc bus name"
default "rtc"
config RTC_DRV_NAME
string "rtc bus driver name"
default "rtc_drv"
config RTC_DEVICE_NAME
string "rtc bus device name"
default "rtc_dev"
endif

2
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/rtc/Makefile Normal file
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SRC_FILES := connect_rtc.c
include $(KERNEL_ROOT)/compiler.mk

185
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/rtc/connect_rtc.c Normal file
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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_rtc.c
* @brief support aiit-edu-arm32-board rtc function and register to bus framework
* @version 1.0
* @author AIIT XUOS Lab
* @date 2023-02-02
*/
#include <connect_rtc.h>
#include <stdint.h>
#include <stdlib.h>
#include <time.h>
static uint32 RtcConfigure(void *drv, struct BusConfigureInfo *configure_info)
{
NULL_PARAM_CHECK(drv);
struct RtcDriver *rtc_drv = (struct RtcDriver *)drv;
struct RtcDrvConfigureParam *drv_param = (struct RtcDrvConfigureParam *)configure_info->private_data;
int cmd = drv_param->rtc_operation_cmd;
time_t *time = drv_param->time;
switch (cmd)
{
case OPER_RTC_GET_TIME:
{
struct tm ct;
stc_rtc_date_t rtc_date;
stc_rtc_time_t rtc_time;
// rtc_timer_get(&year, &month, &day, &hour, &minute, &second);
RTC_GetDate(RTC_DATA_FMT_DEC, &rtc_date);
RTC_GetTime(RTC_DATA_FMT_DEC, &rtc_time);
ct.tm_year = rtc_date.u8Year ;
ct.tm_mon = rtc_date.u8Month ;
ct.tm_mday = rtc_date.u8Day;
ct.tm_wday = rtc_date.u8Weekday;
ct.tm_hour = rtc_time.u8Hour;
ct.tm_min = rtc_time.u8Minute;
ct.tm_sec = rtc_time.u8Second;
*time = mktime(&ct);
}
break;
case OPER_RTC_SET_TIME:
{
struct tm *ct;
stc_rtc_date_t rtc_date;
stc_rtc_time_t rtc_time;
x_base lock;
lock = CriticalAreaLock();
ct = localtime(time);
rtc_date.u8Year = ct->tm_year ;
rtc_date.u8Month = ct->tm_mon ;
rtc_date.u8Day = ct->tm_mday;
rtc_date.u8Weekday = ct->tm_wday;
rtc_time.u8Hour = ct->tm_hour;
rtc_time.u8Minute = ct->tm_min;
rtc_time.u8Second = ct->tm_sec;
CriticalAreaUnLock(lock);
RTC_SetDate(RTC_DATA_FMT_DEC, &rtc_date);
RTC_SetTime(RTC_DATA_FMT_DEC, &rtc_time);
}
break;
}
return EOK;
}
/*manage the rtc device operations*/
static const struct RtcDevDone dev_done =
{
.open = NONE,
.close = NONE,
.write = NONE,
.read = NONE,
};
static int BoardRtcBusInit(struct RtcBus *rtc_bus, struct RtcDriver *rtc_driver)
{
x_err_t ret = EOK;
/*Init the rtc bus */
ret = RtcBusInit(rtc_bus, RTC_BUS_NAME);
if (EOK != ret) {
KPrintf("HwRtcInit RtcBusInit error %d\n", ret);
return ERROR;
}
/*Init the rtc driver*/
ret = RtcDriverInit(rtc_driver, RTC_DRV_NAME);
if (EOK != ret) {
KPrintf("HwRtcInit RtcDriverInit error %d\n", ret);
return ERROR;
}
/*Attach the rtc driver to the rtc bus*/
ret = RtcDriverAttachToBus(RTC_DRV_NAME, RTC_BUS_NAME);
if (EOK != ret) {
KPrintf("HwRtcInit RtcDriverAttachToBus error %d\n", ret);
return ERROR;
}
return ret;
}
/*Attach the rtc device to the rtc bus*/
static int BoardRtcDevBend(void)
{
x_err_t ret = EOK;
static struct RtcHardwareDevice rtc_device;
memset(&rtc_device, 0, sizeof(struct RtcHardwareDevice));
rtc_device.dev_done = &(dev_done);
ret = RtcDeviceRegister(&rtc_device, NONE, RTC_DEVICE_NAME);
if (EOK != ret) {
KPrintf("HwRtcInit RtcDeviceInit device %s error %d\n", RTC_DEVICE_NAME, ret);
return ERROR;
}
ret = RtcDeviceAttachToBus(RTC_DEVICE_NAME, RTC_BUS_NAME);
if (EOK != ret) {
KPrintf("HwRtcInit RtcDeviceAttachToBus device %s error %d\n", RTC_DEVICE_NAME, ret);
return ERROR;
}
return ret;
}
int HwRtcInit(void)
{
x_err_t ret = EOK;
static struct RtcBus rtc_bus;
memset(&rtc_bus, 0, sizeof(struct RtcBus));
static struct RtcDriver rtc_driver;
memset(&rtc_driver, 0, sizeof(struct RtcDriver));
rtc_driver.configure = &(RtcConfigure);
ret = BoardRtcBusInit(&rtc_bus, &rtc_driver);
if (EOK != ret) {
KPrintf("HwRtcInit error ret %u\n", ret);
return ERROR;
}
ret = BoardRtcDevBend();
if (EOK != ret) {
KPrintf("HwRtcInit error ret %u\n", ret);
}
stc_rtc_init_t stcRtcInit;
/* Configure structure initialization */
(void)RTC_StructInit(&stcRtcInit);
/* Configuration RTC structure */
stcRtcInit.u8ClockSrc = RTC_CLK_SRC_XTAL32;
stcRtcInit.u8HourFormat= RTC_HOUR_FMT_24H;
stcRtcInit.u8IntPeriod = RTC_INT_PERIOD_PER_SEC;
(void)RTC_Init(&stcRtcInit);
RTC_Cmd(LL_RTC_ENABLE);
return ret;
}

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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_flash.c
* @brief support edu-arm32-board qspi-flash function and register to bus framework
* @version 2.0
* @author AIIT XUOS Lab
* @date 2023-02-16
*/
#include <connect_flash.h>
#define QSPI_DEVICE_SLAVE_ID_0 (0)
#define QSPI_UNIT (CM_QSPI)
#define QSPI_CS_PORT (GPIO_PORT_C)
#define QSPI_SCK_PORT (GPIO_PORT_C)
#define QSPI_IO0_PORT (GPIO_PORT_D)
#define QSPI_IO1_PORT (GPIO_PORT_D)
#define QSPI_IO2_PORT (GPIO_PORT_D)
#define QSPI_IO3_PORT (GPIO_PORT_D)
#define QSPI_CS_PIN (GPIO_PIN_07)
#define QSPI_SCK_PIN (GPIO_PIN_06)
#define QSPI_IO0_PIN (GPIO_PIN_08)
#define QSPI_IO1_PIN (GPIO_PIN_09)
#define QSPI_IO2_PIN (GPIO_PIN_10)
#define QSPI_IO3_PIN (GPIO_PIN_11)
#define QSPI_PIN_FUNC (GPIO_FUNC_18)
static uint32 QSpiSdkInit(struct SpiDriver *spi_drv)
{
stc_qspi_init_t stcInit;
FCG_Fcg1PeriphClockCmd(PWC_FCG1_QSPI, ENABLE);
(void)QSPI_StructInit(&stcInit);
stcInit.u32ClockDiv = QSPI_CLK_DIV3;
stcInit.u32SpiMode = QSPI_SPI_MD0;
stcInit.u32ReadMode = QSPI_RD_MD_STD_RD;
stcInit.u32DummyCycle = QSPI_DUMMY_CYCLE8;
stcInit.u32AddrWidth = QSPI_ADDR_WIDTH_24BIT;
return QSPI_Init(&stcInit);
}
static void QspiPinConfig(void)
{
stc_gpio_init_t stcGpioInit;
(void)GPIO_StructInit(&stcGpioInit);
stcGpioInit.u16PinState = PIN_STAT_RST;
stcGpioInit.u16PinDir = PIN_DIR_OUT;
(void)GPIO_Init(QSPI_CS_PORT, QSPI_CS_PIN|QSPI_SCK_PIN, &stcGpioInit);
stcGpioInit.u16PinState = PIN_STAT_SET;
(void)GPIO_Init(QSPI_IO0_PORT, QSPI_IO1_PIN|QSPI_IO2_PIN|QSPI_IO3_PIN, &stcGpioInit);
stcGpioInit.u16PinDir = PIN_DIR_IN;
(void)GPIO_Init(QSPI_IO0_PORT, QSPI_IO0_PIN, &stcGpioInit);
GPIO_ResetPins(QSPI_CS_PORT, QSPI_CS_PIN);
GPIO_SetPins(QSPI_IO0_PORT, QSPI_IO2_PIN|QSPI_IO3_PIN);
GPIO_SetFunc(QSPI_CS_PORT, QSPI_CS_PIN, QSPI_PIN_FUNC);
GPIO_SetFunc(QSPI_SCK_PORT, QSPI_SCK_PIN, QSPI_PIN_FUNC);
GPIO_SetFunc(QSPI_IO0_PORT, QSPI_IO0_PIN, QSPI_PIN_FUNC);
GPIO_SetFunc(QSPI_IO1_PORT, QSPI_IO1_PIN, QSPI_PIN_FUNC);
GPIO_SetFunc(QSPI_IO2_PORT, QSPI_IO2_PIN, QSPI_PIN_FUNC);
GPIO_SetFunc(QSPI_IO3_PORT, QSPI_IO3_PIN, QSPI_PIN_FUNC);
}
static uint32 QSpiWriteData(struct SpiHardwareDevice *spi_dev, struct SpiDataStandard *spi_datacfg)
{
SpiDeviceParam *dev_param = (SpiDeviceParam *)(spi_dev->haldev.private_data);
uint8 cs_gpio_pin = dev_param->spi_slave_param->spi_cs_gpio_pin;
uint8 cs_gpio_port = dev_param->spi_slave_param->spi_cs_gpio_port;
CM_SPI_TypeDef *spi = spi_dev->haldev.owner_bus->private_data;
x_err_t ret = EOK;
if (spi_datacfg->spi_chip_select) {
// GPIO_ResetPins(cs_gpio_port, cs_gpio_pin);
QSPI_EnterDirectCommMode();
}
if(spi_datacfg->length > 0U && spi_datacfg->tx_buff!=NULL){
for(int i=0;i<spi_datacfg->length;i++){
QSPI_WriteDirectCommValue(spi_datacfg->tx_buff[i]);
}
}
if (spi_datacfg->spi_cs_release) {
// GPIO_SetPins(cs_gpio_port, cs_gpio_pin);
QSPI_ExitDirectCommMode();
}
return ret;
}
static uint32 QSpiReadData(struct SpiHardwareDevice *spi_dev, struct SpiDataStandard *spi_datacfg)
{
SpiDeviceParam *dev_param = (SpiDeviceParam *)(spi_dev->haldev.private_data);
uint8 cs_gpio_pin = dev_param->spi_slave_param->spi_cs_gpio_pin;
uint8 cs_gpio_port = dev_param->spi_slave_param->spi_cs_gpio_port;
CM_SPI_TypeDef *spi = spi_dev->haldev.owner_bus->private_data;
x_err_t ret = EOK;
uint8_t *read_buffer = spi_datacfg->rx_buff;
if (spi_datacfg->spi_chip_select) {
// GPIO_ResetPins(cs_gpio_port, cs_gpio_pin);
QSPI_EnterDirectCommMode();
}
if(spi_datacfg->length > 0U && spi_datacfg->rx_buff!=NULL){
for(int i=0;i<spi_datacfg->length;i++){
read_buffer[i] = (uint8_t)QSPI_ReadDirectCommValue();
}
}
if (spi_datacfg->spi_cs_release) {
// GPIO_SetPins(cs_gpio_port, cs_gpio_pin);
QSPI_ExitDirectCommMode();
}
return ret;
}
static uint32 QSpiDrvConfigure(void *drv, struct BusConfigureInfo *configure_info)
{
NULL_PARAM_CHECK(drv);
NULL_PARAM_CHECK(configure_info);
x_err_t ret = EOK;
struct SpiDriver *spi_drv = (struct SpiDriver *)drv;
struct SpiMasterParam *spi_param;
switch (configure_info->configure_cmd)
{
case OPE_INT:
QSpiSdkInit(spi_drv);
QspiPinConfig();
break;
case OPE_CFG:
spi_param = (struct SpiMasterParam *)configure_info->private_data;
break;
default:
break;
}
return ret;
}
/*manage the qspi device operations*/
static const struct SpiDevDone qspi_dev_done =
{
.dev_open = NONE,
.dev_close = NONE,
.dev_write = QSpiWriteData,
.dev_read = QSpiReadData,
};
static int BoardQSpiDevBend(void)
{
x_err_t ret = EOK;
static struct SpiHardwareDevice qspi_device0;
memset(&qspi_device0, 0, sizeof(struct SpiHardwareDevice));
static struct SpiSlaveParam qspi_slaveparam0;
memset(&qspi_slaveparam0, 0, sizeof(struct SpiSlaveParam));
qspi_slaveparam0.spi_slave_id = QSPI_DEVICE_SLAVE_ID_0;
qspi_slaveparam0.spi_cs_gpio_pin = QSPI_CS_PIN;
qspi_slaveparam0.spi_cs_gpio_port = QSPI_CS_PORT;
qspi_device0.spi_param.spi_slave_param = &qspi_slaveparam0;
qspi_device0.spi_dev_done = &(qspi_dev_done);
ret = SpiDeviceRegister(&qspi_device0, (void *)(&qspi_device0.spi_param), QSPI_DEVICE_NAME_0);
if (EOK != ret) {
KPrintf("BoardSpiDevBend SpiDeviceRegister device %s error %d\n", QSPI_DEVICE_NAME_0, ret);
return ERROR;
}
ret = SpiDeviceAttachToBus(QSPI_DEVICE_NAME_0, QSPI_BUS_NAME);
if (EOK != ret) {
KPrintf("BoardSpiDevBend SpiDeviceAttachToBus device %s error %d\n", QSPI_DEVICE_NAME_0, ret);
return ERROR;
}
return ret;
}
static int BoardSpiBusInit(struct SpiBus *spi_bus, struct SpiDriver *spi_driver, const char *bus_name, const char *drv_name)
{
x_err_t ret = EOK;
/*Init the spi bus */
ret = SpiBusInit(spi_bus, bus_name);
if (EOK != ret) {
KPrintf("Board_Spi_init SpiBusInit error %d\n", ret);
return ERROR;
}
/*Init the spi driver*/
ret = SpiDriverInit(spi_driver, drv_name);
if (EOK != ret) {
KPrintf("Board_Spi_init SpiDriverInit error %d\n", ret);
return ERROR;
}
/*Attach the spi driver to the spi bus*/
ret = SpiDriverAttachToBus(drv_name, bus_name);
if (EOK != ret) {
KPrintf("Board_Spi_init SpiDriverAttachToBus error %d\n", ret);
return ERROR;
}
return ret;
}
int HwQSpiInit(void)
{
x_err_t ret = EOK;
static struct SpiBus qspi_bus;
memset(&qspi_bus, 0, sizeof(struct SpiBus));
static struct SpiDriver qspi_driver;
memset(&qspi_driver, 0, sizeof(struct SpiDriver));
qspi_bus.private_data = QSPI_UNIT;
qspi_driver.configure = QSpiDrvConfigure;
ret = BoardSpiBusInit(&qspi_bus, &qspi_driver, QSPI_BUS_NAME, QSPI_DRV_NAME);
if (EOK != ret) {
KPrintf("BoardSpiBusInit error ret %u\n", ret);
return ERROR;
}
ret = BoardQSpiDevBend();
if (EOK != ret) {
KPrintf("BoardSpiDevBend error ret %u\n", ret);
return ERROR;
}
return ret;
}
int FlashW25qxxSpiDeviceInit(void)
{
HwQSpiInit();
QSpiSdkInit(NULL);
QspiPinConfig();
if (NONE == SpiFlashInit(QSPI_BUS_NAME, QSPI_DEVICE_NAME_0, QSPI_DRV_NAME, QSPI_FLASH_DEV_NAME)) {
return ERROR;
}
return EOK;
}

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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_lora_spi.c
* @brief support to register spi lora pointer and function
* @version 2.0
* @author AIIT XUOS Lab
* @date 2022-10-31
*/
#include <connect_spi_lora.h>
/* RST = PI02 */
#define LORA_RST_PORT (GPIO_PORT_I)
#define LORA_RST_PIN (GPIO_PIN_02)
static struct HardwareDev *g_spi_lora_dev;
static tRadioDriver *Radio = NONE;
void SX1276InitIo(void)
{
stc_gpio_init_t stcGpioInit;
(void)GPIO_StructInit(&stcGpioInit);
stcGpioInit.u16PinState = PIN_STAT_RST;
stcGpioInit.u16PinDir = PIN_DIR_OUT;
(void)GPIO_Init(LORA_RST_PORT, LORA_RST_PIN, &stcGpioInit);
}
inline void SX1276WriteRxTx(uint8_t txEnable)
{
if (txEnable != 0) {
/*to do*/
} else {
/*to do*/
}
}
void SX1276SetReset(uint8_t state)
{
if (state == RADIO_RESET_ON) {
GPIO_ResetPins(LORA_RST_PORT, LORA_RST_PIN);
} else {
stc_gpio_init_t stcGpioInit;
(void)GPIO_StructInit(&stcGpioInit);
stcGpioInit.u16PinDir = PIN_DIR_IN;
(void)GPIO_Init(LORA_RST_PORT, LORA_RST_PIN, &stcGpioInit);
}
}
//Not-necessary Function
uint8_t SX1276ReadDio0(void)
{
return 1;
}
uint8_t SX1276ReadDio1(void)
{
return 1;
}
uint8_t SX1276ReadDio2(void)
{
return 1;
}
uint8_t SX1276ReadDio3(void)
{
return 1;
}
uint8_t SX1276ReadDio4(void)
{
return 1;
}
uint8_t SX1276ReadDio5(void)
{
return 1;
}
void SX1276WriteBuffer(uint8_t addr, uint8_t *buffer, uint8_t size)
{
struct BusBlockWriteParam write_param;
uint8 write_addr = addr | 0x80;
BusDevOpen(g_spi_lora_dev);
write_param.buffer = (void *)&write_addr;
write_param.size = 1;
BusDevWriteData(g_spi_lora_dev, &write_param);
write_param.buffer = (void *)buffer;
write_param.size = size;
BusDevWriteData(g_spi_lora_dev, &write_param);
BusDevClose(g_spi_lora_dev);
}
void SX1276ReadBuffer(uint8_t addr, uint8_t *buffer, uint8_t size)
{
struct BusBlockWriteParam write_param;
struct BusBlockReadParam read_param;
uint8 write_addr = addr & 0x7F;
BusDevOpen(g_spi_lora_dev);
write_param.buffer = (void *)&write_addr;
write_param.size = 1;
BusDevWriteData(g_spi_lora_dev, &write_param);
read_param.buffer = (void *)buffer;
read_param.size = size;
BusDevReadData(g_spi_lora_dev, &read_param);
BusDevClose(g_spi_lora_dev);
}
void SX1276WriteFifo(uint8_t *buffer, uint8_t size)
{
SX1276WriteBuffer(0, buffer, size);
}
void SX1276ReadFifo(uint8_t *buffer, uint8_t size)
{
SX1276ReadBuffer(0, buffer, size);
}
void SX1276Write(uint8_t addr, uint8_t data)
{
SX1276WriteBuffer(addr, &data, 1);
}
void SX1276Read(uint8_t addr, uint8_t *data)
{
SX1276ReadBuffer(addr, data, 1);
}
uint8_t Sx1276SpiCheck(void)
{
uint8_t test = 0;
tLoRaSettings settings;
SX1276Read(REG_LR_VERSION, &test);
KPrintf("version code of the chip is 0x%x\n", test);
settings.RFFrequency = SX1276LoRaGetRFFrequency();
KPrintf("SX1278 Lora parameters are :\nRFFrequency is %d\n", settings.RFFrequency);
settings.Power = SX1276LoRaGetRFPower();
KPrintf("RFPower is %d\n",settings.Power);
settings.SignalBw = SX1276LoRaGetSignalBandwidth();
KPrintf("SignalBw is %d\n",settings.SignalBw);
settings.SpreadingFactor = SX1276LoRaGetSpreadingFactor();
KPrintf("SpreadingFactor is %d\n",settings.SpreadingFactor);
/*SPI confirm*/
SX1276Write(REG_LR_HOPPERIOD, 0x91);
SX1276Read(REG_LR_HOPPERIOD, &test);
if (test != 0x91) {
return 0;
}
return test;
}
/**
* This function supports to write data to the lora.
*
* @param dev lora dev descriptor
* @param write_param lora dev write datacfg param
*/
static uint32 SpiLoraWrite(void *dev, struct BusBlockWriteParam *write_param)
{
NULL_PARAM_CHECK(dev);
NULL_PARAM_CHECK(write_param);
if (write_param->size > 256) {
KPrintf("SpiLoraWrite ERROR:The message is too long!\n");
return ERROR;
} else {
SX1276SetTx(write_param->buffer, write_param->size);
KPrintf("SpiLoraWrite success!\n");
}
return EOK;
}
/**
* This function supports to read data from the lora.
*
* @param dev lora dev descriptor
* @param read_param lora dev read datacfg param
*/
static uint32 SpiLoraRead(void *dev, struct BusBlockReadParam *read_param)
{
NULL_PARAM_CHECK(dev);
NULL_PARAM_CHECK(read_param);
KPrintf("SpiLoraRead Ready!\n");
int ret = SX1276GetRx(read_param->buffer, (uint16 *)&read_param->read_length);
if (ret < 0) {
return 0;
}
return read_param->read_length;
}
static uint32 SpiLoraOpen(void *dev)
{
NULL_PARAM_CHECK(dev);
KPrintf("SpiLoraOpen start\n");
x_err_t ret = EOK;
static x_bool lora_init_status = RET_FALSE;
if (RET_TRUE == lora_init_status) {
return EOK;
}
struct HardwareDev *haldev = (struct HardwareDev *)dev;
struct SpiHardwareDevice *lora_dev = CONTAINER_OF(haldev, struct SpiHardwareDevice, haldev);
NULL_PARAM_CHECK(lora_dev);
SpiLoraDeviceType spi_lora_dev = CONTAINER_OF(lora_dev, struct SpiLoraDevice, lora_dev);
NULL_PARAM_CHECK(spi_lora_dev);
struct Driver *spi_drv = spi_lora_dev->spi_dev->haldev.owner_bus->owner_driver;
struct BusConfigureInfo configure_info;
struct SpiMasterParam spi_master_param;
spi_master_param.spi_data_bit_width = 8;
spi_master_param.spi_work_mode = SPI_MODE_0 | SPI_MSB;
configure_info.configure_cmd = OPE_CFG;
configure_info.private_data = (void *)&spi_master_param;
ret = BusDrvConfigure(spi_drv, &configure_info);
if (ret) {
KPrintf("spi drv OPE_CFG error drv %8p cfg %8p\n", spi_drv, &spi_master_param);
return ERROR;
}
configure_info.configure_cmd = OPE_INT;
ret = BusDrvConfigure(spi_drv, &configure_info);
if (ret) {
KPrintf("spi drv OPE_INT error drv %8p\n", spi_drv);
return ERROR;
}
SX1276Init();
if (0x91 != Sx1276SpiCheck()) {
KPrintf("LoRa check failed!\n!");
} else {
Radio = RadioDriverInit();
KPrintf("LoRa check ok!\nNote: The length of the message that can be sent in a single time is 256 characters\n");
}
lora_init_status = RET_TRUE;
return ret;
}
static uint32 SpiLoraClose(void *dev)
{
NULL_PARAM_CHECK(dev);
return EOK;
}
static const struct LoraDevDone lora_done =
{
.open = SpiLoraOpen,
.close = SpiLoraClose,
.write = SpiLoraWrite,
.read = SpiLoraRead,
};
/**
* This function supports to init spi_lora_dev
*
* @param bus_name spi bus name
* @param dev_name spi dev name
* @param drv_name spi drv name
* @param lora_name lora dev name
*/
SpiLoraDeviceType SpiLoraInit(char *bus_name, char *dev_name, char *drv_name, char *lora_name)
{
NULL_PARAM_CHECK(dev_name);
NULL_PARAM_CHECK(drv_name);
NULL_PARAM_CHECK(lora_name);
NULL_PARAM_CHECK(bus_name);
x_err_t ret;
static HardwareDevType haldev;
haldev = SpiDeviceFind(dev_name, TYPE_SPI_DEV);
if (NONE == haldev) {
KPrintf("SpiLoraInit find spi haldev %s error! \n", dev_name);
return NONE;
}
SpiLoraDeviceType spi_lora_dev = (SpiLoraDeviceType)malloc(sizeof(struct SpiLoraDevice));
if (NONE == spi_lora_dev) {
KPrintf("SpiLoraInit malloc spi_lora_dev failed\n");
free(spi_lora_dev);
return NONE;
}
memset(spi_lora_dev, 0, sizeof(struct SpiLoraDevice));
spi_lora_dev->spi_dev = CONTAINER_OF(haldev, struct SpiHardwareDevice, haldev);
spi_lora_dev->lora_dev.spi_dev_flag = RET_TRUE;
spi_lora_dev->lora_dev.haldev.dev_done = (struct HalDevDone *)&lora_done;
struct Driver *spi_driver = SpiDriverFind(drv_name, TYPE_SPI_DRV);
if (NONE == spi_driver) {
KPrintf("SpiLoraInit find spi driver %s error! \n", drv_name);
free(spi_lora_dev);
return NONE;
}
//spi drv get spi dev param (SpiDeviceParam)
spi_driver->private_data = spi_lora_dev->spi_dev->haldev.private_data;
spi_lora_dev->spi_dev->haldev.owner_bus->owner_driver = spi_driver;
ret = SpiDeviceRegister(&spi_lora_dev->lora_dev, spi_lora_dev->spi_dev->haldev.private_data, lora_name);
if (EOK != ret) {
KPrintf("SpiLoraInit SpiDeviceRegister device %s error %d\n", lora_name, ret);
free(spi_lora_dev);
return NONE;
}
ret = SpiDeviceAttachToBus(lora_name, bus_name);
if (EOK != ret) {
KPrintf("SpiLoraInit SpiDeviceAttachToBus device %s error %d\n", lora_name, ret);
free(spi_lora_dev);
return NONE;
}
g_spi_lora_dev = &spi_lora_dev->spi_dev->haldev;
return spi_lora_dev;
}
/**
* This function supports to release spi_lora_dev
*
* @param spi_lora_dev spi lora descriptor
*/
uint32 SpiLoraRelease(SpiLoraDeviceType spi_lora_dev)
{
NULL_PARAM_CHECK(spi_lora_dev);
x_err_t ret;
DeviceDeleteFromBus(spi_lora_dev->lora_dev.haldev.owner_bus, &spi_lora_dev->lora_dev.haldev);
free(spi_lora_dev);
return EOK;
}
int LoraSx12xxSpiDeviceInit(void)
{
#ifdef BSP_USING_SPI1
if (NONE == SpiLoraInit(SPI_BUS_NAME_1, SPI_1_DEVICE_NAME_0, SPI_1_DRV_NAME, SX12XX_DEVICE_NAME)) {
return ERROR;
}
#endif
return EOK;
}
#define LORA_TEST
#ifdef LORA_TEST
/*Just for lora test*/
static struct Bus *bus;
static struct HardwareDev *dev;
void LoraOpen(void)
{
x_err_t ret = EOK;
bus = BusFind(SPI_BUS_NAME_1);
dev = BusFindDevice(bus, SX12XX_DEVICE_NAME);
ret = SpiLoraOpen(dev);
if (EOK != ret) {
KPrintf("LoRa init failed\n");
return;
}
KPrintf("LoRa init succeed\n");
return;
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0)|SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN),
LoraOpen, LoraOpen, open lora device and read parameters );
static void LoraReceive(void)
{
uint32 read_length = 0;
struct BusBlockReadParam read_param;
memset(&read_param, 0, sizeof(struct BusBlockReadParam));
read_param.buffer = malloc(SPI_LORA_BUFFER_SIZE);
read_length = SpiLoraRead(dev, &read_param);
KPrintf("LoraReceive length %d\n", read_length);
for (int i = 0; i < read_length; i ++) {
KPrintf("i %d data 0x%x\n", i, ((uint8 *)read_param.buffer)[i]);
}
free(read_param.buffer);
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0)|SHELL_CMD_TYPE(SHELL_TYPE_CMD_FUNC)|SHELL_CMD_PARAM_NUM(0),
LoraReceive, LoraReceive, lora wait message );
static void LoraSend(int argc, char *argv[])
{
char Msg[SPI_LORA_BUFFER_SIZE] = {0};
struct BusBlockWriteParam write_param;
memset(&write_param, 0, sizeof(struct BusBlockWriteParam));
if (argc == 2) {
strncpy(Msg, argv[1], SPI_LORA_BUFFER_SIZE);
write_param.buffer = Msg;
write_param.size = strlen(Msg);
KPrintf("LoraSend data %s length %d\n", Msg, strlen(Msg));
SpiLoraWrite(dev, &write_param);
}
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0)|SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN),
LoraSend, LoraSend, lora send message );
#endif

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ifeq ($(CONFIG_RESOURCES_SPI_LORA),y)
SRC_DIR := sx12xx
endif
include $(KERNEL_ROOT)/compiler.mk

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SRC_DIR := src
include $(KERNEL_ROOT)/compiler.mk

51
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/spi/third_party_spi_lora/sx12xx/inc/spi_lora_sx12xx.h Normal file
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/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file spi_lora_sx12xx.h
* @brief define spi lora driver function
* @version 2.0
* @author AIIT XUOS Lab
* @date 2022-10-31
*/
#ifndef SPI_LORA_SX12XX_H
#define SPI_LORA_SX12XX_H
#include <connect_spi_lora.h>
#ifdef __cplusplus
extern "C" {
#endif
uint8_t SX1276ReadDio0(void);
uint8_t SX1276ReadDio1(void);
uint8_t SX1276ReadDio2(void);
uint8_t SX1276ReadDio3(void);
uint8_t SX1276ReadDio4(void);
uint8_t SX1276ReadDio5(void);
void SX1276Write(uint8_t addr, uint8_t data);
void SX1276Read(uint8_t addr, uint8_t *data);
void SX1276WriteBuffer(uint8_t addr, uint8_t *buffer, uint8_t size);
void SX1276ReadBuffer(uint8_t addr, uint8_t *buffer, uint8_t size);
void SX1276WriteFifo(uint8_t *buffer, uint8_t size);
void SX1276ReadFifo(uint8_t *buffer, uint8_t size);
void SX1276SetReset(uint8_t state);
uint8_t Sx1276SpiCheck(void);
void SX1276WriteRxTx(uint8_t txEnable);
#ifdef __cplusplus
}
#endif
#endif

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SRC_DIR := radio
include $(KERNEL_ROOT)/compiler.mk

3
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SRC_FILES := radio.c sx1276-Fsk.c sx1276-FskMisc.c sx1276-LoRa.c sx1276-LoRaMisc.c sx1276.c
include $(KERNEL_ROOT)/compiler.mk

96
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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file platform.h
* \brief
*
* \version 1.0
* \date Nov 21 2012
* \author Miguel Luis
*/
/*************************************************
File name: platform.h
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#ifndef __PLATFORM_H__
#define __PLATFORM_H__
#ifndef __GNUC__
#define inline
#endif
/*!
* Platform definition
*/
#define Bleeper 3
#define SX1243ska 2
#define SX12xxEiger 1
#define SX12000DVK 0
/*!
* Platform choice. Please uncoment the PLATFORM define and choose your platform
* or add/change the PLATFORM definition on the compiler Defines option
*/
#define PLATFORM SX12xxEiger
#if( PLATFORM == SX12xxEiger )
/*!
* Radio choice. Please uncomment the wanted radio and comment the others
* or add/change wanted radio definition on the compiler Defines option
*/
//#define USE_SX1232_RADIO
//#define USE_SX1272_RADIO
#define USE_SX1276_RADIO
//#define USE_SX1243_RADIO
/*!
* Module choice. There are three existing module with the SX1276.
* Please set the connected module to the value 1 and set the others to 0
*/
#ifdef USE_SX1276_RADIO
#define MODULE_SX1276RF1IAS 0
#define MODULE_SX1276RF1JAS 0
#define MODULE_SX1276RF1KAS 1
#endif
#include <spi_lora_sx12xx.h>
#define USE_UART 0
#elif( PLATFORM == SX12000DVK )
/*!
* Radio choice. Please uncomment the wanted radio and comment the others
* or add/change wanted radio definition on the compiler Defines option
*/
//#define USE_SX1232_RADIO
#define USE_SX1272_RADIO
//#define USE_SX1276_RADIO
//#define USE_SX1243_RADIO
#include "sx1200dvk/sx1200dvk.h"
#elif( PLATFORM == SX1243ska )
#elif( PLATFORM == Bleeper )
#define USE_SX1272_RADIO
#include "bleeper/bleeper.h"
#define USE_UART 0
#else
#error "Missing define: Platform (ie. SX12xxEiger)"
#endif
#endif // __PLATFORM_H__

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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file radio.c
* \brief Generic radio driver ( radio abstraction )
*
* \version 2.0.0
* \date Nov 21 2012
* \author Miguel Luis
*
* Last modified by Gregory Cristian on Apr 25 2013
*/
/*************************************************
File name: radio.c
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#include <stdint.h>
#include "platform.h"
#include "radio.h"
#if defined( USE_SX1232_RADIO )
#include "sx1232.h"
#elif defined( USE_SX1272_RADIO )
#include "sx1272.h"
#elif defined( USE_SX1276_RADIO )
#include "sx1276.h"
#else
#error "Missing define: USE_XXXXXX_RADIO (ie. USE_SX1272_RADIO)"
#endif
tRadioDriver RadioDriver;
tRadioDriver* RadioDriverInit( void )
{
#if defined( USE_SX1232_RADIO )
RadioDriver.Init = SX1232Init;
RadioDriver.Reset = SX1232Reset;
RadioDriver.StartRx = SX1232StartRx;
RadioDriver.GetRxPacket = SX1232GetRxPacket;
RadioDriver.SetTxPacket = SX1232SetTxPacket;
RadioDriver.Process = SX1232Process;
#elif defined( USE_SX1272_RADIO )
RadioDriver.Init = SX1272Init;
RadioDriver.Reset = SX1272Reset;
RadioDriver.StartRx = SX1272StartRx;
RadioDriver.GetRxPacket = SX1272GetRxPacket;
RadioDriver.SetTxPacket = SX1272SetTxPacket;
RadioDriver.Process = SX1272Process;
#elif defined( USE_SX1276_RADIO )
RadioDriver.Init = SX1276Init;
RadioDriver.Reset = SX1276Reset;
RadioDriver.StartRx = SX1276StartRx;
RadioDriver.GetRxPacket = SX1276GetRxPacket;
RadioDriver.SetTxPacket = SX1276SetTxPacket;
RadioDriver.Process = SX1276Process;
RadioDriver.ChannelEmpty = SX1276ChannelEmpty;
#else
#error "Missing define: USE_XXXXXX_RADIO (ie. USE_SX1272_RADIO)"
#endif
return &RadioDriver;
}

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@ -0,0 +1,77 @@
/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file radio.h
* \brief Generic radio driver ( radio abstraction )
*
* \version 2.0.B2
* \date Nov 21 2012
* \author Miguel Luis
*
* Last modified by Gregory Cristian on Apr 25 2013
*/
/*************************************************
File name: radio.h
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#ifndef __RADIO_H__
#define __RADIO_H__
/*!
* SX1272 and SX1276 General parameters definition
*/
#define LORA 1 // [0: OFF, 1: ON]
/*!
* RF process function return codes
*/
typedef enum
{
RF_IDLE,
RF_BUSY,
RF_RX_DONE,
RF_RX_TIMEOUT,
RF_TX_DONE,
RF_TX_TIMEOUT,
RF_LEN_ERROR,
RF_CHANNEL_EMPTY,
RF_CHANNEL_ACTIVITY_DETECTED,
}tRFProcessReturnCodes;
/*!
* Radio driver structure defining the different function pointers
*/
typedef struct sRadioDriver
{
void ( *Init )( void );
void ( *Reset )( void );
void ( *StartRx )( void );
void ( *GetRxPacket )( void *buffer, uint16_t *size );
void ( *SetTxPacket )( const void *buffer, uint16_t size );
uint32_t ( *Process )( void );
uint32_t ( *ChannelEmpty )(void );
}tRadioDriver;
/*!
* \brief Initializes the RadioDriver structure with specific radio
* functions.
*
* \retval radioDriver Pointer to the radio driver variable
*/
tRadioDriver* RadioDriverInit( void );
#endif // __RADIO_H__

616
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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file sx1276.c
* \brief SX1276 RF chip driver
*
* \version 2.0.0
* \date May 6 2013
* \author Gregory Cristian
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276-Fsk.c
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#include <string.h>
#include <math.h>
#include "platform.h"
#if defined( USE_SX1276_RADIO )
#include "radio.h"
#include "sx1276-Hal.h"
#include "sx1276.h"
#include "sx1276-FskMisc.h"
#include "sx1276-Fsk.h"
// Default settings
tFskSettings FskSettings =
{
870000000, // RFFrequency
9600, // Bitrate
50000, // Fdev
20, // Power
100000, // RxBw
150000, // RxBwAfc
true, // CrcOn
true, // AfcOn
255 // PayloadLength (set payload size to the maximum for variable mode, else set the exact payload length)
};
/*!
* SX1276 FSK registers variable
*/
tSX1276* SX1276;
/*!
* Local RF buffer for communication support
*/
static uint8_t RFBuffer[RF_BUFFER_SIZE];
/*!
* Chunk size of data write in buffer
*/
static uint8_t DataChunkSize = 32;
/*!
* RF state machine variable
*/
static uint8_t RFState = RF_STATE_IDLE;
/*!
* Rx management support variables
*/
/*!
* PacketTimeout holds the RF packet timeout
* SyncSize = [0..8]
* VariableSize = [0;1]
* AddressSize = [0;1]
* PayloadSize = [0..RF_BUFFER_SIZE]
* CrcSize = [0;2]
* PacketTimeout = ( ( 8 * ( VariableSize + AddressSize + PayloadSize + CrcSize ) / BR ) * 1000.0 ) + 1
* Computed timeout is in miliseconds
*/
static uint32_t PacketTimeout;
/*!
* Preamble2SyncTimeout
* Preamble2SyncTimeout = ( ( 8 * ( PremableSize + SyncSize ) / RFBitrate ) * 1000.0 ) + 1
* Computed timeout is in miliseconds
*/
static uint32_t Preamble2SyncTimeout;
static bool PreambleDetected = false;
static bool SyncWordDetected = false;
static bool PacketDetected = false;
static uint16_t RxPacketSize = 0;
static uint8_t RxBytesRead = 0;
static uint8_t TxBytesSent = 0;
static double RxPacketRssiValue;
static uint32_t RxPacketAfcValue;
static uint8_t RxGain = 1;
static uint32_t RxTimeoutTimer = 0;
static uint32_t Preamble2SyncTimer = 0;
/*!
* Tx management support variables
*/
static uint16_t TxPacketSize = 0;
static uint32_t TxTimeoutTimer = 0;
void SX1276FskInit( void )
{
RFState = RF_STATE_IDLE;
SX1276FskSetDefaults( );
SX1276ReadBuffer( REG_OPMODE, SX1276Regs + 1, 0x70 - 1 );
// Set the device in FSK mode and Sleep Mode
SX1276->RegOpMode = RF_OPMODE_MODULATIONTYPE_FSK | RF_OPMODE_SLEEP;
SX1276Write( REG_OPMODE, SX1276->RegOpMode );
SX1276->RegPaRamp = RF_PARAMP_MODULATIONSHAPING_01;
SX1276Write( REG_PARAMP, SX1276->RegPaRamp );
SX1276->RegLna = RF_LNA_GAIN_G1;
SX1276Write( REG_LNA, SX1276->RegLna );
if( FskSettings.AfcOn == true )
{
SX1276->RegRxConfig = RF_RXCONFIG_RESTARTRXONCOLLISION_OFF | RF_RXCONFIG_AFCAUTO_ON |
RF_RXCONFIG_AGCAUTO_ON | RF_RXCONFIG_RXTRIGER_PREAMBLEDETECT;
}
else
{
SX1276->RegRxConfig = RF_RXCONFIG_RESTARTRXONCOLLISION_OFF | RF_RXCONFIG_AFCAUTO_OFF |
RF_RXCONFIG_AGCAUTO_ON | RF_RXCONFIG_RXTRIGER_PREAMBLEDETECT;
}
SX1276->RegPreambleLsb = 8;
SX1276->RegPreambleDetect = RF_PREAMBLEDETECT_DETECTOR_ON | RF_PREAMBLEDETECT_DETECTORSIZE_2 |
RF_PREAMBLEDETECT_DETECTORTOL_10;
SX1276->RegRssiThresh = 0xFF;
SX1276->RegSyncConfig = RF_SYNCCONFIG_AUTORESTARTRXMODE_WAITPLL_ON | RF_SYNCCONFIG_PREAMBLEPOLARITY_AA |
RF_SYNCCONFIG_SYNC_ON |
RF_SYNCCONFIG_SYNCSIZE_4;
SX1276->RegSyncValue1 = 0x69;
SX1276->RegSyncValue2 = 0x81;
SX1276->RegSyncValue3 = 0x7E;
SX1276->RegSyncValue4 = 0x96;
SX1276->RegPacketConfig1 = RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE | RF_PACKETCONFIG1_DCFREE_OFF |
( FskSettings.CrcOn << 4 ) | RF_PACKETCONFIG1_CRCAUTOCLEAR_ON |
RF_PACKETCONFIG1_ADDRSFILTERING_OFF | RF_PACKETCONFIG1_CRCWHITENINGTYPE_CCITT;
SX1276FskGetPacketCrcOn( ); // Update CrcOn on FskSettings
SX1276->RegPayloadLength = FskSettings.PayloadLength;
// we can now update the registers with our configuration
SX1276WriteBuffer( REG_OPMODE, SX1276Regs + 1, 0x70 - 1 );
// then we need to set the RF settings
SX1276FskSetRFFrequency( FskSettings.RFFrequency );
SX1276FskSetBitrate( FskSettings.Bitrate );
SX1276FskSetFdev( FskSettings.Fdev );
SX1276FskSetDccBw( &SX1276->RegRxBw, 0, FskSettings.RxBw );
SX1276FskSetDccBw( &SX1276->RegAfcBw, 0, FskSettings.RxBwAfc );
SX1276FskSetRssiOffset( 0 );
#if( ( MODULE_SX1276RF1IAS == 1 ) || ( MODULE_SX1276RF1KAS == 1 ) )
if( FskSettings.RFFrequency > 860000000 )
{
SX1276FskSetPAOutput( RF_PACONFIG_PASELECT_RFO );
SX1276FskSetPa20dBm( false );
FskSettings.Power = 14;
SX1276FskSetRFPower( FskSettings.Power );
}
else
{
SX1276FskSetPAOutput( RF_PACONFIG_PASELECT_PABOOST );
SX1276FskSetPa20dBm( true );
FskSettings.Power = 20;
SX1276FskSetRFPower( FskSettings.Power );
}
#elif( MODULE_SX1276RF1JAS == 1 )
if( FskSettings.RFFrequency > 860000000 )
{
SX1276FskSetPAOutput( RF_PACONFIG_PASELECT_PABOOST );
SX1276FskSetPa20dBm( true );
FskSettings.Power = 20;
SX1276FskSetRFPower( FskSettings.Power );
}
else
{
SX1276FskSetPAOutput( RF_PACONFIG_PASELECT_RFO );
SX1276FskSetPa20dBm( false );
FskSettings.Power = 14;
SX1276FskSetRFPower( FskSettings.Power );
}
#endif
SX1276FskSetOpMode( RF_OPMODE_STANDBY );
// Calibrate the HF
SX1276FskRxCalibrate( );
}
void SX1276FskSetDefaults( void )
{
// REMARK: See SX1276 datasheet for modified default values.
SX1276Read( REG_VERSION, &SX1276->RegVersion );
}
void SX1276FskSetOpMode( uint8_t opMode )
{
static uint8_t opModePrev = RF_OPMODE_STANDBY;
static bool antennaSwitchTxOnPrev = true;
bool antennaSwitchTxOn = false;
opModePrev = SX1276->RegOpMode & ~RF_OPMODE_MASK;
if( opMode != opModePrev )
{
if( opMode == RF_OPMODE_TRANSMITTER )
{
antennaSwitchTxOn = true;
}
else
{
antennaSwitchTxOn = false;
}
if( antennaSwitchTxOn != antennaSwitchTxOnPrev )
{
antennaSwitchTxOnPrev = antennaSwitchTxOn;
RXTX( antennaSwitchTxOn ); // Antenna switch control
}
SX1276->RegOpMode = ( SX1276->RegOpMode & RF_OPMODE_MASK ) | opMode;
SX1276Write( REG_OPMODE, SX1276->RegOpMode );
}
}
uint8_t SX1276FskGetOpMode( void )
{
SX1276Read( REG_OPMODE, &SX1276->RegOpMode );
return SX1276->RegOpMode & ~RF_OPMODE_MASK;
}
int32_t SX1276FskReadFei( void )
{
SX1276ReadBuffer( REG_FEIMSB, &SX1276->RegFeiMsb, 2 ); // Reads the FEI value
return ( int32_t )( double )( ( ( uint16_t )SX1276->RegFeiMsb << 8 ) | ( uint16_t )SX1276->RegFeiLsb ) * ( double )FREQ_STEP;
}
int32_t SX1276FskReadAfc( void )
{
SX1276ReadBuffer( REG_AFCMSB, &SX1276->RegAfcMsb, 2 ); // Reads the AFC value
return ( int32_t )( double )( ( ( uint16_t )SX1276->RegAfcMsb << 8 ) | ( uint16_t )SX1276->RegAfcLsb ) * ( double )FREQ_STEP;
}
uint8_t SX1276FskReadRxGain( void )
{
SX1276Read( REG_LNA, &SX1276->RegLna );
return( SX1276->RegLna >> 5 ) & 0x07;
}
double SX1276FskReadRssi( void )
{
SX1276Read( REG_RSSIVALUE, &SX1276->RegRssiValue ); // Reads the RSSI value
return -( double )( ( double )SX1276->RegRssiValue / 2.0 );
}
uint8_t SX1276FskGetPacketRxGain( void )
{
return RxGain;
}
double SX1276FskGetPacketRssi( void )
{
return RxPacketRssiValue;
}
uint32_t SX1276FskGetPacketAfc( void )
{
return RxPacketAfcValue;
}
void SX1276FskStartRx( void )
{
SX1276FskSetRFState( RF_STATE_RX_INIT );
}
void SX1276FskGetRxPacket( void *buffer, uint16_t *size )
{
*size = RxPacketSize;
RxPacketSize = 0;
memcpy( ( void * )buffer, ( void * )RFBuffer, ( size_t )*size );
}
void SX1276FskSetTxPacket( const void *buffer, uint16_t size )
{
TxPacketSize = size;
memcpy( ( void * )RFBuffer, buffer, ( size_t )TxPacketSize );
RFState = RF_STATE_TX_INIT;
}
// Remark: SX1276 must be fully initialized before calling this function
uint16_t SX1276FskGetPacketPayloadSize( void )
{
uint16_t syncSize;
uint16_t variableSize;
uint16_t addressSize;
uint16_t payloadSize;
uint16_t crcSize;
syncSize = ( SX1276->RegSyncConfig & 0x07 ) + 1;
variableSize = ( ( SX1276->RegPacketConfig1 & 0x80 ) == 0x80 ) ? 1 : 0;
addressSize = ( ( SX1276->RegPacketConfig1 & 0x06 ) != 0x00 ) ? 1 : 0;
payloadSize = SX1276->RegPayloadLength;
crcSize = ( ( SX1276->RegPacketConfig1 & 0x10 ) == 0x10 ) ? 2 : 0;
return syncSize + variableSize + addressSize + payloadSize + crcSize;
}
// Remark: SX1276 must be fully initialized before calling this function
uint16_t SX1276FskGetPacketHeaderSize( void )
{
uint16_t preambleSize;
uint16_t syncSize;
preambleSize = ( ( uint16_t )SX1276->RegPreambleMsb << 8 ) | ( uint16_t )SX1276->RegPreambleLsb;
syncSize = ( SX1276->RegSyncConfig & 0x07 ) + 1;
return preambleSize + syncSize;
}
uint8_t SX1276FskGetRFState( void )
{
return RFState;
}
void SX1276FskSetRFState( uint8_t state )
{
RFState = state;
}
uint32_t SX1276FskProcess( void )
{
uint32_t result = RF_BUSY;
switch( RFState )
{
case RF_STATE_IDLE:
break;
// Rx management
case RF_STATE_RX_INIT:
// DIO mapping setup
if( ( SX1276->RegPacketConfig1 & RF_PACKETCONFIG1_CRC_ON ) == RF_PACKETCONFIG1_CRC_ON )
{
// CrcOk, FifoLevel, SyncAddr, FifoEmpty
SX1276->RegDioMapping1 = RF_DIOMAPPING1_DIO0_01 | RF_DIOMAPPING1_DIO1_00 | RF_DIOMAPPING1_DIO2_11 | RF_DIOMAPPING1_DIO3_00;
}
else
{
// PayloadReady, FifoLevel, SyncAddr, FifoEmpty
SX1276->RegDioMapping1 = RF_DIOMAPPING1_DIO0_00 | RF_DIOMAPPING1_DIO1_00 | RF_DIOMAPPING1_DIO2_11 | RF_DIOMAPPING1_DIO3_00;
}
// Preamble, Data
SX1276->RegDioMapping2 = RF_DIOMAPPING2_DIO4_11 | RF_DIOMAPPING2_DIO5_10 | RF_DIOMAPPING2_MAP_PREAMBLEDETECT;
SX1276WriteBuffer( REG_DIOMAPPING1, &SX1276->RegDioMapping1, 2 );
SX1276FskSetOpMode( RF_OPMODE_RECEIVER );
memset( RFBuffer, 0, ( size_t )RF_BUFFER_SIZE );
PacketTimeout = ( uint16_t )( round( ( 8.0 * ( ( double )SX1276FskGetPacketPayloadSize( ) ) / ( double )FskSettings.Bitrate ) * 1000.0 ) + 1.0 );
PacketTimeout = PacketTimeout + ( PacketTimeout >> 1 ); // Set the Packet timeout as 1.5 times the full payload transmission time
Preamble2SyncTimeout = PacketTimeout;
Preamble2SyncTimer = RxTimeoutTimer = GET_TICK_COUNT( );
SX1276->RegFifoThresh = RF_FIFOTHRESH_TXSTARTCONDITION_FIFONOTEMPTY | 0x20; // 32 bytes of data
SX1276Write( REG_FIFOTHRESH, SX1276->RegFifoThresh );
PreambleDetected = false;
SyncWordDetected = false;
PacketDetected = false;
RxBytesRead = 0;
RxPacketSize = 0;
RFState = RF_STATE_RX_SYNC;
break;
case RF_STATE_RX_SYNC:
if( ( DIO4 == 1 ) && ( PreambleDetected == false ) )// Preamble
{
PreambleDetected = true;
Preamble2SyncTimer = GET_TICK_COUNT( );
}
if( ( DIO2 == 1 ) && ( PreambleDetected == true ) && ( SyncWordDetected == false ) ) // SyncAddr
{
SyncWordDetected = true;
RxPacketRssiValue = SX1276FskReadRssi( );
RxPacketAfcValue = SX1276FskReadAfc( );
RxGain = SX1276FskReadRxGain( );
Preamble2SyncTimer = RxTimeoutTimer = GET_TICK_COUNT( );
RFState = RF_STATE_RX_RUNNING;
}
// Preamble 2 SyncAddr timeout
if( ( SyncWordDetected == false ) && ( PreambleDetected == true ) && ( ( GET_TICK_COUNT( ) - Preamble2SyncTimer ) > Preamble2SyncTimeout ) )
{
RFState = RF_STATE_RX_INIT;
SX1276Write( REG_RXCONFIG, SX1276->RegRxConfig | RF_RXCONFIG_RESTARTRXWITHPLLLOCK );
}
if( ( SyncWordDetected == false ) &&
( PreambleDetected == false ) &&
( PacketDetected == false ) &&
( ( GET_TICK_COUNT( ) - RxTimeoutTimer ) > PacketTimeout ) )
{
RFState = RF_STATE_RX_TIMEOUT;
}
break;
case RF_STATE_RX_RUNNING:
if( RxPacketSize > RF_BUFFER_SIZE_MAX )
{
RFState = RF_STATE_RX_LEN_ERROR;
break;
}
#if 1
if( DIO1 == 1 ) // FifoLevel
{
if( ( RxPacketSize == 0 ) && ( RxBytesRead == 0 ) ) // Read received packet size
{
if( ( SX1276->RegPacketConfig1 & RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE ) == RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE )
{
SX1276ReadFifo( ( uint8_t* )&RxPacketSize, 1 );
}
else
{
RxPacketSize = SX1276->RegPayloadLength;
}
}
if( ( RxPacketSize - RxBytesRead ) > ( SX1276->RegFifoThresh & 0x3F ) )
{
SX1276ReadFifo( ( RFBuffer + RxBytesRead ), ( SX1276->RegFifoThresh & 0x3F ) );
RxBytesRead += ( SX1276->RegFifoThresh & 0x3F );
}
else
{
SX1276ReadFifo( ( RFBuffer + RxBytesRead ), RxPacketSize - RxBytesRead );
RxBytesRead += ( RxPacketSize - RxBytesRead );
}
}
#endif
if( DIO0 == 1 ) // PayloadReady/CrcOk
{
RxTimeoutTimer = GET_TICK_COUNT( );
if( ( RxPacketSize == 0 ) && ( RxBytesRead == 0 ) ) // Read received packet size
{
if( ( SX1276->RegPacketConfig1 & RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE ) == RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE )
{
SX1276ReadFifo( ( uint8_t* )&RxPacketSize, 1 );
}
else
{
RxPacketSize = SX1276->RegPayloadLength;
}
SX1276ReadFifo( RFBuffer + RxBytesRead, RxPacketSize - RxBytesRead );
RxBytesRead += ( RxPacketSize - RxBytesRead );
PacketDetected = true;
RFState = RF_STATE_RX_DONE;
}
else
{
SX1276ReadFifo( RFBuffer + RxBytesRead, RxPacketSize - RxBytesRead );
RxBytesRead += ( RxPacketSize - RxBytesRead );
PacketDetected = true;
RFState = RF_STATE_RX_DONE;
}
}
// Packet timeout
if( ( PacketDetected == false ) && ( ( GET_TICK_COUNT( ) - RxTimeoutTimer ) > PacketTimeout ) )
{
RFState = RF_STATE_RX_TIMEOUT;
}
break;
case RF_STATE_RX_DONE:
RxBytesRead = 0;
RFState = RF_STATE_RX_INIT;
result = RF_RX_DONE;
break;
case RF_STATE_RX_TIMEOUT:
RxBytesRead = 0;
RxPacketSize = 0;
SX1276Write( REG_RXCONFIG, SX1276->RegRxConfig | RF_RXCONFIG_RESTARTRXWITHPLLLOCK );
RFState = RF_STATE_RX_INIT;
result = RF_RX_TIMEOUT;
break;
case RF_STATE_RX_LEN_ERROR:
RxBytesRead = 0;
RxPacketSize = 0;
SX1276Write( REG_RXCONFIG, SX1276->RegRxConfig | RF_RXCONFIG_RESTARTRXWITHPLLLOCK );
RFState = RF_STATE_RX_INIT;
result = RF_LEN_ERROR;
break;
// Tx management
case RF_STATE_TX_INIT:
// Packet DIO mapping setup
// PacketSent, FifoLevel, FifoFull, TxReady
SX1276->RegDioMapping1 = RF_DIOMAPPING1_DIO0_00 | RF_DIOMAPPING1_DIO1_00 | RF_DIOMAPPING1_DIO2_00 | RF_DIOMAPPING1_DIO3_01;
// LowBat, Data
SX1276->RegDioMapping2 = RF_DIOMAPPING2_DIO4_00 | RF_DIOMAPPING2_DIO5_10;
SX1276WriteBuffer( REG_DIOMAPPING1, &SX1276->RegDioMapping1, 2 );
SX1276->RegFifoThresh = RF_FIFOTHRESH_TXSTARTCONDITION_FIFONOTEMPTY | 0x18; // 24 bytes of data
SX1276Write( REG_FIFOTHRESH, SX1276->RegFifoThresh );
SX1276FskSetOpMode( RF_OPMODE_TRANSMITTER );
RFState = RF_STATE_TX_READY_WAIT;
TxBytesSent = 0;
break;
case RF_STATE_TX_READY_WAIT:
if( DIO3 == 1 ) // TxReady
{
if( ( SX1276->RegPacketConfig1 & RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE ) == RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE )
{
SX1276WriteFifo( ( uint8_t* )&TxPacketSize, 1 );
}
if( ( TxPacketSize > 0 ) && ( TxPacketSize <= 64 ) )
{
DataChunkSize = TxPacketSize;
}
else
{
DataChunkSize = 32;
}
SX1276WriteFifo( RFBuffer, DataChunkSize );
TxBytesSent += DataChunkSize;
TxTimeoutTimer = GET_TICK_COUNT( );
RFState = RF_STATE_TX_RUNNING;
}
break;
case RF_STATE_TX_RUNNING:
if( DIO1 == 0 ) // FifoLevel below thresold
{
if( ( TxPacketSize - TxBytesSent ) > DataChunkSize )
{
SX1276WriteFifo( ( RFBuffer + TxBytesSent ), DataChunkSize );
TxBytesSent += DataChunkSize;
}
else
{
// we write the last chunk of data
SX1276WriteFifo( RFBuffer + TxBytesSent, TxPacketSize - TxBytesSent );
TxBytesSent += TxPacketSize - TxBytesSent;
}
}
if( DIO0 == 1 ) // PacketSent
{
TxTimeoutTimer = GET_TICK_COUNT( );
RFState = RF_STATE_TX_DONE;
SX1276FskSetOpMode( RF_OPMODE_STANDBY );
}
// Packet timeout
if( ( GET_TICK_COUNT( ) - TxTimeoutTimer ) > TICK_RATE_MS( 1000 ) )
{
RFState = RF_STATE_TX_TIMEOUT;
}
break;
case RF_STATE_TX_DONE:
RFState = RF_STATE_IDLE;
result = RF_TX_DONE;
break;
case RF_STATE_TX_TIMEOUT:
RFState = RF_STATE_IDLE;
result = RF_TX_TIMEOUT;
break;
default:
break;
}
return result;
}
#endif // USE_SX1276_RADIO

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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file sx1276-FskMisc.c
* \brief SX1276 RF chip high level functions driver
*
* \remark Optional support functions.
* These functions are defined only to easy the change of the
* parameters.
* For a final firmware the radio parameters will be known so
* there is no need to support all possible parameters.
* Removing these functions will greatly reduce the final firmware
* size.
*
* \version 2.0.0
* \date May 6 2013
* \author Gregory Cristian
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276-FskMisc.c
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#include <math.h>
#include "platform.h"
#if defined( USE_SX1276_RADIO )
#include "sx1276-Hal.h"
#include "sx1276.h"
#include "sx1276-Fsk.h"
#include "sx1276-FskMisc.h"
extern tFskSettings FskSettings;
void SX1276FskSetRFFrequency( uint32_t freq )
{
FskSettings.RFFrequency = freq;
freq = ( uint32_t )( ( double )freq / ( double )FREQ_STEP );
SX1276->RegFrfMsb = ( uint8_t )( ( freq >> 16 ) & 0xFF );
SX1276->RegFrfMid = ( uint8_t )( ( freq >> 8 ) & 0xFF );
SX1276->RegFrfLsb = ( uint8_t )( freq & 0xFF );
SX1276WriteBuffer( REG_FRFMSB, &SX1276->RegFrfMsb, 3 );
}
uint32_t SX1276FskGetRFFrequency( void )
{
SX1276ReadBuffer( REG_FRFMSB, &SX1276->RegFrfMsb, 3 );
FskSettings.RFFrequency = ( ( uint32_t )SX1276->RegFrfMsb << 16 ) | ( ( uint32_t )SX1276->RegFrfMid << 8 ) | ( ( uint32_t )SX1276->RegFrfLsb );
FskSettings.RFFrequency = ( uint32_t )( ( double )FskSettings.RFFrequency * ( double )FREQ_STEP );
return FskSettings.RFFrequency;
}
void SX1276FskRxCalibrate( void )
{
// the function RadioRxCalibrate is called just after the reset so all register are at their default values
uint8_t regPaConfigInitVal;
uint32_t initialFreq;
// save register values;
SX1276Read( REG_PACONFIG, &regPaConfigInitVal );
initialFreq = SX1276FskGetRFFrequency( );
// Cut the PA just in case
SX1276->RegPaConfig = 0x00; // RFO output, power = -1 dBm
SX1276Write( REG_PACONFIG, SX1276->RegPaConfig );
// Set Frequency in HF band
SX1276FskSetRFFrequency( 860000000 );
// Rx chain re-calibration workaround
SX1276Read( REG_IMAGECAL, &SX1276->RegImageCal );
SX1276->RegImageCal = ( SX1276->RegImageCal & RF_IMAGECAL_IMAGECAL_MASK ) | RF_IMAGECAL_IMAGECAL_START;
SX1276Write( REG_IMAGECAL, SX1276->RegImageCal );
SX1276Read( REG_IMAGECAL, &SX1276->RegImageCal );
// rx_cal_run goes low when calibration in finished
while( ( SX1276->RegImageCal & RF_IMAGECAL_IMAGECAL_RUNNING ) == RF_IMAGECAL_IMAGECAL_RUNNING )
{
SX1276Read( REG_IMAGECAL, &SX1276->RegImageCal );
}
// reload saved values into the registers
SX1276->RegPaConfig = regPaConfigInitVal;
SX1276Write( REG_PACONFIG, SX1276->RegPaConfig );
SX1276FskSetRFFrequency( initialFreq );
}
void SX1276FskSetBitrate( uint32_t bitrate )
{
FskSettings.Bitrate = bitrate;
bitrate = ( uint16_t )( ( double )XTAL_FREQ / ( double )bitrate );
SX1276->RegBitrateMsb = ( uint8_t )( bitrate >> 8 );
SX1276->RegBitrateLsb = ( uint8_t )( bitrate & 0xFF );
SX1276WriteBuffer( REG_BITRATEMSB, &SX1276->RegBitrateMsb, 2 );
}
uint32_t SX1276FskGetBitrate( void )
{
SX1276ReadBuffer( REG_BITRATEMSB, &SX1276->RegBitrateMsb, 2 );
FskSettings.Bitrate = ( ( ( uint32_t )SX1276->RegBitrateMsb << 8 ) | ( ( uint32_t )SX1276->RegBitrateLsb ) );
FskSettings.Bitrate = ( uint16_t )( ( double )XTAL_FREQ / ( double )FskSettings.Bitrate );
return FskSettings.Bitrate;
}
void SX1276FskSetFdev( uint32_t fdev )
{
FskSettings.Fdev = fdev;
SX1276Read( REG_FDEVMSB, &SX1276->RegFdevMsb );
fdev = ( uint16_t )( ( double )fdev / ( double )FREQ_STEP );
SX1276->RegFdevMsb = ( ( SX1276->RegFdevMsb & RF_FDEVMSB_FDEV_MASK ) | ( ( ( uint8_t )( fdev >> 8 ) ) & ~RF_FDEVMSB_FDEV_MASK ) );
SX1276->RegFdevLsb = ( uint8_t )( fdev & 0xFF );
SX1276WriteBuffer( REG_FDEVMSB, &SX1276->RegFdevMsb, 2 );
}
uint32_t SX1276FskGetFdev( void )
{
SX1276ReadBuffer( REG_FDEVMSB, &SX1276->RegFdevMsb, 2 );
FskSettings.Fdev = ( ( ( uint32_t )( ( SX1276->RegFdevMsb << 8 ) & ~RF_FDEVMSB_FDEV_MASK ) ) | ( ( uint32_t )SX1276->RegFdevLsb ) );
FskSettings.Fdev = ( uint16_t )( ( double )FskSettings.Fdev * ( double )FREQ_STEP );
return FskSettings.Fdev;
}
void SX1276FskSetRFPower( int8_t power )
{
SX1276Read( REG_PACONFIG, &SX1276->RegPaConfig );
SX1276Read( REG_PADAC, &SX1276->RegPaDac );
if( ( SX1276->RegPaConfig & RF_PACONFIG_PASELECT_PABOOST ) == RF_PACONFIG_PASELECT_PABOOST )
{
if( ( SX1276->RegPaDac & 0x87 ) == 0x87 )
{
if( power < 5 )
{
power = 5;
}
if( power > 20 )
{
power = 20;
}
SX1276->RegPaConfig = ( SX1276->RegPaConfig & RF_PACONFIG_MAX_POWER_MASK ) | 0x70;
SX1276->RegPaConfig = ( SX1276->RegPaConfig & RF_PACONFIG_OUTPUTPOWER_MASK ) | ( uint8_t )( ( uint16_t )( power - 5 ) & 0x0F );
}
else
{
if( power < 2 )
{
power = 2;
}
if( power > 17 )
{
power = 17;
}
SX1276->RegPaConfig = ( SX1276->RegPaConfig & RF_PACONFIG_MAX_POWER_MASK ) | 0x70;
SX1276->RegPaConfig = ( SX1276->RegPaConfig & RF_PACONFIG_OUTPUTPOWER_MASK ) | ( uint8_t )( ( uint16_t )( power - 2 ) & 0x0F );
}
}
else
{
if( power < -1 )
{
power = -1;
}
if( power > 14 )
{
power = 14;
}
SX1276->RegPaConfig = ( SX1276->RegPaConfig & RF_PACONFIG_MAX_POWER_MASK ) | 0x70;
SX1276->RegPaConfig = ( SX1276->RegPaConfig & RF_PACONFIG_OUTPUTPOWER_MASK ) | ( uint8_t )( ( uint16_t )( power + 1 ) & 0x0F );
}
SX1276Write( REG_PACONFIG, SX1276->RegPaConfig );
FskSettings.Power = power;
}
int8_t SX1276FskGetRFPower( void )
{
SX1276Read( REG_PACONFIG, &SX1276->RegPaConfig );
SX1276Read( REG_PADAC, &SX1276->RegPaDac );
if( ( SX1276->RegPaConfig & RF_PACONFIG_PASELECT_PABOOST ) == RF_PACONFIG_PASELECT_PABOOST )
{
if( ( SX1276->RegPaDac & 0x07 ) == 0x07 )
{
FskSettings.Power = 5 + ( SX1276->RegPaConfig & ~RF_PACONFIG_OUTPUTPOWER_MASK );
}
else
{
FskSettings.Power = 2 + ( SX1276->RegPaConfig & ~RF_PACONFIG_OUTPUTPOWER_MASK );
}
}
else
{
FskSettings.Power = -1 + ( SX1276->RegPaConfig & ~RF_PACONFIG_OUTPUTPOWER_MASK );
}
return FskSettings.Power;
}
/*!
* \brief Computes the Rx bandwidth with the mantisse and exponent
*
* \param [IN] mantisse Mantisse of the bandwidth value
* \param [IN] exponent Exponent of the bandwidth value
* \retval bandwidth Computed bandwidth
*/
static uint32_t SX1276FskComputeRxBw( uint8_t mantisse, uint8_t exponent )
{
// rxBw
if( ( SX1276->RegOpMode & RF_OPMODE_MODULATIONTYPE_FSK ) == RF_OPMODE_MODULATIONTYPE_FSK )
{
return ( uint32_t )( ( double )XTAL_FREQ / ( mantisse * ( double )pow( 2, exponent + 2 ) ) );
}
else
{
return ( uint32_t )( ( double )XTAL_FREQ / ( mantisse * ( double )pow( 2, exponent + 3 ) ) );
}
}
/*!
* \brief Computes the mantisse and exponent from the bandwitdh value
*
* \param [IN] rxBwValue Bandwidth value
* \param [OUT] mantisse Mantisse of the bandwidth value
* \param [OUT] exponent Exponent of the bandwidth value
*/
static void SX1276FskComputeRxBwMantExp( uint32_t rxBwValue, uint8_t* mantisse, uint8_t* exponent )
{
uint8_t tmpExp = 0;
uint8_t tmpMant = 0;
double tmpRxBw = 0;
double rxBwMin = 10e6;
for( tmpExp = 0; tmpExp < 8; tmpExp++ )
{
for( tmpMant = 16; tmpMant <= 24; tmpMant += 4 )
{
if( ( SX1276->RegOpMode & RF_OPMODE_MODULATIONTYPE_FSK ) == RF_OPMODE_MODULATIONTYPE_FSK )
{
tmpRxBw = ( double )XTAL_FREQ / ( tmpMant * ( double )pow( 2, tmpExp + 2 ) );
}
else
{
tmpRxBw = ( double )XTAL_FREQ / ( tmpMant * ( double )pow( 2, tmpExp + 3 ) );
}
if( fabs( tmpRxBw - rxBwValue ) < rxBwMin )
{
rxBwMin = fabs( tmpRxBw - rxBwValue );
*mantisse = tmpMant;
*exponent = tmpExp;
}
}
}
}
void SX1276FskSetDccBw( uint8_t* reg, uint32_t dccValue, uint32_t rxBwValue )
{
uint8_t mantisse = 0;
uint8_t exponent = 0;
if( reg == &SX1276->RegRxBw )
{
*reg = ( uint8_t )dccValue & 0x60;
}
else
{
*reg = 0;
}
SX1276FskComputeRxBwMantExp( rxBwValue, &mantisse, &exponent );
switch( mantisse )
{
case 16:
*reg |= ( uint8_t )( 0x00 | ( exponent & 0x07 ) );
break;
case 20:
*reg |= ( uint8_t )( 0x08 | ( exponent & 0x07 ) );
break;
case 24:
*reg |= ( uint8_t )( 0x10 | ( exponent & 0x07 ) );
break;
default:
// Something went terribely wrong
break;
}
if( reg == &SX1276->RegRxBw )
{
SX1276Write( REG_RXBW, *reg );
FskSettings.RxBw = rxBwValue;
}
else
{
SX1276Write( REG_AFCBW, *reg );
FskSettings.RxBwAfc = rxBwValue;
}
}
uint32_t SX1276FskGetBw( uint8_t* reg )
{
uint32_t rxBwValue = 0;
uint8_t mantisse = 0;
switch( ( *reg & 0x18 ) >> 3 )
{
case 0:
mantisse = 16;
break;
case 1:
mantisse = 20;
break;
case 2:
mantisse = 24;
break;
default:
break;
}
rxBwValue = SX1276FskComputeRxBw( mantisse, ( uint8_t )*reg & 0x07 );
if( reg == &SX1276->RegRxBw )
{
return FskSettings.RxBw = rxBwValue;
}
else
{
return FskSettings.RxBwAfc = rxBwValue;
}
}
void SX1276FskSetPacketCrcOn( bool enable )
{
SX1276Read( REG_PACKETCONFIG1, &SX1276->RegPacketConfig1 );
SX1276->RegPacketConfig1 = ( SX1276->RegPacketConfig1 & RF_PACKETCONFIG1_CRC_MASK ) | ( enable << 4 );
SX1276Write( REG_PACKETCONFIG1, SX1276->RegPacketConfig1 );
FskSettings.CrcOn = enable;
}
bool SX1276FskGetPacketCrcOn( void )
{
SX1276Read( REG_PACKETCONFIG1, &SX1276->RegPacketConfig1 );
FskSettings.CrcOn = ( SX1276->RegPacketConfig1 & RF_PACKETCONFIG1_CRC_ON ) >> 4;
return FskSettings.CrcOn;
}
void SX1276FskSetAfcOn( bool enable )
{
SX1276Read( REG_RXCONFIG, &SX1276->RegRxConfig );
SX1276->RegRxConfig = ( SX1276->RegRxConfig & RF_RXCONFIG_AFCAUTO_MASK ) | ( enable << 4 );
SX1276Write( REG_RXCONFIG, SX1276->RegRxConfig );
FskSettings.AfcOn = enable;
}
bool SX1276FskGetAfcOn( void )
{
SX1276Read( REG_RXCONFIG, &SX1276->RegRxConfig );
FskSettings.AfcOn = ( SX1276->RegRxConfig & RF_RXCONFIG_AFCAUTO_ON ) >> 4;
return FskSettings.AfcOn;
}
void SX1276FskSetPayloadLength( uint8_t value )
{
SX1276->RegPayloadLength = value;
SX1276Write( REG_PAYLOADLENGTH, SX1276->RegPayloadLength );
FskSettings.PayloadLength = value;
}
uint8_t SX1276FskGetPayloadLength( void )
{
SX1276Read( REG_PAYLOADLENGTH, &SX1276->RegPayloadLength );
FskSettings.PayloadLength = SX1276->RegPayloadLength;
return FskSettings.PayloadLength;
}
void SX1276FskSetPa20dBm( bool enale )
{
SX1276Read( REG_PADAC, &SX1276->RegPaDac );
SX1276Read( REG_PACONFIG, &SX1276->RegPaConfig );
if( ( SX1276->RegPaConfig & RF_PACONFIG_PASELECT_PABOOST ) == RF_PACONFIG_PASELECT_PABOOST )
{
if( enale == true )
{
SX1276->RegPaDac = 0x87;
}
}
else
{
SX1276->RegPaDac = 0x84;
}
SX1276Write( REG_PADAC, SX1276->RegPaDac );
}
bool SX1276FskGetPa20dBm( void )
{
SX1276Read( REG_PADAC, &SX1276->RegPaDac );
return ( ( SX1276->RegPaDac & 0x07 ) == 0x07 ) ? true : false;
}
void SX1276FskSetPAOutput( uint8_t outputPin )
{
SX1276Read( REG_PACONFIG, &SX1276->RegPaConfig );
SX1276->RegPaConfig = (SX1276->RegPaConfig & RF_PACONFIG_PASELECT_MASK ) | outputPin;
SX1276Write( REG_PACONFIG, SX1276->RegPaConfig );
}
uint8_t SX1276FskGetPAOutput( void )
{
SX1276Read( REG_PACONFIG, &SX1276->RegPaConfig );
return SX1276->RegPaConfig & ~RF_PACONFIG_PASELECT_MASK;
}
void SX1276FskSetPaRamp( uint8_t value )
{
SX1276Read( REG_PARAMP, &SX1276->RegPaRamp );
SX1276->RegPaRamp = ( SX1276->RegPaRamp & RF_PARAMP_MASK ) | ( value & ~RF_PARAMP_MASK );
SX1276Write( REG_PARAMP, SX1276->RegPaRamp );
}
uint8_t SX1276FskGetPaRamp( void )
{
SX1276Read( REG_PARAMP, &SX1276->RegPaRamp );
return SX1276->RegPaRamp & ~RF_PARAMP_MASK;
}
void SX1276FskSetRssiOffset( int8_t offset )
{
SX1276Read( REG_RSSICONFIG, &SX1276->RegRssiConfig );
if( offset < 0 )
{
offset = ( ~offset & 0x1F );
offset += 1;
offset = -offset;
}
SX1276->RegRssiConfig |= ( uint8_t )( ( offset & 0x1F ) << 3 );
SX1276Write( REG_RSSICONFIG, SX1276->RegRssiConfig );
}
int8_t SX1276FskGetRssiOffset( void )
{
int8_t offset;
SX1276Read( REG_RSSICONFIG, &SX1276->RegRssiConfig );
offset = SX1276->RegRssiConfig >> 3;
if( ( offset & 0x10 ) == 0x10 )
{
offset = ( ~offset & 0x1F );
offset += 1;
offset = -offset;
}
return offset;
}
int8_t SX1276FskGetRawTemp( void )
{
int8_t temp = 0;
uint8_t previousOpMode;
uint32_t startTick;
// Enable Temperature reading
SX1276Read( REG_IMAGECAL, &SX1276->RegImageCal );
SX1276->RegImageCal = ( SX1276->RegImageCal & RF_IMAGECAL_TEMPMONITOR_MASK ) | RF_IMAGECAL_TEMPMONITOR_ON;
SX1276Write( REG_IMAGECAL, SX1276->RegImageCal );
// save current Op Mode
SX1276Read( REG_OPMODE, &SX1276->RegOpMode );
previousOpMode = SX1276->RegOpMode;
// put device in FSK RxSynth
SX1276->RegOpMode = RF_OPMODE_SYNTHESIZER_RX;
SX1276Write( REG_OPMODE, SX1276->RegOpMode );
// Wait 1ms
startTick = GET_TICK_COUNT( );
while( ( GET_TICK_COUNT( ) - startTick ) < TICK_RATE_MS( 1 ) );
// Disable Temperature reading
SX1276Read( REG_IMAGECAL, &SX1276->RegImageCal );
SX1276->RegImageCal = ( SX1276->RegImageCal & RF_IMAGECAL_TEMPMONITOR_MASK ) | RF_IMAGECAL_TEMPMONITOR_OFF;
SX1276Write( REG_IMAGECAL, SX1276->RegImageCal );
// Read temperature
SX1276Read( REG_TEMP, &SX1276->RegTemp );
temp = SX1276->RegTemp & 0x7F;
if( ( SX1276->RegTemp & 0x80 ) == 0x80 )
{
temp *= -1;
}
// Reload previous Op Mode
SX1276Write( REG_OPMODE, previousOpMode );
return temp;
}
int8_t SX1276FskCalibreateTemp( int8_t actualTemp )
{
return actualTemp - SX1276FskGetRawTemp( );
}
int8_t SX1276FskGetTemp( int8_t compensationFactor )
{
return SX1276FskGetRawTemp( ) + compensationFactor;
}
#endif // USE_SX1276_RADIO

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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file sx1276-FskMisc.h
* \brief SX1276 RF chip high level functions driver
*
* \remark Optional support functions.
* These functions are defined only to easy the change of the
* parameters.
* For a final firmware the radio parameters will be known so
* there is no need to support all possible parameters.
* Removing these functions will greatly reduce the final firmware
* size.
*
* \version 2.0.B2
* \date May 6 2013
* \author Gregory Cristian
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276-FskMisc.h
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#ifndef __SX1276_FSK_MISC_H__
#define __SX1276_FSK_MISC_H__
/*!
* \brief Writes the new RF frequency value
*
* \param [IN] freq New RF frequency value in [Hz]
*/
void SX1276FskSetRFFrequency( uint32_t freq );
/*!
* \brief Reads the current RF frequency value
*
* \retval freq Current RF frequency value in [Hz]
*/
uint32_t SX1276FskGetRFFrequency( void );
/*!
* \brief Calibrate RSSI and I/Q mismatch for HF
*
* \retval none
*/
void SX1276FskRxCalibrate( void );
/*!
* \brief Writes the new bitrate value
*
* \param [IN] bitrate New bitrate value in [bps]
*/
void SX1276FskSetBitrate( uint32_t bitrate );
/*!
* \brief Reads the current bitrate value
*
* \retval bitrate Current bitrate value in [bps]
*/
uint32_t SX1276FskGetBitrate( void );
/*!
* \brief Writes the new frequency deviation value
*
* \param [IN] fdev New frequency deviation value in [Hz]
*/
void SX1276FskSetFdev( uint32_t fdev );
/*!
* \brief Reads the current frequency deviation value
*
* \retval fdev Current frequency deviation value in [Hz]
*/
uint32_t SX1276FskGetFdev( void );
/*!
* \brief Writes the new RF output power value
*
* \param [IN] power New output power value in [dBm]
*/
void SX1276FskSetRFPower( int8_t power );
/*!
* \brief Reads the current RF output power value
*
* \retval power Current output power value in [dBm]
*/
int8_t SX1276FskGetRFPower( void );
/*!
* \brief Writes the DC offset canceller and Rx bandwidth values
*
* \remark For SX1276 there is no DCC setting. dccValue should be 0
* ie: SX1276SetDccBw( &SX1276.RegRxBw, 0, 62500 );
*
* \param [IN] reg Register pointer to either SX1231.RegRxBw or SX1231.RegAfcBw
* \param [IN] dccValue New DC offset canceller value in [Hz] ( SX1231 only )
* \param [IN] rxBwValue New Rx bandwidth value in [Hz]
*/
void SX1276FskSetDccBw( uint8_t* reg, uint32_t dccValue, uint32_t rxBwValue );
/*!
* \brief Reads the current bandwidth setting
*
* \param [IN] reg Register pointer to either SX1231.RegRxBw or SX1231.RegAfcBw
*
* \retval bandwidth Bandwidth value
*/
uint32_t SX1276FskGetBw( uint8_t* reg );
/*!
* \brief Enables/Disables CRC
*
* \param [IN] enable CRC enable/disable
*/
void SX1276FskSetPacketCrcOn( bool enable );
/*!
* \brief Reads the current CRC Enable/Disbale value
*
* \retval enable Current CRC Enable/Disbale value
*/
bool SX1276FskGetPacketCrcOn( void );
/*!
* \brief Enables/Disables AFC
*
* \param [IN] enable AFC enable/disable
*/
void SX1276FskSetAfcOn( bool enable );
/*!
* \brief Reads the current AFC Enable/Disbale value
*
* \retval enable Current AFC Enable/Disbale value
*/
bool SX1276FskGetAfcOn( void );
/*!
* \brief Writes the new payload length value
*
* \param [IN] value New payload length value
*/
void SX1276FskSetPayloadLength( uint8_t value );
/*!
* \brief Reads the current payload length value
*
* \retval value Current payload length value
*/
uint8_t SX1276FskGetPayloadLength( void );
/*!
* \brief Enables/Disables the 20 dBm PA
*
* \param [IN] enable [true, false]
*/
void SX1276FskSetPa20dBm( bool enale );
/*!
* \brief Gets the current 20 dBm PA status
*
* \retval enable [true, false]
*/
bool SX1276FskGetPa20dBm( void );
/*!
* \brief Set the RF Output pin
*
* \param [IN] RF_PACONFIG_PASELECT_PABOOST or RF_PACONFIG_PASELECT_RFO
*/
void SX1276FskSetPAOutput( uint8_t outputPin );
/*!
* \brief Gets the used RF Ouptu pin
*
* \retval RF_PACONFIG_PASELECT_PABOOST or RF_PACONFIG_PASELECT_RFO
*/
uint8_t SX1276FskGetPAOutput( void );
/*!
* \brief Writes the new PA rise/fall time of ramp up/down value
*
* \param [IN] value New PaRamp value
*/
void SX1276FskSetPaRamp( uint8_t value );
/*!
* \brief Reads the current PA rise/fall time of ramp up/down value
*
* \retval value Current PaRamp value
*/
uint8_t SX1276FskGetPaRamp( void );
/*!
* \brief Applies an offset to the RSSI. Compensates board components
*
* \param [IN] offset Offset to be applied (+/-)
*/
void SX1276FskSetRssiOffset( int8_t offset );
/*!
* \brief Gets the current RSSI offset.
*
* \retval offset Current offset (+/-)
*/
int8_t SX1276FskGetRssiOffset( void );
/*!
* \brief Writes the new value for the preamble size
*
* \param [IN] size New value of pramble size
*/
void SX1276FskSetPreambleSize( uint16_t size );
/*!
* Reads the raw temperature
* \retval temperature New raw temperature reading in 2's complement format
*/
int8_t SX1276FskGetRawTemp( void );
/*!
* Computes the temperature compensation factor
* \param [IN] actualTemp Actual temperature measured by an external device
* \retval compensationFactor Computed compensation factor
*/
int8_t SX1276FskCalibreateTemp( int8_t actualTemp );
/*!
* Gets the actual compensated temperature
* \param [IN] compensationFactor Return value of the calibration function
* \retval New compensated temperature value
*/
int8_t SX1276FskGetTemp( int8_t compensationFactor );
#endif //__SX1276_FSK_MISC_H__

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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file sx1276-Hal.h
* \brief SX1276 Hardware Abstraction Layer
*
* \version 2.0.B2
* \date Nov 21 2012
* \author Miguel Luis
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276-Hal.h
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#ifndef __SX1276_HAL_H__
#define __SX1276_HAL_H__
#include "platform.h"
/*!
* DIO state read functions mapping
*/
#define DIO0 SX1276ReadDio0( )
#define DIO1 SX1276ReadDio1( )
#define DIO2 SX1276ReadDio2( )
#define DIO3 SX1276ReadDio3( )
#define DIO4 SX1276ReadDio4( )
#define DIO5 SX1276ReadDio5( )
// RXTX pin control see errata note
#define RXTX( txEnable ) SX1276WriteRxTx( txEnable );
#define GET_TICK_COUNT( ) CurrentTicksGain()
#define TICK_RATE_MS( ms ) ( ms )
typedef enum
{
RADIO_RESET_OFF,
RADIO_RESET_ON,
}tRadioResetState;
/*!
* \brief Initializes the radio interface I/Os
*/
void SX1276InitIo( void );
/*!
* \brief Set the radio reset pin state
*
* \param state New reset pin state
*/
void SX1276SetReset( uint8_t state );
/*!
* \brief Writes the radio register at the specified address
*
* \param [IN]: addr Register address
* \param [IN]: data New register value
*/
void SX1276Write( uint8_t addr, uint8_t data );
/*!
* \brief Reads the radio register at the specified address
*
* \param [IN]: addr Register address
* \param [OUT]: data Register value
*/
void SX1276Read( uint8_t addr, uint8_t *data );
/*!
* \brief Writes multiple radio registers starting at address
*
* \param [IN] addr First Radio register address
* \param [IN] buffer Buffer containing the new register's values
* \param [IN] size Number of registers to be written
*/
void SX1276WriteBuffer( uint8_t addr, uint8_t *buffer, uint8_t size );
/*!
* \brief Reads multiple radio registers starting at address
*
* \param [IN] addr First Radio register address
* \param [OUT] buffer Buffer where to copy the registers data
* \param [IN] size Number of registers to be read
*/
void SX1276ReadBuffer( uint8_t addr, uint8_t *buffer, uint8_t size );
/*!
* \brief Writes the buffer contents to the radio FIFO
*
* \param [IN] buffer Buffer containing data to be put on the FIFO.
* \param [IN] size Number of bytes to be written to the FIFO
*/
void SX1276WriteFifo( uint8_t *buffer, uint8_t size );
/*!
* \brief Reads the contents of the radio FIFO
*
* \param [OUT] buffer Buffer where to copy the FIFO read data.
* \param [IN] size Number of bytes to be read from the FIFO
*/
void SX1276ReadFifo( uint8_t *buffer, uint8_t size );
/*!
* \brief Gets the SX1276 DIO0 hardware pin status
*
* \retval status Current hardware pin status [1, 0]
*/
inline uint8_t SX1276ReadDio0( void );
/*!
* \brief Ge// USE_SX1276_RADIOts the SX1276 DIO1 hardware pin status
*
* \retval status Current hardware pin status [1, 0]
*/
inline uint8_t SX1276ReadDio1( void );
/*!
* \brief Gets the SX1276 DIO2 hardware pin status
*
* \retval status Current hardware pin status [1, 0]
*/
inline uint8_t SX1276ReadDio2( void );
/*!
* \brief Gets the SX1276 DIO3 hardware pin status
*
* \retval status Current hardware pin status [1, 0]
*/
inline uint8_t SX1276ReadDio3( void );
/*!
* \brief Gets the SX1276 DIO4 hardware pin status
*
* \retval status Current hardware pin status [1, 0]
*/
inline uint8_t SX1276ReadDio4( void );
/*!
* \brief Gets the SX1276 DIO5 hardware pin status
*
* \retval status Current hardware pin status [1, 0]
*/
inline uint8_t SX1276ReadDio5( void );
/*!
* \brief Writes the external RxTx pin value
*
* \remark see errata note
*
* \param [IN] txEnable [1: Tx, 0: Rx]
*/
inline void SX1276WriteRxTx( uint8_t txEnable );
#endif //__SX1276_HAL_H__

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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Original Copyright (C) SEMTECH S.A.
* Modified Copyright (C) 2020 AIIT XUOS Lab
*/
/*!
* \file sx1276-LoRa.c
* \brief SX1276 RF chip driver mode LoRa
*
* \version 2.0.0
* \date Nov 21 2012
* \author Miguel Luis
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276-LoRa.c
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#include <string.h>
#include "platform.h"
#if defined( USE_SX1276_RADIO )
#include "radio.h"
#include "sx1276-Hal.h"
#include "sx1276.h"
#include "sx1276-LoRaMisc.h"
#include "sx1276-LoRa.h"
#define LoRa_FREQENCY 433000000
#define RSSI_OFFSET_LF -155.0
#define RSSI_OFFSET_HF -150.0
#define NOISE_ABSOLUTE_ZERO -174.0
#define NOISE_FIGURE_LF 4.0
#define NOISE_FIGURE_HF 6.0
volatile uint32 TickCounter = 0;
uint32 Tx_Time_Start,Tx_Time_End;
uint32 Rx_Time_Start,Rx_Time_End;
//Signal bandwidth, used to calculate RSSI
const double SignalBwLog[] =
{
3.8927900303521316335038277369285, // 7.8 kHz
4.0177301567005500940384239336392, // 10.4 kHz
4.193820026016112828717566631653, // 15.6 kHz
4.31875866931372901183597627752391, // 20.8 kHz
4.4948500216800940239313055263775, // 31.2 kHz
4.6197891057238405255051280399961, // 41.6 kHz
4.795880017344075219145044421102, // 62.5 kHz
5.0969100130080564143587833158265, // 125 kHz
5.397940008672037609572522210551, // 250 kHz
5.6989700043360188047862611052755 // 500 kHz
};
//These values need testing
const double RssiOffsetLF[] =
{
-155.0,
-155.0,
-155.0,
-155.0,
-155.0,
-155.0,
-155.0,
-155.0,
-155.0,
-155.0,
};
//These values need testing
const double RssiOffsetHF[] =
{
-150.0,
-150.0,
-150.0,
-150.0,
-150.0,
-150.0,
-150.0,
-150.0,
-150.0,
-150.0,
};
/*!
* Frequency hopping frequencies table
*/
const int32_t HoppingFrequencies[] =
{
916500000,
923500000,
906500000,
917500000,
917500000,
909000000,
903000000,
916000000,
912500000,
926000000,
925000000,
909500000,
913000000,
918500000,
918500000,
902500000,
911500000,
926500000,
902500000,
922000000,
924000000,
903500000,
913000000,
922000000,
926000000,
910000000,
920000000,
922500000,
911000000,
922000000,
909500000,
926000000,
922000000,
918000000,
925500000,
908000000,
917500000,
926500000,
908500000,
916000000,
905500000,
916000000,
903000000,
905000000,
915000000,
913000000,
907000000,
910000000,
926500000,
925500000,
911000000,
};
// Default settings
tLoRaSettings LoRaSettings =
{
LoRa_FREQENCY , // RFFrequency
20, // Power
9, // SignalBw [0: 125 kHz, 1: 250 kHz, 2: 500 kHz, 3: Reserved]
12, // SpreadingFactor [6: 64, 7: 128, 8: 256, 9: 512, 10: 1024, 11: 2048, 12: 4096 chips]
2, // ErrorCoding [1: 4/5, 2: 4/6, 3: 4/7, 4: 4/8]
true, // CrcOn [0: OFF, 1: ON]
false, // ImplicitHeaderOn [0: OFF, 1: ON]
0, // RxSingleOn [0: Continuous, 1 Single]
0, // FreqHopOn [0: OFF, 1: ON]
4, // HopPeriod Hops every frequency hopping period symbols
1000, // TxPacketTimeout
1000, // RxPacketTimeout
128, // PayloadLength (used for implicit header mode)
};
/*!
* SX1276 LoRa registers variable
*/
tSX1276LR* SX1276LR;
/*!
* Local RF buffer for communication support
*/
static uint8_t RFBuffer[RF_BUFFER_SIZE];
static uint8_t TFBuffer[RF_BUFFER_SIZE];
/*!
* RF state machine variable
*/
static uint8_t RFLRState = RFLR_STATE_IDLE;
/*!
* Rx management support variables
*/
static uint16_t RxPacketSize = 0;
static int8_t RxPacketSnrEstimate;
static double RxPacketRssiValue;
static uint8_t RxGain = 1;
static uint32_t RxTimeoutTimer = 0;
/*!
* PacketTimeout Stores the Rx window time value for packet reception
*/
static uint32_t PacketTimeout;
/*!
* Tx management support variables
*/
static uint16_t TxPacketSize = 0;
void SX1276LoRaInit( void )
{
RFLRState = RFLR_STATE_IDLE;
SX1276LoRaSetDefaults();
SX1276ReadBuffer( REG_LR_OPMODE, SX1276Regs + 1, 0x70 - 1 );
//SX1276LoRaSetOpMode( RFLR_OPMODE_SLEEP );
SX1276LR->RegLna = RFLR_LNA_GAIN_G1;
SX1276WriteBuffer( REG_LR_OPMODE, SX1276Regs + 1, 0x70 - 1 );
// set the RF settings
SX1276LoRaSetRFFrequency( LoRaSettings.RFFrequency );
SX1276LoRaSetSpreadingFactor( LoRaSettings.SpreadingFactor );
SX1276LoRaSetErrorCoding( LoRaSettings.ErrorCoding );
SX1276LoRaSetPacketCrcOn( LoRaSettings.CrcOn );
SX1276LoRaSetSignalBandwidth( LoRaSettings.SignalBw );
SX1276LoRaSetImplicitHeaderOn( LoRaSettings.ImplicitHeaderOn );
SX1276LoRaSetSymbTimeout(0x3FF);
SX1276LoRaSetPayloadLength( LoRaSettings.PayloadLength );
SX1276LoRaSetLowDatarateOptimize( true );
#if( ( MODULE_SX1276RF1IAS == 1 ) || ( MODULE_SX1276RF1KAS == 1 ) )
if( LoRaSettings.RFFrequency > 860000000 )
{
SX1276LoRaSetPAOutput( RFLR_PACONFIG_PASELECT_RFO );
SX1276LoRaSetPa20dBm( false );
LoRaSettings.Power = 14;
SX1276LoRaSetRFPower( LoRaSettings.Power );
}
else
{
//SX1276Write( REG_LR_OCP, 0x3f );
SX1276LoRaSetPAOutput( RFLR_PACONFIG_PASELECT_PABOOST );
SX1276LoRaSetPa20dBm( true );
LoRaSettings.Power = 20;
SX1276LoRaSetRFPower( LoRaSettings.Power );
}
#elif( MODULE_SX1276RF1JAS == 1 )
if( LoRaSettings.RFFrequency > 380000000 )
{
SX1276LoRaSetPAOutput( RFLR_PACONFIG_PASELECT_PABOOST );
SX1276LoRaSetPa20dBm( true );
LoRaSettings.Power = 20;
SX1276LoRaSetRFPower( LoRaSettings.Power );
}
else
{
SX1276LoRaSetPAOutput( RFLR_PACONFIG_PASELECT_RFO );
SX1276LoRaSetPa20dBm( false );
LoRaSettings.Power = 14;
SX1276LoRaSetRFPower( LoRaSettings.Power );
}
#endif
SX1276LoRaSetOpMode( RFLR_OPMODE_STANDBY );
SX1276ReadBuffer( REG_LR_OPMODE, SX1276Regs + 1, 0x70 - 1 );
}
void SX1276LoRaSetDefaults( void )
{
// REMARK: See SX1276 datasheet for modified default values.
// Sets IF frequency selection manual
SX1276Read( REG_LR_VERSION, &SX1276LR->RegVersion );
}
void SX1276LoRaReset( void )
{
uint32_t startTick;
SX1276SetReset( RADIO_RESET_ON );
// Wait 1ms
startTick = GET_TICK_COUNT( );
while( ( GET_TICK_COUNT( ) - startTick ) < TICK_RATE_MS( 1 ) );
SX1276SetReset( RADIO_RESET_OFF );
// Wait 6ms
startTick = GET_TICK_COUNT( );
while( ( GET_TICK_COUNT( ) - startTick ) < TICK_RATE_MS( 6 ) );
}
void SX1276LoRaSetOpMode( uint8_t opMode )
{
static uint8_t opModePrev = RFLR_OPMODE_STANDBY;
static bool antennaSwitchTxOnPrev = true;
bool antennaSwitchTxOn = false;
opModePrev = SX1276LR->RegOpMode & ~RFLR_OPMODE_MASK;
if( opMode != opModePrev )
{
if( opMode == RFLR_OPMODE_TRANSMITTER )
{
antennaSwitchTxOn = true;
}
else
{
antennaSwitchTxOn = false;
}
if( antennaSwitchTxOn != antennaSwitchTxOnPrev )
{
antennaSwitchTxOnPrev = antennaSwitchTxOn; // Antenna switch control
RXTX( antennaSwitchTxOn );
}
SX1276LR->RegOpMode = ( SX1276LR->RegOpMode & RFLR_OPMODE_MASK ) | opMode | RFLR_OPMODE_FREQMODE_ACCESS_LF;
SX1276Write( REG_LR_OPMODE, SX1276LR->RegOpMode );
}
}
uint8_t SX1276LoRaGetOpMode( void )
{
SX1276Read( REG_LR_OPMODE, &SX1276LR->RegOpMode );
return SX1276LR->RegOpMode & ~RFLR_OPMODE_MASK;
}
uint8_t SX1276LoRaReadRxGain( void )
{
SX1276Read( REG_LR_LNA, &SX1276LR->RegLna );
return( SX1276LR->RegLna >> 5 ) & 0x07;
}
double SX1276LoRaReadRssi( void )
{
// Reads the RSSI value
SX1276Read( REG_LR_RSSIVALUE, &SX1276LR->RegRssiValue );
if( LoRaSettings.RFFrequency < 860000000 )
{
return RssiOffsetLF[LoRaSettings.SignalBw] + ( double )SX1276LR->RegRssiValue;
}
else
{
return RssiOffsetHF[LoRaSettings.SignalBw] + ( double )SX1276LR->RegRssiValue;
}
}
uint8_t SX1276LoRaGetPacketRxGain( void )
{
return RxGain;
}
int8_t SX1276LoRaGetPacketSnr( void )
{
return RxPacketSnrEstimate;
}
double SX1276LoRaGetPacketRssi( void )
{
return RxPacketRssiValue;
}
void SX1276LoRaStartRx( void )
{
SX1276LoRaSetRFState( RFLR_STATE_RX_INIT );
}
void SX1276LoRaGetRxPacket( void *buffer, uint16_t *size )
{
*size = RxPacketSize;
RxPacketSize = 0;
memcpy( (void*)buffer, (void*)RFBuffer, (size_t)*size );
}
void SX1276LoRaSetTxPacket( const void *buffer, uint16_t size )
{
if( LoRaSettings.FreqHopOn == false )
{
TxPacketSize = size;
}
else
{
TxPacketSize = 255;
}
memcpy( ( void * )TFBuffer, buffer, ( size_t )TxPacketSize );
RFLRState = RFLR_STATE_TX_INIT;
}
uint8_t SX1276LoRaGetRFState( void )
{
return RFLRState;
}
void SX1276LoRaSetRFState( uint8_t state )
{
RFLRState = state;
}
/*!
* \brief Process the LoRa modem Rx and Tx state machines depending on the
* SX1276 operating mode.
*
* \retval rfState Current RF state [RF_IDLE, RF_BUSY,
* RF_RX_DONE, RF_RX_TIMEOUT,
* RF_TX_DONE, RF_TX_TIMEOUT]
*/
uint32_t SX1276LoRaProcess( void )
{
uint32_t result = RF_BUSY;
uint8_t regValue = 0;
switch( RFLRState )
{
case RFLR_STATE_IDLE:
break;
case RFLR_STATE_RX_INIT:
SX1276LoRaSetOpMode(RFLR_OPMODE_STANDBY);
SX1276LR->RegIrqFlagsMask = RFLR_IRQFLAGS_RXTIMEOUT |
//RFLR_IRQFLAGS_RXDONE |
RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
RFLR_IRQFLAGS_TXDONE |
RFLR_IRQFLAGS_CADDONE |
RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL |
RFLR_IRQFLAGS_CADDETECTED;
SX1276Write( REG_LR_IRQFLAGSMASK, SX1276LR->RegIrqFlagsMask );
if(LoRaSettings.FreqHopOn == true )
{
SX1276LR->RegHopPeriod = LoRaSettings.HopPeriod;
SX1276Read( REG_LR_HOPCHANNEL, &SX1276LR->RegHopChannel );
SX1276LoRaSetRFFrequency( HoppingFrequencies[SX1276LR->RegHopChannel & RFLR_HOPCHANNEL_CHANNEL_MASK] );
}
else
{
SX1276LR->RegHopPeriod = 255;
}
SX1276Write( REG_LR_HOPPERIOD, SX1276LR->RegHopPeriod );
if( LoRaSettings.RxSingleOn == true ) // Rx single mode
{
SX1276LoRaSetOpMode( RFLR_OPMODE_RECEIVER_SINGLE );
}
else // Rx continuous mode
{
SX1276LR->RegFifoAddrPtr = SX1276LR->RegFifoRxBaseAddr;
SX1276Write( REG_LR_FIFOADDRPTR, SX1276LR->RegFifoAddrPtr );
SX1276LoRaSetOpMode( RFLR_OPMODE_RECEIVER );
}
memset( RFBuffer, 0, ( size_t )RF_BUFFER_SIZE );
Rx_Time_Start=TickCounter;
PacketTimeout = LoRaSettings.RxPacketTimeout;
RxTimeoutTimer = GET_TICK_COUNT( );
RFLRState = RFLR_STATE_RX_RUNNING;
break;
case RFLR_STATE_RX_RUNNING:
SX1276Read(0x12, &regValue);
// RxDone
if(regValue & (1<<6))
{
RxTimeoutTimer = GET_TICK_COUNT( );
if( LoRaSettings.FreqHopOn == true )
{
SX1276Read( REG_LR_HOPCHANNEL, &SX1276LR->RegHopChannel );
SX1276LoRaSetRFFrequency( HoppingFrequencies[SX1276LR->RegHopChannel & RFLR_HOPCHANNEL_CHANNEL_MASK] );
}
// Clear Irq
SX1276Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_RXDONE );
RFLRState = RFLR_STATE_RX_DONE;
}
// FHSS Changed Channel
if(regValue & (1<<1))
{
RxTimeoutTimer = GET_TICK_COUNT( );
if( LoRaSettings.FreqHopOn == true )
{
SX1276Read( REG_LR_HOPCHANNEL, &SX1276LR->RegHopChannel );
SX1276LoRaSetRFFrequency( HoppingFrequencies[SX1276LR->RegHopChannel & RFLR_HOPCHANNEL_CHANNEL_MASK] );
}
// Clear Irq
SX1276Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL );
//RxGain = SX1276LoRaReadRxGain( );
}
if( LoRaSettings.RxSingleOn == true ) // Rx single mode
{
if( ( GET_TICK_COUNT( ) - RxTimeoutTimer ) > PacketTimeout )
{
RFLRState = RFLR_STATE_RX_TIMEOUT;
}
}
break;
case RFLR_STATE_RX_DONE:
SX1276Read( REG_LR_IRQFLAGS, &SX1276LR->RegIrqFlags );
if( ( SX1276LR->RegIrqFlags & RFLR_IRQFLAGS_PAYLOADCRCERROR ) == RFLR_IRQFLAGS_PAYLOADCRCERROR )
{
// Clear Irq
SX1276Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_PAYLOADCRCERROR );
if( LoRaSettings.RxSingleOn == true ) // Rx single mode
{
RFLRState = RFLR_STATE_RX_INIT;
}
else
{
RFLRState = RFLR_STATE_RX_RUNNING;
}
break;
}
if( LoRaSettings.RxSingleOn == true ) // Rx single mode
{
SX1276LR->RegFifoAddrPtr = SX1276LR->RegFifoRxBaseAddr;
SX1276Write( REG_LR_FIFOADDRPTR, SX1276LR->RegFifoAddrPtr );
if( LoRaSettings.ImplicitHeaderOn == true )
{
RxPacketSize = SX1276LR->RegPayloadLength;
SX1276ReadFifo( RFBuffer, SX1276LR->RegPayloadLength );
}
else
{
SX1276Read( REG_LR_NBRXBYTES, &SX1276LR->RegNbRxBytes );
RxPacketSize = SX1276LR->RegNbRxBytes;
SX1276ReadFifo( RFBuffer, SX1276LR->RegNbRxBytes );
}
}
else // Rx continuous mode
{
SX1276Read( REG_LR_FIFORXCURRENTADDR, &SX1276LR->RegFifoRxCurrentAddr );
if( LoRaSettings.ImplicitHeaderOn == true )
{
RxPacketSize = SX1276LR->RegPayloadLength;
SX1276LR->RegFifoAddrPtr = SX1276LR->RegFifoRxCurrentAddr;
SX1276Write( REG_LR_FIFOADDRPTR, SX1276LR->RegFifoAddrPtr );
SX1276ReadFifo( RFBuffer, SX1276LR->RegPayloadLength );
}
else
{
SX1276Read( REG_LR_NBRXBYTES, &SX1276LR->RegNbRxBytes );
RxPacketSize = SX1276LR->RegNbRxBytes;
SX1276LR->RegFifoAddrPtr = SX1276LR->RegFifoRxCurrentAddr;
SX1276Write( REG_LR_FIFOADDRPTR, SX1276LR->RegFifoAddrPtr );
SX1276ReadFifo( RFBuffer, SX1276LR->RegNbRxBytes );
}
}
if( LoRaSettings.RxSingleOn == true ) // Rx single mode
{
RFLRState = RFLR_STATE_RX_INIT;
}
else // Rx continuous mode
{
RFLRState = RFLR_STATE_RX_RUNNING;
}
Rx_Time_End=TickCounter;
result = RF_RX_DONE;
break;
case RFLR_STATE_RX_TIMEOUT:
RFLRState = RFLR_STATE_RX_INIT;
result = RF_RX_TIMEOUT;
break;
case RFLR_STATE_TX_INIT:
Tx_Time_Start = TickCounter;
// Initializes the payload size
SX1276LR->RegPayloadLength = TxPacketSize;
SX1276Write( REG_LR_PAYLOADLENGTH, SX1276LR->RegPayloadLength );
SX1276LR->RegFifoTxBaseAddr = 0x00; // Full buffer used for Tx
SX1276Write( REG_LR_FIFOTXBASEADDR, SX1276LR->RegFifoTxBaseAddr );
SX1276LR->RegFifoAddrPtr = SX1276LR->RegFifoTxBaseAddr;
SX1276Write( REG_LR_FIFOADDRPTR, SX1276LR->RegFifoAddrPtr );
SX1276LoRaSetOpMode( RFLR_OPMODE_STANDBY );
// Write payload buffer to LORA modem
SX1276WriteFifo( TFBuffer, SX1276LR->RegPayloadLength );
if( LoRaSettings.FreqHopOn == true )
{
SX1276LR->RegIrqFlagsMask = RFLR_IRQFLAGS_RXTIMEOUT |
RFLR_IRQFLAGS_RXDONE |
RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
//RFLR_IRQFLAGS_TXDONE |
RFLR_IRQFLAGS_CADDONE |
RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL |
RFLR_IRQFLAGS_CADDETECTED;
SX1276LR->RegHopPeriod = LoRaSettings.HopPeriod;
SX1276Read( REG_LR_HOPCHANNEL, &SX1276LR->RegHopChannel );
SX1276LoRaSetRFFrequency( HoppingFrequencies[SX1276LR->RegHopChannel & RFLR_HOPCHANNEL_CHANNEL_MASK] );
}
else
{
SX1276LR->RegIrqFlagsMask = RFLR_IRQFLAGS_RXTIMEOUT |
RFLR_IRQFLAGS_RXDONE |
RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
//RFLR_IRQFLAGS_TXDONE |
RFLR_IRQFLAGS_CADDONE |
RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL |
RFLR_IRQFLAGS_CADDETECTED;
SX1276LR->RegHopPeriod = 0;
}
SX1276Write( REG_LR_HOPPERIOD, SX1276LR->RegHopPeriod );
SX1276Write( REG_LR_IRQFLAGSMASK, SX1276LR->RegIrqFlagsMask );
SX1276Write( REG_LR_DIOMAPPING1, ( regValue & RFLR_DIOMAPPING1_DIO0_MASK ) | RFLR_DIOMAPPING1_DIO0_01 );//DIO0设置为TXdone中断
SX1276LoRaSetOpMode( RFLR_OPMODE_TRANSMITTER );
RFLRState = RFLR_STATE_TX_RUNNING;
break;
case RFLR_STATE_TX_RUNNING:
SX1276Read(0x12, &regValue);
if(regValue & (1<<3))
{
// Clear Irq
SX1276Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_TXDONE );
RFLRState = RFLR_STATE_TX_DONE;
}
// FHSS Changed Channel
if(regValue & (1<<3))
{
if( LoRaSettings.FreqHopOn == true )
{
SX1276Read( REG_LR_HOPCHANNEL, &SX1276LR->RegHopChannel );
SX1276LoRaSetRFFrequency( HoppingFrequencies[SX1276LR->RegHopChannel & RFLR_HOPCHANNEL_CHANNEL_MASK] );
}
// Clear Irq
SX1276Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL );
}
break;
case RFLR_STATE_TX_DONE:
Tx_Time_End=TickCounter;
SX1276LoRaSetOpMode( RFLR_OPMODE_STANDBY );
RFLRState = RFLR_STATE_IDLE;
result = RF_TX_DONE;
break;
case RFLR_STATE_CAD_INIT:
// optimize the power consumption by switching off the transmitter as soon as the packet has been sent
SX1276LoRaSetOpMode( RFLR_OPMODE_STANDBY );
SX1276LR->RegIrqFlagsMask = RFLR_IRQFLAGS_RXTIMEOUT |
RFLR_IRQFLAGS_RXDONE |
RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
RFLR_IRQFLAGS_TXDONE |
//RFLR_IRQFLAGS_CADDONE |
RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL;
//RFLR_IRQFLAGS_CADDETECTED;
SX1276Write( REG_LR_IRQFLAGSMASK, SX1276LR->RegIrqFlagsMask );
SX1276LoRaSetOpMode( RFLR_OPMODE_CAD );
RFLRState = RFLR_STATE_CAD_RUNNING;
break;
case RFLR_STATE_CAD_RUNNING:
SX1276Read(0x12,&regValue);
int cad_done = regValue & (1<<2);
int cad_detected = regValue & (1<<0);
if( cad_done ) //CAD Done interrupt
{
SX1276Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_CADDONE );
if( cad_detected ) // CAD Detected interrupt
{
SX1276Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_CADDETECTED );
//CAD detected, we have a LoRa preamble
RFLRState = RFLR_STATE_RX_INIT;
result = RF_CHANNEL_ACTIVITY_DETECTED;
}
else
{
// The device goes in Standby Mode automatically
RFLRState = RFLR_STATE_IDLE;
result = RF_CHANNEL_EMPTY;
}
}
break;
default:
break;
}
return result;
}
uint32_t SX1276LoraChannelEmpty( void )
{
uint32_t result = 0;
RFLRState = RFLR_STATE_CAD_INIT;
SX1276LoRaProcess();
while(RFLRState == RFLR_STATE_CAD_RUNNING)
{
//KPrintf("\nLora--SX1276LoRaProcess()");
result = SX1276LoRaProcess();
}
if(result == RF_CHANNEL_EMPTY)
{
KPrintf("\nLora--RF_CHANNEL_EMPTY\n");
return 0;
}
else if(result == RF_CHANNEL_ACTIVITY_DETECTED)
{
KPrintf("\nLora--RF_CHANNEL_ACTIVITY_DETECTED\n");
return 1;
}
else
{
return 2;
}
}
#endif // USE_SX1276_RADIO

820
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/spi/third_party_spi_lora/sx12xx/src/radio/sx1276-LoRa.h Normal file
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@ -0,0 +1,820 @@
/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Original Copyright (C) SEMTECH S.A.
* Modified Copyright (C) 2020 AIIT XUOS Lab
*/
/*!
* \file sx1276-LoRa.h
* \brief SX1276 RF chip driver mode LoRa
*
* \version 2.0.0
* \date Nov 21 2012
* \author Miguel Luis
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276-LoRa.h
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#ifndef __SX1276_LORA_H__
#define __SX1276_LORA_H__
#include "stdint.h"
#include "stdbool.h"
//SX1276一些配置参数设置
typedef struct sLoRaSettings
{
uint32_t RFFrequency; //无线通信频率
int8_t Power; //功率
uint8_t SignalBw; //LORA 带宽[0: 7.8 kHz, 1: 10.4 kHz, 2: 15.6 kHz, 3: 20.8 kHz, 4: 31.2 kHz,
//5: 41.6 kHz, 6: 62.5 kHz, 7: 125 kHz, 8: 250 kHz, 9: 500 kHz, other: Reserved]
uint8_t SpreadingFactor; //扩频因子 LORA [6: 64, 7: 128, 8: 256, 9: 512, 10: 1024, 11: 2048, 12: 4096 chips]
uint8_t ErrorCoding; //LORA 纠错码 [1: 4/5, 2: 4/6, 3: 4/7, 4: 4/8]
bool CrcOn; //CRC效验开关 [0: OFF, 1: ON]
bool ImplicitHeaderOn; //隐藏头部信息开关 [0: OFF, 1: ON]
bool RxSingleOn; //接收单次模式\连续模式配置[0: Continuous, 1 Single]
bool FreqHopOn; //跳频模式开关 [0: OFF, 1: ON]
uint8_t HopPeriod; //跳频之间的周期长度 Hops every frequency hopping period symbols
uint32_t TxPacketTimeout; //最大发送时间
uint32_t RxPacketTimeout; //最大接收时间
uint8_t PayloadLength; //数据长度
}tLoRaSettings;
//RF数据包大小(模块配备了256Byte的RAM缓存该缓存仅能通过LoRa模式访问)
#define RF_BUFFER_SIZE_MAX 256
#define RF_BUFFER_SIZE 256
//LoRa的返回值
typedef enum
{
RFLR_STATE_IDLE,
RFLR_STATE_RX_INIT,
RFLR_STATE_RX_RUNNING,
RFLR_STATE_RX_DONE,
RFLR_STATE_RX_TIMEOUT,
RFLR_STATE_TX_INIT,
RFLR_STATE_TX_RUNNING,
RFLR_STATE_TX_DONE,
RFLR_STATE_TX_TIMEOUT,
RFLR_STATE_CAD_INIT,
RFLR_STATE_CAD_RUNNING,
}tRFLRStates;
//SX1276 definitions
#define XTAL_FREQ 32000000
#define FREQ_STEP 61.03515625
/*LoRa模式寄存器映射*/
//SX1276内部寄存器地址
#define REG_LR_FIFO 0x00 //FIFO 数据输入/输出。当器件处于睡眠模式时FIFO被清零无法访问。
//通用寄存器
#define REG_LR_OPMODE 0x01 //关于模式选择相关的寄存器
#define REG_LR_BANDSETTING 0x04
#define REG_LR_FRFMSB 0x06 //RF 载波频率最高有效位
#define REG_LR_FRFMID 0x07 //RF 载波频率中间有效位
#define REG_LR_FRFLSB 0x08 //RF 载波频率最低有效位
//RF模块寄存器
#define REG_LR_PACONFIG 0x09
#define REG_LR_PARAMP 0x0A
#define REG_LR_OCP 0x0B
#define REG_LR_LNA 0x0C
//LoRa页面寄存器
#define REG_LR_FIFOADDRPTR 0x0D
#define REG_LR_FIFOTXBASEADDR 0x0E
#define REG_LR_FIFORXBASEADDR 0x0F
#define REG_LR_FIFORXCURRENTADDR 0x10
#define REG_LR_IRQFLAGSMASK 0x11 //IAQ标志屏蔽
#define REG_LR_IRQFLAGS 0x12
#define REG_LR_NBRXBYTES 0x13
#define REG_LR_RXHEADERCNTVALUEMSB 0x14
#define REG_LR_RXHEADERCNTVALUELSB 0x15
#define REG_LR_RXPACKETCNTVALUEMSB 0x16
#define REG_LR_RXPACKETCNTVALUELSB 0x17
#define REG_LR_MODEMSTAT 0x18
#define REG_LR_PKTSNRVALUE 0x19
#define REG_LR_PKTRSSIVALUE 0x1A
#define REG_LR_RSSIVALUE 0x1B
#define REG_LR_HOPCHANNEL 0x1C
#define REG_LR_MODEMCONFIG1 0x1D
#define REG_LR_MODEMCONFIG2 0x1E
#define REG_LR_SYMBTIMEOUTLSB 0x1F
#define REG_LR_PREAMBLEMSB 0x20
#define REG_LR_PREAMBLELSB 0x21
#define REG_LR_PAYLOADLENGTH 0x22
#define REG_LR_PAYLOADMAXLENGTH 0x23
#define REG_LR_HOPPERIOD 0x24
#define REG_LR_FIFORXBYTEADDR 0x25
#define REG_LR_MODEMCONFIG3 0x26
/*以上是LoRa模式寄存器映射*/
//IO控制寄存器关于DI00-DI05的映射设置
#define REG_LR_DIOMAPPING1 0x40
#define REG_LR_DIOMAPPING2 0x41
//版本寄存器
#define REG_LR_VERSION 0x42
//附加寄存器
#define REG_LR_PLLHOP 0x44
#define REG_LR_TCXO 0x4B
#define REG_LR_PADAC 0x4D
#define REG_LR_FORMERTEMP 0x5B
#define REG_LR_BITRATEFRAC 0x5D
#define REG_LR_AGCREF 0x61
#define REG_LR_AGCTHRESH1 0x62
#define REG_LR_AGCTHRESH2 0x63
#define REG_LR_AGCTHRESH3 0x64
//与模式选择相关的宏定义 RegOpMode(寄存器地址0X01)
#define RFLR_OPMODE_LONGRANGEMODE_MASK 0x7F
#define RFLR_OPMODE_LONGRANGEMODE_OFF 0x00 // Default
#define RFLR_OPMODE_LONGRANGEMODE_ON 0x80
#define RFLR_OPMODE_ACCESSSHAREDREG_MASK 0xBF
#define RFLR_OPMODE_ACCESSSHAREDREG_ENABLE 0x40
#define RFLR_OPMODE_ACCESSSHAREDREG_DISABLE 0x00 // Default
#define RFLR_OPMODE_FREQMODE_ACCESS_MASK 0xF7
#define RFLR_OPMODE_FREQMODE_ACCESS_LF 0x08 // Default
#define RFLR_OPMODE_FREQMODE_ACCESS_HF 0x00
#define RFLR_OPMODE_MASK 0xF8
#define RFLR_OPMODE_SLEEP 0x00 //睡眠模式
#define RFLR_OPMODE_STANDBY 0x01 //待机模式
#define RFLR_OPMODE_SYNTHESIZER_TX 0x02 //频率合成器转换至Tx频率
#define RFLR_OPMODE_TRANSMITTER 0x03 //发送模式
#define RFLR_OPMODE_SYNTHESIZER_RX 0x04 //频率合成器转换至Rx频率
#define RFLR_OPMODE_RECEIVER 0x05 //接收模式
#define RFLR_OPMODE_RECEIVER_SINGLE 0x06 //单次接收模式
#define RFLR_OPMODE_CAD 0x07 //CAD模式
//与位带操作相关的宏定义
#define RFLR_BANDSETTING_MASK 0x3F
#define RFLR_BANDSETTING_AUTO 0x00 // Default
#define RFLR_BANDSETTING_DIV_BY_1 0x40
#define RFLR_BANDSETTING_DIV_BY_2 0x80
#define RFLR_BANDSETTING_DIV_BY_6 0xC0
//射频载波频率设置相关宏定义 RegFrf (MHz)(寄存器地址0x060x07,0x08)
#define RFLR_FRFMSB_434_MHZ 0x6C // Default
#define RFLR_FRFMID_434_MHZ 0x80 // Default
#define RFLR_FRFLSB_434_MHZ 0x00 // Default
#define RFLR_FRFMSB_470_MHZ 0x73 // Default
#define RFLR_FRFMID_470_MHZ 0xBB // Default
#define RFLR_FRFLSB_470_MHZ 0xBB // Default
#define RFLR_FRFMSB_863_MHZ 0xD7
#define RFLR_FRFMID_863_MHZ 0xC0
#define RFLR_FRFLSB_863_MHZ 0x00
#define RFLR_FRFMSB_864_MHZ 0xD8
#define RFLR_FRFMID_864_MHZ 0x00
#define RFLR_FRFLSB_864_MHZ 0x00
#define RFLR_FRFMSB_865_MHZ 0xD8
#define RFLR_FRFMID_865_MHZ 0x40
#define RFLR_FRFLSB_865_MHZ 0x00
#define RFLR_FRFMSB_866_MHZ 0xD8
#define RFLR_FRFMID_866_MHZ 0x80
#define RFLR_FRFLSB_866_MHZ 0x00
#define RFLR_FRFMSB_867_MHZ 0xD8
#define RFLR_FRFMID_867_MHZ 0xC0
#define RFLR_FRFLSB_867_MHZ 0x00
#define RFLR_FRFMSB_868_MHZ 0xD9
#define RFLR_FRFMID_868_MHZ 0x00
#define RFLR_FRFLSB_868_MHZ 0x00
#define RFLR_FRFMSB_869_MHZ 0xD9
#define RFLR_FRFMID_869_MHZ 0x40
#define RFLR_FRFLSB_869_MHZ 0x00
#define RFLR_FRFMSB_870_MHZ 0xD9
#define RFLR_FRFMID_870_MHZ 0x80
#define RFLR_FRFLSB_870_MHZ 0x00
#define RFLR_FRFMSB_902_MHZ 0xE1
#define RFLR_FRFMID_902_MHZ 0x80
#define RFLR_FRFLSB_902_MHZ 0x00
#define RFLR_FRFMSB_903_MHZ 0xE1
#define RFLR_FRFMID_903_MHZ 0xC0
#define RFLR_FRFLSB_903_MHZ 0x00
#define RFLR_FRFMSB_904_MHZ 0xE2
#define RFLR_FRFMID_904_MHZ 0x00
#define RFLR_FRFLSB_904_MHZ 0x00
#define RFLR_FRFMSB_905_MHZ 0xE2
#define RFLR_FRFMID_905_MHZ 0x40
#define RFLR_FRFLSB_905_MHZ 0x00
#define RFLR_FRFMSB_906_MHZ 0xE2
#define RFLR_FRFMID_906_MHZ 0x80
#define RFLR_FRFLSB_906_MHZ 0x00
#define RFLR_FRFMSB_907_MHZ 0xE2
#define RFLR_FRFMID_907_MHZ 0xC0
#define RFLR_FRFLSB_907_MHZ 0x00
#define RFLR_FRFMSB_908_MHZ 0xE3
#define RFLR_FRFMID_908_MHZ 0x00
#define RFLR_FRFLSB_908_MHZ 0x00
#define RFLR_FRFMSB_909_MHZ 0xE3
#define RFLR_FRFMID_909_MHZ 0x40
#define RFLR_FRFLSB_909_MHZ 0x00
#define RFLR_FRFMSB_910_MHZ 0xE3
#define RFLR_FRFMID_910_MHZ 0x80
#define RFLR_FRFLSB_910_MHZ 0x00
#define RFLR_FRFMSB_911_MHZ 0xE3
#define RFLR_FRFMID_911_MHZ 0xC0
#define RFLR_FRFLSB_911_MHZ 0x00
#define RFLR_FRFMSB_912_MHZ 0xE4
#define RFLR_FRFMID_912_MHZ 0x00
#define RFLR_FRFLSB_912_MHZ 0x00
#define RFLR_FRFMSB_913_MHZ 0xE4
#define RFLR_FRFMID_913_MHZ 0x40
#define RFLR_FRFLSB_913_MHZ 0x00
#define RFLR_FRFMSB_914_MHZ 0xE4
#define RFLR_FRFMID_914_MHZ 0x80
#define RFLR_FRFLSB_914_MHZ 0x00
#define RFLR_FRFMSB_915_MHZ 0xE4 // Default
#define RFLR_FRFMID_915_MHZ 0xC0 // Default
#define RFLR_FRFLSB_915_MHZ 0x00 // Default
#define RFLR_FRFMSB_916_MHZ 0xE5
#define RFLR_FRFMID_916_MHZ 0x00
#define RFLR_FRFLSB_916_MHZ 0x00
#define RFLR_FRFMSB_917_MHZ 0xE5
#define RFLR_FRFMID_917_MHZ 0x40
#define RFLR_FRFLSB_917_MHZ 0x00
#define RFLR_FRFMSB_918_MHZ 0xE5
#define RFLR_FRFMID_918_MHZ 0x80
#define RFLR_FRFLSB_918_MHZ 0x00
#define RFLR_FRFMSB_919_MHZ 0xE5
#define RFLR_FRFMID_919_MHZ 0xC0
#define RFLR_FRFLSB_919_MHZ 0x00
#define RFLR_FRFMSB_920_MHZ 0xE6
#define RFLR_FRFMID_920_MHZ 0x00
#define RFLR_FRFLSB_920_MHZ 0x00
#define RFLR_FRFMSB_921_MHZ 0xE6
#define RFLR_FRFMID_921_MHZ 0x40
#define RFLR_FRFLSB_921_MHZ 0x00
#define RFLR_FRFMSB_922_MHZ 0xE6
#define RFLR_FRFMID_922_MHZ 0x80
#define RFLR_FRFLSB_922_MHZ 0x00
#define RFLR_FRFMSB_923_MHZ 0xE6
#define RFLR_FRFMID_923_MHZ 0xC0
#define RFLR_FRFLSB_923_MHZ 0x00
#define RFLR_FRFMSB_924_MHZ 0xE7
#define RFLR_FRFMID_924_MHZ 0x00
#define RFLR_FRFLSB_924_MHZ 0x00
#define RFLR_FRFMSB_925_MHZ 0xE7
#define RFLR_FRFMID_925_MHZ 0x40
#define RFLR_FRFLSB_925_MHZ 0x00
#define RFLR_FRFMSB_926_MHZ 0xE7
#define RFLR_FRFMID_926_MHZ 0x80
#define RFLR_FRFLSB_926_MHZ 0x00
#define RFLR_FRFMSB_927_MHZ 0xE7
#define RFLR_FRFMID_927_MHZ 0xC0
#define RFLR_FRFLSB_927_MHZ 0x00
#define RFLR_FRFMSB_928_MHZ 0xE8
#define RFLR_FRFMID_928_MHZ 0x00
#define RFLR_FRFLSB_928_MHZ 0x00
//PA功率放大器 选择和输出功率控制设置相关宏定义 RegPaConfig寄存器地址0X09
#define RFLR_PACONFIG_PASELECT_MASK 0x7F
#define RFLR_PACONFIG_PASELECT_PABOOST 0x80
#define RFLR_PACONFIG_PASELECT_RFO 0x00 // Default
#define RFLR_PACONFIG_MAX_POWER_MASK 0x8F
#define RFLR_PACONFIG_OUTPUTPOWER_MASK 0xF0
//PA功率放大器 斜升/斜降时间和低相噪设置相关定义 RegPaRamp寄存器地址0X0A
#define RFLR_PARAMP_TXBANDFORCE_MASK 0xEF
#define RFLR_PARAMP_TXBANDFORCE_BAND_SEL 0x10
#define RFLR_PARAMP_TXBANDFORCE_AUTO 0x00 // Default
#define RFLR_PARAMP_MASK 0xF0
#define RFLR_PARAMP_3400_US 0x00
#define RFLR_PARAMP_2000_US 0x01
#define RFLR_PARAMP_1000_US 0x02
#define RFLR_PARAMP_0500_US 0x03
#define RFLR_PARAMP_0250_US 0x04
#define RFLR_PARAMP_0125_US 0x05
#define RFLR_PARAMP_0100_US 0x06
#define RFLR_PARAMP_0062_US 0x07
#define RFLR_PARAMP_0050_US 0x08
#define RFLR_PARAMP_0040_US 0x09 // Default
#define RFLR_PARAMP_0031_US 0x0A
#define RFLR_PARAMP_0025_US 0x0B
#define RFLR_PARAMP_0020_US 0x0C
#define RFLR_PARAMP_0015_US 0x0D
#define RFLR_PARAMP_0012_US 0x0E
#define RFLR_PARAMP_0010_US 0x0F
//过流保护控制设置相关宏定义 RegOcp寄存器地址0X0B
#define RFLR_OCP_MASK 0xDF
#define RFLR_OCP_ON 0x20 // Default
#define RFLR_OCP_OFF 0x00
#define RFLR_OCP_TRIM_MASK 0xE0
#define RFLR_OCP_TRIM_045_MA 0x00
#define RFLR_OCP_TRIM_050_MA 0x01
#define RFLR_OCP_TRIM_055_MA 0x02
#define RFLR_OCP_TRIM_060_MA 0x03
#define RFLR_OCP_TRIM_065_MA 0x04
#define RFLR_OCP_TRIM_070_MA 0x05
#define RFLR_OCP_TRIM_075_MA 0x06
#define RFLR_OCP_TRIM_080_MA 0x07
#define RFLR_OCP_TRIM_085_MA 0x08
#define RFLR_OCP_TRIM_090_MA 0x09
#define RFLR_OCP_TRIM_095_MA 0x0A
#define RFLR_OCP_TRIM_100_MA 0x0B // Default
#define RFLR_OCP_TRIM_105_MA 0x0C
#define RFLR_OCP_TRIM_110_MA 0x0D
#define RFLR_OCP_TRIM_115_MA 0x0E
#define RFLR_OCP_TRIM_120_MA 0x0F
#define RFLR_OCP_TRIM_130_MA 0x10
#define RFLR_OCP_TRIM_140_MA 0x11
#define RFLR_OCP_TRIM_150_MA 0x12
#define RFLR_OCP_TRIM_160_MA 0x13
#define RFLR_OCP_TRIM_170_MA 0x14
#define RFLR_OCP_TRIM_180_MA 0x15
#define RFLR_OCP_TRIM_190_MA 0x16
#define RFLR_OCP_TRIM_200_MA 0x17
#define RFLR_OCP_TRIM_210_MA 0x18
#define RFLR_OCP_TRIM_220_MA 0x19
#define RFLR_OCP_TRIM_230_MA 0x1A
#define RFLR_OCP_TRIM_240_MA 0x1B
//LNA低噪声放大器 )设置相关宏定义 RegLna寄存器地址0X0C
#define RFLR_LNA_GAIN_MASK 0x1F
#define RFLR_LNA_GAIN_G1 0x20 // Default
#define RFLR_LNA_GAIN_G2 0x40
#define RFLR_LNA_GAIN_G3 0x60
#define RFLR_LNA_GAIN_G4 0x80
#define RFLR_LNA_GAIN_G5 0xA0
#define RFLR_LNA_GAIN_G6 0xC0
#define RFLR_LNA_BOOST_LF_MASK 0xE7
#define RFLR_LNA_BOOST_LF_DEFAULT 0x00 // Default
#define RFLR_LNA_BOOST_LF_GAIN 0x08
#define RFLR_LNA_BOOST_LF_IP3 0x10
#define RFLR_LNA_BOOST_LF_BOOST 0x18
#define RFLR_LNA_RXBANDFORCE_MASK 0xFB
#define RFLR_LNA_RXBANDFORCE_BAND_SEL 0x04
#define RFLR_LNA_RXBANDFORCE_AUTO 0x00 // Default
#define RFLR_LNA_BOOST_HF_MASK 0xFC
#define RFLR_LNA_BOOST_HF_OFF 0x00 // Default
#define RFLR_LNA_BOOST_HF_ON 0x03
//FIFO 数据缓冲区中 SPI 接口地址指针寄存器地址0X0D
#define RFLR_FIFOADDRPTR 0x00 // Default
//发送信息的起始位置
#define RFLR_FIFOTXBASEADDR 0x80 // Default
//接收信息的起始位置
#define RFLR_FIFORXBASEADDR 0x00 // Default
/*!
* RegFifoRxCurrentAddr (Read Only)
*/
//关于中断屏蔽相关的宏定义
#define RFLR_IRQFLAGS_RXTIMEOUT_MASK 0x80
#define RFLR_IRQFLAGS_RXDONE_MASK 0x40
#define RFLR_IRQFLAGS_PAYLOADCRCERROR_MASK 0x20
#define RFLR_IRQFLAGS_VALIDHEADER_MASK 0x10
#define RFLR_IRQFLAGS_TXDONE_MASK 0x08
#define RFLR_IRQFLAGS_CADDONE_MASK 0x04
#define RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL_MASK 0x02
#define RFLR_IRQFLAGS_CADDETECTED_MASK 0x01
//关于中断打开相关的宏定义
#define RFLR_IRQFLAGS_RXTIMEOUT 0x80
#define RFLR_IRQFLAGS_RXDONE 0x40
#define RFLR_IRQFLAGS_PAYLOADCRCERROR 0x20
#define RFLR_IRQFLAGS_VALIDHEADER 0x10
#define RFLR_IRQFLAGS_TXDONE 0x08
#define RFLR_IRQFLAGS_CADDONE 0x04
#define RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL 0x02
#define RFLR_IRQFLAGS_CADDETECTED 0x01
/*!
* RegFifoRxNbBytes (Read Only) //
*/
/*!
* RegRxHeaderCntValueMsb (Read Only) //
*/
/*!
* RegRxHeaderCntValueLsb (Read Only) //
*/
/*!
* RegRxPacketCntValueMsb (Read Only) //
*/
/*!
* RegRxPacketCntValueLsb (Read Only) //
*/
/*!
* RegModemStat (Read Only) //
*/
#define RFLR_MODEMSTAT_RX_CR_MASK 0x1F
#define RFLR_MODEMSTAT_MODEM_STATUS_MASK 0xE0
/*!
* RegPktSnrValue (Read Only) //
*/
/*!
* RegPktRssiValue (Read Only) //
*/
/*!
* RegRssiValue (Read Only) //
*/
//与信号宽度纠错编码率是否显示报头有关宏定义寄存器位置0X1D
#define RFLR_MODEMCONFIG1_BW_MASK 0x0F
#define RFLR_MODEMCONFIG1_BW_7_81_KHZ 0x00
#define RFLR_MODEMCONFIG1_BW_10_41_KHZ 0x10
#define RFLR_MODEMCONFIG1_BW_15_62_KHZ 0x20
#define RFLR_MODEMCONFIG1_BW_20_83_KHZ 0x30
#define RFLR_MODEMCONFIG1_BW_31_25_KHZ 0x40
#define RFLR_MODEMCONFIG1_BW_41_66_KHZ 0x50
#define RFLR_MODEMCONFIG1_BW_62_50_KHZ 0x60
#define RFLR_MODEMCONFIG1_BW_125_KHZ 0x70 // Default
#define RFLR_MODEMCONFIG1_BW_250_KHZ 0x80
#define RFLR_MODEMCONFIG1_BW_500_KHZ 0x90
#define RFLR_MODEMCONFIG1_CODINGRATE_MASK 0xF1
#define RFLR_MODEMCONFIG1_CODINGRATE_4_5 0x02
#define RFLR_MODEMCONFIG1_CODINGRATE_4_6 0x04 // Default
#define RFLR_MODEMCONFIG1_CODINGRATE_4_7 0x06
#define RFLR_MODEMCONFIG1_CODINGRATE_4_8 0x08
#define RFLR_MODEMCONFIG1_IMPLICITHEADER_MASK 0xFE
#define RFLR_MODEMCONFIG1_IMPLICITHEADER_ON 0x01
#define RFLR_MODEMCONFIG1_IMPLICITHEADER_OFF 0x00 // Default
//与扩频因子接收模式发送CRC开启RX超时相关宏定义
#define RFLR_MODEMCONFIG2_SF_MASK 0x0F
#define RFLR_MODEMCONFIG2_SF_6 0x60
#define RFLR_MODEMCONFIG2_SF_7 0x70 // Default
#define RFLR_MODEMCONFIG2_SF_8 0x80
#define RFLR_MODEMCONFIG2_SF_9 0x90
#define RFLR_MODEMCONFIG2_SF_10 0xA0
#define RFLR_MODEMCONFIG2_SF_11 0xB0
#define RFLR_MODEMCONFIG2_SF_12 0xC0
#define RFLR_MODEMCONFIG2_TXCONTINUOUSMODE_MASK 0xF7
#define RFLR_MODEMCONFIG2_TXCONTINUOUSMODE_ON 0x08
#define RFLR_MODEMCONFIG2_TXCONTINUOUSMODE_OFF 0x00
#define RFLR_MODEMCONFIG2_RXPAYLOADCRC_MASK 0xFB
#define RFLR_MODEMCONFIG2_RXPAYLOADCRC_ON 0x04
#define RFLR_MODEMCONFIG2_RXPAYLOADCRC_OFF 0x00 // Default
#define RFLR_MODEMCONFIG2_SYMBTIMEOUTMSB_MASK 0xFC
#define RFLR_MODEMCONFIG2_SYMBTIMEOUTMSB 0x00 // Default
/*!
* RegHopChannel (Read Only)
*/
#define RFLR_HOPCHANNEL_PLL_LOCK_TIMEOUT_MASK 0x7F
#define RFLR_HOPCHANNEL_PLL_LOCK_FAIL 0x80
#define RFLR_HOPCHANNEL_PLL_LOCK_SUCCEED 0x00 // Default
#define RFLR_HOPCHANNEL_PAYLOAD_CRC16_MASK 0xBF
#define RFLR_HOPCHANNEL_PAYLOAD_CRC16_ON 0x40
#define RFLR_HOPCHANNEL_PAYLOAD_CRC16_OFF 0x00 // Default
#define RFLR_HOPCHANNEL_CHANNEL_MASK 0x3F
/*!
* RegSymbTimeoutLsb
*/
#define RFLR_SYMBTIMEOUTLSB_SYMBTIMEOUT 0x64 // Default
/*!
* RegPreambleLengthMsb
*/
#define RFLR_PREAMBLELENGTHMSB 0x00 // Default
/*!
* RegPreambleLengthLsb
*/
#define RFLR_PREAMBLELENGTHLSB 0x08 // Default
/*!
* RegPayloadLength
*/
#define RFLR_PAYLOADLENGTH 0x0E // Default
/*!
* RegPayloadMaxLength
*/
#define RFLR_PAYLOADMAXLENGTH 0xFF // Default
/*!
* RegHopPeriod
*/
#define RFLR_HOPPERIOD_FREQFOPPINGPERIOD 0x00 // Default
/*!
* RegDioMapping1
*/
#define RFLR_DIOMAPPING1_DIO0_MASK 0x3F
#define RFLR_DIOMAPPING1_DIO0_00 0x00 // Default
#define RFLR_DIOMAPPING1_DIO0_01 0x40
#define RFLR_DIOMAPPING1_DIO0_10 0x80
#define RFLR_DIOMAPPING1_DIO0_11 0xC0
#define RFLR_DIOMAPPING1_DIO1_MASK 0xCF
#define RFLR_DIOMAPPING1_DIO1_00 0x00 // Default
#define RFLR_DIOMAPPING1_DIO1_01 0x10
#define RFLR_DIOMAPPING1_DIO1_10 0x20
#define RFLR_DIOMAPPING1_DIO1_11 0x30
#define RFLR_DIOMAPPING1_DIO2_MASK 0xF3
#define RFLR_DIOMAPPING1_DIO2_00 0x00 // Default
#define RFLR_DIOMAPPING1_DIO2_01 0x04
#define RFLR_DIOMAPPING1_DIO2_10 0x08
#define RFLR_DIOMAPPING1_DIO2_11 0x0C
#define RFLR_DIOMAPPING1_DIO3_MASK 0xFC
#define RFLR_DIOMAPPING1_DIO3_00 0x00 // Default
#define RFLR_DIOMAPPING1_DIO3_01 0x01
#define RFLR_DIOMAPPING1_DIO3_10 0x02
#define RFLR_DIOMAPPING1_DIO3_11 0x03
/*!
* RegDioMapping2
*/
#define RFLR_DIOMAPPING2_DIO4_MASK 0x3F
#define RFLR_DIOMAPPING2_DIO4_00 0x00 // Default
#define RFLR_DIOMAPPING2_DIO4_01 0x40
#define RFLR_DIOMAPPING2_DIO4_10 0x80
#define RFLR_DIOMAPPING2_DIO4_11 0xC0
#define RFLR_DIOMAPPING2_DIO5_MASK 0xCF
#define RFLR_DIOMAPPING2_DIO5_00 0x00 // Default
#define RFLR_DIOMAPPING2_DIO5_01 0x10
#define RFLR_DIOMAPPING2_DIO5_10 0x20
#define RFLR_DIOMAPPING2_DIO5_11 0x30
#define RFLR_DIOMAPPING2_MAP_MASK 0xFE
#define RFLR_DIOMAPPING2_MAP_PREAMBLEDETECT 0x01
#define RFLR_DIOMAPPING2_MAP_RSSI 0x00 // Default
/*!
* RegVersion (Read Only)
*/
/*!
* RegAgcRef
*/
/*!
* RegAgcThresh1
*/
/*!
* RegAgcThresh2
*/
/*!
* RegAgcThresh3
*/
/*!
* RegFifoRxByteAddr (Read Only)
*/
/*!
* RegPllHop
*/
#define RFLR_PLLHOP_FASTHOP_MASK 0x7F
#define RFLR_PLLHOP_FASTHOP_ON 0x80
#define RFLR_PLLHOP_FASTHOP_OFF 0x00 // Default
/*!
* RegTcxo
*/
#define RFLR_TCXO_TCXOINPUT_MASK 0xEF
#define RFLR_TCXO_TCXOINPUT_ON 0x10
#define RFLR_TCXO_TCXOINPUT_OFF 0x00 // Default
/*!
* RegPaDac
*/
#define RFLR_PADAC_20DBM_MASK 0xF8
#define RFLR_PADAC_20DBM_ON 0x07
#define RFLR_PADAC_20DBM_OFF 0x04 // Default
/*!
* RegPll
*/
#define RFLR_PLL_BANDWIDTH_MASK 0x3F
#define RFLR_PLL_BANDWIDTH_75 0x00
#define RFLR_PLL_BANDWIDTH_150 0x40
#define RFLR_PLL_BANDWIDTH_225 0x80
#define RFLR_PLL_BANDWIDTH_300 0xC0 // Default
/*!
* RegPllLowPn
*/
#define RFLR_PLLLOWPN_BANDWIDTH_MASK 0x3F
#define RFLR_PLLLOWPN_BANDWIDTH_75 0x00
#define RFLR_PLLLOWPN_BANDWIDTH_150 0x40
#define RFLR_PLLLOWPN_BANDWIDTH_225 0x80
#define RFLR_PLLLOWPN_BANDWIDTH_300 0xC0 // Default
/*!
* RegModemConfig3
*/
#define RFLR_MODEMCONFIG3_LOWDATARATEOPTIMIZE_MASK 0xF7
#define RFLR_MODEMCONFIG3_LOWDATARATEOPTIMIZE_ON 0x08
#define RFLR_MODEMCONFIG3_LOWDATARATEOPTIMIZE_OFF 0x00 // Default
#define RFLR_MODEMCONFIG3_AGCAUTO_MASK 0xFB
#define RFLR_MODEMCONFIG3_AGCAUTO_ON 0x04 // Default
#define RFLR_MODEMCONFIG3_AGCAUTO_OFF 0x00
/*!
* RegFormerTemp
*/
typedef struct sSX1276LR
{
uint8_t RegFifo; // 0x00
// Common settings
uint8_t RegOpMode; // 0x01
uint8_t RegRes02; // 0x02
uint8_t RegRes03; // 0x03
uint8_t RegBandSetting; // 0x04
uint8_t RegRes05; // 0x05
uint8_t RegFrfMsb; // 0x06
uint8_t RegFrfMid; // 0x07
uint8_t RegFrfLsb; // 0x08
// Tx settings
uint8_t RegPaConfig; // 0x09
uint8_t RegPaRamp; // 0x0A
uint8_t RegOcp; // 0x0B
// Rx settings
uint8_t RegLna; // 0x0C
// LoRa registers
uint8_t RegFifoAddrPtr; // 0x0D
uint8_t RegFifoTxBaseAddr; // 0x0E
uint8_t RegFifoRxBaseAddr; // 0x0F
uint8_t RegFifoRxCurrentAddr; // 0x10
uint8_t RegIrqFlagsMask; // 0x11
uint8_t RegIrqFlags; // 0x12
uint8_t RegNbRxBytes; // 0x13
uint8_t RegRxHeaderCntValueMsb; // 0x14
uint8_t RegRxHeaderCntValueLsb; // 0x15
uint8_t RegRxPacketCntValueMsb; // 0x16
uint8_t RegRxPacketCntValueLsb; // 0x17
uint8_t RegModemStat; // 0x18
uint8_t RegPktSnrValue; // 0x19
uint8_t RegPktRssiValue; // 0x1A
uint8_t RegRssiValue; // 0x1B
uint8_t RegHopChannel; // 0x1C
uint8_t RegModemConfig1; // 0x1D
uint8_t RegModemConfig2; // 0x1E
uint8_t RegSymbTimeoutLsb; // 0x1F
uint8_t RegPreambleMsb; // 0x20
uint8_t RegPreambleLsb; // 0x21
uint8_t RegPayloadLength; // 0x22
uint8_t RegMaxPayloadLength; // 0x23
uint8_t RegHopPeriod; // 0x24 跳频周期
uint8_t RegFifoRxByteAddr; // 0x25
uint8_t RegModemConfig3; // 0x26
uint8_t RegTestReserved27[0x30 - 0x27]; // 0x27-0x30
uint8_t RegTestReserved31; // 0x31
uint8_t RegTestReserved32[0x40 - 0x32]; // 0x32-0x40
// I/O settings
uint8_t RegDioMapping1; // 0x40
uint8_t RegDioMapping2; // 0x41
// Version
uint8_t RegVersion; // 0x42
// Additional settings
uint8_t RegAgcRef; // 0x43
uint8_t RegAgcThresh1; // 0x44
uint8_t RegAgcThresh2; // 0x45
uint8_t RegAgcThresh3; // 0x46
// Test
uint8_t RegTestReserved47[0x4B - 0x47]; // 0x47-0x4A
// Additional settings
uint8_t RegPllHop; // 0x4B
uint8_t RegTestReserved4C; // 0x4C
uint8_t RegPaDac; // 0x4D
// Test
uint8_t RegTestReserved4E[0x58-0x4E]; // 0x4E-0x57
// Additional settings
uint8_t RegTcxo; // 0x58
// Test
uint8_t RegTestReserved59; // 0x59
// Test
uint8_t RegTestReserved5B; // 0x5B
// Additional settings
uint8_t RegPll; // 0x5C
// Test
uint8_t RegTestReserved5D; // 0x5D
// Additional settings
uint8_t RegPllLowPn; // 0x5E
// Test
uint8_t RegTestReserved5F[0x6C - 0x5F]; // 0x5F-0x6B
// Additional settings
uint8_t RegFormerTemp; // 0x6C
// Test
uint8_t RegTestReserved6D[0x71 - 0x6D]; // 0x6D-0x70
}tSX1276LR;
extern tSX1276LR* SX1276LR;
//初始化SX1276LoRa模式
void SX1276LoRaInit( void );
//读SX1276的版本号
void SX1276LoRaSetDefaults( void );
//启用/禁用LoRa模式
void SX1276LoRaSetLoRaOn( bool enable );
//设置SX1276操作模式
void SX1276LoRaSetOpMode( uint8_t opMode );
//获取SX1276操作模式
uint8_t SX1276LoRaGetOpMode( void );
//读取SX1276低噪声放大器信号放大的增益
uint8_t SX1276LoRaReadRxGain( void );
//读取lora模式下无线信号强度
double SX1276LoRaReadRssi( void );
//获取数据时的增益值
uint8_t SX1276LoRaGetPacketRxGain( void );
//获取数据时的信噪比值,信号和噪声的比值,信噪比越高,说明信号干扰越小。
int8_t SX1276LoRaGetPacketSnr( void );
//获取数据时的无线信号强度
double SX1276LoRaGetPacketRssi( void );
//开始接收
void SX1276LoRaStartRx( void );
//接收数据
void SX1276LoRaGetRxPacket( void *buffer, uint16_t *size );
//发送数据
void SX1276LoRaSetTxPacket( const void *buffer, uint16_t size );
//得到RFLRState状态
uint8_t SX1276LoRaGetRFState( void );
//设置RFLRState状态RFLRState的值决定了下面的函数处理哪一步的代码
void SX1276LoRaSetRFState( uint8_t state );
//SX1276模块接发收数据的处理函数
uint32_t SX1276LoRaProcess( void );
uint32_t SX1276LoraChannelEmpty( void );
#endif

420
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/spi/third_party_spi_lora/sx12xx/src/radio/sx1276-LoRaMisc.c Normal file
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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file sx1276-LoRaMisc.c
* \brief SX1276 RF chip high level functions driver
*
* \remark Optional support functions.
* These functions are defined only to easy the change of the
* parameters.
* For a final firmware the radio parameters will be known so
* there is no need to support all possible parameters.
* Removing these functions will greatly reduce the final firmware
* size.
*
* \version 2.0.0
* \date May 6 2013
* \author Gregory Cristian
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276-LoRaMisc.c
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#include "platform.h"
#if defined( USE_SX1276_RADIO )
#include "sx1276-Hal.h"
#include "sx1276.h"
#include "sx1276-LoRa.h"
#include "sx1276-LoRaMisc.h"
/*!
* SX1276 definitions
*/
#define XTAL_FREQ 32000000
#define FREQ_STEP 61.03515625
extern tLoRaSettings LoRaSettings;
void SX1276LoRaSetRFFrequency( uint32_t freq )
{
LoRaSettings.RFFrequency = freq;
freq = ( uint32_t )( ( double )freq / ( double )FREQ_STEP );
SX1276LR->RegFrfMsb = ( uint8_t )( ( freq >> 16 ) & 0xFF );
SX1276LR->RegFrfMid = ( uint8_t )( ( freq >> 8 ) & 0xFF );
SX1276LR->RegFrfLsb = ( uint8_t )( freq & 0xFF );
SX1276WriteBuffer( REG_LR_FRFMSB, &SX1276LR->RegFrfMsb, 3 );
}
uint32_t SX1276LoRaGetRFFrequency( void )
{
SX1276ReadBuffer( REG_LR_FRFMSB, &SX1276LR->RegFrfMsb, 3 );
LoRaSettings.RFFrequency = ( ( uint32_t )SX1276LR->RegFrfMsb << 16 ) | ( ( uint32_t )SX1276LR->RegFrfMid << 8 ) | ( ( uint32_t )SX1276LR->RegFrfLsb );
LoRaSettings.RFFrequency = ( uint32_t )( ( double )LoRaSettings.RFFrequency * ( double )FREQ_STEP );
return LoRaSettings.RFFrequency;
}
void SX1276LoRaSetRFPower( int8_t power )
{
SX1276Read( REG_LR_PACONFIG, &SX1276LR->RegPaConfig );
SX1276Read( REG_LR_PADAC, &SX1276LR->RegPaDac );
if( ( SX1276LR->RegPaConfig & RFLR_PACONFIG_PASELECT_PABOOST ) == RFLR_PACONFIG_PASELECT_PABOOST )
{
if( ( SX1276LR->RegPaDac & 0x87 ) == 0x87 )
{
if( power < 5 )
{
power = 5;
}
if( power > 20 )
{
power = 20;
}
SX1276LR->RegPaConfig = ( SX1276LR->RegPaConfig & RFLR_PACONFIG_MAX_POWER_MASK ) | 0x70;
SX1276LR->RegPaConfig = ( SX1276LR->RegPaConfig & RFLR_PACONFIG_OUTPUTPOWER_MASK ) | ( uint8_t )( ( uint16_t )( power - 5 ) & 0x0F );
}
else
{
if( power < 2 )
{
power = 2;
}
if( power > 17 )
{
power = 17;
}
SX1276LR->RegPaConfig = ( SX1276LR->RegPaConfig & RFLR_PACONFIG_MAX_POWER_MASK ) | 0x70;
SX1276LR->RegPaConfig = ( SX1276LR->RegPaConfig & RFLR_PACONFIG_OUTPUTPOWER_MASK ) | ( uint8_t )( ( uint16_t )( power - 2 ) & 0x0F );
}
}
else
{
if( power < -1 )
{
power = -1;
}
if( power > 14 )
{
power = 14;
}
SX1276LR->RegPaConfig = ( SX1276LR->RegPaConfig & RFLR_PACONFIG_MAX_POWER_MASK ) | 0x70;
SX1276LR->RegPaConfig = ( SX1276LR->RegPaConfig & RFLR_PACONFIG_OUTPUTPOWER_MASK ) | ( uint8_t )( ( uint16_t )( power + 1 ) & 0x0F );
}
SX1276Write( REG_LR_PACONFIG, SX1276LR->RegPaConfig );
LoRaSettings.Power = power;
}
int8_t SX1276LoRaGetRFPower( void )
{
SX1276Read( REG_LR_PACONFIG, &SX1276LR->RegPaConfig );
SX1276Read( REG_LR_PADAC, &SX1276LR->RegPaDac );
if( ( SX1276LR->RegPaConfig & RFLR_PACONFIG_PASELECT_PABOOST ) == RFLR_PACONFIG_PASELECT_PABOOST )
{
if( ( SX1276LR->RegPaDac & 0x07 ) == 0x07 )
{
LoRaSettings.Power = 5 + ( SX1276LR->RegPaConfig & ~RFLR_PACONFIG_OUTPUTPOWER_MASK );
}
else
{
LoRaSettings.Power = 2 + ( SX1276LR->RegPaConfig & ~RFLR_PACONFIG_OUTPUTPOWER_MASK );
}
}
else
{
LoRaSettings.Power = -1 + ( SX1276LR->RegPaConfig & ~RFLR_PACONFIG_OUTPUTPOWER_MASK );
}
return LoRaSettings.Power;
}
void SX1276LoRaSetSignalBandwidth( uint8_t bw )
{
SX1276Read( REG_LR_MODEMCONFIG1, &SX1276LR->RegModemConfig1 );
SX1276LR->RegModemConfig1 = ( SX1276LR->RegModemConfig1 & RFLR_MODEMCONFIG1_BW_MASK ) | ( bw << 4 );
SX1276Write( REG_LR_MODEMCONFIG1, SX1276LR->RegModemConfig1 );
LoRaSettings.SignalBw = bw;
}
uint8_t SX1276LoRaGetSignalBandwidth( void )
{
SX1276Read( REG_LR_MODEMCONFIG1, &SX1276LR->RegModemConfig1 );
LoRaSettings.SignalBw = ( SX1276LR->RegModemConfig1 & ~RFLR_MODEMCONFIG1_BW_MASK ) >> 4;
return LoRaSettings.SignalBw;
}
void SX1276LoRaSetSpreadingFactor( uint8_t factor )
{
if( factor > 12 )
{
factor = 12;
}
else if( factor < 6 )
{
factor = 6;
}
if( factor == 6 )
{
SX1276LoRaSetNbTrigPeaks( 5 );
}
else
{
SX1276LoRaSetNbTrigPeaks( 3 );
}
SX1276Read( REG_LR_MODEMCONFIG2, &SX1276LR->RegModemConfig2 );
SX1276LR->RegModemConfig2 = ( SX1276LR->RegModemConfig2 & RFLR_MODEMCONFIG2_SF_MASK ) | ( factor << 4 );
SX1276Write( REG_LR_MODEMCONFIG2, SX1276LR->RegModemConfig2 );
LoRaSettings.SpreadingFactor = factor;
}
uint8_t SX1276LoRaGetSpreadingFactor( void )
{
SX1276Read( REG_LR_MODEMCONFIG2, &SX1276LR->RegModemConfig2 );
LoRaSettings.SpreadingFactor = ( SX1276LR->RegModemConfig2 & ~RFLR_MODEMCONFIG2_SF_MASK ) >> 4;
return LoRaSettings.SpreadingFactor;
}
void SX1276LoRaSetErrorCoding( uint8_t value )
{
SX1276Read( REG_LR_MODEMCONFIG1, &SX1276LR->RegModemConfig1 );
SX1276LR->RegModemConfig1 = ( SX1276LR->RegModemConfig1 & RFLR_MODEMCONFIG1_CODINGRATE_MASK ) | ( value << 1 );
SX1276Write( REG_LR_MODEMCONFIG1, SX1276LR->RegModemConfig1 );
LoRaSettings.ErrorCoding = value;
}
uint8_t SX1276LoRaGetErrorCoding( void )
{
SX1276Read( REG_LR_MODEMCONFIG1, &SX1276LR->RegModemConfig1 );
LoRaSettings.ErrorCoding = ( SX1276LR->RegModemConfig1 & ~RFLR_MODEMCONFIG1_CODINGRATE_MASK ) >> 1;
return LoRaSettings.ErrorCoding;
}
void SX1276LoRaSetPacketCrcOn( bool enable )
{
SX1276Read( REG_LR_MODEMCONFIG2, &SX1276LR->RegModemConfig2 );
SX1276LR->RegModemConfig2 = ( SX1276LR->RegModemConfig2 & RFLR_MODEMCONFIG2_RXPAYLOADCRC_MASK ) | ( enable << 2 );
SX1276Write( REG_LR_MODEMCONFIG2, SX1276LR->RegModemConfig2 );
LoRaSettings.CrcOn = enable;
}
void SX1276LoRaSetPreambleLength( uint16_t value )
{
SX1276ReadBuffer( REG_LR_PREAMBLEMSB, &SX1276LR->RegPreambleMsb, 2 );
SX1276LR->RegPreambleMsb = ( value >> 8 ) & 0x00FF;
SX1276LR->RegPreambleLsb = value & 0xFF;
SX1276WriteBuffer( REG_LR_PREAMBLEMSB, &SX1276LR->RegPreambleMsb, 2 );
}
uint16_t SX1276LoRaGetPreambleLength( void )
{
SX1276ReadBuffer( REG_LR_PREAMBLEMSB, &SX1276LR->RegPreambleMsb, 2 );
return ( ( SX1276LR->RegPreambleMsb & 0x00FF ) << 8 ) | SX1276LR->RegPreambleLsb;
}
bool SX1276LoRaGetPacketCrcOn( void )
{
SX1276Read( REG_LR_MODEMCONFIG2, &SX1276LR->RegModemConfig2 );
LoRaSettings.CrcOn = ( SX1276LR->RegModemConfig2 & RFLR_MODEMCONFIG2_RXPAYLOADCRC_ON ) >> 1;
return LoRaSettings.CrcOn;
}
void SX1276LoRaSetImplicitHeaderOn( bool enable )
{
SX1276Read( REG_LR_MODEMCONFIG1, &SX1276LR->RegModemConfig1 );
SX1276LR->RegModemConfig1 = ( SX1276LR->RegModemConfig1 & RFLR_MODEMCONFIG1_IMPLICITHEADER_MASK ) | ( enable );
SX1276Write( REG_LR_MODEMCONFIG1, SX1276LR->RegModemConfig1 );
LoRaSettings.ImplicitHeaderOn = enable;
}
bool SX1276LoRaGetImplicitHeaderOn( void )
{
SX1276Read( REG_LR_MODEMCONFIG1, &SX1276LR->RegModemConfig1 );
LoRaSettings.ImplicitHeaderOn = ( SX1276LR->RegModemConfig1 & RFLR_MODEMCONFIG1_IMPLICITHEADER_ON );
return LoRaSettings.ImplicitHeaderOn;
}
void SX1276LoRaSetRxSingleOn( bool enable )
{
LoRaSettings.RxSingleOn = enable;
}
bool SX1276LoRaGetRxSingleOn( void )
{
return LoRaSettings.RxSingleOn;
}
void SX1276LoRaSetFreqHopOn( bool enable )
{
LoRaSettings.FreqHopOn = enable;
}
bool SX1276LoRaGetFreqHopOn( void )
{
return LoRaSettings.FreqHopOn;
}
void SX1276LoRaSetHopPeriod( uint8_t value )
{
SX1276LR->RegHopPeriod = value;
SX1276Write( REG_LR_HOPPERIOD, SX1276LR->RegHopPeriod );
LoRaSettings.HopPeriod = value;
}
uint8_t SX1276LoRaGetHopPeriod( void )
{
SX1276Read( REG_LR_HOPPERIOD, &SX1276LR->RegHopPeriod );
LoRaSettings.HopPeriod = SX1276LR->RegHopPeriod;
return LoRaSettings.HopPeriod;
}
void SX1276LoRaSetTxPacketTimeout( uint32_t value )
{
LoRaSettings.TxPacketTimeout = value;
}
uint32_t SX1276LoRaGetTxPacketTimeout( void )
{
return LoRaSettings.TxPacketTimeout;
}
void SX1276LoRaSetRxPacketTimeout( uint32_t value )
{
LoRaSettings.RxPacketTimeout = value;
}
uint32_t SX1276LoRaGetRxPacketTimeout( void )
{
return LoRaSettings.RxPacketTimeout;
}
void SX1276LoRaSetPayloadLength( uint8_t value )
{
SX1276LR->RegPayloadLength = value;
SX1276Write( REG_LR_PAYLOADLENGTH, SX1276LR->RegPayloadLength );
LoRaSettings.PayloadLength = value;
}
uint8_t SX1276LoRaGetPayloadLength( void )
{
SX1276Read( REG_LR_PAYLOADLENGTH, &SX1276LR->RegPayloadLength );
LoRaSettings.PayloadLength = SX1276LR->RegPayloadLength;
return LoRaSettings.PayloadLength;
}
void SX1276LoRaSetPa20dBm( bool enale )
{
SX1276Read( REG_LR_PADAC, &SX1276LR->RegPaDac );
SX1276Read( REG_LR_PACONFIG, &SX1276LR->RegPaConfig );
if( ( SX1276LR->RegPaConfig & RFLR_PACONFIG_PASELECT_PABOOST ) == RFLR_PACONFIG_PASELECT_PABOOST )
{
if( enale == true )
{
SX1276LR->RegPaDac = 0x87;
}
}
else
{
SX1276LR->RegPaDac = 0x84;
}
SX1276Write( REG_LR_PADAC, SX1276LR->RegPaDac );
}
bool SX1276LoRaGetPa20dBm( void )
{
SX1276Read( REG_LR_PADAC, &SX1276LR->RegPaDac );
return ( ( SX1276LR->RegPaDac & 0x07 ) == 0x07 ) ? true : false;
}
void SX1276LoRaSetPAOutput( uint8_t outputPin )
{
SX1276Read( REG_LR_PACONFIG, &SX1276LR->RegPaConfig );
SX1276LR->RegPaConfig = (SX1276LR->RegPaConfig & RFLR_PACONFIG_PASELECT_MASK ) | outputPin;
SX1276Write( REG_LR_PACONFIG, SX1276LR->RegPaConfig );
}
uint8_t SX1276LoRaGetPAOutput( void )
{
SX1276Read( REG_LR_PACONFIG, &SX1276LR->RegPaConfig );
return SX1276LR->RegPaConfig & ~RFLR_PACONFIG_PASELECT_MASK;
}
void SX1276LoRaSetPaRamp( uint8_t value )
{
SX1276Read( REG_LR_PARAMP, &SX1276LR->RegPaRamp );
SX1276LR->RegPaRamp = ( SX1276LR->RegPaRamp & RFLR_PARAMP_MASK ) | ( value & ~RFLR_PARAMP_MASK );
SX1276Write( REG_LR_PARAMP, SX1276LR->RegPaRamp );
}
uint8_t SX1276LoRaGetPaRamp( void )
{
SX1276Read( REG_LR_PARAMP, &SX1276LR->RegPaRamp );
return SX1276LR->RegPaRamp & ~RFLR_PARAMP_MASK;
}
void SX1276LoRaSetSymbTimeout( uint16_t value )
{
SX1276ReadBuffer( REG_LR_MODEMCONFIG2, &SX1276LR->RegModemConfig2, 2 );
SX1276LR->RegModemConfig2 = ( SX1276LR->RegModemConfig2 & RFLR_MODEMCONFIG2_SYMBTIMEOUTMSB_MASK ) | ( ( value >> 8 ) & ~RFLR_MODEMCONFIG2_SYMBTIMEOUTMSB_MASK );
SX1276LR->RegSymbTimeoutLsb = value & 0xFF;
SX1276WriteBuffer( REG_LR_MODEMCONFIG2, &SX1276LR->RegModemConfig2, 2 );
}
uint16_t SX1276LoRaGetSymbTimeout( void )
{
SX1276ReadBuffer( REG_LR_MODEMCONFIG2, &SX1276LR->RegModemConfig2, 2 );
return ( ( SX1276LR->RegModemConfig2 & ~RFLR_MODEMCONFIG2_SYMBTIMEOUTMSB_MASK ) << 8 ) | SX1276LR->RegSymbTimeoutLsb;
}
void SX1276LoRaSetLowDatarateOptimize( bool enable )
{
SX1276Read( REG_LR_MODEMCONFIG3, &SX1276LR->RegModemConfig3 );
SX1276LR->RegModemConfig3 = ( SX1276LR->RegModemConfig3 & RFLR_MODEMCONFIG3_LOWDATARATEOPTIMIZE_MASK ) | ( enable << 3 );
SX1276Write( REG_LR_MODEMCONFIG3, SX1276LR->RegModemConfig3 );
}
bool SX1276LoRaGetLowDatarateOptimize( void )
{
SX1276Read( REG_LR_MODEMCONFIG3, &SX1276LR->RegModemConfig3 );
return ( ( SX1276LR->RegModemConfig3 & RFLR_MODEMCONFIG3_LOWDATARATEOPTIMIZE_ON ) >> 3 );
}
void SX1276LoRaSetNbTrigPeaks( uint8_t value )
{
SX1276Read( 0x31, &SX1276LR->RegTestReserved31 );
SX1276LR->RegTestReserved31 = ( SX1276LR->RegTestReserved31 & 0xF8 ) | value;//数据包长度最高有效位 0x31 bit2 1 0
SX1276Write( 0x31, SX1276LR->RegTestReserved31 );
}
uint8_t SX1276LoRaGetNbTrigPeaks( void )
{
SX1276Read( 0x31, &SX1276LR->RegTestReserved31 );
return ( SX1276LR->RegTestReserved31 & 0x07 );
}
#endif // USE_SX1276_RADIO

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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file sx1276-LoRaMisc.h
* \brief SX1276 RF chip high level functions driver
*
* \remark Optional support functions.
* These functions are defined only to easy the change of the
* parameters.
* For a final firmware the radio parameters will be known so
* there is no need to support all possible parameters.
* Removing these functions will greatly reduce the final firmware
* size.
*
* \version 2.0.0
* \date May 6 2013
* \author Gregory Cristian
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276-LoRaMisc.h
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#ifndef __SX1276_LORA_MISC_H__
#define __SX1276_LORA_MISC_H__
#include "stdint.h"
#include "stdbool.h"
/*!
* \brief Writes the new RF frequency value
*
* \param [IN] freq New RF frequency value in [Hz]
*/
void SX1276LoRaSetRFFrequency( uint32_t freq );
/*!
* \brief Reads the current RF frequency value
*
* \retval freq Current RF frequency value in [Hz]
*/
uint32_t SX1276LoRaGetRFFrequency( void );
/*!
* \brief Writes the new RF output power value
*
* \param [IN] power New output power value in [dBm]
*/
void SX1276LoRaSetRFPower( int8_t power );
/*!
* \brief Reads the current RF output power value
*
* \retval power Current output power value in [dBm]
*/
int8_t SX1276LoRaGetRFPower( void );
/*!
* \brief Writes the new Signal Bandwidth value
*
* \remark This function sets the IF frequency according to the datasheet
*
* \param [IN] factor New Signal Bandwidth value [0: 125 kHz, 1: 250 kHz, 2: 500 kHz]
*/
void SX1276LoRaSetSignalBandwidth( uint8_t bw );
/*!
* \brief Reads the current Signal Bandwidth value
*
* \retval factor Current Signal Bandwidth value [0: 125 kHz, 1: 250 kHz, 2: 500 kHz]
*/
uint8_t SX1276LoRaGetSignalBandwidth( void );
/*!
* \brief Writes the new Spreading Factor value
*
* \param [IN] factor New Spreading Factor value [7, 8, 9, 10, 11, 12]
*/
void SX1276LoRaSetSpreadingFactor( uint8_t factor );
/*!
* \brief Reads the current Spreading Factor value
*
* \retval factor Current Spreading Factor value [7, 8, 9, 10, 11, 12]
*/
uint8_t SX1276LoRaGetSpreadingFactor( void );
/*!
* \brief Writes the new Error Coding value
*
* \param [IN] value New Error Coding value [1: 4/5, 2: 4/6, 3: 4/7, 4: 4/8]
*/
void SX1276LoRaSetErrorCoding( uint8_t value );
/*!
* \brief Reads the current Error Coding value
*
* \retval value Current Error Coding value [1: 4/5, 2: 4/6, 3: 4/7, 4: 4/8]
*/
uint8_t SX1276LoRaGetErrorCoding( void );
/*!
* \brief Enables/Disables the packet CRC generation
*
* \param [IN] enaable [true, false]
*/
void SX1276LoRaSetPacketCrcOn( bool enable );
/*!
* \brief Reads the current packet CRC generation status
*
* \retval enable [true, false]
*/
bool SX1276LoRaGetPacketCrcOn( void );
/*!
* \brief Enables/Disables the Implicit Header mode in LoRa
*
* \param [IN] enable [true, false]
*/
void SX1276LoRaSetImplicitHeaderOn( bool enable );
/*!
* \brief Check if implicit header mode in LoRa in enabled or disabled
*
* \retval enable [true, false]
*/
bool SX1276LoRaGetImplicitHeaderOn( void );
/*!
* \brief Enables/Disables Rx single instead of Rx continuous
*
* \param [IN] enable [true, false]
*/
void SX1276LoRaSetRxSingleOn( bool enable );
/*!
* \brief Check if LoRa is in Rx Single mode
*
* \retval enable [true, false]
*/
bool SX1276LoRaGetRxSingleOn( void );
/*!
* \brief Enables/Disables the frequency hopping
*
* \param [IN] enable [true, false]
*/
void SX1276LoRaSetFreqHopOn( bool enable );
/*!
* \brief Get the frequency hopping status
*
* \param [IN] enable [true, false]
*/
bool SX1276LoRaGetFreqHopOn( void );
/*!
* \brief Set symbol period between frequency hops
*
* \param [IN] value
*/
void SX1276LoRaSetHopPeriod( uint8_t value );
/*!
* \brief Get symbol period between frequency hops
*
* \retval value symbol period between frequency hops
*/
uint8_t SX1276LoRaGetHopPeriod( void );
/*!
* \brief Set timeout Tx packet (based on MCU timer, timeout between Tx Mode entry Tx Done IRQ)
*
* \param [IN] value timeout (ms)
*/
void SX1276LoRaSetTxPacketTimeout( uint32_t value );
/*!
* \brief Get timeout between Tx packet (based on MCU timer, timeout between Tx Mode entry Tx Done IRQ)
*
* \retval value timeout (ms)
*/
uint32_t SX1276LoRaGetTxPacketTimeout( void );
/*!
* \brief Set timeout Rx packet (based on MCU timer, timeout between Rx Mode entry and Rx Done IRQ)
*
* \param [IN] value timeout (ms)
*/
void SX1276LoRaSetRxPacketTimeout( uint32_t value );
/*!
* \brief Get timeout Rx packet (based on MCU timer, timeout between Rx Mode entry and Rx Done IRQ)
*
* \retval value timeout (ms)
*/
uint32_t SX1276LoRaGetRxPacketTimeout( void );
/*!
* \brief Set payload length
*
* \param [IN] value payload length
*/
void SX1276LoRaSetPayloadLength( uint8_t value );
/*!
* \brief Get payload length
*
* \retval value payload length
*/
uint8_t SX1276LoRaGetPayloadLength( void );
/*!
* \brief Enables/Disables the 20 dBm PA
*
* \param [IN] enable [true, false]
*/
void SX1276LoRaSetPa20dBm( bool enale );
/*!
* \brief Gets the current 20 dBm PA status
*
* \retval enable [true, false]
*/
bool SX1276LoRaGetPa20dBm( void );
/*!
* \brief Set the RF Output pin
*
* \param [IN] RF_PACONFIG_PASELECT_PABOOST or RF_PACONFIG_PASELECT_RFO
*/
void SX1276LoRaSetPAOutput( uint8_t outputPin );
/*!
* \brief Gets the used RF Ouptut pin
*
* \retval RF_PACONFIG_PASELECT_PABOOST or RF_PACONFIG_PASELECT_RFO
*/
uint8_t SX1276LoRaGetPAOutput( void );
/*!
* \brief Writes the new PA rise/fall time of ramp up/down value
*
* \param [IN] value New PaRamp value
*/
void SX1276LoRaSetPaRamp( uint8_t value );
/*!
* \brief Reads the current PA rise/fall time of ramp up/down value
*
* \retval freq Current PaRamp value
*/
uint8_t SX1276LoRaGetPaRamp( void );
/*!
* \brief Set Symbol Timeout based on symbol length
*
* \param [IN] value number of symbol
*/
void SX1276LoRaSetSymbTimeout( uint16_t value );
/*!
* \brief Get Symbol Timeout based on symbol length
*
* \retval value number of symbol
*/
uint16_t SX1276LoRaGetSymbTimeout( void );
/*!
* \brief Configure the device to optimize low datarate transfers
*
* \param [IN] enable Enables/Disables the low datarate optimization
*/
void SX1276LoRaSetLowDatarateOptimize( bool enable );
/*!
* \brief Get the status of optimize low datarate transfers
*
* \retval LowDatarateOptimize enable or disable
*/
bool SX1276LoRaGetLowDatarateOptimize( void );
/*!
* \brief Get the preamble length
*
* \retval value preamble length
*/
uint16_t SX1276LoRaGetPreambleLength( void );
/*!
* \brief Set the preamble length
*
* \param [IN] value preamble length
*/
void SX1276LoRaSetPreambleLength( uint16_t value );
/*!
* \brief Set the number or rolling preamble symbol needed for detection
*
* \param [IN] value number of preamble symbol
*/
void SX1276LoRaSetNbTrigPeaks( uint8_t value );
/*!
* \brief Get the number or rolling preamble symbol needed for detection
*
* \retval value number of preamble symbol
*/
uint8_t SX1276LoRaGetNbTrigPeaks( void );
#endif

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/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file sx1276.c
* \brief SX1276 RF chip high level functions driver
*
* \remark Optional support functions.
* These functions are defined only to easy the change of the
* parameters.
* For a final firmware the radio parameters will be known so
* there is no need to support all possible parameters.
* Removing these functions will greatly reduce the final firmware
* size.
*
* \version 2.0.0
* \date May 6 2013
* \author Gregory Cristian
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276.c
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#include "platform.h"
#include "radio.h"
#if defined(USE_SX1276_RADIO)
#include "sx1276.h"
#include "sx1276-Hal.h"
#include "sx1276-Fsk.h"
#include "sx1276-LoRa.h"
uint8_t SX1276Regs[0x70];
static bool LoRaOn = true;
static bool LoRaOnState = false;
static int sx1276_tx_sem, sx1276_rx_sem;
static int sx1276_radio_task;
void SX1276Reset(void)
{
uint32_t startTick;
SX1276SetReset(RADIO_RESET_ON);
DDL_DelayMS(1);
SX1276SetReset(RADIO_RESET_OFF);
DDL_DelayMS(6);
}
void SX1276_SetLoRaOn(bool enable)
{
if(LoRaOnState == enable) {
return;
}
LoRaOnState = enable;
LoRaOn = enable;
if(LoRaOn == true) {
SX1276LoRaSetOpMode(RFLR_OPMODE_SLEEP);
SX1276LR->RegOpMode = (SX1276LR->RegOpMode & RFLR_OPMODE_LONGRANGEMODE_MASK) | RFLR_OPMODE_LONGRANGEMODE_ON;
SX1276Write(REG_LR_OPMODE, SX1276LR->RegOpMode);
SX1276LoRaSetOpMode(RFLR_OPMODE_STANDBY);
// RxDone RxTimeout FhssChangeChannel CadDone
SX1276LR->RegDioMapping1 = RFLR_DIOMAPPING1_DIO0_00 | RFLR_DIOMAPPING1_DIO1_00 | RFLR_DIOMAPPING1_DIO2_00 | RFLR_DIOMAPPING1_DIO3_00;
// CadDetected ModeReady
SX1276LR->RegDioMapping2 = RFLR_DIOMAPPING2_DIO4_00 | RFLR_DIOMAPPING2_DIO5_00;
SX1276WriteBuffer(REG_LR_DIOMAPPING1, &SX1276LR->RegDioMapping1, 2);
SX1276ReadBuffer(REG_LR_OPMODE, SX1276Regs + 1, 0x70 - 1);
} else {
SX1276LoRaSetOpMode(RFLR_OPMODE_SLEEP);
SX1276LR->RegOpMode = (SX1276LR->RegOpMode & RFLR_OPMODE_LONGRANGEMODE_MASK) | RFLR_OPMODE_LONGRANGEMODE_OFF;
SX1276Write(REG_LR_OPMODE, SX1276LR->RegOpMode);
SX1276LoRaSetOpMode(RFLR_OPMODE_STANDBY);
SX1276ReadBuffer(REG_OPMODE, SX1276Regs + 1, 0x70 - 1);
}
}
bool SX1276_GetLoRaOn(void)
{
return LoRaOn;
}
void SX1276SetOpMode(uint8_t opMode)
{
if(LoRaOn == false) {
SX1276FskSetOpMode(opMode);
} else {
SX1276LoRaSetOpMode(opMode);
}
}
uint8_t SX1276_GetOpMode(void)
{
if(LoRaOn == false) {
return SX1276FskGetOpMode();
} else {
return SX1276LoRaGetOpMode();
}
}
double SX1276ReadRssi(void)
{
if(LoRaOn == false) {
return SX1276FskReadRssi();
} else {
return SX1276LoRaReadRssi();
}
}
uint8_t SX1276_ReadRxGain(void)
{
if(LoRaOn == false) {
return SX1276FskReadRxGain();
} else {
return SX1276LoRaReadRxGain();
}
}
uint8_t SX1276_GetPacketRxGain(void)
{
if(LoRaOn == false) {
return SX1276FskGetPacketRxGain();
} else {
return SX1276LoRaGetPacketRxGain();
}
}
int8_t SX1276_GetPacketSnr(void)
{
if(LoRaOn == false) {
while(1) {
// Useless in FSK mode
// Block program here
}
} else {
return SX1276LoRaGetPacketSnr();
}
}
double SX1276_GetPacketRssi(void)
{
if(LoRaOn == false) {
return SX1276FskGetPacketRssi();
} else {
return SX1276LoRaGetPacketRssi();
}
}
uint32_t SX1276GetPacketAfc(void)
{
if(LoRaOn == false) {
return SX1276FskGetPacketAfc();
} else {
while(1) {
// Useless in LoRa mode
// Block program here
}
}
}
void SX1276StartRx(void)
{
if(LoRaOn == false) {
SX1276FskSetRFState(RF_STATE_RX_INIT);
} else {
SX1276LoRaSetRFState(RFLR_STATE_RX_INIT);
}
}
void SX1276GetRxPacket(void *buffer, uint16_t *size)
{
if(LoRaOn == false) {
SX1276FskGetRxPacket(buffer, size);
} else {
SX1276LoRaGetRxPacket(buffer, size);
}
}
int SX1276GetRx(void *buffer, uint16_t *size)
{
int ret = -1;
SX1276StartRx();
//receive timeout 10s
ret = KSemaphoreObtain(sx1276_rx_sem, 10000);
if (0 == ret) {
SX1276LoRaSetRFState(RFLR_STATE_IDLE);
SX1276GetRxPacket(buffer, size);
}
return ret;
}
void SX1276SetTxPacket(const void *buffer, uint16_t size)
{
if(LoRaOn == false) {
SX1276FskSetTxPacket(buffer, size);
} else {
SX1276LoRaSetTxPacket(buffer, size);
}
}
void SX1276SetTx(const void *buffer, uint16_t size)
{
SX1276SetTxPacket(buffer, size);
KSemaphoreObtain(sx1276_tx_sem, WAITING_FOREVER);
SX1276StartRx();
}
uint8_t SX1276GetRFState(void)
{
if(LoRaOn == false) {
return SX1276FskGetRFState();
} else {
return SX1276LoRaGetRFState();
}
}
void SX1276SetRFState(uint8_t state)
{
if(LoRaOn == false) {
SX1276FskSetRFState(state);
} else {
SX1276LoRaSetRFState(state);
}
}
uint32_t SX1276Process(void)
{
if(LoRaOn == false) {
return SX1276FskProcess();
} else {
return SX1276LoRaProcess();
}
}
static void Sx1276RadioEntry(void *parameter)
{
uint32_t result;
while(1) {
result = SX1276Process();
if (RF_RX_DONE == result) {
KSemaphoreAbandon(sx1276_rx_sem);
}
if (RF_TX_DONE == result) {
KSemaphoreAbandon(sx1276_tx_sem);
}
}
}
uint32_t SX1276ChannelEmpty(void)
{
if(LoRaOn == false) {
return true;
} else {
SX1276LoraChannelEmpty();
}
}
void SX1276Init(void)
{
uint8_t TempReg;
SX1276 = (tSX1276 *)SX1276Regs;
SX1276LR = (tSX1276LR *)SX1276Regs;
SX1276InitIo();
SX1276Reset();
SX1276Read(0x06, &TempReg);
if(TempReg != 0x6C) {
KPrintf("Hard SPI Err!\r\n");
}
SX1276Read(0x42, &TempReg);
if(TempReg != 0x12) {
KPrintf("Hard SPI Err! version 0x%x\r\n", TempReg);
}
#if (LORA == 0)
LoRaOn = false;
SX1276_SetLoRaOn(LoRaOn);
SX1276FskInit();
#else
LoRaOn = true;
SX1276_SetLoRaOn(LoRaOn);
SX1276LoRaInit();
#endif
sx1276_rx_sem = KSemaphoreCreate(0);
sx1276_tx_sem = KSemaphoreCreate(0);
sx1276_radio_task = KTaskCreate("radio", Sx1276RadioEntry , NONE, 2048, 20);
StartupKTask(sx1276_radio_task);
}
#endif

97
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/spi/third_party_spi_lora/sx12xx/src/radio/sx1276.h Normal file
View File

@ -0,0 +1,97 @@
/*
* THE FOLLOWING FIRMWARE IS PROVIDED: (1) "AS IS" WITH NO WARRANTY; AND
* (2)TO ENABLE ACCESS TO CODING INFORMATION TO GUIDE AND FACILITATE CUSTOMER.
* CONSEQUENTLY, SEMTECH SHALL NOT BE HELD LIABLE FOR ANY DIRECT, INDIRECT OR
* CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE CONTENT
* OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING INFORMATION
* CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*
* Copyright (C) SEMTECH S.A.
*/
/*!
* \file sx1276.h
* \brief SX1276 RF chip high level functions driver
*
* \remark Optional support functions.
* These functions are defined only to easy the change of the
* parameters.
* For a final firmware the radio parameters will be known so
* there is no need to support all possible parameters.
* Removing these functions will greatly reduce the final firmware
* size.
*
* \version 2.0.0
* \date May 6 2013
* \author Gregory Cristian
*
* Last modified by Miguel Luis on Jun 19 2013
*/
/*************************************************
File name: sx1276.h
Description: support aiit board configure and register function
History:
1. Date: 2021-04-25
Author: AIIT XUOS Lab
Modification:
1. replace original macro and basic date type with AIIT XUOS Lab's own defination
*************************************************/
#ifndef __SX1276_H__
#define __SX1276_H__
#include <stdint.h>
#include <stdbool.h>
extern uint8_t SX1276Regs[0x70]; //SX1276寄存器数组
void SX1276Init( void ); //初始化SX1276
void SX1276Reset( void ); //重置SX1276
/*以下函数都没有被使用到因为在sx1276-LoRa.h里面又定义了一系列与下面作用相同的函数*/
void SX1276_SetLoRaOn( bool enable ); //启用LoRa调制解调器或FSK调制解调器
bool SX1276_GetLoRaOn( void ); //获取LoRa调制解调器状态
void SX1276SetOpMode( uint8_t opMode ); //设置SX1276操作模式
uint8_t SX1276_GetOpMode( void ); //获取SX1276操作模式
uint8_t SX1276_ReadRxGain( void ); //读取当前Rx增益设置
double SX1276ReadRssi( void ); //读取无线信号强度
uint8_t SX1276_GetPacketRxGain( void ); //获取数据时的增益值
int8_t SX1276_GetPacketSnr( void ); //获取数据时的信噪比值,信号和噪声的比值,信噪比越高,说明信号干扰越小。
double SX1276_GetPacketRssi( void ); //获取数据是的无线信号强度
/*!
* \brief Gets the AFC value measured while receiving the packet
*
* \retval afcValue Current AFC value in [Hz]
*/
uint32_t SX1276GetPacketAfc( void ); //此函数不知道作用
void SX1276StartRx( void ); //开始接收
void SX1276GetRxPacket( void *buffer, uint16_t *size ); //得到接收的数据
int SX1276GetRx(void *buffer, uint16_t *size); //应用接收数据,无数据时阻塞
void SX1276SetTxPacket( const void *buffer, uint16_t size ); //发送数据
void SX1276SetTx( const void *buffer, uint16_t size ); //应用发送数据
uint8_t SX1276GetRFState( void ); //得到RFLRState状态
void SX1276SetRFState( uint8_t state ); //设置RFLRState状态RFLRState的值决定了下面的函数处理哪一步的代码
uint32_t SX1276Process( void ); //SX1276模块接发收数据的处理函数
uint32_t SX1276ChannelEmpty( void );
#endif

16
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/timer/Kconfig Normal file
View File

@ -0,0 +1,16 @@
menuconfig BSP_USING_HWTIMER
bool "Using hwtimer"
default y
select RESOURCES_HWTIMER
if BSP_USING_HWTIMER
config HWTIMER_BUS_NAME_0
string "timer 0 bus 0 name"
default "timer0"
config HWTIMER_0_DEVICE_NAME_0
string "timer 0 bus 0 device 0 name"
default "timer0_dev0"
config HWTIMER_DRIVER_NAME_0
string "timer 0 bus 0 driver name"
default "timer0_drv"
endif

3
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/timer/Makefile Normal file
View File

@ -0,0 +1,3 @@
SRC_FILES := connect_hwtimer.c
include $(KERNEL_ROOT)/compiler.mk

189
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/timer/connect_hwtimer.c Normal file
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@ -0,0 +1,189 @@
/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_hwtimer.c
* @brief support edu-arm32-board hwtimer function and register to bus framework
* @version 1.0
* @author AIIT XUOS Lab
* @date 2021-04-25
*/
#include <connect_hwtimer.h>
#define TMR0_CMP_VAL 1000
#define TMR0x ((CM_TMR0_TypeDef *)CM_TMR0_1_BASE)
#define TMR0_CH_x (TMR0_CH_A)
#define INTSEL_REG ((uint32_t)(&CM_INTC->SEL0))
#define TIMER0_IRQn (18)
void (*callback_function)(void *) ;
static void Timer0Callback(int vector, void *param)
{
TMR0_SetCountValue(TMR0x, TMR0_CH_x, 0);
if (callback_function) {
callback_function(param);
}
}
static uint32 HwtimerOpen(void *dev)
{
struct HwtimerHardwareDevice *hwtimer_dev = dev;
stc_tmr0_init_t stcTmr0Init;
/* Enable timer0 peripheral clock */
FCG_Fcg2PeriphClockCmd(PWC_FCG2_TMR0_1, ENABLE);
/* TIMER0 basetimer function initialize */
(void)TMR0_StructInit(&stcTmr0Init);
stcTmr0Init.u32ClockDiv = TMR0_CLK_DIV128; /* Config clock division */
stcTmr0Init.u32ClockSrc = TMR0_CLK_SRC_INTERN_CLK; /* Chose clock source */
stcTmr0Init.u32Func = TMR0_FUNC_CMP; /* Timer0 compare mode */
stcTmr0Init.u16CompareValue = TMR0_CMP_VAL; /* Set compare register data */
(void)TMR0_Init(TMR0x, TMR0_CH_x, &stcTmr0Init);
// DelayKTask(1);
// /* Set internal hardware capture source */
// TMR0_SetTriggerSrc(EVT_PORT_EIRQ0);
// DelayKTask(1);
return EOK;
}
static uint32 HwtimerClose(void *dev)
{
/* Timer0 interrupt function Disable */
TMR0_IntCmd(TMR0x, TMR0_INT_CMP_A, DISABLE);
return EOK;
}
/*manage the hwtimer device operations*/
static const struct HwtimerDevDone dev_done =
{
.open = HwtimerOpen,
.close = HwtimerClose,
.write = NONE,
.read = NONE,
};
static uint32 HwtimerDrvConfigure(void *drv, struct BusConfigureInfo *configure_info)
{
NULL_PARAM_CHECK(drv);
NULL_PARAM_CHECK(configure_info);
x_err_t ret = EOK;
__IO uint32_t *INTC_SELx;
switch (configure_info->configure_cmd)
{
case OPE_INT:
INTC_SELx = (__IO uint32_t *)(INTSEL_REG+ 4U * (uint32_t)(TIMER0_IRQn));
WRITE_REG32(*INTC_SELx, EVT_SRC_TMR0_1_CMP_A);
callback_function = (void (*)(void *param))configure_info->private_data;
isrManager.done->registerIrq(TIMER0_IRQn+16,Timer0Callback,NULL);
isrManager.done->enableIrq(TIMER0_IRQn);
TMR0_IntCmd(TMR0x, TMR0_INT_CMP_A, ENABLE);
break;
case OPE_CFG:
TMR0_ClearStatus(TMR0x, TMR0_FLAG_CMP_A);
TMR0_SetCompareValue(TMR0x, TMR0_CH_x, *((int *)configure_info->private_data) );
/* Timer0 interrupt function Enable */
TMR0_SetCountValue(TMR0x, TMR0_CH_x, 0x0000);
TMR0_Start(TMR0x, TMR0_CH_x);
break;
default:
break;
}
return ret;
}
/*Init hwtimer bus*/
static int BoardHwtimerBusInit(struct HwtimerBus *hwtimer_bus, struct HwtimerDriver *hwtimer_driver)
{
x_err_t ret = EOK;
/*Init the hwtimer bus */
ret = HwtimerBusInit(hwtimer_bus, HWTIMER_BUS_NAME_0);
if (EOK != ret) {
KPrintf("board_hwtimer_init HwtimerBusInit error %d\n", ret);
return ERROR;
}
/*Init the hwtimer driver*/
hwtimer_driver->configure = &(HwtimerDrvConfigure);
ret = HwtimerDriverInit(hwtimer_driver, HWTIMER_DRIVER_NAME_0);
if (EOK != ret) {
KPrintf("board_hwtimer_init HwtimerDriverInit error %d\n", ret);
return ERROR;
}
/*Attach the hwtimer driver to the hwtimer bus*/
ret = HwtimerDriverAttachToBus(HWTIMER_DRIVER_NAME_0, HWTIMER_BUS_NAME_0);
if (EOK != ret) {
KPrintf("board_hwtimer_init USEDriverAttachToBus error %d\n", ret);
return ERROR;
}
return ret;
}
/*Attach the hwtimer device to the hwtimer bus*/
static int BoardHwtimerDevBend(void)
{
x_err_t ret = EOK;
static struct HwtimerHardwareDevice hwtimer_device_0;
memset(&hwtimer_device_0, 0, sizeof(struct HwtimerHardwareDevice));
hwtimer_device_0.dev_done = &dev_done;
ret = HwtimerDeviceRegister(&hwtimer_device_0, NONE, HWTIMER_0_DEVICE_NAME_0);
if (EOK != ret) {
KPrintf("BoardHwtimerDevBend HwtimerDeviceRegister device %s error %d\n", HWTIMER_0_DEVICE_NAME_0, ret);
return ERROR;
}
ret = HwtimerDeviceAttachToBus(HWTIMER_0_DEVICE_NAME_0, HWTIMER_BUS_NAME_0);
if (EOK != ret) {
KPrintf("BoardHwtimerDevBend HwtimerDeviceAttachToBus device %s error %d\n", HWTIMER_0_DEVICE_NAME_0, ret);
return ERROR;
}
return ret;
}
/*EDU-ARM32 BOARD HWTIMER INIT*/
int HwTimerInit(void)
{
x_err_t ret = EOK;
static struct HwtimerBus hwtimer_bus;
memset(&hwtimer_bus, 0, sizeof(struct HwtimerBus));
static struct HwtimerDriver hwtimer_driver;
memset(&hwtimer_driver, 0, sizeof(struct HwtimerDriver));
ret = BoardHwtimerBusInit(&hwtimer_bus, &hwtimer_driver);
if (EOK != ret) {
KPrintf("board_hwtimer_Init error ret %u\n", ret);
return ERROR;
}
ret = BoardHwtimerDevBend();
if (EOK != ret) {
KPrintf("board_hwtimer_Init error ret %u\n", ret);
return ERROR;
}
return ret;
}

15
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/watchdog/Kconfig Normal file
View File

@ -0,0 +1,15 @@
if BSP_USING_WDT
config WDT_BUS_NAME_0
string "watchdog bus 0 name"
default "wdt0"
config WDT_DRIVER_NAME_0
string "watchdog driver 0 name"
default "wdt0_drv"
config WDT_0_DEVICE_NAME_0
string "watchdog device 0 name"
default "wdt0_dev0"
endif

3
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/watchdog/Makefile Normal file
View File

@ -0,0 +1,3 @@
SRC_FILES := connect_wdt.c
include $(KERNEL_ROOT)/compiler.mk

145
Ubiquitous/XiZi_IIoT/board/xishutong-arm32/third_party_driver/watchdog/connect_wdt.c Normal file
View File

@ -0,0 +1,145 @@
/*
* Copyright (c) 2020 AIIT XUOS Lab
* XiUOS is licensed under Mulan PSL v2.
* You can use this software according to the terms and conditions of the Mulan PSL v2.
* You may obtain a copy of Mulan PSL v2 at:
* http://license.coscl.org.cn/MulanPSL2
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PSL v2 for more details.
*/
/**
* @file connect_wdt.c
* @brief support edu-arm32-board watchdog function and register to bus framework
* @version 1.0
* @author AIIT XUOS Lab
* @date 2023-02-02
*/
#include <connect_wdt.h>
#define WDT_COUNT_CYCLE 65536U
static uint32 WdtOpen(void *dev)
{
NULL_PARAM_CHECK(dev);
stc_wdt_init_t stcWdtInit;
stcWdtInit.u32CountPeriod = WDT_CNT_PERIOD65536;
stcWdtInit.u32ClockDiv = WDT_CLK_DIV1024;
stcWdtInit.u32RefreshRange = WDT_RANGE_0TO25PCT;
stcWdtInit.u32LPMCount = WDT_LPM_CNT_STOP;
stcWdtInit.u32ExceptionType = WDT_EXP_TYPE_RST;
(void)WDT_Init(&stcWdtInit);
return EOK;
}
static uint32 WdtConfigure(void *drv, struct BusConfigureInfo *args)
{
NULL_PARAM_CHECK(drv);
NULL_PARAM_CHECK(args);
stc_wdt_init_t stcWdtInit;
int period_option = *((int*)args->private_data);
if(period_option<=256){
period_option = WDT_CNT_PERIOD256;
}else if(period_option<=4096){
period_option = WDT_CNT_PERIOD4096;
}else if(period_option<=16384){
period_option = WDT_CNT_PERIOD16384;
}else{
period_option = WDT_CNT_PERIOD65536;
}
switch (args->configure_cmd)
{
case OPER_WDT_SET_TIMEOUT:
stcWdtInit.u32CountPeriod = period_option;
stcWdtInit.u32ClockDiv = WDT_CLK_DIV1024;
stcWdtInit.u32RefreshRange = WDT_RANGE_0TO25PCT;
stcWdtInit.u32LPMCount = WDT_LPM_CNT_STOP;
stcWdtInit.u32ExceptionType = WDT_EXP_TYPE_RST;
if (WDT_Init(&stcWdtInit) != 0) {
return ERROR;
}
/* the chip SDK's feature:to start up watchdog counter, feed dog first after initialization*/
WDT_FeedDog();
break;
case OPER_WDT_KEEPALIVE:
/* must wait for count lower than 25%(division by 4) for a feed as RefreshRange is set as 0TO25PCT*/
if (WDT_GetCountValue() < WDT_COUNT_CYCLE/4){
WDT_FeedDog();
}
break;
default:
return ERROR;
}
return EOK;
}
static const struct WdtDevDone dev_done =
{
WdtOpen,
NONE,
NONE,
NONE,
};
/**
* @description: Watchdog function
* @return success: EOK, failure: other
*/
int StartWatchdog(void)
{
//add feed watchdog task function
return EOK;
}
int HwWdtInit(void)
{
x_err_t ret = EOK;
static struct WdtBus wdt0;
ret = WdtBusInit(&wdt0, WDT_BUS_NAME_0);
if (ret != EOK) {
KPrintf("Watchdog bus init error %d\n", ret);
return ERROR;
}
static struct WdtDriver drv0;
drv0.configure = WdtConfigure;
ret = WdtDriverInit(&drv0, WDT_DRIVER_NAME_0);
if (ret != EOK) {
KPrintf("Watchdog driver init error %d\n", ret);
return ERROR;
}
ret = WdtDriverAttachToBus(WDT_DRIVER_NAME_0, WDT_BUS_NAME_0);
if (ret != EOK) {
KPrintf("Watchdog driver attach error %d\n", ret);
return ERROR;
}
static struct WdtHardwareDevice dev0;
dev0.dev_done = &dev_done;
ret = WdtDeviceRegister(&dev0, WDT_0_DEVICE_NAME_0);
if (ret != EOK) {
KPrintf("Watchdog device register error %d\n", ret);
return ERROR;
}
ret = WdtDeviceAttachToBus(WDT_0_DEVICE_NAME_0, WDT_BUS_NAME_0);
if (ret != EOK) {
KPrintf("Watchdog device register error %d\n", ret);
return ERROR;
}
return ret;
}

11
Ubiquitous/XiZi_IIoT/board/xiwangtong-arm32/third_party_driver/ethernet/eth_netdev.c
View File

@ -76,6 +76,7 @@ static int lwip_netdev_set_addr_info(struct netdev* netdev, ip_addr_t* ip_addr,
netif_set_gw((struct netif*)netdev->user_data, ip_2_ip4(gw));
}
}
return 0;
}
#ifdef LWIP_DNS
@ -92,7 +93,7 @@ static int lwip_netdev_set_dns_server(struct netdev* netdev, uint8_t dns_num, ip
}
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
static int lwip_netdev_set_dhcp(struct netdev* netdev, bool is_enabled)
{
netdev_low_level_set_dhcp_status(netdev, is_enabled);
@ -120,7 +121,7 @@ static const struct netdev_ops lwip_netdev_ops = {
#ifdef LWIP_DNS
.set_dns_server = lwip_netdev_set_dns_server,
#endif
#ifdef LWIP_DHCP
#if LWIP_DHCP
.set_dhcp = lwip_netdev_set_dhcp,
#endif
.set_default = lwip_netdev_set_default,
@ -180,9 +181,9 @@ int lwip_netdev_add(struct netif* lwip_netif)
netdev->ops = &lwip_netdev_ops;
netdev->hwaddr_len = lwip_netif->hwaddr_len;
memcpy(netdev->hwaddr, lwip_netif->hwaddr, lwip_netif->hwaddr_len);
netdev->ip_addr = lwip_netif->ip_addr;
netdev->gw = lwip_netif->gw;
netdev->netmask = lwip_netif->netmask;
netdev->ip_addr = &lwip_netif->ip_addr;
netdev->gw = &lwip_netif->gw;
netdev->netmask = &lwip_netif->netmask;
return result;
}

3
Ubiquitous/XiZi_IIoT/compiler.mk
View File

@ -2,6 +2,8 @@ ifeq ($(COMPILE_TYPE), COMPILE_MUSL)
SRC_DIR_TEMP := $(MUSL_DIR)
else ifeq ($(COMPILE_TYPE), COMPILE_LWIP)
SRC_DIR_TEMP := $(LWIP_DIR)
else ifeq ($(COMPILE_TYPE), COMPILE_MONGOOSE)
SRC_DIR_TEMP := $(MONGOOSE_DIR)
else
SRC_DIR_TEMP := $(SRC_DIR)
endif
@ -9,6 +11,7 @@ endif
SRC_DIR :=
MUSL_DIR :=
LWIP_DIR :=
MONGOOSE_DIR :=
ifeq ($(USE_APP_INCLUDEPATH), y)
include $(KERNEL_ROOT)/path_app.mk

15
Ubiquitous/XiZi_IIoT/fs/shared/include/iot-vfs_posix.h
View File

@ -15,7 +15,8 @@
#include <iot-vfs.h>
typedef void DIR;
#include <ff.h>
// typedef void void;
#if defined(LIB_NEWLIB) && defined(_EXFUN)
_READ_WRITE_RETURN_TYPE _EXFUN(read, (int __fd, void *__buf, size_t __nbyte));
@ -39,15 +40,15 @@ int fsync(int fd);
int ftruncate(int fd, off_t length);
int mkdir(const char *path, mode_t mode);
DIR *opendir(const char *path);
int closedir(DIR *dirp);
struct dirent *readdir(DIR *dirp);
void* opendir(const char* path);
int closedir(void* dirp);
struct dirent* readdir(void* dirp);
int rmdir(const char *path);
int chdir(const char *path);
char *getcwd(char *buf, size_t size);
long telldir(DIR *dirp);
void seekdir(DIR *dirp, off_t offset);
void rewinddir(DIR *dirp);
long telldir(void* dirp);
void seekdir(void* dirp, off_t offset);
void rewinddir(void* dirp);
int statfs(const char *path, struct statfs *buf);

12
Ubiquitous/XiZi_IIoT/fs/shared/src/iot-vfs.c
View File

@ -906,7 +906,7 @@ err:
return 0;
}
DIR *opendir(const char *path)
void* opendir(const char* path)
{
struct FileDescriptor *fdp;
struct MountPoint *mp;
@ -968,7 +968,7 @@ err:
return fdp;
}
int closedir(DIR *dirp)
int closedir(void* dirp)
{
struct FileDescriptor *fdp = dirp;
int ret;
@ -999,7 +999,7 @@ int closedir(DIR *dirp)
}
static struct dirent dirent;
struct dirent *readdir(DIR *dirp)
struct dirent* readdir(void* dirp)
{
struct FileDescriptor *fdp = dirp;
int ret;
@ -1036,7 +1036,7 @@ int rmdir(const char *path)
int chdir(const char *path)
{
char *abspath;
DIR *dirp;
void* dirp;
if (path == NULL) {
SYS_ERR("%s: invalid path\n", __func__);
@ -1074,7 +1074,7 @@ char *getcwd(char *buf, size_t size)
return buf;
}
void seekdir(DIR *dirp, off_t offset)
void seekdir(void* dirp, off_t offset)
{
struct FileDescriptor *fdp = dirp;
@ -1093,7 +1093,7 @@ void seekdir(DIR *dirp, off_t offset)
fdp->mntp->fs->seekdir(fdp, offset);
}
void rewinddir(DIR *dirp)
void rewinddir(void* dirp)
{
struct FileDescriptor *fdp = dirp;

13
Ubiquitous/XiZi_IIoT/kernel/include/xs_kdbg.h
View File

@ -44,15 +44,16 @@ extern "C" {
#define MSGQUEUE_DEBUG 0
#define FILESYS_DEBUG 0
#define NETDEV_DEBUG 0
#define NETDEV_DEBUG 1
#define WEBNET_DEBUG 0
#define WIZNET_DEBUG 0
#define SYS_KDEBUG_LOG(section, information) \
do { \
if (section) { \
KPrintf information; \
} \
#define SYS_KDEBUG_LOG(section, information) \
do { \
if (section) { \
KPrintf("[%s:%d] ", __func__, __LINE__); \
KPrintf information; \
} \
} while (0)
#define KDYN_NONE 0

2
Ubiquitous/XiZi_IIoT/link.mk
View File

@ -3,7 +3,7 @@ OBJS := $(shell cat make.obj)
$(TARGET): $(OBJS)
@echo ------------------------------------------------
@echo link $(TARGET)
@$(CROSS_COMPILE)g++ -o $@ $($(LINK_FLAGS)) $(OBJS) $(LINK_LWIP) $(LINK_MUSLLIB) $(LIBCC)
@$(CROSS_COMPILE)g++ -o $@ $($(LINK_FLAGS)) $(OBJS) $(LINK_LWIP) $(LINK_MUSLLIB) $(LINK_MONGOOSE) $(LIBCC)
@echo ------------------------------------------------
@$(CROSS_COMPILE)objcopy -O binary $@ XiZi-$(BOARD)$(COMPILE_TYPE).bin
@$(CROSS_COMPILE)objdump -S $@ > XiZi-$(BOARD)$(COMPILE_TYPE).asm

9
Ubiquitous/XiZi_IIoT/link_mongoose.mk Normal file
View File

@ -0,0 +1,9 @@
OBJS := $(shell cat make.obj)
$(TARGET): $(OBJS)
@echo ------------------------------------------------
@echo link $(TARGET)
@$(CROSS_COMPILE)ar -r $@ $(OBJS)
@echo ------------------------------------------------
@$(CROSS_COMPILE)objcopy $@ $(TARGET)
@$(CROSS_COMPILE)size $@

8
Ubiquitous/XiZi_IIoT/resources/ethernet/LwIP/api/sockets.c
View File

@ -640,7 +640,8 @@ lwip_accept(int s, struct sockaddr *addr, socklen_t *addrlen)
LWIP_DEBUGF(SOCKETS_DEBUG, ("lwip_accept(%d)...\n", s));
sock = get_socket(s);
if (!sock) {
return -1;
KPrintf("sock = get_socket(s);\n");
return -1;
}
/* wait for a new connection */
@ -655,6 +656,7 @@ lwip_accept(int s, struct sockaddr *addr, socklen_t *addrlen)
sock_set_errno(sock, err_to_errno(err));
}
done_socket(sock);
KPrintf("err = netconn_accept(sock->conn, &newconn);\n");
return -1;
}
LWIP_ASSERT("newconn != NULL", newconn != NULL);
@ -664,6 +666,7 @@ lwip_accept(int s, struct sockaddr *addr, socklen_t *addrlen)
netconn_delete(newconn);
sock_set_errno(sock, ENFILE);
done_socket(sock);
KPrintf("newsock = alloc_socket(newconn, 1);\n");
return -1;
}
LWIP_ASSERT("invalid socket index", (newsock >= LWIP_SOCKET_OFFSET) && (newsock < NUM_SOCKETS + LWIP_SOCKET_OFFSET));
@ -701,6 +704,7 @@ lwip_accept(int s, struct sockaddr *addr, socklen_t *addrlen)
free_socket(nsock, 1);
sock_set_errno(sock, err_to_errno(err));
done_socket(sock);
KPrintf("err = netconn_peer(newconn, &naddr, &port);\n");
return -1;
}
@ -1242,6 +1246,8 @@ lwip_recvfrom(int s, void *mem, size_t len, int flags,
if (err != ERR_OK) {
LWIP_DEBUGF(SOCKETS_DEBUG, ("lwip_recvfrom[UDP/RAW](%d): buf == NULL, error is \"%s\"!\n",
s, lwip_strerr(err)));
KPrintf("lwip_recvfrom[UDP/RAW](%d): buf == NULL, error is \"%s\"!\n",
s, lwip_strerr(err));
sock_set_errno(sock, err_to_errno(err));
done_socket(sock);
return -1;

20
Ubiquitous/XiZi_IIoT/resources/ethernet/LwIP/arch/lwipopts.h
View File

@ -36,6 +36,7 @@
#ifndef LWIP_DEBUG
#define LWIP_DEBUG 1
// #define LWIP_SOCKET_DEBUG
// #define LWIP_SOCKETS_DEBUG
// #define LWIP_TCPIP_DEBUG
// #define LWIP_MEMP_DEBUG
// #define LWIP_PBUF_DEBUG
@ -271,13 +272,16 @@ a lot of data that needs to be copied, this should be set high. */
#define MEMP_NUM_PBUF 32
/* MEMP_NUM_UDP_PCB: the number of UDP protocol control blocks. One
per active UDP "connection". */
#define MEMP_NUM_UDP_PCB 4
#define MEMP_NUM_UDP_PCB 32
/* MEMP_NUM_TCP_PCB: the number of simulatenously active TCP
connections. */
#define MEMP_NUM_TCP_PCB 64
#define MEMP_NUM_TCP_PCB 32
#define MEMP_NUM_RAW_PCB 32
#define MEMP_NUM_REASSDATA 32
#define MEMP_NUM_NETCONN 32
/* MEMP_NUM_TCP_PCB_LISTEN: the number of listening TCP
connections. */
#define MEMP_NUM_TCP_PCB_LISTEN 2
#define MEMP_NUM_TCP_PCB_LISTEN 32
/* MEMP_NUM_TCP_SEG: the number of simultaneously queued TCP
segments. */
#define MEMP_NUM_TCP_SEG 256
@ -383,12 +387,6 @@ a lot of data that needs to be copied, this should be set high. */
/* ---------- ICMP options ---------- */
#define LWIP_ICMP 1
/* ---------- DHCP options ---------- */
/* Define LWIP_DHCP to 1 if you want DHCP configuration of
interfaces. DHCP is not implemented in lwIP 0.5.1, however, so
turning this on does currently not work. */
#define LWIP_DHCP 1
/* ---------- UDP options ---------- */
#define LWIP_UDP 1
#define UDP_TTL 255
@ -412,7 +410,7 @@ The STM32F4x7 allows computing and verifying the IP, UDP, TCP and ICMP checksums
- To use this feature let the following define uncommented.
- To disable it and process by CPU comment the the checksum.
*/
#define CHECKSUM_BY_HARDWARE
// #define CHECKSUM_BY_HARDWARE
#ifdef CHECKSUM_BY_HARDWARE
/* CHECKSUM_GEN_IP==0: Generate checksums by hardware for outgoing IP packets.*/
@ -520,7 +518,7 @@ The STM32F4x7 allows computing and verifying the IP, UDP, TCP and ICMP checksums
/* ---------- DHCP options ---------- */
/* Define LWIP_DHCP to 1 if you want DHCP configuration of
interfaces. */
#define LWIP_DHCP 1
#define LWIP_DHCP 0
/* 1 if you want to do an ARP check on the offered address
(recommended). */

193
Ubiquitous/XiZi_IIoT/resources/ethernet/LwIP/arch/sys_arch.c
View File

@ -76,9 +76,9 @@ char lwip_eth0_ipaddr[20] = { 192, 168, 130, 77 };
char lwip_eth0_netmask[20] = { 255, 255, 254, 0 };
char lwip_eth0_gwaddr[20] = { 192, 168, 130, 1 };
char lwip_eth1_ipaddr[20] = { 192, 168, 130, 99 };
char lwip_eth1_ipaddr[20] = { 192, 168, 131, 88 };
char lwip_eth1_netmask[20] = { 255, 255, 254, 0 };
char lwip_eth1_gwaddr[20] = { 192, 168, 130, 23 };
char lwip_eth1_gwaddr[20] = { 192, 168, 130, 1 };
char lwip_flag = 0;
@ -93,6 +93,13 @@ sys_sem_t* get_eth_recv_sem()
return &g_recv_sem;
}
struct netif gnetif2;
sys_sem_t* get_eth_recv_sem2()
{
static sys_sem_t g_recv_sem = 0;
return &g_recv_sem;
}
void sys_init(void)
{
// do nothing
@ -332,136 +339,104 @@ ip4_addr_t ipaddr;
ip4_addr_t netmask;
ip4_addr_t gw;
void lwip_config_input(struct netif* net)
void lwip_config_input(int eport, struct netif* net)
{
sys_thread_t th_id = 0;
th_id = sys_thread_new("eth_input", ethernetif_input, net, LWIP_TASK_STACK_SIZE, 30);
// if (th_id >= 0) {
// lw_print("%s %d successfully!\n", __func__, th_id);
// } else {
// lw_print("%s failed!\n", __func__);
// }
if (eport == 0) {
th_id = sys_thread_new("eth_input", ethernetif_input, net, LWIP_TASK_STACK_SIZE, 30);
} else if (eport == 1) {
#ifdef NETIF_ENET1_INIT_FUNC
th_id = sys_thread_new("eth_input2", ethernetif_input2, net, LWIP_TASK_STACK_SIZE, 30);
#endif
}
}
void lwip_config_tcp(uint8_t enet_port, char* ip, char* mask, char* gw)
{
static char is_init = 0;
if (is_init != 0) {
return;
static char is_init_0 = 0;
static char is_init_1 = 0;
if (is_init_0 == 0 && is_init_1 == 0) {
sys_sem_new(get_eth_recv_sem(), 0);
sys_sem_new(get_eth_recv_sem2(), 0);
if (chk_lwip_bit(LWIP_INIT_FLAG)) {
lw_print("lw: [%s] already ...\n", __func__);
}
set_lwip_bit(LWIP_INIT_FLAG);
tcpip_init(NULL, NULL);
}
is_init = 1;
sys_sem_new(get_eth_recv_sem(), 0);
ip4_addr_t net_ipaddr, net_netmask, net_gw;
char* eth_cfg;
eth_cfg = ethernetif_config_enet_set(enet_port);
if (chk_lwip_bit(LWIP_INIT_FLAG)) {
lw_print("lw: [%s] already ...\n", __func__);
return;
}
set_lwip_bit(LWIP_INIT_FLAG);
tcpip_init(NULL, NULL);
lw_print("lw: [%s] start ...\n", __func__);
char* eth_cfg = ethernetif_config_enet_set(enet_port);
ip4_addr_t net_ipaddr, net_netmask, net_gw;
IP4_ADDR(&net_ipaddr, ip[0], ip[1], ip[2], ip[3]);
IP4_ADDR(&net_netmask, mask[0], mask[1], mask[2], mask[3]);
IP4_ADDR(&net_gw, gw[0], gw[1], gw[2], gw[3]);
if (0 == enet_port) {
if (is_init_0 == 1) {
return;
}
#ifndef NETIF_ENET0_INIT_FUNC
lw_print("Not Netif driver for Eport 0\n");
return;
#endif
#ifdef NETIF_ENET0_INIT_FUNC
lw_print("Add netif eport 0\n");
netif_add(&gnetif, &net_ipaddr, &net_netmask, &net_gw, eth_cfg, NETIF_ENET0_INIT_FUNC,
tcpip_input);
#endif
} else if (1 == enet_port) {
#ifdef NETIF_ENET1_INIT_FUNC
netif_add(&gnetif, &net_ipaddr, &net_netmask, &net_gw, eth_cfg, NETIF_ENET1_INIT_FUNC,
tcpip_input);
#endif
}
netif_set_default(&gnetif);
netif_set_up(&gnetif);
lw_print("\r\n************************************************\r\n");
lw_print(" Network Configuration\r\n");
lw_print("************************************************\r\n");
lw_print(" IPv4 Address : %u.%u.%u.%u\r\n", ((u8_t*)&net_ipaddr)[0], ((u8_t*)&net_ipaddr)[1],
((u8_t*)&net_ipaddr)[2], ((u8_t*)&net_ipaddr)[3]);
lw_print(" IPv4 Subnet mask : %u.%u.%u.%u\r\n", ((u8_t*)&net_netmask)[0], ((u8_t*)&net_netmask)[1],
((u8_t*)&net_netmask)[2], ((u8_t*)&net_netmask)[3]);
lw_print(" IPv4 Gateway : %u.%u.%u.%u\r\n", ((u8_t*)&net_gw)[0], ((u8_t*)&net_gw)[1],
((u8_t*)&net_gw)[2], ((u8_t*)&net_gw)[3]);
lw_print("************************************************\r\n");
lwip_config_input(&gnetif);
}
void lwip_config_net(uint8_t enet_port, char* ip, char* mask, char* gw)
{
ip4_addr_t net_ipaddr, net_netmask, net_gw;
char* eth_cfg;
eth_cfg = ethernetif_config_enet_set(enet_port);
if (chk_lwip_bit(LWIP_INIT_FLAG)) {
lw_print("lw: [%s] already ...\n", __func__);
IP4_ADDR(&net_ipaddr, ip[0], ip[1], ip[2], ip[3]);
IP4_ADDR(&net_netmask, mask[0], mask[1], mask[2], mask[3]);
IP4_ADDR(&net_gw, gw[0], gw[1], gw[2], gw[3]);
// update ip addr
netif_set_down(&gnetif);
netif_set_gw(&gnetif, &net_gw);
netif_set_netmask(&gnetif, &net_netmask);
netif_set_ipaddr(&gnetif, &net_ipaddr);
netif_set_default(&gnetif);
netif_set_up(&gnetif);
return;
}
set_lwip_bit(LWIP_INIT_FLAG);
lw_print("lw: [%s] start ...\n", __func__);
IP4_ADDR(&net_ipaddr, ip[0], ip[1], ip[2], ip[3]);
IP4_ADDR(&net_netmask, mask[0], mask[1], mask[2], mask[3]);
IP4_ADDR(&net_gw, gw[0], gw[1], gw[2], gw[3]);
lwip_init();
if (0 == enet_port) {
#ifdef NETIF_ENET0_INIT_FUNC
netif_add(&gnetif, &net_ipaddr, &net_netmask, &net_gw, eth_cfg, NETIF_ENET0_INIT_FUNC,
ethernet_input);
#endif
} else if (1 == enet_port) {
#ifdef NETIF_ENET1_INIT_FUNC
netif_add(&gnetif, &net_ipaddr, &net_netmask, &net_gw, eth_cfg, NETIF_ENET1_INIT_FUNC,
ethernet_input);
#endif
}
netif_set_default(&gnetif);
netif_set_up(&gnetif);
if (chk_lwip_bit(LWIP_PRINT_FLAG)) {
lw_notice("\r\n************************************************\r\n");
lw_notice(" Network Configuration\r\n");
lw_notice("************************************************\r\n");
lw_notice(" IPv4 Address : %u.%u.%u.%u\r\n", ((u8_t*)&net_ipaddr)[0], ((u8_t*)&net_ipaddr)[1],
lw_print("\r\n************************************************\r\n");
lw_print(" Network Configuration\r\n");
lw_print("************************************************\r\n");
lw_print(" IPv4 Address : %u.%u.%u.%u\r\n", ((u8_t*)&net_ipaddr)[0], ((u8_t*)&net_ipaddr)[1],
((u8_t*)&net_ipaddr)[2], ((u8_t*)&net_ipaddr)[3]);
lw_notice(" IPv4 Subnet mask : %u.%u.%u.%u\r\n", ((u8_t*)&net_netmask)[0], ((u8_t*)&net_netmask)[1],
lw_print(" IPv4 Subnet mask : %u.%u.%u.%u\r\n", ((u8_t*)&net_netmask)[0], ((u8_t*)&net_netmask)[1],
((u8_t*)&net_netmask)[2], ((u8_t*)&net_netmask)[3]);
lw_notice(" IPv4 Gateway : %u.%u.%u.%u\r\n", ((u8_t*)&net_gw)[0], ((u8_t*)&net_gw)[1],
lw_print(" IPv4 Gateway : %u.%u.%u.%u\r\n", ((u8_t*)&net_gw)[0], ((u8_t*)&net_gw)[1],
((u8_t*)&net_gw)[2], ((u8_t*)&net_gw)[3]);
lw_notice("************************************************\r\n");
lw_print("************************************************\r\n");
lwip_config_input(enet_port, &gnetif);
is_init_0 = 1;
#endif
} else if (1 == enet_port) {
if (is_init_1 == 1) {
return;
}
#ifndef NETIF_ENET1_INIT_FUNC
lw_print("Not Netif driver for Eport 1\n");
return;
#endif
#ifdef NETIF_ENET1_INIT_FUNC
lw_print("Add netif eport 1\n");
netif_add(&gnetif2, &net_ipaddr, &net_netmask, &net_gw, eth_cfg, NETIF_ENET1_INIT_FUNC,
tcpip_input);
// netif_set_default(&gnetif2);
netif_set_up(&gnetif2);
lw_print("\r\n************************************************\r\n");
lw_print(" Network Configuration\r\n");
lw_print("************************************************\r\n");
lw_print(" IPv4 Address : %u.%u.%u.%u\r\n", ((u8_t*)&net_ipaddr)[0], ((u8_t*)&net_ipaddr)[1],
((u8_t*)&net_ipaddr)[2], ((u8_t*)&net_ipaddr)[3]);
lw_print(" IPv4 Subnet mask : %u.%u.%u.%u\r\n", ((u8_t*)&net_netmask)[0], ((u8_t*)&net_netmask)[1],
((u8_t*)&net_netmask)[2], ((u8_t*)&net_netmask)[3]);
lw_print(" IPv4 Gateway : %u.%u.%u.%u\r\n", ((u8_t*)&net_gw)[0], ((u8_t*)&net_gw)[1],
((u8_t*)&net_gw)[2], ((u8_t*)&net_gw)[3]);
lw_print("************************************************\r\n");
lwip_config_input(enet_port, &gnetif2);
is_init_1 = 1;
#endif
}
lwip_config_input(&gnetif);
}
}

2
Ubiquitous/XiZi_IIoT/resources/ethernet/LwIP/arch/sys_arch.h
View File

@ -101,6 +101,8 @@ extern char lwip_eth1_gwaddr[];
extern struct netif gnetif;
extern sys_sem_t* get_eth_recv_sem();
extern struct netif gnetif2;
extern sys_sem_t* get_eth_recv_sem2();
void lwip_tcp_init(void);
void lwip_config_net(uint8_t enet_port, char *ip, char *mask, char *gw);

89
Ubiquitous/XiZi_IIoT/resources/ethernet/LwIP/core/ipv4/ip4.c
View File

@ -228,6 +228,95 @@ ip4_route(const ip4_addr_t *dest)
return netif_default;
}
/**
* Finds the appropriate network interface for a given IP address. It
* searches the list of network interfaces linearly. A match is found
* if the masked IP address of the network interface equals the masked
* IP address given to the function.
*
* @param dest the destination IP address for which to find the route
* @return the netif on which to send to reach dest
*/
struct netif*
ip4_route2(const ip4_addr_t* src, const ip4_addr_t* dest)
{
#if !LWIP_SINGLE_NETIF
struct netif* netif;
LWIP_ASSERT_CORE_LOCKED();
#if LWIP_MULTICAST_TX_OPTIONS
/* Use administratively selected interface for multicast by default */
if (ip4_addr_ismulticast(dest) && ip4_default_multicast_netif) {
return ip4_default_multicast_netif;
}
#endif /* LWIP_MULTICAST_TX_OPTIONS */
/* bug #54569: in case LWIP_SINGLE_NETIF=1 and LWIP_DEBUGF() disabled, the following loop is optimized away */
LWIP_UNUSED_ARG(dest);
/* iterate through netifs */
NETIF_FOREACH(netif)
{
/* is the netif up, does it have a link and a valid address? */
if (netif_is_up(netif) && netif_is_link_up(netif) && !ip4_addr_isany_val(*netif_ip4_addr(netif))) {
/* network mask matches? */
// if (ip4_addr_netcmp(dest, netif_ip4_addr(netif), netif_ip4_netmask(netif))) {
if (ip4_addr_cmp(src, netif_ip4_addr(netif))) {
/* return netif on which to forward IP packet */
return netif;
}
/* gateway matches on a non broadcast interface? (i.e. peer in a point to point interface) */
if (((netif->flags & NETIF_FLAG_BROADCAST) == 0) && ip4_addr_cmp(dest, netif_ip4_gw(netif))) {
/* return netif on which to forward IP packet */
return netif;
}
}
}
#if LWIP_NETIF_LOOPBACK && !LWIP_HAVE_LOOPIF
/* loopif is disabled, looopback traffic is passed through any netif */
if (ip4_addr_isloopback(dest)) {
/* don't check for link on loopback traffic */
if (netif_default != NULL && netif_is_up(netif_default)) {
return netif_default;
}
/* default netif is not up, just use any netif for loopback traffic */
NETIF_FOREACH(netif)
{
if (netif_is_up(netif)) {
return netif;
}
}
return NULL;
}
#endif /* LWIP_NETIF_LOOPBACK && !LWIP_HAVE_LOOPIF */
#ifdef LWIP_HOOK_IP4_ROUTE_SRC
netif = LWIP_HOOK_IP4_ROUTE_SRC(NULL, dest);
if (netif != NULL) {
return netif;
}
#elif defined(LWIP_HOOK_IP4_ROUTE)
netif = LWIP_HOOK_IP4_ROUTE(dest);
if (netif != NULL) {
return netif;
}
#endif
#endif /* !LWIP_SINGLE_NETIF */
if ((netif_default == NULL) || !netif_is_up(netif_default) || !netif_is_link_up(netif_default) || ip4_addr_isany_val(*netif_ip4_addr(netif_default)) || ip4_addr_isloopback(dest)) {
/* No matching netif found and default netif is not usable.
If this is not good enough for you, use LWIP_HOOK_IP4_ROUTE() */
LWIP_DEBUGF(IP_DEBUG | LWIP_DBG_LEVEL_SERIOUS, ("ip4_route: No route to %" U16_F ".%" U16_F ".%" U16_F ".%" U16_F "\n", ip4_addr1_16(dest), ip4_addr2_16(dest), ip4_addr3_16(dest), ip4_addr4_16(dest)));
IP_STATS_INC(ip.rterr);
MIB2_STATS_INC(mib2.ipoutnoroutes);
return NULL;
}
return netif_default;
}
#if IP_FORWARD
/**
* Determine whether an IP address is in a reserved set of addresses

40
Ubiquitous/XiZi_IIoT/resources/ethernet/LwIP/include/lwip/ip4.h
View File

@ -63,39 +63,41 @@ extern "C" {
#define ip_init() /* Compatibility define, no init needed. */
struct netif *ip4_route(const ip4_addr_t *dest);
struct netif* ip4_route2(const ip4_addr_t* src, const ip4_addr_t* dest);
#if LWIP_IPV4_SRC_ROUTING
struct netif *ip4_route_src(const ip4_addr_t *src, const ip4_addr_t *dest);
struct netif* ip4_route_src(const ip4_addr_t* src, const ip4_addr_t* dest);
#else /* LWIP_IPV4_SRC_ROUTING */
#define ip4_route_src(src, dest) ip4_route(dest)
// #define ip4_route_src(src, dest) ip4_route(dest)
#define ip4_route_src(src, dest) ip4_route2(src, dest)
#endif /* LWIP_IPV4_SRC_ROUTING */
err_t ip4_input(struct pbuf *p, struct netif *inp);
err_t ip4_output(struct pbuf *p, const ip4_addr_t *src, const ip4_addr_t *dest,
u8_t ttl, u8_t tos, u8_t proto);
err_t ip4_output_if(struct pbuf *p, const ip4_addr_t *src, const ip4_addr_t *dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif *netif);
err_t ip4_output_if_src(struct pbuf *p, const ip4_addr_t *src, const ip4_addr_t *dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif *netif);
err_t ip4_input(struct pbuf* p, struct netif* inp);
err_t ip4_output(struct pbuf* p, const ip4_addr_t* src, const ip4_addr_t* dest,
u8_t ttl, u8_t tos, u8_t proto);
err_t ip4_output_if(struct pbuf* p, const ip4_addr_t* src, const ip4_addr_t* dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif* netif);
err_t ip4_output_if_src(struct pbuf* p, const ip4_addr_t* src, const ip4_addr_t* dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif* netif);
#if LWIP_NETIF_USE_HINTS
err_t ip4_output_hinted(struct pbuf *p, const ip4_addr_t *src, const ip4_addr_t *dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif_hint *netif_hint);
err_t ip4_output_hinted(struct pbuf* p, const ip4_addr_t* src, const ip4_addr_t* dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif_hint* netif_hint);
#endif /* LWIP_NETIF_USE_HINTS */
#if IP_OPTIONS_SEND
err_t ip4_output_if_opt(struct pbuf *p, const ip4_addr_t *src, const ip4_addr_t *dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif *netif, void *ip_options,
u16_t optlen);
err_t ip4_output_if_opt_src(struct pbuf *p, const ip4_addr_t *src, const ip4_addr_t *dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif *netif, void *ip_options,
u16_t optlen);
err_t ip4_output_if_opt(struct pbuf* p, const ip4_addr_t* src, const ip4_addr_t* dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif* netif, void* ip_options,
u16_t optlen);
err_t ip4_output_if_opt_src(struct pbuf* p, const ip4_addr_t* src, const ip4_addr_t* dest,
u8_t ttl, u8_t tos, u8_t proto, struct netif* netif, void* ip_options,
u16_t optlen);
#endif /* IP_OPTIONS_SEND */
#if LWIP_MULTICAST_TX_OPTIONS
void ip4_set_default_multicast_netif(struct netif* default_multicast_netif);
void ip4_set_default_multicast_netif(struct netif* default_multicast_netif);
#endif /* LWIP_MULTICAST_TX_OPTIONS */
#define ip4_netif_get_local_ip(netif) (((netif) != NULL) ? netif_ip_addr4(netif) : NULL)
#if IP_DEBUG
void ip4_debug_print(struct pbuf *p);
void ip4_debug_print(struct pbuf* p);
#else
#define ip4_debug_print(p)
#endif /* IP_DEBUG */

14
Ubiquitous/XiZi_IIoT/resources/ethernet/LwIP/include/lwip/opt.h
View File

@ -521,7 +521,7 @@
* (only needed if you use the sequential API, like api_lib.c)
*/
#if !defined MEMP_NUM_NETBUF || defined __DOXYGEN__
#define MEMP_NUM_NETBUF 2
#define MEMP_NUM_NETBUF 8
#endif
/**
@ -529,7 +529,7 @@
* (only needed if you use the sequential API, like api_lib.c)
*/
#if !defined MEMP_NUM_NETCONN || defined __DOXYGEN__
#define MEMP_NUM_NETCONN 4
#define MEMP_NUM_NETCONN 8
#endif
/**
@ -538,7 +538,7 @@
* In that case, you need one per thread calling lwip_select.)
*/
#if !defined MEMP_NUM_SELECT_CB || defined __DOXYGEN__
#define MEMP_NUM_SELECT_CB 4
#define MEMP_NUM_SELECT_CB 4
#endif
/**
@ -547,7 +547,7 @@
* (only needed if you use tcpip.c)
*/
#if !defined MEMP_NUM_TCPIP_MSG_API || defined __DOXYGEN__
#define MEMP_NUM_TCPIP_MSG_API 8
#define MEMP_NUM_TCPIP_MSG_API 8
#endif
/**
@ -556,7 +556,7 @@
* (only needed if you use tcpip.c)
*/
#if !defined MEMP_NUM_TCPIP_MSG_INPKT || defined __DOXYGEN__
#define MEMP_NUM_TCPIP_MSG_INPKT 8
#define MEMP_NUM_TCPIP_MSG_INPKT 8
#endif
/**
@ -564,7 +564,7 @@
* (before freeing the corresponding memory using lwip_freeaddrinfo()).
*/
#if !defined MEMP_NUM_NETDB || defined __DOXYGEN__
#define MEMP_NUM_NETDB 1
#define MEMP_NUM_NETDB 2
#endif
/**
@ -572,7 +572,7 @@
* if DNS_LOCAL_HOSTLIST_IS_DYNAMIC==1.
*/
#if !defined MEMP_NUM_LOCALHOSTLIST || defined __DOXYGEN__
#define MEMP_NUM_LOCALHOSTLIST 1
#define MEMP_NUM_LOCALHOSTLIST 2
#endif
/**

2
Ubiquitous/XiZi_IIoT/resources/ethernet/cmd_lwip/Makefile
View File

@ -1,4 +1,4 @@
# SRC_FILES := ping.c lwip_ping_demo.c lwip_config_demo.c lwip_dhcp_demo.c iperf.c http_test.c
SRC_FILES := ping.c lwip_ping_demo.c lwip_udp_demo.c tcpecho_raw.c lwip_config_demo.c lwip_dhcp_demo.c
SRC_FILES := ping.c lwip_ping_demo.c tcpecho_raw.c lwip_config_demo.c
include $(KERNEL_ROOT)/compiler.mk

207
Ubiquitous/XiZi_IIoT/resources/ethernet/cmd_lwip/lwip_config_demo.c
View File

@ -25,104 +25,145 @@
#include <sys_arch.h>
#include <xs_kdbg.h>
#include <netdev.h>
#include "argparse.h"
#include "inet.h"
#include "netdev.h"
/******************************************************************************/
uint8_t enet_id = 0;
static void LwipSetIPTask(void* param)
{
uint8_t enet_port = *(uint8_t*)param; ///< test enet port
printf("lw: [%s] config netport id[%d]\n", __func__, enet_port);
// lwip_config_net(enet_port, lwip_ipaddr, lwip_netmask, lwip_gwaddr);
lwip_config_tcp(enet_port, lwip_ipaddr, lwip_netmask, lwip_gwaddr);
}
enum NETWORK_ACTIVE_E {
LWIP_ACTIVE = 'e',
LWIP_ACTIVE_ALL = 'a',
};
void LwipSetIPTest(int argc, char* argv[])
void LwipNetworkActive(int argc, char* argv[])
{
if (argc >= 4) {
printf("lw: [%s] ip %s mask %s gw %s netport %s\n", __func__, argv[1], argv[2], argv[3], argv[4]);
sscanf(argv[1], "%hhd.%hhd.%hhd.%hhd", &lwip_ipaddr[0], &lwip_ipaddr[1], &lwip_ipaddr[2], &lwip_ipaddr[3]);
sscanf(argv[2], "%hhd.%hhd.%hhd.%hhd", &lwip_netmask[0], &lwip_netmask[1], &lwip_netmask[2], &lwip_netmask[3]);
sscanf(argv[3], "%hhd.%hhd.%hhd.%hhd", &lwip_gwaddr[0], &lwip_gwaddr[1], &lwip_gwaddr[2], &lwip_gwaddr[3]);
sscanf(argv[4], "%hhd", &enet_id);
static char usage_info[] = "select a eport to start.";
static char program_info[] = "Active lwip network function.";
static const char* const net_active_usages[] = {
"LwipNetworkActive -e 0",
"LwipNetworkActive -e 1",
"LwipNetworkActive -a",
};
if (0 == enet_id) {
printf("save eth0 info\n");
memcpy(lwip_eth0_ipaddr, lwip_ipaddr, 20);
memcpy(lwip_eth0_netmask, lwip_netmask, 20);
memcpy(lwip_eth0_gwaddr, lwip_gwaddr, 20);
} else if (1 == enet_id) {
printf("save eth1 info\n");
memcpy(lwip_eth1_ipaddr, lwip_ipaddr, 20);
memcpy(lwip_eth1_netmask, lwip_netmask, 20);
memcpy(lwip_eth1_gwaddr, lwip_gwaddr, 20);
}
} else if (argc == 2) {
printf("lw: [%s] set eth0 ipaddr %s \n", __func__, argv[1]);
sscanf(argv[1], "%hhd.%hhd.%hhd.%hhd", &lwip_ipaddr[0], &lwip_ipaddr[1], &lwip_ipaddr[2], &lwip_ipaddr[3]);
memcpy(lwip_eth0_ipaddr, lwip_ipaddr, strlen(lwip_ipaddr));
int eport = -1;
bool all = false;
bool is_help = false;
struct argparse_option options[] = {
OPT_HELP(&is_help),
OPT_INTEGER(LWIP_ACTIVE, "eport", &eport, "eport to start network.", NULL, 0, 0),
OPT_BIT(LWIP_ACTIVE_ALL, "all", &all, "start network at both eport 0 and 1.", NULL, true, 0),
OPT_END(),
};
struct argparse argparse;
argparse_init(&argparse, options, net_active_usages, 0);
argparse_describe(&argparse, usage_info, program_info);
argc = argparse_parse(&argparse, argc, (const char**)argv);
if (is_help) {
return;
}
// sys_thread_new("SET ip address", LwipSetIPTask, &enet_id, LWIP_TASK_STACK_SIZE, LWIP_DEMO_TASK_PRIO);
LwipSetIPTask(&enet_id);
}
if (all) {
lwip_config_tcp(0, lwip_eth0_ipaddr, lwip_eth0_netmask, lwip_eth0_gwaddr);
lwip_config_tcp(1, lwip_eth1_ipaddr, lwip_eth1_netmask, lwip_eth1_gwaddr);
return;
}
if (eport != 0 && eport != 1) {
printf("[%s] Err: Support only eport 0 and eport 1.\n", __func__);
}
if (eport == 0) {
lwip_config_tcp(0, lwip_eth0_ipaddr, lwip_eth0_netmask, lwip_eth0_gwaddr);
} else if (eport == 1) {
lwip_config_tcp(1, lwip_eth1_ipaddr, lwip_eth1_netmask, lwip_eth1_gwaddr);
}
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0) | SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN) | SHELL_CMD_PARAM_NUM(5),
setip, LwipSetIPTest, setip[IP][Netmask][Gateway][port]);
LwipNetworkActive, LwipNetworkActive, start lwip);
void LwipShowIPTask(int argc, char* argv[])
enum NETWORK_CONFIG_E {
NETWORK_DEV = 'd',
NETWORK_IP = 'i',
NETWORK_NM = 'n',
NETWORK_GW = 'g',
};
void LwipSetNetwork(int argc, char* argv[])
{
#ifdef configMAC_ADDR
char mac_addr0[] = configMAC_ADDR;
#endif
static char usage_info[] = "config network information.";
static char program_info[] = "set network ip, netmask, gateway";
static const char* const net_set_usages[] = {
"LwipSetNetwork -d [dev] -i [ip]",
"LwipSetNetwork -d [dev] -n [netmask]",
"LwipSetNetwork -d [dev] -g [gw]",
"LwipSetNetwork -d [dev] -i [ip] -n [netmask] -g [gw]",
};
// find default netdev
struct netdev* netdev = netdev_get_by_name("en\0");
char* dev_ptr = NULL;
char* ip_ptr = NULL;
char* nm_ptr = NULL;
char* gw_ptr = NULL;
bool is_help = false;
struct argparse_option options[] = {
OPT_HELP(&is_help),
OPT_GROUP("Param Options"),
OPT_STRING(NETWORK_DEV, "dev", &dev_ptr, "netdev", NULL, 0, 0),
OPT_STRING(NETWORK_IP, "ip", &ip_ptr, "change ip", NULL, 0, 0),
OPT_STRING(NETWORK_NM, "nm", &nm_ptr, "change netmask", NULL, 0, 0),
OPT_STRING(NETWORK_GW, "gw", &gw_ptr, "change gateway", NULL, 0, 0),
OPT_END(),
};
struct argparse argparse;
argparse_init(&argparse, options, net_set_usages, 0);
argparse_describe(&argparse, usage_info, program_info);
argc = argparse_parse(&argparse, argc, (const char**)argv);
/* help task */
if (is_help) {
return;
}
if (dev_ptr == NULL) {
printf("[%s] Err: must given a netdev name.\n", __func__);
return;
}
struct netdev* netdev = netdev_get_by_name(dev_ptr);
if (netdev == NULL) {
lw_notice("[%s] Netdev not found by name en\n");
struct netdev* default_netdev = NETDEV_DEFAULT;
printf("[%s] Err: Netdev not found by name: %s\n", __func__, dev_ptr);
return;
}
lw_notice("\r\n************************************************\r\n");
lw_notice(" Network Configuration\r\n");
lw_notice("************************************************\r\n");
// lw_notice(" ETH0 IPv4 Address : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_eth0_ipaddr)[0], ((u8_t*)&lwip_eth0_ipaddr)[1],
// ((u8_t*)&lwip_eth0_ipaddr)[2], ((u8_t*)&lwip_eth0_ipaddr)[3]);
// lw_notice(" ETH0 IPv4 Subnet mask : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_eth0_netmask)[0], ((u8_t*)&lwip_eth0_netmask)[1],
// ((u8_t*)&lwip_eth0_netmask)[2], ((u8_t*)&lwip_eth0_netmask)[3]);
// lw_notice(" ETH0 IPv4 Gateway : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_gwaddr)[0], ((u8_t*)&lwip_eth0_gwaddr)[1],
// ((u8_t*)&lwip_eth0_gwaddr)[2], ((u8_t*)&lwip_eth0_gwaddr)[3]);
// #ifdef configMAC_ADDR
// lw_notice(" ETH0 MAC Address : %x:%x:%x:%x:%x:%x\r\n", mac_addr0[0], mac_addr0[1], mac_addr0[2],
// mac_addr0[3], mac_addr0[4], mac_addr0[5]);
// #endif
lw_notice(" ETH0 IPv4 Address : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_eth0_ipaddr)[0], ((u8_t*)&lwip_eth0_ipaddr)[1],
((u8_t*)&lwip_eth0_ipaddr)[2], ((u8_t*)&lwip_eth0_ipaddr)[3]);
lw_notice(" ETH0 IPv4 Subnet mask : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_eth0_netmask)[0], ((u8_t*)&lwip_eth0_netmask)[1],
((u8_t*)&lwip_eth0_netmask)[2], ((u8_t*)&lwip_eth0_netmask)[3]);
lw_notice(" ETH0 IPv4 Gateway : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_gwaddr)[0], ((u8_t*)&lwip_eth0_gwaddr)[1],
((u8_t*)&lwip_eth0_gwaddr)[2], ((u8_t*)&lwip_eth0_gwaddr)[3]);
#ifdef configMAC_ADDR
lw_notice(" ETH0 MAC Address : %x:%x:%x:%x:%x:%x\r\n", mac_addr0[0], mac_addr0[1], mac_addr0[2],
mac_addr0[3], mac_addr0[4], mac_addr0[5]);
#endif
#ifdef BOARD_NET_COUNT
if (BOARD_NET_COUNT > 1) {
char mac_addr1[] = configMAC_ADDR_ETH1;
lw_notice("\r\n");
lw_notice(" ETH1 IPv4 Address : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_eth1_ipaddr)[0], ((u8_t*)&lwip_eth1_ipaddr)[1],
((u8_t*)&lwip_eth1_ipaddr)[2], ((u8_t*)&lwip_eth1_ipaddr)[3]);
lw_notice(" ETH1 IPv4 Subnet mask : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_eth1_netmask)[0], ((u8_t*)&lwip_eth1_netmask)[1],
((u8_t*)&lwip_eth1_netmask)[2], ((u8_t*)&lwip_eth1_netmask)[3]);
lw_notice(" ETH1 IPv4 Gateway : %u.%u.%u.%u\r\n", ((u8_t*)&lwip_eth1_gwaddr)[0], ((u8_t*)&lwip_eth1_gwaddr)[1],
((u8_t*)&lwip_eth1_gwaddr)[2], ((u8_t*)&lwip_eth1_gwaddr)[3]);
lw_notice(" ETH1 MAC Address : %x:%x:%x:%x:%x:%x\r\n", mac_addr1[0], mac_addr1[1], mac_addr1[2],
mac_addr1[3], mac_addr1[4], mac_addr1[5]);
ip_addr_t ipaddr, maskaddr, gwaddr;
if (ip_ptr != NULL) {
inet_aton(ip_ptr, &ipaddr);
if (0 != netdev_set_ipaddr(netdev, &ipaddr)) {
printf("[%s] Err: set ip: %s failed.\n", __func__, ip_ptr);
}
}
#endif
lw_notice("************************************************\r\n");
if (nm_ptr != NULL) {
inet_aton(nm_ptr, &maskaddr);
if (0 != netdev_set_netmask(netdev, &maskaddr)) {
printf("[%s] Err: set netmask: %s failed.\n", __func__, nm_ptr);
}
}
if (gw_ptr != NULL) {
inet_aton(gw_ptr, &gwaddr);
if (0 != netdev_set_gw(netdev, &gwaddr)) {
printf("[%s] Err: set gateway: %s failed.\n", __func__, gw_ptr);
}
}
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0) | SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN) | SHELL_CMD_PARAM_NUM(11),
LwipSetNetwork, LwipSetNetwork, config lwip);
void LwipShowNetwork(int argc, char* argv[])
{
extern void netdev_list_dev();
netdev_list_dev();
}
SHELL_EXPORT_CMD(SHELL_CMD_PERMISSION(0) | SHELL_CMD_TYPE(SHELL_TYPE_CMD_MAIN) | SHELL_CMD_PARAM_NUM(0),
showip, LwipShowIPTask, GetIp[IP][Netmask][Gateway]);
LwipShowNetwork, LwipShowNetwork, show lwip network configuration);

12
Ubiquitous/XiZi_IIoT/resources/ethernet/netdev/netdev_lowlevel.c
View File

@ -43,8 +43,8 @@ void netdev_low_level_set_ipaddr(struct netdev* netdev, const ip_addr_t* ip_addr
{
CHECK(ip_addr);
if (netdev && ip_addr_cmp(&(netdev->ip_addr), ip_addr) == 0) {
ip_addr_copy(netdev->ip_addr, *ip_addr);
if (netdev && ip_addr_cmp((netdev->ip_addr), ip_addr) == 0) {
ip_addr_copy(*netdev->ip_addr, *ip_addr);
/* execute IP address change callback function */
if (netdev->addr_callback) {
@ -64,8 +64,8 @@ void netdev_low_level_set_netmask(struct netdev* netdev, const ip_addr_t* netmas
{
CHECK(netmask);
if (netdev && ip_addr_cmp(&(netdev->netmask), netmask) == 0) {
ip_addr_copy(netdev->netmask, *netmask);
if (netdev && ip_addr_cmp((netdev->netmask), netmask) == 0) {
ip_addr_copy(*netdev->netmask, *netmask);
/* execute netmask address change callback function */
if (netdev->addr_callback) {
@ -85,8 +85,8 @@ void netdev_low_level_set_gw(struct netdev* netdev, const ip_addr_t* gw)
{
CHECK(gw);
if (netdev && ip_addr_cmp(&(netdev->gw), gw) == 0) {
ip_addr_copy(netdev->gw, *gw);
if (netdev && ip_addr_cmp((netdev->gw), gw) == 0) {
ip_addr_copy(*netdev->gw, *gw);
/* execute gateway address change callback function */
if (netdev->addr_callback) {

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