Merge branch 'master' of https://github.com/jeelabs/esp-link into jeelabs-master

Conflicts:
	esp-link/cgi.c
	include/user_config.h
	mqtt/mqtt.h
	user/user_main.c
pull/47/head
Benjamin Runnels 9 years ago
commit 33f9ede084
  1. 6
      Makefile
  2. 39
      README.md
  3. 2
      cmd/handlers.c
  4. 155
      esp-link/cgi.c
  5. 3
      esp-link/cgi.h
  6. 111
      esp-link/cgimqtt.c
  7. 8
      esp-link/cgimqtt.h
  8. 46
      esp-link/cgipins.c
  9. 824
      esp-link/cgiwifi.c
  10. 21
      esp-link/config.c
  11. 5
      esp-link/config.h
  12. 21
      esp-link/main.c
  13. 176
      esp-link/status.c
  14. 2
      html/console.html
  15. 99
      html/mqtt.html
  16. 4
      html/style.css
  17. 130
      html/ui.js
  18. 4
      httpd/httpd.c
  19. 925
      mqtt/mqtt.c
  20. 170
      mqtt/mqtt.h
  21. 47
      mqtt/mqtt_cmd.c
  22. 1
      mqtt/mqtt_cmd.h
  23. 51
      mqtt/mqtt_msg.c
  24. 48
      mqtt/mqtt_msg.h
  25. 64
      mqtt/pktbuf.c
  26. 29
      mqtt/pktbuf.h
  27. 86
      mqtt/proto.c
  28. 21
      mqtt/proto.h
  29. 53
      mqtt/queue.c
  30. 46
      mqtt/queue.h
  31. 63
      mqtt/ringbuf.c
  32. 17
      mqtt/ringbuf.h
  33. 12
      rest/rest.c
  34. 15
      serial/serbridge.c
  35. 1
      serial/serled.h
  36. 19
      serial/slip.c
  37. 6
      serial/slip.h
  38. 2
      serial/uart.c
  39. 151
      user/user_main.c

@ -164,7 +164,7 @@ EXTRA_INCDIR =include .
EXTRA_INCDIR = include .
# libraries used in this project, mainly provided by the SDK
LIBS = c gcc hal phy pp net80211 wpa main lwip
LIBS = c gcc hal phy pp net80211 wpa main lwip # crypto ssl
# compiler flags using during compilation of source files
CFLAGS += -Os -ggdb -std=c99 -Werror -Wpointer-arith -Wundef -Wall -Wl,-EL -fno-inline-functions \
@ -373,8 +373,8 @@ release: all
$(Q) egrep -a 'esp-link [a-z0-9.]+ - 201' $(FW_BASE)/user2.bin | cut -b 1-80
$(Q) cp $(FW_BASE)/user1.bin $(FW_BASE)/user2.bin $(SDK_BASE)/bin/blank.bin \
"$(SDK_BASE)/bin/boot_v1.4(b1).bin" wiflash release/esp-link-$(BRANCH)
$(Q) tar zcf esp-link-$(BRANCH)-$(FLASH_SIZE).tgz -C release esp-link-$(BRANCH)
$(Q) echo "Release file: esp-link-$(BRANCH)-$(FLASH_SIZE).tgz"
$(Q) tar zcf esp-link-$(BRANCH).tgz -C release esp-link-$(BRANCH)
$(Q) echo "Release file: esp-link-$(BRANCH).tgz"
$(Q) rm -rf release
clean:

@ -26,6 +26,28 @@ Many thanks to https://github.com/brunnels for contributions around the espduino
For quick support and questions:
[![Chat at https://gitter.im/jeelabs/esp-link](https://badges.gitter.im/Join%20Chat.svg)](https://gitter.im/jeelabs/esp-link?utm_source=badge&utm_medium=badge&utm_campaign=pr-badge&utm_content=badge)
Esp-link uses
-------------
The simplest use of esp-link is as a transparent serial to wifi bridge. You can flash an attached
uC over wifi and you can watch the uC's serial debug output by connecting to port 23 or looking
at the uC Console web page.
The next level is to use the outbound connectivity of esp-link in the uC code. For example, the
uC can use REST requests to services like thingspeak.com to send sensor values that then get
stored and plotted by the external service.
The uC can also use REST requests to retrieve simple configuration
information or push other forms of notifications. (MQTT functionality is forthcoming.)
An additional option is to add code to esp-link to customize it and put all the communication
code into esp-link and only keep simple sensor/actuator control in the attached uC. In this
mode the attached uC sends custom commands to esp-link with sensor/acturator info and
registers a set of callbacks with esp-link that control sensors/actuators. This way, custom
commands in esp-link can receive MQTT messages, make simple callbacks into the uC to get sensor
values or change actuators, and then respond back with MQTT. The way this is architected is that
the attached uC registers callbacks at start-up such that the code in the esp doesn't need to
know which exact sensors/actuators the attached uC has, it learns thta through the initial
callback registration.
Eye Candy
---------
These screen shots show the Home page, the Wifi configuration page, the console for the
@ -237,7 +259,22 @@ The attached micro-controller can open outbound TCP connections using a simple
[serial protocol](https://gist.github.com/tve/a46c44bf1f6b42bc572e).
More info and sample code forthcoming...
Outbound HTTP REST requests
---------------------------
The V2 versions of esp-link support the espduino SLIP protocol that supports simple outbound
HTTP REST requests. The SLIP protocol consists of commands with binary arguments sent from the
attached microcontroller to the esp8266, which then performs the command and responds back.
The responses back use a callback address in the attached microcontroller code, i.e., the
command sent by the uC contains a callback address and the response from the esp8266 starts
with that callback address. This enables asynchronous communication where esp-link can notify the
uC when requests complete or when other actions happen, such as wifi connectivity status changes.
Support for MQTT is forthcoming.
You can find a demo sketch in a fork of the espduino library at
https://github.com/tve/espduino in the
[examples/demo folder](https://github.com/tve/espduino/tree/master/espduino/examples/demo).
Contact
-------
If you find problems with esp-link, please create a github issue. If you have a question, please
use the gitter link at the top of this page.
use the gitter chat link at the top of this page.

@ -94,7 +94,7 @@ cmdCallback* ICACHE_FLASH_ATTR
CMD_GetCbByName(char* name) {
char checkname[16];
os_strncpy(checkname, name, sizeof(checkname));
for (uint8_t i = 0; i < sizeof(commands); i++) {
for (uint8_t i = 0; i < MAX_CALLBACKS; i++) {
//os_printf("CMD_GetCbByName: index %d name=%s cb=%p\n", i, callbacks[i].name,
// (void *)callbacks[i].callback);
// if callback doesn't exist or it's null

@ -12,95 +12,112 @@ Some random cgi routines.
* Heavily modified and enhanced by Thorsten von Eicken in 2015
* ----------------------------------------------------------------------------
*/
#include <esp8266.h>
#include "cgi.h"
#include "espfs.h"
void noCacheHeaders(HttpdConnData *connData, int code) {
httpdStartResponse(connData, code);
httpdHeader(connData, "Cache-Control", "no-cache, no-store, must-revalidate");
httpdHeader(connData, "Pragma", "no-cache");
httpdHeader(connData, "Expires", "0");
}
void ICACHE_FLASH_ATTR
jsonHeader(HttpdConnData *connData, int code) {
httpdStartResponse(connData, code);
httpdHeader(connData, "Cache-Control", "no-cache, no-store, must-revalidate");
httpdHeader(connData, "Pragma", "no-cache");
httpdHeader(connData, "Expires", "0");
httpdHeader(connData, "Content-Type", "application/json");
httpdEndHeaders(connData);
noCacheHeaders(connData, code);
httpdHeader(connData, "Content-Type", "application/json");
httpdEndHeaders(connData);
}
uint8_t ICACHE_FLASH_ATTR
UTILS_StrToIP(const char* str, void *ip){
/* The count of the number of bytes processed. */
int i;
/* A pointer to the next digit to process. */
const char * start;
void ICACHE_FLASH_ATTR
errorResponse(HttpdConnData *connData, int code, char *message) {
noCacheHeaders(connData, code);
httpdEndHeaders(connData);
httpdSend(connData, message, -1);
os_printf("HTTP %d error response: \"%s\"\n", code, message);
}
start = str;
for (i = 0; i < 4; i++) {
/* The digit being processed. */
char c;
/* The value of this byte. */
int n = 0;
while (1) {
c = *start;
start++;
if (c >= '0' && c <= '9') {
n *= 10;
n += c - '0';
}
/* We insist on stopping at "." if we are still parsing
the first, second, or third numbers. If we have reached
the end of the numbers, we will allow any character. */
else if ((i < 3 && c == '.') || i == 3) {
break;
}
else {
return 0;
}
}
if (n >= 256) {
return 0;
}
((uint8_t*)ip)[i] = n;
// look for the HTTP arg 'name' and store it at 'config' with max length 'max_len' (incl
// terminating zero), returns -1 on error, 0 if not found, 1 if found and OK
int ICACHE_FLASH_ATTR
getStringArg(HttpdConnData *connData, char *name, char *config, int max_len) {
char buff[128];
int len = httpdFindArg(connData->getArgs, name, buff, sizeof(buff));
if (len < 0) return 0; // not found, skip
if (len >= max_len) {
os_sprintf(buff, "Value for %s too long (%d > %d allowed)", name, len, max_len-1);
errorResponse(connData, 400, buff);
return -1;
}
strcpy(config, buff);
return 1;
}
int ICACHE_FLASH_ATTR
getBoolArg(HttpdConnData *connData, char *name, bool*config) {
char buff[64];
int len = httpdFindArg(connData->getArgs, name, buff, sizeof(buff));
if (len < 0) return 0; // not found, skip
if (strcmp(buff, "1") == 0 || strcmp(buff, "true") == 0) {
*config = true;
return 1;
}
if (strcmp(buff, "0") == 0 || strcmp(buff, "false") == 0) {
*config = false;
return 1;
}
os_sprintf(buff, "Invalid value for %s", name);
errorResponse(connData, 400, buff);
return -1;
}
#define TOKEN(x) (os_strcmp(token, x) == 0)
#if 0
// Handle system information variables and print their value, returns the number of
// characters appended to buff
int ICACHE_FLASH_ATTR printGlobalInfo(char *buff, int buflen, char *token) {
if (TOKEN("si_chip_id")) {
return os_sprintf(buff, "0x%x", system_get_chip_id());
} else if (TOKEN("si_freeheap")) {
return os_sprintf(buff, "%dKB", system_get_free_heap_size()/1024);
} else if (TOKEN("si_uptime")) {
uint32 t = system_get_time() / 1000000; // in seconds
return os_sprintf(buff, "%dd%dh%dm%ds", t/(24*3600), (t/(3600))%24, (t/60)%60, t%60);
} else if (TOKEN("si_boot_version")) {
return os_sprintf(buff, "%d", system_get_boot_version());
} else if (TOKEN("si_boot_address")) {
return os_sprintf(buff, "0x%x", system_get_userbin_addr());
} else if (TOKEN("si_cpu_freq")) {
return os_sprintf(buff, "%dMhz", system_get_cpu_freq());
} else {
return 0;
}
if (TOKEN("si_chip_id")) {
return os_sprintf(buff, "0x%x", system_get_chip_id());
} else if (TOKEN("si_freeheap")) {
return os_sprintf(buff, "%dKB", system_get_free_heap_size()/1024);
} else if (TOKEN("si_uptime")) {
uint32 t = system_get_time() / 1000000; // in seconds
return os_sprintf(buff, "%dd%dh%dm%ds", t/(24*3600), (t/(3600))%24, (t/60)%60, t%60);
} else if (TOKEN("si_boot_version")) {
return os_sprintf(buff, "%d", system_get_boot_version());
} else if (TOKEN("si_boot_address")) {
return os_sprintf(buff, "0x%x", system_get_userbin_addr());
} else if (TOKEN("si_cpu_freq")) {
return os_sprintf(buff, "%dMhz", system_get_cpu_freq());
} else {
return 0;
}
}
#endif
extern char *esp_link_version; // in user_main.c
int ICACHE_FLASH_ATTR cgiMenu(HttpdConnData *connData) {
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
char buff[1024];
// don't use jsonHeader so the response does get cached
httpdStartResponse(connData, 200);
httpdHeader(connData, "Cache-Control", "max-age=3600, must-revalidate");
httpdHeader(connData, "Content-Type", "application/json");
httpdEndHeaders(connData);
// construct json response
os_sprintf(buff,
"{\"menu\": [\"Home\", \"/home.html\", \"Wifi\", \"/wifi/wifi.html\","
"\"\xC2\xB5" "C Console\", \"/console.html\", \"Debug log\", \"/log.html\" ],\n"
" \"version\": \"%s\" }", esp_link_version);
httpdSend(connData, buff, -1);
return HTTPD_CGI_DONE;
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
char buff[1024];
// don't use jsonHeader so the response does get cached
httpdStartResponse(connData, 200);
httpdHeader(connData, "Cache-Control", "max-age=3600, must-revalidate");
httpdHeader(connData, "Content-Type", "application/json");
httpdEndHeaders(connData);
// construct json response
os_sprintf(buff,
"{\"menu\": [\"Home\", \"/home.html\", "
"\"Wifi\", \"/wifi/wifi.html\","
"\"\xC2\xB5" "C Console\", \"/console.html\", "
"\"REST/MQTT\", \"/mqtt.html\","
"\"Debug log\", \"/log.html\" ],\n"
" \"version\": \"%s\" }", esp_link_version);
httpdSend(connData, buff, -1);
return HTTPD_CGI_DONE;
}

@ -5,6 +5,9 @@
#include "httpd.h"
void jsonHeader(HttpdConnData *connData, int code);
void errorResponse(HttpdConnData *connData, int code, char *message);
int getStringArg(HttpdConnData *connData, char *name, char *config, int max_len);
int getBoolArg(HttpdConnData *connData, char *name, bool*config);
int cgiMenu(HttpdConnData *connData);
uint8_t UTILS_StrToIP(const char* str, void *ip);

@ -0,0 +1,111 @@
// Copyright 2015 by Thorsten von Eicken, see LICENSE.txt
// // TCP Client settings
#include <esp8266.h>
#include "cgi.h"
#include "config.h"
#include "cgimqtt.h"
// Cgi to return MQTT settings
int ICACHE_FLASH_ATTR cgiMqttGet(HttpdConnData *connData) {
char buff[2048];
int len;
if (connData->conn==NULL) return HTTPD_CGI_DONE;
len = os_sprintf(buff, "{ "
"\"slip-enable\":%d, "
"\"mqtt-enable\":%d, "
"\"mqtt-status-enable\":%d, "
"\"mqtt-port\":%d, "
"\"mqtt-host\":\"%s\", "
"\"mqtt-client-id\":\"%s\", "
"\"mqtt-username\":\"%s\", "
"\"mqtt-password\":\"%s\", "
"\"mqtt-status-topic\":\"%s\", "
"\"mqtt-state\":\"%s\" }",
flashConfig.slip_enable, flashConfig.mqtt_enable, flashConfig.mqtt_status_enable,
flashConfig.mqtt_port, flashConfig.mqtt_hostname, flashConfig.mqtt_client,
flashConfig.mqtt_username, flashConfig.mqtt_password,
flashConfig.mqtt_status_topic, "connected");
jsonHeader(connData, 200);
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
}
// Cgi to change choice of pin assignments
int ICACHE_FLASH_ATTR cgiMqttSet(HttpdConnData *connData) {
if (connData->conn==NULL) return HTTPD_CGI_DONE;
// handle MQTT server settings
int mqtt_server = 0; // accumulator for changes/errors
mqtt_server |= getStringArg(connData, "mqtt-host",
flashConfig.mqtt_hostname, sizeof(flashConfig.mqtt_hostname));
if (mqtt_server < 0) return HTTPD_CGI_DONE;
mqtt_server |= getStringArg(connData, "mqtt-client-id",
flashConfig.mqtt_client, sizeof(flashConfig.mqtt_client));
if (mqtt_server < 0) return HTTPD_CGI_DONE;
mqtt_server |= getStringArg(connData, "mqtt-username",
flashConfig.mqtt_username, sizeof(flashConfig.mqtt_username));
if (mqtt_server < 0) return HTTPD_CGI_DONE;
mqtt_server |= getStringArg(connData, "mqtt-password",
flashConfig.mqtt_password, sizeof(flashConfig.mqtt_password));
if (mqtt_server < 0) return HTTPD_CGI_DONE;
mqtt_server |= getBoolArg(connData, "mqtt-enable",
&flashConfig.mqtt_enable);
// handle mqtt port
char buff[16];
if (httpdFindArg(connData->getArgs, "mqtt-port", buff, sizeof(buff)) > 0) {
int32_t port = atoi(buff);
if (port > 0 && port < 65536) {
flashConfig.mqtt_port = port;
mqtt_server |= 1;
} else {
errorResponse(connData, 400, "Invalid MQTT port");
return HTTPD_CGI_DONE;
}
}
// if server setting changed, we need to "make it so"
if (mqtt_server) {
os_printf("MQTT server settings changed, enable=%d\n", flashConfig.mqtt_enable);
// TODO
}
// no action required if mqtt status settings change, they just get picked up at the
// next status tick
if (getBoolArg(connData, "mqtt-status-enable", &flashConfig.mqtt_status_enable) < 0)
return HTTPD_CGI_DONE;
if (getStringArg(connData, "mqtt-status-topic",
flashConfig.mqtt_status_topic, sizeof(flashConfig.mqtt_status_topic)) < 0)
return HTTPD_CGI_DONE;
// if SLIP-enable is toggled it gets picked-up immediately by the parser
int slip_update = getBoolArg(connData, "slip-enable", &flashConfig.slip_enable);
if (slip_update < 0) return HTTPD_CGI_DONE;
if (slip_update > 0) os_printf("SLIP-enable changed: %d\n", flashConfig.slip_enable);
os_printf("Saving config\n");
if (configSave()) {
httpdStartResponse(connData, 200);
httpdEndHeaders(connData);
} else {
httpdStartResponse(connData, 500);
httpdEndHeaders(connData);
httpdSend(connData, "Failed to save config", -1);
}
return HTTPD_CGI_DONE;
}
int ICACHE_FLASH_ATTR cgiMqtt(HttpdConnData *connData) {
if (connData->requestType == HTTPD_METHOD_GET) {
return cgiMqttGet(connData);
} else if (connData->requestType == HTTPD_METHOD_POST) {
return cgiMqttSet(connData);
} else {
jsonHeader(connData, 404);
return HTTPD_CGI_DONE;
}
}

@ -0,0 +1,8 @@
#ifndef CGIMQTT_H
#define CGIMQTT_H
#include "httpd.h"
int cgiMqtt(HttpdConnData *connData);
#endif

@ -24,9 +24,9 @@ static const int num_map_func = sizeof(map_func)/sizeof(char*);
// Cgi to return choice of pin assignments
int ICACHE_FLASH_ATTR cgiPinsGet(HttpdConnData *connData) {
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted
char buff[2048];
char buff[2048];
int len;
// figure out current mapping
@ -62,27 +62,27 @@ int ICACHE_FLASH_ATTR cgiPinsGet(HttpdConnData *connData) {
}
len += os_sprintf(buff+len, "\n] }");
jsonHeader(connData, 200);
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
jsonHeader(connData, 200);
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
}
// Cgi to change choice of pin assignments
int ICACHE_FLASH_ATTR cgiPinsSet(HttpdConnData *connData) {
if (connData->conn==NULL) {
return HTTPD_CGI_DONE; // Connection aborted
}
if (connData->conn==NULL) {
return HTTPD_CGI_DONE; // Connection aborted
}
char buff[128];
int len = httpdFindArg(connData->getArgs, "map", buff, sizeof(buff));
if (len <= 0) {
jsonHeader(connData, 400);
int len = httpdFindArg(connData->getArgs, "map", buff, sizeof(buff));
if (len <= 0) {
jsonHeader(connData, 400);
return HTTPD_CGI_DONE;
}
int m = atoi(buff);
if (m < 0 || m >= num_map_names) {
jsonHeader(connData, 400);
if (m < 0 || m >= num_map_names) {
jsonHeader(connData, 400);
return HTTPD_CGI_DONE;
}
@ -106,17 +106,17 @@ int ICACHE_FLASH_ATTR cgiPinsSet(HttpdConnData *connData) {
httpdEndHeaders(connData);
httpdSend(connData, "Failed to save config", -1);
}
return HTTPD_CGI_DONE;
return HTTPD_CGI_DONE;
}
int ICACHE_FLASH_ATTR cgiPins(HttpdConnData *connData) {
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
if (connData->requestType == HTTPD_METHOD_GET) {
return cgiPinsGet(connData);
} else if (connData->requestType == HTTPD_METHOD_POST) {
return cgiPinsSet(connData);
} else {
jsonHeader(connData, 404);
return HTTPD_CGI_DONE;
}
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
if (connData->requestType == HTTPD_METHOD_GET) {
return cgiPinsGet(connData);
} else if (connData->requestType == HTTPD_METHOD_POST) {
return cgiPinsSet(connData);
} else {
jsonHeader(connData, 404);
return HTTPD_CGI_DONE;
}
}

@ -31,12 +31,12 @@ uint8_t wifiState = wifiIsDisconnected;
// reasons for which a connection failed
uint8_t wifiReason = 0;
static char *wifiReasons[] = {
"", "unspecified", "auth_expire", "auth_leave", "assoc_expire", "assoc_toomany", "not_authed",
"not_assoced", "assoc_leave", "assoc_not_authed", "disassoc_pwrcap_bad", "disassoc_supchan_bad",
"ie_invalid", "mic_failure", "4way_handshake_timeout", "group_key_update_timeout",
"ie_in_4way_differs", "group_cipher_invalid", "pairwise_cipher_invalid", "akmp_invalid",
"unsupp_rsn_ie_version", "invalid_rsn_ie_cap", "802_1x_auth_failed", "cipher_suite_rejected",
"beacon_timeout", "no_ap_found" };
"", "unspecified", "auth_expire", "auth_leave", "assoc_expire", "assoc_toomany", "not_authed",
"not_assoced", "assoc_leave", "assoc_not_authed", "disassoc_pwrcap_bad", "disassoc_supchan_bad",
"ie_invalid", "mic_failure", "4way_handshake_timeout", "group_key_update_timeout",
"ie_in_4way_differs", "group_cipher_invalid", "pairwise_cipher_invalid", "akmp_invalid",
"unsupp_rsn_ie_version", "invalid_rsn_ie_cap", "802_1x_auth_failed", "cipher_suite_rejected",
"beacon_timeout", "no_ap_found" };
static char *wifiMode[] = { 0, "STA", "AP", "AP+STA" };
static char *wifiPhy[] = { 0, "11b", "11g", "11n" };
@ -44,51 +44,51 @@ static char *wifiPhy[] = { 0, "11b", "11g", "11n" };
void (*wifiStatusCb)(uint8_t); // callback when wifi status changes
static char* ICACHE_FLASH_ATTR wifiGetReason(void) {
if (wifiReason <= 24) return wifiReasons[wifiReason];
if (wifiReason >= 200 && wifiReason <= 201) return wifiReasons[wifiReason-200+24];
return wifiReasons[1];
if (wifiReason <= 24) return wifiReasons[wifiReason];
if (wifiReason >= 200 && wifiReason <= 201) return wifiReasons[wifiReason-200+24];
return wifiReasons[1];
}
// handler for wifi status change callback coming in from espressif library
static void ICACHE_FLASH_ATTR wifiHandleEventCb(System_Event_t *evt) {
switch (evt->event) {
case EVENT_STAMODE_CONNECTED:
wifiState = wifiIsConnected;
wifiReason = 0;
os_printf("Wifi connected to ssid %s, ch %d\n", evt->event_info.connected.ssid,
evt->event_info.connected.channel);
statusWifiUpdate(wifiState);
break;
case EVENT_STAMODE_DISCONNECTED:
wifiState = wifiIsDisconnected;
wifiReason = evt->event_info.disconnected.reason;
os_printf("Wifi disconnected from ssid %s, reason %s (%d)\n",
evt->event_info.disconnected.ssid, wifiGetReason(), evt->event_info.disconnected.reason);
statusWifiUpdate(wifiState);
break;
case EVENT_STAMODE_AUTHMODE_CHANGE:
os_printf("Wifi auth mode: %d -> %d\n",
evt->event_info.auth_change.old_mode, evt->event_info.auth_change.new_mode);
break;
case EVENT_STAMODE_GOT_IP:
wifiState = wifiGotIP;
wifiReason = 0;
os_printf("Wifi got ip:" IPSTR ",mask:" IPSTR ",gw:" IPSTR "\n",
IP2STR(&evt->event_info.got_ip.ip), IP2STR(&evt->event_info.got_ip.mask),
IP2STR(&evt->event_info.got_ip.gw));
statusWifiUpdate(wifiState);
break;
case EVENT_SOFTAPMODE_STACONNECTED:
os_printf("Wifi AP: station " MACSTR " joined, AID = %d\n",
MAC2STR(evt->event_info.sta_connected.mac), evt->event_info.sta_connected.aid);
break;
case EVENT_SOFTAPMODE_STADISCONNECTED:
os_printf("Wifi AP: station " MACSTR " left, AID = %d\n",
MAC2STR(evt->event_info.sta_disconnected.mac), evt->event_info.sta_disconnected.aid);
break;
default:
break;
}
switch (evt->event) {
case EVENT_STAMODE_CONNECTED:
wifiState = wifiIsConnected;
wifiReason = 0;
os_printf("Wifi connected to ssid %s, ch %d\n", evt->event_info.connected.ssid,
evt->event_info.connected.channel);
statusWifiUpdate(wifiState);
break;
case EVENT_STAMODE_DISCONNECTED:
wifiState = wifiIsDisconnected;
wifiReason = evt->event_info.disconnected.reason;
os_printf("Wifi disconnected from ssid %s, reason %s (%d)\n",
evt->event_info.disconnected.ssid, wifiGetReason(), evt->event_info.disconnected.reason);
statusWifiUpdate(wifiState);
break;
case EVENT_STAMODE_AUTHMODE_CHANGE:
os_printf("Wifi auth mode: %d -> %d\n",
evt->event_info.auth_change.old_mode, evt->event_info.auth_change.new_mode);
break;
case EVENT_STAMODE_GOT_IP:
wifiState = wifiGotIP;
wifiReason = 0;
os_printf("Wifi got ip:" IPSTR ",mask:" IPSTR ",gw:" IPSTR "\n",
IP2STR(&evt->event_info.got_ip.ip), IP2STR(&evt->event_info.got_ip.mask),
IP2STR(&evt->event_info.got_ip.gw));
statusWifiUpdate(wifiState);
break;
case EVENT_SOFTAPMODE_STACONNECTED:
os_printf("Wifi AP: station " MACSTR " joined, AID = %d\n",
MAC2STR(evt->event_info.sta_connected.mac), evt->event_info.sta_connected.aid);
break;
case EVENT_SOFTAPMODE_STADISCONNECTED:
os_printf("Wifi AP: station " MACSTR " left, AID = %d\n",
MAC2STR(evt->event_info.sta_disconnected.mac), evt->event_info.sta_disconnected.aid);
break;
default:
break;
}
for (int i = 0; i < 4; i++) {
if (wifi_state_change_cb[i] != NULL) (wifi_state_change_cb[i])(wifiState);
@ -110,16 +110,16 @@ wifiAddStateChangeCb(WifiStateChangeCb cb) {
//WiFi access point data
typedef struct {
char ssid[32];
sint8 rssi;
char enc;
char ssid[32];
sint8 rssi;
char enc;
} ApData;
//Scan result
typedef struct {
char scanInProgress; //if 1, don't access the underlying stuff from the webpage.
ApData **apData;
int noAps;
char scanInProgress; //if 1, don't access the underlying stuff from the webpage.
ApData **apData;
int noAps;
} ScanResultData;
//Static scan status storage.
@ -128,109 +128,109 @@ static ScanResultData cgiWifiAps;
//Callback the code calls when a wlan ap scan is done. Basically stores the result in
//the cgiWifiAps struct.
void ICACHE_FLASH_ATTR wifiScanDoneCb(void *arg, STATUS status) {
int n;
struct bss_info *bss_link = (struct bss_info *)arg;
if (status!=OK) {
os_printf("wifiScanDoneCb status=%d\n", status);
cgiWifiAps.scanInProgress=0;
return;
}
//Clear prev ap data if needed.
if (cgiWifiAps.apData!=NULL) {
for (n=0; n<cgiWifiAps.noAps; n++) os_free(cgiWifiAps.apData[n]);
os_free(cgiWifiAps.apData);
}
//Count amount of access points found.
n=0;
while (bss_link != NULL) {
bss_link = bss_link->next.stqe_next;
n++;
}
//Allocate memory for access point data
cgiWifiAps.apData=(ApData **)os_malloc(sizeof(ApData *)*n);
cgiWifiAps.noAps=n;
os_printf("Scan done: found %d APs\n", n);
//Copy access point data to the static struct
n=0;
bss_link = (struct bss_info *)arg;
while (bss_link != NULL) {
if (n>=cgiWifiAps.noAps) {
//This means the bss_link changed under our nose. Shouldn't happen!
//Break because otherwise we will write in unallocated memory.
os_printf("Huh? I have more than the allocated %d aps!\n", cgiWifiAps.noAps);
break;
}
//Save the ap data.
cgiWifiAps.apData[n]=(ApData *)os_malloc(sizeof(ApData));
cgiWifiAps.apData[n]->rssi=bss_link->rssi;
cgiWifiAps.apData[n]->enc=bss_link->authmode;
strncpy(cgiWifiAps.apData[n]->ssid, (char*)bss_link->ssid, 32);
os_printf("bss%d: %s (%d)\n", n+1, (char*)bss_link->ssid, bss_link->rssi);
bss_link = bss_link->next.stqe_next;
n++;
}
//We're done.
cgiWifiAps.scanInProgress=0;
int n;
struct bss_info *bss_link = (struct bss_info *)arg;
if (status!=OK) {
os_printf("wifiScanDoneCb status=%d\n", status);
cgiWifiAps.scanInProgress=0;
return;
}
//Clear prev ap data if needed.
if (cgiWifiAps.apData!=NULL) {
for (n=0; n<cgiWifiAps.noAps; n++) os_free(cgiWifiAps.apData[n]);
os_free(cgiWifiAps.apData);
}
//Count amount of access points found.
n=0;
while (bss_link != NULL) {
bss_link = bss_link->next.stqe_next;
n++;
}
//Allocate memory for access point data
cgiWifiAps.apData=(ApData **)os_malloc(sizeof(ApData *)*n);
cgiWifiAps.noAps=n;
os_printf("Scan done: found %d APs\n", n);
//Copy access point data to the static struct
n=0;
bss_link = (struct bss_info *)arg;
while (bss_link != NULL) {
if (n>=cgiWifiAps.noAps) {
//This means the bss_link changed under our nose. Shouldn't happen!
//Break because otherwise we will write in unallocated memory.
os_printf("Huh? I have more than the allocated %d aps!\n", cgiWifiAps.noAps);
break;
}
//Save the ap data.
cgiWifiAps.apData[n]=(ApData *)os_malloc(sizeof(ApData));
cgiWifiAps.apData[n]->rssi=bss_link->rssi;
cgiWifiAps.apData[n]->enc=bss_link->authmode;
strncpy(cgiWifiAps.apData[n]->ssid, (char*)bss_link->ssid, 32);
os_printf("bss%d: %s (%d)\n", n+1, (char*)bss_link->ssid, bss_link->rssi);
bss_link = bss_link->next.stqe_next;
n++;
}
//We're done.
cgiWifiAps.scanInProgress=0;
}
static ETSTimer scanTimer;
static void ICACHE_FLASH_ATTR scanStartCb(void *arg) {
os_printf("Starting a scan\n");
wifi_station_scan(NULL, wifiScanDoneCb);
os_printf("Starting a scan\n");
wifi_station_scan(NULL, wifiScanDoneCb);
}
static int ICACHE_FLASH_ATTR cgiWiFiStartScan(HttpdConnData *connData) {
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
jsonHeader(connData, 200);
if (!cgiWifiAps.scanInProgress) {
cgiWifiAps.scanInProgress = 1;
os_timer_disarm(&scanTimer);
os_timer_setfn(&scanTimer, scanStartCb, NULL);
os_timer_arm(&scanTimer, 1000, 0);
}
return HTTPD_CGI_DONE;
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
jsonHeader(connData, 200);
if (!cgiWifiAps.scanInProgress) {
cgiWifiAps.scanInProgress = 1;
os_timer_disarm(&scanTimer);
os_timer_setfn(&scanTimer, scanStartCb, NULL);
os_timer_arm(&scanTimer, 1000, 0);
}
return HTTPD_CGI_DONE;
}
static int ICACHE_FLASH_ATTR cgiWiFiGetScan(HttpdConnData *connData) {
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
char buff[2048];
int len;
jsonHeader(connData, 200);
if (cgiWifiAps.scanInProgress==1) {
//We're still scanning. Tell Javascript code that.
len = os_sprintf(buff, "{\n \"result\": { \n\"inProgress\": \"1\"\n }\n}\n");
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
}
len = os_sprintf(buff, "{\"result\": {\"inProgress\": \"0\", \"APs\": [\n");
for (int pos=0; pos<cgiWifiAps.noAps; pos++) {
len += os_sprintf(buff+len, "{\"essid\": \"%s\", \"rssi\": %d, \"enc\": \"%d\"}%s\n",
cgiWifiAps.apData[pos]->ssid, cgiWifiAps.apData[pos]->rssi,
cgiWifiAps.apData[pos]->enc, (pos==cgiWifiAps.noAps-1)?"":",");
}
len += os_sprintf(buff+len, "]}}\n");
//os_printf("Sending %d bytes: %s\n", len, buff);
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
char buff[2048];
int len;
jsonHeader(connData, 200);
if (cgiWifiAps.scanInProgress==1) {
//We're still scanning. Tell Javascript code that.
len = os_sprintf(buff, "{\n \"result\": { \n\"inProgress\": \"1\"\n }\n}\n");
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
}
len = os_sprintf(buff, "{\"result\": {\"inProgress\": \"0\", \"APs\": [\n");
for (int pos=0; pos<cgiWifiAps.noAps; pos++) {
len += os_sprintf(buff+len, "{\"essid\": \"%s\", \"rssi\": %d, \"enc\": \"%d\"}%s\n",
cgiWifiAps.apData[pos]->ssid, cgiWifiAps.apData[pos]->rssi,
cgiWifiAps.apData[pos]->enc, (pos==cgiWifiAps.noAps-1)?"":",");
}
len += os_sprintf(buff+len, "]}}\n");
//os_printf("Sending %d bytes: %s\n", len, buff);
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
}
int ICACHE_FLASH_ATTR cgiWiFiScan(HttpdConnData *connData) {
if (connData->requestType == HTTPD_METHOD_GET) {
return cgiWiFiGetScan(connData);
} else if (connData->requestType == HTTPD_METHOD_POST) {
return cgiWiFiStartScan(connData);
} else {
jsonHeader(connData, 404);
return HTTPD_CGI_DONE;
}
if (connData->requestType == HTTPD_METHOD_GET) {
return cgiWiFiGetScan(connData);
} else if (connData->requestType == HTTPD_METHOD_POST) {
return cgiWiFiStartScan(connData);
} else {
jsonHeader(connData, 404);
return HTTPD_CGI_DONE;
}
}
// ===== timers to change state and rescue from failed associations
@ -243,31 +243,31 @@ static ETSTimer resetTimer;
// the connect succeeds, this gets the module in STA-only mode. If it fails, it ensures
// that the module is in STA+AP mode so the user has a chance to recover.
static void ICACHE_FLASH_ATTR resetTimerCb(void *arg) {
int x = wifi_station_get_connect_status();
int m = wifi_get_opmode() & 0x3;
os_printf("Wifi check: mode=%s status=%d\n", wifiMode[m], x);
int x = wifi_station_get_connect_status();
int m = wifi_get_opmode() & 0x3;
os_printf("Wifi check: mode=%s status=%d\n", wifiMode[m], x);
if (x == STATION_GOT_IP) {
if (m != 1) {
if (x == STATION_GOT_IP) {
if (m != 1) {
#ifdef CHANGE_TO_STA
// We're happily connected, go to STA mode
os_printf("Wifi got IP. Going into STA mode..\n");
wifi_set_opmode(1);
wifi_set_sleep_type(SLEEP_MODE);
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
// We're happily connected, go to STA mode
os_printf("Wifi got IP. Going into STA mode..\n");
wifi_set_opmode(1);
wifi_set_sleep_type(SLEEP_MODE);
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
#endif
}
log_uart(false);
// no more resetTimer at this point, gotta use physical reset to recover if in trouble
} else {
if (m != 3) {
os_printf("Wifi connect failed. Going into STA+AP mode..\n");
wifi_set_opmode(3);
}
log_uart(true);
os_printf("Enabling/continuing uart log\n");
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
}
}
log_uart(false);
// no more resetTimer at this point, gotta use physical reset to recover if in trouble
} else {
if (m != 3) {
os_printf("Wifi connect failed. Going into STA+AP mode..\n");
wifi_set_opmode(3);
}
log_uart(true);
os_printf("Enabling/continuing uart log\n");
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
}
}
// Temp store for new ap info.
@ -277,206 +277,206 @@ static ETSTimer reassTimer;
// Callback actually doing reassociation
static void ICACHE_FLASH_ATTR reassTimerCb(void *arg) {
os_printf("Wifi changing association\n");
wifi_station_disconnect();
stconf.bssid_set = 0;
wifi_station_set_config(&stconf);
wifi_station_connect();
// Schedule check
os_timer_disarm(&resetTimer);
os_timer_setfn(&resetTimer, resetTimerCb, NULL);
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
os_printf("Wifi changing association\n");
wifi_station_disconnect();
stconf.bssid_set = 0;
wifi_station_set_config(&stconf);
wifi_station_connect();
// Schedule check
os_timer_disarm(&resetTimer);
os_timer_setfn(&resetTimer, resetTimerCb, NULL);
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
}
// This cgi uses the routines above to connect to a specific access point with the
// given ESSID using the given password.
int ICACHE_FLASH_ATTR cgiWiFiConnect(HttpdConnData *connData) {
char essid[128];
char passwd[128];
if (connData->conn==NULL) return HTTPD_CGI_DONE;
int el = httpdFindArg(connData->getArgs, "essid", essid, sizeof(essid));
int pl = httpdFindArg(connData->getArgs, "passwd", passwd, sizeof(passwd));
if (el > 0 && pl >= 0) {
//Set to 0 if you want to disable the actual reconnecting bit
os_strncpy((char*)stconf.ssid, essid, 32);
os_strncpy((char*)stconf.password, passwd, 64);
os_printf("Wifi try to connect to AP %s pw %s\n", essid, passwd);
//Schedule disconnect/connect
os_timer_disarm(&reassTimer);
os_timer_setfn(&reassTimer, reassTimerCb, NULL);
os_timer_arm(&reassTimer, 1000, 0);
jsonHeader(connData, 200);
} else {
jsonHeader(connData, 400);
httpdSend(connData, "Cannot parse ssid or password", -1);
}
return HTTPD_CGI_DONE;
char essid[128];
char passwd[128];
if (connData->conn==NULL) return HTTPD_CGI_DONE;
int el = httpdFindArg(connData->getArgs, "essid", essid, sizeof(essid));
int pl = httpdFindArg(connData->getArgs, "passwd", passwd, sizeof(passwd));
if (el > 0 && pl >= 0) {
//Set to 0 if you want to disable the actual reconnecting bit
os_strncpy((char*)stconf.ssid, essid, 32);
os_strncpy((char*)stconf.password, passwd, 64);
os_printf("Wifi try to connect to AP %s pw %s\n", essid, passwd);
//Schedule disconnect/connect
os_timer_disarm(&reassTimer);
os_timer_setfn(&reassTimer, reassTimerCb, NULL);
os_timer_arm(&reassTimer, 1000, 0);
jsonHeader(connData, 200);
} else {
jsonHeader(connData, 400);
httpdSend(connData, "Cannot parse ssid or password", -1);
}
return HTTPD_CGI_DONE;
}
static bool parse_ip(char *buff, ip_addr_t *ip_ptr) {
char *next = buff; // where to start parsing next integer
int found = 0; // number of integers parsed
uint32_t ip = 0; // the ip addres parsed
for (int i=0; i<32; i++) { // 32 is just a safety limit
char c = buff[i];
if (c == '.' || c == 0) {
// parse the preceding integer and accumulate into IP address
bool last = c == 0;
buff[i] = 0;
uint32_t v = atoi(next);
ip = ip | ((v&0xff)<<(found*8));
next = buff+i+1; // next integer starts after the '.'
found++;
if (last) { // if at end of string we better got 4 integers
ip_ptr->addr = ip;
return found == 4;
}
continue;
}
if (c < '0' || c > '9') return false;
}
return false;
char *next = buff; // where to start parsing next integer
int found = 0; // number of integers parsed
uint32_t ip = 0; // the ip addres parsed
for (int i=0; i<32; i++) { // 32 is just a safety limit
char c = buff[i];
if (c == '.' || c == 0) {
// parse the preceding integer and accumulate into IP address
bool last = c == 0;
buff[i] = 0;
uint32_t v = atoi(next);
ip = ip | ((v&0xff)<<(found*8));
next = buff+i+1; // next integer starts after the '.'
found++;
if (last) { // if at end of string we better got 4 integers
ip_ptr->addr = ip;
return found == 4;
}
continue;
}
if (c < '0' || c > '9') return false;
}
return false;
}
#define DEBUGIP
#ifdef DEBUGIP
static void ICACHE_FLASH_ATTR debugIP() {
struct ip_info info;
if (wifi_get_ip_info(0, &info)) {
os_printf("\"ip\": \"%d.%d.%d.%d\"\n", IP2STR(&info.ip.addr));
os_printf("\"netmask\": \"%d.%d.%d.%d\"\n", IP2STR(&info.netmask.addr));
os_printf("\"gateway\": \"%d.%d.%d.%d\"\n", IP2STR(&info.gw.addr));
os_printf("\"hostname\": \"%s\"\n", wifi_station_get_hostname());
} else {
os_printf("\"ip\": \"-none-\"\n");
}
struct ip_info info;
if (wifi_get_ip_info(0, &info)) {
os_printf("\"ip\": \"%d.%d.%d.%d\"\n", IP2STR(&info.ip.addr));
os_printf("\"netmask\": \"%d.%d.%d.%d\"\n", IP2STR(&info.netmask.addr));
os_printf("\"gateway\": \"%d.%d.%d.%d\"\n", IP2STR(&info.gw.addr));
os_printf("\"hostname\": \"%s\"\n", wifi_station_get_hostname());
} else {
os_printf("\"ip\": \"-none-\"\n");
}
}
#endif
// configure Wifi, specifically DHCP vs static IP address based on flash config
static void ICACHE_FLASH_ATTR configWifiIP() {
if (flashConfig.staticip == 0) {
// let's DHCP!
wifi_station_set_hostname(flashConfig.hostname);
if (wifi_station_dhcpc_status() == DHCP_STARTED)
wifi_station_dhcpc_stop();
wifi_station_dhcpc_start();
os_printf("Wifi uses DHCP, hostname=%s\n", flashConfig.hostname);
} else {
// no DHCP, we got static network config!
wifi_station_dhcpc_stop();
struct ip_info ipi;
ipi.ip.addr = flashConfig.staticip;
ipi.netmask.addr = flashConfig.netmask;
ipi.gw.addr = flashConfig.gateway;
wifi_set_ip_info(0, &ipi);
os_printf("Wifi uses static IP %d.%d.%d.%d\n", IP2STR(&ipi.ip.addr));
}
if (flashConfig.staticip == 0) {
// let's DHCP!
wifi_station_set_hostname(flashConfig.hostname);
if (wifi_station_dhcpc_status() == DHCP_STARTED)
wifi_station_dhcpc_stop();
wifi_station_dhcpc_start();
os_printf("Wifi uses DHCP, hostname=%s\n", flashConfig.hostname);
} else {
// no DHCP, we got static network config!
wifi_station_dhcpc_stop();
struct ip_info ipi;
ipi.ip.addr = flashConfig.staticip;
ipi.netmask.addr = flashConfig.netmask;
ipi.gw.addr = flashConfig.gateway;
wifi_set_ip_info(0, &ipi);
os_printf("Wifi uses static IP %d.%d.%d.%d\n", IP2STR(&ipi.ip.addr));
}
#ifdef DEBUGIP
debugIP();
debugIP();
#endif
}
// Change special settings
int ICACHE_FLASH_ATTR cgiWiFiSpecial(HttpdConnData *connData) {
char dhcp[8];
char hostname[32];
char staticip[20];
char netmask[20];
char gateway[20];
if (connData->conn==NULL) return HTTPD_CGI_DONE;
// get args and their string lengths
int dl = httpdFindArg(connData->getArgs, "dhcp", dhcp, sizeof(dhcp));
int hl = httpdFindArg(connData->getArgs, "hostname", hostname, sizeof(hostname));
int sl = httpdFindArg(connData->getArgs, "staticip", staticip, sizeof(staticip));
int nl = httpdFindArg(connData->getArgs, "netmask", netmask, sizeof(netmask));
int gl = httpdFindArg(connData->getArgs, "gateway", gateway, sizeof(gateway));
if (!(dl > 0 && hl >= 0 && sl >= 0 && nl >= 0 && gl >= 0)) {
jsonHeader(connData, 400);
httpdSend(connData, "Request is missing fields", -1);
return HTTPD_CGI_DONE;
}
char url[64]; // redirect URL
if (os_strcmp(dhcp, "off") == 0) {
// parse static IP params
struct ip_info ipi;
bool ok = parse_ip(staticip, &ipi.ip);
if (nl > 0) ok = ok && parse_ip(netmask, &ipi.netmask);
else IP4_ADDR(&ipi.netmask, 255, 255, 255, 0);
if (gl > 0) ok = ok && parse_ip(gateway, &ipi.gw);
else ipi.gw.addr = 0;
if (!ok) {
jsonHeader(connData, 400);
httpdSend(connData, "Cannot parse static IP config", -1);
return HTTPD_CGI_DONE;
}
// save the params in flash
flashConfig.staticip = ipi.ip.addr;
flashConfig.netmask = ipi.netmask.addr;
flashConfig.gateway = ipi.gw.addr;
// construct redirect URL
os_sprintf(url, "{\"url\": \"http://%d.%d.%d.%d\"}", IP2STR(&ipi.ip));
} else {
// no static IP, set hostname
if (hl == 0) os_strcpy(hostname, "esp-link");
flashConfig.staticip = 0;
os_strcpy(flashConfig.hostname, hostname);
os_sprintf(url, "{\"url\": \"http://%s\"}", hostname);
}
configSave(); // ignore error...
// schedule change-over
os_timer_disarm(&reassTimer);
os_timer_setfn(&reassTimer, configWifiIP, NULL);
os_timer_arm(&reassTimer, 1000, 0);
// return redirect info
jsonHeader(connData, 200);
httpdSend(connData, url, -1);
return HTTPD_CGI_DONE;
char dhcp[8];
char hostname[32];
char staticip[20];
char netmask[20];
char gateway[20];
if (connData->conn==NULL) return HTTPD_CGI_DONE;
// get args and their string lengths
int dl = httpdFindArg(connData->getArgs, "dhcp", dhcp, sizeof(dhcp));
int hl = httpdFindArg(connData->getArgs, "hostname", hostname, sizeof(hostname));
int sl = httpdFindArg(connData->getArgs, "staticip", staticip, sizeof(staticip));
int nl = httpdFindArg(connData->getArgs, "netmask", netmask, sizeof(netmask));
int gl = httpdFindArg(connData->getArgs, "gateway", gateway, sizeof(gateway));
if (!(dl > 0 && hl >= 0 && sl >= 0 && nl >= 0 && gl >= 0)) {
jsonHeader(connData, 400);
httpdSend(connData, "Request is missing fields", -1);
return HTTPD_CGI_DONE;
}
char url[64]; // redirect URL
if (os_strcmp(dhcp, "off") == 0) {
// parse static IP params
struct ip_info ipi;
bool ok = parse_ip(staticip, &ipi.ip);
if (nl > 0) ok = ok && parse_ip(netmask, &ipi.netmask);
else IP4_ADDR(&ipi.netmask, 255, 255, 255, 0);
if (gl > 0) ok = ok && parse_ip(gateway, &ipi.gw);
else ipi.gw.addr = 0;
if (!ok) {
jsonHeader(connData, 400);
httpdSend(connData, "Cannot parse static IP config", -1);
return HTTPD_CGI_DONE;
}
// save the params in flash
flashConfig.staticip = ipi.ip.addr;
flashConfig.netmask = ipi.netmask.addr;
flashConfig.gateway = ipi.gw.addr;
// construct redirect URL
os_sprintf(url, "{\"url\": \"http://%d.%d.%d.%d\"}", IP2STR(&ipi.ip));
} else {
// no static IP, set hostname
if (hl == 0) os_strcpy(hostname, "esp-link");
flashConfig.staticip = 0;
os_strcpy(flashConfig.hostname, hostname);
os_sprintf(url, "{\"url\": \"http://%s\"}", hostname);
}
configSave(); // ignore error...
// schedule change-over
os_timer_disarm(&reassTimer);
os_timer_setfn(&reassTimer, configWifiIP, NULL);
os_timer_arm(&reassTimer, 1000, 0);
// return redirect info
jsonHeader(connData, 200);
httpdSend(connData, url, -1);
return HTTPD_CGI_DONE;
}
//This cgi changes the operating mode: STA / AP / STA+AP
int ICACHE_FLASH_ATTR cgiWiFiSetMode(HttpdConnData *connData) {
int len;
char buff[1024];
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
len=httpdFindArg(connData->getArgs, "mode", buff, sizeof(buff));
if (len!=0) {
int m = atoi(buff);
os_printf("Wifi switching to mode %d\n", m);
wifi_set_opmode(m&3);
if (m == 1) {
wifi_set_sleep_type(SLEEP_MODE);
// STA-only mode, reset into STA+AP after a timeout
os_timer_disarm(&resetTimer);
os_timer_setfn(&resetTimer, resetTimerCb, NULL);
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
}
jsonHeader(connData, 200);
} else {
jsonHeader(connData, 400);
}
return HTTPD_CGI_DONE;
int len;
char buff[1024];
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
len=httpdFindArg(connData->getArgs, "mode", buff, sizeof(buff));
if (len!=0) {
int m = atoi(buff);
os_printf("Wifi switching to mode %d\n", m);
wifi_set_opmode(m&3);
if (m == 1) {
wifi_set_sleep_type(SLEEP_MODE);
// STA-only mode, reset into STA+AP after a timeout
os_timer_disarm(&resetTimer);
os_timer_setfn(&resetTimer, resetTimerCb, NULL);
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
}
jsonHeader(connData, 200);
} else {
jsonHeader(connData, 400);
}
return HTTPD_CGI_DONE;
}
static char *connStatuses[] = { "idle", "connecting", "wrong password", "AP not found",
"failed", "got IP address" };
static char *wifiWarn[] = { 0,
"Switch to <a href=\\\"#\\\" onclick=\\\"changeWifiMode(3)\\\">STA+AP mode</a>",
"<b>Can't scan in this mode!</b> Switch to <a href=\\\"#\\\" onclick=\\\"changeWifiMode(3)\\\">STA+AP mode</a>",
"Switch to <a href=\\\"#\\\" onclick=\\\"changeWifiMode(1)\\\">STA mode</a>",
"Switch to <a href=\\\"#\\\" onclick=\\\"changeWifiMode(3)\\\">STA+AP mode</a>",
"<b>Can't scan in this mode!</b> Switch to <a href=\\\"#\\\" onclick=\\\"changeWifiMode(3)\\\">STA+AP mode</a>",
"Switch to <a href=\\\"#\\\" onclick=\\\"changeWifiMode(1)\\\">STA mode</a>",
};
#ifdef CHANGE_TO_STA
@ -487,109 +487,109 @@ static char *wifiWarn[] = { 0,
// print various Wifi information into json buffer
int ICACHE_FLASH_ATTR printWifiInfo(char *buff) {
int len;
struct station_config stconf;
wifi_station_get_config(&stconf);
uint8_t op = wifi_get_opmode() & 0x3;
char *mode = wifiMode[op];
char *status = "unknown";
int st = wifi_station_get_connect_status();
if (st >= 0 && st < sizeof(connStatuses)) status = connStatuses[st];
int p = wifi_get_phy_mode();
char *phy = wifiPhy[p&3];
char *warn = wifiWarn[op];
sint8 rssi = wifi_station_get_rssi();
if (rssi > 0) rssi = 0;
uint8 mac_addr[6];
wifi_get_macaddr(0, mac_addr);
uint8_t chan = wifi_get_channel();
len = os_sprintf(buff,
"\"mode\": \"%s\", \"modechange\": \"%s\", \"ssid\": \"%s\", \"status\": \"%s\", \"phy\": \"%s\", "
"\"rssi\": \"%ddB\", \"warn\": \"%s\", \"mac\":\"%02x:%02x:%02x:%02x:%02x:%02x\", \"chan\":%d",
mode, MODECHANGE, (char*)stconf.ssid, status, phy, rssi, warn,
mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5], chan);
struct ip_info info;
if (wifi_get_ip_info(0, &info)) {
len += os_sprintf(buff+len, ", \"ip\": \"%d.%d.%d.%d\"", IP2STR(&info.ip.addr));
len += os_sprintf(buff+len, ", \"netmask\": \"%d.%d.%d.%d\"", IP2STR(&info.netmask.addr));
len += os_sprintf(buff+len, ", \"gateway\": \"%d.%d.%d.%d\"", IP2STR(&info.gw.addr));
len += os_sprintf(buff+len, ", \"hostname\": \"%s\"", flashConfig.hostname);
} else {
len += os_sprintf(buff+len, ", \"ip\": \"-none-\"");
}
len += os_sprintf(buff+len, ", \"staticip\": \"%d.%d.%d.%d\"", IP2STR(&flashConfig.staticip));
len += os_sprintf(buff+len, ", \"dhcp\": \"%s\"", flashConfig.staticip > 0 ? "off" : "on");
return len;
int len;
struct station_config stconf;
wifi_station_get_config(&stconf);
uint8_t op = wifi_get_opmode() & 0x3;
char *mode = wifiMode[op];
char *status = "unknown";
int st = wifi_station_get_connect_status();
if (st >= 0 && st < sizeof(connStatuses)) status = connStatuses[st];
int p = wifi_get_phy_mode();
char *phy = wifiPhy[p&3];
char *warn = wifiWarn[op];
sint8 rssi = wifi_station_get_rssi();
if (rssi > 0) rssi = 0;
uint8 mac_addr[6];
wifi_get_macaddr(0, mac_addr);
uint8_t chan = wifi_get_channel();
len = os_sprintf(buff,
"\"mode\": \"%s\", \"modechange\": \"%s\", \"ssid\": \"%s\", \"status\": \"%s\", \"phy\": \"%s\", "
"\"rssi\": \"%ddB\", \"warn\": \"%s\", \"mac\":\"%02x:%02x:%02x:%02x:%02x:%02x\", \"chan\":%d",
mode, MODECHANGE, (char*)stconf.ssid, status, phy, rssi, warn,
mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5], chan);
struct ip_info info;
if (wifi_get_ip_info(0, &info)) {
len += os_sprintf(buff+len, ", \"ip\": \"%d.%d.%d.%d\"", IP2STR(&info.ip.addr));
len += os_sprintf(buff+len, ", \"netmask\": \"%d.%d.%d.%d\"", IP2STR(&info.netmask.addr));
len += os_sprintf(buff+len, ", \"gateway\": \"%d.%d.%d.%d\"", IP2STR(&info.gw.addr));
len += os_sprintf(buff+len, ", \"hostname\": \"%s\"", flashConfig.hostname);
} else {
len += os_sprintf(buff+len, ", \"ip\": \"-none-\"");
}
len += os_sprintf(buff+len, ", \"staticip\": \"%d.%d.%d.%d\"", IP2STR(&flashConfig.staticip));
len += os_sprintf(buff+len, ", \"dhcp\": \"%s\"", flashConfig.staticip > 0 ? "off" : "on");
return len;
}
int ICACHE_FLASH_ATTR cgiWiFiConnStatus(HttpdConnData *connData) {
char buff[1024];
int len;
char buff[1024];
int len;
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
jsonHeader(connData, 200);
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
jsonHeader(connData, 200);
len = os_sprintf(buff, "{");
len += printWifiInfo(buff+len);
len += os_sprintf(buff+len, ", ");
len = os_sprintf(buff, "{");
len += printWifiInfo(buff+len);
len += os_sprintf(buff+len, ", ");
if (wifiReason != 0) {
len += os_sprintf(buff+len, "\"reason\": \"%s\", ", wifiGetReason());
}
if (wifiReason != 0) {
len += os_sprintf(buff+len, "\"reason\": \"%s\", ", wifiGetReason());
}
#if 0
// commented out 'cause often the client that requested the change can't get a request in to
// find out that it succeeded. Better to just wait the std 15 seconds...
int st=wifi_station_get_connect_status();
if (st == STATION_GOT_IP) {
if (wifi_get_opmode() != 1) {
// Reset into AP-only mode sooner.
os_timer_disarm(&resetTimer);
os_timer_setfn(&resetTimer, resetTimerCb, NULL);
os_timer_arm(&resetTimer, 1000, 0);
}
}
// commented out 'cause often the client that requested the change can't get a request in to
// find out that it succeeded. Better to just wait the std 15 seconds...
int st=wifi_station_get_connect_status();
if (st == STATION_GOT_IP) {
if (wifi_get_opmode() != 1) {
// Reset into AP-only mode sooner.
os_timer_disarm(&resetTimer);
os_timer_setfn(&resetTimer, resetTimerCb, NULL);
os_timer_arm(&resetTimer, 1000, 0);
}
}
#endif
len += os_sprintf(buff+len, "\"x\":0}\n");
len += os_sprintf(buff+len, "\"x\":0}\n");
os_printf(" -> %s\n", buff);
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
os_printf(" -> %s\n", buff);
httpdSend(connData, buff, len);
return HTTPD_CGI_DONE;
}
// Cgi to return various Wifi information
int ICACHE_FLASH_ATTR cgiWifiInfo(HttpdConnData *connData) {
char buff[1024];
char buff[1024];
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
if (connData->conn==NULL) return HTTPD_CGI_DONE; // Connection aborted. Clean up.
os_strcpy(buff, "{");
printWifiInfo(buff+1);
os_strcat(buff, "}");
os_strcpy(buff, "{");
printWifiInfo(buff+1);
os_strcat(buff, "}");
jsonHeader(connData, 200);
httpdSend(connData, buff, -1);
return HTTPD_CGI_DONE;
jsonHeader(connData, 200);
httpdSend(connData, buff, -1);
return HTTPD_CGI_DONE;
}
// Init the wireless, which consists of setting a timer if we expect to connect to an AP
// so we can revert to STA+AP mode if we can't connect.
void ICACHE_FLASH_ATTR wifiInit() {
wifi_set_phy_mode(2);
int x = wifi_get_opmode() & 0x3;
os_printf("Wifi init, mode=%s\n", wifiMode[x]);
configWifiIP();
wifi_set_event_handler_cb(wifiHandleEventCb);
// check on the wifi in a few seconds to see whether we need to switch mode
os_timer_disarm(&resetTimer);
os_timer_setfn(&resetTimer, resetTimerCb, NULL);
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
wifi_set_phy_mode(2);
int x = wifi_get_opmode() & 0x3;
os_printf("Wifi init, mode=%s\n", wifiMode[x]);
configWifiIP();
wifi_set_event_handler_cb(wifiHandleEventCb);
// check on the wifi in a few seconds to see whether we need to switch mode
os_timer_disarm(&resetTimer);
os_timer_setfn(&resetTimer, resetTimerCb, NULL);
os_timer_arm(&resetTimer, RESET_TIMEOUT, 0);
}

@ -5,26 +5,27 @@
#include <osapi.h>
#include "config.h"
#include "espfs.h"
// hack: this from LwIP
extern uint16_t inet_chksum(void *dataptr, uint16_t len);
#include "crc16.h"
FlashConfig flashConfig;
FlashConfig flashDefault = {
33, 0, 0,
MCU_RESET_PIN, MCU_ISP_PIN, LED_CONN_PIN, LED_SERIAL_PIN,
115200,
"esp-link\0 ", // hostname
"esp-link\0", // hostname
0, 0x00ffffff, 0, // static ip, netmask, gateway
0, // log mode
0, // swap uart (don't by default)
1, 0, // tcp_enable, rssi_enable
"\0", // api_key
0, 0, 0, // slip_enable, mqtt_enable, mqtt_status_enable
1833, // mqtt port
"\0", "\0", "\0", "\0", "\0", // mqtt host, client, user, password, status-topic
};
typedef union {
FlashConfig fc;
uint8_t block[128];
uint8_t block[1024];
} FlashFull;
// magic number to recognize thet these are our flash settings as opposed to some random stuff
@ -63,7 +64,7 @@ bool ICACHE_FLASH_ATTR configSave(void) {
ff.fc.crc = 0;
//os_printf("cksum of: ");
//memDump(&ff, sizeof(ff));
ff.fc.crc = inet_chksum(&ff, sizeof(ff));
ff.fc.crc = crc16_data((unsigned char*)&ff, sizeof(ff), 0);
//os_printf("cksum is %04x\n", ff.fc.crc);
// write primary with incorrect seq
ff.fc.seq = 0xffffffff;
@ -121,12 +122,16 @@ static int ICACHE_FLASH_ATTR selectPrimary(FlashFull *ff0, FlashFull *ff1) {
// check CRC of ff0
uint16_t crc = ff0->fc.crc;
ff0->fc.crc = 0;
bool ff0_crc_ok = inet_chksum(ff0, sizeof(FlashFull)) == crc;
bool ff0_crc_ok = crc16_data((unsigned char*)ff0, sizeof(FlashFull), 0) == crc;
os_printf("FLASH chk=0x%04x crc=0x%04x full_sz=%d sz=%d\n",
crc16_data((unsigned char*)ff0, sizeof(FlashFull), 0),
crc, sizeof(FlashFull), sizeof(FlashConfig));
// check CRC of ff1
crc = ff1->fc.crc;
ff1->fc.crc = 0;
bool ff1_crc_ok = inet_chksum(ff1, sizeof(FlashFull)) == crc;
bool ff1_crc_ok = crc16_data((unsigned char*)ff1, sizeof(FlashFull), 0) == crc;
// decided which we like better
if (ff0_crc_ok)

@ -16,6 +16,11 @@ typedef struct {
uint8_t swap_uart; // swap uart0 to gpio 13&15
uint8_t tcp_enable, rssi_enable; // TCP client settings
char api_key[48]; // RSSI submission API key (Grovestreams for now)
uint8_t slip_enable, mqtt_enable, // SLIP protocol, MQTT client
mqtt_status_enable; // MQTT status reporting
uint16_t mqtt_port;
char mqtt_hostname[32], mqtt_client[48], mqtt_username[32], mqtt_password[32];
char mqtt_status_topic[32];
} FlashConfig;
extern FlashConfig flashConfig;

@ -17,6 +17,7 @@
#include "cgiwifi.h"
#include "cgipins.h"
#include "cgitcp.h"
#include "cgimqtt.h"
#include "cgiflash.h"
#include "auth.h"
#include "espfs.h"
@ -29,7 +30,7 @@
#include "log.h"
#include <gpio.h>
//#define SHOW_HEAP_USE
#define SHOW_HEAP_USE
//Function that tells the authentication system what users/passwords live on the system.
//This is disabled in the default build; if you want to try it, enable the authBasic line in
@ -90,6 +91,7 @@ HttpdBuiltInUrl builtInUrls[] = {
{ "/wifi/special", cgiWiFiSpecial, NULL },
{ "/pins", cgiPins, NULL },
{ "/tcpclient", cgiTcp, NULL },
{ "/mqtt", cgiMqtt, NULL },
{ "*", cgiEspFsHook, NULL }, //Catch-all cgi function for the filesystem
{ NULL, NULL, NULL }
@ -120,16 +122,22 @@ static char *rst_codes[] = {
# define VERS_STR(V) VERS_STR_STR(V)
char* esp_link_version = VERS_STR(VERSION);
//Main routine. Initialize stdout, the I/O, filesystem and the webserver and we're done.
extern void app_init(void);
// Main routine to initialize esp-link.
void user_init(void) {
uart_init(115200, 115200);
logInit(); // must come after init of uart
os_delay_us(10000L);
// get the flash config so we know how to init things
//configWipe(); // uncomment to reset the config for testing purposes
bool restoreOk = configRestore();
// init gpio pin registers
gpio_init();
gpio_output_set(0, 0, 0, (1<<15)); // some people tie it GND, gotta ensure it's disabled
// init UART
uart_init(flashConfig.baud_rate, 115200);
logInit(); // must come after init of uart
// uart_init(flashConfig.baud_rate, 115200);
// logInit(); // must come after init of uart
// say hello (leave some time to cause break in TX after boot loader's msg
os_delay_us(10000L);
os_printf("\n\n** %s\n", esp_link_version);
@ -163,6 +171,5 @@ void user_init(void) {
os_printf("** esp-link ready\n");
// call user_main init
init();
}
app_init();
}

@ -14,56 +14,56 @@ static ETSTimer ledTimer;
static void ICACHE_FLASH_ATTR setLed(int on) {
int8_t pin = flashConfig.conn_led_pin;
if (pin < 0) return; // disabled
// LED is active-low
if (on) {
gpio_output_set(0, (1<<pin), (1<<pin), 0);
} else {
gpio_output_set((1<<pin), 0, (1<<pin), 0);
}
// LED is active-low
if (on) {
gpio_output_set(0, (1<<pin), (1<<pin), 0);
} else {
gpio_output_set((1<<pin), 0, (1<<pin), 0);
}
}
static uint8_t ledState = 0;
// Timer callback to update the LED
static void ICACHE_FLASH_ATTR ledTimerCb(void *v) {
int time = 1000;
if (wifiState == wifiGotIP) {
// connected, all is good, solid light with a short dark blip every 3 seconds
ledState = 1-ledState;
time = ledState ? 2900 : 100;
} else if (wifiState == wifiIsConnected) {
// waiting for DHCP, go on/off every second
ledState = 1 - ledState;
time = 1000;
} else {
// not connected
switch (wifi_get_opmode()) {
case 1: // STA
ledState = 0;
break;
case 2: // AP
ledState = 1-ledState;
time = ledState ? 50 : 1950;
break;
case 3: // STA+AP
ledState = 1-ledState;
time = ledState ? 50 : 950;
break;
}
}
setLed(ledState);
os_timer_arm(&ledTimer, time, 0);
int time = 1000;
if (wifiState == wifiGotIP) {
// connected, all is good, solid light with a short dark blip every 3 seconds
ledState = 1-ledState;
time = ledState ? 2900 : 100;
} else if (wifiState == wifiIsConnected) {
// waiting for DHCP, go on/off every second
ledState = 1 - ledState;
time = 1000;
} else {
// not connected
switch (wifi_get_opmode()) {
case 1: // STA
ledState = 0;
break;
case 2: // AP
ledState = 1-ledState;
time = ledState ? 50 : 1950;
break;
case 3: // STA+AP
ledState = 1-ledState;
time = ledState ? 50 : 950;
break;
}
}
setLed(ledState);
os_timer_arm(&ledTimer, time, 0);
}
// change the wifi state indication
void ICACHE_FLASH_ATTR statusWifiUpdate(uint8_t state) {
wifiState = state;
// schedule an update (don't want to run into concurrency issues)
os_timer_disarm(&ledTimer);
os_timer_setfn(&ledTimer, ledTimerCb, NULL);
os_timer_arm(&ledTimer, 500, 0);
wifiState = state;
// schedule an update (don't want to run into concurrency issues)
os_timer_disarm(&ledTimer);
os_timer_setfn(&ledTimer, ledTimerCb, NULL);
os_timer_arm(&ledTimer, 500, 0);
}
//===== RSSI Status update sent to GroveStreams
@ -76,59 +76,59 @@ static ETSTimer rssiTimer;
// Timer callback to send an RSSI update to a monitoring system
static void ICACHE_FLASH_ATTR rssiTimerCb(void *v) {
if (!flashConfig.rssi_enable || !flashConfig.tcp_enable || flashConfig.api_key[0]==0)
return;
sint8 rssi = wifi_station_get_rssi();
os_printf("timer rssi=%d\n", rssi);
if (rssi >= 0) return; // not connected or other error
// compose TCP command
uint8_t chan = MAX_TCP_CHAN-1;
tcpClientCommand(chan, 'T', "grovestreams.com:80");
// compose http header
char buf[1024];
int hdrLen = os_sprintf(buf,
"PUT /api/feed?api_key=%s HTTP/1.0\r\n"
"Content-Type: application/json\r\n"
"Content-Length: XXXXX\r\n\r\n",
flashConfig.api_key);
// http body
int dataLen = os_sprintf(buf+hdrLen,
"[{\"compId\":\"%s\", \"streamId\":\"%s\", \"data\":%d}]\r",
flashConfig.hostname, GS_STREAM, rssi);
buf[hdrLen+dataLen++] = 0;
buf[hdrLen+dataLen++] = '\n';
// hackish way to fill in the content-length
os_sprintf(buf+hdrLen-9, "%5d", dataLen);
buf[hdrLen-4] = '\r'; // fix-up the \0 inserted by sprintf (hack!)
// send the request off and forget about it...
for (short i=0; i<hdrLen+dataLen; i++) {
tcpClientSendChar(chan, buf[i]);
}
tcpClientSendPush(chan);
if (!flashConfig.rssi_enable || !flashConfig.tcp_enable || flashConfig.api_key[0]==0)
return;
sint8 rssi = wifi_station_get_rssi();
os_printf("timer rssi=%d\n", rssi);
if (rssi >= 0) return; // not connected or other error
// compose TCP command
uint8_t chan = MAX_TCP_CHAN-1;
tcpClientCommand(chan, 'T', "grovestreams.com:80");
// compose http header
char buf[1024];
int hdrLen = os_sprintf(buf,
"PUT /api/feed?api_key=%s HTTP/1.0\r\n"
"Content-Type: application/json\r\n"
"Content-Length: XXXXX\r\n\r\n",
flashConfig.api_key);
// http body
int dataLen = os_sprintf(buf+hdrLen,
"[{\"compId\":\"%s\", \"streamId\":\"%s\", \"data\":%d}]\r",
flashConfig.hostname, GS_STREAM, rssi);
buf[hdrLen+dataLen++] = 0;
buf[hdrLen+dataLen++] = '\n';
// hackish way to fill in the content-length
os_sprintf(buf+hdrLen-9, "%5d", dataLen);
buf[hdrLen-4] = '\r'; // fix-up the \0 inserted by sprintf (hack!)
// send the request off and forget about it...
for (short i=0; i<hdrLen+dataLen; i++) {
tcpClientSendChar(chan, buf[i]);
}
tcpClientSendPush(chan);
}
//===== Init status stuff
void ICACHE_FLASH_ATTR statusInit(void) {
if (flashConfig.conn_led_pin >= 0) {
makeGpio(flashConfig.conn_led_pin);
setLed(1);
}
os_printf("CONN led=%d\n", flashConfig.conn_led_pin);
os_timer_disarm(&ledTimer);
os_timer_setfn(&ledTimer, ledTimerCb, NULL);
os_timer_arm(&ledTimer, 2000, 0);
os_timer_disarm(&rssiTimer);
os_timer_setfn(&rssiTimer, rssiTimerCb, NULL);
os_timer_arm(&rssiTimer, RSSI_INTERVAL, 1); // recurring timer
if (flashConfig.conn_led_pin >= 0) {
makeGpio(flashConfig.conn_led_pin);
setLed(1);
}
os_printf("CONN led=%d\n", flashConfig.conn_led_pin);
os_timer_disarm(&ledTimer);
os_timer_setfn(&ledTimer, ledTimerCb, NULL);
os_timer_arm(&ledTimer, 2000, 0);
os_timer_disarm(&rssiTimer);
os_timer_setfn(&rssiTimer, rssiTimerCb, NULL);
os_timer_arm(&rssiTimer, RSSI_INTERVAL, 1); // recurring timer
}

@ -20,7 +20,7 @@
<script type="text/javascript">console_url = "/console/text"</script>
<script src="console.js"></script>
<script type="text/javascript">
var rates = [57600, 115200, 230400, 460800];
var rates = [9600, 57600, 115200, 250000];
onLoad(function() {
fetchText(100, true);

@ -0,0 +1,99 @@
<div id="main">
<div class="header">
<h1>REST &amp; MQTT</h1>
</div>
<div class="content">
<div class="pure-g">
<div class="pure-u-1"><div class="card">
<p>The REST &amp; MQTT support uses the SLIP protocol over the serial port to enable
the attached microcontroller to initiate outbound connections.
The REST support lets the uC initiate simple HTTP requests while the MQTT support
lets it communicate with an MQTT server bidirectionally at QoS 0 thru 2.</p>
<p>The MQTT support is in the form of a built-in client that connects to a server
using parameters set below and stored in esp-link's flash settings. This allows
esp-link to take care of connection parameters and disconnect/reconnect operations.</p>
<p>The MQTT client also supports sending periodic status messages about esp-link itself,
including Wifi RSSI, and free heap memory.</p>
<div class="form-horizontal">
<input type="checkbox" name="slip-enable"/>
<label>Enable SLIP on serial port</label>
</div>
</div></div>
</div>
<div class="pure-g">
<div class="pure-u-1 pure-u-md-1-2">
<div class="card">
<h1>MQTT
<div id="mqtt-spinner" class="spinner spinner-small"></div>
</h1>
<form action="#" id="mqtt-form" class="pure-form" hidden>
<div class="form-horizontal">
<input type="checkbox" name="mqtt-enable"/>
<label>Enable MQTT client</label>
</div>
<div class="form-horizontal">
<label>MQTT client state: </label>
<b id="mqtt-state"></b>
</div>
<br>
<legend>MQTT server settings</legend>
<div class="pure-form-stacked">
<label>Server hostname/ip</label>
<input type="text" name="mqtt-host"/>
<label>Server port/ip</label>
<input type="text" name="mqtt-port"/>
<label>Client ID</label>
<input type="text" name="mqtt-client-id"/>
<label>Username</label>
<input type="text" name="mqtt-username"/>
<label>Password</label>
<input type="password" name="mqtt-password"/>
</div>
<button id="mqtt-button" type="submit" class="pure-button button-primary">
Update server settings!
</button>
</form>
</div>
</div>
<div class="pure-u-1 pure-u-md-1-2">
<div class="card">
<h1>Status reporting
<div id="mqtt-status-spinner" class="spinner spinner-small"></div>
</h1>
<form action="#" id="mqtt-status-form" class="pure-form" hidden>
<div class="form-horizontal">
<input type="checkbox" name="mqtt-status-enable"/>
<label>Enable status reporting via MQTT</label>
</div>
<br>
<legend>Status reporting settings</legend>
<div class="pure-form-stacked">
<label>Topic prefix</label>
<input type="text" name="mqtt-status-topic"/>
Suffixes: rssi, heap-free, ...
</div>
<button id="mqtt-status-button" type="submit" class="pure-button button-primary">
Update status settings!
</button>
</form>
</div>
<div class="card">
<h1>REST</h1>
<p>REST requests are enabled as soon as SLIP is enabled.
There are no REST-specific settings.</p>
</div>
</div>
</div>
</div>
</div>
</div>
<script type="text/javascript">
onLoad(function() {
fetchMqtt();
bnd($("#mqtt-form"), "submit", changeMqtt);
bnd($("#mqtt-status-form"), "submit", changeMqttStatus);
});
</script>
</body></html>

@ -3,6 +3,10 @@ html, button, input, select, textarea, .pure-g [class *= "pure-u"] {
font-family: sans-serif;
}
input[type="text"], input[type="password"] {
width: 100%;
}
body {
color: #777;
}

@ -316,44 +316,44 @@ function createInputForPin(pin) {
input.type = "radio";
input.name = "pins";
input.data = pin.name;
input.className = "pin-input";
input.className = "pin-input";
input.value= pin.value;
input.id = "opt-" + pin.value;
if (currPin == pin.name) input.checked = "1";
var descr = m('<label for="opt-'+pin.value+'"><b>'+pin.name+":</b>"+pin.descr+"</label>");
var div = document.createElement("div");
div.appendChild(input);
div.appendChild(descr);
return div;
var descr = m('<label for="opt-'+pin.value+'"><b>'+pin.name+":</b>"+pin.descr+"</label>");
var div = document.createElement("div");
div.appendChild(input);
div.appendChild(descr);
return div;
}
function displayPins(resp) {
var po = $("#pin-mux");
po.innerHTML = "";
currPin = resp.curr;
resp.map.forEach(function(v) {
po.appendChild(createInputForPin(v));
});
var i, inputs = $(".pin-input");
for (i=0; i<inputs.length; i++) {
inputs[i].onclick = function() { setPins(this.value, this.data) };
};
var po = $("#pin-mux");
po.innerHTML = "";
currPin = resp.curr;
resp.map.forEach(function(v) {
po.appendChild(createInputForPin(v));
});
var i, inputs = $(".pin-input");
for (i=0; i<inputs.length; i++) {
inputs[i].onclick = function() { setPins(this.value, this.data) };
};
}
function fetchPins() {
ajaxJson("GET", "/pins", displayPins, function() {
window.setTimeout(fetchPins, 1000);
});
window.setTimeout(fetchPins, 1000);
});
}
function setPins(v, name) {
ajaxSpin("POST", "/pins?map="+v, function() {
showNotification("Pin assignment changed to " + name);
}, function() {
showNotification("Pin assignment change failed");
window.setTimeout(fetchPins, 100);
});
showNotification("Pin assignment changed to " + name);
}, function() {
showNotification("Pin assignment change failed");
window.setTimeout(fetchPins, 100);
});
}
//===== TCP client card
@ -374,11 +374,11 @@ function changeTcpClient(e) {
addClass(cb, 'pure-button-disabled');
ajaxSpin("POST", url, function(resp) {
removeClass(cb, 'pure-button-disabled');
getWifiInfo();
fetchTcpClient();
}, function(s, st) {
showWarning("Error: "+st);
removeClass(cb, 'pure-button-disabled');
getWifiInfo();
fetchTcpClient();
});
}
@ -390,8 +390,84 @@ function displayTcpClient(resp) {
function fetchTcpClient() {
ajaxJson("GET", "/tcpclient", displayTcpClient, function() {
window.setTimeout(fetchTcpClient, 1000);
});
window.setTimeout(fetchTcpClient, 1000);
});
}
//===== MQTT cards
function changeMqtt(e) {
e.preventDefault();
var url = "mqtt?1=1";
var i, inputs = document.querySelectorAll('#mqtt-form input');
for (i=0; i<inputs.length; i++) {
if (inputs[i].type != "checkbox")
url += "&" + inputs[i].name + "=" + inputs[i].value;
};
hideWarning();
var cb = $("#mqtt-button");
addClass(cb, 'pure-button-disabled');
ajaxSpin("POST", url, function(resp) {
showNotification("MQTT updated");
removeClass(cb, 'pure-button-disabled');
}, function(s, st) {
showWarning("Error: "+st);
removeClass(cb, 'pure-button-disabled');
window.setTimeout(fetchMqtt, 100);
});
}
function displayMqtt(data) {
Object.keys(data).forEach(function(v) {
el = $("#" + v);
if (el != null) {
if (el.nodeName === "INPUT") el.value = data[v];
else el.innerHTML = data[v];
return;
}
el = document.querySelector('input[name="' + v + '"]');
if (el != null) {
if (el.type == "checkbox") el.checked = data[v] > 0;
else el.value = data[v];
}
});
$("#mqtt-spinner").setAttribute("hidden", "");
$("#mqtt-status-spinner").setAttribute("hidden", "");
$("#mqtt-form").removeAttribute("hidden");
$("#mqtt-status-form").removeAttribute("hidden");
var i, inputs = $("input");
for (i=0; i<inputs.length; i++) {
if (inputs[i].type == "checkbox")
inputs[i].onclick = function() { console.log(this); setMqtt(this.name, this.checked) };
}
}
function fetchMqtt() {
ajaxJson("GET", "/mqtt", displayMqtt, function() {
window.setTimeout(fetchMqtt, 1000);
});
}
function changeMqttStatus(e) {
e.preventDefault();
var v = document.querySelector('input[name="mqtt-status-topic"]').value;
ajaxSpin("POST", "/mqtt?mqtt-status-topic=" + v, function() {
showNotification("MQTT status settings updated");
}, function(s, st) {
showWarning("Error: "+st);
window.setTimeout(fetchMqtt, 100);
});
}
function setMqtt(name, v) {
ajaxSpin("POST", "/mqtt?" + name + "=" + (v ? 1 : 0), function() {
var n = name.replace("-enable", "");
showNotification(n + " is now " + (v ? "enabled" : "disabled"));
}, function() {
showWarning("Enable/disable failed");
window.setTimeout(fetchMqtt, 100);
});
}

@ -191,7 +191,7 @@ int ICACHE_FLASH_ATTR httpdFindArg(char *line, char *arg, char *buff, int buffLe
p=(char*)os_strstr(p, "&");
if (p!=NULL) p+=1;
}
os_printf("Finding %s in %s: Not found :/\n", arg, line);
//os_printf("Finding %s in %s: Not found :/\n", arg, line);
return -1; //not found
}
@ -521,7 +521,7 @@ static void ICACHE_FLASH_ATTR httpdDisconCb(void *arg) {
}
// Callback indicating a failure in the connection. "Recon" is probably intended in the sense
// of "you need to reconnect". Sigh... Note that there is no DiconCb after ReconCb
// of "you need to reconnect". Sigh... Note that there is no DisconCb after ReconCb
static void ICACHE_FLASH_ATTR httpdReconCb(void *arg, sint8 err) {
debugConn(arg, "httpdReconCb");
HttpdConnData *conn = httpdFindConnData(arg);

File diff suppressed because it is too large Load Diff

@ -27,117 +27,101 @@
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef USER_AT_MQTT_H_
#define USER_AT_MQTT_H_
#ifndef MQTT_H_
#define MQTT_H_
#include <esp8266.h>
#include "mqtt_msg.h"
#include "queue.h"
#include "pktbuf.h"
typedef struct mqtt_event_data_t {
uint8_t type;
const char* topic;
const char* data;
uint16_t topic_length;
uint16_t data_length;
uint16_t data_offset;
} mqtt_event_data_t;
typedef struct mqtt_state_t {
uint16_t port;
int auto_reconnect;
mqtt_connect_info_t* connect_info;
uint8_t* in_buffer;
uint8_t* out_buffer;
int in_buffer_length;
int out_buffer_length;
uint16_t message_length;
uint16_t message_length_read;
mqtt_message_t* outbound_message;
mqtt_connection_t mqtt_connection;
uint16_t pending_msg_id;
int pending_msg_type;
int pending_publish_qos;
} mqtt_state_t;
// in rest.c
uint8_t UTILS_StrToIP(const char* str, void *ip);
// State of MQTT connection
typedef enum {
WIFI_INIT,
WIFI_CONNECTING,
WIFI_CONNECTING_ERROR,
WIFI_CONNECTED,
DNS_RESOLVE,
TCP_DISCONNECTED,
TCP_RECONNECT_REQ,
TCP_RECONNECT,
TCP_CONNECTING,
TCP_CONNECTING_ERROR,
TCP_CONNECTED,
MQTT_CONNECT_SEND,
MQTT_CONNECT_SENDING,
MQTT_SUBSCIBE_SEND,
MQTT_SUBSCIBE_SENDING,
MQTT_DATA,
MQTT_PUBLISH_RECV,
MQTT_PUBLISHING
MQTT_DISCONNECTED, // we're in disconnected state
TCP_RECONNECT_REQ, // connect failed, needs reconnecting
TCP_CONNECTING, // in TCP connection process
MQTT_CONNECTED, // conneted (or connecting)
} tConnState;
// Simple notification callback
typedef void (*MqttCallback)(uint32_t* args);
typedef void (*MqttDataCallback)(uint32_t* args, const char* topic, uint32_t topic_len, const char* data, uint32_t lengh);
// Callback with data messge
typedef void (*MqttDataCallback)(uint32_t* args, const char* topic, uint32_t topic_len,
const char* data, uint32_t data_len);
// MQTTY client data structure
typedef struct {
struct espconn* pCon;
uint8_t security;
char* host;
uint32_t port;
ip_addr_t ip;
mqtt_state_t mqtt_state;
mqtt_connect_info_t connect_info;
MqttCallback connectedCb;
MqttCallback cmdConnectedCb;
MqttCallback disconnectedCb;
MqttCallback cmdDisconnectedCb;
MqttCallback tcpDisconnectedCb;
MqttCallback cmdTcpDisconnectedCb;
MqttCallback publishedCb;
MqttCallback cmdPublishedCb;
MqttDataCallback dataCb;
MqttDataCallback cmdDataCb;
ETSTimer mqttTimer;
uint32_t keepAliveTick;
uint32_t reconnectTick;
uint32_t sendTimeout;
tConnState connState;
QUEUE msgQueue;
void* user_data;
struct espconn* pCon; // socket
// connection information
char* host; // MQTT server
uint16_t port;
uint8_t security; // 0=tcp, 1=ssl
ip_addr_t ip; // MQTT server IP address
mqtt_connect_info_t connect_info; // info to connect/reconnect
// protocol state and message assembly
tConnState connState; // connection state
bool sending; // espconn_send is pending
mqtt_connection_t mqtt_connection; // message assembly descriptor
PktBuf* msgQueue; // queued outbound messages
// TCP input buffer
uint8_t* in_buffer;
int in_buffer_size; // length allocated
int in_buffer_filled; // number of bytes held
// outstanding message when we expect an ACK
PktBuf* pending_buffer; // buffer sent and awaiting ACK
PktBuf* sending_buffer; // buffer sent not awaiting ACK
// timer and associated timeout counters
ETSTimer mqttTimer; // timer for this connection
uint8_t keepAliveTick; // seconds 'til keep-alive is required (0=no k-a)
uint8_t keepAliveAckTick; // seconds 'til keep-alive ack is overdue (0=no k-a)
uint8_t timeoutTick; // seconds 'til other timeout
uint8_t sendTimeout; // value of send timeout setting
// callbacks
MqttCallback connectedCb;
MqttCallback cmdConnectedCb;
MqttCallback disconnectedCb;
MqttCallback cmdDisconnectedCb;
MqttCallback tcpDisconnectedCb;
MqttCallback cmdTcpDisconnectedCb;
MqttCallback publishedCb;
MqttCallback cmdPublishedCb;
MqttDataCallback dataCb;
MqttDataCallback cmdDataCb;
// misc
void* user_data;
} MQTT_Client;
#define SEC_NONSSL 0
#define SEC_SSL 1
// Initialize client data structure
void MQTT_Init(MQTT_Client* mqttClient, char* host, uint32 port,
uint8_t security, uint8_t sendTimeout,
char* client_id, char* client_user, char* client_pass,
uint8_t keepAliveTime, uint8_t cleanSession);
// Set Last Will Topic on client, must be called before MQTT_InitConnection
void MQTT_InitLWT(MQTT_Client* mqttClient, char* will_topic, char* will_msg,
uint8_t will_qos, uint8_t will_retain);
// Kick of a persistent connection to the broker, will reconnect anytime conn breaks
void MQTT_Connect(MQTT_Client* mqttClient);
// Kill persistent connection
void MQTT_Disconnect(MQTT_Client* mqttClient);
#define MQTT_FLAG_CONNECTED 1
#define MQTT_FLAG_READY 2
#define MQTT_FLAG_EXIT 4
// Subscribe to a topic
bool MQTT_Subscribe(MQTT_Client* client, char* topic, uint8_t qos);
#define MQTT_EVENT_TYPE_NONE 0
#define MQTT_EVENT_TYPE_CONNECTED 1
#define MQTT_EVENT_TYPE_DISCONNECTED 2
#define MQTT_EVENT_TYPE_SUBSCRIBED 3
#define MQTT_EVENT_TYPE_UNSUBSCRIBED 4
#define MQTT_EVENT_TYPE_PUBLISH 5
#define MQTT_EVENT_TYPE_PUBLISHED 6
#define MQTT_EVENT_TYPE_EXITED 7
#define MQTT_EVENT_TYPE_PUBLISH_CONTINUATION 8
// Publish a message
bool MQTT_Publish(MQTT_Client* client, const char* topic, const char* data,
uint8_t qos, uint8_t retain);
void MQTT_InitConnection(MQTT_Client* mqttClient, char* host, uint32 port, uint8_t security);
void MQTT_InitClient(MQTT_Client* mqttClient, char* client_id, char* client_user, char* client_pass, uint8_t keepAliveTime, uint8_t cleanSession);
void MQTT_InitLWT(MQTT_Client* mqttClient, char* will_topic, char* will_msg, uint8_t will_qos, uint8_t will_retain);
// Callback when connected
void MQTT_OnConnected(MQTT_Client* mqttClient, MqttCallback connectedCb);
// Callback when disconnected
void MQTT_OnDisconnected(MQTT_Client* mqttClient, MqttCallback disconnectedCb);
// Callback when publish succeeded
void MQTT_OnPublished(MQTT_Client* mqttClient, MqttCallback publishedCb);
// Callback when data arrives for subscription
void MQTT_OnData(MQTT_Client* mqttClient, MqttDataCallback dataCb);
bool MQTT_Subscribe(MQTT_Client* client, char* topic, uint8_t qos);
void MQTT_Connect(MQTT_Client* mqttClient);
void MQTT_Disconnect(MQTT_Client* mqttClient);
bool MQTT_Publish(MQTT_Client* client, const char* topic, const char* data, uint8_t qos, uint8_t retain);
#endif /* USER_AT_MQTT_H_ */

@ -1,8 +1,10 @@
#include <esp8266.h>
#include "mqtt.h"
#include "mqtt_cmd.h"
uint32_t connectedCb = 0, disconnectCb = 0, tcpDisconnectedCb = 0, publishedCb = 0, dataCb = 0;
void ICACHE_FLASH_ATTR
void ICACHE_FLASH_ATTR
cmdMqttConnectedCb(uint32_t* args) {
MQTT_Client* client = (MQTT_Client*)args;
MqttCmdCb* cb = (MqttCmdCb*)client->user_data;
@ -24,7 +26,7 @@ cmdMqttTcpDisconnectedCb(uint32_t *args) {
CMD_ResponseEnd(crc);
}
void ICACHE_FLASH_ATTR
void ICACHE_FLASH_ATTR
cmdMqttDisconnectedCb(uint32_t* args) {
MQTT_Client* client = (MQTT_Client*)args;
MqttCmdCb* cb = (MqttCmdCb*)client->user_data;
@ -33,7 +35,7 @@ cmdMqttDisconnectedCb(uint32_t* args) {
CMD_ResponseEnd(crc);
}
void ICACHE_FLASH_ATTR
void ICACHE_FLASH_ATTR
cmdMqttPublishedCb(uint32_t* args) {
MQTT_Client* client = (MQTT_Client*)args;
MqttCmdCb* cb = (MqttCmdCb*)client->user_data;
@ -42,7 +44,7 @@ cmdMqttPublishedCb(uint32_t* args) {
CMD_ResponseEnd(crc);
}
void ICACHE_FLASH_ATTR
void ICACHE_FLASH_ATTR
cmdMqttDataCb(uint32_t* args, const char* topic, uint32_t topic_len, const char* data, uint32_t data_len) {
uint16_t crc = 0;
MQTT_Client* client = (MQTT_Client*)args;
@ -54,7 +56,7 @@ cmdMqttDataCb(uint32_t* args, const char* topic, uint32_t topic_len, const char*
CMD_ResponseEnd(crc);
}
uint32_t ICACHE_FLASH_ATTR
uint32_t ICACHE_FLASH_ATTR
MQTTCMD_Setup(CmdPacket *cmd) {
CmdRequest req;
CMD_Request(&req, cmd);
@ -65,10 +67,12 @@ MQTTCMD_Setup(CmdPacket *cmd) {
// create mqtt client
uint8_t clientLen = sizeof(MQTT_Client);
MQTT_Client* client = (MQTT_Client*)os_zalloc(clientLen);
if (client == NULL)
return 0;
if (client == NULL) return 0;
os_memset(client, 0, clientLen);
return 0;
#if 0
uint16_t len;
uint8_t *client_id, *user_data, *pass_data;
uint32_t keepalive, clean_session, cb_data;
@ -102,7 +106,7 @@ MQTTCMD_Setup(CmdPacket *cmd) {
os_printf("MQTT: MQTTCMD_Setup clientid=%s, user=%s, pw=%s, keepalive=%ld, clean_session=%ld\n", client_id, user_data, pass_data, keepalive, clean_session);
// init client
// init client
// TODO: why malloc these all here, pass to MQTT_InitClient to be malloc'd again?
MQTT_InitClient(client, (char*)client_id, (char*)user_data, (char*)pass_data, keepalive, clean_session);
@ -112,11 +116,11 @@ MQTTCMD_Setup(CmdPacket *cmd) {
CMD_PopArg(&req, (uint8_t*)&cb_data, 4);
callback->connectedCb = cb_data;
CMD_PopArg(&req, (uint8_t*)&cb_data, 4);
callback->disconnectedCb = cb_data;
callback->disconnectedCb = cb_data;
CMD_PopArg(&req, (uint8_t*)&cb_data, 4);
callback->publishedCb = cb_data;
CMD_PopArg(&req, (uint8_t*)&cb_data, 4);
callback->dataCb = cb_data;
callback->dataCb = cb_data;
client->user_data = callback;
@ -136,9 +140,10 @@ MQTTCMD_Setup(CmdPacket *cmd) {
os_free(pass_data);
return (uint32_t)client;
#endif
}
uint32_t ICACHE_FLASH_ATTR
uint32_t ICACHE_FLASH_ATTR
MQTTCMD_Lwt(CmdPacket *cmd) {
CmdRequest req;
CMD_Request(&req, cmd);
@ -153,7 +158,7 @@ MQTTCMD_Lwt(CmdPacket *cmd) {
os_printf("MQTT: MQTTCMD_Lwt client ptr=%p\n", (void*)client_ptr);
uint16_t len;
// get topic
if (client->connect_info.will_topic)
os_free(client->connect_info.will_topic);
@ -174,7 +179,7 @@ MQTTCMD_Lwt(CmdPacket *cmd) {
// get qos
CMD_PopArg(&req, (uint8_t*)&client->connect_info.will_qos, 4);
// get retain
CMD_PopArg(&req, (uint8_t*)&client->connect_info.will_retain, 4);
@ -186,13 +191,13 @@ MQTTCMD_Lwt(CmdPacket *cmd) {
return 1;
}
uint32_t ICACHE_FLASH_ATTR
uint32_t ICACHE_FLASH_ATTR
MQTTCMD_Connect(CmdPacket *cmd) {
CmdRequest req;
CMD_Request(&req, cmd);
if (CMD_GetArgc(&req) != 4)
return 0;
return 0;
// get mqtt client
uint32_t client_ptr;
@ -202,7 +207,7 @@ MQTTCMD_Connect(CmdPacket *cmd) {
uint16_t len;
// get host
// get host
if (client->host)
os_free(client->host);
len = CMD_ArgLen(&req);
@ -217,7 +222,7 @@ MQTTCMD_Connect(CmdPacket *cmd) {
// get security
CMD_PopArg(&req, (uint8_t*)&client->security, 4);
os_printf("MQTT: MQTTCMD_Connect host=%s, port=%ld, security=%d\n",
os_printf("MQTT: MQTTCMD_Connect host=%s, port=%d, security=%d\n",
client->host,
client->port,
client->security);
@ -226,7 +231,7 @@ MQTTCMD_Connect(CmdPacket *cmd) {
return 1;
}
uint32_t ICACHE_FLASH_ATTR
uint32_t ICACHE_FLASH_ATTR
MQTTCMD_Disconnect(CmdPacket *cmd) {
CmdRequest req;
CMD_Request(&req, cmd);
@ -245,7 +250,7 @@ MQTTCMD_Disconnect(CmdPacket *cmd) {
return 1;
}
uint32_t ICACHE_FLASH_ATTR
uint32_t ICACHE_FLASH_ATTR
MQTTCMD_Publish(CmdPacket *cmd) {
CmdRequest req;
CMD_Request(&req, cmd);
@ -279,7 +284,7 @@ MQTTCMD_Publish(CmdPacket *cmd) {
// TODO: next line not originally present
data[len] = 0;
// get data length
// get data length
// TODO: this isn't used but we have to pull it off the stack
CMD_PopArg(&req, (uint8_t*)&data_len, 4);
@ -301,7 +306,7 @@ MQTTCMD_Publish(CmdPacket *cmd) {
return 1;
}
uint32_t ICACHE_FLASH_ATTR
uint32_t ICACHE_FLASH_ATTR
MQTTCMD_Subscribe(CmdPacket *cmd) {
CmdRequest req;
CMD_Request(&req, cmd);

@ -2,7 +2,6 @@
#define MODULES_MQTT_CMD_H_
#include "cmd.h"
#include "mqtt.h"
typedef struct {
uint32_t connectedCb;

@ -29,6 +29,7 @@
*
*/
#include <esp8266.h>
#include "mqtt_msg.h"
#define MQTT_MAX_FIXED_HEADER_SIZE 3
@ -57,7 +58,7 @@ struct
uint8_t keepaliveLsb;
};
static int ICACHE_FLASH_ATTR
static int ICACHE_FLASH_ATTR
append_string(mqtt_connection_t* connection, const char* string, int len) {
if (connection->message.length + len + 2 > connection->buffer_length)
return -1;
@ -70,7 +71,7 @@ append_string(mqtt_connection_t* connection, const char* string, int len) {
return len + 2;
}
static uint16_t ICACHE_FLASH_ATTR
static uint16_t ICACHE_FLASH_ATTR
append_message_id(mqtt_connection_t* connection, uint16_t message_id) {
// If message_id is zero then we should assign one, otherwise
// we'll use the one supplied by the caller
@ -86,20 +87,20 @@ append_message_id(mqtt_connection_t* connection, uint16_t message_id) {
return message_id;
}
static int ICACHE_FLASH_ATTR
static int ICACHE_FLASH_ATTR
init_message(mqtt_connection_t* connection) {
connection->message.length = MQTT_MAX_FIXED_HEADER_SIZE;
return MQTT_MAX_FIXED_HEADER_SIZE;
}
static mqtt_message_t* ICACHE_FLASH_ATTR
static mqtt_message_t* ICACHE_FLASH_ATTR
fail_message(mqtt_connection_t* connection) {
connection->message.data = connection->buffer;
connection->message.length = 0;
return &connection->message;
}
static mqtt_message_t* ICACHE_FLASH_ATTR
static mqtt_message_t* ICACHE_FLASH_ATTR
fini_message(mqtt_connection_t* connection, int type, int dup, int qos, int retain) {
int remaining_length = connection->message.length - MQTT_MAX_FIXED_HEADER_SIZE;
@ -120,7 +121,7 @@ fini_message(mqtt_connection_t* connection, int type, int dup, int qos, int reta
return &connection->message;
}
void ICACHE_FLASH_ATTR
void ICACHE_FLASH_ATTR
mqtt_msg_init(mqtt_connection_t* connection, uint8_t* buffer, uint16_t buffer_length) {
uint8_t len = sizeof(connection);
memset(connection, '\0', len);
@ -128,8 +129,8 @@ mqtt_msg_init(mqtt_connection_t* connection, uint8_t* buffer, uint16_t buffer_le
connection->buffer_length = buffer_length;
}
int ICACHE_FLASH_ATTR
mqtt_get_total_length(uint8_t* buffer, uint16_t length) {
int ICACHE_FLASH_ATTR
mqtt_get_total_length(const uint8_t* buffer, uint16_t length) {
int i;
int totlen = 0;
@ -145,8 +146,8 @@ mqtt_get_total_length(uint8_t* buffer, uint16_t length) {
return totlen;
}
const char* ICACHE_FLASH_ATTR
mqtt_get_publish_topic(uint8_t* buffer, uint16_t* length) {
const char* ICACHE_FLASH_ATTR
mqtt_get_publish_topic(const uint8_t* buffer, uint16_t* length) {
int i;
int totlen = 0;
int topiclen;
@ -172,8 +173,8 @@ mqtt_get_publish_topic(uint8_t* buffer, uint16_t* length) {
return (const char*)(buffer + i);
}
const char* ICACHE_FLASH_ATTR
mqtt_get_publish_data(uint8_t* buffer, uint16_t* length) {
const char* ICACHE_FLASH_ATTR
mqtt_get_publish_data(const uint8_t* buffer, uint16_t* length) {
int i;
int totlen = 0;
int topiclen;
@ -214,8 +215,8 @@ mqtt_get_publish_data(uint8_t* buffer, uint16_t* length) {
return (const char*)(buffer + i);
}
uint16_t ICACHE_FLASH_ATTR
mqtt_get_id(uint8_t* buffer, uint16_t length) {
uint16_t ICACHE_FLASH_ATTR
mqtt_get_id(const uint8_t* buffer, uint16_t length) {
if (length < 1)
return 0;
@ -271,7 +272,7 @@ mqtt_get_id(uint8_t* buffer, uint16_t length) {
}
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_connect(mqtt_connection_t* connection, mqtt_connect_info_t* info) {
struct mqtt_connect_variable_header* variable_header;
@ -339,7 +340,7 @@ mqtt_msg_connect(mqtt_connection_t* connection, mqtt_connect_info_t* info) {
return fini_message(connection, MQTT_MSG_TYPE_CONNECT, 0, 0, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_publish(mqtt_connection_t* connection, const char* topic, const char* data, int data_length, int qos, int retain, uint16_t* message_id) {
init_message(connection);
@ -364,7 +365,7 @@ mqtt_msg_publish(mqtt_connection_t* connection, const char* topic, const char* d
return fini_message(connection, MQTT_MSG_TYPE_PUBLISH, 0, qos, retain);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_puback(mqtt_connection_t* connection, uint16_t message_id) {
init_message(connection);
if (append_message_id(connection, message_id) == 0)
@ -372,7 +373,7 @@ mqtt_msg_puback(mqtt_connection_t* connection, uint16_t message_id) {
return fini_message(connection, MQTT_MSG_TYPE_PUBACK, 0, 0, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_pubrec(mqtt_connection_t* connection, uint16_t message_id) {
init_message(connection);
if (append_message_id(connection, message_id) == 0)
@ -380,7 +381,7 @@ mqtt_msg_pubrec(mqtt_connection_t* connection, uint16_t message_id) {
return fini_message(connection, MQTT_MSG_TYPE_PUBREC, 0, 0, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_pubrel(mqtt_connection_t* connection, uint16_t message_id) {
init_message(connection);
if (append_message_id(connection, message_id) == 0)
@ -388,7 +389,7 @@ mqtt_msg_pubrel(mqtt_connection_t* connection, uint16_t message_id) {
return fini_message(connection, MQTT_MSG_TYPE_PUBREL, 0, 1, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_pubcomp(mqtt_connection_t* connection, uint16_t message_id) {
init_message(connection);
if (append_message_id(connection, message_id) == 0)
@ -396,7 +397,7 @@ mqtt_msg_pubcomp(mqtt_connection_t* connection, uint16_t message_id) {
return fini_message(connection, MQTT_MSG_TYPE_PUBCOMP, 0, 0, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_subscribe(mqtt_connection_t* connection, const char* topic, int qos, uint16_t* message_id) {
init_message(connection);
@ -416,7 +417,7 @@ mqtt_msg_subscribe(mqtt_connection_t* connection, const char* topic, int qos, ui
return fini_message(connection, MQTT_MSG_TYPE_SUBSCRIBE, 0, 1, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_unsubscribe(mqtt_connection_t* connection, const char* topic, uint16_t* message_id) {
init_message(connection);
@ -432,19 +433,19 @@ mqtt_msg_unsubscribe(mqtt_connection_t* connection, const char* topic, uint16_t*
return fini_message(connection, MQTT_MSG_TYPE_UNSUBSCRIBE, 0, 1, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_pingreq(mqtt_connection_t* connection) {
init_message(connection);
return fini_message(connection, MQTT_MSG_TYPE_PINGREQ, 0, 0, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_pingresp(mqtt_connection_t* connection) {
init_message(connection);
return fini_message(connection, MQTT_MSG_TYPE_PINGRESP, 0, 0, 0);
}
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_message_t* ICACHE_FLASH_ATTR
mqtt_msg_disconnect(mqtt_connection_t* connection) {
init_message(connection);
return fini_message(connection, MQTT_MSG_TYPE_DISCONNECT, 0, 0, 0);

@ -30,8 +30,9 @@
*/
#ifndef MQTT_MSG_H
#define MQTT_MSG_H
#include <esp8266.h>
#define MQTT_MSG_H
#define PROTOCOL_NAMEv311
enum mqtt_message_type {
MQTT_MSG_TYPE_CONNECT = 1,
@ -50,21 +51,22 @@ enum mqtt_message_type {
MQTT_MSG_TYPE_DISCONNECT = 14
};
// Descriptor for a serialized MQTT message, this is returned by functions that compose a message
// (It's really an MQTT packet in v3.1.1 terminology)
typedef struct mqtt_message {
uint8_t* data;
uint16_t length;
} mqtt_message_t;
// Descriptor for a connection with message assembly storage
typedef struct mqtt_connection {
mqtt_message_t message;
uint16_t message_id;
uint8_t* buffer;
uint16_t buffer_length;
mqtt_message_t message; // resulting message
uint16_t message_id; // id of assembled message and memo to calculate next message id
uint8_t* buffer; // buffer for assembling messages
uint16_t buffer_length; // buffer length
} mqtt_connection_t;
// Descriptor for a connect request
typedef struct mqtt_connect_info {
char* client_id;
char* username;
@ -75,32 +77,40 @@ typedef struct mqtt_connect_info {
uint8_t will_qos;
uint8_t will_retain;
uint8_t clean_session;
} mqtt_connect_info_t;
static inline int ICACHE_FLASH_ATTR mqtt_get_type(uint8_t* buffer) {
static inline int ICACHE_FLASH_ATTR mqtt_get_type(const uint8_t* buffer) {
return (buffer[0] & 0xf0) >> 4;
}
static inline int ICACHE_FLASH_ATTR mqtt_get_dup(uint8_t* buffer) {
static inline int ICACHE_FLASH_ATTR mqtt_get_dup(const uint8_t* buffer) {
return (buffer[0] & 0x08) >> 3;
}
static inline int ICACHE_FLASH_ATTR mqtt_get_qos(uint8_t* buffer) {
static inline int ICACHE_FLASH_ATTR mqtt_get_qos(const uint8_t* buffer) {
return (buffer[0] & 0x06) >> 1;
}
static inline int ICACHE_FLASH_ATTR mqtt_get_retain(uint8_t* buffer) {
static inline int ICACHE_FLASH_ATTR mqtt_get_retain(const uint8_t* buffer) {
return (buffer[0] & 0x01);
}
// Init a connection descriptor
void mqtt_msg_init(mqtt_connection_t* connection, uint8_t* buffer, uint16_t buffer_length);
int mqtt_get_total_length(uint8_t* buffer, uint16_t length);
const char* mqtt_get_publish_topic(uint8_t* buffer, uint16_t* length);
const char* mqtt_get_publish_data(uint8_t* buffer, uint16_t* length);
uint16_t mqtt_get_id(uint8_t* buffer, uint16_t length);
// Returns the total length of a message including MQTT fixed header
int mqtt_get_total_length(const uint8_t* buffer, uint16_t length);
// Return pointer to topic, length in in/out param: in=length of buffer, out=length of topic
const char* mqtt_get_publish_topic(const uint8_t* buffer, uint16_t* length);
// Return pointer to data, length in in/out param: in=length of buffer, out=length of data
const char* mqtt_get_publish_data(const uint8_t* buffer, uint16_t* length);
// Return message id
uint16_t mqtt_get_id(const uint8_t* buffer, uint16_t length);
// The following functions construct an outgoing message
mqtt_message_t* mqtt_msg_connect(mqtt_connection_t* connection, mqtt_connect_info_t* info);
mqtt_message_t* mqtt_msg_publish(mqtt_connection_t* connection, const char* topic, const char* data, int data_length, int qos, int retain, uint16_t* message_id);
mqtt_message_t* mqtt_msg_puback(mqtt_connection_t* connection, uint16_t message_id);

@ -0,0 +1,64 @@
// Copyright 2015 by Thorsten von Eicken, see LICENSE.txt
#include <esp8266.h>
#include "pktbuf.h"
void ICACHE_FLASH_ATTR
PktBuf_Print(PktBuf *buf) {
os_printf("PktBuf:");
for (int i=-16; i<0; i++)
os_printf(" %02X", ((uint8_t*)buf)[i]);
os_printf(" %p", buf);
for (int i=0; i<16; i++)
os_printf(" %02X", ((uint8_t*)buf)[i]);
os_printf("\n");
os_printf("PktBuf: next=%p len=0x%04x\n",
((void**)buf)[-4], ((uint16_t*)buf)[-6]);
}
PktBuf * ICACHE_FLASH_ATTR
PktBuf_New(uint16_t length) {
PktBuf *buf = os_zalloc(length+sizeof(PktBuf));
buf->next = NULL;
buf->filled = 0;
//os_printf("PktBuf_New: %p l=%d->%d d=%p\n",
// buf, length, length+sizeof(PktBuf), buf->data);
return buf;
}
PktBuf * ICACHE_FLASH_ATTR
PktBuf_Push(PktBuf *headBuf, PktBuf *buf) {
if (headBuf == NULL) {
//os_printf("PktBuf_Push: %p\n", buf);
return buf;
}
PktBuf *h = headBuf;
while (h->next != NULL) h = h->next;
h->next = buf;
//os_printf("PktBuf_Push: %p->..->%p\n", headBuf, buf);
return headBuf;
}
PktBuf * ICACHE_FLASH_ATTR
PktBuf_Unshift(PktBuf *headBuf, PktBuf *buf) {
buf->next = headBuf;
//os_printf("PktBuf_Unshift: %p->%p\n", buf, buf->next);
return buf;
}
PktBuf * ICACHE_FLASH_ATTR
PktBuf_Shift(PktBuf *headBuf) {
PktBuf *buf = headBuf->next;
headBuf->next = NULL;
//os_printf("PktBuf_Shift: (%p)->%p\n", headBuf, buf);
return buf;
}
PktBuf * ICACHE_FLASH_ATTR
PktBuf_ShiftFree(PktBuf *headBuf) {
PktBuf *buf = headBuf->next;
//os_printf("PktBuf_ShiftFree: (%p)->%p\n", headBuf, buf);
os_free(headBuf);
return buf;
}

@ -0,0 +1,29 @@
// Copyright 2015 by Thorsten von Eicken, see LICENSE.txt
#ifndef PKTBUF_H
#define PKTBUF_H
typedef struct PktBuf {
struct PktBuf *next; // next buffer in chain
uint16_t filled; // number of bytes filled in buffer
uint8_t data[0]; // data in buffer
} PktBuf;
// Allocate a new packet buffer of given length
PktBuf *PktBuf_New(uint16_t length);
// Append a buffer to the end of a packet buffer queue, returns new head
PktBuf *PktBuf_Push(PktBuf *headBuf, PktBuf *buf);
// Prepend a buffer to the beginning of a packet buffer queue, return new head
PktBuf * PktBuf_Unshift(PktBuf *headBuf, PktBuf *buf);
// Shift first buffer off queue, returns new head (not shifted buffer!)
PktBuf *PktBuf_Shift(PktBuf *headBuf);
// Shift first buffer off queue, free it, return new head
PktBuf *PktBuf_ShiftFree(PktBuf *headBuf);
void PktBuf_Print(PktBuf *buf);
#endif

@ -1,86 +0,0 @@
#include "proto.h"
int8_t ICACHE_FLASH_ATTR
PROTO_Init(PROTO_PARSER* parser, PROTO_PARSE_CALLBACK* completeCallback, uint8_t* buf, uint16_t bufSize) {
parser->buf = buf;
parser->bufSize = bufSize;
parser->dataLen = 0;
parser->callback = completeCallback;
parser->isEsc = 0;
return 0;
}
int8_t ICACHE_FLASH_ATTR
PROTO_ParseByte(PROTO_PARSER* parser, uint8_t value) {
switch (value) {
case 0x7D:
parser->isEsc = 1;
break;
case 0x7E:
parser->dataLen = 0;
parser->isEsc = 0;
parser->isBegin = 1;
break;
case 0x7F:
if (parser->callback != NULL)
parser->callback();
parser->isBegin = 0;
return 0;
break;
default:
if (parser->isBegin == 0) break;
if (parser->isEsc) {
value ^= 0x20;
parser->isEsc = 0;
}
if (parser->dataLen < parser->bufSize)
parser->buf[parser->dataLen++] = value;
break;
}
return -1;
}
int16_t ICACHE_FLASH_ATTR
PROTO_ParseRb(RINGBUF* rb, uint8_t* bufOut, uint16_t* len, uint16_t maxBufLen) {
uint8_t c;
PROTO_PARSER proto;
PROTO_Init(&proto, NULL, bufOut, maxBufLen);
while (RINGBUF_Get(rb, &c) == 0) {
if (PROTO_ParseByte(&proto, c) == 0) {
*len = proto.dataLen;
return 0;
}
}
return -1;
}
int16_t ICACHE_FLASH_ATTR
PROTO_AddRb(RINGBUF* rb, const uint8_t* packet, int16_t len) {
uint16_t i = 2;
if (RINGBUF_Put(rb, 0x7E) == -1) return -1;
while (len--) {
switch (*packet) {
case 0x7D:
case 0x7E:
case 0x7F:
if (RINGBUF_Put(rb, 0x7D) == -1) return -1;
if (RINGBUF_Put(rb, *packet++ ^ 0x20) == -1) return -1;
i += 2;
break;
default:
if (RINGBUF_Put(rb, *packet++) == -1) return -1;
i++;
break;
}
}
if (RINGBUF_Put(rb, 0x7F) == -1) return -1;
return i;
}

@ -1,21 +0,0 @@
#ifndef _PROTO_H_
#define _PROTO_H_
#include <esp8266.h>
#include "ringbuf.h"
typedef void (PROTO_PARSE_CALLBACK)();
typedef struct {
uint8_t* buf;
uint16_t bufSize;
uint16_t dataLen;
uint8_t isEsc;
uint8_t isBegin;
PROTO_PARSE_CALLBACK* callback;
} PROTO_PARSER;
int8_t PROTO_Init(PROTO_PARSER* parser, PROTO_PARSE_CALLBACK* completeCallback, uint8_t* buf, uint16_t bufSize);
int16_t PROTO_AddRb(RINGBUF* rb, const uint8_t* packet, int16_t len);
int8_t PROTO_ParseByte(PROTO_PARSER* parser, uint8_t value);
int16_t PROTO_ParseRb(RINGBUF* rb, uint8_t* bufOut, uint16_t* len, uint16_t maxBufLen);
#endif

@ -1,53 +0,0 @@
/* str_queue.c
*
* Copyright (c) 2014-2015, Tuan PM <tuanpm at live dot com>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of Redis nor the names of its contributors may be used
* to endorse or promote products derived from this software without
* specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#include "queue.h"
void ICACHE_FLASH_ATTR
QUEUE_Init(QUEUE* queue, int bufferSize) {
queue->buf = (uint8_t*)os_zalloc(bufferSize);
RINGBUF_Init(&queue->rb, queue->buf, bufferSize);
}
int32_t ICACHE_FLASH_ATTR
QUEUE_Puts(QUEUE* queue, uint8_t* buffer, uint16_t len) {
return PROTO_AddRb(&queue->rb, buffer, len);
}
int32_t ICACHE_FLASH_ATTR
QUEUE_Gets(QUEUE* queue, uint8_t* buffer, uint16_t* len, uint16_t maxLen) {
return PROTO_ParseRb(&queue->rb, buffer, len, maxLen);
}
bool ICACHE_FLASH_ATTR
QUEUE_IsEmpty(QUEUE* queue) {
if (queue->rb.fill_cnt <= 0)
return TRUE;
return FALSE;
}

@ -1,46 +0,0 @@
/* str_queue.h --
*
* Copyright (c) 2014-2015, Tuan PM <tuanpm at live dot com>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of Redis nor the names of its contributors may be used
* to endorse or promote products derived from this software without
* specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef USER_QUEUE_H_
#define USER_QUEUE_H_
#include <esp8266.h>
#include "proto.h"
#include "ringbuf.h"
typedef struct {
uint8_t* buf;
RINGBUF rb;
} QUEUE;
void QUEUE_Init(QUEUE* queue, int bufferSize);
int32_t QUEUE_Puts(QUEUE* queue, uint8_t* buffer, uint16_t len);
int32_t QUEUE_Gets(QUEUE* queue, uint8_t* buffer, uint16_t* len, uint16_t maxLen);
bool QUEUE_IsEmpty(QUEUE* queue);
#endif /* USER_QUEUE_H_ */

@ -1,63 +0,0 @@
#include "ringbuf.h"
/**
* \brief init a RINGBUF object
* \param r pointer to a RINGBUF object
* \param buf pointer to a byte array
* \param size size of buf
* \return 0 if successfull, otherwise failed
*/
int16_t ICACHE_FLASH_ATTR
RINGBUF_Init(RINGBUF* r, uint8_t* buf, int32_t size) {
if (r == NULL || buf == NULL || size < 2) return -1;
r->p_o = r->p_r = r->p_w = buf;
r->fill_cnt = 0;
r->size = size;
return 0;
}
/**
* \brief put a character into ring buffer
* \param r pointer to a ringbuf object
* \param c character to be put
* \return 0 if successfull, otherwise failed
*/
int16_t ICACHE_FLASH_ATTR
RINGBUF_Put(RINGBUF* r, uint8_t c) {
if (r->fill_cnt >= r->size)return -1; // ring buffer is full, this should be atomic operation
r->fill_cnt++; // increase filled slots count, this should be atomic operation
*r->p_w++ = c; // put character into buffer
if (r->p_w >= r->p_o + r->size) // rollback if write pointer go pass
r->p_w = r->p_o; // the physical boundary
return 0;
}
/**
* \brief get a character from ring buffer
* \param r pointer to a ringbuf object
* \param c read character
* \return 0 if successfull, otherwise failed
*/
int16_t ICACHE_FLASH_ATTR
RINGBUF_Get(RINGBUF* r, uint8_t* c) {
if (r->fill_cnt <= 0)return -1; // ring buffer is empty, this should be atomic operation
r->fill_cnt--; // decrease filled slots count
*c = *r->p_r++; // get the character out
if (r->p_r >= r->p_o + r->size) // rollback if write pointer go pass
r->p_r = r->p_o; // the physical boundary
return 0;
}

@ -1,17 +0,0 @@
#ifndef _RING_BUF_H_
#define _RING_BUF_H_
#include <esp8266.h>
typedef struct {
uint8_t* p_o; /**< Original pointer */
uint8_t* volatile p_r; /**< Read pointer */
uint8_t* volatile p_w; /**< Write pointer */
volatile int32_t fill_cnt; /**< Number of filled slots */
int32_t size; /**< Buffer size */
} RINGBUF;
int16_t RINGBUF_Init(RINGBUF* r, uint8_t* buf, int32_t size);
int16_t RINGBUF_Put(RINGBUF* r, uint8_t c);
int16_t RINGBUF_Get(RINGBUF* r, uint8_t* c);
#endif

@ -154,12 +154,12 @@ rest_dns_found(const char *name, ip_addr_t *ipaddr, void *arg) {
if(client->ip.addr == 0 && ipaddr->addr != 0) {
os_memcpy(client->pCon->proto.tcp->remote_ip, &ipaddr->addr, 4);
//if(client->security){
// espconn_secure_connect(client->pCon);
//}
//else {
#ifdef CLIENT_SSL_ENABLE
if(client->security) {
espconn_secure_connect(client->pCon);
} else
#endif
espconn_connect(client->pCon);
//}
os_printf("REST: connecting...\n");
}
}
@ -368,6 +368,8 @@ REST_Request(CmdPacket *cmd) {
}
os_printf("\n");
//os_printf("REST request: %s", (char*)client->data);
os_printf("REST: pCon state=%d\n", client->pCon->state);
client->pCon->state = ESPCONN_NONE;
espconn_regist_connectcb(client->pCon, tcpclient_connect_cb);

@ -14,6 +14,7 @@
#include "serled.h"
#include "config.h"
#include "console.h"
#include "slip.h"
#include "cmd.h"
static struct espconn serbridgeConn;
@ -258,6 +259,19 @@ console_process(char *buf, short len) {
}
}
// callback with a buffer of characters that have arrived on the uart
void ICACHE_FLASH_ATTR
serbridgeUartCb(char *buf, short length) {
if (!flashConfig.slip_enable || slip_disabled > 0) {
//os_printf("SLIP: disabled got %d\n", length);
console_process(buf, length);
} else {
slip_parse_buf(buf, length);
}
serledFlash(50); // short blink on serial LED
}
//callback after the data are sent
static void ICACHE_FLASH_ATTR
serbridgeSentCb(void *arg) {
@ -273,6 +287,7 @@ serbridgeSentCb(void *arg) {
// Error callback (it's really poorly named, it's not a "connection reconnected" callback,
// it's really a "connection broken, please reconnect" callback)
// Note that there is no DisconCb after a ReconCb
static void ICACHE_FLASH_ATTR serbridgeReconCb(void *arg, sint8 err) {
serbridgeConnData *sbConn = serbridgeFindConnData(arg);
if (sbConn == NULL) return;

@ -6,4 +6,3 @@ void serledInit(void);
void makeGpio(uint8_t pin);
#endif

@ -4,11 +4,10 @@
#include "uart.h"
#include "crc16.h"
#include "serbridge.h"
#include "serled.h"
#include "console.h"
#include "cmd.h"
uint8_t slip_disabled; // disable slip to allow flashing of attached MCU
uint8_t slip_disabled; // temporarily disable slip to allow flashing of attached MCU
extern void ICACHE_FLASH_ATTR console_process(char *buf, short len);
@ -115,18 +114,7 @@ slip_parse_char(char c) {
// callback with a buffer of characters that have arrived on the uart
void ICACHE_FLASH_ATTR
serbridgeUartCb(char *buf, short length) {
if (slip_disabled > 0) {
//os_printf("SLIP: disabled got %d\n", length);
console_process(buf, length);
for (short i=0; i<length; i++)
if (buf[i] == SLIP_START) {
os_printf("SLIP: START while disabled=%d\n", slip_disabled);
break;
}
return;
}
slip_parse_buf(char *buf, short length) {
// do SLIP parsing
for (short i=0; i<length; i++)
slip_parse_char(buf[i]);
@ -136,6 +124,5 @@ serbridgeUartCb(char *buf, short length) {
slip_process();
slip_reset();
}
serledFlash(50); // short blink on serial LED
}

@ -0,0 +1,6 @@
#ifndef SLIP_H
#define SLIP_H
void slip_parse_buf(char *buf, short length);
#endif

@ -23,7 +23,7 @@
#include "user_interface.h"
#include "uart.h"
#define recvTaskPrio 0
#define recvTaskPrio 1
#define recvTaskQueueLen 64
// UartDev is defined and initialized in rom code.

@ -1,70 +1,87 @@
#include <esp8266.h>
//#include <mqtt.h>
//#include <cgiwifi.h>
#include "cgiwifi.h"
#include "mqtt.h"
MQTT_Client mqttClient;
static ETSTimer mqttTimer;
static int once = 0;
static void ICACHE_FLASH_ATTR mqttTimerCb(void *arg) {
if (once++ > 0) return;
MQTT_Init(&mqttClient, "h.voneicken.com", 1883, 0, 2, "test1", "", "", 10, 1);
MQTT_Connect(&mqttClient);
MQTT_Subscribe(&mqttClient, "system/time", 0);
}
void ICACHE_FLASH_ATTR
wifiStateChangeCb(uint8_t status)
{
if (status == wifiGotIP) {
os_timer_disarm(&mqttTimer);
os_timer_setfn(&mqttTimer, mqttTimerCb, NULL);
os_timer_arm(&mqttTimer, 15000, 0);
}
}
// initialize the custom stuff that goes beyond esp-link
void app_init() {
wifiAddStateChangeCb(wifiStateChangeCb);
}
#if 0
MQTT_Client mqttClient;
void ICACHE_FLASH_ATTR
mqttConnectedCb(uint32_t *args) {
MQTT_Client* client = (MQTT_Client*)args;
MQTT_Publish(client, "announce/all", "Hello World!", 0, 0);
}
void ICACHE_FLASH_ATTR
mqttDisconnectedCb(uint32_t *args) {
// MQTT_Client* client = (MQTT_Client*)args;
os_printf("MQTT Disconnected\n");
}
void ICACHE_FLASH_ATTR
mqttTcpDisconnectedCb(uint32_t *args) {
// MQTT_Client* client = (MQTT_Client*)args;
os_printf("MQTT TCP Disconnected\n");
}
void ICACHE_FLASH_ATTR
mqttPublishedCb(uint32_t *args) {
// MQTT_Client* client = (MQTT_Client*)args;
os_printf("MQTT Published\n");
}
void ICACHE_FLASH_ATTR
mqttDataCb(uint32_t *args, const char* topic, uint32_t topic_len, const char *data, uint32_t data_len) {
char *topicBuf = (char*)os_zalloc(topic_len + 1);
char *dataBuf = (char*)os_zalloc(data_len + 1);
//MQTT_Client mqttClient;
//
//void ICACHE_FLASH_ATTR
//mqttConnectedCb(uint32_t *args) {
// MQTT_Client* client = (MQTT_Client*)args;
// MQTT_Publish(client, "announce/all", "Hello World!", 0, 0);
//}
//
//void ICACHE_FLASH_ATTR
//mqttDisconnectedCb(uint32_t *args) {
//// MQTT_Client* client = (MQTT_Client*)args;
// os_printf("MQTT Disconnected\n");
//}
//
//void ICACHE_FLASH_ATTR
//mqttTcpDisconnectedCb(uint32_t *args) {
//// MQTT_Client* client = (MQTT_Client*)args;
// os_printf("MQTT TCP Disconnected\n");
//}
//
//void ICACHE_FLASH_ATTR
//mqttPublishedCb(uint32_t *args) {
//// MQTT_Client* client = (MQTT_Client*)args;
// os_printf("MQTT Published\n");
//}
//
//void ICACHE_FLASH_ATTR
//mqttDataCb(uint32_t *args, const char* topic, uint32_t topic_len, const char *data, uint32_t data_len) {
// char *topicBuf = (char*)os_zalloc(topic_len + 1);
// char *dataBuf = (char*)os_zalloc(data_len + 1);
//
//// MQTT_Client* client = (MQTT_Client*)args;
//
// os_memcpy(topicBuf, topic, topic_len);
// topicBuf[topic_len] = 0;
//
// os_memcpy(dataBuf, data, data_len);
// dataBuf[data_len] = 0;
//
// os_printf("Receive topic: %s, data: %s\n", topicBuf, dataBuf);
// os_free(topicBuf);
// os_free(dataBuf);
//}
//
//void ICACHE_FLASH_ATTR
//wifiStateChangeCb(uint8_t status)
//{
// if (status == wifiGotIP && mqttClient.connState != TCP_CONNECTING){
// MQTT_Connect(&mqttClient);
// }
// else if (status == wifiIsDisconnected && mqttClient.connState == TCP_CONNECTING){
// MQTT_Disconnect(&mqttClient);
// }
//}
void init() {
// wifiAddStateChangeCb(wifiStateChangeCb);
// MQTT_InitConnection(&mqttClient, MQTT_HOST, MQTT_PORT, MQTT_SECURITY);
// MQTT_InitClient(&mqttClient, MQTT_CLIENT_ID, MQTT_USER, MQTT_PASS, MQTT_KEEPALIVE, MQTT_CLSESSION);
// MQTT_InitLWT(&mqttClient, "/lwt", "offline", 0, 0);
// MQTT_OnConnected(&mqttClient, mqttConnectedCb);
// MQTT_OnDisconnected(&mqttClient, mqttDisconnectedCb);
// MQTT_OnDisconnected(&mqttClient, mqttTcpDisconnectedCb);
// MQTT_OnPublished(&mqttClient, mqttPublishedCb);
// MQTT_OnData(&mqttClient, mqttDataCb);
}
os_memcpy(topicBuf, topic, topic_len);
topicBuf[topic_len] = 0;
os_memcpy(dataBuf, data, data_len);
dataBuf[data_len] = 0;
os_printf("Receive topic: %s, data: %s\n", topicBuf, dataBuf);
os_free(topicBuf);
os_free(dataBuf);
}
MQTT_InitConnection(&mqttClient, MQTT_HOST, MQTT_PORT, MQTT_SECURITY);
MQTT_InitClient(&mqttClient, MQTT_CLIENT_ID, MQTT_USER, MQTT_PASS, MQTT_KEEPALIVE, MQTT_CLSESSION);
MQTT_InitLWT(&mqttClient, "/lwt", "offline", 0, 0);
MQTT_OnConnected(&mqttClient, mqttConnectedCb);
MQTT_OnDisconnected(&mqttClient, mqttDisconnectedCb);
MQTT_OnDisconnected(&mqttClient, mqttTcpDisconnectedCb);
MQTT_OnPublished(&mqttClient, mqttPublishedCb);
MQTT_OnData(&mqttClient, mqttDataCb);
#endif

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