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520 lines
16 KiB
520 lines
16 KiB
// Copyright 2015 by Thorsten von Eicken, see LICENSE.txt
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#include "esp8266.h"
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#include "uart.h"
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#include "crc16.h"
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#include "serbridge.h"
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#include "serled.h"
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#include "config.h"
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#include "console.h"
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#include "slip.h"
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#include "cmd.h"
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#ifdef SYSLOG
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#include "syslog.h"
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#else
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#define syslog(X1...)
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#endif
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#define SKIP_AT_RESET
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static struct espconn serbridgeConn1; // plain bridging port
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static struct espconn serbridgeConn2; // programming port
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static esp_tcp serbridgeTcp1, serbridgeTcp2;
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static int8_t mcu_reset_pin, mcu_isp_pin, uart0_tx_enable_pin;
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extern uint8_t slip_disabled; // disable slip to allow flashing of attached MCU
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void (*programmingCB)(char *buffer, short length) = NULL;
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// Connection pool
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serbridgeConnData connData[MAX_CONN];
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//===== TCP -> UART
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// Telnet protocol characters
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#define IAC 255 // escape
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#define WILL 251 // negotiation
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#define SB 250 // subnegotiation begin
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#define SE 240 // subnegotiation end
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#define ComPortOpt 44 // COM port options
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#define SetControl 5 // Set control lines
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#define DTR_ON 8 // used here to reset microcontroller
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#define DTR_OFF 9
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#define RTS_ON 11 // used here to signal ISP (in-system-programming) to uC
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#define RTS_OFF 12
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// telnet state machine states
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enum { TN_normal, TN_iac, TN_will, TN_start, TN_end, TN_comPort, TN_setControl };
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// process a buffer-full on a telnet connection and return the ending telnet state
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static uint8_t ICACHE_FLASH_ATTR
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telnetUnwrap(uint8_t *inBuf, int len, uint8_t state)
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{
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for (int i=0; i<len; i++) {
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uint8_t c = inBuf[i];
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switch (state) {
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default:
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case TN_normal:
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if (c == IAC) state = TN_iac; // escape char: see what's next
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else uart0_write_char(c); // regular char
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break;
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case TN_iac:
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switch (c) {
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case IAC: // second escape -> write one to outbuf and go normal again
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state = TN_normal;
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uart0_write_char(c);
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break;
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case WILL: // negotiation
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state = TN_will;
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break;
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case SB: // command sequence begin
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state = TN_start;
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break;
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case SE: // command sequence end
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state = TN_normal;
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break;
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default: // not sure... let's ignore
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uart0_write_char(IAC);
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uart0_write_char(c);
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}
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break;
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case TN_will:
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state = TN_normal; // yes, we do COM port options, let's go back to normal
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break;
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case TN_start: // in command seq, now comes the type of cmd
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if (c == ComPortOpt) state = TN_comPort;
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else state = TN_end; // an option we don't know, skip 'til the end seq
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break;
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case TN_end: // wait for end seq
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if (c == IAC) state = TN_iac; // simple wait to accept end or next escape seq
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break;
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case TN_comPort:
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if (c == SetControl) state = TN_setControl;
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else state = TN_end;
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break;
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case TN_setControl: // switch control line and delay a tad
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switch (c) {
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case DTR_ON:
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if (mcu_reset_pin >= 0) {
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#ifdef SERBR_DBG
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os_printf("MCU reset gpio%d\n", mcu_reset_pin);
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#endif
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GPIO_OUTPUT_SET(mcu_reset_pin, 0);
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os_delay_us(100L);
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}
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#ifdef SERBR_DBG
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else { os_printf("MCU reset: no pin\n"); }
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#endif
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break;
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case DTR_OFF:
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if (mcu_reset_pin >= 0) {
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GPIO_OUTPUT_SET(mcu_reset_pin, 1);
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os_delay_us(100L);
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}
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break;
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case RTS_ON:
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if (mcu_isp_pin >= 0) {
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#ifdef SERBR_DBG
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os_printf("MCU ISP gpio%d\n", mcu_isp_pin);
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#endif
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GPIO_OUTPUT_SET(mcu_isp_pin, 0);
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os_delay_us(100L);
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}
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#ifdef SERBR_DBG
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else { os_printf("MCU isp: no pin\n"); }
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#endif
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slip_disabled++;
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break;
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case RTS_OFF:
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if (mcu_isp_pin >= 0) {
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GPIO_OUTPUT_SET(mcu_isp_pin, 1);
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os_delay_us(100L);
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}
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if (slip_disabled > 0) slip_disabled--;
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break;
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}
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state = TN_end;
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break;
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}
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}
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return state;
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}
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// Generate a reset pulse for the attached microcontroller
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void ICACHE_FLASH_ATTR
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serbridgeReset()
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{
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if (mcu_reset_pin >= 0) {
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#ifdef SERBR_DBG
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os_printf("MCU reset gpio%d\n", mcu_reset_pin);
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#endif
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GPIO_OUTPUT_SET(mcu_reset_pin, 0);
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os_delay_us(2000L); // esp8266 needs at least 1ms reset pulse, it seems...
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GPIO_OUTPUT_SET(mcu_reset_pin, 1);
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}
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#ifdef SERBR_DBG
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else { os_printf("MCU reset: no pin\n"); }
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#endif
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}
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// Receive callback
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static void ICACHE_FLASH_ATTR
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serbridgeRecvCb(void *arg, char *data, unsigned short len)
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{
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serbridgeConnData *conn = ((struct espconn*)arg)->reverse;
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//os_printf("Receive callback on conn %p\n", conn);
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if (conn == NULL) return;
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bool startPGM = false;
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// at the start of a connection we're in cmInit mode and we wait for the first few characters
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// to arrive in order to decide what type of connection this is.. The following if statements
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// do this dispatch. An issue here is that we assume that the first few characters all arrive
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// in the same TCP packet, which is true if the sender is a program, but not necessarily
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// if the sender is a person typing (although in that case the line-oriented TTY input seems
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// to make it work too). If this becomes a problem we need to buffer the first few chars...
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if (conn->conn_mode == cmInit) {
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// If the connection starts with the Arduino or ARM reset sequence we perform a RESET
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if ((len == 2 && strncmp(data, "0 ", 2) == 0) ||
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(len == 2 && strncmp(data, "?\n", 2) == 0) ||
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(len == 3 && strncmp(data, "?\r\n", 3) == 0)) {
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startPGM = true;
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conn->conn_mode = cmPGM;
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// If the connection starts with a telnet negotiation we will do telnet
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}
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else if (len >= 3 && strncmp(data, (char[]){IAC, WILL, ComPortOpt}, 3) == 0) {
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conn->conn_mode = cmTelnet;
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conn->telnet_state = TN_normal;
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// note that the three negotiation chars will be gobbled-up by telnetUnwrap
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#ifdef SERBR_DBG
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os_printf("telnet mode\n");
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#endif
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// looks like a plain-vanilla connection!
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}
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else {
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conn->conn_mode = cmTransparent;
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}
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// if we start out in cmPGM mode due to a connection to the second port we need to do the
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// reset dance right away
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} else if (conn->conn_mode == cmPGMInit) {
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conn->conn_mode = cmPGM;
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startPGM = true;
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}
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// do the programming reset dance
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if (startPGM) {
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#ifdef SERBR_DBG
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os_printf("MCU Reset=gpio%d ISP=gpio%d\n", mcu_reset_pin, mcu_isp_pin);
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os_delay_us(2*1000L); // time for os_printf to happen
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#endif
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// send reset to arduino/ARM, send "ISP" signal for the duration of the programming
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if (mcu_reset_pin >= 0) GPIO_OUTPUT_SET(mcu_reset_pin, 0);
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os_delay_us(100L);
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if (mcu_isp_pin >= 0) GPIO_OUTPUT_SET(mcu_isp_pin, 0);
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os_delay_us(2000L);
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if (mcu_reset_pin >= 0) GPIO_OUTPUT_SET(mcu_reset_pin, 1);
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//os_delay_us(100L);
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//if (mcu_isp_pin >= 0) GPIO_OUTPUT_SET(mcu_isp_pin, 1);
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os_delay_us(1000L); // wait a millisecond before writing to the UART below
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conn->conn_mode = cmPGM;
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slip_disabled++; // disable SLIP so it doesn't interfere with flashing
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#ifdef SKIP_AT_RESET
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serledFlash(50); // short blink on serial LED
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return;
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#endif
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}
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// write the buffer to the uart
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if (conn->conn_mode == cmTelnet) {
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conn->telnet_state = telnetUnwrap((uint8_t *)data, len, conn->telnet_state);
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} else {
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uart0_tx_buffer(data, len);
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}
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serledFlash(50); // short blink on serial LED
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}
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//===== UART -> TCP
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// Send all data in conn->txbuffer
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// returns result from espconn_sent if data in buffer or ESPCONN_OK (0)
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// Use only internally from espbuffsend and serbridgeSentCb
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static sint8 ICACHE_FLASH_ATTR
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sendtxbuffer(serbridgeConnData *conn)
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{
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sint8 result = ESPCONN_OK;
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if (conn->txbufferlen != 0) {
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//os_printf("TX %p %d\n", conn, conn->txbufferlen);
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conn->readytosend = false;
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result = espconn_sent(conn->conn, (uint8_t*)conn->txbuffer, conn->txbufferlen);
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conn->txbufferlen = 0;
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if (result != ESPCONN_OK) {
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os_printf("sendtxbuffer: espconn_sent error %d on conn %p\n", result, conn);
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conn->txbufferlen = 0;
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if (!conn->txoverflow_at) conn->txoverflow_at = system_get_time();
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} else {
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conn->sentbuffer = conn->txbuffer;
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conn->txbuffer = NULL;
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conn->txbufferlen = 0;
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}
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}
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return result;
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}
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// espbuffsend adds data to the send buffer. If the previous send was completed it calls
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// sendtxbuffer and espconn_sent.
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// Returns ESPCONN_OK (0) for success, -128 if buffer is full or error from espconn_sent
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// Use espbuffsend instead of espconn_sent as it solves the problem that espconn_sent must
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// only be called *after* receiving an espconn_sent_callback for the previous packet.
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static sint8 ICACHE_FLASH_ATTR
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espbuffsend(serbridgeConnData *conn, const char *data, uint16 len)
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{
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if (conn->txbufferlen >= MAX_TXBUFFER) goto overflow;
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// make sure we indeed have a buffer
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if (conn->txbuffer == NULL) conn->txbuffer = os_zalloc(MAX_TXBUFFER);
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if (conn->txbuffer == NULL) {
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os_printf("espbuffsend: cannot alloc tx buffer\n");
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return -128;
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}
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// add to send buffer
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uint16_t avail = conn->txbufferlen+len > MAX_TXBUFFER ? MAX_TXBUFFER-conn->txbufferlen : len;
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os_memcpy(conn->txbuffer + conn->txbufferlen, data, avail);
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conn->txbufferlen += avail;
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// try to send
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sint8 result = ESPCONN_OK;
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if (conn->readytosend) result = sendtxbuffer(conn);
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if (avail < len) {
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// some data didn't fit into the buffer
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if (conn->txbufferlen == 0) {
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// we sent the prior buffer, so try again
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return espbuffsend(conn, data+avail, len-avail);
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}
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goto overflow;
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}
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return result;
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overflow:
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if (conn->txoverflow_at) {
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// we've already been overflowing
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if (system_get_time() - conn->txoverflow_at > 10*1000*1000) {
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// no progress in 10 seconds, kill the connection
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os_printf("serbridge: killing overlowing stuck conn %p\n", conn);
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espconn_disconnect(conn->conn);
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}
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// else be silent, we already printed an error
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} else {
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// print 1-time message and take timestamp
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os_printf("serbridge: txbuffer full, conn %p\n", conn);
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conn->txoverflow_at = system_get_time();
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}
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return -128;
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}
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//callback after the data are sent
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static void ICACHE_FLASH_ATTR
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serbridgeSentCb(void *arg)
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{
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serbridgeConnData *conn = ((struct espconn*)arg)->reverse;
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//os_printf("Sent CB %p\n", conn);
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if (conn == NULL) return;
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//os_printf("%d ST\n", system_get_time());
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if (conn->sentbuffer != NULL) os_free(conn->sentbuffer);
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conn->sentbuffer = NULL;
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conn->readytosend = true;
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conn->txoverflow_at = 0;
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sendtxbuffer(conn); // send possible new data in txbuffer
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}
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void ICACHE_FLASH_ATTR
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console_process(char *buf, short len)
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{
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// push buffer into web-console
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for (short i=0; i<len; i++)
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console_write_char(buf[i]);
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// push the buffer into each open connection
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for (short i=0; i<MAX_CONN; i++) {
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if (connData[i].conn) {
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espbuffsend(&connData[i], buf, len);
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}
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}
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}
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// callback with a buffer of characters that have arrived on the uart
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void ICACHE_FLASH_ATTR
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serbridgeUartCb(char *buf, short length)
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{
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if (programmingCB) {
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programmingCB(buf, length);
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} else if (!flashConfig.slip_enable || slip_disabled > 0) {
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//os_printf("SLIP: disabled got %d\n", length);
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console_process(buf, length);
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} else {
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slip_parse_buf(buf, length);
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}
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serledFlash(50); // short blink on serial LED
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}
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//===== Connect / disconnect
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// Disconnection callback
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static void ICACHE_FLASH_ATTR
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serbridgeDisconCb(void *arg)
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{
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serbridgeConnData *conn = ((struct espconn*)arg)->reverse;
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if (conn == NULL) return;
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// Free buffers
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if (conn->sentbuffer != NULL) os_free(conn->sentbuffer);
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conn->sentbuffer = NULL;
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if (conn->txbuffer != NULL) os_free(conn->txbuffer);
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conn->txbuffer = NULL;
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conn->txbufferlen = 0;
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// Send reset to attached uC if it was in programming mode
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if (conn->conn_mode == cmPGM && mcu_reset_pin >= 0) {
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if (mcu_isp_pin >= 0) GPIO_OUTPUT_SET(mcu_isp_pin, 1);
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os_delay_us(100L);
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GPIO_OUTPUT_SET(mcu_reset_pin, 0);
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os_delay_us(100L);
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GPIO_OUTPUT_SET(mcu_reset_pin, 1);
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}
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conn->conn = NULL;
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}
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// Connection reset callback (note that there will be no DisconCb)
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static void ICACHE_FLASH_ATTR
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serbridgeResetCb(void *arg, sint8 err)
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{
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os_printf("serbridge: connection reset err=%d\n", err);
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serbridgeDisconCb(arg);
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}
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// New connection callback, use one of the connection descriptors, if we have one left.
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static void ICACHE_FLASH_ATTR
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serbridgeConnectCb(void *arg)
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{
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struct espconn *conn = arg;
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// Find empty conndata in pool
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int i;
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for (i=0; i<MAX_CONN; i++) if (connData[i].conn==NULL) break;
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#ifdef SERBR_DBG
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os_printf("Accept port %d, conn=%p, pool slot %d\n", conn->proto.tcp->local_port, conn, i);
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#endif
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syslog(SYSLOG_FAC_USER, SYSLOG_PRIO_NOTICE, "esp-link", "Accept port %d, conn=%p, pool slot %d\n", conn->proto.tcp->local_port, conn, i);
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if (i==MAX_CONN) {
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#ifdef SERBR_DBG
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os_printf("Aiee, conn pool overflow!\n");
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#endif
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syslog(SYSLOG_FAC_USER, SYSLOG_PRIO_WARNING, "esp-link", "Aiee, conn pool overflow!\n");
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espconn_disconnect(conn);
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return;
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}
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os_memset(connData+i, 0, sizeof(struct serbridgeConnData));
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connData[i].conn = conn;
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conn->reverse = connData+i;
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connData[i].readytosend = true;
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connData[i].conn_mode = cmInit;
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// if it's the second port we start out in programming mode
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if (conn->proto.tcp->local_port == serbridgeConn2.proto.tcp->local_port)
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connData[i].conn_mode = cmPGMInit;
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espconn_regist_recvcb(conn, serbridgeRecvCb);
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espconn_regist_disconcb(conn, serbridgeDisconCb);
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espconn_regist_reconcb(conn, serbridgeResetCb);
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espconn_regist_sentcb(conn, serbridgeSentCb);
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espconn_set_opt(conn, ESPCONN_REUSEADDR|ESPCONN_NODELAY);
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}
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//===== Initialization
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void ICACHE_FLASH_ATTR
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serbridgeInitPins()
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{
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mcu_reset_pin = flashConfig.reset_pin;
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mcu_isp_pin = flashConfig.isp_pin;
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uart0_tx_enable_pin = flashConfig.uart0_tx_enable_pin;
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#ifdef SERBR_DBG
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os_printf("Serbridge pins: reset=%d isp=%d tx_enable=%d swap=%d\n",
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mcu_reset_pin, mcu_isp_pin, uart0_tx_enable_pin, flashConfig.swap_uart);
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#endif
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if (flashConfig.swap_uart) {
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PIN_FUNC_SELECT(PERIPHS_IO_MUX_MTCK_U, 4); // RX
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PIN_FUNC_SELECT(PERIPHS_IO_MUX_MTDO_U, 4); // TX
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PIN_PULLUP_DIS(PERIPHS_IO_MUX_MTDO_U);
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if (flashConfig.rx_pullup) PIN_PULLUP_EN(PERIPHS_IO_MUX_MTCK_U);
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else PIN_PULLUP_DIS(PERIPHS_IO_MUX_MTCK_U);
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system_uart_swap();
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} else {
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PIN_FUNC_SELECT(PERIPHS_IO_MUX_U0TXD_U, 0);
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PIN_FUNC_SELECT(PERIPHS_IO_MUX_U0RXD_U, 0);
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PIN_PULLUP_DIS(PERIPHS_IO_MUX_U0TXD_U);
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if (flashConfig.rx_pullup) PIN_PULLUP_EN(PERIPHS_IO_MUX_U0RXD_U);
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else PIN_PULLUP_DIS(PERIPHS_IO_MUX_U0RXD_U);
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system_uart_de_swap();
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}
|
|
|
|
/* set both pins to 1 before turning them on (so we don't cause a reset)
|
|
* then switch pin mux to make these pins GPIO pins
|
|
*/
|
|
if (mcu_isp_pin >= 0) {
|
|
GPIO_OUTPUT_SET(mcu_isp_pin, 1);
|
|
makeGpio(mcu_isp_pin);
|
|
}
|
|
|
|
if (mcu_reset_pin >= 0) {
|
|
GPIO_OUTPUT_SET(mcu_reset_pin, 1);
|
|
makeGpio(mcu_reset_pin);
|
|
}
|
|
|
|
// set TX_ENABLE to 0 so we start up listening
|
|
if (uart0_tx_enable_pin >= 0) {
|
|
GPIO_OUTPUT_SET(uart0_tx_enable_pin, 0);
|
|
makeGpio(uart0_tx_enable_pin);
|
|
uart0_set_tx_enable_pin(uart0_tx_enable_pin);
|
|
}
|
|
}
|
|
|
|
// Start transparent serial bridge TCP server on specified port (typ. 23)
|
|
void ICACHE_FLASH_ATTR
|
|
serbridgeInit(int port1, int port2)
|
|
{
|
|
serbridgeInitPins();
|
|
|
|
os_memset(connData, 0, sizeof(connData));
|
|
os_memset(&serbridgeTcp1, 0, sizeof(serbridgeTcp1));
|
|
os_memset(&serbridgeTcp2, 0, sizeof(serbridgeTcp2));
|
|
|
|
// set-up the primary port for plain bridging
|
|
serbridgeConn1.type = ESPCONN_TCP;
|
|
serbridgeConn1.state = ESPCONN_NONE;
|
|
serbridgeTcp1.local_port = port1;
|
|
serbridgeConn1.proto.tcp = &serbridgeTcp1;
|
|
|
|
espconn_regist_connectcb(&serbridgeConn1, serbridgeConnectCb);
|
|
espconn_accept(&serbridgeConn1);
|
|
espconn_tcp_set_max_con_allow(&serbridgeConn1, MAX_CONN);
|
|
espconn_regist_time(&serbridgeConn1, SER_BRIDGE_TIMEOUT, 0);
|
|
|
|
// set-up the secondary port for programming
|
|
serbridgeConn2.type = ESPCONN_TCP;
|
|
serbridgeConn2.state = ESPCONN_NONE;
|
|
serbridgeTcp2.local_port = port2;
|
|
serbridgeConn2.proto.tcp = &serbridgeTcp2;
|
|
|
|
espconn_regist_connectcb(&serbridgeConn2, serbridgeConnectCb);
|
|
espconn_accept(&serbridgeConn2);
|
|
espconn_tcp_set_max_con_allow(&serbridgeConn2, MAX_CONN);
|
|
espconn_regist_time(&serbridgeConn2, SER_BRIDGE_TIMEOUT, 0);
|
|
}
|
|
|