/**
* Marlin 3D Printer Firmware
* Copyright (c) 2020 MarlinFirmware [https://github.com/MarlinFirmware/Marlin]
*
* Based on Sprinter and grbl.
* Copyright (c) 2011 Camiel Gubbels / Erik van der Zalm
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*
*/
#pragma once
#include "../inc/MarlinConfig.h"
#include "serial_hook.h"
// Commonly-used strings in serial output
extern const char NUL_STR[], SP_P_STR[], SP_T_STR[],
X_STR[], Y_STR[], Z_STR[], E_STR[],
X_LBL[], Y_LBL[], Z_LBL[], E_LBL[],
SP_A_STR[], SP_B_STR[], SP_C_STR[],
SP_X_STR[], SP_Y_STR[], SP_Z_STR[], SP_E_STR[],
SP_X_LBL[], SP_Y_LBL[], SP_Z_LBL[], SP_E_LBL[];
//
// Debugging flags for use by M111
//
enum MarlinDebugFlags : uint8_t {
MARLIN_DEBUG_NONE = 0,
MARLIN_DEBUG_ECHO = _BV(0), ///< Echo commands in order as they are processed
MARLIN_DEBUG_INFO = _BV(1), ///< Print messages for code that has debug output
MARLIN_DEBUG_ERRORS = _BV(2), ///< Not implemented
MARLIN_DEBUG_DRYRUN = _BV(3), ///< Ignore temperature setting and E movement commands
MARLIN_DEBUG_COMMUNICATION = _BV(4), ///< Not implemented
#if ENABLED(DEBUG_LEVELING_FEATURE)
MARLIN_DEBUG_LEVELING = _BV(5), ///< Print detailed output for homing and leveling
MARLIN_DEBUG_MESH_ADJUST = _BV(6), ///< UBL bed leveling
#else
MARLIN_DEBUG_LEVELING = 0,
MARLIN_DEBUG_MESH_ADJUST = 0,
#endif
MARLIN_DEBUG_ALL = 0xFF
};
extern uint8_t marlin_debug_flags;
#define DEBUGGING(F) (marlin_debug_flags & (MARLIN_DEBUG_## F))
//
// Serial redirection
//
#define SERIAL_ALL 0x7F
#if HAS_MULTI_SERIAL
#define _PORT_REDIRECT(n,p) REMEMBER(n,multiSerial.portMask,p)
#define _PORT_RESTORE(n,p) RESTORE(n)
#define SERIAL_ASSERT(P) if(multiSerial.portMask!=(P)){ debugger(); }
#ifdef SERIAL_CATCHALL
typedef MultiSerial SerialOutputT;
#else
typedef MultiSerial, decltype(MYSERIAL1)), 0> SerialOutputT;
#endif
extern SerialOutputT multiSerial;
#define SERIAL_IMPL multiSerial
#else
#define _PORT_REDIRECT(n,p) NOOP
#define _PORT_RESTORE(n) NOOP
#define SERIAL_ASSERT(P) NOOP
#define SERIAL_IMPL MYSERIAL0
#endif
#define SERIAL_OUT(WHAT, V...) (void)SERIAL_IMPL.WHAT(V)
#define PORT_REDIRECT(p) _PORT_REDIRECT(1,p)
#define PORT_RESTORE() _PORT_RESTORE(1)
#define SERIAL_PORTMASK(P) _BV(P)
//
// SERIAL_CHAR - Print one or more individual chars
//
inline void SERIAL_CHAR(char a) { SERIAL_IMPL.write(a); }
template
void SERIAL_CHAR(char a, Args ... args) { SERIAL_IMPL.write(a); SERIAL_CHAR(args ...); }
/**
* SERIAL_ECHO - Print a single string or value.
* Any numeric parameter (including char) is printed as a base-10 number.
* A string pointer or literal will be output as a string.
*
* NOTE: Use SERIAL_CHAR to print char as a single character.
*/
template
void SERIAL_ECHO(T x) { SERIAL_IMPL.print(x); }
// Wrapper for ECHO commands to interpret a char
typedef struct SerialChar { char c; SerialChar(char n) : c(n) { } } serial_char_t;
inline void SERIAL_ECHO(serial_char_t x) { SERIAL_IMPL.write(x.c); }
#define AS_CHAR(C) serial_char_t(C)
// SERIAL_ECHO_F prints a floating point value with optional precision
inline void SERIAL_ECHO_F(EnsureDouble x, int digit = 2) { SERIAL_IMPL.print(x, digit); }
template
void SERIAL_ECHOLN(T x) { SERIAL_IMPL.println(x); }
// SERIAL_PRINT works like SERIAL_ECHO but allow to specify the encoding base of the number printed
template
void SERIAL_PRINT(T x, U y) { SERIAL_IMPL.print(x, y); }
template
void SERIAL_PRINTLN(T x, U y) { SERIAL_IMPL.println(x, y); }
// Flush the serial port
inline void SERIAL_FLUSH() { SERIAL_IMPL.flush(); }
inline void SERIAL_FLUSHTX() { SERIAL_IMPL.flushTX(); }
// Print a single PROGMEM string to serial
void serialprintPGM(PGM_P str);
// SERIAL_ECHOPAIR / SERIAL_ECHOPAIR_P is used to output a key value pair. The key must be a string and the value can be anything
// Print up to 12 pairs of values. Odd elements auto-wrapped in PSTR().
#define __SEP_N(N,V...) _SEP_##N(V)
#define _SEP_N(N,V...) __SEP_N(N,V)
#define _SEP_1(PRE) SERIAL_ECHOPGM(PRE)
#define _SEP_2(PRE,V) serial_echopair_PGM(PSTR(PRE),V)
#define _SEP_3(a,b,c) do{ _SEP_2(a,b); SERIAL_ECHOPGM(c); }while(0)
#define _SEP_4(a,b,V...) do{ _SEP_2(a,b); _SEP_2(V); }while(0)
#define _SEP_5(a,b,V...) do{ _SEP_2(a,b); _SEP_3(V); }while(0)
#define _SEP_6(a,b,V...) do{ _SEP_2(a,b); _SEP_4(V); }while(0)
#define _SEP_7(a,b,V...) do{ _SEP_2(a,b); _SEP_5(V); }while(0)
#define _SEP_8(a,b,V...) do{ _SEP_2(a,b); _SEP_6(V); }while(0)
#define _SEP_9(a,b,V...) do{ _SEP_2(a,b); _SEP_7(V); }while(0)
#define _SEP_10(a,b,V...) do{ _SEP_2(a,b); _SEP_8(V); }while(0)
#define _SEP_11(a,b,V...) do{ _SEP_2(a,b); _SEP_9(V); }while(0)
#define _SEP_12(a,b,V...) do{ _SEP_2(a,b); _SEP_10(V); }while(0)
#define _SEP_13(a,b,V...) do{ _SEP_2(a,b); _SEP_11(V); }while(0)
#define _SEP_14(a,b,V...) do{ _SEP_2(a,b); _SEP_12(V); }while(0)
#define _SEP_15(a,b,V...) do{ _SEP_2(a,b); _SEP_13(V); }while(0)
#define _SEP_16(a,b,V...) do{ _SEP_2(a,b); _SEP_14(V); }while(0)
#define _SEP_17(a,b,V...) do{ _SEP_2(a,b); _SEP_15(V); }while(0)
#define _SEP_18(a,b,V...) do{ _SEP_2(a,b); _SEP_16(V); }while(0)
#define _SEP_19(a,b,V...) do{ _SEP_2(a,b); _SEP_17(V); }while(0)
#define _SEP_20(a,b,V...) do{ _SEP_2(a,b); _SEP_18(V); }while(0)
#define _SEP_21(a,b,V...) do{ _SEP_2(a,b); _SEP_19(V); }while(0)
#define _SEP_22(a,b,V...) do{ _SEP_2(a,b); _SEP_20(V); }while(0)
#define _SEP_23(a,b,V...) do{ _SEP_2(a,b); _SEP_21(V); }while(0)
#define _SEP_24(a,b,V...) do{ _SEP_2(a,b); _SEP_22(V); }while(0)
#define SERIAL_ECHOPAIR(V...) _SEP_N(NUM_ARGS(V),V)
// Print up to 12 pairs of values. Odd elements must be PSTR pointers.
#define __SEP_N_P(N,V...) _SEP_##N##_P(V)
#define _SEP_N_P(N,V...) __SEP_N_P(N,V)
#define _SEP_1_P(PRE) serialprintPGM(PRE)
#define _SEP_2_P(PRE,V) serial_echopair_PGM(PRE,V)
#define _SEP_3_P(a,b,c) do{ _SEP_2_P(a,b); serialprintPGM(c); }while(0)
#define _SEP_4_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_2_P(V); }while(0)
#define _SEP_5_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_3_P(V); }while(0)
#define _SEP_6_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_4_P(V); }while(0)
#define _SEP_7_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_5_P(V); }while(0)
#define _SEP_8_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_6_P(V); }while(0)
#define _SEP_9_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_7_P(V); }while(0)
#define _SEP_10_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_8_P(V); }while(0)
#define _SEP_11_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_9_P(V); }while(0)
#define _SEP_12_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_10_P(V); }while(0)
#define _SEP_13_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_11_P(V); }while(0)
#define _SEP_14_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_12_P(V); }while(0)
#define _SEP_15_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_13_P(V); }while(0)
#define _SEP_16_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_14_P(V); }while(0)
#define _SEP_17_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_15_P(V); }while(0)
#define _SEP_18_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_16_P(V); }while(0)
#define _SEP_19_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_17_P(V); }while(0)
#define _SEP_20_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_18_P(V); }while(0)
#define _SEP_21_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_19_P(V); }while(0)
#define _SEP_22_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_20_P(V); }while(0)
#define _SEP_23_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_21_P(V); }while(0)
#define _SEP_24_P(a,b,V...) do{ _SEP_2_P(a,b); _SEP_22_P(V); }while(0)
// SERIAL_ECHOPAIR_P is used to output a key value pair. Unlike SERIAL_ECHOPAIR, the key must be a PGM string already and the value can be anything
#define SERIAL_ECHOPAIR_P(V...) _SEP_N_P(NUM_ARGS(V),V)
// Print up to 12 pairs of values followed by newline
#define __SELP_N(N,V...) _SELP_##N(V)
#define _SELP_N(N,V...) __SELP_N(N,V)
#define _SELP_1(PRE) SERIAL_ECHOLNPGM(PRE)
#define _SELP_2(PRE,V) do{ serial_echopair_PGM(PSTR(PRE),V); SERIAL_EOL(); }while(0)
#define _SELP_3(a,b,c) do{ _SEP_2(a,b); SERIAL_ECHOLNPGM(c); }while(0)
#define _SELP_4(a,b,V...) do{ _SEP_2(a,b); _SELP_2(V); }while(0)
#define _SELP_5(a,b,V...) do{ _SEP_2(a,b); _SELP_3(V); }while(0)
#define _SELP_6(a,b,V...) do{ _SEP_2(a,b); _SELP_4(V); }while(0)
#define _SELP_7(a,b,V...) do{ _SEP_2(a,b); _SELP_5(V); }while(0)
#define _SELP_8(a,b,V...) do{ _SEP_2(a,b); _SELP_6(V); }while(0)
#define _SELP_9(a,b,V...) do{ _SEP_2(a,b); _SELP_7(V); }while(0)
#define _SELP_10(a,b,V...) do{ _SEP_2(a,b); _SELP_8(V); }while(0)
#define _SELP_11(a,b,V...) do{ _SEP_2(a,b); _SELP_9(V); }while(0)
#define _SELP_12(a,b,V...) do{ _SEP_2(a,b); _SELP_10(V); }while(0)
#define _SELP_13(a,b,V...) do{ _SEP_2(a,b); _SELP_11(V); }while(0)
#define _SELP_14(a,b,V...) do{ _SEP_2(a,b); _SELP_12(V); }while(0)
#define _SELP_15(a,b,V...) do{ _SEP_2(a,b); _SELP_13(V); }while(0)
#define _SELP_16(a,b,V...) do{ _SEP_2(a,b); _SELP_14(V); }while(0)
#define _SELP_17(a,b,V...) do{ _SEP_2(a,b); _SELP_15(V); }while(0)
#define _SELP_18(a,b,V...) do{ _SEP_2(a,b); _SELP_16(V); }while(0)
#define _SELP_19(a,b,V...) do{ _SEP_2(a,b); _SELP_17(V); }while(0)
#define _SELP_20(a,b,V...) do{ _SEP_2(a,b); _SELP_18(V); }while(0)
#define _SELP_21(a,b,V...) do{ _SEP_2(a,b); _SELP_19(V); }while(0)
#define _SELP_22(a,b,V...) do{ _SEP_2(a,b); _SELP_20(V); }while(0)
#define _SELP_23(a,b,V...) do{ _SEP_2(a,b); _SELP_21(V); }while(0)
#define _SELP_24(a,b,V...) do{ _SEP_2(a,b); _SELP_22(V); }while(0)
#define _SELP_25(a,b,V...) do{ _SEP_2(a,b); _SELP_23(V); }while(0)
#define _SELP_26(a,b,V...) do{ _SEP_2(a,b); _SELP_24(V); }while(0)
#define _SELP_27(a,b,V...) do{ _SEP_2(a,b); _SELP_25(V); }while(0)
#define _SELP_28(a,b,V...) do{ _SEP_2(a,b); _SELP_26(V); }while(0)
#define _SELP_29(a,b,V...) do{ _SEP_2(a,b); _SELP_27(V); }while(0)
#define _SELP_30(a,b,V...) do{ _SEP_2(a,b); _SELP_28(V); }while(0) // Eat two args, pass the rest up
#define SERIAL_ECHOLNPAIR(V...) _SELP_N(NUM_ARGS(V),V)
// Print up to 12 pairs of values followed by newline
#define __SELP_N_P(N,V...) _SELP_##N##_P(V)
#define _SELP_N_P(N,V...) __SELP_N_P(N,V)
#define _SELP_1_P(PRE) serialprintPGM(PRE)
#define _SELP_2_P(PRE,V) do{ serial_echopair_PGM(PRE,V); SERIAL_EOL(); }while(0)
#define _SELP_3_P(a,b,c) do{ _SEP_2_P(a,b); serialprintPGM(c); }while(0)
#define _SELP_4_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_2_P(V); }while(0)
#define _SELP_5_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_3_P(V); }while(0)
#define _SELP_6_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_4_P(V); }while(0)
#define _SELP_7_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_5_P(V); }while(0)
#define _SELP_8_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_6_P(V); }while(0)
#define _SELP_9_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_7_P(V); }while(0)
#define _SELP_10_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_8_P(V); }while(0)
#define _SELP_11_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_9_P(V); }while(0)
#define _SELP_12_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_10_P(V); }while(0)
#define _SELP_13_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_11_P(V); }while(0)
#define _SELP_14_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_12_P(V); }while(0)
#define _SELP_15_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_13_P(V); }while(0)
#define _SELP_16_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_14_P(V); }while(0)
#define _SELP_17_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_15_P(V); }while(0)
#define _SELP_18_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_16_P(V); }while(0)
#define _SELP_19_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_17_P(V); }while(0)
#define _SELP_20_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_18_P(V); }while(0)
#define _SELP_21_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_19_P(V); }while(0)
#define _SELP_22_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_20_P(V); }while(0)
#define _SELP_23_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_21_P(V); }while(0)
#define _SELP_24_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_22_P(V); }while(0)
#define _SELP_25_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_23_P(V); }while(0)
#define _SELP_26_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_24_P(V); }while(0)
#define _SELP_27_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_25_P(V); }while(0)
#define _SELP_28_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_26_P(V); }while(0)
#define _SELP_29_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_27_P(V); }while(0)
#define _SELP_30_P(a,b,V...) do{ _SEP_2_P(a,b); _SELP_28_P(V); }while(0) // Eat two args, pass the rest up
#define SERIAL_ECHOLNPAIR_P(V...) _SELP_N_P(NUM_ARGS(V),V)
#ifdef AllowDifferentTypeInList
inline void SERIAL_ECHOLIST_IMPL() {}
template
void SERIAL_ECHOLIST_IMPL(T && t) { SERIAL_IMPL.print(t); }
template
void SERIAL_ECHOLIST_IMPL(T && t, Args && ... args) {
SERIAL_IMPL.print(t);
serialprintPGM(PSTR(", "));
SERIAL_ECHOLIST_IMPL(args...);
}
template
void SERIAL_ECHOLIST(PGM_P const str, Args && ... args) {
SERIAL_IMPL.print(str);
SERIAL_ECHOLIST_IMPL(args...);
}
#else // Optimization if the listed type are all the same (seems to be the case in the codebase so use that instead)
template
void SERIAL_ECHOLIST(PGM_P const str, Args && ... args) {
serialprintPGM(str);
typename Private::first_type_of::type values[] = { args... };
constexpr size_t argsSize = sizeof...(args);
for (size_t i = 0; i < argsSize; i++) {
if (i) serialprintPGM(PSTR(", "));
SERIAL_IMPL.print(values[i]);
}
}
#endif
#define SERIAL_ECHOPGM_P(P) (serialprintPGM(P))
#define SERIAL_ECHOLNPGM_P(P) (serialprintPGM(P "\n"))
#define SERIAL_ECHOPGM(S) (serialprintPGM(PSTR(S)))
#define SERIAL_ECHOLNPGM(S) (serialprintPGM(PSTR(S "\n")))
#define SERIAL_ECHOPAIR_F_P(P,V...) do{ serialprintPGM(P); SERIAL_ECHO_F(V); }while(0)
#define SERIAL_ECHOLNPAIR_F_P(V...) do{ SERIAL_ECHOPAIR_F_P(V); SERIAL_EOL(); }while(0)
#define SERIAL_ECHOPAIR_F(S,V...) SERIAL_ECHOPAIR_F_P(PSTR(S),V)
#define SERIAL_ECHOLNPAIR_F(V...) do{ SERIAL_ECHOPAIR_F(V); SERIAL_EOL(); }while(0)
#define SERIAL_ECHO_START() serial_echo_start()
#define SERIAL_ERROR_START() serial_error_start()
#define SERIAL_EOL() SERIAL_CHAR('\n')
#define SERIAL_ECHO_MSG(V...) do{ SERIAL_ECHO_START(); SERIAL_ECHOLNPAIR(V); }while(0)
#define SERIAL_ERROR_MSG(V...) do{ SERIAL_ERROR_START(); SERIAL_ECHOLNPAIR(V); }while(0)
#define SERIAL_ECHO_SP(C) serial_spaces(C)
#define SERIAL_ECHO_TERNARY(TF, PRE, ON, OFF, POST) serial_ternary(TF, PSTR(PRE), PSTR(ON), PSTR(OFF), PSTR(POST))
#if SERIAL_FLOAT_PRECISION
#define SERIAL_DECIMAL(V) SERIAL_PRINT(V, SERIAL_FLOAT_PRECISION)
#else
#define SERIAL_DECIMAL(V) SERIAL_ECHO(V)
#endif
//
// Functions for serial printing from PROGMEM. (Saves loads of SRAM.)
//
void serial_echopair_PGM(PGM_P const s_P, serial_char_t v);
void serial_echopair_PGM(PGM_P const s_P, const char *v);
void serial_echopair_PGM(PGM_P const s_P, char v);
void serial_echopair_PGM(PGM_P const s_P, int v);
void serial_echopair_PGM(PGM_P const s_P, long v);
void serial_echopair_PGM(PGM_P const s_P, float v);
void serial_echopair_PGM(PGM_P const s_P, double v);
void serial_echopair_PGM(PGM_P const s_P, unsigned char v);
void serial_echopair_PGM(PGM_P const s_P, unsigned int v);
void serial_echopair_PGM(PGM_P const s_P, unsigned long v);
inline void serial_echopair_PGM(PGM_P const s_P, bool v) { serial_echopair_PGM(s_P, (int)v); }
inline void serial_echopair_PGM(PGM_P const s_P, void *v) { serial_echopair_PGM(s_P, (uintptr_t)v); }
void serial_echo_start();
void serial_error_start();
void serial_ternary(const bool onoff, PGM_P const pre, PGM_P const on, PGM_P const off, PGM_P const post=nullptr);
void serialprint_onoff(const bool onoff);
void serialprintln_onoff(const bool onoff);
void serialprint_truefalse(const bool tf);
void serial_spaces(uint8_t count);
void print_bin(const uint16_t val);
void print_xyz(const float &x, const float &y, const float &z, PGM_P const prefix=nullptr, PGM_P const suffix=nullptr);
inline void print_xyz(const xyz_pos_t &xyz, PGM_P const prefix=nullptr, PGM_P const suffix=nullptr) {
print_xyz(xyz.x, xyz.y, xyz.z, prefix, suffix);
}
#define SERIAL_POS(SUFFIX,VAR) do { print_xyz(VAR, PSTR(" " STRINGIFY(VAR) "="), PSTR(" : " SUFFIX "\n")); }while(0)
#define SERIAL_XYZ(PREFIX,V...) do { print_xyz(V, PSTR(PREFIX), nullptr); }while(0)