Flags for MarlinSerial instance features (#21318)
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@ -27,11 +27,12 @@
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// Useful macro for stopping the CPU on an unexpected condition
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// This is used like SERIAL_ECHOPAIR, that is: a key-value call of the local variables you want
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// to dump to the serial port before stopping the CPU.
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#define BUG_ON(V...) do { SERIAL_ECHOPAIR(ONLY_FILENAME, __LINE__, ": "); SERIAL_ECHOLNPAIR(V); SERIAL_FLUSHTX(); *(char*)0 = 42; } while(0)
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// \/ Don't replace by SERIAL_ECHOPAIR since ONLY_FILENAME cannot be transformed to a PGM string on Arduino and it breaks building
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#define BUG_ON(V...) do { SERIAL_ECHO(ONLY_FILENAME); SERIAL_ECHO(__LINE__); SERIAL_ECHOLN(": "); SERIAL_ECHOLNPAIR(V); SERIAL_FLUSHTX(); *(char*)0 = 42; } while(0)
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#elif ENABLED(MARLIN_DEV_MODE)
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// Don't stop the CPU here, but at least dump the bug on the serial port
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//#define BUG_ON(V...) do { SERIAL_ECHOPAIR(ONLY_FILENAME, __LINE__, ": BUG!\n"); SERIAL_ECHOLNPAIR(V); SERIAL_FLUSHTX(); } while(0)
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#define BUG_ON(V...) NOOP
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// \/ Don't replace by SERIAL_ECHOPAIR since ONLY_FILENAME cannot be transformed to a PGM string on Arduino and it breaks building
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#define BUG_ON(V...) do { SERIAL_ECHO(ONLY_FILENAME); SERIAL_ECHO(__LINE__); SERIAL_ECHOLN(": BUG!"); SERIAL_ECHOLNPAIR(V); SERIAL_FLUSHTX(); } while(0)
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#else
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// Release mode, let's ignore the bug
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#define BUG_ON(V...) NOOP
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@ -318,6 +318,16 @@
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#endif
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// Allow manipulating enumeration value like flags without ugly cast everywhere
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#define ENUM_FLAGS(T) \
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FORCE_INLINE constexpr T operator&(T x, T y) { return static_cast<T>(static_cast<int>(x) & static_cast<int>(y)); } \
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FORCE_INLINE constexpr T operator|(T x, T y) { return static_cast<T>(static_cast<int>(x) | static_cast<int>(y)); } \
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FORCE_INLINE constexpr T operator^(T x, T y) { return static_cast<T>(static_cast<int>(x) ^ static_cast<int>(y)); } \
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FORCE_INLINE constexpr T operator~(T x) { return static_cast<T>(~static_cast<int>(x)); } \
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FORCE_INLINE T & operator&=(T &x, T y) { return x &= y; } \
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FORCE_INLINE T & operator|=(T &x, T y) { return x |= y; } \
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FORCE_INLINE T & operator^=(T &x, T y) { return x ^= y; }
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// C++11 solution that is standard compliant. <type_traits> is not available on all platform
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namespace Private {
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template<bool, typename _Tp = void> struct enable_if { };
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@ -357,23 +367,43 @@
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return *str ? findStringEnd(str + 1) : str;
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}
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// Check whether a string contains a slash
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constexpr bool containsSlash(const char *str) {
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return *str == '/' ? true : (*str ? containsSlash(str + 1) : false);
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// Check whether a string contains a specific character
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constexpr bool contains(const char *str, const char ch) {
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return *str == ch ? true : (*str ? contains(str + 1, ch) : false);
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}
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// Find the last position of the slash
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constexpr const char* findLastSlashPos(const char *str) {
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return *str == '/' ? (str + 1) : findLastSlashPos(str - 1);
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// Find the last position of the specific character (should be called with findStringEnd)
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constexpr const char* findLastPos(const char *str, const char ch) {
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return *str == ch ? (str + 1) : findLastPos(str - 1, ch);
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}
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// Compile-time evaluation of the last part of a file path
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// Typically used to shorten the path to file in compiled strings
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// CompileTimeString::baseName(__FILE__) returns "macros.h" and not /path/to/Marlin/src/core/macros.h
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constexpr const char* baseName(const char *str) {
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return containsSlash(str) ? findLastSlashPos(findStringEnd(str)) : str;
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return contains(str, '/') ? findLastPos(findStringEnd(str), '/') : str;
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}
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// Find the first occurence of a character in a string (or return the last position in the string)
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constexpr const char* findFirst(const char *str, const char ch) {
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return *str == ch || *str == 0 ? (str + 1) : findFirst(str + 1, ch);
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}
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// Compute the string length at compile time
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constexpr unsigned stringLen(const char *str) {
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return *str == 0 ? 0 : 1 + stringLen(str + 1);
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}
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}
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#define ONLY_FILENAME CompileTimeString::baseName(__FILE__)
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/** Get the templated type name. This does not depends on RTTI, but on the preprocessor, so it should be quite safe to use even on old compilers.
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WARNING: DO NOT RENAME THIS FUNCTION (or change the text inside the function to match what the preprocessor will generate)
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The name is chosen very short since the binary will store "const char* gtn(T*) [with T = YourTypeHere]" so avoid long function name here */
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template <typename T>
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inline const char* gtn(T*) {
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// It works on GCC by instantiating __PRETTY_FUNCTION__ and parsing the result. So the syntax here is very limited to GCC output
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constexpr unsigned verboseChatLen = sizeof("const char* gtn(T*) [with T = ") - 1;
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static char templateType[sizeof(__PRETTY_FUNCTION__) - verboseChatLen] = {};
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__builtin_memcpy(templateType, __PRETTY_FUNCTION__ + verboseChatLen, sizeof(__PRETTY_FUNCTION__) - verboseChatLen - 2);
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return templateType;
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}
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#else
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@ -146,7 +146,7 @@ inline void SERIAL_ECHO(serial_char_t x) { SERIAL_IMPL.write(x.c); }
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#define AS_CHAR(C) serial_char_t(C)
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// SERIAL_ECHO_F prints a floating point value with optional precision
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inline void SERIAL_ECHO_F(EnsureDouble x, int digit = 2) { SERIAL_IMPL.print(x, digit); }
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inline void SERIAL_ECHO_F(EnsureDouble x, int digit=2) { SERIAL_IMPL.print(x, digit); }
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template <typename T>
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void SERIAL_ECHOLN(T x) { SERIAL_IMPL.println(x); }
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@ -45,10 +45,6 @@ struct serial_index_t {
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constexpr serial_index_t() : index(-1) {}
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};
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// flushTX is not implemented in all HAL, so use SFINAE to call the method where it is.
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CALL_IF_EXISTS_IMPL(void, flushTX);
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CALL_IF_EXISTS_IMPL(bool, connected, true);
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// In order to catch usage errors in code, we make the base to encode number explicit
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// If given a number (and not this enum), the compiler will reject the overload, falling back to the (double, digit) version
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// We don't want hidden conversion of the first parameter to double, so it has to be as hard to do for the compiler as creating this enum
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@ -59,19 +55,34 @@ enum class PrintBase {
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Bin = 2
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};
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// A simple forward struct that prevent the compiler to select print(double, int) as a default overload for any type different than
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// double or float. For double or float, a conversion exists so the call will be transparent
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// A simple feature list enumeration
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enum class SerialFeature {
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None = 0x00,
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MeatPack = 0x01, //!< Enabled when Meatpack is present
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BinaryFileTransfer = 0x02, //!< Enabled for BinaryFile transfer support (in the future)
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Virtual = 0x04, //!< Enabled for virtual serial port (like Telnet / Websocket / ...)
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Hookable = 0x08, //!< Enabled if the serial class supports a setHook method
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};
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ENUM_FLAGS(SerialFeature);
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// flushTX is not implemented in all HAL, so use SFINAE to call the method where it is.
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CALL_IF_EXISTS_IMPL(void, flushTX);
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CALL_IF_EXISTS_IMPL(bool, connected, true);
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CALL_IF_EXISTS_IMPL(SerialFeature, features, SerialFeature::None);
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// A simple forward struct to prevent the compiler from selecting print(double, int) as a default overload
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// for any type other than double/float. For double/float, a conversion exists so the call will be invisible.
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struct EnsureDouble {
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double a;
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FORCE_INLINE operator double() { return a; }
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// If the compiler breaks on ambiguity here, it's likely because you're calling print(X, base) with X not a double or a float, and a
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// base that's not one of PrintBase's value. This exact code is made to detect such error, you NEED to set a base explicitely like this:
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// If the compiler breaks on ambiguity here, it's likely because print(X, base) is called with X not a double/float, and
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// a base that's not a PrintBase value. This code is made to detect the error. You MUST set a base explicitly like this:
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// SERIAL_PRINT(v, PrintBase::Hex)
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FORCE_INLINE EnsureDouble(double a) : a(a) {}
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FORCE_INLINE EnsureDouble(float a) : a(a) {}
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};
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// Using Curiously Recurring Template Pattern here to avoid virtual table cost when compiling.
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// Using Curiously-Recurring Template Pattern here to avoid virtual table cost when compiling.
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// Since the real serial class is known at compile time, this results in the compiler writing
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// a completely efficient code.
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template <class Child>
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@ -85,27 +96,44 @@ struct SerialBase {
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SerialBase(const bool) {}
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#endif
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#define SerialChild static_cast<Child*>(this)
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// Static dispatch methods below:
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// The most important method here is where it all ends to:
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size_t write(uint8_t c) { return static_cast<Child*>(this)->write(c); }
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size_t write(uint8_t c) { return SerialChild->write(c); }
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// Called when the parser finished processing an instruction, usually build to nothing
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void msgDone() { static_cast<Child*>(this)->msgDone(); }
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// Called upon initialization
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void begin(const long baudRate) { static_cast<Child*>(this)->begin(baudRate); }
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// Called upon destruction
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void end() { static_cast<Child*>(this)->end(); }
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void msgDone() const { SerialChild->msgDone(); }
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// Called on initialization
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void begin(const long baudRate) { SerialChild->begin(baudRate); }
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// Called on destruction
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void end() { SerialChild->end(); }
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/** Check for available data from the port
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@param index The port index, usually 0 */
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int available(serial_index_t index = 0) { return static_cast<Child*>(this)->available(index); }
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int available(serial_index_t index=0) const { return SerialChild->available(index); }
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/** Read a value from the port
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@param index The port index, usually 0 */
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int read(serial_index_t index = 0) { return static_cast<Child*>(this)->read(index); }
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int read(serial_index_t index=0) { return SerialChild->read(index); }
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/** Combine the features of this serial instance and return it
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@param index The port index, usually 0 */
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SerialFeature features(serial_index_t index=0) const { return static_cast<const Child*>(this)->features(index); }
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// Check if the serial port has a feature
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bool has_feature(serial_index_t index, SerialFeature flag) const { (features(index) & flag) != SerialFeature::None; }
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// Check if the serial port is connected (usually bypassed)
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bool connected() { return static_cast<Child*>(this)->connected(); }
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bool connected() const { return SerialChild->connected(); }
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// Redirect flush
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void flush() { static_cast<Child*>(this)->flush(); }
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void flush() { SerialChild->flush(); }
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// Not all implementation have a flushTX, so let's call them only if the child has the implementation
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void flushTX() { CALL_IF_EXISTS(void, static_cast<Child*>(this), flushTX); }
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void flushTX() { CALL_IF_EXISTS(void, SerialChild, flushTX); }
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// Glue code here
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FORCE_INLINE void write(const char *str) { while (*str) write(*str++); }
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@ -65,6 +65,8 @@ struct BaseSerial : public SerialBase< BaseSerial<SerialT> >, public SerialT {
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bool connected() { return CALL_IF_EXISTS(bool, static_cast<SerialT*>(this), connected);; }
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void flushTX() { CALL_IF_EXISTS(void, static_cast<SerialT*>(this), flushTX); }
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SerialFeature features(serial_index_t index) const { return CALL_IF_EXISTS(SerialFeature, static_cast<const SerialT*>(this), features, index); }
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// We have 2 implementation of the same method in both base class, let's say which one we want
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using SerialT::available;
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using SerialT::read;
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@ -98,10 +100,11 @@ struct ConditionalSerial : public SerialBase< ConditionalSerial<SerialT> > {
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bool connected() { return CALL_IF_EXISTS(bool, &out, connected); }
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void flushTX() { CALL_IF_EXISTS(void, &out, flushTX); }
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int available(serial_index_t ) { return (int)out.available(); }
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int read(serial_index_t ) { return (int)out.read(); }
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int available(serial_index_t) { return (int)out.available(); }
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int read(serial_index_t) { return (int)out.read(); }
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int available() { return (int)out.available(); }
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int read() { return (int)out.read(); }
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SerialFeature features(serial_index_t index) const { return CALL_IF_EXISTS(SerialFeature, &out, features, index); }
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ConditionalSerial(bool & conditionVariable, SerialT & out, const bool e) : BaseClassT(e), condition(conditionVariable), out(out) {}
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};
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@ -126,6 +129,7 @@ struct ForwardSerial : public SerialBase< ForwardSerial<SerialT> > {
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int read(serial_index_t) { return (int)out.read(); }
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int available() { return (int)out.available(); }
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int read() { return (int)out.read(); }
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SerialFeature features(serial_index_t index) const { return CALL_IF_EXISTS(SerialFeature, &out, features, index); }
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ForwardSerial(const bool e, SerialT & out) : BaseClassT(e), out(out) {}
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};
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@ -163,9 +167,15 @@ struct RuntimeSerial : public SerialBase< RuntimeSerial<SerialT> >, public Seria
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// Underlying implementation might use Arduino's bool operator
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bool connected() {
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return Private::HasMember_connected<SerialT>::value ? CALL_IF_EXISTS(bool, static_cast<SerialT*>(this), connected) : static_cast<SerialT*>(this)->operator bool();
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return Private::HasMember_connected<SerialT>::value
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? CALL_IF_EXISTS(bool, static_cast<SerialT*>(this), connected)
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: static_cast<SerialT*>(this)->operator bool();
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}
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void flushTX() { CALL_IF_EXISTS(void, static_cast<SerialT*>(this), flushTX); }
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void flushTX() { CALL_IF_EXISTS(void, static_cast<SerialT*>(this), flushTX); }
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// Append Hookable for this class
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SerialFeature features(serial_index_t index) const { return SerialFeature::Hookable | CALL_IF_EXISTS(SerialFeature, static_cast<const SerialT*>(this), features, index); }
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void setHook(WriteHook writeHook = 0, EndOfMessageHook eofHook = 0, void * userPointer = 0) {
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// Order is important here as serial code can be called inside interrupts
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@ -251,6 +261,15 @@ struct MultiSerial : public SerialBase< MultiSerial<Serial0T, Serial1T, offset,
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if (portMask.enabled(SecondOutput)) CALL_IF_EXISTS(void, &serial1, flushTX);
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}
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// Forward feature queries
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SerialFeature features(serial_index_t index) const {
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if (index.within(0 + offset, step + offset - 1))
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return serial0.features(index);
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else if (index.within(step + offset, 2 * step + offset - 1))
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return serial1.features(index);
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return SerialFeature::None;
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}
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MultiSerial(Serial0T & serial0, Serial1T & serial1, const SerialMask mask = Both, const bool e = false) :
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BaseClassT(e),
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portMask(mask), serial0(serial0), serial1(serial1) {}
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@ -142,6 +142,8 @@ struct MeatpackSerial : public SerialBase <MeatpackSerial < SerialT >> {
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// Existing instances implement Arduino's operator bool, so use that if it's available
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bool connected() { return Private::HasMember_connected<SerialT>::value ? CALL_IF_EXISTS(bool, &out, connected) : (bool)out; }
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void flushTX() { CALL_IF_EXISTS(void, &out, flushTX); }
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SerialFeature features(serial_index_t index) const { return SerialFeature::MeatPack | CALL_IF_EXISTS(SerialFeature, &out, features, index); }
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int available(serial_index_t index) {
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if (charCount) return charCount; // The buffer still has data
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@ -167,6 +167,11 @@
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dump_delay_accuracy_check();
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break;
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case 7: // D7 dump the current serial port type (hence configuration)
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SERIAL_ECHOLNPAIR("Current serial configuration RX_BS:", RX_BUFFER_SIZE, ", TX_BS:", TX_BUFFER_SIZE);
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SERIAL_ECHOLN(gtn(&SERIAL_IMPL));
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break;
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case 100: { // D100 Disable heaters and attempt a hard hang (Watchdog Test)
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SERIAL_ECHOLNPGM("Disabling heaters and attempting to trigger Watchdog");
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SERIAL_ECHOLNPGM("(USE_WATCHDOG " TERN(USE_WATCHDOG, "ENABLED", "DISABLED") ")");
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#include "../gcode.h"
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#include "../../inc/MarlinConfig.h"
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#include "../queue.h" // for getting the command port
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#if ENABLED(M115_GEOMETRY_REPORT)
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#include "../../module/motion.h"
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@ -59,6 +61,9 @@ void GcodeSuite::M115() {
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#if ENABLED(EXTENDED_CAPABILITIES_REPORT)
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// The port that sent M115
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serial_index_t port = queue.ring_buffer.command_port();
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// PAREN_COMMENTS
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TERN_(PAREN_COMMENTS, cap_line(PSTR("PAREN_COMMENTS"), true));
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@ -69,7 +74,7 @@ void GcodeSuite::M115() {
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cap_line(PSTR("SERIAL_XON_XOFF"), ENABLED(SERIAL_XON_XOFF));
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// BINARY_FILE_TRANSFER (M28 B1)
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cap_line(PSTR("BINARY_FILE_TRANSFER"), ENABLED(BINARY_FILE_TRANSFER));
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cap_line(PSTR("BINARY_FILE_TRANSFER"), ENABLED(BINARY_FILE_TRANSFER)); // TODO: Use SERIAL_IMPL.has_feature(port, SerialFeature::BinaryFileTransfer) once implemented
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// EEPROM (M500, M501)
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cap_line(PSTR("EEPROM"), ENABLED(EEPROM_SETTINGS));
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@ -148,7 +153,7 @@ void GcodeSuite::M115() {
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cap_line(PSTR("COOLER_TEMPERATURE"), ENABLED(HAS_COOLER));
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// MEATPACK Compression
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cap_line(PSTR("MEATPACK"), ENABLED(HAS_MEATPACK));
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cap_line(PSTR("MEATPACK"), SERIAL_IMPL.has_feature(port, SerialFeature::MeatPack));
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// Machine Geometry
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#if ENABLED(M115_GEOMETRY_REPORT)
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