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/****************************************************************************************************
RepRapFirmware - Main Include
This includes all the other include files in the right order and defines some globals.
No other definitions or information should be in here.
-----------------------------------------------------------------------------------------------------
Version 0.1
18 November 2012
Adrian Bowyer
RepRap Professional Ltd
http://reprappro.com
Licence: GPL
****************************************************************************************************/
#ifndef REPRAPFIRMWARE_H
#define REPRAPFIRMWARE_H
#include <cstddef> // for size_t
#include <cfloat>
#include <cstdarg>
#include <climits> // for CHAR_BIT
#include "ecv.h"
#include "Core.h"
typedef uint16_t PwmFrequency; // type used to represent a PWM frequency. 0 sometimes means "default".
#include "Configuration.h"
#include "Pins.h"
#include "Libraries/General/SafeStrtod.h"
#include "Libraries/General/SafeVsnprintf.h"
#include "Libraries/General/StringRef.h"
// Module numbers and names, used for diagnostics and debug
enum Module : uint8_t
{
modulePlatform = 0,
moduleNetwork = 1,
moduleWebserver = 2,
moduleGcodes = 3,
moduleMove = 4,
moduleHeat = 5,
moduleDda = 6,
moduleRoland = 7,
moduleScanner = 8,
modulePrintMonitor = 9,
moduleStorage = 10,
modulePortControl = 11,
moduleDuetExpansion = 12,
moduleFilamentSensors = 13,
moduleWiFi = 14,
moduleDisplay = 15,
numModules = 16, // make this one greater than the last module number
noModule = 16
};
extern const char * const moduleName[];
// Warn of what's to come, so we can use pointers to classes without including the entire header files
class Network;
class Platform;
class GCodes;
class Move;
class DDA;
class Kinematics;
class Heat;
class PID;
class TemperatureSensor;
class Tool;
class Roland;
class Scanner;
class PrintMonitor;
class RepRap;
class FileStore;
class OutputBuffer;
class OutputStack;
class GCodeBuffer;
class GCodeQueue;
class FilamentMonitor;
class RandomProbePointSet;
class Logger;
#if SUPPORT_IOBITS
class PortControl;
#endif
#if SUPPORT_12864_LCD
class Display;
#endif
// Define floating point type to use for calculations where we would like high precision in matrix calculations
#if SAM4E || SAM4S || SAME70
typedef double floatc_t; // type of matrix element used for calibration
#else
// We are more memory-constrained on the SAM3X
typedef float floatc_t; // type of matrix element used for calibration
#endif
typedef uint32_t AxesBitmap; // Type of a bitmap representing a set of axes
typedef uint32_t DriversBitmap; // Type of a bitmap representing a set of driver numbers
typedef uint32_t FansBitmap; // Type of a bitmap representing a set of fan numbers
// A single instance of the RepRap class contains all the others
extern RepRap reprap;
// Debugging support
extern "C" void debugPrintf(const char* fmt, ...) __attribute__ ((format (printf, 1, 2)));
#define DEBUG_HERE do { } while (false)
//#define DEBUG_HERE do { debugPrintf("At " __FILE__ " line %d\n", __LINE__); delay(50); } while (false)
// Functions and globals not part of any class
#ifdef RTOS
void delay(uint32_t ms);
#else
inline void delay(uint32_t ms)
{
coreDelay(ms);
}
#endif
bool StringEndsWith(const char* string, const char* ending);
bool StringStartsWith(const char* string, const char* starting);
bool StringEquals(const char* s1, const char* s2);
int StringContains(const char* string, const char* match);
void SafeStrncpy(char *dst, const char *src, size_t length) pre(length != 0);
void SafeStrncat(char *dst, const char *src, size_t length) pre(length != 0);
double HideNan(float val);
void ListDrivers(const StringRef& str, DriversBitmap drivers);
// Macro to assign an array from an initialiser list
#define ARRAY_INIT(_dest, _init) static_assert(sizeof(_dest) == sizeof(_init), "Incompatible array types"); memcpy(_dest, _init, sizeof(_init));
// UTF8 code for the degree-symbol
#define DEGREE_SYMBOL "\xC2\xB0" // Unicode degree-symbol as UTF8
// Classes to facilitate range-based for loops that iterate from 0 up to just below a limit
template<class T> class SimpleRangeIterator
{
public:
SimpleRangeIterator(T value_) : val(value_) {}
bool operator != (SimpleRangeIterator<T> const& other) const { return val != other.val; }
T const& operator*() const { return val; }
SimpleRangeIterator& operator++() { ++val; return *this; }
private:
T val;
};
template<class T> class SimpleRange
{
public:
SimpleRange(T limit) : _end(limit) {}
SimpleRangeIterator<T> begin() const { return SimpleRangeIterator<T>(0); }
SimpleRangeIterator<T> end() const { return SimpleRangeIterator<T>(_end); }
private:
const T _end;
};
// Macro to create a SimpleRange from an array
#define ARRAY_INDICES(_arr) (SimpleRange<size_t>(ARRAY_SIZE(_arr)))
// Helper functions to work on bitmaps of various lengths.
// The primary purpose of these is to allow us to switch between 16, 32 and 64-bit bitmaps.
// Convert an unsigned integer to a bit in a bitmap
template<typename BitmapType> inline constexpr BitmapType MakeBitmap(unsigned int n)
{
return (BitmapType)1u << n;
}
// Make a bitmap with the lowest n bits set
template<typename BitmapType> inline constexpr BitmapType LowestNBits(unsigned int n)
{
return ((BitmapType)1u << n) - 1;
}
// Check if a particular bit is set in a bitmap
template<typename BitmapType> inline constexpr bool IsBitSet(BitmapType b, unsigned int n)
{
return (b & ((BitmapType)1u << n)) != 0;
}
// Set a bit in a bitmap
template<typename BitmapType> inline void SetBit(BitmapType &b, unsigned int n)
{
b |= ((BitmapType)1u << n);
}
// Clear a bit in a bitmap
template<typename BitmapType> inline void ClearBit(BitmapType &b, unsigned int n)
{
b &= ~((BitmapType)1u << n);
}
// Convert an array of longs to a bit map with overflow checking
template<typename BitmapType> BitmapType UnsignedArrayToBitMap(const uint32_t *arr, size_t numEntries)
{
BitmapType res = 0;
for (size_t i = 0; i < numEntries; ++i)
{
const uint32_t f = arr[i];
if (f < sizeof(BitmapType) * CHAR_BIT)
{
SetBit(res, f);
}
}
return res;
}
// Common definitions used by more than one module
constexpr size_t ScratchStringLength = 220; // standard length of a scratch string, enough to print delta parameters to
constexpr size_t ShortScratchStringLength = 50;
constexpr size_t XYZ_AXES = 3; // The number of Cartesian axes
constexpr size_t X_AXIS = 0, Y_AXIS = 1, Z_AXIS = 2, E0_AXIS = 3; // The indices of the Cartesian axes in drive arrays
constexpr size_t CoreXYU_AXES = 5; // The number of axes in a CoreXYU machine (there is a hidden V axis)
constexpr size_t CoreXYUV_AXES = 5; // The number of axes in a CoreXYUV machine
constexpr size_t U_AXIS = 3, V_AXIS = 4; // The indices of the U and V motors in a CoreXYU machine (needed by Platform)
// Common conversion factors
constexpr float MinutesToSeconds = 60.0;
constexpr float SecondsToMinutes = 1.0/MinutesToSeconds;
constexpr float SecondsToMillis = 1000.0;
constexpr float MillisToSeconds = 0.001;
constexpr float InchToMm = 25.4;
constexpr float Pi = 3.141592653589793;
constexpr float TwoPi = 3.141592653589793 * 2;
constexpr float DegreesToRadians = 3.141592653589793/180.0;
constexpr float RadiansToDegrees = 180.0/3.141592653589793;
#define DEGREE_SYMBOL "\xC2\xB0" // degree-symbol encoding in UTF8
// Type of an offset in a file
typedef uint32_t FilePosition;
const FilePosition noFilePosition = 0xFFFFFFFF;
// Interrupt priorities - must be chosen with care! 0 is the highest priority, 15 is the lowest.
#if SAM4E || SAME70
const uint32_t NvicPriorityWatchdog = 0; // the secondary watchdog has the highest priority
#endif
const uint32_t NvicPriorityPanelDueUart = 1; // UART is highest to avoid character loss (it has only a 1-character receive buffer)
const uint32_t NvicPriorityDriversSerialTMC = 2;// USART or UART used to control and monitor the smart drivers
const uint32_t NvicPrioritySystick = 3; // systick kicks the watchdog and starts the ADC conversions, so must be quite high
const uint32_t NvicPriorityPins = 4; // priority for GPIO pin interrupts - filament sensors must be higher than step
const uint32_t NvicPriorityStep = 5; // step interrupt is next highest, it can preempt most other interrupts
const uint32_t NvicPriorityWiFiUart = 6; // UART used to receive debug data from the WiFi module
const uint32_t NvicPriorityUSB = 6; // USB interrupt
const uint32_t NvicPriorityHSMCI = 6; // HSMCI command complete interrupt
#if HAS_LWIP_NETWORKING
const uint32_t NvicPriorityNetworkTick = 7; // priority for network tick interrupt
const uint32_t NvicPriorityEthernet = 7; // priority for Ethernet interface
#endif
const uint32_t NvicPrioritySpi = 7; // SPI is used for network transfers on Duet WiFi/Duet vEthernet
const uint32_t NvicPriorityTwi = 8; // TWI is used to read endstop and other inputs on the DueXn
#endif
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