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Support for up to 9 axes (#23112, #24036, #24231)

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This commit is contained in:
Scott Lahteine
2022-04-29 15:21:15 -05:00
parent 369542db3b
commit fd13a928c1
103 changed files with 4553 additions and 799 deletions
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5
Marlin/src/core/drivers.h
View File

@ -63,6 +63,9 @@
#define AXIS_DRIVER_TYPE_I(T) _AXIS_DRIVER_TYPE(I,T)
#define AXIS_DRIVER_TYPE_J(T) _AXIS_DRIVER_TYPE(J,T)
#define AXIS_DRIVER_TYPE_K(T) _AXIS_DRIVER_TYPE(K,T)
#define AXIS_DRIVER_TYPE_U(T) _AXIS_DRIVER_TYPE(U,T)
#define AXIS_DRIVER_TYPE_V(T) _AXIS_DRIVER_TYPE(V,T)
#define AXIS_DRIVER_TYPE_W(T) _AXIS_DRIVER_TYPE(W,T)
#define AXIS_DRIVER_TYPE_X2(T) (HAS_X2_STEPPER && _AXIS_DRIVER_TYPE(X2,T))
#define AXIS_DRIVER_TYPE_Y2(T) (HAS_DUAL_Y_STEPPERS && _AXIS_DRIVER_TYPE(Y2,T))
@ -87,6 +90,7 @@
#define HAS_DRIVER(T) ( AXIS_DRIVER_TYPE_X(T) || AXIS_DRIVER_TYPE_Y(T) || AXIS_DRIVER_TYPE_Z(T) \
|| AXIS_DRIVER_TYPE_I(T) || AXIS_DRIVER_TYPE_J(T) || AXIS_DRIVER_TYPE_K(T) \
|| AXIS_DRIVER_TYPE_U(T) || AXIS_DRIVER_TYPE_V(T) || AXIS_DRIVER_TYPE_W(T) \
|| AXIS_DRIVER_TYPE_X2(T) || AXIS_DRIVER_TYPE_Y2(T) || AXIS_DRIVER_TYPE_Z2(T) \
|| AXIS_DRIVER_TYPE_Z3(T) || AXIS_DRIVER_TYPE_Z4(T) || HAS_E_DRIVER(T) )
@ -161,6 +165,7 @@
|| AXIS_HAS_##T(Y) || AXIS_HAS_##T(Y2) \
|| AXIS_HAS_##T(Z) || AXIS_HAS_##T(Z2) || AXIS_HAS_##T(Z3) || AXIS_HAS_##T(Z4) \
|| AXIS_HAS_##T(I) || AXIS_HAS_##T(J) || AXIS_HAS_##T(K) \
|| AXIS_HAS_##T(U) || AXIS_HAS_##T(V) || AXIS_HAS_##T(W) \
|| E_AXIS_HAS(T) )
#if ANY_AXIS_HAS(STEALTHCHOP)

48
Marlin/src/core/language.h
View File

@ -457,6 +457,54 @@
#define STR_K ""
#endif
#if HAS_U_AXIS
#if AXIS7_NAME == 'U'
#define STR_U "U"
#define STR_U_MIN "u_min"
#define STR_U_MAX "u_max"
#elif AXIS7_NAME == 'V'
#define STR_U "V"
#define STR_U_MIN "v_min"
#define STR_U_MAX "v_max"
#elif AXIS7_NAME == 'W'
#define STR_U "W"
#define STR_U_MIN "w_min"
#define STR_U_MAX "w_max"
#else
#error "AXIS7_NAME can only be one of 'U', 'V', or 'W'."
#endif
#else
#define STR_U ""
#endif
#if HAS_V_AXIS
#if AXIS8_NAME == 'V'
#define STR_V "V"
#define STR_V_MIN "v_min"
#define STR_V_MAX "v_max"
#elif AXIS8_NAME == 'W'
#define STR_V "W"
#define STR_V_MIN "w_min"
#define STR_V_MAX "w_max"
#else
#error "AXIS8_NAME can only be one of 'V', or 'W'."
#endif
#else
#define STR_V ""
#endif
#if HAS_W_AXIS
#if AXIS9_NAME == 'W'
#define STR_W "W"
#define STR_W_MIN "w_min"
#define STR_W_MAX "w_max"
#else
#error "AXIS9_NAME can only be 'W'."
#endif
#else
#define STR_W ""
#endif
#if EITHER(HAS_MARLINUI_HD44780, IS_TFTGLCD_PANEL)
// Custom characters defined in the first 8 characters of the LCD

14
Marlin/src/core/macros.h
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@ -39,24 +39,36 @@
#define _ISTOP_ 0x04
#define _JSTOP_ 0x05
#define _KSTOP_ 0x06
#define _USTOP_ 0x07
#define _VSTOP_ 0x08
#define _WSTOP_ 0x09
#define _XMIN_ 0x11
#define _YMIN_ 0x12
#define _ZMIN_ 0x13
#define _IMIN_ 0x14
#define _JMIN_ 0x15
#define _KMIN_ 0x16
#define _UMIN_ 0x17
#define _VMIN_ 0x18
#define _WMIN_ 0x19
#define _XMAX_ 0x21
#define _YMAX_ 0x22
#define _ZMAX_ 0x23
#define _IMAX_ 0x24
#define _JMAX_ 0x25
#define _KMAX_ 0x26
#define _UMAX_ 0x27
#define _VMAX_ 0x28
#define _WMAX_ 0x29
#define _XDIAG_ 0x31
#define _YDIAG_ 0x32
#define _ZDIAG_ 0x33
#define _IDIAG_ 0x34
#define _JDIAG_ 0x35
#define _KDIAG_ 0x36
#define _UDIAG_ 0x37
#define _VDIAG_ 0x38
#define _WDIAG_ 0x39
#define _E0DIAG_ 0xE0
#define _E1DIAG_ 0xE1
#define _E2DIAG_ 0xE2
@ -350,7 +362,7 @@
#define _LIST_N(N,V...) LIST_##N(V)
#define LIST_N(N,V...) _LIST_N(N,V)
#define LIST_N_1(N,K) _LIST_N(N,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K)
#define LIST_N_1(N,K) _LIST_N(N,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K,K)
#define ARRAY_N(N,V...) { _LIST_N(N,V) }
#define ARRAY_N_1(N,K) { LIST_N_1(N,K) }

8
Marlin/src/core/serial.cpp
View File

@ -32,14 +32,18 @@ uint8_t marlin_debug_flags = MARLIN_DEBUG_NONE;
// Commonly-used strings in serial output
PGMSTR(NUL_STR, ""); PGMSTR(SP_P_STR, " P"); PGMSTR(SP_T_STR, " T");
PGMSTR(X_STR, "X"); PGMSTR(Y_STR, "Y"); PGMSTR(Z_STR, "Z"); PGMSTR(E_STR, "E");
PGMSTR(U_STR, STR_U); PGMSTR(V_STR, STR_V); PGMSTR(W_STR, STR_W);
PGMSTR(X_LBL, "X:"); PGMSTR(Y_LBL, "Y:"); PGMSTR(Z_LBL, "Z:"); PGMSTR(E_LBL, "E:");
PGMSTR(U_LBL, STR_U ":"); PGMSTR(V_LBL, STR_V ":"); PGMSTR(W_LBL, STR_W ":");
PGMSTR(SP_A_STR, " A"); PGMSTR(SP_B_STR, " B"); PGMSTR(SP_C_STR, " C");
PGMSTR(SP_X_STR, " X"); PGMSTR(SP_Y_STR, " Y"); PGMSTR(SP_Z_STR, " Z"); PGMSTR(SP_E_STR, " E");
PGMSTR(SP_X_LBL, " X:"); PGMSTR(SP_Y_LBL, " Y:"); PGMSTR(SP_Z_LBL, " Z:"); PGMSTR(SP_E_LBL, " E:");
PGMSTR(I_STR, STR_I); PGMSTR(J_STR, STR_J); PGMSTR(K_STR, STR_K);
PGMSTR(I_LBL, STR_I ":"); PGMSTR(J_LBL, STR_J ":"); PGMSTR(K_LBL, STR_K ":");
PGMSTR(SP_I_STR, " " STR_I); PGMSTR(SP_J_STR, " " STR_J); PGMSTR(SP_K_STR, " " STR_K);
PGMSTR(SP_U_STR, " " STR_U); PGMSTR(SP_V_STR, " " STR_V); PGMSTR(SP_W_STR, " " STR_W);
PGMSTR(SP_I_LBL, " " STR_I ":"); PGMSTR(SP_J_LBL, " " STR_J ":"); PGMSTR(SP_K_LBL, " " STR_K ":");
PGMSTR(SP_U_LBL, " " STR_U ":"); PGMSTR(SP_V_LBL, " " STR_V ":"); PGMSTR(SP_W_LBL, " " STR_W ":");
// Hook Meatpack if it's enabled on the first leaf
#if ENABLED(MEATPACK_ON_SERIAL_PORT_1)
@ -102,10 +106,10 @@ void print_bin(uint16_t val) {
}
}
void print_pos(LINEAR_AXIS_ARGS(const_float_t), FSTR_P const prefix/*=nullptr*/, FSTR_P const suffix/*=nullptr*/) {
void print_pos(NUM_AXIS_ARGS(const_float_t), FSTR_P const prefix/*=nullptr*/, FSTR_P const suffix/*=nullptr*/) {
if (prefix) serial_print(prefix);
SERIAL_ECHOPGM_P(
LIST_N(DOUBLE(LINEAR_AXES), SP_X_STR, x, SP_Y_STR, y, SP_Z_STR, z, SP_I_STR, i, SP_J_STR, j, SP_K_STR, k)
LIST_N(DOUBLE(NUM_AXES), SP_X_STR, x, SP_Y_STR, y, SP_Z_STR, z, SP_I_STR, i, SP_J_STR, j, SP_K_STR, k, SP_U_STR, u, SP_V_STR, v, SP_W_STR, w)
);
if (suffix) serial_print(suffix); else SERIAL_EOL();
}

21
Marlin/src/core/serial.h
View File

@ -29,17 +29,12 @@
#endif
// Commonly-used strings in serial output
extern const char NUL_STR[],
SP_X_STR[], SP_Y_STR[], SP_Z_STR[],
SP_A_STR[], SP_B_STR[], SP_C_STR[], SP_E_STR[],
SP_X_LBL[], SP_Y_LBL[], SP_Z_LBL[], SP_E_LBL[],
SP_I_STR[], SP_J_STR[], SP_K_STR[],
SP_I_LBL[], SP_J_LBL[], SP_K_LBL[],
SP_P_STR[], SP_T_STR[],
X_STR[], Y_STR[], Z_STR[], E_STR[],
I_STR[], J_STR[], K_STR[],
X_LBL[], Y_LBL[], Z_LBL[], E_LBL[],
I_LBL[], J_LBL[], K_LBL[];
extern const char NUL_STR[], SP_P_STR[], SP_T_STR[],
SP_A_STR[], SP_B_STR[], SP_C_STR[],
SP_X_STR[], SP_Y_STR[], SP_Z_STR[], SP_I_STR[], SP_J_STR[], SP_K_STR[], SP_U_STR[], SP_V_STR[], SP_W_STR[], SP_E_STR[],
SP_X_LBL[], SP_Y_LBL[], SP_Z_LBL[], SP_I_LBL[], SP_J_LBL[], SP_K_LBL[], SP_U_LBL[], SP_V_LBL[], SP_W_LBL[], SP_E_LBL[],
X_STR[], Y_STR[], Z_STR[], I_STR[], J_STR[], K_STR[], U_STR[], V_STR[], W_STR[], E_STR[],
X_LBL[], Y_LBL[], Z_LBL[], I_LBL[], J_LBL[], K_LBL[], U_LBL[], V_LBL[], W_LBL[], E_LBL[];
//
// Debugging flags for use by M111
@ -348,10 +343,10 @@ void serial_spaces(uint8_t count);
void serial_offset(const_float_t v, const uint8_t sp=0); // For v==0 draw space (sp==1) or plus (sp==2)
void print_bin(const uint16_t val);
void print_pos(LINEAR_AXIS_ARGS(const_float_t), FSTR_P const prefix=nullptr, FSTR_P const suffix=nullptr);
void print_pos(NUM_AXIS_ARGS(const_float_t), FSTR_P const prefix=nullptr, FSTR_P const suffix=nullptr);
inline void print_pos(const xyz_pos_t &xyz, FSTR_P const prefix=nullptr, FSTR_P const suffix=nullptr) {
print_pos(LINEAR_AXIS_ELEM(xyz), prefix, suffix);
print_pos(NUM_AXIS_ELEM(xyz), prefix, suffix);
}
#define SERIAL_POS(SUFFIX,VAR) do { print_pos(VAR, F(" " STRINGIFY(VAR) "="), F(" : " SUFFIX "\n")); }while(0)

382
Marlin/src/core/types.h
View File

@ -36,23 +36,33 @@ struct IF { typedef R type; };
template <class L, class R>
struct IF<true, L, R> { typedef L type; };
#define LINEAR_AXIS_GANG(V...) GANG_N(LINEAR_AXES, V)
#define LINEAR_AXIS_CODE(V...) CODE_N(LINEAR_AXES, V)
#define LINEAR_AXIS_LIST(V...) LIST_N(LINEAR_AXES, V)
#define LINEAR_AXIS_ARRAY(V...) { LINEAR_AXIS_LIST(V) }
#define LINEAR_AXIS_ARGS(T...) LINEAR_AXIS_LIST(T x, T y, T z, T i, T j, T k)
#define LINEAR_AXIS_ELEM(O) LINEAR_AXIS_LIST(O.x, O.y, O.z, O.i, O.j, O.k)
#define LINEAR_AXIS_DEFS(T,V) LINEAR_AXIS_LIST(T x=V, T y=V, T z=V, T i=V, T j=V, T k=V)
#define NUM_AXIS_GANG(V...) GANG_N(NUM_AXES, V)
#define NUM_AXIS_CODE(V...) CODE_N(NUM_AXES, V)
#define NUM_AXIS_LIST(V...) LIST_N(NUM_AXES, V)
#define NUM_AXIS_ARRAY(V...) { NUM_AXIS_LIST(V) }
#define NUM_AXIS_ARGS(T...) NUM_AXIS_LIST(T x, T y, T z, T i, T j, T k, T u, T v, T w)
#define NUM_AXIS_ELEM(O) NUM_AXIS_LIST(O.x, O.y, O.z, O.i, O.j, O.k, O.u, O.v, O.w)
#define NUM_AXIS_DEFS(T,V) NUM_AXIS_LIST(T x=V, T y=V, T z=V, T i=V, T j=V, T k=V, T u=V, T v=V, T w=V)
#define LOGICAL_AXIS_GANG(E,V...) LINEAR_AXIS_GANG(V) GANG_ITEM_E(E)
#define LOGICAL_AXIS_CODE(E,V...) LINEAR_AXIS_CODE(V) CODE_ITEM_E(E)
#define LOGICAL_AXIS_LIST(E,V...) LINEAR_AXIS_LIST(V) LIST_ITEM_E(E)
#define LOGICAL_AXIS_GANG(E,V...) NUM_AXIS_GANG(V) GANG_ITEM_E(E)
#define LOGICAL_AXIS_CODE(E,V...) NUM_AXIS_CODE(V) CODE_ITEM_E(E)
#define LOGICAL_AXIS_LIST(E,V...) NUM_AXIS_LIST(V) LIST_ITEM_E(E)
#define LOGICAL_AXIS_ARRAY(E,V...) { LOGICAL_AXIS_LIST(E,V) }
#define LOGICAL_AXIS_ARGS(T...) LOGICAL_AXIS_LIST(T e, T x, T y, T z, T i, T j, T k)
#define LOGICAL_AXIS_ELEM(O) LOGICAL_AXIS_LIST(O.e, O.x, O.y, O.z, O.i, O.j, O.k)
#define LOGICAL_AXIS_DECL(T,V) LOGICAL_AXIS_LIST(T e=V, T x=V, T y=V, T z=V, T i=V, T j=V, T k=V)
#define LOGICAL_AXIS_ARGS(T...) LOGICAL_AXIS_LIST(T e, T x, T y, T z, T i, T j, T k, T u, T v, T w)
#define LOGICAL_AXIS_ELEM(O) LOGICAL_AXIS_LIST(O.e, O.x, O.y, O.z, O.i, O.j, O.k, O.u, O.v, O.w)
#define LOGICAL_AXIS_DECL(T,V) LOGICAL_AXIS_LIST(T e=V, T x=V, T y=V, T z=V, T i=V, T j=V, T k=V, T u=V, T v=V, T w=V)
#define LOGICAL_AXES_STRING LOGICAL_AXIS_GANG("E", "X", "Y", "Z", STR_I, STR_J, STR_K)
#define LOGICAL_AXES_STRING LOGICAL_AXIS_GANG("E", "X", "Y", "Z", STR_I, STR_J, STR_K, STR_U, STR_V, STR_W)
#define XYZ_GANG(V...) GANG_N(PRIMARY_LINEAR_AXES, V)
#define XYZ_CODE(V...) CODE_N(PRIMARY_LINEAR_AXES, V)
#define SECONDARY_AXIS_GANG(V...) GANG_N(SECONDARY_AXES, V)
#define SECONDARY_AXIS_CODE(V...) CODE_N(SECONDARY_AXES, V)
#if HAS_ROTATIONAL_AXES
#define ROTATIONAL_AXIS_GANG(V...) GANG_N(ROTATIONAL_AXES, V)
#endif
#if HAS_EXTRUDERS
#define LIST_ITEM_E(N) , N
@ -64,7 +74,7 @@ struct IF<true, L, R> { typedef L type; };
#define GANG_ITEM_E(N)
#endif
#define AXIS_COLLISION(L) (AXIS4_NAME == L || AXIS5_NAME == L || AXIS6_NAME == L)
#define AXIS_COLLISION(L) (AXIS4_NAME == L || AXIS5_NAME == L || AXIS6_NAME == L || AXIS7_NAME == L || AXIS8_NAME == L || AXIS9_NAME == L)
// General Flags for some number of states
template<size_t N>
@ -129,7 +139,7 @@ typedef struct AxisFlags {
enum AxisEnum : uint8_t {
// Linear axes may be controlled directly or indirectly
LINEAR_AXIS_LIST(X_AXIS, Y_AXIS, Z_AXIS, I_AXIS, J_AXIS, K_AXIS)
NUM_AXIS_LIST(X_AXIS, Y_AXIS, Z_AXIS, I_AXIS, J_AXIS, K_AXIS, U_AXIS, V_AXIS, W_AXIS)
// Extruder axes may be considered distinctly
#define _EN_ITEM(N) , E##N##_AXIS
@ -163,12 +173,13 @@ enum AxisEnum : uint8_t {
};
typedef IF<(NUM_AXIS_ENUMS > 8), uint16_t, uint8_t>::type axis_bits_t;
typedef IF<(NUM_AXES > 8), uint16_t, uint8_t>::type linear_axis_bits_t;
//
// Loop over axes
//
#define LOOP_ABC(VAR) LOOP_S_LE_N(VAR, A_AXIS, C_AXIS)
#define LOOP_LINEAR_AXES(VAR) LOOP_S_L_N(VAR, X_AXIS, LINEAR_AXES)
#define LOOP_NUM_AXES(VAR) LOOP_S_L_N(VAR, X_AXIS, NUM_AXES)
#define LOOP_LOGICAL_AXES(VAR) LOOP_S_L_N(VAR, X_AXIS, LOGICAL_AXES)
#define LOOP_DISTINCT_AXES(VAR) LOOP_S_L_N(VAR, X_AXIS, DISTINCT_AXES)
#define LOOP_DISTINCT_E(VAR) LOOP_L_N(VAR, DISTINCT_E)
@ -313,10 +324,10 @@ struct XYval {
FI void set(const T px, const T py) { x = px; y = py; }
FI void set(const T (&arr)[XY]) { x = arr[0]; y = arr[1]; }
#endif
#if LINEAR_AXES > XY
FI void set(const T (&arr)[LINEAR_AXES]) { x = arr[0]; y = arr[1]; }
#if NUM_AXES > XY
FI void set(const T (&arr)[NUM_AXES]) { x = arr[0]; y = arr[1]; }
#endif
#if LOGICAL_AXES > LINEAR_AXES
#if LOGICAL_AXES > NUM_AXES
FI void set(const T (&arr)[LOGICAL_AXES]) { x = arr[0]; y = arr[1]; }
#if DISTINCT_AXES > LOGICAL_AXES
FI void set(const T (&arr)[DISTINCT_AXES]) { x = arr[0]; y = arr[1]; }
@ -438,60 +449,69 @@ struct XYval {
template<typename T>
struct XYZval {
union {
struct { T LINEAR_AXIS_ARGS(); };
struct { T LINEAR_AXIS_LIST(a, b, c, u, v, w); };
T pos[LINEAR_AXES];
struct { T NUM_AXIS_ARGS(); };
struct { T NUM_AXIS_LIST(a, b, c, _i, _j, _k, _u, _v, _w); };
T pos[NUM_AXES];
};
// Set all to 0
FI void reset() { LINEAR_AXIS_GANG(x =, y =, z =, i =, j =, k =) 0; }
FI void reset() { NUM_AXIS_GANG(x =, y =, z =, i =, j =, k =, u =, v =, w =) 0; }
// Setters taking struct types and arrays
FI void set(const T px) { x = px; }
FI void set(const T px, const T py) { x = px; y = py; }
FI void set(const XYval<T> pxy) { x = pxy.x; y = pxy.y; }
FI void set(const XYval<T> pxy, const T pz) { LINEAR_AXIS_CODE(x = pxy.x, y = pxy.y, z = pz, NOOP, NOOP, NOOP); }
FI void set(const XYval<T> pxy, const T pz) { NUM_AXIS_CODE(x = pxy.x, y = pxy.y, z = pz, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP); }
FI void set(const T (&arr)[XY]) { x = arr[0]; y = arr[1]; }
#if HAS_Z_AXIS
FI void set(const T (&arr)[LINEAR_AXES]) { LINEAR_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5]); }
FI void set(LINEAR_AXIS_ARGS(const T)) { LINEAR_AXIS_CODE(a = x, b = y, c = z, u = i, v = j, w = k ); }
FI void set(const T (&arr)[NUM_AXES]) { NUM_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5], u = arr[6], v = arr[7], w = arr[8]); }
FI void set(NUM_AXIS_ARGS(const T)) { NUM_AXIS_CODE(a = x, b = y, c = z, _i = i, _j = j, _k = k, _u = u, _v = v, _w = w ); }
#endif
#if LOGICAL_AXES > LINEAR_AXES
FI void set(const T (&arr)[LOGICAL_AXES]) { LINEAR_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5]); }
FI void set(LOGICAL_AXIS_ARGS(const T)) { LINEAR_AXIS_CODE(a = x, b = y, c = z, u = i, v = j, w = k ); }
#if LOGICAL_AXES > NUM_AXES
FI void set(const T (&arr)[LOGICAL_AXES]) { NUM_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5], u = arr[6], v = arr[7], w = arr[8]); }
FI void set(LOGICAL_AXIS_ARGS(const T)) { NUM_AXIS_CODE(a = x, b = y, c = z, _i = i, _j = j, _k = k, _u = u, _v = v, _w = w ); }
#if DISTINCT_AXES > LOGICAL_AXES
FI void set(const T (&arr)[DISTINCT_AXES]) { LINEAR_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5]); }
FI void set(const T (&arr)[DISTINCT_AXES]) { NUM_AXIS_CODE(x = arr[0], y = arr[1], z = arr[2], i = arr[3], j = arr[4], k = arr[5], u = arr[6], v = arr[7], w = arr[8]); }
#endif
#endif
#if HAS_I_AXIS
FI void set(const T px, const T py, const T pz) { x = px; y = py; z = pz; }
FI void set(const T px, const T py, const T pz) { x = px; y = py; z = pz; }
#endif
#if HAS_J_AXIS
FI void set(const T px, const T py, const T pz, const T pi) { x = px; y = py; z = pz; i = pi; }
FI void set(const T px, const T py, const T pz, const T pi) { x = px; y = py; z = pz; i = pi; }
#endif
#if HAS_K_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj) { x = px; y = py; z = pz; i = pi; j = pj; }
#endif
#if HAS_U_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; }
#endif
#if HAS_V_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk, const T pm) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; u = pu; }
#endif
#if HAS_W_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk, const T pm, const T po) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; u = pu; v = pv; }
#endif
// Length reduced to one dimension
FI T magnitude() const { return (T)sqrtf(LINEAR_AXIS_GANG(x*x, + y*y, + z*z, + i*i, + j*j, + k*k)); }
FI T magnitude() const { return (T)sqrtf(NUM_AXIS_GANG(x*x, + y*y, + z*z, + i*i, + j*j, + k*k, + u*u, + v*v, + w*w)); }
// Pointer to the data as a simple array
FI operator T* () { return pos; }
// If any element is true then it's true
FI operator bool() { return LINEAR_AXIS_GANG(x, || y, || z, || i, || j, || k); }
FI operator bool() { return NUM_AXIS_GANG(x, || y, || z, || i, || j, || k, || u, || v, || w); }
// Explicit copy and copies with conversion
FI XYZval<T> copy() const { XYZval<T> o = *this; return o; }
FI XYZval<T> ABS() const { return LINEAR_AXIS_ARRAY(T(_ABS(x)), T(_ABS(y)), T(_ABS(z)), T(_ABS(i)), T(_ABS(j)), T(_ABS(k))); }
FI XYZval<int16_t> asInt() { return LINEAR_AXIS_ARRAY(int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k)); }
FI XYZval<int16_t> asInt() const { return LINEAR_AXIS_ARRAY(int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k)); }
FI XYZval<int32_t> asLong() { return LINEAR_AXIS_ARRAY(int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k)); }
FI XYZval<int32_t> asLong() const { return LINEAR_AXIS_ARRAY(int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k)); }
FI XYZval<int32_t> ROUNDL() { return LINEAR_AXIS_ARRAY(int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k))); }
FI XYZval<int32_t> ROUNDL() const { return LINEAR_AXIS_ARRAY(int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k))); }
FI XYZval<float> asFloat() { return LINEAR_AXIS_ARRAY(static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k)); }
FI XYZval<float> asFloat() const { return LINEAR_AXIS_ARRAY(static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k)); }
FI XYZval<float> reciprocal() const { return LINEAR_AXIS_ARRAY(_RECIP(x), _RECIP(y), _RECIP(z), _RECIP(i), _RECIP(j), _RECIP(k)); }
FI XYZval<T> ABS() const { return NUM_AXIS_ARRAY(T(_ABS(x)), T(_ABS(y)), T(_ABS(z)), T(_ABS(i)), T(_ABS(j)), T(_ABS(k)), T(_ABS(u)), T(_ABS(v)), T(_ABS(w))); }
FI XYZval<int16_t> asInt() { return NUM_AXIS_ARRAY(int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k), int16_t(u), int16_t(v), int16_t(w)); }
FI XYZval<int16_t> asInt() const { return NUM_AXIS_ARRAY(int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k), int16_t(u), int16_t(v), int16_t(w)); }
FI XYZval<int32_t> asLong() { return NUM_AXIS_ARRAY(int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k), int32_t(u), int32_t(v), int32_t(w)); }
FI XYZval<int32_t> asLong() const { return NUM_AXIS_ARRAY(int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k), int32_t(u), int32_t(v), int32_t(w)); }
FI XYZval<int32_t> ROUNDL() { return NUM_AXIS_ARRAY(int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k)), int32_t(LROUND(u)), int32_t(LROUND(v)), int32_t(LROUND(w))); }
FI XYZval<int32_t> ROUNDL() const { return NUM_AXIS_ARRAY(int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k)), int32_t(LROUND(u)), int32_t(LROUND(v)), int32_t(LROUND(w))); }
FI XYZval<float> asFloat() { return NUM_AXIS_ARRAY(static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k), static_cast<float>(u), static_cast<float>(v), static_cast<float>(w)); }
FI XYZval<float> asFloat() const { return NUM_AXIS_ARRAY(static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k), static_cast<float>(u), static_cast<float>(v), static_cast<float>(w)); }
FI XYZval<float> reciprocal() const { return NUM_AXIS_ARRAY(_RECIP(x), _RECIP(y), _RECIP(z), _RECIP(i), _RECIP(j), _RECIP(k), _RECIP(u), _RECIP(v), _RECIP(w)); }
// Marlin workspace shifting is done with G92 and M206
FI XYZval<float> asLogical() const { XYZval<float> o = asFloat(); toLogical(o); return o; }
@ -502,78 +522,78 @@ struct XYZval {
FI operator const XYval<T>&() const { return *(const XYval<T>*)this; }
// Cast to a type with more fields by making a new object
FI operator XYZEval<T>() const { return LINEAR_AXIS_ARRAY(x, y, z, i, j, k); }
FI operator XYZEval<T>() const { return NUM_AXIS_ARRAY(x, y, z, i, j, k, u, v, w); }
// Accessor via an AxisEnum (or any integer) [index]
FI T& operator[](const int n) { return pos[n]; }
FI const T& operator[](const int n) const { return pos[n]; }
// Assignment operator overrides do the expected thing
FI XYZval<T>& operator= (const T v) { set(ARRAY_N_1(LINEAR_AXES, v)); return *this; }
FI XYZval<T>& operator= (const T v) { set(ARRAY_N_1(NUM_AXES, v)); return *this; }
FI XYZval<T>& operator= (const XYval<T> &rs) { set(rs.x, rs.y ); return *this; }
FI XYZval<T>& operator= (const XYZEval<T> &rs) { set(LINEAR_AXIS_ELEM(rs)); return *this; }
FI XYZval<T>& operator= (const XYZEval<T> &rs) { set(NUM_AXIS_ELEM(rs)); return *this; }
// Override other operators to get intuitive behaviors
FI XYZval<T> operator+ (const XYval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator+ (const XYval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator- (const XYval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator- (const XYval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator* (const XYval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator* (const XYval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator/ (const XYval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator/ (const XYval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator+ (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZval<T> operator+ (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZval<T> operator- (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZval<T> operator- (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZval<T> operator* (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZval<T> operator* (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZval<T> operator/ (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZval<T> operator/ (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZval<T> operator+ (const XYZEval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZval<T> operator+ (const XYZEval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZval<T> operator- (const XYZEval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZval<T> operator- (const XYZEval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZval<T> operator* (const XYZEval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZval<T> operator* (const XYZEval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZval<T> operator/ (const XYZEval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZval<T> operator/ (const XYZEval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZval<T> operator* (const float &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZval<T> operator* (const float &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZval<T> operator* (const int &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZval<T> operator* (const int &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZval<T> operator/ (const float &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZval<T> operator/ (const float &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZval<T> operator/ (const int &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZval<T> operator/ (const int &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZval<T> operator>>(const int &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(_RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k) ); return ls; }
FI XYZval<T> operator>>(const int &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(_RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k) ); return ls; }
FI XYZval<T> operator<<(const int &v) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(_LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k) ); return ls; }
FI XYZval<T> operator<<(const int &v) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(_LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k) ); return ls; }
FI const XYZval<T> operator-() const { XYZval<T> o = *this; LINEAR_AXIS_CODE(o.x = -x, o.y = -y, o.z = -z, o.i = -i, o.j = -j, o.k = -k); return o; }
FI XYZval<T> operator-() { XYZval<T> o = *this; LINEAR_AXIS_CODE(o.x = -x, o.y = -y, o.z = -z, o.i = -i, o.j = -j, o.k = -k); return o; }
FI XYZval<T> operator+ (const XYval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator+ (const XYval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator- (const XYval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator- (const XYval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator* (const XYval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator* (const XYval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator/ (const XYval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator/ (const XYval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, NOOP , NOOP , NOOP , NOOP , NOOP , NOOP , NOOP ); return ls; }
FI XYZval<T> operator+ (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZval<T> operator+ (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZval<T> operator- (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZval<T> operator- (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZval<T> operator* (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZval<T> operator* (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZval<T> operator/ (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZval<T> operator/ (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZval<T> operator+ (const XYZEval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZval<T> operator+ (const XYZEval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZval<T> operator- (const XYZEval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZval<T> operator- (const XYZEval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZval<T> operator* (const XYZEval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZval<T> operator* (const XYZEval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZval<T> operator/ (const XYZEval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZval<T> operator/ (const XYZEval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZval<T> operator* (const float &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZval<T> operator* (const float &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZval<T> operator* (const int &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZval<T> operator* (const int &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZval<T> operator/ (const float &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZval<T> operator/ (const float &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZval<T> operator/ (const int &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZval<T> operator/ (const int &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZval<T> operator>>(const int &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(_RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k), _RS(ls.u), _RS(ls.v), _RS(ls.w) ); return ls; }
FI XYZval<T> operator>>(const int &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(_RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k), _RS(ls.u), _RS(ls.v), _RS(ls.w) ); return ls; }
FI XYZval<T> operator<<(const int &v) const { XYZval<T> ls = *this; NUM_AXIS_CODE(_LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k), _LS(ls.u), _LS(ls.v), _LS(ls.w) ); return ls; }
FI XYZval<T> operator<<(const int &v) { XYZval<T> ls = *this; NUM_AXIS_CODE(_LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k), _LS(ls.u), _LS(ls.v), _LS(ls.w) ); return ls; }
FI const XYZval<T> operator-() const { XYZval<T> o = *this; NUM_AXIS_CODE(o.x = -x, o.y = -y, o.z = -z, o.i = -i, o.j = -j, o.k = -k, o.u = -u, o.v = -v, o.w = -w); return o; }
FI XYZval<T> operator-() { XYZval<T> o = *this; NUM_AXIS_CODE(o.x = -x, o.y = -y, o.z = -z, o.i = -i, o.j = -j, o.k = -k, o.u = -u, o.v = -v, o.w = -w); return o; }
// Modifier operators
FI XYZval<T>& operator+=(const XYval<T> &rs) { LINEAR_AXIS_CODE(x += rs.x, y += rs.y, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator-=(const XYval<T> &rs) { LINEAR_AXIS_CODE(x -= rs.x, y -= rs.y, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator*=(const XYval<T> &rs) { LINEAR_AXIS_CODE(x *= rs.x, y *= rs.y, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator/=(const XYval<T> &rs) { LINEAR_AXIS_CODE(x /= rs.x, y /= rs.y, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator+=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k); return *this; }
FI XYZval<T>& operator-=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k); return *this; }
FI XYZval<T>& operator*=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k); return *this; }
FI XYZval<T>& operator/=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k); return *this; }
FI XYZval<T>& operator+=(const XYZEval<T> &rs) { LINEAR_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k); return *this; }
FI XYZval<T>& operator-=(const XYZEval<T> &rs) { LINEAR_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k); return *this; }
FI XYZval<T>& operator*=(const XYZEval<T> &rs) { LINEAR_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k); return *this; }
FI XYZval<T>& operator/=(const XYZEval<T> &rs) { LINEAR_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k); return *this; }
FI XYZval<T>& operator*=(const float &v) { LINEAR_AXIS_CODE(x *= v, y *= v, z *= v, i *= v, j *= v, k *= v); return *this; }
FI XYZval<T>& operator*=(const int &v) { LINEAR_AXIS_CODE(x *= v, y *= v, z *= v, i *= v, j *= v, k *= v); return *this; }
FI XYZval<T>& operator>>=(const int &v) { LINEAR_AXIS_CODE(_RS(x), _RS(y), _RS(z), _RS(i), _RS(j), _RS(k)); return *this; }
FI XYZval<T>& operator<<=(const int &v) { LINEAR_AXIS_CODE(_LS(x), _LS(y), _LS(z), _LS(i), _LS(j), _LS(k)); return *this; }
FI XYZval<T>& operator+=(const XYval<T> &rs) { NUM_AXIS_CODE(x += rs.x, y += rs.y, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator-=(const XYval<T> &rs) { NUM_AXIS_CODE(x -= rs.x, y -= rs.y, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator*=(const XYval<T> &rs) { NUM_AXIS_CODE(x *= rs.x, y *= rs.y, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator/=(const XYval<T> &rs) { NUM_AXIS_CODE(x /= rs.x, y /= rs.y, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP, NOOP ); return *this; }
FI XYZval<T>& operator+=(const XYZval<T> &rs) { NUM_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k, u += rs.u, v += rs.v, w += rs.w); return *this; }
FI XYZval<T>& operator-=(const XYZval<T> &rs) { NUM_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k, u -= rs.u, v -= rs.v, w -= rs.w); return *this; }
FI XYZval<T>& operator*=(const XYZval<T> &rs) { NUM_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k, u *= rs.u, v *= rs.v, w *= rs.w); return *this; }
FI XYZval<T>& operator/=(const XYZval<T> &rs) { NUM_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k, u /= rs.u, v /= rs.v, w /= rs.w); return *this; }
FI XYZval<T>& operator+=(const XYZEval<T> &rs) { NUM_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k, u += rs.u, v += rs.v, w += rs.w); return *this; }
FI XYZval<T>& operator-=(const XYZEval<T> &rs) { NUM_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k, u -= rs.u, v -= rs.v, w -= rs.w); return *this; }
FI XYZval<T>& operator*=(const XYZEval<T> &rs) { NUM_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k, u *= rs.u, v *= rs.v, w *= rs.w); return *this; }
FI XYZval<T>& operator/=(const XYZEval<T> &rs) { NUM_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k, u /= rs.u, v /= rs.v, w /= rs.w); return *this; }
FI XYZval<T>& operator*=(const float &v) { NUM_AXIS_CODE(x *= v, y *= v, z *= v, i *= v, j *= v, k *= v, u *= v, v *= v, w *= v); return *this; }
FI XYZval<T>& operator*=(const int &v) { NUM_AXIS_CODE(x *= v, y *= v, z *= v, i *= v, j *= v, k *= v, u *= v, v *= v, w *= v); return *this; }
FI XYZval<T>& operator>>=(const int &v) { NUM_AXIS_CODE(_RS(x), _RS(y), _RS(z), _RS(i), _RS(j), _RS(k), _RS(u), _RS(v), _RS(w)); return *this; }
FI XYZval<T>& operator<<=(const int &v) { NUM_AXIS_CODE(_LS(x), _LS(y), _LS(z), _LS(i), _LS(j), _LS(k), _LS(u), _LS(v), _LS(w)); return *this; }
// Exact comparisons. For floats a "NEAR" operation may be better.
FI bool operator==(const XYZEval<T> &rs) { return true LINEAR_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k); }
FI bool operator==(const XYZEval<T> &rs) const { return true LINEAR_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k); }
FI bool operator==(const XYZEval<T> &rs) { return true NUM_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k, && u == rs.u, && v == rs.v, && w == rs.w); }
FI bool operator==(const XYZEval<T> &rs) const { return true NUM_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k, && u == rs.u, && v == rs.v, && w == rs.w); }
FI bool operator!=(const XYZEval<T> &rs) { return !operator==(rs); }
FI bool operator!=(const XYZEval<T> &rs) const { return !operator==(rs); }
};
@ -585,56 +605,66 @@ template<typename T>
struct XYZEval {
union {
struct { T LOGICAL_AXIS_ARGS(); };
struct { T LOGICAL_AXIS_LIST(_e, a, b, c, u, v, w); };
struct { T LOGICAL_AXIS_LIST(_e, a, b, c, _i, _j, _k, _u, _v, _w); };
T pos[LOGICAL_AXES];
};
// Reset all to 0
FI void reset() { LOGICAL_AXIS_GANG(e =, x =, y =, z =, i =, j =, k =) 0; }
FI void reset() { LOGICAL_AXIS_GANG(e =, x =, y =, z =, i =, j =, k =, u =, v =, w =) 0; }
// Setters for some number of linear axes, not all
FI void set(const T px) { x = px; }
FI void set(const T px, const T py) { x = px; y = py; }
FI void set(const T px) { x = px; }
FI void set(const T px, const T py) { x = px; y = py; }
#if HAS_I_AXIS
FI void set(const T px, const T py, const T pz) { x = px; y = py; z = pz; }
FI void set(const T px, const T py, const T pz) { x = px; y = py; z = pz; }
#endif
#if HAS_J_AXIS
FI void set(const T px, const T py, const T pz, const T pi) { x = px; y = py; z = pz; i = pi; }
FI void set(const T px, const T py, const T pz, const T pi) { x = px; y = py; z = pz; i = pi; }
#endif
#if HAS_K_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj) { x = px; y = py; z = pz; i = pi; j = pj; }
FI void set(const T px, const T py, const T pz, const T pi, const T pj) { x = px; y = py; z = pz; i = pi; j = pj; }
#endif
#if HAS_U_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; }
#endif
#if HAS_V_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk, const T pm) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; u = pu; }
#endif
#if HAS_W_AXIS
FI void set(const T px, const T py, const T pz, const T pi, const T pj, const T pk, const T pm, const T po) { x = px; y = py; z = pz; i = pi; j = pj; k = pk; u = pm; v = pv; }
#endif
// Setters taking struct types and arrays
FI void set(const XYval<T> pxy) { x = pxy.x; y = pxy.y; }
FI void set(const XYZval<T> pxyz) { set(LINEAR_AXIS_ELEM(pxyz)); }
FI void set(const XYval<T> pxy) { x = pxy.x; y = pxy.y; }
FI void set(const XYZval<T> pxyz) { set(NUM_AXIS_ELEM(pxyz)); }
#if HAS_Z_AXIS
FI void set(LINEAR_AXIS_ARGS(const T)) { LINEAR_AXIS_CODE(a = x, b = y, c = z, u = i, v = j, w = k); }
FI void set(NUM_AXIS_ARGS(const T)) { NUM_AXIS_CODE(a = x, b = y, c = z, _i = i, _j = j, _k = k, _u = u, _v = v, _w = w); }
#endif
FI void set(const XYval<T> pxy, const T pz) { set(pxy); TERN_(HAS_Z_AXIS, z = pz); }
#if LOGICAL_AXES > LINEAR_AXES
FI void set(const XYval<T> pxy, const T pz) { set(pxy); TERN_(HAS_Z_AXIS, z = pz); }
#if LOGICAL_AXES > NUM_AXES
FI void set(const XYval<T> pxy, const T pz, const T pe) { set(pxy, pz); e = pe; }
FI void set(const XYZval<T> pxyz, const T pe) { set(pxyz); e = pe; }
FI void set(LOGICAL_AXIS_ARGS(const T)) { LOGICAL_AXIS_CODE(_e = e, a = x, b = y, c = z, u = i, v = j, w = k); }
FI void set(const XYZval<T> pxyz, const T pe) { set(pxyz); e = pe; }
FI void set(LOGICAL_AXIS_ARGS(const T)) { LOGICAL_AXIS_CODE(_e = e, a = x, b = y, c = z, _i = i, _j = j, _k = k, _u = u, _v = v, _w = w); }
#endif
// Length reduced to one dimension
FI T magnitude() const { return (T)sqrtf(LOGICAL_AXIS_GANG(+ e*e, + x*x, + y*y, + z*z, + i*i, + j*j, + k*k)); }
FI T magnitude() const { return (T)sqrtf(LOGICAL_AXIS_GANG(+ e*e, + x*x, + y*y, + z*z, + i*i, + j*j, + k*k, + u*u, + v*v, + w*w)); }
// Pointer to the data as a simple array
FI operator T* () { return pos; }
// If any element is true then it's true
FI operator bool() { return 0 LOGICAL_AXIS_GANG(|| e, || x, || y, || z, || i, || j, || k); }
FI operator bool() { return 0 LOGICAL_AXIS_GANG(|| e, || x, || y, || z, || i, || j, || k, || u, || v, || w); }
// Explicit copy and copies with conversion
FI XYZEval<T> copy() const { XYZEval<T> o = *this; return o; }
FI XYZEval<T> ABS() const { return LOGICAL_AXIS_ARRAY(T(_ABS(e)), T(_ABS(x)), T(_ABS(y)), T(_ABS(z)), T(_ABS(i)), T(_ABS(j)), T(_ABS(k))); }
FI XYZEval<int16_t> asInt() { return LOGICAL_AXIS_ARRAY(int16_t(e), int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k)); }
FI XYZEval<int16_t> asInt() const { return LOGICAL_AXIS_ARRAY(int16_t(e), int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k)); }
FI XYZEval<int32_t> asLong() { return LOGICAL_AXIS_ARRAY(int32_t(e), int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k)); }
FI XYZEval<int32_t> asLong() const { return LOGICAL_AXIS_ARRAY(int32_t(e), int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k)); }
FI XYZEval<int32_t> ROUNDL() { return LOGICAL_AXIS_ARRAY(int32_t(LROUND(e)), int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k))); }
FI XYZEval<int32_t> ROUNDL() const { return LOGICAL_AXIS_ARRAY(int32_t(LROUND(e)), int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k))); }
FI XYZEval<float> asFloat() { return LOGICAL_AXIS_ARRAY(static_cast<float>(e), static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k)); }
FI XYZEval<float> asFloat() const { return LOGICAL_AXIS_ARRAY(static_cast<float>(e), static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k)); }
FI XYZEval<float> reciprocal() const { return LOGICAL_AXIS_ARRAY(_RECIP(e), _RECIP(x), _RECIP(y), _RECIP(z), _RECIP(i), _RECIP(j), _RECIP(k)); }
FI XYZEval<T> copy() const { XYZEval<T> v = *this; return v; }
FI XYZEval<T> ABS() const { return LOGICAL_AXIS_ARRAY(T(_ABS(e)), T(_ABS(x)), T(_ABS(y)), T(_ABS(z)), T(_ABS(i)), T(_ABS(j)), T(_ABS(k)), T(_ABS(u)), T(_ABS(v)), T(_ABS(w))); }
FI XYZEval<int16_t> asInt() { return LOGICAL_AXIS_ARRAY(int16_t(e), int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k), int16_t(u), int16_t(v), int16_t(w)); }
FI XYZEval<int16_t> asInt() const { return LOGICAL_AXIS_ARRAY(int16_t(e), int16_t(x), int16_t(y), int16_t(z), int16_t(i), int16_t(j), int16_t(k), int16_t(u), int16_t(v), int16_t(w)); }
FI XYZEval<int32_t> asLong() { return LOGICAL_AXIS_ARRAY(int32_t(e), int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k), int32_t(u), int32_t(v), int32_t(w)); }
FI XYZEval<int32_t> asLong() const { return LOGICAL_AXIS_ARRAY(int32_t(e), int32_t(x), int32_t(y), int32_t(z), int32_t(i), int32_t(j), int32_t(k), int32_t(u), int32_t(v), int32_t(w)); }
FI XYZEval<int32_t> ROUNDL() { return LOGICAL_AXIS_ARRAY(int32_t(LROUND(e)), int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k)), int32_t(LROUND(u)), int32_t(LROUND(v)), int32_t(LROUND(w))); }
FI XYZEval<int32_t> ROUNDL() const { return LOGICAL_AXIS_ARRAY(int32_t(LROUND(e)), int32_t(LROUND(x)), int32_t(LROUND(y)), int32_t(LROUND(z)), int32_t(LROUND(i)), int32_t(LROUND(j)), int32_t(LROUND(k)), int32_t(LROUND(u)), int32_t(LROUND(v)), int32_t(LROUND(w))); }
FI XYZEval<float> asFloat() { return LOGICAL_AXIS_ARRAY(static_cast<float>(e), static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k), static_cast<float>(u), static_cast<float>(v), static_cast<float>(w)); }
FI XYZEval<float> asFloat() const { return LOGICAL_AXIS_ARRAY(static_cast<float>(e), static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), static_cast<float>(i), static_cast<float>(j), static_cast<float>(k), static_cast<float>(u), static_cast<float>(v), static_cast<float>(w)); }
FI XYZEval<float> reciprocal() const { return LOGICAL_AXIS_ARRAY(_RECIP(e), _RECIP(x), _RECIP(y), _RECIP(z), _RECIP(i), _RECIP(j), _RECIP(k), _RECIP(u), _RECIP(v), _RECIP(w)); }
// Marlin workspace shifting is done with G92 and M206
FI XYZEval<float> asLogical() const { XYZEval<float> o = asFloat(); toLogical(o); return o; }
@ -651,9 +681,9 @@ struct XYZEval {
FI const T& operator[](const int n) const { return pos[n]; }
// Assignment operator overrides do the expected thing
FI XYZEval<T>& operator= (const T v) { set(LIST_N_1(LINEAR_AXES, v)); return *this; }
FI XYZEval<T>& operator= (const T v) { set(LIST_N_1(NUM_AXES, v)); return *this; }
FI XYZEval<T>& operator= (const XYval<T> &rs) { set(rs.x, rs.y); return *this; }
FI XYZEval<T>& operator= (const XYZval<T> &rs) { set(LINEAR_AXIS_ELEM(rs)); return *this; }
FI XYZEval<T>& operator= (const XYZval<T> &rs) { set(NUM_AXIS_ELEM(rs)); return *this; }
// Override other operators to get intuitive behaviors
FI XYZEval<T> operator+ (const XYval<T> &rs) const { XYZEval<T> ls = *this; ls.x += rs.x; ls.y += rs.y; return ls; }
@ -664,57 +694,57 @@ struct XYZEval {
FI XYZEval<T> operator* (const XYval<T> &rs) { XYZEval<T> ls = *this; ls.x *= rs.x; ls.y *= rs.y; return ls; }
FI XYZEval<T> operator/ (const XYval<T> &rs) const { XYZEval<T> ls = *this; ls.x /= rs.x; ls.y /= rs.y; return ls; }
FI XYZEval<T> operator/ (const XYval<T> &rs) { XYZEval<T> ls = *this; ls.x /= rs.x; ls.y /= rs.y; return ls; }
FI XYZEval<T> operator+ (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZEval<T> operator+ (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZEval<T> operator- (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZEval<T> operator- (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZEval<T> operator* (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZEval<T> operator* (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZEval<T> operator/ (const XYZval<T> &rs) const { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZEval<T> operator/ (const XYZval<T> &rs) { XYZval<T> ls = *this; LINEAR_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZEval<T> operator+ (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e += rs.e, ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZEval<T> operator+ (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e += rs.e, ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k); return ls; }
FI XYZEval<T> operator- (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e -= rs.e, ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZEval<T> operator- (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e -= rs.e, ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k); return ls; }
FI XYZEval<T> operator* (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= rs.e, ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZEval<T> operator* (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= rs.e, ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k); return ls; }
FI XYZEval<T> operator/ (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= rs.e, ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZEval<T> operator/ (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= rs.e, ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k); return ls; }
FI XYZEval<T> operator* (const float &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZEval<T> operator* (const float &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZEval<T> operator* (const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZEval<T> operator* (const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v ); return ls; }
FI XYZEval<T> operator/ (const float &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZEval<T> operator/ (const float &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZEval<T> operator/ (const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZEval<T> operator/ (const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v ); return ls; }
FI XYZEval<T> operator>>(const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_RS(ls.e), _RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k) ); return ls; }
FI XYZEval<T> operator>>(const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_RS(ls.e), _RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k) ); return ls; }
FI XYZEval<T> operator<<(const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_LS(ls.e), _LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k) ); return ls; }
FI XYZEval<T> operator<<(const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_LS(ls.e), _LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k) ); return ls; }
FI const XYZEval<T> operator-() const { return LOGICAL_AXIS_ARRAY(-e, -x, -y, -z, -i, -j, -k); }
FI XYZEval<T> operator-() { return LOGICAL_AXIS_ARRAY(-e, -x, -y, -z, -i, -j, -k); }
FI XYZEval<T> operator+ (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZEval<T> operator+ (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZEval<T> operator- (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZEval<T> operator- (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZEval<T> operator* (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZEval<T> operator* (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZEval<T> operator/ (const XYZval<T> &rs) const { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZEval<T> operator/ (const XYZval<T> &rs) { XYZval<T> ls = *this; NUM_AXIS_CODE(ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZEval<T> operator+ (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e += rs.e, ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZEval<T> operator+ (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e += rs.e, ls.x += rs.x, ls.y += rs.y, ls.z += rs.z, ls.i += rs.i, ls.j += rs.j, ls.k += rs.k, ls.u += rs.u, ls.v += rs.v, ls.w += rs.w); return ls; }
FI XYZEval<T> operator- (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e -= rs.e, ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZEval<T> operator- (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e -= rs.e, ls.x -= rs.x, ls.y -= rs.y, ls.z -= rs.z, ls.i -= rs.i, ls.j -= rs.j, ls.k -= rs.k, ls.u -= rs.u, ls.v -= rs.v, ls.w -= rs.w); return ls; }
FI XYZEval<T> operator* (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= rs.e, ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZEval<T> operator* (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= rs.e, ls.x *= rs.x, ls.y *= rs.y, ls.z *= rs.z, ls.i *= rs.i, ls.j *= rs.j, ls.k *= rs.k, ls.u *= rs.u, ls.v *= rs.v, ls.w *= rs.w); return ls; }
FI XYZEval<T> operator/ (const XYZEval<T> &rs) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= rs.e, ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZEval<T> operator/ (const XYZEval<T> &rs) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= rs.e, ls.x /= rs.x, ls.y /= rs.y, ls.z /= rs.z, ls.i /= rs.i, ls.j /= rs.j, ls.k /= rs.k, ls.u /= rs.u, ls.v /= rs.v, ls.w /= rs.w); return ls; }
FI XYZEval<T> operator* (const float &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZEval<T> operator* (const float &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZEval<T> operator* (const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZEval<T> operator* (const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e *= v, ls.x *= v, ls.y *= v, ls.z *= v, ls.i *= v, ls.j *= v, ls.k *= v, ls.u *= v, ls.v *= v, ls.w *= v ); return ls; }
FI XYZEval<T> operator/ (const float &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZEval<T> operator/ (const float &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZEval<T> operator/ (const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZEval<T> operator/ (const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(ls.e /= v, ls.x /= v, ls.y /= v, ls.z /= v, ls.i /= v, ls.j /= v, ls.k /= v, ls.u /= v, ls.v /= v, ls.w /= v ); return ls; }
FI XYZEval<T> operator>>(const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_RS(ls.e), _RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k), _RS(ls.u), _RS(ls.v), _RS(ls.w) ); return ls; }
FI XYZEval<T> operator>>(const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_RS(ls.e), _RS(ls.x), _RS(ls.y), _RS(ls.z), _RS(ls.i), _RS(ls.j), _RS(ls.k), _RS(ls.u), _RS(ls.v), _RS(ls.w) ); return ls; }
FI XYZEval<T> operator<<(const int &v) const { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_LS(ls.e), _LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k), _LS(ls.u), _LS(ls.v), _LS(ls.w) ); return ls; }
FI XYZEval<T> operator<<(const int &v) { XYZEval<T> ls = *this; LOGICAL_AXIS_CODE(_LS(ls.e), _LS(ls.x), _LS(ls.y), _LS(ls.z), _LS(ls.i), _LS(ls.j), _LS(ls.k), _LS(ls.u), _LS(ls.v), _LS(ls.w) ); return ls; }
FI const XYZEval<T> operator-() const { return LOGICAL_AXIS_ARRAY(-e, -x, -y, -z, -i, -j, -k, -u, -v, -w); }
FI XYZEval<T> operator-() { return LOGICAL_AXIS_ARRAY(-e, -x, -y, -z, -i, -j, -k, -u, -v, -w); }
// Modifier operators
FI XYZEval<T>& operator+=(const XYval<T> &rs) { x += rs.x; y += rs.y; return *this; }
FI XYZEval<T>& operator-=(const XYval<T> &rs) { x -= rs.x; y -= rs.y; return *this; }
FI XYZEval<T>& operator*=(const XYval<T> &rs) { x *= rs.x; y *= rs.y; return *this; }
FI XYZEval<T>& operator/=(const XYval<T> &rs) { x /= rs.x; y /= rs.y; return *this; }
FI XYZEval<T>& operator+=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k); return *this; }
FI XYZEval<T>& operator-=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k); return *this; }
FI XYZEval<T>& operator*=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k); return *this; }
FI XYZEval<T>& operator/=(const XYZval<T> &rs) { LINEAR_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k); return *this; }
FI XYZEval<T>& operator+=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e += rs.e, x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k); return *this; }
FI XYZEval<T>& operator-=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e -= rs.e, x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k); return *this; }
FI XYZEval<T>& operator*=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e *= rs.e, x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k); return *this; }
FI XYZEval<T>& operator/=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e /= rs.e, x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k); return *this; }
FI XYZEval<T>& operator*=(const T &v) { LOGICAL_AXIS_CODE(e *= v, x *= v, y *= v, z *= v, i *= v, j *= v, k *= v); return *this; }
FI XYZEval<T>& operator>>=(const int &v) { LOGICAL_AXIS_CODE(_RS(e), _RS(x), _RS(y), _RS(z), _RS(i), _RS(j), _RS(k)); return *this; }
FI XYZEval<T>& operator<<=(const int &v) { LOGICAL_AXIS_CODE(_LS(e), _LS(x), _LS(y), _LS(z), _LS(i), _LS(j), _LS(k)); return *this; }
FI XYZEval<T>& operator+=(const XYZval<T> &rs) { NUM_AXIS_CODE(x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k, u += rs.u, v += rs.v, w += rs.w); return *this; }
FI XYZEval<T>& operator-=(const XYZval<T> &rs) { NUM_AXIS_CODE(x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k, u -= rs.u, v -= rs.v, w -= rs.w); return *this; }
FI XYZEval<T>& operator*=(const XYZval<T> &rs) { NUM_AXIS_CODE(x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k, u *= rs.u, v *= rs.v, w *= rs.w); return *this; }
FI XYZEval<T>& operator/=(const XYZval<T> &rs) { NUM_AXIS_CODE(x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k, u /= rs.u, v /= rs.v, w /= rs.w); return *this; }
FI XYZEval<T>& operator+=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e += rs.e, x += rs.x, y += rs.y, z += rs.z, i += rs.i, j += rs.j, k += rs.k, u += rs.u, v += rs.v, w += rs.w); return *this; }
FI XYZEval<T>& operator-=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e -= rs.e, x -= rs.x, y -= rs.y, z -= rs.z, i -= rs.i, j -= rs.j, k -= rs.k, u -= rs.u, v -= rs.v, w -= rs.w); return *this; }
FI XYZEval<T>& operator*=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e *= rs.e, x *= rs.x, y *= rs.y, z *= rs.z, i *= rs.i, j *= rs.j, k *= rs.k, u *= rs.u, v *= rs.v, w *= rs.w); return *this; }
FI XYZEval<T>& operator/=(const XYZEval<T> &rs) { LOGICAL_AXIS_CODE(e /= rs.e, x /= rs.x, y /= rs.y, z /= rs.z, i /= rs.i, j /= rs.j, k /= rs.k, u /= rs.u, v /= rs.v, w /= rs.w); return *this; }
FI XYZEval<T>& operator*=(const T &v) { LOGICAL_AXIS_CODE(e *= v, x *= v, y *= v, z *= v, i *= v, j *= v, k *= v, u *= v, v *= v, w *= v); return *this; }
FI XYZEval<T>& operator>>=(const int &v) { LOGICAL_AXIS_CODE(_RS(e), _RS(x), _RS(y), _RS(z), _RS(i), _RS(j), _RS(k), _RS(u), _RS(v), _RS(w)); return *this; }
FI XYZEval<T>& operator<<=(const int &v) { LOGICAL_AXIS_CODE(_LS(e), _LS(x), _LS(y), _LS(z), _LS(i), _LS(j), _LS(k), _LS(u), _LS(v), _LS(w)); return *this; }
// Exact comparisons. For floats a "NEAR" operation may be better.
FI bool operator==(const XYZval<T> &rs) { return true LINEAR_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k); }
FI bool operator==(const XYZval<T> &rs) const { return true LINEAR_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k); }
FI bool operator==(const XYZval<T> &rs) { return true NUM_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k, && u == rs.u, && v == rs.v, && w == rs.w); }
FI bool operator==(const XYZval<T> &rs) const { return true NUM_AXIS_GANG(&& x == rs.x, && y == rs.y, && z == rs.z, && i == rs.i, && j == rs.j, && k == rs.k, && u == rs.u, && v == rs.v, && w == rs.w); }
FI bool operator!=(const XYZval<T> &rs) { return !operator==(rs); }
FI bool operator!=(const XYZval<T> &rs) const { return !operator==(rs); }
};

2
Marlin/src/core/utility.cpp
View File

@ -125,7 +125,7 @@ void safe_delay(millis_t ms) {
#endif
#if ABL_PLANAR
SERIAL_ECHOPGM("ABL Adjustment");
LOOP_LINEAR_AXES(a) {
LOOP_NUM_AXES(a) {
SERIAL_CHAR(' ', AXIS_CHAR(a));
serial_offset(planner.get_axis_position_mm(AxisEnum(a)) - current_position[a]);
}

9
Marlin/src/core/utility.h
View File

@ -77,10 +77,13 @@ public:
// in the range 0-100 while avoiding rounding artifacts
constexpr uint8_t ui8_to_percent(const uint8_t i) { return (int(i) * 100 + 127) / 255; }
const xyze_char_t axis_codes LOGICAL_AXIS_ARRAY('E', 'X', 'Y', 'Z', AXIS4_NAME, AXIS5_NAME, AXIS6_NAME);
#if LINEAR_AXES <= XYZ
// Axis names for G-code parsing, reports, etc.
const xyze_char_t axis_codes LOGICAL_AXIS_ARRAY('E', 'X', 'Y', 'Z', AXIS4_NAME, AXIS5_NAME, AXIS6_NAME, AXIS7_NAME, AXIS8_NAME, AXIS9_NAME);
#if NUM_AXES <= XYZ
#define AXIS_CHAR(A) ((char)('X' + A))
#define IAXIS_CHAR AXIS_CHAR
#else
const xyze_char_t iaxis_codes LOGICAL_AXIS_ARRAY('E', 'X', 'Y', 'Z', 'I', 'J', 'K', 'U', 'V', 'W');
#define AXIS_CHAR(A) axis_codes[A]
#define IAXIS_CHAR(A) iaxis_codes[A]
#endif