mx-op-defs.h File Reference

#include "mx-op-decl.h"
#include "mx-inlines.cc"

Include dependency graph for mx-op-defs.h:

Go to the source code of this file.

Defines
#define	octave_mx_op_defs_h   1
#define	VS_BIN_OP(R, F, OP, V, S)
#define	VS_BIN_OPS(R, V, S)
#define	SV_BIN_OP(R, F, OP, S, V)
#define	SV_BIN_OPS(R, S, V)
#define	VV_BIN_OP(R, F, OP, V1, V2)
#define	VV_BIN_OPS(R, V1, V2)
#define	MS_BIN_OP(R, OP, M, S, F)
#define	MS_BIN_OPS(R, M, S)
#define	MS_CMP_OP(F, OP, M, S)
#define	MS_CMP_OPS(M, S)
#define	MS_BOOL_OP(F, OP, M, S)
#define	MS_BOOL_OPS(M, S)
#define	SM_BIN_OP(R, OP, S, M, F)
#define	SM_BIN_OPS(R, S, M)
#define	SM_CMP_OP(F, OP, S, M)
#define	SM_CMP_OPS(S, M)
#define	SM_BOOL_OP(F, OP, S, M)
#define	SM_BOOL_OPS(S, M)
#define	MM_BIN_OP(R, OP, M1, M2, F)
#define	MM_BIN_OPS(R, M1, M2)
#define	MM_CMP_OP(F, OP, M1, M2)
#define	MM_CMP_OPS(M1, M2)
#define	MM_BOOL_OP(F, OP, M1, M2)
#define	MM_BOOL_OPS(M1, M2)
#define	NDS_BIN_OP(R, OP, ND, S, F)
#define	NDS_BIN_OPS(R, ND, S)
#define	NDS_CMP_OP(F, OP, ND, S)
#define	NDS_CMP_OPS(ND, S)
#define	NDS_BOOL_OP(F, OP, ND, S)
#define	NDS_BOOL_OPS(ND, S)
#define	SND_BIN_OP(R, OP, S, ND, F)
#define	SND_BIN_OPS(R, S, ND)
#define	SND_CMP_OP(F, OP, S, ND)
#define	SND_CMP_OPS(S, ND)
#define	SND_BOOL_OP(F, OP, S, ND)
#define	SND_BOOL_OPS(S, ND)
#define	NDND_BIN_OP(R, OP, ND1, ND2, F)
#define	NDND_BIN_OPS(R, ND1, ND2)
#define	NDND_CMP_OP(F, OP, ND1, ND2)
#define	NDND_CMP_OPS(ND1, ND2)
#define	NDND_BOOL_OP(F, OP, ND1, ND2)
#define	NDND_BOOL_OPS(ND1, ND2)
#define	SDM_BIN_OP(R, OP, S, DM)
#define	SDM_BIN_OPS(R, S, DM)   SDM_BIN_OP (R, *, S, DM)
#define	DMS_BIN_OP(R, OP, DM, S)
#define	DMS_BIN_OPS(R, DM, S)
#define	MDM_BIN_OP(R, OP, M, DM, OPEQ)
#define	MDM_MULTIPLY_OP(R, M, DM, R_ZERO)
#define	MDM_BIN_OPS(R, M, DM, R_ZERO)
#define	DMM_BIN_OP(R, OP, DM, M, OPEQ, PREOP)
#define	DMM_MULTIPLY_OP(R, DM, M, R_ZERO)
#define	DMM_BIN_OPS(R, DM, M, R_ZERO)
#define	DMDM_BIN_OP(R, OP, DM1, DM2, F)
#define	DMDM_BIN_OPS(R, DM1, DM2)
#define	SND_MINMAX_FCN(FCN, OP, T)
#define	NDS_MINMAX_FCN(FCN, OP, T)
#define	NDND_MINMAX_FCN(FCN, OP, T)
#define	MINMAX_FCNS(T)
#define	PMM_MULTIPLY_OP(PM, M)
#define	MPM_MULTIPLY_OP(M, PM)
#define	PMM_BIN_OPS(R, PM, M)   PMM_MULTIPLY_OP(PM, M);
#define	MPM_BIN_OPS(R, M, PM)   MPM_MULTIPLY_OP(M, PM);
#define	NDND_MAPPER_BODY(R, NAME)

---

Define Documentation

#define DMDM_BIN_OP	(	R,
		OP,
		DM1,
		DM2,
		F		)

Value:

R \
  OP (const DM1& dm1, const DM2& dm2) \
  { \
    R r; \
 \
    octave_idx_type dm1_nr = dm1.rows (); \
    octave_idx_type dm1_nc = dm1.cols (); \
 \
    octave_idx_type dm2_nr = dm2.rows (); \
    octave_idx_type dm2_nc = dm2.cols (); \
 \
    if (dm1_nr != dm2_nr || dm1_nc != dm2_nc) \
      gripe_nonconformant (#OP, dm1_nr, dm1_nc, dm2_nr, dm2_nc); \
    else \
      { \
        r.resize (dm1_nr, dm1_nc); \
 \
        if (dm1_nr > 0 && dm1_nc > 0) \
          F (dm1.length (), r.fortran_vec (), dm1.data (), dm2.data ()); \
      } \
 \
    return r; \
  }

#define DMDM_BIN_OPS	(	R,
		DM1,
		DM2		)

Value:

DMDM_BIN_OP (R, operator +, DM1, DM2, mx_inline_add) \
  DMDM_BIN_OP (R, operator -, DM1, DM2, mx_inline_sub) \
  DMDM_BIN_OP (R, product,    DM1, DM2, mx_inline_mul)

#define DMM_BIN_OP	(	R,
		OP,
		DM,
		M,
		OPEQ,
		PREOP		)

Value:

R \
OP (const DM& dm, const M& m) \
{ \
  R r; \
 \
  octave_idx_type dm_nr = dm.rows (); \
  octave_idx_type dm_nc = dm.cols (); \
 \
  octave_idx_type m_nr = m.rows (); \
  octave_idx_type m_nc = m.cols (); \
 \
  if (dm_nr != m_nr || dm_nc != m_nc) \
    gripe_nonconformant (#OP, dm_nr, dm_nc, m_nr, m_nc); \
  else \
    { \
      if (m_nr > 0 && m_nc > 0) \
        { \
          r = R (PREOP m); \
 \
          octave_idx_type len = dm.length (); \
 \
          for (octave_idx_type i = 0; i < len; i++) \
            r.elem(i, i) OPEQ dm.elem(i, i); \
        } \
      else \
        r.resize (m_nr, m_nc); \
    } \
 \
  return r; \
}

#define DMM_BIN_OPS	(	R,
		DM,
		M,
		R_ZERO		)

Value:

DMM_BIN_OP (R, operator +, DM, M, +=, ) \
  DMM_BIN_OP (R, operator -, DM, M, +=, -) \
  DMM_MULTIPLY_OP (R, DM, M, R_ZERO)

#define DMM_MULTIPLY_OP	(	R,
		DM,
		M,
		R_ZERO		)

#define DMS_BIN_OP	(	R,
		OP,
		DM,
		S		)

Value:

R \
  operator OP (const DM& dm, const S& s) \
  { \
    R r (dm.rows (), dm.cols ()); \
 \
    for (octave_idx_type i = 0; i < dm.length (); i++) \
      r.dgxelem (i) = dm.dgelem (i) OP s; \
 \
    return r; \
  }

#define DMS_BIN_OPS	(	R,
		DM,
		S		)

Value:

DMS_BIN_OP (R, *, DM, S) \
  DMS_BIN_OP (R, /, DM, S)

#define MDM_BIN_OP	(	R,
		OP,
		M,
		DM,
		OPEQ		)

Value:

R \
OP (const M& m, const DM& dm) \
{ \
  R r; \
 \
  octave_idx_type m_nr = m.rows (); \
  octave_idx_type m_nc = m.cols (); \
 \
  octave_idx_type dm_nr = dm.rows (); \
  octave_idx_type dm_nc = dm.cols (); \
 \
  if (m_nr != dm_nr || m_nc != dm_nc) \
    gripe_nonconformant (#OP, m_nr, m_nc, dm_nr, dm_nc); \
  else \
    { \
      r.resize (m_nr, m_nc); \
 \
      if (m_nr > 0 && m_nc > 0) \
        { \
          r = R (m); \
 \
          octave_idx_type len = dm.length (); \
 \
          for (octave_idx_type i = 0; i < len; i++) \
            r.elem(i, i) OPEQ dm.elem(i, i); \
        } \
    } \
 \
  return r; \
}

#define MDM_BIN_OPS	(	R,
		M,
		DM,
		R_ZERO		)

Value:

MDM_BIN_OP (R, operator +, M, DM, +=) \
  MDM_BIN_OP (R, operator -, M, DM, -=) \
  MDM_MULTIPLY_OP (R, M, DM, R_ZERO)

#define MDM_MULTIPLY_OP	(	R,
		M,
		DM,
		R_ZERO		)

#define MINMAX_FCNS

(

T

)

Value:

SND_MINMAX_FCN (min, <, T) \
  NDS_MINMAX_FCN (min, <, T) \
  NDND_MINMAX_FCN (min, <, T) \
  SND_MINMAX_FCN (max, >, T) \
  NDS_MINMAX_FCN (max, >, T) \
  NDND_MINMAX_FCN (max, >, T)

#define MM_BIN_OP	(	R,
		OP,
		M1,
		M2,
		F		)

Value:

R \
  OP (const M1& m1, const M2& m2) \
  { \
    return do_mm_binary_op<R, M1, M2> (m1, m2, F, #OP); \
  }

#define MM_BIN_OPS	(	R,
		M1,
		M2		)

Value:

MM_BIN_OP (R, operator +, M1, M2, mx_inline_add) \
  MM_BIN_OP (R, operator -, M1, M2, mx_inline_sub) \
  MM_BIN_OP (R, product,    M1, M2, mx_inline_mul) \
  MM_BIN_OP (R, quotient,   M1, M2, mx_inline_div)

#define MM_BOOL_OP	(	F,
		OP,
		M1,
		M2		)

Value:

boolMatrix \
  F (const M1& m1, const M2& m2) \
  { \
    return do_mm_binary_op<boolMatrix, M1, M2> (m1, m2, OP, #F); \
  }

#define MM_BOOL_OPS	(	M1,
		M2		)

Value:

MM_BOOL_OP (mx_el_and, mx_inline_and, M1, M2) \
  MM_BOOL_OP (mx_el_or,  mx_inline_or,  M1, M2)

#define MM_CMP_OP	(	F,
		OP,
		M1,
		M2		)

Value:

boolMatrix \
  F (const M1& m1, const M2& m2) \
  { \
    return do_mm_binary_op<boolMatrix, M1, M2> (m1, m2, OP, #F); \
  }

#define MM_CMP_OPS	(	M1,
		M2		)

Value:

MM_CMP_OP (mx_el_lt, mx_inline_lt, M1, M2) \
  MM_CMP_OP (mx_el_le, mx_inline_le, M1, M2) \
  MM_CMP_OP (mx_el_ge, mx_inline_ge, M1, M2) \
  MM_CMP_OP (mx_el_gt, mx_inline_gt, M1, M2) \
  MM_CMP_OP (mx_el_eq, mx_inline_eq, M1, M2) \
  MM_CMP_OP (mx_el_ne, mx_inline_ne, M1, M2)

#define MPM_BIN_OPS	(	R,
		M,
		PM		)	MPM_MULTIPLY_OP(M, PM);

#define MPM_MULTIPLY_OP	(	M,
		PM		)

Value:

M operator * (const M& x, const PM& p) \
{ \
  octave_idx_type nr = x.rows (), nc = x.columns (); \
  M result; \
  if (p.rows () != nc) \
    gripe_nonconformant ("operator *", nr, nc, p.rows (), p.columns ()); \
  else \
    { \
      if (p.is_col_perm ()) \
        result = x.index (idx_vector::colon, p.pvec ()); \
      else \
        { \
          result = M (nr, nc); \
          result.assign (idx_vector::colon, p.pvec (), x); \
        } \
    } \
  \
  return result; \
}

#define MS_BIN_OP	(	R,
		OP,
		M,
		S,
		F		)

Value:

R \
  OP (const M& m, const S& s) \
  { \
    return do_ms_binary_op<R, M, S> (m, s, F); \
  }

#define MS_BIN_OPS	(	R,
		M,
		S		)

Value:

MS_BIN_OP (R, operator +, M, S, mx_inline_add) \
  MS_BIN_OP (R, operator -, M, S, mx_inline_sub) \
  MS_BIN_OP (R, operator *, M, S, mx_inline_mul) \
  MS_BIN_OP (R, operator /, M, S, mx_inline_div)

#define MS_BOOL_OP	(	F,
		OP,
		M,
		S		)

Value:

boolMatrix \
  F (const M& m, const S& s) \
  { \
    return do_ms_binary_op<boolMatrix, M, S> (m, s, OP); \
  }

#define MS_BOOL_OPS	(	M,
		S		)

Value:

MS_BOOL_OP (mx_el_and, mx_inline_and, M, S) \
  MS_BOOL_OP (mx_el_or,  mx_inline_or,  M, S)

#define MS_CMP_OP	(	F,
		OP,
		M,
		S		)

Value:

boolMatrix \
  F (const M& m, const S& s) \
  { \
    return do_ms_binary_op<boolMatrix, M, S> (m, s, OP); \
  }

#define MS_CMP_OPS	(	M,
		S		)

Value:

MS_CMP_OP (mx_el_lt, mx_inline_lt, M, S) \
  MS_CMP_OP (mx_el_le, mx_inline_le, M, S) \
  MS_CMP_OP (mx_el_ge, mx_inline_ge, M, S) \
  MS_CMP_OP (mx_el_gt, mx_inline_gt, M, S) \
  MS_CMP_OP (mx_el_eq, mx_inline_eq, M, S) \
  MS_CMP_OP (mx_el_ne, mx_inline_ne, M, S)

#define NDND_BIN_OP	(	R,
		OP,
		ND1,
		ND2,
		F		)

Value:

R \
  OP (const ND1& m1, const ND2& m2) \
  { \
    return do_mm_binary_op<R, ND1, ND2> (m1, m2, F, #OP); \
  }

#define NDND_BIN_OPS	(	R,
		ND1,
		ND2		)

Value:

NDND_BIN_OP (R, operator +, ND1, ND2, mx_inline_add) \
  NDND_BIN_OP (R, operator -, ND1, ND2, mx_inline_sub) \
  NDND_BIN_OP (R, product,    ND1, ND2, mx_inline_mul) \
  NDND_BIN_OP (R, quotient,   ND1, ND2, mx_inline_div)

#define NDND_BOOL_OP	(	F,
		OP,
		ND1,
		ND2		)

Value:

boolNDArray \
  F (const ND1& m1, const ND2& m2) \
  { \
    return do_mm_binary_op<boolNDArray, ND1, ND2> (m1, m2, OP, #F); \
  }

#define NDND_BOOL_OPS	(	ND1,
		ND2		)

Value:

NDND_BOOL_OP (mx_el_and,     mx_inline_and,     ND1, ND2) \
  NDND_BOOL_OP (mx_el_or,      mx_inline_or,      ND1, ND2) \
  NDND_BOOL_OP (mx_el_not_and, mx_inline_not_and, ND1, ND2) \
  NDND_BOOL_OP (mx_el_not_or,  mx_inline_not_or,  ND1, ND2) \
  NDND_BOOL_OP (mx_el_and_not, mx_inline_and_not, ND1, ND2) \
  NDND_BOOL_OP (mx_el_or_not,  mx_inline_or_not,  ND1, ND2)

#define NDND_CMP_OP	(	F,
		OP,
		ND1,
		ND2		)

Value:

boolNDArray \
  F (const ND1& m1, const ND2& m2) \
  { \
    return do_mm_binary_op<boolNDArray, ND1, ND2> (m1, m2, OP, #F); \
  }

#define NDND_CMP_OPS	(	ND1,
		ND2		)

Value:

NDND_CMP_OP (mx_el_lt, mx_inline_lt, ND1, ND2) \
  NDND_CMP_OP (mx_el_le, mx_inline_le, ND1, ND2) \
  NDND_CMP_OP (mx_el_ge, mx_inline_ge, ND1, ND2) \
  NDND_CMP_OP (mx_el_gt, mx_inline_gt, ND1, ND2) \
  NDND_CMP_OP (mx_el_eq, mx_inline_eq, ND1, ND2) \
  NDND_CMP_OP (mx_el_ne, mx_inline_ne, ND1, ND2)

#define NDND_MAPPER_BODY	(	R,
		NAME		)

Value:

R retval (dims ()); \
  octave_idx_type n = numel (); \
  for (octave_idx_type i = 0; i < n; i++) \
    retval.xelem (i) = NAME (elem (i)); \
  return retval;

#define NDND_MINMAX_FCN	(	FCN,
		OP,
		T		)

Value:

T ## NDArray \
FCN (const T ## NDArray& a, const T ## NDArray& b) \
{ \
  dim_vector dv = a.dims (); \
  octave_idx_type nel = dv.numel (); \
\
  if (dv != b.dims ()) \
    { \
      (*current_liboctave_error_handler) \
        ("two-arg min expecting args of same size"); \
      return T ## NDArray (); \
    } \
\
  if (nel == 0) \
    return T ## NDArray (dv); \
\
  T ## NDArray result (dv); \
\
  for (octave_idx_type i = 0; i < nel; i++) \
    { \
      OCTAVE_QUIT; \
      result (i) = a(i) OP b(i) ? a(i) : b(i); \
    } \
\
  return result; \
}

#define NDS_BIN_OP	(	R,
		OP,
		ND,
		S,
		F		)

Value:

R \
  OP (const ND& m, const S& s) \
  { \
    return do_ms_binary_op<R, ND, S> (m, s, F); \
  }

#define NDS_BIN_OPS	(	R,
		ND,
		S		)

Value:

NDS_BIN_OP (R, operator +, ND, S, mx_inline_add) \
  NDS_BIN_OP (R, operator -, ND, S, mx_inline_sub) \
  NDS_BIN_OP (R, operator *, ND, S, mx_inline_mul) \
  NDS_BIN_OP (R, operator /, ND, S, mx_inline_div)

#define NDS_BOOL_OP	(	F,
		OP,
		ND,
		S		)

Value:

boolNDArray \
  F (const ND& m, const S& s) \
  { \
    return do_ms_binary_op<boolNDArray, ND, S> (m, s, OP); \
  }

#define NDS_BOOL_OPS	(	ND,
		S		)

Value:

NDS_BOOL_OP (mx_el_and,     mx_inline_and,     ND, S) \
  NDS_BOOL_OP (mx_el_or,      mx_inline_or,      ND, S) \
  NDS_BOOL_OP (mx_el_not_and, mx_inline_not_and, ND, S) \
  NDS_BOOL_OP (mx_el_not_or,  mx_inline_not_or,  ND, S) \
  NDS_BOOL_OP (mx_el_and_not, mx_inline_and_not, ND, S) \
  NDS_BOOL_OP (mx_el_or_not,  mx_inline_or_not,  ND, S)

#define NDS_CMP_OP	(	F,
		OP,
		ND,
		S		)

Value:

boolNDArray \
  F (const ND& m, const S& s) \
  { \
    return do_ms_binary_op<boolNDArray, ND, S> (m, s, OP); \
  }

#define NDS_CMP_OPS	(	ND,
		S		)

Value:

NDS_CMP_OP (mx_el_lt, mx_inline_lt, ND, S) \
  NDS_CMP_OP (mx_el_le, mx_inline_le, ND, S) \
  NDS_CMP_OP (mx_el_ge, mx_inline_ge, ND, S) \
  NDS_CMP_OP (mx_el_gt, mx_inline_gt, ND, S) \
  NDS_CMP_OP (mx_el_eq, mx_inline_eq, ND, S) \
  NDS_CMP_OP (mx_el_ne, mx_inline_ne, ND, S)

#define NDS_MINMAX_FCN	(	FCN,
		OP,
		T		)

Value:

T ## NDArray \
FCN (const T ## NDArray& m, octave_ ## T d) \
{ \
  dim_vector dv = m.dims (); \
  octave_idx_type nel = dv.numel (); \
\
  if (nel == 0) \
    return T ## NDArray (dv); \
\
  T ## NDArray result (dv); \
\
  for (octave_idx_type i = 0; i < nel; i++) \
    { \
      OCTAVE_QUIT; \
      result (i) = m (i) OP d ? m(i) : d; \
    } \
\
  return result; \
}

#define octave_mx_op_defs_h   1

#define PMM_BIN_OPS	(	R,
		PM,
		M		)	PMM_MULTIPLY_OP(PM, M);

#define PMM_MULTIPLY_OP	(	PM,
		M		)

Value:

M operator * (const PM& p, const M& x) \
{ \
  octave_idx_type nr = x.rows (), nc = x.columns (); \
  M result; \
  if (p.columns () != nr) \
    gripe_nonconformant ("operator *", p.rows (), p.columns (), nr, nc); \
  else \
    { \
      if (p.is_col_perm ()) \
        { \
          result = M (nr, nc); \
          result.assign (p.pvec (), idx_vector::colon, x); \
        } \
      else \
        result = x.index (p.pvec (), idx_vector::colon); \
    } \
  \
  return result; \
}

#define SDM_BIN_OP	(	R,
		OP,
		S,
		DM		)

Value:

R \
  operator OP (const S& s, const DM& dm) \
  { \
    R r (dm.rows (), dm.cols ()); \
 \
    for (octave_idx_type i = 0; i < dm.length (); i++) \
      r.dgxelem (i) = s OP dm.dgelem (i); \
 \
    return r; \
}

#define SDM_BIN_OPS	(	R,
		S,
		DM		)	SDM_BIN_OP (R, *, S, DM)

#define SM_BIN_OP	(	R,
		OP,
		S,
		M,
		F		)

Value:

R \
  OP (const S& s, const M& m) \
  { \
    return do_sm_binary_op<R, S, M> (s, m, F); \
  }

#define SM_BIN_OPS	(	R,
		S,
		M		)

Value:

SM_BIN_OP (R, operator +, S, M, mx_inline_add) \
  SM_BIN_OP (R, operator -, S, M, mx_inline_sub) \
  SM_BIN_OP (R, operator *, S, M, mx_inline_mul) \
  SM_BIN_OP (R, operator /, S, M, mx_inline_div)

#define SM_BOOL_OP	(	F,
		OP,
		S,
		M		)

Value:

boolMatrix \
  F (const S& s, const M& m) \
  { \
    return do_sm_binary_op<boolMatrix, S, M> (s, m, OP); \
  }

#define SM_BOOL_OPS	(	S,
		M		)

Value:

SM_BOOL_OP (mx_el_and, mx_inline_and, S, M) \
  SM_BOOL_OP (mx_el_or,  mx_inline_or,  S, M)

#define SM_CMP_OP	(	F,
		OP,
		S,
		M		)

Value:

boolMatrix \
  F (const S& s, const M& m) \
  { \
    return do_sm_binary_op<boolMatrix, S, M> (s, m, OP); \
  }

#define SM_CMP_OPS	(	S,
		M		)

Value:

SM_CMP_OP (mx_el_lt, mx_inline_lt, S, M) \
  SM_CMP_OP (mx_el_le, mx_inline_le, S, M) \
  SM_CMP_OP (mx_el_ge, mx_inline_ge, S, M) \
  SM_CMP_OP (mx_el_gt, mx_inline_gt, S, M) \
  SM_CMP_OP (mx_el_eq, mx_inline_eq, S, M) \
  SM_CMP_OP (mx_el_ne, mx_inline_ne, S, M)

#define SND_BIN_OP	(	R,
		OP,
		S,
		ND,
		F		)

Value:

R \
  OP (const S& s, const ND& m) \
  { \
    return do_sm_binary_op<R, S, ND> (s, m, F); \
  }

#define SND_BIN_OPS	(	R,
		S,
		ND		)

Value:

SND_BIN_OP (R, operator +, S, ND, mx_inline_add) \
  SND_BIN_OP (R, operator -, S, ND, mx_inline_sub) \
  SND_BIN_OP (R, operator *, S, ND, mx_inline_mul) \
  SND_BIN_OP (R, operator /, S, ND, mx_inline_div)

#define SND_BOOL_OP	(	F,
		OP,
		S,
		ND		)

Value:

boolNDArray \
  F (const S& s, const ND& m) \
  { \
    return do_sm_binary_op<boolNDArray, S, ND> (s, m, OP); \
  }

#define SND_BOOL_OPS	(	S,
		ND		)

Value:

SND_BOOL_OP (mx_el_and,     mx_inline_and,     S, ND) \
  SND_BOOL_OP (mx_el_or,      mx_inline_or,      S, ND) \
  SND_BOOL_OP (mx_el_not_and, mx_inline_not_and, S, ND) \
  SND_BOOL_OP (mx_el_not_or,  mx_inline_not_or,  S, ND) \
  SND_BOOL_OP (mx_el_and_not, mx_inline_and_not, S, ND) \
  SND_BOOL_OP (mx_el_or_not,  mx_inline_or_not,  S, ND)

#define SND_CMP_OP	(	F,
		OP,
		S,
		ND		)

Value:

boolNDArray \
  F (const S& s, const ND& m) \
  { \
    return do_sm_binary_op<boolNDArray, S, ND> (s, m, OP); \
  }

#define SND_CMP_OPS	(	S,
		ND		)

Value:

SND_CMP_OP (mx_el_lt, mx_inline_lt, S, ND) \
  SND_CMP_OP (mx_el_le, mx_inline_le, S, ND) \
  SND_CMP_OP (mx_el_ge, mx_inline_ge, S, ND) \
  SND_CMP_OP (mx_el_gt, mx_inline_gt, S, ND) \
  SND_CMP_OP (mx_el_eq, mx_inline_eq, S, ND) \
  SND_CMP_OP (mx_el_ne, mx_inline_ne, S, ND)

#define SND_MINMAX_FCN	(	FCN,
		OP,
		T		)

Value:

T ## NDArray \
FCN (octave_ ## T d, const T ## NDArray& m) \
{ \
  dim_vector dv = m.dims (); \
  octave_idx_type nel = dv.numel (); \
\
  if (nel == 0) \
    return T ## NDArray (dv); \
\
  T ## NDArray result (dv); \
\
  for (octave_idx_type i = 0; i < nel; i++) \
    { \
      OCTAVE_QUIT; \
      result (i) = d OP m (i) ? d : m(i); \
    } \
\
  return result; \
}

#define SV_BIN_OP	(	R,
		F,
		OP,
		S,
		V		)

Value:

R \
  F (const S& s, const V& v) \
  { \
    return do_sm_binary_op<R, S, V> (s, v, OP); \
  }

#define SV_BIN_OPS	(	R,
		S,
		V		)

Value:

SV_BIN_OP (R, operator +, mx_inline_add, S, V) \
  SV_BIN_OP (R, operator -, mx_inline_sub, S, V) \
  SV_BIN_OP (R, operator *, mx_inline_mul, S, V) \
  SV_BIN_OP (R, operator /, mx_inline_div, S, V)

#define VS_BIN_OP	(	R,
		F,
		OP,
		V,
		S		)

Value:

R \
  F (const V& v, const S& s) \
  { \
    return do_ms_binary_op<R, V, S> (v, s, OP); \
  }

#define VS_BIN_OPS	(	R,
		V,
		S		)

Value:

VS_BIN_OP (R, operator +, mx_inline_add, V, S) \
  VS_BIN_OP (R, operator -, mx_inline_sub, V, S) \
  VS_BIN_OP (R, operator *, mx_inline_mul, V, S) \
  VS_BIN_OP (R, operator /, mx_inline_div, V, S)

#define VV_BIN_OP	(	R,
		F,
		OP,
		V1,
		V2		)

Value:

R \
  F (const V1& v1, const V2& v2) \
  { \
    return do_mm_binary_op<R, V1, V2> (v1, v2, OP, #F); \
  }

#define VV_BIN_OPS	(	R,
		V1,
		V2		)

Value:

VV_BIN_OP (R, operator +, mx_inline_add, V1, V2) \
  VV_BIN_OP (R, operator -, mx_inline_sub, V1, V2) \
  VV_BIN_OP (R, product,    mx_inline_mul, V1, V2) \
  VV_BIN_OP (R, quotient,   mx_inline_div, V1, V2)