/* * R : A Computer Language for Statistical Data Analysis * Copyright (C) 1995, 1996 Robert Gentleman and Ross Ihaka * Copyright (C) 1999-2017 The R Core Team. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, a copy is available at * https://www.R-project.org/Licenses/ */ /* Internal header, not installed */ /* this header is always to be included from others. It is only called if COMPILING_R is defined (in util.c) or from GNU C systems. There are different conventions for inlining across compilation units. See http://www.greenend.org.uk/rjk/2003/03/inline.html */ #ifndef R_INLINES_H_ #define R_INLINES_H_ /* Probably not able to use C99 semantics in gcc < 4.3.0 */ #if __GNUC__ == 4 && __GNUC_MINOR__ >= 3 && defined(__GNUC_STDC_INLINE__) && !defined(C99_INLINE_SEMANTICS) #define C99_INLINE_SEMANTICS 1 #endif /* Apple's gcc build >5400 (since Xcode 3.0) doesn't support GNU inline in C99 mode */ #if __APPLE_CC__ > 5400 && !defined(C99_INLINE_SEMANTICS) && __STDC_VERSION__ >= 199901L #define C99_INLINE_SEMANTICS 1 #endif #ifdef COMPILING_R /* defined only in inlined.c: this emits standalone code there */ # define INLINE_FUN #else /* This section is normally only used for versions of gcc which do not support C99 semantics. __GNUC_STDC_INLINE__ is defined if GCC is following C99 inline semantics by default: we switch R's usage to the older GNU semantics via attributes. Do this even for __GNUC_GNUC_INLINE__ to shut up warnings in 4.2.x. __GNUC_STDC_INLINE__ and __GNUC_GNU_INLINE__ were added in gcc 4.2.0. */ # if defined(__GNUC_STDC_INLINE__) || defined(__GNUC_GNU_INLINE__) # define INLINE_FUN extern __attribute__((gnu_inline)) inline # else # define INLINE_FUN extern R_INLINE # endif #endif /* ifdef COMPILING_R */ #if C99_INLINE_SEMANTICS # undef INLINE_FUN # ifdef COMPILING_R /* force exported copy */ # define INLINE_FUN extern inline # else /* either inline or link to extern version at compiler's choice */ # define INLINE_FUN inline # endif /* ifdef COMPILING_R */ #endif /* C99_INLINE_SEMANTICS */ #include /* for strlen, strcmp */ /* define inline-able functions */ #ifdef TESTING_WRITE_BARRIER # define STRICT_TYPECHECK # define CATCH_ZERO_LENGTH_ACCESS #endif #if defined(USE_RINTERNALS) || defined(COMPILING_R) /* inline version of CAR to support immediate bindings */ INLINE_FUN SEXP CAR(SEXP e) { if (BNDCELL_TAG(e)) error("bad binding access"); return CAR0(e); } #else SEXP CAR(SEXP e); #endif #ifdef STRICT_TYPECHECK INLINE_FUN void CHKVEC(SEXP x) { switch (TYPEOF(x)) { case CHARSXP: case LGLSXP: case INTSXP: case REALSXP: case CPLXSXP: case STRSXP: case VECSXP: case EXPRSXP: case RAWSXP: case WEAKREFSXP: break; default: error("cannot get data pointer of '%s' objects", type2char(TYPEOF(x))); } } #else # define CHKVEC(x) do {} while(0) #endif INLINE_FUN void *DATAPTR(SEXP x) { CHKVEC(x); if (ALTREP(x)) return ALTVEC_DATAPTR(x); #ifdef CATCH_ZERO_LENGTH_ACCESS /* Attempts to read or write elements of a zero length vector will result in a segfault, rather than read and write random memory. Returning NULL would be more natural, but Matrix seems to assume that even zero-length vectors have non-NULL data pointers, so return (void *) 1 instead. Zero-length CHARSXP objects still have a trailing zero byte so they are not handled. */ else if (STDVEC_LENGTH(x) == 0 && TYPEOF(x) != CHARSXP) return (void *) 1; #endif else return STDVEC_DATAPTR(x); } INLINE_FUN const void *DATAPTR_RO(SEXP x) { CHKVEC(x); if (ALTREP(x)) return ALTVEC_DATAPTR_RO(x); else return STDVEC_DATAPTR(x); } INLINE_FUN const void *DATAPTR_OR_NULL(SEXP x) { CHKVEC(x); if (ALTREP(x)) return ALTVEC_DATAPTR_OR_NULL(x); else return STDVEC_DATAPTR(x); } #ifdef STRICT_TYPECHECK # define CHECK_VECTOR_LGL(x) do { \ if (TYPEOF(x) != LGLSXP) error("bad LGLSXP vector"); \ } while (0) # define CHECK_VECTOR_INT(x) do { \ if (! (TYPEOF(x) == INTSXP || TYPEOF(x) == LGLSXP)) \ error("bad INTSXP vector"); \ } while (0) # define CHECK_VECTOR_REAL(x) do { \ if (TYPEOF(x) != REALSXP) error("bad REALSXP vector"); \ } while (0) # define CHECK_VECTOR_CPLX(x) do { \ if (TYPEOF(x) != CPLXSXP) error("bad CPLXSXP vector"); \ } while (0) # define CHECK_VECTOR_RAW(x) do { \ if (TYPEOF(x) != RAWSXP) error("bad RAWSXP vector"); \ } while (0) #else # define CHECK_VECTOR_LGL(x) do { } while(0) # define CHECK_VECTOR_INT(x) do { } while(0) # define CHECK_VECTOR_REAL(x) do { } while(0) # define CHECK_VECTOR_CPLX(x) do { } while(0) # define CHECK_VECTOR_RAW(x) do { } while(0) #endif INLINE_FUN const int *LOGICAL_OR_NULL(SEXP x) { CHECK_VECTOR_LGL(x); return ALTREP(x) ? ALTVEC_DATAPTR_OR_NULL(x) : STDVEC_DATAPTR(x); } INLINE_FUN const int *INTEGER_OR_NULL(SEXP x) { CHECK_VECTOR_INT(x); return ALTREP(x) ? ALTVEC_DATAPTR_OR_NULL(x) : STDVEC_DATAPTR(x); } INLINE_FUN const double *REAL_OR_NULL(SEXP x) { CHECK_VECTOR_REAL(x); return ALTREP(x) ? ALTVEC_DATAPTR_OR_NULL(x) : STDVEC_DATAPTR(x); } INLINE_FUN const double *COMPLEX_OR_NULL(SEXP x) { CHECK_VECTOR_CPLX(x); return ALTREP(x) ? ALTVEC_DATAPTR_OR_NULL(x) : STDVEC_DATAPTR(x); } INLINE_FUN const double *RAW_OR_NULL(SEXP x) { CHECK_VECTOR_RAW(x); return ALTREP(x) ? ALTVEC_DATAPTR_OR_NULL(x) : STDVEC_DATAPTR(x); } INLINE_FUN R_xlen_t XLENGTH_EX(SEXP x) { return ALTREP(x) ? ALTREP_LENGTH(x) : STDVEC_LENGTH(x); } INLINE_FUN R_xlen_t XTRUELENGTH(SEXP x) { return ALTREP(x) ? ALTREP_TRUELENGTH(x) : STDVEC_TRUELENGTH(x); } INLINE_FUN int LENGTH_EX(SEXP x, const char *file, int line) { if (x == R_NilValue) return 0; R_xlen_t len = XLENGTH(x); #ifdef LONG_VECTOR_SUPPORT if (len > R_SHORT_LEN_MAX) R_BadLongVector(x, file, line); #endif return (int) len; } #ifdef STRICT_TYPECHECK # define CHECK_STDVEC_LGL(x) do { \ CHECK_VECTOR_LGL(x); \ if (ALTREP(x)) error("bad standard LGLSXP vector"); \ } while (0) # define CHECK_STDVEC_INT(x) do { \ CHECK_VECTOR_INT(x); \ if (ALTREP(x)) error("bad standard INTSXP vector"); \ } while (0) # define CHECK_STDVEC_REAL(x) do { \ CHECK_VECTOR_REAL(x); \ if (ALTREP(x)) error("bad standard REALSXP vector"); \ } while (0) # define CHECK_STDVEC_CPLX(x) do { \ CHECK_VECTOR_CPLX(x); \ if (ALTREP(x)) error("bad standard CPLXSXP vector"); \ } while (0) # define CHECK_STDVEC_RAW(x) do { \ CHECK_VECTOR_RAW(x); \ if (ALTREP(x)) error("bad standard RAWSXP vector"); \ } while (0) # define CHECK_SCALAR_LGL(x) do { \ CHECK_STDVEC_LGL(x); \ if (XLENGTH(x) != 1) error("bad LGLSXP scalar"); \ } while (0) # define CHECK_SCALAR_INT(x) do { \ CHECK_STDVEC_INT(x); \ if (XLENGTH(x) != 1) error("bad INTSXP scalar"); \ } while (0) # define CHECK_SCALAR_REAL(x) do { \ CHECK_STDVEC_REAL(x); \ if (XLENGTH(x) != 1) error("bad REALSXP scalar"); \ } while (0) # define CHECK_SCALAR_CPLX(x) do { \ CHECK_STDVEC_CPLX(x); \ if (XLENGTH(x) != 1) error("bad CPLXSXP scalar"); \ } while (0) # define CHECK_SCALAR_RAW(x) do { \ CHECK_STDVEC_RAW(x); \ if (XLENGTH(x) != 1) error("bad RAWSXP scalar"); \ } while (0) # define CHECK_BOUNDS_ELT(x, i) do { \ if (i < 0 || i > XLENGTH(x)) \ error("subscript out of bounds"); \ } while (0) # define CHECK_VECTOR_LGL_ELT(x, i) do { \ SEXP ce__x__ = (x); \ R_xlen_t ce__i__ = (i); \ CHECK_VECTOR_LGL(ce__x__); \ CHECK_BOUNDS_ELT(ce__x__, ce__i__); \ } while (0) # define CHECK_VECTOR_INT_ELT(x, i) do { \ SEXP ce__x__ = (x); \ R_xlen_t ce__i__ = (i); \ CHECK_VECTOR_INT(ce__x__); \ CHECK_BOUNDS_ELT(ce__x__, ce__i__); \ } while (0) # define CHECK_VECTOR_REAL_ELT(x, i) do { \ SEXP ce__x__ = (x); \ R_xlen_t ce__i__ = (i); \ CHECK_VECTOR_REAL(ce__x__); \ CHECK_BOUNDS_ELT(ce__x__, ce__i__); \ } while (0) # define CHECK_VECTOR_CPLX_ELT(x, i) do { \ SEXP ce__x__ = (x); \ R_xlen_t ce__i__ = (i); \ CHECK_VECTOR_CPLX(ce__x__); \ CHECK_BOUNDS_ELT(ce__x__, ce__i__); \ } while (0) # define CHECK_VECTOR_RAW_ELT(x, i) do { \ SEXP ce__x__ = (x); \ R_xlen_t ce__i__ = (i); \ CHECK_VECTOR_RAW(ce__x__); \ CHECK_BOUNDS_ELT(ce__x__, ce__i__); \ } while (0) #else # define CHECK_STDVEC_LGL(x) do { } while(0) # define CHECK_STDVEC_INT(x) do { } while(0) # define CHECK_STDVEC_REAL(x) do { } while(0) # define CHECK_STDVEC_CPLX(x) do { } while(0) # define CHECK_STDVEC_RAW(x) do { } while(0) # define CHECK_SCALAR_LGL(x) do { } while(0) # define CHECK_SCALAR_INT(x) do { } while(0) # define CHECK_SCALAR_REAL(x) do { } while(0) # define CHECK_SCALAR_CPLX(x) do { } while(0) # define CHECK_SCALAR_RAW(x) do { } while(0) # define CHECK_VECTOR_LGL_ELT(x, i) do { } while(0) # define CHECK_VECTOR_INT_ELT(x, i) do { } while(0) # define CHECK_VECTOR_REAL_ELT(x, i) do { } while(0) # define CHECK_VECTOR_CPLX_ELT(x, i) do { } while(0) # define CHECK_VECTOR_RAW_ELT(x, i) do { } while(0) #endif INLINE_FUN int *LOGICAL0(SEXP x) { CHECK_STDVEC_LGL(x); return (int *) STDVEC_DATAPTR(x); } INLINE_FUN Rboolean SCALAR_LVAL(SEXP x) { CHECK_SCALAR_LGL(x); return LOGICAL0(x)[0]; } INLINE_FUN void SET_SCALAR_LVAL(SEXP x, Rboolean v) { CHECK_SCALAR_LGL(x); LOGICAL0(x)[0] = v; } INLINE_FUN int *INTEGER0(SEXP x) { CHECK_STDVEC_INT(x); return (int *) STDVEC_DATAPTR(x); } INLINE_FUN int SCALAR_IVAL(SEXP x) { CHECK_SCALAR_INT(x); return INTEGER0(x)[0]; } INLINE_FUN void SET_SCALAR_IVAL(SEXP x, int v) { CHECK_SCALAR_INT(x); INTEGER0(x)[0] = v; } INLINE_FUN double *REAL0(SEXP x) { CHECK_STDVEC_REAL(x); return (double *) STDVEC_DATAPTR(x); } INLINE_FUN double SCALAR_DVAL(SEXP x) { CHECK_SCALAR_REAL(x); return REAL0(x)[0]; } INLINE_FUN void SET_SCALAR_DVAL(SEXP x, double v) { CHECK_SCALAR_REAL(x); REAL0(x)[0] = v; } INLINE_FUN Rcomplex *COMPLEX0(SEXP x) { CHECK_STDVEC_CPLX(x); return (Rcomplex *) STDVEC_DATAPTR(x); } INLINE_FUN Rcomplex SCALAR_CVAL(SEXP x) { CHECK_SCALAR_CPLX(x); return COMPLEX0(x)[0]; } INLINE_FUN void SET_SCALAR_CVAL(SEXP x, Rcomplex v) { CHECK_SCALAR_CPLX(x); COMPLEX0(x)[0] = v; } INLINE_FUN Rbyte *RAW0(SEXP x) { CHECK_STDVEC_RAW(x); return (Rbyte *) STDVEC_DATAPTR(x); } INLINE_FUN Rbyte SCALAR_BVAL(SEXP x) { CHECK_SCALAR_RAW(x); return RAW0(x)[0]; } INLINE_FUN void SET_SCALAR_BVAL(SEXP x, Rbyte v) { CHECK_SCALAR_RAW(x); RAW0(x)[0] = v; } INLINE_FUN SEXP ALTREP_CLASS(SEXP x) { return TAG(x); } INLINE_FUN SEXP R_altrep_data1(SEXP x) { return CAR(x); } INLINE_FUN SEXP R_altrep_data2(SEXP x) { return CDR(x); } INLINE_FUN void R_set_altrep_data1(SEXP x, SEXP v) { SETCAR(x, v); } INLINE_FUN void R_set_altrep_data2(SEXP x, SEXP v) { SETCDR(x, v); } INLINE_FUN int INTEGER_ELT(SEXP x, R_xlen_t i) { CHECK_VECTOR_INT_ELT(x, i); return ALTREP(x) ? ALTINTEGER_ELT(x, i) : INTEGER0(x)[i]; } INLINE_FUN void SET_INTEGER_ELT(SEXP x, R_xlen_t i, int v) { CHECK_VECTOR_INT_ELT(x, i); if (ALTREP(x)) ALTINTEGER_SET_ELT(x, i, v); else INTEGER0(x)[i] = v; } INLINE_FUN int LOGICAL_ELT(SEXP x, R_xlen_t i) { CHECK_VECTOR_LGL_ELT(x, i); return ALTREP(x) ? ALTLOGICAL_ELT(x, i) : LOGICAL0(x)[i]; } INLINE_FUN void SET_LOGICAL_ELT(SEXP x, R_xlen_t i, int v) { CHECK_VECTOR_LGL_ELT(x, i); if (ALTREP(x)) ALTLOGICAL_SET_ELT(x, i, v); else LOGICAL0(x)[i] = v; } INLINE_FUN double REAL_ELT(SEXP x, R_xlen_t i) { CHECK_VECTOR_REAL_ELT(x, i); return ALTREP(x) ? ALTREAL_ELT(x, i) : REAL0(x)[i]; } INLINE_FUN void SET_REAL_ELT(SEXP x, R_xlen_t i, double v) { CHECK_VECTOR_REAL_ELT(x, i); if (ALTREP(x)) ALTREAL_SET_ELT(x, i, v); else REAL0(x)[i] = v; } INLINE_FUN Rcomplex COMPLEX_ELT(SEXP x, R_xlen_t i) { CHECK_VECTOR_CPLX_ELT(x, i); return ALTREP(x) ? ALTCOMPLEX_ELT(x, i) : COMPLEX0(x)[i]; } INLINE_FUN void SET_COMPLEX_ELT(SEXP x, R_xlen_t i, Rcomplex v) { CHECK_VECTOR_CPLX_ELT(x, i); if (ALTREP(x)) ALTCOMPLEX_SET_ELT(x, i, v); else COMPLEX0(x)[i] = v; } INLINE_FUN Rbyte RAW_ELT(SEXP x, R_xlen_t i) { CHECK_VECTOR_RAW_ELT(x, i); return ALTREP(x) ? ALTRAW_ELT(x, i) : RAW0(x)[i]; } INLINE_FUN void SET_RAW_ELT(SEXP x, R_xlen_t i, Rbyte v) { CHECK_VECTOR_RAW_ELT(x, i); if (ALTREP(x)) ALTRAW_SET_ELT(x, i, v); else RAW0(x)[i] = v; } #if !defined(COMPILING_R) && !defined(COMPILING_MEMORY_C) && \ !defined(TESTING_WRITE_BARRIER) /* if not inlining use version in memory.c with more error checking */ INLINE_FUN SEXP STRING_ELT(SEXP x, R_xlen_t i) { if (ALTREP(x)) return ALTSTRING_ELT(x, i); else { SEXP *ps = STDVEC_DATAPTR(x); return ps[i]; } } #else SEXP STRING_ELT(SEXP x, R_xlen_t i); #endif #ifdef INLINE_PROTECT extern int R_PPStackSize; extern int R_PPStackTop; extern SEXP* R_PPStack; INLINE_FUN SEXP protect(SEXP s) { R_CHECK_THREAD; if (R_PPStackTop < R_PPStackSize) R_PPStack[R_PPStackTop++] = s; else R_signal_protect_error(); return s; } INLINE_FUN void unprotect(int l) { R_CHECK_THREAD; #ifdef PROTECT_PARANOID if (R_PPStackTop >= l) R_PPStackTop -= l; else R_signal_unprotect_error(); #else R_PPStackTop -= l; #endif } INLINE_FUN void R_ProtectWithIndex(SEXP s, PROTECT_INDEX *pi) { protect(s); *pi = R_PPStackTop - 1; } INLINE_FUN void R_Reprotect(SEXP s, PROTECT_INDEX i) { R_CHECK_THREAD; if (i >= R_PPStackTop || i < 0) R_signal_reprotect_error(i); R_PPStack[i] = s; } #endif /* INLINE_PROTECT */ /* from dstruct.c */ /* length - length of objects */ int Rf_envlength(SEXP rho); /* TODO: a Length(.) {say} which is length() + dispatch (S3 + S4) if needed for one approach, see do_seq_along() in ../main/seq.c */ INLINE_FUN R_len_t length(SEXP s) { switch (TYPEOF(s)) { case NILSXP: return 0; case LGLSXP: case INTSXP: case REALSXP: case CPLXSXP: case STRSXP: case CHARSXP: case VECSXP: case EXPRSXP: case RAWSXP: return LENGTH(s); case LISTSXP: case LANGSXP: case DOTSXP: { int i = 0; while (s != NULL && s != R_NilValue) { i++; s = CDR(s); } return i; } case ENVSXP: return Rf_envlength(s); default: return 1; } } R_xlen_t Rf_envxlength(SEXP rho); INLINE_FUN R_xlen_t xlength(SEXP s) { switch (TYPEOF(s)) { case NILSXP: return 0; case LGLSXP: case INTSXP: case REALSXP: case CPLXSXP: case STRSXP: case CHARSXP: case VECSXP: case EXPRSXP: case RAWSXP: return XLENGTH(s); case LISTSXP: case LANGSXP: case DOTSXP: { // it is implausible this would be >= 2^31 elements, but allow it R_xlen_t i = 0; while (s != NULL && s != R_NilValue) { i++; s = CDR(s); } return i; } case ENVSXP: return Rf_envxlength(s); default: return 1; } } /* regular allocVector() as a special case of allocVector3() with no custom allocator */ INLINE_FUN SEXP allocVector(SEXPTYPE type, R_xlen_t length) { return allocVector3(type, length, NULL); } /* from list.c */ /* Return a dotted pair with the given CAR and CDR. */ /* The (R) TAG slot on the cell is set to NULL. */ /* Get the i-th element of a list */ INLINE_FUN SEXP elt(SEXP list, int i) { int j; SEXP result = list; if ((i < 0) || (i > length(list))) return R_NilValue; else for (j = 0; j < i; j++) result = CDR(result); return CAR(result); } /* Return the last element of a list */ INLINE_FUN SEXP lastElt(SEXP list) { SEXP result = R_NilValue; while (list != R_NilValue) { result = list; list = CDR(list); } return result; } /* Shorthands for creating small lists */ INLINE_FUN SEXP list1(SEXP s) { return CONS(s, R_NilValue); } INLINE_FUN SEXP list2(SEXP s, SEXP t) { PROTECT(s); s = CONS(s, list1(t)); UNPROTECT(1); return s; } INLINE_FUN SEXP list3(SEXP s, SEXP t, SEXP u) { PROTECT(s); s = CONS(s, list2(t, u)); UNPROTECT(1); return s; } INLINE_FUN SEXP list4(SEXP s, SEXP t, SEXP u, SEXP v) { PROTECT(s); s = CONS(s, list3(t, u, v)); UNPROTECT(1); return s; } INLINE_FUN SEXP list5(SEXP s, SEXP t, SEXP u, SEXP v, SEXP w) { PROTECT(s); s = CONS(s, list4(t, u, v, w)); UNPROTECT(1); return s; } INLINE_FUN SEXP list6(SEXP s, SEXP t, SEXP u, SEXP v, SEXP w, SEXP x) { PROTECT(s); s = CONS(s, list5(t, u, v, w, x)); UNPROTECT(1); return s; } /* Destructive list append : See also ``append'' */ INLINE_FUN SEXP listAppend(SEXP s, SEXP t) { SEXP r; if (s == R_NilValue) return t; r = s; while (CDR(r) != R_NilValue) r = CDR(r); SETCDR(r, t); return s; } /* Language based list constructs. These are identical to the list */ /* constructs, but the results can be evaluated. */ /* Return a (language) dotted pair with the given car and cdr */ INLINE_FUN SEXP lcons(SEXP car, SEXP cdr) { SEXP e = cons(car, cdr); SET_TYPEOF(e, LANGSXP); return e; } INLINE_FUN SEXP lang1(SEXP s) { return LCONS(s, R_NilValue); } INLINE_FUN SEXP lang2(SEXP s, SEXP t) { PROTECT(s); s = LCONS(s, list1(t)); UNPROTECT(1); return s; } INLINE_FUN SEXP lang3(SEXP s, SEXP t, SEXP u) { PROTECT(s); s = LCONS(s, list2(t, u)); UNPROTECT(1); return s; } INLINE_FUN SEXP lang4(SEXP s, SEXP t, SEXP u, SEXP v) { PROTECT(s); s = LCONS(s, list3(t, u, v)); UNPROTECT(1); return s; } INLINE_FUN SEXP lang5(SEXP s, SEXP t, SEXP u, SEXP v, SEXP w) { PROTECT(s); s = LCONS(s, list4(t, u, v, w)); UNPROTECT(1); return s; } INLINE_FUN SEXP lang6(SEXP s, SEXP t, SEXP u, SEXP v, SEXP w, SEXP x) { PROTECT(s); s = LCONS(s, list5(t, u, v, w, x)); UNPROTECT(1); return s; } /* from util.c */ /* Check to see if the arrays "x" and "y" have the identical extents */ INLINE_FUN Rboolean conformable(SEXP x, SEXP y) { int i, n; PROTECT(x = getAttrib(x, R_DimSymbol)); y = getAttrib(y, R_DimSymbol); UNPROTECT(1); if ((n = length(x)) != length(y)) return FALSE; for (i = 0; i < n; i++) if (INTEGER(x)[i] != INTEGER(y)[i]) return FALSE; return TRUE; } /* NOTE: R's inherits() is based on inherits3() in ../main/objects.c * Here, use char / CHAR() instead of the slower more general translateChar() */ INLINE_FUN Rboolean inherits(SEXP s, const char *name) { SEXP klass; int i, nclass; if (OBJECT(s)) { klass = getAttrib(s, R_ClassSymbol); nclass = length(klass); for (i = 0; i < nclass; i++) { if (!strcmp(CHAR(STRING_ELT(klass, i)), name)) return TRUE; } } return FALSE; } INLINE_FUN Rboolean isValidString(SEXP x) { return TYPEOF(x) == STRSXP && LENGTH(x) > 0 && TYPEOF(STRING_ELT(x, 0)) != NILSXP; } /* non-empty ("") valid string :*/ INLINE_FUN Rboolean isValidStringF(SEXP x) { return isValidString(x) && CHAR(STRING_ELT(x, 0))[0]; } INLINE_FUN Rboolean isUserBinop(SEXP s) { if (TYPEOF(s) == SYMSXP) { const char *str = CHAR(PRINTNAME(s)); if (strlen(str) >= 2 && str[0] == '%' && str[strlen(str)-1] == '%') return TRUE; } return FALSE; } INLINE_FUN Rboolean isFunction(SEXP s) { return (TYPEOF(s) == CLOSXP || TYPEOF(s) == BUILTINSXP || TYPEOF(s) == SPECIALSXP); } INLINE_FUN Rboolean isPrimitive(SEXP s) { return (TYPEOF(s) == BUILTINSXP || TYPEOF(s) == SPECIALSXP); } INLINE_FUN Rboolean isList(SEXP s) { return (s == R_NilValue || TYPEOF(s) == LISTSXP); } INLINE_FUN Rboolean isNewList(SEXP s) { return (s == R_NilValue || TYPEOF(s) == VECSXP); } INLINE_FUN Rboolean isPairList(SEXP s) { switch (TYPEOF(s)) { case NILSXP: case LISTSXP: case LANGSXP: case DOTSXP: return TRUE; default: return FALSE; } } INLINE_FUN Rboolean isVectorList(SEXP s) { switch (TYPEOF(s)) { case VECSXP: case EXPRSXP: return TRUE; default: return FALSE; } } INLINE_FUN Rboolean isVectorAtomic(SEXP s) { switch (TYPEOF(s)) { case LGLSXP: case INTSXP: case REALSXP: case CPLXSXP: case STRSXP: case RAWSXP: return TRUE; default: /* including NULL */ return FALSE; } } INLINE_FUN Rboolean isVector(SEXP s)/* === isVectorList() or isVectorAtomic() */ { switch(TYPEOF(s)) { case LGLSXP: case INTSXP: case REALSXP: case CPLXSXP: case STRSXP: case RAWSXP: case VECSXP: case EXPRSXP: return TRUE; default: return FALSE; } } INLINE_FUN Rboolean isFrame(SEXP s) { SEXP klass; int i; if (OBJECT(s)) { klass = getAttrib(s, R_ClassSymbol); for (i = 0; i < length(klass); i++) if (!strcmp(CHAR(STRING_ELT(klass, i)), "data.frame")) return TRUE; } return FALSE; } /* DIFFERENT than R's is.language(.) in ../main/coerce.c [do_is(), case 301:] * which is <=> SYMSXP || LANGSXP || EXPRSXP */ INLINE_FUN Rboolean isLanguage(SEXP s) { return (s == R_NilValue || TYPEOF(s) == LANGSXP); } INLINE_FUN Rboolean isMatrix(SEXP s) { SEXP t; if (isVector(s)) { t = getAttrib(s, R_DimSymbol); /* You are not supposed to be able to assign a non-integer dim, although this might be possible by misuse of ATTRIB. */ if (TYPEOF(t) == INTSXP && LENGTH(t) == 2) return TRUE; } return FALSE; } INLINE_FUN Rboolean isArray(SEXP s) { SEXP t; if (isVector(s)) { t = getAttrib(s, R_DimSymbol); /* You are not supposed to be able to assign a 0-length dim, nor a non-integer dim */ if (TYPEOF(t) == INTSXP && LENGTH(t) > 0) return TRUE; } return FALSE; } INLINE_FUN Rboolean isTs(SEXP s) { return (isVector(s) && getAttrib(s, R_TspSymbol) != R_NilValue); } INLINE_FUN Rboolean isInteger(SEXP s) { return (TYPEOF(s) == INTSXP && !inherits(s, "factor")); } INLINE_FUN Rboolean isFactor(SEXP s) { return (TYPEOF(s) == INTSXP && inherits(s, "factor")); } INLINE_FUN int nlevels(SEXP f) { if (!isFactor(f)) return 0; return LENGTH(getAttrib(f, R_LevelsSymbol)); } /* Is an object of numeric type. */ /* FIXME: the LGLSXP case should be excluded here * (really? in many places we affirm they are treated like INTs)*/ INLINE_FUN Rboolean isNumeric(SEXP s) { switch(TYPEOF(s)) { case INTSXP: if (inherits(s,"factor")) return FALSE; case LGLSXP: case REALSXP: return TRUE; default: return FALSE; } } /** Is an object "Numeric" or complex */ INLINE_FUN Rboolean isNumber(SEXP s) { switch(TYPEOF(s)) { case INTSXP: if (inherits(s,"factor")) return FALSE; case LGLSXP: case REALSXP: case CPLXSXP: return TRUE; default: return FALSE; } } /* As from R 2.4.0 we check that the value is allowed. */ INLINE_FUN SEXP ScalarLogical(int x) { extern SEXP R_LogicalNAValue, R_TrueValue, R_FalseValue; if (x == NA_LOGICAL) return R_LogicalNAValue; else if (x != 0) return R_TrueValue; else return R_FalseValue; } INLINE_FUN SEXP ScalarInteger(int x) { SEXP ans = allocVector(INTSXP, 1); SET_SCALAR_IVAL(ans, x); return ans; } INLINE_FUN SEXP ScalarReal(double x) { SEXP ans = allocVector(REALSXP, 1); SET_SCALAR_DVAL(ans, x); return ans; } INLINE_FUN SEXP ScalarComplex(Rcomplex x) { SEXP ans = allocVector(CPLXSXP, 1); SET_SCALAR_CVAL(ans, x); return ans; } INLINE_FUN SEXP ScalarString(SEXP x) { SEXP ans; PROTECT(x); ans = allocVector(STRSXP, (R_xlen_t)1); SET_STRING_ELT(ans, (R_xlen_t)0, x); UNPROTECT(1); return ans; } INLINE_FUN SEXP ScalarRaw(Rbyte x) { SEXP ans = allocVector(RAWSXP, 1); SET_SCALAR_BVAL(ans, x); return ans; } /* Check to see if a list can be made into a vector. */ /* it must have every element being a vector of length 1. */ /* BUT it does not exclude 0! */ INLINE_FUN Rboolean isVectorizable(SEXP s) { if (s == R_NilValue) return TRUE; else if (isNewList(s)) { R_xlen_t i, n; n = XLENGTH(s); for (i = 0 ; i < n; i++) if (!isVector(VECTOR_ELT(s, i)) || XLENGTH(VECTOR_ELT(s, i)) > 1) return FALSE; return TRUE; } else if (isList(s)) { for ( ; s != R_NilValue; s = CDR(s)) if (!isVector(CAR(s)) || LENGTH(CAR(s)) > 1) return FALSE; return TRUE; } else return FALSE; } /** * Create a named vector of type TYP * * @example const char *nms[] = {"xi", "yi", "zi", ""}; * mkNamed(VECSXP, nms); =~= R list(xi=, yi=, zi=) * * @param TYP a vector SEXP type (e.g. REALSXP) * @param names names of list elements with null string appended * * @return (pointer to a) named vector of type TYP */ INLINE_FUN SEXP mkNamed(SEXPTYPE TYP, const char **names) { SEXP ans, nms; R_xlen_t i, n; for (n = 0; strlen(names[n]) > 0; n++) {} ans = PROTECT(allocVector(TYP, n)); nms = PROTECT(allocVector(STRSXP, n)); for (i = 0; i < n; i++) SET_STRING_ELT(nms, i, mkChar(names[i])); setAttrib(ans, R_NamesSymbol, nms); UNPROTECT(2); return ans; } /* from gram.y */ /* short cut for ScalarString(mkChar(s)) : */ INLINE_FUN SEXP mkString(const char *s) { SEXP t; PROTECT(t = allocVector(STRSXP, (R_xlen_t)1)); SET_STRING_ELT(t, (R_xlen_t)0, mkChar(s)); UNPROTECT(1); return t; } /* index of a given C string in (translated) R string vector */ INLINE_FUN int stringPositionTr(SEXP string, const char *translatedElement) { int slen = LENGTH(string); int i; const void *vmax = vmaxget(); for (i = 0 ; i < slen; i++) { Rboolean found = ! strcmp(translateChar(STRING_ELT(string, i)), translatedElement); vmaxset(vmax); if (found) return i; } return -1; /* not found */ } /* duplicate RHS value of complex assignment if necessary to prevent cycles */ INLINE_FUN SEXP R_FixupRHS(SEXP x, SEXP y) { if( y != R_NilValue && MAYBE_REFERENCED(y) ) { if (R_cycle_detected(x, y)) { #ifdef WARNING_ON_CYCLE_DETECT warning("cycle detected"); R_cycle_detected(x, y); #endif y = duplicate(y); } else ENSURE_NAMEDMAX(y); } return y; } #endif /* R_INLINES_H_ */