/* n/i.c ** ** This file is in the public domain. */ #include "all.h" /* u3_ci_words(): ** ** Copy [a] words from [b] into an atom. */ u3_noun u3_ci_words(c3_w a_w, const c3_w* b_w) { /* Strip trailing zeroes. */ while ( a_w && !b_w[a_w - 1] ) { a_w--; } /* Check for cat. */ if ( !a_w ) { return 0; } else if ( (a_w == 1) && !(b_w[0] >> 31) ) { return b_w[0]; } /* Allocate, fill, return. */ { c3_w* nov_w = u3_ca_walloc(a_w + c3_wiseof(u3_cs_atom)); u3_cs_atom* nov_u = (void*)nov_w; nov_u->mug_w = 0; nov_u->len_w = a_w; /* Fill the words. */ { c3_w i_w; for ( i_w=0; i_w < a_w; i_w++ ) { nov_u->buf_w[i_w] = b_w[i_w]; } } return u3_co_to_pug(u3_co_outa(nov_w)); } } /* u3_ci_chubs(): ** ** Construct `a` double-words from `b`, LSD first, as an atom. */ u3_atom u3_ci_chubs(c3_w a_w, const c3_d* b_d) { c3_w *b_w = c3_malloc(a_w * 8); c3_w i_w; u3_atom p; for ( i_w = 0; i_w < a_w; i_w++ ) { b_w[(2 * i_w)] = b_d[i_w] & 0xffffffffULL; b_w[(2 * i_w) + 1] = b_d[i_w] >> 32ULL; } p = u3_ci_words((a_w * 2), b_w); free(b_w); return p; } /* u3_ci_bytes(): ** ** Copy `a` bytes from `b` to an LSB first atom. */ u3_noun u3_ci_bytes(c3_w a_w, const c3_y* b_y) { /* Strip trailing zeroes. */ while ( a_w && !b_y[a_w - 1] ) { a_w--; } /* Check for cat. */ if ( a_w <= 4 ) { if ( !a_w ) { return 0; } else if ( a_w == 1 ) { return b_y[0]; } else if ( a_w == 2 ) { return (b_y[0] | (b_y[1] << 8)); } else if ( a_w == 3 ) { return (b_y[0] | (b_y[1] << 8) | (b_y[2] << 16)); } else if ( (b_y[3] <= 0x7f) ) { return (b_y[0] | (b_y[1] << 8) | (b_y[2] << 16) | (b_y[3] << 24)); } } /* Allocate, fill, return. */ { c3_w len_w = (a_w + 3) >> 2; c3_w* nov_w = u3_ca_walloc((len_w + c3_wiseof(u3_cs_atom))); u3_cs_atom* nov_u = (void*)nov_w; nov_u->mug_w = 0; nov_u->len_w = len_w; /* Clear the words. */ { c3_w i_w; for ( i_w=0; i_w < len_w; i_w++ ) { nov_u->buf_w[i_w] = 0; } } /* Fill the bytes. */ { c3_w i_w; for ( i_w=0; i_w < a_w; i_w++ ) { nov_u->buf_w[i_w >> 2] |= (b_y[i_w] << ((i_w & 3) * 8)); } } return u3_co_to_pug(u3_co_outa(nov_w)); } } /* u3_ci_mp(): ** ** Copy the GMP integer `a` into an atom, and clear it. */ u3_noun u3_ci_mp(mpz_t a_mp) { /* Efficiency: unnecessary copy. */ { c3_w pyg_w = mpz_size(a_mp) * ((sizeof(mp_limb_t)) / 4); c3_w *buz_w = alloca(pyg_w * 4); c3_w i_w; for ( i_w = 0; i_w < pyg_w; i_w++ ) { buz_w[i_w] = 0; } mpz_export(buz_w, 0, -1, 4, 0, 0, a_mp); mpz_clear(a_mp); return u3_ci_words(pyg_w, buz_w); } } /* u3_ci_vint(): ** ** Create `a + 1`. */ u3_noun u3_ci_vint(u3_noun a) { c3_assert(u3_none != a); if ( u3_so(u3_co_is_cat(a)) ) { c3_w vin_w = (a + 1); if ( a == 0x7fffffff ) { return u3_ci_words(1, &vin_w); } else return vin_w; } else if ( u3_so(u3_co_is_cell(a)) ) { return u3_cm_bail(c3__exit); } else { mpz_t a_mp; u3_cr_mp(a_mp, a); u3_ca_lose(a); mpz_add_ui(a_mp, a_mp, 1); return u3_ci_mp(a_mp); } } /* u3_ci_cell(): ** ** Produce the cell `[a b]`. */ u3_noun u3_ci_cell(u3_noun a, u3_noun b) { c3_assert(u3_none != a); c3_assert(u3_none != b); c3_assert(u3_ne(u3_co_is_junior(a))); c3_assert(u3_ne(u3_co_is_junior(b))); { c3_w* nov_w = u3_ca_walloc(c3_wiseof(u3_cs_cell)); u3_cs_cell* nov_u = (void *)nov_w; nov_u->mug_w = 0; nov_u->hed = a; nov_u->tel = b; return u3_co_to_pom(u3_co_outa(nov_w)); } } /* u3_ci_trel(): ** ** Produce the triple `[a b c]`. */ u3_noun u3_ci_trel(u3_noun a, u3_noun b, u3_noun c) { return u3_ci_cell(a, u3_ci_cell(b, c)); } /* u3_ci_qual(): ** ** Produce the cell `[a b c d]`. */ u3_noun u3_ci_qual(u3_noun a, u3_noun b, u3_noun c, u3_noun d) { return u3_ci_cell(a, u3_ci_trel(b, c, d)); } /* u3_ci_string(): ** ** Produce an LSB-first atom from the C string `a`. */ u3_noun u3_ci_string(const c3_c* a_c) { return u3_ci_bytes(strlen(a_c), (c3_y *)a_c); } /* u3_ci_tape(): from a C string, to a list of bytes. */ u3_atom u3_ci_tape(const c3_c* txt_c) { if ( !*txt_c ) { return u3_nul; } else return u3_ci_cell(*txt_c, u3_ci_tape(txt_c + 1)); } /* u3_ci_decimal(): ** ** Parse `a` as a list of decimal digits. */ u3_atom u3_ci_decimal(u3_noun a); /* u3_ci_heximal(): ** ** Parse `a` as a list of hex digits. */ u3_noun u3_ci_heximal(u3_noun a); /* u3_ci_list(): ** ** Generate a null-terminated list, with `u3_none` as terminator. */ u3_noun u3_ci_list(u3_weak one, ...); /* u3_ci_molt(): ** ** Mutate `som` with a 0-terminated list of axis, noun pairs. ** Axes must be cats (31 bit). */ struct _molt_pair { c3_w axe_w; u3_noun som; }; static c3_w _molt_cut(c3_w len_w, struct _molt_pair* pms_m) { c3_w i_w, cut_t, cut_w; cut_t = c3_false; cut_w = 0; for ( i_w = 0; i_w < len_w; i_w++ ) { c3_w axe_w = pms_m[i_w].axe_w; if ( (cut_t == c3_false) && (3 == u3_ax_cap(axe_w)) ) { cut_t = c3_true; cut_w = i_w; } pms_m[i_w].axe_w = u3_ax_mas(axe_w); } return cut_t ? cut_w : i_w; } static u3_noun // transfer _molt_apply(u3_noun som, // retain c3_w len_w, struct _molt_pair* pms_m) // transfer { if ( len_w == 0 ) { return u3_ca_gain(som); } else if ( (len_w == 1) && (1 == pms_m[0].axe_w) ) { return pms_m[0].som; } else { c3_w cut_w = _molt_cut(len_w, pms_m); if ( u3_no == u3_co_is_cell(som) ) { return u3_cm_bail(c3__exit); } else { return u3_ci_cell (_molt_apply(u3_co_h(som), cut_w, pms_m), _molt_apply(u3_co_t(som), (len_w - cut_w), (pms_m + cut_w))); } } } u3_noun u3_ci_molt(u3_noun som, ...) { va_list ap; c3_w len_w; struct _molt_pair* pms_m; u3_noun pro; /* Count. */ len_w = 0; { va_start(ap, som); while ( 1 ) { if ( 0 == va_arg(ap, c3_w) ) { break; } va_arg(ap, u3_weak*); len_w++; } va_end(ap); } pms_m = alloca(len_w * sizeof(struct _molt_pair)); /* Install. */ { c3_w i_w; va_start(ap, som); for ( i_w = 0; i_w < len_w; i_w++ ) { pms_m[i_w].axe_w = va_arg(ap, c3_w); pms_m[i_w].som = va_arg(ap, u3_noun); } va_end(ap); } /* Apply. */ pro = _molt_apply(som, len_w, pms_m); u3_ca_lose(som); return pro; }