/* * Copyright © 2017 Google, Inc. * Copyright © 2019 Google, Inc. * * This is part of HarfBuzz, a text shaping library. * * Permission is hereby granted, without written agreement and without * license or royalty fees, to use, copy, modify, and distribute this * software and its documentation for any purpose, provided that the * above copyright notice and the following two paragraphs appear in * all copies of this software. * * IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES * ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN * IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH * DAMAGE. * * THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING, * BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND * FITNESS FOR A PARTICULAR PURPOSE. THE SOFTWARE PROVIDED HEREUNDER IS * ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO * PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS. * * Google Author(s): Behdad Esfahbod * Facebook Author(s): Behdad Esfahbod */ #ifndef HB_ALGS_HH #define HB_ALGS_HH #include "hb.hh" #include "hb-meta.hh" #include "hb-null.hh" struct { /* Note. This is dangerous in that if it's passed an rvalue, it returns rvalue-reference. */ template auto operator () (T&& v) const HB_AUTO_RETURN ( hb_forward (v) ) } HB_FUNCOBJ (hb_identity); struct { /* Like identity(), but only retains lvalue-references. Rvalues are returned as rvalues. */ template T& operator () (T& v) const { return v; } template hb_remove_reference operator () (T&& v) const { return v; } } HB_FUNCOBJ (hb_lidentity); struct { /* Like identity(), but always returns rvalue. */ template hb_remove_reference operator () (T&& v) const { return v; } } HB_FUNCOBJ (hb_ridentity); struct { template bool operator () (T&& v) const { return bool (hb_forward (v)); } } HB_FUNCOBJ (hb_bool); struct { private: template auto impl (const T& v, hb_priority<1>) const HB_RETURN (uint32_t, hb_deref (v).hash ()) template auto impl (const T& v, hb_priority<0>) const HB_AUTO_RETURN ( /* Knuth's multiplicative method: */ (uint32_t) v * 2654435761u ) public: template auto operator () (const T& v) const HB_RETURN (uint32_t, impl (v, hb_prioritize)) } HB_FUNCOBJ (hb_hash); struct { private: /* Pointer-to-member-function. */ template auto impl (Appl&& a, hb_priority<2>, T &&v, Ts&&... ds) const HB_AUTO_RETURN ((hb_deref (hb_forward (v)).*hb_forward (a)) (hb_forward (ds)...)) /* Pointer-to-member. */ template auto impl (Appl&& a, hb_priority<1>, T &&v) const HB_AUTO_RETURN ((hb_deref (hb_forward (v))).*hb_forward (a)) /* Operator(). */ template auto impl (Appl&& a, hb_priority<0>, Ts&&... ds) const HB_AUTO_RETURN (hb_deref (hb_forward (a)) (hb_forward (ds)...)) public: template auto operator () (Appl&& a, Ts&&... ds) const HB_AUTO_RETURN ( impl (hb_forward (a), hb_prioritize, hb_forward (ds)...) ) } HB_FUNCOBJ (hb_invoke); struct { private: template auto impl (Pred&& p, Val &&v, hb_priority<1>) const HB_AUTO_RETURN (hb_deref (hb_forward (p)).has (hb_forward (v))) template auto impl (Pred&& p, Val &&v, hb_priority<0>) const HB_AUTO_RETURN ( hb_invoke (hb_forward (p), hb_forward (v)) ) public: template auto operator () (Pred&& p, Val &&v) const HB_RETURN (bool, impl (hb_forward (p), hb_forward (v), hb_prioritize) ) } HB_FUNCOBJ (hb_has); struct { private: template auto impl (Pred&& p, Val &&v, hb_priority<1>) const HB_AUTO_RETURN ( hb_has (hb_forward (p), hb_forward (v)) ) template auto impl (Pred&& p, Val &&v, hb_priority<0>) const HB_AUTO_RETURN ( hb_forward (p) == hb_forward (v) ) public: template auto operator () (Pred&& p, Val &&v) const HB_RETURN (bool, impl (hb_forward (p), hb_forward (v), hb_prioritize) ) } HB_FUNCOBJ (hb_match); struct { private: template auto impl (Proj&& f, Val &&v, hb_priority<2>) const HB_AUTO_RETURN (hb_deref (hb_forward (f)).get (hb_forward (v))) template auto impl (Proj&& f, Val &&v, hb_priority<1>) const HB_AUTO_RETURN ( hb_invoke (hb_forward (f), hb_forward (v)) ) template auto impl (Proj&& f, Val &&v, hb_priority<0>) const HB_AUTO_RETURN ( hb_forward (f)[hb_forward (v)] ) public: template auto operator () (Proj&& f, Val &&v) const HB_AUTO_RETURN ( impl (hb_forward (f), hb_forward (v), hb_prioritize) ) } HB_FUNCOBJ (hb_get); template struct hb_pair_t { typedef T1 first_t; typedef T2 second_t; typedef hb_pair_t pair_t; hb_pair_t (T1 a, T2 b) : first (a), second (b) {} hb_pair_t (const pair_t& o) : first (o.first), second (o.second) {} template operator hb_pair_t () { return hb_pair_t (first, second); } hb_pair_t reverse () const { return hb_pair_t (second, first); } bool operator == (const pair_t& o) const { return first == o.first && second == o.second; } T1 first; T2 second; }; #define hb_pair_t(T1,T2) hb_pair_t template static inline hb_pair_t hb_pair (T1&& a, T2&& b) { return hb_pair_t (a, b); } struct { template auto operator () (const Pair& pair) const HB_AUTO_RETURN (pair.first) } HB_FUNCOBJ (hb_first); struct { template auto operator () (const Pair& pair) const HB_AUTO_RETURN (pair.second) } HB_FUNCOBJ (hb_second); /* Note. In min/max impl, we can use hb_type_identity for second argument. * However, that would silently convert between different-signedness integers. * Instead we accept two different types, such that compiler can err if * comparing integers of different signedness. */ struct { private: template auto impl (T&& a, T2&& b) const HB_AUTO_RETURN (hb_forward (a) <= hb_forward (b) ? hb_forward (a) : hb_forward (b)) public: template auto operator () (T&& a) const HB_AUTO_RETURN (hb_forward (a)) template auto operator () (T&& a, Ts&& ...ds) const HB_AUTO_RETURN (impl (hb_forward (a), (*this) (hb_forward (ds)...))) } HB_FUNCOBJ (hb_min); struct { private: template auto impl (T&& a, T2&& b) const HB_AUTO_RETURN (hb_forward (a) >= hb_forward (b) ? hb_forward (a) : hb_forward (b)) public: template auto operator () (T&& a) const HB_AUTO_RETURN (hb_forward (a)) template auto operator () (T&& a, Ts&& ...ds) const HB_AUTO_RETURN (impl (hb_forward (a), (*this) (hb_forward (ds)...))) } HB_FUNCOBJ (hb_max); /* * Bithacks. */ /* Return the number of 1 bits in v. */ template static inline HB_CONST_FUNC unsigned int hb_popcount (T v) { #if (defined(__GNUC__) && (__GNUC__ >= 4)) || defined(__clang__) if (sizeof (T) <= sizeof (unsigned int)) return __builtin_popcount (v); if (sizeof (T) <= sizeof (unsigned long)) return __builtin_popcountl (v); if (sizeof (T) <= sizeof (unsigned long long)) return __builtin_popcountll (v); #endif if (sizeof (T) <= 4) { /* "HACKMEM 169" */ uint32_t y; y = (v >> 1) &033333333333; y = v - y - ((y >>1) & 033333333333); return (((y + (y >> 3)) & 030707070707) % 077); } if (sizeof (T) == 8) { unsigned int shift = 32; return hb_popcount ((uint32_t) v) + hb_popcount ((uint32_t) (v >> shift)); } if (sizeof (T) == 16) { unsigned int shift = 64; return hb_popcount ((uint64_t) v) + hb_popcount ((uint64_t) (v >> shift)); } assert (0); return 0; /* Shut up stupid compiler. */ } /* Returns the number of bits needed to store number */ template static inline HB_CONST_FUNC unsigned int hb_bit_storage (T v) { if (unlikely (!v)) return 0; #if (defined(__GNUC__) && (__GNUC__ >= 4)) || defined(__clang__) if (sizeof (T) <= sizeof (unsigned int)) return sizeof (unsigned int) * 8 - __builtin_clz (v); if (sizeof (T) <= sizeof (unsigned long)) return sizeof (unsigned long) * 8 - __builtin_clzl (v); if (sizeof (T) <= sizeof (unsigned long long)) return sizeof (unsigned long long) * 8 - __builtin_clzll (v); #endif #if (defined(_MSC_VER) && _MSC_VER >= 1500) || defined(__MINGW32__) if (sizeof (T) <= sizeof (unsigned int)) { unsigned long where; _BitScanReverse (&where, v); return 1 + where; } # if defined(_WIN64) if (sizeof (T) <= 8) { unsigned long where; _BitScanReverse64 (&where, v); return 1 + where; } # endif #endif if (sizeof (T) <= 4) { /* "bithacks" */ const unsigned int b[] = {0x2, 0xC, 0xF0, 0xFF00, 0xFFFF0000}; const unsigned int S[] = {1, 2, 4, 8, 16}; unsigned int r = 0; for (int i = 4; i >= 0; i--) if (v & b[i]) { v >>= S[i]; r |= S[i]; } return r + 1; } if (sizeof (T) <= 8) { /* "bithacks" */ const uint64_t b[] = {0x2ULL, 0xCULL, 0xF0ULL, 0xFF00ULL, 0xFFFF0000ULL, 0xFFFFFFFF00000000ULL}; const unsigned int S[] = {1, 2, 4, 8, 16, 32}; unsigned int r = 0; for (int i = 5; i >= 0; i--) if (v & b[i]) { v >>= S[i]; r |= S[i]; } return r + 1; } if (sizeof (T) == 16) { unsigned int shift = 64; return (v >> shift) ? hb_bit_storage ((uint64_t) (v >> shift)) + shift : hb_bit_storage ((uint64_t) v); } assert (0); return 0; /* Shut up stupid compiler. */ } /* Returns the number of zero bits in the least significant side of v */ template static inline HB_CONST_FUNC unsigned int hb_ctz (T v) { if (unlikely (!v)) return 0; #if (defined(__GNUC__) && (__GNUC__ >= 4)) || defined(__clang__) if (sizeof (T) <= sizeof (unsigned int)) return __builtin_ctz (v); if (sizeof (T) <= sizeof (unsigned long)) return __builtin_ctzl (v); if (sizeof (T) <= sizeof (unsigned long long)) return __builtin_ctzll (v); #endif #if (defined(_MSC_VER) && _MSC_VER >= 1500) || defined(__MINGW32__) if (sizeof (T) <= sizeof (unsigned int)) { unsigned long where; _BitScanForward (&where, v); return where; } # if defined(_WIN64) if (sizeof (T) <= 8) { unsigned long where; _BitScanForward64 (&where, v); return where; } # endif #endif if (sizeof (T) <= 4) { /* "bithacks" */ unsigned int c = 32; v &= - (int32_t) v; if (v) c--; if (v & 0x0000FFFF) c -= 16; if (v & 0x00FF00FF) c -= 8; if (v & 0x0F0F0F0F) c -= 4; if (v & 0x33333333) c -= 2; if (v & 0x55555555) c -= 1; return c; } if (sizeof (T) <= 8) { /* "bithacks" */ unsigned int c = 64; v &= - (int64_t) (v); if (v) c--; if (v & 0x00000000FFFFFFFFULL) c -= 32; if (v & 0x0000FFFF0000FFFFULL) c -= 16; if (v & 0x00FF00FF00FF00FFULL) c -= 8; if (v & 0x0F0F0F0F0F0F0F0FULL) c -= 4; if (v & 0x3333333333333333ULL) c -= 2; if (v & 0x5555555555555555ULL) c -= 1; return c; } if (sizeof (T) == 16) { unsigned int shift = 64; return (uint64_t) v ? hb_bit_storage ((uint64_t) v) : hb_bit_storage ((uint64_t) (v >> shift)) + shift; } assert (0); return 0; /* Shut up stupid compiler. */ } /* * Tiny stuff. */ /* ASCII tag/character handling */ static inline bool ISALPHA (unsigned char c) { return (c >= 'a' && c <= 'z') || (c >= 'A' && c <= 'Z'); } static inline bool ISALNUM (unsigned char c) { return (c >= 'a' && c <= 'z') || (c >= 'A' && c <= 'Z') || (c >= '0' && c <= '9'); } static inline bool ISSPACE (unsigned char c) { return c == ' ' || c =='\f'|| c =='\n'|| c =='\r'|| c =='\t'|| c =='\v'; } static inline unsigned char TOUPPER (unsigned char c) { return (c >= 'a' && c <= 'z') ? c - 'a' + 'A' : c; } static inline unsigned char TOLOWER (unsigned char c) { return (c >= 'A' && c <= 'Z') ? c - 'A' + 'a' : c; } static inline unsigned int DIV_CEIL (const unsigned int a, unsigned int b) { return (a + (b - 1)) / b; } #undef ARRAY_LENGTH template static inline unsigned int ARRAY_LENGTH (const Type (&)[n]) { return n; } /* A const version, but does not detect erratically being called on pointers. */ #define ARRAY_LENGTH_CONST(__array) ((signed int) (sizeof (__array) / sizeof (__array[0]))) static inline int hb_memcmp (const void *a, const void *b, unsigned int len) { /* It's illegal to pass NULL to memcmp(), even if len is zero. * So, wrap it. * https://sourceware.org/bugzilla/show_bug.cgi?id=23878 */ if (!len) return 0; return memcmp (a, b, len); } static inline bool hb_unsigned_mul_overflows (unsigned int count, unsigned int size) { return (size > 0) && (count >= ((unsigned int) -1) / size); } static inline unsigned int hb_ceil_to_4 (unsigned int v) { return ((v - 1) | 3) + 1; } template static inline bool hb_in_range (T u, T lo, T hi) { static_assert (!hb_is_signed::value, ""); /* The casts below are important as if T is smaller than int, * the subtract results will become a signed int! */ return (T)(u - lo) <= (T)(hi - lo); } template static inline bool hb_in_ranges (T u, T lo1, T hi1, T lo2, T hi2) { return hb_in_range (u, lo1, hi1) || hb_in_range (u, lo2, hi2); } template static inline bool hb_in_ranges (T u, T lo1, T hi1, T lo2, T hi2, T lo3, T hi3) { return hb_in_range (u, lo1, hi1) || hb_in_range (u, lo2, hi2) || hb_in_range (u, lo3, hi3); } /* * Sort and search. */ static inline void * hb_bsearch (const void *key, const void *base, size_t nmemb, size_t size, int (*compar)(const void *_key, const void *_item)) { int min = 0, max = (int) nmemb - 1; while (min <= max) { int mid = (min + max) / 2; const void *p = (const void *) (((const char *) base) + (mid * size)); int c = compar (key, p); if (c < 0) max = mid - 1; else if (c > 0) min = mid + 1; else return (void *) p; } return nullptr; } static inline void * hb_bsearch_r (const void *key, const void *base, size_t nmemb, size_t size, int (*compar)(const void *_key, const void *_item, void *_arg), void *arg) { int min = 0, max = (int) nmemb - 1; while (min <= max) { int mid = ((unsigned int) min + (unsigned int) max) / 2; const void *p = (const void *) (((const char *) base) + (mid * size)); int c = compar (key, p, arg); if (c < 0) max = mid - 1; else if (c > 0) min = mid + 1; else return (void *) p; } return nullptr; } /* From https://github.com/noporpoise/sort_r * With following modifications: * * 10 November 2018: * https://github.com/noporpoise/sort_r/issues/7 */ /* Isaac Turner 29 April 2014 Public Domain */ /* hb_sort_r function to be exported. Parameters: base is the array to be sorted nel is the number of elements in the array width is the size in bytes of each element of the array compar is the comparison function arg is a pointer to be passed to the comparison function void hb_sort_r(void *base, size_t nel, size_t width, int (*compar)(const void *_a, const void *_b, void *_arg), void *arg); */ /* swap a, b iff a>b */ /* __restrict is same as restrict but better support on old machines */ static int sort_r_cmpswap(char *__restrict a, char *__restrict b, size_t w, int (*compar)(const void *_a, const void *_b, void *_arg), void *arg) { char tmp, *end = a+w; if(compar(a, b, arg) > 0) { for(; a < end; a++, b++) { tmp = *a; *a = *b; *b = tmp; } return 1; } return 0; } /* Note: quicksort is not stable, equivalent values may be swapped */ static inline void sort_r_simple(void *base, size_t nel, size_t w, int (*compar)(const void *_a, const void *_b, void *_arg), void *arg) { char *b = (char *)base, *end = b + nel*w; if(nel < 7) { /* Insertion sort for arbitrarily small inputs */ char *pi, *pj; for(pi = b+w; pi < end; pi += w) { for(pj = pi; pj > b && sort_r_cmpswap(pj-w,pj,w,compar,arg); pj -= w) {} } } else { /* nel > 6; Quicksort */ /* Use median of first, middle and last items as pivot */ char *x, *y, *xend, ch; char *pl, *pm, *pr; char *last = b+w*(nel-1), *tmp; char *l[3]; l[0] = b; l[1] = b+w*(nel/2); l[2] = last; if(compar(l[0],l[1],arg) > 0) { tmp=l[0]; l[0]=l[1]; l[1]=tmp; } if(compar(l[1],l[2],arg) > 0) { tmp=l[1]; l[1]=l[2]; l[2]=tmp; /* swap(l[1],l[2]) */ if(compar(l[0],l[1],arg) > 0) { tmp=l[0]; l[0]=l[1]; l[1]=tmp; } } /* swap l[id], l[2] to put pivot as last element */ for(x = l[1], y = last, xend = x+w; x>1); for(; pl < pm; pl += w) { if(sort_r_cmpswap(pl, pr, w, compar, arg)) { pr -= w; /* pivot now at pl */ break; } } pm = pl+((pr-pl)>>1); for(; pm < pr; pr -= w) { if(sort_r_cmpswap(pl, pr, w, compar, arg)) { pl += w; /* pivot now at pr */ break; } } } sort_r_simple(b, (pl-b)/w, w, compar, arg); sort_r_simple(pl+w, (end-(pl+w))/w, w, compar, arg); } } static inline void hb_sort_r (void *base, size_t nel, size_t width, int (*compar)(const void *_a, const void *_b, void *_arg), void *arg) { sort_r_simple(base, nel, width, compar, arg); } template static inline void hb_stable_sort (T *array, unsigned int len, int(*compar)(const T2 *, const T2 *), T3 *array2) { for (unsigned int i = 1; i < len; i++) { unsigned int j = i; while (j && compar (&array[j - 1], &array[i]) > 0) j--; if (i == j) continue; /* Move item i to occupy place for item j, shift what's in between. */ { T t = array[i]; memmove (&array[j + 1], &array[j], (i - j) * sizeof (T)); array[j] = t; } if (array2) { T3 t = array2[i]; memmove (&array2[j + 1], &array2[j], (i - j) * sizeof (T3)); array2[j] = t; } } } template static inline void hb_stable_sort (T *array, unsigned int len, int(*compar)(const T *, const T *)) { hb_stable_sort (array, len, compar, (int *) nullptr); } static inline hb_bool_t hb_codepoint_parse (const char *s, unsigned int len, int base, hb_codepoint_t *out) { /* Pain because we don't know whether s is nul-terminated. */ char buf[64]; len = hb_min (ARRAY_LENGTH (buf) - 1, len); strncpy (buf, s, len); buf[len] = '\0'; char *end; errno = 0; unsigned long v = strtoul (buf, &end, base); if (errno) return false; if (*end) return false; *out = v; return true; } struct HbOpOr { static constexpr bool passthru_left = true; static constexpr bool passthru_right = true; template static void process (T &o, const T &a, const T &b) { o = a | b; } }; struct HbOpAnd { static constexpr bool passthru_left = false; static constexpr bool passthru_right = false; template static void process (T &o, const T &a, const T &b) { o = a & b; } }; struct HbOpMinus { static constexpr bool passthru_left = true; static constexpr bool passthru_right = false; template static void process (T &o, const T &a, const T &b) { o = a & ~b; } }; struct HbOpXor { static constexpr bool passthru_left = true; static constexpr bool passthru_right = true; template static void process (T &o, const T &a, const T &b) { o = a ^ b; } }; /* Compiler-assisted vectorization. */ /* Type behaving similar to vectorized vars defined using __attribute__((vector_size(...))), * using vectorized operations if HB_VECTOR_SIZE is set to **bit** numbers (eg 128). * Define that to 0 to disable. */ template struct hb_vector_size_t { elt_t& operator [] (unsigned int i) { return u.v[i]; } const elt_t& operator [] (unsigned int i) const { return u.v[i]; } void clear (unsigned char v = 0) { memset (this, v, sizeof (*this)); } template hb_vector_size_t process (const hb_vector_size_t &o) const { hb_vector_size_t r; #if HB_VECTOR_SIZE if (HB_VECTOR_SIZE && 0 == (byte_size * 8) % HB_VECTOR_SIZE) for (unsigned int i = 0; i < ARRAY_LENGTH (u.vec); i++) Op::process (r.u.vec[i], u.vec[i], o.u.vec[i]); else #endif for (unsigned int i = 0; i < ARRAY_LENGTH (u.v); i++) Op::process (r.u.v[i], u.v[i], o.u.v[i]); return r; } hb_vector_size_t operator | (const hb_vector_size_t &o) const { return process (o); } hb_vector_size_t operator & (const hb_vector_size_t &o) const { return process (o); } hb_vector_size_t operator ^ (const hb_vector_size_t &o) const { return process (o); } hb_vector_size_t operator ~ () const { hb_vector_size_t r; #if HB_VECTOR_SIZE && 0 if (HB_VECTOR_SIZE && 0 == (byte_size * 8) % HB_VECTOR_SIZE) for (unsigned int i = 0; i < ARRAY_LENGTH (u.vec); i++) r.u.vec[i] = ~u.vec[i]; else #endif for (unsigned int i = 0; i < ARRAY_LENGTH (u.v); i++) r.u.v[i] = ~u.v[i]; return r; } private: static_assert (byte_size / sizeof (elt_t) * sizeof (elt_t) == byte_size, ""); union { elt_t v[byte_size / sizeof (elt_t)]; #if HB_VECTOR_SIZE hb_vector_size_impl_t vec[byte_size / sizeof (hb_vector_size_impl_t)]; #endif } u; }; #endif /* HB_ALGS_HH */