// Copyright (c) 2013 // INRIA Saclay - Ile de France (France). // All rights reserved. // // This file is part of CGAL (www.cgal.org); you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public License as // published by the Free Software Foundation; either version 3 of the License, // or (at your option) any later version. // // Licensees holding a valid commercial license may use this file in // accordance with the commercial license agreement provided with the software. // // This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE // WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. // // $URL$ // $Id$ // SPDX-License-Identifier: LGPL-3.0+ // // Author(s) : Marc Glisse #ifndef CGAL_MPZF_H #define CGAL_MPZF_H #include #include #include #include #include #include #include #include #ifdef CGAL_USE_GMPXX # include #else # include #endif #include #include #include #include //#include #include // The following is currently assumed in several places. I hope I am not // making too many other assumptions. // * limbs are 64 bits // * if using gcc, sizeof(long long)==8 // * mpn_neg(_n) exists // * IEEE double // * not too fancy endianness #if !defined(CGAL_DO_NOT_USE_MPZF) \ && __GNU_MP_VERSION * 10 + __GNU_MP_VERSION_MINOR >= 43 \ && GMP_NUMB_BITS == 64 #define CGAL_HAS_MPZF 1 // GMP-4.3.* has a different name for mpn_neg. #ifndef mpn_neg #define mpn_neg mpn_neg_n #endif // GMP-4.3.0 is missing mpn_sqr. #ifndef mpn_sqr #define mpn_sqr(dest,a,n) mpn_mul_n(dest,a,a,n) #endif // GMP before 5.0 doesn't provide mpn_copyi. #ifndef mpn_copyi #define mpn_copyi(dst, src, siz) std::copy((src), (src)+(siz), (dst)) #endif #include #ifdef _MSC_VER #include #pragma intrinsic(_BitScanForward64) #pragma intrinsic(_BitScanReverse64) #endif #ifdef __xlC__ #include #endif #include #include #include #include #if defined(BOOST_MSVC) # pragma warning(push) # pragma warning(disable:4146 4244 4267 4800) // warning on - applied on unsigned number // conversion with loss of data // conversion with loss of data // int to bool performance #endif /* #ifdef CGAL_MPZF_NO_USE_CACHE # ifdef CGAL_MPZF_USE_CACHE # undef CGAL_MPZF_USE_CACHE # endif #else # if !defined(CGAL_MPZF_USE_CACHE) \ && defined(CGAL_HAS_THREADS) \ && !defined(CGAL_I_PROMISE_I_WONT_USE_MANY_THREADS) # define CGAL_MPZF_USE_CACHE 1 # endif #endif */ #define CGAL_MPZF_USE_CACHE 1 // On a dataset provided by Andreas, replacing Gmpq with this type in // Epick reduced the running time of the construction of a Delaunay // triangulation by a factor larger than 6 #if !defined(CGAL_HAS_THREADS) #define CGAL_MPZF_THREAD_LOCAL #define CGAL_MPZF_TLS #elif defined(CGAL_CAN_USE_CXX11_THREAD_LOCAL) #define CGAL_MPZF_THREAD_LOCAL thread_local #define CGAL_MPZF_TLS thread_local #elif defined(_MSC_VER) #define CGAL_MPZF_THREAD_LOCAL __declspec(thread) #define CGAL_MPZF_TLS #else #define CGAL_MPZF_THREAD_LOCAL __thread #define CGAL_MPZF_TLS // Too bad for the others #endif namespace CGAL { namespace Mpzf_impl { // Warning: these pools aren't generic at all! // Not thread-safe template struct pool1 { static T pop() { T ret = data.back(); data.pop_back(); return ret; } static void push(T t) { data.push_back(t); } static bool empty() { return data.empty(); } static const int extra = 0; private: // thread_local would be fine, but not __declspec(thread) and for most // compilers not __thread, since data is not POD. static std::vector data; }; template std::vector pool1::data; // Use an intrusive single-linked list instead (allocate one more limb and use // it to store the pointer to next), the difference isn't that noticable (still // the list wins). Neither is thread-safe (both can be with threadlocal, and // the list can be with an atomic compare-exchange (never tried)). With gcc, // TLS has a large effect on classes with constructor/destructor, but is free // for a simple pointer. The slowdown is because of PR55812. // Leaks at thread destruction template struct pool2 { static T pop() { T ret = data(); data() = ptr(data()); return ret; } static void push(T t) { ptr(t) = data(); data() = t; } static bool empty() { return data() == 0; } static const int extra = 1; // TODO: handle the case where a pointer is larger than a mp_limb_t private: CGAL_static_assertion(sizeof(T) >= sizeof(T*)); static T& data () { static CGAL_MPZF_TLS T data_ = 0; return data_; } static T& ptr(T t) { t -= extra+1; return *reinterpret_cast(t); } }; #if defined(CGAL_CAN_USE_CXX11_THREAD_LOCAL) template struct pool3 { static T pop() { T ret = data(); data() = ptr(data()); return ret; } static void push(T t) { ptr(t) = data(); data() = t; } static bool empty() { return data() == 0; } static const int extra = 1; // TODO: handle the case where a pointer is larger than a mp_limb_t private: CGAL_static_assertion(sizeof(T) >= sizeof(T*)); struct cleaner { T data_ = 0; ~cleaner(){ // Deallocate everything. As an alternative, we could store it in a // global location, for re-use by a later thread. while (!empty()) delete[] (pop() - (extra + 1)); } }; static T& data () { static thread_local cleaner obj; return obj.data_; } static T& ptr(T t) { t -= extra+1; return *reinterpret_cast(t); } }; #endif // No caching template struct no_pool { static T pop() { throw "Shouldn't be here!"; } static void push(T t) { delete [] (t - (extra+1)); } static bool empty() { return true; } static const int extra = 0; }; // Only used with an argument known not to be 0. inline int ctz (boost::uint64_t x) { #if defined(_MSC_VER) unsigned long ret; _BitScanForward64(&ret, x); return (int)ret; #elif defined(__xlC__) return __cnttz8 (x); #else // Assume long long is 64 bits return __builtin_ctzll (x); #endif } inline int clz (boost::uint64_t x) { #if defined(_MSC_VER) unsigned long ret; _BitScanReverse64(&ret, x); return 63 - (int)ret; #elif defined(__xlC__) // Macro supposedly not defined on z/OS. return __cntlz8 (x); #else return __builtin_clzll (x); #endif } // In C++11, std::fill_n returns a pointer to the end, but in C++03, // it returns void. inline mp_limb_t* fill_n_ptr(mp_limb_t* p, int n, int c) { #if CGAL_CXX11 return std::fill_n (p, n, c); #else mp_limb_t* q = p + n; std::fill (p, q, c); //std::fill_n (p, n, c); //memset (p, sizeof(mp_limb_t)*n, c); return q; #endif } } // namespace Mpzf_impl #undef CGAL_MPZF_THREAD_LOCAL #undef CGAL_MPZF_TLS // TODO: // * make data==0 a valid state for number 0. Incompatible with the cache. I // tried, and it doesn't seem to help (may even hurt a bit). struct Mpzf { private: #ifdef CGAL_MPZF_USE_CACHE // More experiments to determine the best value would be good. It likely // depends on the usage. Note that pool2 is fast enough that a conditional // cache slows it down. A purely static cache (crash if it isn't large // enough) still wins by about 11% on the Delaunay_3 construction, but is // more complicated to handle. // Evaluating a polynomial in double will never require more than roughly // (2100*degree) bits, or (33*degree) mp_limb_t, which is very small. I // checked by including an array of 150 limbs in every Mpzf (that's where // the 11% number comes from). // BONUS: doing that is thread-safe! static const unsigned int cache_size = 8; #endif //#if !defined(CGAL_HAS_THREADS) || defined(CGAL_I_PROMISE_I_WONT_USE_MANY_THREADS) // typedef Mpzf_impl::pool2 pool; //#elif defined(CGAL_CAN_USE_CXX11_THREAD_LOCAL) // typedef Mpzf_impl::pool3 pool; //#else typedef Mpzf_impl::no_pool pool; //#endif mp_limb_t* data_; /* data_[0] is never 0 (except possibly for 0). */ inline mp_limb_t*& data() { return data_; } inline mp_limb_t const* data() const { return data_; } #ifdef CGAL_MPZF_USE_CACHE mp_limb_t cache[cache_size + 1]; #endif int size; /* Number of relevant limbs in data_. */ int exp; /* The number is data_ (an integer) * 2 ^ (64 * exp). */ typedef int Exponent_type; typedef int Size_type; struct allocate{}; struct noalloc{}; void init(unsigned mini=2){ #ifdef CGAL_MPZF_USE_CACHE if (mini <= cache_size) { cache[0] = cache_size; data() = cache + 1; return; } #endif if(!pool::empty()){ data() = pool::pop(); if(data()[-1] >= mini) return; // TODO: when mini==2, no need to check delete[] (data() - (pool::extra+1)); // too small, useless } if(mini<2) mini=2; data() = (new mp_limb_t[mini+(pool::extra+1)]) + (pool::extra+1); data()[-1] = mini; } void clear(){ while(*--data()==0); // in case we skipped final zeroes #ifdef CGAL_MPZF_USE_CACHE if (data() == cache) return; #endif ++data(); pool::push(data()); } Mpzf(noalloc){} Mpzf(allocate,int i) { init(i); } public: static void clear_pool () { while (!pool::empty()) delete[] (pool::pop() - (pool::extra + 1)); } ~Mpzf(){ clear(); } Mpzf(): size(0), exp(0) { init(); } Mpzf& operator=(Mpzf const& x){ unsigned asize=std::abs(x.size); if(asize==0) { exp=0; size=0; return *this; } if(this==&x) return *this; while(*--data()==0); // factor that code somewhere? if(*data() 0) { size = 1; data()[0] = i; } else /* (i < 0) */ { size =-1; data()[0] = -(mp_limb_t)i; } // cast to mp_limb_t because -INT_MIN is undefined } Mpzf(unsigned int i) : exp(0) { // assume that int is smaller than mp_limb_t init(); if (i == 0) { size = 0; } else /* (i > 0) */ { size = 1; data()[0] = i; } } Mpzf(long i) : exp(0) { // assume that long is smaller than mp_limb_t init(); if (i == 0) { size = 0; } else if (i > 0) { size = 1; data()[0] = i; } else /* (i < 0) */ { size =-1; data()[0] = -(mp_limb_t)i; } // cast to mp_limb_t because -LONG_MIN is undefined } Mpzf(unsigned long i) : exp(0) { // assume that long is smaller than mp_limb_t init(); if (i == 0) { size = 0; } else /* (i > 0) */ { size = 1; data()[0] = i; } } Mpzf(double d){ init(); using boost::uint64_t; union { #ifdef CGAL_LITTLE_ENDIAN struct { uint64_t man:52; uint64_t exp:11; uint64_t sig:1; } s; #else /* CGAL_BIG_ENDIAN */ //WARNING: untested! struct { uint64_t sig:1; uint64_t exp:11; uint64_t man:52; } s; #endif double d; } u; u.d = d; uint64_t m; uint64_t dexp = u.s.exp; CGAL_assertion_msg(dexp != 2047, "Creating an Mpzf from infinity or NaN."); if (dexp == 0) { if (d == 0) { size=0; exp=0; return; } else { // denormal number m = u.s.man; ++dexp; } } else { m = (1LL<<52) | u.s.man; } int e1 = (int)dexp+13; // FIXME: make it more general! But not slower... CGAL_static_assertion(GMP_NUMB_BITS == 64); int e2 = e1 % 64; exp = e1 / 64 - 17; // 52+1023+13==17*64 ? #if 0 // This seems very slightly faster if(Mpzf_impl::ctz(m)+e2>=64){ data()[0] = m >> (64-e2); size = 1; ++exp; }else{ data()[0] = m << e2; if(e2>11){ // Wrong test for denormals data()[1] = m >> (64-e2); size = 2; } else { size = 1; } } #else mp_limb_t d0 = (m << e2) & GMP_NUMB_MASK; mp_limb_t d1 = 0; if (e2 != 0) // shifting by 64 is UB d1 = m >> (GMP_NUMB_BITS - e2); if (d0 == 0) { data()[0] = d1; size = 1; ++exp; } else { data()[0] = d0; if (d1 == 0) { size = 1; } else { data()[1] = d1; size = 2; } } #endif if(u.s.sig) size=-size; //CGAL_assertion(to_double()==IA_force_to_double(d)); } #ifdef CGAL_USE_GMPXX Mpzf(mpz_class const&z){ init_from_mpz_t(z.get_mpz_t()); } #endif Mpzf(Gmpz const&z){ init_from_mpz_t(z.mpz()); } void init_from_mpz_t(mpz_t const z){ exp=Exponent_type(mpz_scan1(z,0)/GMP_NUMB_BITS); size=Size_type(mpz_size(z)-exp); init(size); mpn_copyi(data(),z->_mp_d+exp,size); } #if 0 // For debug purposes only void print()const{ //std::cout << "size: " << size << std::endl; if(size==0) { std::cout << "zero\n"; return; } if(size<0) std::cout << "- "; int asize = std::abs(size); std::cout << std::hex; while(--asize>=0) { std::cout << data()[asize] << ' '; } std::cout << std::dec << "exp " << exp << ' '; std::cout << std::dec << "size " << size << ' '; asize = std::abs(size); std::cout << "double: " << std::ldexp((double)data()[asize-1],64*(exp+asize-1))*((size<0)?-1:1) << '\n'; } #endif friend int Mpzf_abscmp(Mpzf const&a, Mpzf const&b){ int asize=std::abs(a.size); int bsize=std::abs(b.size); // size==0 should mean exp==-infinity, like with double. // Since it doesn't, test for it explicitly. if (bsize == 0) return asize; if (asize == 0) return -1; int ah=asize+a.exp; int bh=bsize+b.exp; if(ah!=bh) return ah-bh; int minsize=(std::min)(asize,bsize); const mp_limb_t* adata=a.data()+(asize-1); const mp_limb_t* bdata=b.data()+(bsize-1); for(int i=0;i(Mpzf const&a, Mpzf const&b){ return b=(Mpzf const&a, Mpzf const&b){ return !(ab); } friend bool operator==(Mpzf const&a, Mpzf const&b){ if (a.exp != b.exp || a.size != b.size) return false; if (a.size == 0) return true; return mpn_cmp(a.data(), b.data(), std::abs(a.size)) == 0; } friend bool operator!=(Mpzf const&a, Mpzf const&b){ return !(a==b); } private: static Mpzf aors(Mpzf const&a, Mpzf const&b, int bsize){ Mpzf res=noalloc(); if(bsize==0){ int size=std::abs(a.size); res.init(size); res.exp=a.exp; res.size=a.size; if(size!=0) mpn_copyi(res.data(),a.data(),size); return res; } int asize=a.size; if(asize==0){ int size=std::abs(bsize); res.init(size); res.exp=b.exp; res.size=bsize; mpn_copyi(res.data(),b.data(),size); return res; } if((asize^bsize)>=0){ // Addition int absasize=std::abs(asize); int absbsize=std::abs(bsize); const mp_limb_t* adata=a.data(); const mp_limb_t* bdata=b.data(); int aexp=a.exp; int bexp=b.exp; if(aexp0, swap a and b so we don't repeat the code. if(0=absbsize){ mp_limb_t carry=mpn_add(rdata,adata,absasize,bdata,absbsize); res.size+=absasize; if(carry!=0){ res.size++; rdata[absasize]=carry; } } else { mp_limb_t carry=mpn_add(rdata,bdata,absbsize,adata,absasize); res.size+=absbsize; if(carry!=0){ res.size++; rdata[absbsize]=carry; } } // unnecessary if a.exp != b.exp while(/*res.size>0&&*/res.data()[0]==0){--res.size;++res.data();++res.exp;} if(bsize<0) res.size=-res.size; } else { // Subtraction const Mpzf *x, *y; int xsize=a.size; int ysize=bsize; int cmp=Mpzf_abscmp(a,b); if(cmp==0){ res.init(); res.size=0; res.exp=0; return res; } if(cmp<0) { x=&b; y=&a; std::swap(xsize, ysize); } else { x=&a; y=&b; } int absxsize=std::abs(xsize); int absysize=std::abs(ysize); const mp_limb_t* xdata=x->data(); const mp_limb_t* ydata=y->data(); int xexp=x->exp; int yexp=y->exp; if(xexp0&&*/res.data()[res.size-1]==0) --res.size; while(/*res.size>0&&*/res.data()[0]==0){--res.size;++res.data();++res.exp;} if(xsize<0) res.size=-res.size; } return res; } public: friend Mpzf operator+(Mpzf const&a, Mpzf const&b){ return aors(a,b,b.size); } friend Mpzf operator-(Mpzf const&a, Mpzf const&b){ return aors(a,b,-b.size); } friend Mpzf operator*(Mpzf const&a, Mpzf const&b){ int asize=std::abs(a.size); int bsize=std::abs(b.size); int siz=asize+bsize; Mpzf res(allocate(),siz); if(asize==0||bsize==0){res.exp=0;res.size=0;return res;} res.exp=a.exp+b.exp; mp_limb_t high; if(asize>=bsize) high = mpn_mul(res.data(),a.data(),asize,b.data(),bsize); else high = mpn_mul(res.data(),b.data(),bsize,a.data(),asize); if(high==0) --siz; if(res.data()[0]==0) { ++res.data(); ++res.exp; --siz; } res.size=((a.size^b.size)>=0)?siz:-siz; return res; } friend Mpzf Mpzf_square(Mpzf const&a){ int asize=std::abs(a.size); int siz=2*asize; Mpzf res(allocate(),siz); res.exp=2*a.exp; if(asize==0){res.size=0;return res;} mpn_sqr(res.data(),a.data(),asize); mp_limb_t high = res.data()[siz-1]; if(high==0) --siz; if(res.data()[0]==0) { ++res.data(); ++res.exp; --siz; } res.size=siz; return res; } friend Mpzf operator/(Mpzf const&a, Mpzf const&b){ // FIXME: Untested int asize=std::abs(a.size); int bsize=std::abs(b.size); int siz=asize+2-bsize; Mpzf res(allocate(),asize+2); if(bsize==0){throw std::range_error("Division by zero");} if(asize==0){res.exp=0;res.size=0;return res;} res.size=siz; res.exp=a.exp-b.exp; const mp_limb_t *adata = a.data(); const mp_limb_t *bdata = b.data(); mp_limb_t *qp = res.data(); mp_limb_t *rp = qp + siz; if(Mpzf_impl::ctz(adata[0]) >= Mpzf_impl::ctz(bdata[0])){ // Easy case --res.size; mpn_tdiv_qr(qp, rp, 0, adata, asize, bdata, bsize); CGAL_assertion_code( for (int i=0; i0&&*/res.data()[res.size-1]==0) --res.size; //while(/*res.size>0&&*/res.data()[0]==0){--res.size;++res.data();++res.exp;} if((a.size^b.size)<0) res.size=-res.size; return res; } friend Mpzf Mpzf_gcd(Mpzf const&a, Mpzf const&b){ // FIXME: Untested if (a.size == 0) return b; if (b.size == 0) return a; int asize=std::abs(a.size); int bsize=std::abs(b.size); int atz=Mpzf_impl::ctz(a.data()[0]); int btz=Mpzf_impl::ctz(b.data()[0]); int rtz=(std::min)(atz,btz); Mpzf tmp(allocate(), asize); Mpzf res(allocate(), bsize); if (atz != 0) { mpn_rshift(tmp.data(), a.data(), asize, atz); if(tmp.data()[asize-1]==0) --asize; } else { mpn_copyi(tmp.data(), a.data(), asize); } if (btz != 0) { mpn_rshift(res.data(), b.data(), bsize, btz); if(res.data()[bsize-1]==0) --bsize; } else { mpn_copyi(res.data(), b.data(), bsize); } res.exp = 0; // Pick b.exp? or the average? 0 helps return 1 more often. if (asize < bsize) res.size = Size_type(mpn_gcd(res.data(), res.data(), bsize, tmp.data(), asize)); else res.size = Size_type(mpn_gcd(res.data(), tmp.data(), asize, res.data(), bsize)); if(rtz!=0) { mp_limb_t c = mpn_lshift(res.data(), res.data(), res.size, rtz); if(c) { res.data()[res.size]=c; ++res.size; } } return res; } friend bool Mpzf_is_square(Mpzf const&x){ if (x.size < 0) return false; if (x.size == 0) return true; // Assume that GMP_NUMB_BITS is even. return mpn_perfect_square_p (x.data(), x.size); } friend Mpzf Mpzf_sqrt(Mpzf const&x){ // FIXME: Untested if (x.size < 0) throw std::range_error("Sqrt of negative number"); if (x.size == 0) return 0; if (x.exp % 2 == 0) { Mpzf res(allocate(), (x.size + 1) / 2); res.exp = x.exp / 2; res.size = (x.size + 1) / 2; CGAL_assertion_code(mp_size_t rem=) mpn_sqrtrem(res.data(), 0, x.data(), x.size); CGAL_assertion(rem==0); return res; } else if (x.data()[-1] == 0) { Mpzf res(allocate(), (x.size + 2) / 2); res.exp = (x.exp - 1) / 2; res.size = (x.size + 2) / 2; CGAL_assertion_code(mp_size_t rem=) mpn_sqrtrem(res.data(), 0, x.data()-1, x.size+1); CGAL_assertion(rem==0); return res; } else { Mpzf res(allocate(), (x.size + 2) / 2); res.exp = (x.exp - 1) / 2; res.size = (x.size + 2) / 2; CGAL_assertion_code(mp_size_t rem=) mpn_sqrtrem(res.data(), 0, x.data(), x.size); CGAL_assertion(rem==0); mpn_lshift(res.data(), res.data(), res.size, GMP_NUMB_BITS / 2); return res; } } friend Mpzf operator-(Mpzf const&x){ Mpzf ret = x; ret.size = -ret.size; return ret; } Mpzf& operator+=(Mpzf const&x){ *this=*this+x; return *this; } Mpzf& operator-=(Mpzf const&x){ *this=*this-x; return *this; } Mpzf& operator*=(Mpzf const&x){ *this=*this*x; return *this; } Mpzf& operator/=(Mpzf const&x){ *this=*this/x; return *this; } bool is_canonical () const { if (size == 0) return true; if (data()[0] == 0) return false; if (data()[std::abs(size)-1] == 0) return false; return true; } bool is_zero () const { return size==0; } bool is_one () const { return exp==0 && size==1 && data()[0]==1; } CGAL::Sign sign () const { return CGAL::sign(size); } double to_double () const { // Assumes GMP_NUMB_BITS == 64 using std::ldexp; if(size==0) return 0; int asize = std::abs(size); mp_limb_t top = data()[asize-1]; double dtop = (double)top; if(top >= (1LL<<53) || asize == 1) /* ok */ ; else { dtop += (double)data()[asize-2] * ldexp(1.,-GMP_NUMB_BITS); } return ldexp( (size<0) ? -dtop : dtop, (asize-1+exp) * GMP_NUMB_BITS); } std::pair to_interval () const { // Assumes GMP_NUMB_BITS == 64 if (size == 0) return std::make_pair(0., 0.); double dl, dh; int asize = std::abs(size); int e = 64 * (asize - 1 + exp); mp_limb_t x = data()[asize-1]; int lz = Mpzf_impl::clz(x); if (lz <= 11) { if (lz != 11) { e += (11 - lz); x >>= (11 - lz); } dl = double(x); dh = double(x + 1); // Check for the few cases where dh=x works (asize==1 and the evicted // bits from x were 0s) } else if (asize == 1) { dl = dh = double(x); // conversion is exact } else { mp_limb_t y = data()[asize-2]; e -= (lz - 11); x <<= (lz - 11); y >>= (75 - lz); x |= y; dl = double(x); dh = double(x + 1); // Check for the few cases where dh=x works (asize==2 and the evicted // bits from y were 0s) } typedef Interval_nt<> IA; IA res (dl, dh); res = ldexp (res, e); if (size < 0) res = -res; return CGAL::to_interval(res); // Use ldexp(Interval_nt,int) to delegate the hard thinking // about over/underflow. } #ifdef CGAL_USE_GMPXX #ifndef CGAL_CFG_NO_CPP0X_EXPLICIT_CONVERSION_OPERATORS explicit #endif operator mpq_class () const { mpq_class q; export_to_mpq_t(q.get_mpq_t()); return q; } #endif #ifndef CGAL_CFG_NO_CPP0X_EXPLICIT_CONVERSION_OPERATORS explicit #endif operator Gmpq () const { Gmpq q; export_to_mpq_t(q.mpq()); return q; } void export_to_mpq_t(mpq_t q) const { /* q must be 0/1 before this call */ CGAL_precondition(mpq_cmp_ui(q,0,1)==0); if (size != 0) { mpz_import (mpq_numref (q), std::abs(size), -1, // data()[0] is the least significant part sizeof(mp_limb_t), 0, // native endianness inside mp_limb_t GMP_NAIL_BITS, // should be 0 data()); if (exp > 0) mpq_mul_2exp(q, q, (sizeof(mp_limb_t) * CHAR_BIT * exp)); else if (exp < 0) mpq_div_2exp(q, q, (sizeof(mp_limb_t) * CHAR_BIT * -exp)); if (size < 0) mpq_neg(q,q); } } #if 0 #ifndef CGAL_CFG_NO_CPP0X_EXPLICIT_CONVERSION_OPERATORS explicit #endif // This makes Mpzf==int ambiguous operator Gmpzf () const { mpz_t z; z->_mp_d=const_cast(data()); z->_mp_size=size; Gmpzf m(z); // Only works for a very limited range of exponents Gmpzf e(std::ldexp(1.,GMP_NUMB_BITS*exp)); return m*e; } #endif friend void simplify_quotient(Mpzf& a, Mpzf& b){ // Avoid quotient(2^huge_a/2^huge_b) a.exp -= b.exp; b.exp = 0; // Simplify with gcd? } }; // Copied from Gmpzf, not sure that's the best thing to do. inline std::ostream& operator<< (std::ostream& os, const Mpzf& a) { return os << a.to_double(); } inline std::istream& operator>> (std::istream& is, Mpzf& a) { double d; is >> d; if (is) a = d; return is; } template <> struct Algebraic_structure_traits< Mpzf > : public Algebraic_structure_traits_base< Mpzf, Integral_domain_without_division_tag > { typedef Tag_true Is_exact; typedef Tag_false Is_numerical_sensitive; struct Is_zero : public CGAL::cpp98::unary_function< Type, bool > { bool operator()( const Type& x ) const { return x.is_zero(); } }; struct Is_one : public CGAL::cpp98::unary_function< Type, bool > { bool operator()( const Type& x ) const { return x.is_one(); } }; struct Gcd : public CGAL::cpp98::binary_function< Type, Type, Type > { Type operator()( const Type& x, const Type& y ) const { return Mpzf_gcd(x, y); } }; struct Square : public CGAL::cpp98::unary_function< Type, Type > { Type operator()( const Type& x ) const { return Mpzf_square(x); } }; struct Integral_division : public CGAL::cpp98::binary_function< Type, Type, Type > { Type operator()( const Type& x, const Type& y ) const { return x / y; } }; struct Sqrt : public CGAL::cpp98::unary_function< Type, Type > { Type operator()( const Type& x) const { return Mpzf_sqrt(x); } }; struct Is_square : public CGAL::cpp98::binary_function< Type, Type&, bool > { bool operator()( const Type& x, Type& y ) const { // TODO: avoid doing 2 calls. if (!Mpzf_is_square(x)) return false; y = Mpzf_sqrt(x); return true; } bool operator()( const Type& x) const { return Mpzf_is_square(x); } }; }; template <> struct Real_embeddable_traits< Mpzf > : public INTERN_RET::Real_embeddable_traits_base< Mpzf , CGAL::Tag_true > { struct Sgn : public CGAL::cpp98::unary_function< Type, ::CGAL::Sign > { ::CGAL::Sign operator()( const Type& x ) const { return x.sign(); } }; struct To_double : public CGAL::cpp98::unary_function< Type, double > { double operator()( const Type& x ) const { return x.to_double(); } }; struct Compare : public CGAL::cpp98::binary_function< Type, Type, Comparison_result > { Comparison_result operator()( const Type& x, const Type& y ) const { return CGAL::sign(Mpzf_cmp(x,y)); } }; struct To_interval : public CGAL::cpp98::unary_function< Type, std::pair< double, double > > { std::pair operator()( const Type& x ) const { return x.to_interval(); } }; }; CGAL_DEFINE_COERCION_TRAITS_FOR_SELF(Mpzf) CGAL_DEFINE_COERCION_TRAITS_FROM_TO(short ,Mpzf) CGAL_DEFINE_COERCION_TRAITS_FROM_TO(int ,Mpzf) CGAL_DEFINE_COERCION_TRAITS_FROM_TO(long ,Mpzf) CGAL_DEFINE_COERCION_TRAITS_FROM_TO(float ,Mpzf) CGAL_DEFINE_COERCION_TRAITS_FROM_TO(double ,Mpzf) CGAL_DEFINE_COERCION_TRAITS_FROM_TO(Gmpz ,Mpzf) #ifdef CGAL_USE_GMPXX CGAL_DEFINE_COERCION_TRAITS_FROM_TO(mpz_class,Mpzf) #endif } /* There isn't much Eigen can do with such a type, * mostly this is here for IsInteger to protect people. */ namespace Eigen { template struct NumTraits; template<> struct NumTraits { typedef CGAL::Mpzf Real; /* Should this be Quotient? Gmpq? */ typedef CGAL::Mpzf NonInteger; typedef CGAL::Mpzf Nested; typedef CGAL::Mpzf Literal; static inline Real epsilon() { return 0; } static inline Real dummy_precision() { return 0; } enum { /* Only exact divisions are supported, close enough to an integer. * This way we get compilation failures instead of runtime. */ IsInteger = 1, IsSigned = 1, IsComplex = 0, RequireInitialization = 1, ReadCost = 6, AddCost = 30, MulCost = 50 }; }; } #if defined(BOOST_MSVC) # pragma warning(pop) #endif #endif // GMP_NUMB_BITS == 64 #endif // CGAL_MPZF_H