/* This file is part of * ====================================================== * * LyX, The Document Processor * * Copyright (C) 1995 Matthias Ettrich * Copyright (C) 1995-1999 The LyX Team. * * ======================================================*/ #ifdef HAVE_CONFIG_H #include #endif #ifdef __GNUG__ #pragma implementation "lyxstring.h" #endif #include "lyxstring.h" #include #include #include #include "LAssert.h" using std::min; // This class is supposed to be functionaly equivalent to a // standard conformant string. This mean among others that we // are useing the same requirements. Before you change anything // in this file consult me and/or the standard to discover the // right behavior. // Reference count has been checked, empty_rep removed and // introduced again in a similar guise. Where is empty_rep _really_ // needed? // Insertion and replace is implemented, as far as I can see everything // works, but could perhaps be done smarter. // All the different find functions need a good look over. // I have so far not tested them extensively and would be // happy if others took the time to have a peek. /////////////////////////////////////// // The internal string representation /////////////////////////////////////// struct lyxstring::Srep { /// static lyxstring::size_type const xtra = static_cast(8); /// size lyxstring::size_type sz; /// Reference count unsigned short ref; /// The total amount of data reserved for this representaion lyxstring::size_type res; /// Data. At least 1 char for trailing null. lyxstring::value_type * s; /// Srep(lyxstring::size_type nsz, const lyxstring::value_type * p); /// Srep(lyxstring::size_type nsz, lyxstring::value_type ch); /// ~Srep() { delete[] s; } /// Srep * get_own_copy() { if (ref == 1) return this; --ref; return new Srep(sz, s); } /// void assign(lyxstring::size_type nsz, const lyxstring::value_type * p); /// void assign(lyxstring::size_type nsz, lyxstring::value_type ch); /// void append(lyxstring::size_type asz, const lyxstring::value_type * p); /// void push_back(lyxstring::value_type c); /// void insert(lyxstring::size_type pos, const lyxstring::value_type * p, lyxstring::size_type n); /// void resize(lyxstring::size_type n, lyxstring::value_type c); /// void reserve(lyxstring::size_type res_arg); /// void replace(lyxstring::size_type i, lyxstring::size_type n, lyxstring::value_type const * p, lyxstring::size_type n2); private: Srep(const Srep &); Srep & operator=(const Srep &); }; lyxstring::Srep::Srep(lyxstring::size_type nsz, const value_type * p) { // can be called with p==0 by lyxstring::assign(const value_type *, size_type) sz = nsz; ref = 1; res = sz + xtra; s = new value_type[res + 1]; // add space for terminator if (p && sz) { // if sz = 0 nothing gets copied and we have an error memcpy(s, p, sz); } else { // possibly allows for large but empty string sz = 0; // this line should be redundant s[0] = '\0'; } } lyxstring::Srep::Srep(lyxstring::size_type nsz, value_type ch) { sz = nsz; ref = 1; res = sz + xtra; s = new value_type[res + 1]; // add space for terminator memset(s, ch, sz); if (!ch) { // if ch == '\0' strlen(lyxstring.c_str()) == 0 so sz = 0 // allows for large but empty string sz = 0; } } void lyxstring::Srep::assign(lyxstring::size_type nsz, const value_type * p) { // can be called with p==0 by lyxstring::assign(const value_type *, size_type) if (res < nsz) { delete[] s; sz = nsz; res = sz + xtra; s = new value_type[res + 1]; // add space for terminator } else { sz = nsz; } if (p && sz) { // if sz = 0 nothing gets copied and we have an error memcpy(s, p, sz); } else { // stops segfaults sz = 0; // this line should be redundant s[0] = '\0'; } } void lyxstring::Srep::assign(lyxstring::size_type nsz, value_type ch) { sz = nsz; if (res < nsz) { delete[] s; res = sz + xtra; s = new value_type[res + 1]; // add space for terminator } memset(s, ch, sz); if (!ch) { // if ch == '\0' strlen(lyxstring.c_str()) == 0 so sz = 0 // allows for a large empty string sz = 0; } } void lyxstring::Srep::append(lyxstring::size_type asz, const value_type * p) { register unsigned int const len = sz + asz; if (res < len) { res = len + xtra; value_type * tmp = new value_type[res + 1]; memcpy(tmp, s, sz); memcpy(tmp + sz, p, asz); sz += asz; delete[] s; s = tmp; } else { memcpy(s + sz, p, asz); sz += asz; } } void lyxstring::Srep::push_back(value_type c) { s[sz] = c; // it is always room to put a value_type at the end ++sz; if (res < sz) { res = sz + xtra; value_type * tmp = new value_type[res + 1]; memcpy(tmp, s, sz); delete[] s; s = tmp; } } void lyxstring::Srep::insert(lyxstring::size_type pos, const value_type * p, lyxstring::size_type n) { Assert(pos <= sz); if (res < n + sz) { res = sz + n + xtra; value_type * tmp = new value_type[res + 1]; memcpy(tmp, s, pos); memcpy(tmp + pos, p, n); memcpy(tmp + pos + n, & s[pos], sz - pos); sz += n; delete[] s; s = tmp; } else { memmove(s + pos + n, & s[pos], sz - pos); memcpy(s + pos, p, n); sz += n; } } void lyxstring::Srep::resize(size_type n, value_type c) { Assert(n < npos); // This resets sz to res_arg res = min(n, npos - 2); // We keep no xtra when we resize value_type * tmp = new value_type[res + 1]; memcpy(tmp, s, min(sz, res)); if (res > sz) memset(tmp + sz, c, res - sz); delete[] s; sz = res; s = tmp; } void lyxstring::Srep::reserve(lyxstring::size_type res_arg) { // This keeps the old sz, but // increases res with res_arg res += res_arg; value_type * tmp = new value_type[res + 1]; memcpy(tmp, s, sz); delete[] s; s = tmp; } void lyxstring::Srep::replace(lyxstring::size_type i, lyxstring::size_type n, value_type const * p, size_type n2) { // can be called with p=0 and n2=0 Assert(i < sz && ((!p && !n2) || p)); n = min(sz - i, n); sz -= n; if (res >= n2 + sz) { memmove(s + i + n2, &s[i + n], sz - i); memcpy(s + i, p, n2); sz += n2; } else { res = sz + n2 + xtra; value_type * tmp = new value_type[res + 1]; memcpy(tmp, s, i); memcpy(tmp + i, p, n2); memcpy(tmp + i + n2, &s[i + n], sz - i); delete[] s; s = tmp; sz += n2; } } /////////////////////////////////////// // The lyxstring Invariant tester /////////////////////////////////////// #ifdef DEVEL_VERSION /** Testing of the lyxstring invariant * By creating an object that tests the lyxstring invariant during its * construction *and* its deconstruction we greatly simplify our code. * Calling TestlyxstringInvariant() upon entry to an lyxstring method * will test the invariant upon entry to the code. If the Asserts fail * then we know from the stack trace that the corruption occurred *before* * entry to this method. We can also be sure it didn't happen in any of * the tested lyxstring methods. It is therefore likely to be due to some * other external force. * Several lyxstring methods have multiple exit points which would otherwise * require us to insert a separate test before each return. But since we * created an object its destructor will be called upon exit (any exit!). * We thus get testing at both start and end of a method with one line of * code at the head of a method. More importantly, we get good testing * everytime we run the code. * NOTE: just because we test the invariant doesn't mean we can forget * about testing pre and post conditions specific to any given method. * This test simply proves that the lyxstring/Srep is in a valid state it * does *not* prove that the method did what it was supposed to. */ class lyxstringInvariant { public: lyxstringInvariant(lyxstring const *); ~lyxstringInvariant(); private: void helper() const; lyxstring const * object; }; // To test if this scheme works "as advertised" uncomment the printf's in // the constructor and destructor below and then uncomment the printf and the // call to TestlyxstringInvariant() in lyxstring::operator=(char const *). // The correct output when LyX has been recompiled and run is: // lyxstringInvariant constructor // lyxstring::operator=(char const *) // lyxstringInvariant constructor // lyxstringInvariant destructor completed // lyxstringInvariant destructor completed // NOTE: The easiest way to catch this snippet of the output is to wait for // the splash screen to disappear and then open and close Help->Credits // lyxstringInvariant::lyxstringInvariant(lyxstring const * ls) : object(ls) { // printf("lyxstringInvariant constructor\n"); helper(); } lyxstringInvariant::~lyxstringInvariant() { helper(); // printf("lyxstringInvariant destructor completed\n"); } void lyxstringInvariant::helper() const { // Some of these tests might look pointless but they are // all part of the invariant and if we want to make sure // we have a bullet proof implementation then we need to // test every last little thing we *know* should be true. // I may have missed a test or two, so feel free to fill // in the gaps. ARRae. // NOTE: Don't put TestlyxstringInvariant() in any of the // lyxstring methods used below otherwise you'll get an // infinite recursion and a crash. Assert(object); Assert(object->rep); Assert(object->rep->s); // s is never 0 Assert(object->rep->res); // always some space allocated Assert(object->size() <= object->rep->res); Assert(object->rep->ref >= 1); // its in use so it must be referenced Assert(object->rep->ref < (1 << 8*sizeof(object->rep->ref)) - 1); // if it does ever == then we should be generating a new copy // and starting again. (Is char always 8-bits?) } #define TestlyxstringInvariant(s) lyxstringInvariant lyxstring_invariant(s); #else #define TestlyxstringInvariant(s) #endif //DEVEL_VERSION /////////////////////////////////////// // Constructors and Deconstructors. /////////////////////////////////////// lyxstring::size_type const lyxstring::npos = static_cast(-1); lyxstring::lyxstring() { static Srep empty_rep(0, ""); ++empty_rep.ref; rep = &empty_rep; } lyxstring::lyxstring(lyxstring const & x, size_type pos, size_type n) { Assert(pos < x.rep->sz || pos == 0); if (pos == 0 && n >= x.length()) { // this is the default x.rep->ref++; rep = x.rep; } else { rep = new Srep(min(n, x.rep->sz - pos), &(x.rep->s[pos])); } } lyxstring::lyxstring(value_type const * s, size_type n) { Assert(s); // we don't allow null pointers static Srep empty_rep(0, ""); if (*s && n) { // s is not empty string and n > 0 rep = new Srep(min(strlen(s), n), s); } else { ++empty_rep.ref; rep = &empty_rep; } } lyxstring::lyxstring(value_type const * s) { Assert(s); // we don't allow null pointers static Srep empty_rep(0, ""); if (*s) { // s is not empty string rep = new Srep(strlen(s), s); } else { ++empty_rep.ref; rep = &empty_rep; } } lyxstring::lyxstring(size_type n, value_type c) { rep = new Srep(n, c); } lyxstring::lyxstring(iterator first, iterator last) { rep = new Srep(last - first, first); } lyxstring::~lyxstring() { if (--rep->ref == 0) delete rep; } /////////////////////// // Iterators /////////////////////// lyxstring::iterator lyxstring::begin() { return rep->s; } lyxstring::const_iterator lyxstring::begin() const { return rep->s; } lyxstring::iterator lyxstring::end() { return rep->s + rep->sz; } lyxstring::const_iterator lyxstring::end() const { return rep->s + rep->sz; } #if 0 reverse_iterator lyxstring::rbegin() { return reverse_iterator( end() ); } const_reverse_iterator lyxstring::rbegin() const { return const_reverse_iterator( end() ); } reverse_iterator lyxstring::rend() { return reverse_iterator( begin() ); } const_reverse_iterator lyxstring::rend() const { return const_reverse_iterator( begin() ); } #endif /////////////////////// // Size and Capacity /////////////////////// lyxstring::size_type lyxstring::size() const { return rep->sz; } void lyxstring::resize(size_type n, value_type c) { TestlyxstringInvariant(this); // This resets sz to res_arg rep = rep->get_own_copy(); rep->resize(n, c); } lyxstring::size_type lyxstring::capacity() const { return rep->res; } void lyxstring::reserve(size_type res_arg) { TestlyxstringInvariant(this); rep = rep->get_own_copy(); rep->reserve(res_arg); } //////////////// // Assignment //////////////// lyxstring & lyxstring::operator=(lyxstring const & x) { TestlyxstringInvariant(this); return assign(x); } lyxstring & lyxstring::operator=(value_type const * s) { Assert(s); TestlyxstringInvariant(this); // printf("lyxstring::operator=(value_type const *)\n"); return assign(s); } lyxstring & lyxstring::operator=(value_type c) { TestlyxstringInvariant(this); value_type s[1]; s[0] = c; if (rep->ref == 1) // recycle rep rep->assign(1, s); else { rep->ref--; rep = new Srep(1, s); } return *this; } lyxstring & lyxstring::assign(lyxstring const & x) { TestlyxstringInvariant(this); x.rep->ref++; // protect against ``st = st'' if (--rep->ref == 0) delete rep; rep = x.rep; // share representation return *this; } lyxstring & lyxstring::assign(lyxstring const & x, size_type pos, size_type n) { TestlyxstringInvariant(this); return assign(x.substr(pos, n)); } lyxstring & lyxstring::assign(value_type const * s, size_type n) { Assert(s); TestlyxstringInvariant(this); n = min(strlen(s), n); if (rep->ref == 1) // recycle rep rep->assign(n, s); else { rep->ref--; rep = new Srep(n, s); } return *this; } lyxstring & lyxstring::assign(value_type const * s) { Assert(s); TestlyxstringInvariant(this); return assign(s, strlen(s)); } lyxstring & lyxstring::assign(size_type n, value_type ch) { TestlyxstringInvariant(this); rep = rep->get_own_copy(); rep->assign(n, ch); return *this; } lyxstring & lyxstring::assign(iterator first, iterator last) { TestlyxstringInvariant(this); rep = rep->get_own_copy(); rep->assign(last - first, first); return *this; } //////////////////// // Element Access //////////////////// lyxstring::const_reference lyxstring::operator[](size_type pos) const { Assert(pos < rep->sz); return rep->s[pos]; } lyxstring::reference lyxstring::operator[](size_type pos) { Assert(pos < rep->sz); TestlyxstringInvariant(this); rep = rep->get_own_copy(); return rep->s[pos]; } lyxstring::const_reference lyxstring::at(size_type n) const { Assert(n < rep->sz); return rep->s[n]; } lyxstring::reference lyxstring::at(size_type n) { Assert(n < rep->sz); TestlyxstringInvariant(this); rep = rep->get_own_copy(); return rep->s[n]; } ///////////// // Insert ///////////// lyxstring & lyxstring::operator+=(lyxstring const & x) { TestlyxstringInvariant(this); return append(x); } lyxstring & lyxstring::operator+=(value_type const * x) { Assert(x); TestlyxstringInvariant(this); return append(x); } lyxstring & lyxstring::operator+=(value_type c) { TestlyxstringInvariant(this); push_back(c); return *this; } void lyxstring::push_back(value_type c) { TestlyxstringInvariant(this); rep = rep->get_own_copy(); rep->push_back(c); } lyxstring & lyxstring::append(lyxstring const & x) { TestlyxstringInvariant(this); if (x.empty()) return *this; rep = rep->get_own_copy(); rep->append(x.length(), x.rep->s); return *this; } lyxstring & lyxstring::append(lyxstring const & x, size_type pos, size_type n) { TestlyxstringInvariant(this); return append(x.substr(pos, n)); } lyxstring & lyxstring::append(value_type const * p, size_type n) { Assert(p); TestlyxstringInvariant(this); if (!*p || !n) return *this; rep = rep->get_own_copy(); rep->append(min(n, strlen(p)), p); return *this; } lyxstring & lyxstring::append(value_type const * p) { Assert(p); TestlyxstringInvariant(this); if (!*p) return *this; rep = rep->get_own_copy(); rep->append(strlen(p), p); return *this; } lyxstring & lyxstring::append(size_type n, value_type c) { TestlyxstringInvariant(this); value_type * tmp = new value_type[n]; memset(tmp, c, n); rep = rep->get_own_copy(); rep->append(n, tmp); delete[] tmp; return *this; } lyxstring & lyxstring::append(iterator first, iterator last) { TestlyxstringInvariant(this); rep = rep->get_own_copy(); rep->append(last - first, first); return *this; } // insert value_typeacters before (*this)[pos] lyxstring & lyxstring::insert(size_type pos, lyxstring const & x) { TestlyxstringInvariant(this); return insert(pos, x, 0, x.rep->sz); } lyxstring & lyxstring::insert(size_type pos, lyxstring const & x, size_type pos2, size_type n) { TestlyxstringInvariant(this); rep = rep->get_own_copy(); rep->insert(pos, &(x.rep->s[pos2]), min(n, x.rep->sz)); return *this; } lyxstring & lyxstring::insert(size_type pos, value_type const * p, size_type n) { Assert(p); TestlyxstringInvariant(this); if (*p && n) { // insert nothing and you change nothing rep = rep->get_own_copy(); rep->insert(pos, p, min(n, strlen(p))); } return *this; } lyxstring & lyxstring::insert(size_type pos, value_type const * p) { Assert(p); TestlyxstringInvariant(this); if (*p) { // insert nothing and you change nothing rep = rep->get_own_copy(); rep->insert(pos, p, strlen(p)); } return *this; } lyxstring & lyxstring::insert(size_type pos, size_type n, value_type c) { TestlyxstringInvariant(this); rep = rep->get_own_copy(); value_type * tmp = new value_type[n]; memset(tmp, c, n); rep->insert(pos, tmp, n); delete[] tmp; return *this; } lyxstring::iterator lyxstring::insert(iterator p, value_type c) { TestlyxstringInvariant(this); // what iterator is this supposed to return?? size_type tmp = p - begin(); insert(p - begin(), 1, c); return begin() + tmp + 1; // ?? } void lyxstring::insert(iterator p, size_type n , value_type c) { TestlyxstringInvariant(this); insert(p - begin(), n , c); } void lyxstring::insert(iterator p, iterator first, iterator last) { TestlyxstringInvariant(this); insert(p - begin(), first, last - first); } //////////////// // Find //////////////// // All the below find functions should be verified, // it is very likely that I have mixed up or interpreted // some of the parameters wrong, also some of the funcs can surely // be written more effectively. lyxstring::size_type lyxstring::find(lyxstring const & a, size_type i) const { if (!rep->sz || i >= rep->sz) return npos; TestlyxstringInvariant(this); for (size_type t = i; rep->sz - t >= a.length(); ++t) { // search until (*this)[i] == a[0] if (rep->s[t] == a[0]) { // check if the rest of the value_types match bool equal = true; for (size_type j = 0; j < a.length(); ++j) { if (rep->s[t + j] != a[j]) { equal = false; break; } } if (equal) return t; } } return npos; } lyxstring::size_type lyxstring::find(value_type const * ptr, size_type i, size_type n) const { Assert(ptr); if (!rep->sz || !*ptr || i >= rep->sz) return npos; TestlyxstringInvariant(this); // What is "n" here? is it the number of value_types to use in ptr // or does "i" and "n" togeter form a substring to search // for ptr in? For now I will assume that "n" tells the length // of ptr. (Lgb) n = min(n, strlen(ptr)); for (size_type t = i; rep->sz - t >= n; ++t) { // search until (*this)[i] == a[0] if (rep->s[t] == ptr[0]) { // check if the rest of the value_types match bool equal = true; for (size_type j = 0; j < n; ++j) { if (rep->s[t + j] != ptr[j]) { equal = false; break; } } if (equal) return t; } } return npos; } lyxstring::size_type lyxstring::find(value_type const * s, size_type i) const { Assert(s); if (!rep->sz || i >= rep->sz) return npos; TestlyxstringInvariant(this); if (!s || !*s) return npos; return find(s, i, strlen(s)); } lyxstring::size_type lyxstring::find(value_type c, size_type i) const { if (!rep->sz || i >= rep->sz) return npos; TestlyxstringInvariant(this); for (size_type t = 0; t + i < rep->sz; ++t) { if (rep->s[t + i] == c) return t + i; } return npos; } lyxstring::size_type lyxstring::rfind(lyxstring const & a, size_type i) const { TestlyxstringInvariant(this); size_type ii = min(rep->sz - 1, i); do { if (a[a.length() - 1] == rep->s[ii]) { int t = rep->sz - 2; size_type l = ii - 1; for (; t >= 0; --t, --l) { if (a[t] != rep->s[l]) break; } if (a[t] == rep->s[l]) return l; } } while(ii-- > 0); return npos; } lyxstring::size_type lyxstring::rfind(value_type const * ptr, size_type i, size_type n) const { Assert(ptr); TestlyxstringInvariant(this); if (!*ptr) return npos; size_type ii = min(rep->sz - 1, i); do { if (ptr[n - 1] == rep->s[ii]) { int t = n - 2; size_type l = ii - 1; for (; t >= 0; --t, --l) { if (ptr[t] != rep->s[l]) break; } if (ptr[t] == rep->s[l]) return l; } } while (ii-- > 0); return npos; } lyxstring::size_type lyxstring::rfind(value_type const * ptr, size_type i) const { Assert(ptr); TestlyxstringInvariant(this); if (!*ptr) return npos; size_type ii = min(rep->sz - 1, i); do { if (ptr[strlen(ptr) - 1] == rep->s[ii]) { int t = strlen(ptr) - 2; size_type l = ii - 1; for (; t >= 0; --t, --l) { if (ptr[t] != rep->s[l]) break; } if (ptr[t] == rep->s[l]) return l; } } while (ii-- > 0); return npos; } lyxstring::size_type lyxstring::rfind(value_type c, size_type i) const { TestlyxstringInvariant(this); size_type ii = min(rep->sz - 1, i); for (size_type t = ii; t != 0; --t) { if (rep->s[t] == c) return t; } return npos; } lyxstring::size_type lyxstring::find_first_of(lyxstring const & a, size_type i) const { Assert(i < rep->sz); TestlyxstringInvariant(this); for (size_type t = i; t < rep->sz; ++t) { if (a.find(rep->s[t]) != npos) return t; } return npos; } lyxstring::size_type lyxstring::find_first_of(value_type const * ptr, size_type i, size_type n) const { Assert(ptr && i < rep->sz); TestlyxstringInvariant(this); if (!n) return npos; for (size_type t = i; t < rep->sz; ++t) { if(memchr(ptr, rep->s[t], n) != 0) return t; } return npos; } lyxstring::size_type lyxstring::find_first_of(value_type const * ptr, size_type i) const { Assert(ptr && i < rep->sz); TestlyxstringInvariant(this); for (size_type t = i; t < rep->sz; ++t) { if (strchr(ptr, rep->s[t]) != 0) return t; } return npos; } lyxstring::size_type lyxstring::find_first_of(value_type c, size_type i) const { Assert(i < rep->sz); TestlyxstringInvariant(this); for (size_type t = i; t < rep->sz; ++t) { if (rep->s[t] == c) return t; } return npos; } lyxstring::size_type lyxstring::find_last_of(lyxstring const & a, size_type i) const { TestlyxstringInvariant(this); size_type ii = min(rep->sz - 1, i); for (int t = ii; t >= 0; --t) { if (a.find(rep->s[t]) != npos) return t; } return npos; } lyxstring::size_type lyxstring::find_last_of(value_type const * ptr, size_type i, size_type n) const { Assert(ptr); TestlyxstringInvariant(this); if (!n) return npos; size_type ii = min(rep->sz - 1, i); for (int t = ii; t >= 0; --t) { if(memchr(ptr, rep->s[t], n) != 0) return t; } return npos; } lyxstring::size_type lyxstring::find_last_of(value_type const * ptr, size_type i) const { Assert(ptr); TestlyxstringInvariant(this); size_type ii = min(rep->sz - 1, i); for (int t = ii; t >= 0; --t) { if (strchr(ptr, rep->s[t]) != 0) return t; } return npos; } lyxstring::size_type lyxstring::find_last_of(value_type c, size_type i) const { TestlyxstringInvariant(this); if (!rep->sz) return npos; size_type ii = min(rep->sz - 1, i); for (int t = ii; t >= 0; --t) { if (rep->s[t] == c) return t; } return npos; } lyxstring::size_type lyxstring::find_first_not_of(lyxstring const & a, size_type i) const { TestlyxstringInvariant(this); if (!rep->sz) return npos; Assert(i < rep->sz); for (size_type t = i; t < rep->sz; ++t) { if (a.find(rep->s[t]) == npos) return t; } return npos; } lyxstring::size_type lyxstring::find_first_not_of(value_type const * ptr, size_type i, size_type n) const { Assert(ptr && i < rep->sz); TestlyxstringInvariant(this); if (!n) return (i < rep->sz) ? i : npos; for (size_type t = i; t < rep->sz; ++t) { if(memchr(ptr, rep->s[t], n) == 0) return t; } return npos; } lyxstring::size_type lyxstring::find_first_not_of(value_type const * ptr, size_type i) const { Assert(ptr && i < rep->sz); TestlyxstringInvariant(this); for (size_type t = i; t < rep->sz; ++t) { if (strchr(ptr, rep->s[t]) == 0) return t; } return npos; } lyxstring::size_type lyxstring::find_first_not_of(value_type c, size_type i) const { if (!rep->sz) return npos; Assert(i < rep->sz); TestlyxstringInvariant(this); for (size_type t = i; t < rep->sz; ++t) { if (rep->s[t] != c) return t; } return npos; } lyxstring::size_type lyxstring::find_last_not_of(lyxstring const & a, size_type i) const { TestlyxstringInvariant(this); size_type ii = min(rep->sz - 1, i); for (int t = ii; t >= 0; --t) { if (a.find(rep->s[t]) == npos) return t; } return npos; } lyxstring::size_type lyxstring::find_last_not_of(value_type const * ptr, size_type i, size_type n) const { Assert(ptr); TestlyxstringInvariant(this); if (!n) return npos; size_type ii = min(rep->sz - 1, i); for (int t = ii; t >= 0; --t) { if(memchr(ptr, rep->s[t], n) == 0) return t; } return npos; } lyxstring::size_type lyxstring::find_last_not_of(value_type const * ptr, size_type i) const { Assert(ptr); TestlyxstringInvariant(this); size_type ii = min(rep->sz - 1, i); for (int t = ii; t >= 0; --t) { if (strchr(ptr, rep->s[t]) == 0) return t; } return npos; } lyxstring::size_type lyxstring::find_last_not_of(value_type c, size_type i) const { TestlyxstringInvariant(this); size_type ii = min(rep->sz - 1, i); for (int t = ii; t >= 0; --t) { if (rep->s[t] != c) return t; } return npos; } ///////////////// // Replace ///////////////// lyxstring & lyxstring::replace(size_type i, size_type n, lyxstring const & x) { Assert(i < rep->sz || i == 0); TestlyxstringInvariant(this); return replace(i, n, x, 0, x.length()); } lyxstring & lyxstring::replace(size_type i,size_type n, lyxstring const & x, size_type i2, size_type n2) { Assert((i < rep->sz || i == 0) && (i2 < x.rep->sz || i2 == 0)); TestlyxstringInvariant(this); rep = rep->get_own_copy(); rep->replace(i, min(n, rep->sz), &(x.rep->s[i2]), min(n2, x.rep->sz)); return *this; } lyxstring & lyxstring::replace(size_type i, size_type n, value_type const * p, size_type n2) { Assert(p && i < rep->sz); TestlyxstringInvariant(this); rep = rep->get_own_copy(); rep->replace(i, min(n, rep->sz), p, min(n2, strlen(p))); return *this; } lyxstring & lyxstring::replace(size_type i, size_type n, value_type const * p) { Assert(p && i < rep->sz); TestlyxstringInvariant(this); return replace(i, min(n, rep->sz), p, (!p) ? 0 : strlen(p)); } lyxstring & lyxstring::replace(size_type i, size_type n, size_type n2, value_type c) { Assert(i < rep->sz); TestlyxstringInvariant(this); rep = rep->get_own_copy(); value_type * tmp = new value_type[n2]; memset(tmp, c, n2); rep->replace(i, min(n, rep->sz), tmp, n2); delete[] tmp; return *this; } lyxstring & lyxstring::replace(iterator i, iterator i2, const lyxstring & str) { TestlyxstringInvariant(this); return replace(i - begin(), i2 - i, str); } lyxstring & lyxstring::replace(iterator i, iterator i2, value_type const * p, size_type n) { Assert(p); TestlyxstringInvariant(this); return replace(i - begin(), i2 - i, p, n); } lyxstring & lyxstring::replace(iterator i, iterator i2, value_type const * p) { Assert(p); TestlyxstringInvariant(this); return replace(i - begin(), i2 - i, p); } lyxstring & lyxstring::replace(iterator i, iterator i2, size_type n , value_type c) { TestlyxstringInvariant(this); return replace(i - begin(), i2 - i, n, c); } lyxstring & lyxstring::replace(iterator i, iterator i2, iterator j, iterator j2) { TestlyxstringInvariant(this); return replace(i - begin(), i2 - i, j, j2 - j); } lyxstring & lyxstring::erase(size_type i, size_type n) { Assert(i < rep->sz || i == 0); TestlyxstringInvariant(this); rep = rep->get_own_copy(); if (i == 0 && n >= rep->sz) { rep->sz = 0; } else { n = min(n, rep->sz - i); memmove(&(rep->s[i]), &(rep->s[i + n]), rep->sz - i - n); rep->sz -= n; } return *this; } lyxstring::iterator lyxstring::erase(iterator i) { TestlyxstringInvariant(this); // what iterator is this supposed to return? // the iterator after the one erased erase(i - begin(), 1); return begin(); // BUG } lyxstring::iterator lyxstring::erase(iterator first, iterator last) { TestlyxstringInvariant(this); erase(first - begin(), last - first); return begin(); // BUG } ///////////////////////////////////// // Conversion to C-style Strings ///////////////////////////////////// lyxstring::value_type const * lyxstring::c_str() const { rep->s[length()] = '\0'; return rep->s; } lyxstring::value_type const * lyxstring::data() const { return rep->s; } lyxstring::size_type lyxstring::copy(value_type * buf, size_type len, size_type pos) const { Assert(buf); TestlyxstringInvariant(this); register int nn = min(len, length() - pos); memcpy(buf, &(rep->s[pos]), nn); return nn; } //////////////////// // Comparisons //////////////////// // Compare funcs should be verified. // Should we try to make them work with '\0' value_types? // An STL string can usually contain '\0' value_types. int lyxstring::compare(lyxstring const & str) const { TestlyxstringInvariant(this); return compare(0, rep->sz, str.c_str(), str.rep->sz); } int lyxstring::compare(value_type const * s) const { Assert(s); TestlyxstringInvariant(this); return compare(0, rep->sz, s, (!s) ? 0 : strlen(s)); } int lyxstring::compare(size_type pos, size_type n, lyxstring const & str) const { TestlyxstringInvariant(this); return compare(pos, n, str.c_str(), str.rep->sz); } int lyxstring::compare(size_type pos, size_type n, lyxstring const & str, size_type pos2, size_type n2) const { TestlyxstringInvariant(this); return compare(pos, n, str.c_str() + pos2, n2); } int lyxstring::compare(size_type pos, size_type n, value_type const * s, size_type n2) const { Assert(s && (pos < rep->sz || pos == 0)); TestlyxstringInvariant(this); if ((rep->sz == 0 || n == 0) && (!*s || n2 == 0)) return 0; if (!*s) return 1; // since n > n2, min(n,n2) == 0, c == 0 (stops segfault also) // remember that n can very well be a lot larger than rep->sz // so we have to ensure that n is no larger than rep->sz n = min(n, rep->sz); n2 = min(n2, strlen(s)); if (n == n2) return memcmp(&(rep->s[pos]), s, n); int c = memcmp(&(rep->s[pos]), s, min(n,n2)); if (c) return c; if (n < n2) return -1; return 1; } ///////////////// // Substrings ///////////////// // i = index, n = length lyxstring lyxstring::substr(size_type i, size_type n) const { Assert(i < rep->sz || i == 0); TestlyxstringInvariant(this); return lyxstring(*this, i, n); } ///////////////////////////////////////////// // String operators, non member functions ///////////////////////////////////////////// bool operator==(lyxstring const & a, lyxstring const & b) { return a.compare(b) == 0; } bool operator==(lyxstring::value_type const * a, lyxstring const & b) { Assert(a); return b.compare(a) == 0; } bool operator==(lyxstring const & a, lyxstring::value_type const * b) { Assert(b); return a.compare(b) == 0; } bool operator!=(lyxstring const & a, lyxstring const & b) { return a.compare(b) != 0; } bool operator!=(lyxstring::value_type const * a, lyxstring const & b) { Assert(a); return b.compare(a) != 0; } bool operator!=(lyxstring const & a, lyxstring::value_type const * b) { Assert(b); return a.compare(b) != 0; } bool operator>(lyxstring const & a, lyxstring const & b) { return a.compare(b) > 0; } bool operator>(lyxstring::value_type const * a, lyxstring const & b) { Assert(a); return b.compare(a) < 0; // since we reverse the parameters } bool operator>(lyxstring const & a, lyxstring::value_type const * b) { Assert(b); return a.compare(b) > 0; } bool operator<(lyxstring const & a, lyxstring const & b) { return a.compare(b) < 0; } bool operator<(lyxstring::value_type const * a, lyxstring const & b) { Assert(a); return b.compare(a) > 0; // since we reverse the parameters } bool operator<(lyxstring const & a, lyxstring::value_type const * b) { Assert(b); return a.compare(b) < 0; } bool operator>=(lyxstring const & a, lyxstring const & b) { return a.compare(b) >= 0; } bool operator>=(lyxstring::value_type const * a, lyxstring const & b) { Assert(a); return b.compare(a) <= 0; // since we reverse the parameters } bool operator>=(lyxstring const & a, lyxstring::value_type const * b) { Assert(b); return a.compare(b) >= 0; } bool operator<=(lyxstring const & a, lyxstring const & b) { return a.compare(b) <= 0; } bool operator<=(lyxstring::value_type const * a, lyxstring const & b) { Assert(a); return b.compare(a) >= 0; // since we reverse the parameters } bool operator<=(lyxstring const & a, lyxstring::value_type const * b) { Assert(b); return a.compare(b) <= 0; } lyxstring operator+(lyxstring const & a, lyxstring const & b) { lyxstring tmp(a); tmp += b; return tmp; } lyxstring operator+(lyxstring::value_type const * a, lyxstring const & b) { Assert(a); lyxstring tmp(a); tmp += b; return tmp; } lyxstring operator+(lyxstring::value_type a, lyxstring const & b) { lyxstring tmp; tmp += a; tmp += b; return tmp; } lyxstring operator+(lyxstring const & a, lyxstring::value_type const * b) { Assert(b); lyxstring tmp(a); tmp += b; return tmp; } lyxstring operator+(lyxstring const & a, lyxstring::value_type b) { lyxstring tmp(a); tmp += b; return tmp; } #include istream & operator>>(istream & is, lyxstring & s) { // very bad solution char * nome = new char[1024]; is >> nome; lyxstring tmp(nome); delete [] nome; if (!tmp.empty()) s = tmp; return is; } ostream & operator<<(ostream & o, lyxstring const & s) { return o.write(s.data(), s.length()); } istream & getline(istream & is, lyxstring & s, lyxstring::value_type delim) { // very bad solution char tmp = 0; s.erase(); while(is) { is.get(tmp); if (tmp != delim) { s += tmp; } else { break; } } return is; }