/***************************************************************************** Licensed to Accellera Systems Initiative Inc. (Accellera) under one or more contributor license agreements. See the NOTICE file distributed with this work for additional information regarding copyright ownership. Accellera licenses this file to you under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. *****************************************************************************/ /***************************************************************************** sc_int_base.h -- A signed integer whose length is less than 64 bit. Unlike arbitrary precision, arithmetic and bitwise operations are performed using the native types (hence capped at 64 bits). The sc_int integer is useful when the user does not need arbitrary precision and the performance is superior to sc_bigint/sc_biguint. Original Author: Amit Rao, Synopsys, Inc. *****************************************************************************/ /***************************************************************************** MODIFICATION LOG - modifiers, enter your name, affiliation, date and changes you are making here. Name, Affiliation, Date: Ali Dasdan, Synopsys, Inc. Description of Modification: - Resolved ambiguity with sc_(un)signed. - Merged the code for 64- and 32-bit versions via the constants in sc_nbdefs.h. - Eliminated redundant file inclusions. Name, Affiliation, Date: Description of Modification: *****************************************************************************/ // $Log: sc_int_base.h,v $ // Revision 1.3 2011/08/24 22:05:45 acg // Torsten Maehne: initialization changes to remove warnings. // // Revision 1.2 2011/02/18 20:19:15 acg // Andy Goodrich: updating Copyright notice. // // Revision 1.1.1.1 2006/12/15 20:20:05 acg // SystemC 2.3 // // Revision 1.4 2006/05/08 17:50:01 acg // Andy Goodrich: Added David Long's declarations for friend operators, // functions, and methods, to keep the Microsoft compiler happy. // // Revision 1.3 2006/01/13 18:49:31 acg // Added $Log command so that CVS check in comments are reproduced in the // source. // #ifndef __SYSTEMC_EXT_DT_INT_SC_INT_BASE_HH__ #define __SYSTEMC_EXT_DT_INT_SC_INT_BASE_HH__ #include #include "../misc/sc_value_base.hh" #include "../sc_temporary.hh" #include "sc_length_param.hh" #include "sc_nbdefs.hh" #include "sc_uint_base.hh" namespace sc_dt { class sc_concatref; // classes defined in this module class sc_int_bitref_r; class sc_int_bitref; class sc_int_subref_r; class sc_int_subref; class sc_int_base; class sc_signed_subref_r; class sc_unsigned_subref_r; // forward class declarations class sc_bv_base; class sc_lv_base; class sc_signed; class sc_unsigned; class sc_fxval; class sc_fxval_fast; class sc_fxnum; class sc_fxnum_fast; } // namespace sc_dt // extern template instantiations namespace sc_core { extern template class sc_vpool; extern template class sc_vpool; } // namespace sc_core namespace sc_dt { extern const uint_type mask_int[SC_INTWIDTH][SC_INTWIDTH]; // friend operator declarations // relational operators inline bool operator == (const sc_int_base &a, const sc_int_base &b); inline bool operator != (const sc_int_base &a, const sc_int_base &b); inline bool operator < (const sc_int_base &a, const sc_int_base &b); inline bool operator <= (const sc_int_base &a, const sc_int_base &b); inline bool operator > (const sc_int_base &a, const sc_int_base &b); inline bool operator >= (const sc_int_base &a, const sc_int_base &b); // ---------------------------------------------------------------------------- // CLASS : sc_int_bitref_r // // Proxy class for sc_int bit selection (r-value only). // ---------------------------------------------------------------------------- class sc_int_bitref_r : public sc_value_base { friend class sc_int_base; protected: // constructor sc_int_bitref_r() : sc_value_base(), m_index(), m_obj_p() {} // initializer for sc_core::sc_vpool: void initialize(const sc_int_base *obj_p, int index_) { m_obj_p = (sc_int_base *)obj_p; m_index = index_; } public: // copy constructor sc_int_bitref_r(const sc_int_bitref_r &a) : sc_value_base(a), m_index(a.m_index), m_obj_p(a.m_obj_p) {} // destructor virtual ~sc_int_bitref_r() {} // capacity int length() const { return 1; } #ifdef SC_DT_DEPRECATED int bitwidth() const { return length(); } #endif // concatenation support virtual int concat_length(bool *xz_present_p) const { if (xz_present_p) *xz_present_p = false; return 1; } virtual bool concat_get_ctrl(sc_digit *dst_p, int low_i) const { int bit_mask = 1 << (low_i % BITS_PER_DIGIT); int word_i = low_i / BITS_PER_DIGIT; dst_p[word_i] &= ~bit_mask; return false; } virtual bool concat_get_data(sc_digit *dst_p, int low_i) const { bool non_zero; int bit_mask = 1 << (low_i % BITS_PER_DIGIT); int word_i = low_i / BITS_PER_DIGIT; if (operator uint64()) { dst_p[word_i] |= bit_mask; non_zero = true; } else { dst_p[word_i] &= ~bit_mask; non_zero = false; } return non_zero; } virtual uint64 concat_get_uint64() const { return operator uint64(); } // implicit conversions operator uint64 () const; bool operator ! () const; bool operator ~ () const; // explicit conversions uint64 value() const { return operator uint64(); } bool to_bool() const { return operator uint64(); } // other methods void print(::std::ostream& os=::std::cout) const { os << to_bool(); } protected: int m_index; sc_int_base *m_obj_p; private: // Disabled sc_int_bitref_r &operator = (const sc_int_bitref_r &); }; inline ::std::ostream &operator << (::std::ostream &, const sc_int_bitref_r &); // ---------------------------------------------------------------------------- // CLASS : sc_int_bitref // // Proxy class for sc_int bit selection (r-value and l-value). // ---------------------------------------------------------------------------- class sc_int_bitref : public sc_int_bitref_r { friend class sc_int_base; friend class sc_core::sc_vpool; // constructor sc_int_bitref() : sc_int_bitref_r() {} public: // copy constructor sc_int_bitref(const sc_int_bitref &a) : sc_int_bitref_r(a) {} // assignment operators sc_int_bitref &operator = (const sc_int_bitref_r &b); sc_int_bitref &operator = (const sc_int_bitref &b); sc_int_bitref &operator = (bool b); sc_int_bitref &operator &= (bool b); sc_int_bitref &operator |= (bool b); sc_int_bitref &operator ^= (bool b); // concatenation methods virtual void concat_set(int64 src, int low_i); virtual void concat_set(const sc_signed &src, int low_i); virtual void concat_set(const sc_unsigned &src, int low_i); virtual void concat_set(uint64 src, int low_i); // other methods void scan(::std::istream &is=::std::cin); public: static sc_core::sc_vpool m_pool; }; inline ::std::istream &operator >> (::std::istream &, sc_int_bitref &); // ---------------------------------------------------------------------------- // CLASS : sc_int_subref_r // // Proxy class for sc_int part selection (r-value only). // ---------------------------------------------------------------------------- class sc_int_subref_r : public sc_value_base { friend class sc_int_base; friend class sc_int_signal; friend class sc_int_subref; protected: // constructor sc_int_subref_r() : sc_value_base(), m_left(0), m_obj_p(0), m_right(0) {} // initializer for sc_core::sc_vpool: void initialize( const sc_int_base *obj_p, int left_i, int right_i) { m_obj_p = (sc_int_base *)obj_p; m_left = left_i; m_right = right_i; } public: // copy constructor sc_int_subref_r(const sc_int_subref_r &a) : sc_value_base(a), m_left(a.m_left), m_obj_p(a.m_obj_p), m_right(a.m_right) {} // destructor virtual ~sc_int_subref_r() {} // capacity int length() const { return (m_left - m_right + 1); } // concatenation support virtual int concat_length(bool *xz_present_p) const { if (xz_present_p) *xz_present_p = false; return length(); } virtual bool concat_get_ctrl( sc_digit* dst_p, int low_i ) const; virtual bool concat_get_data( sc_digit* dst_p, int low_i ) const; virtual uint64 concat_get_uint64() const { int len = length(); uint64 val = operator uint_type(); if (len < 64) return (uint64)(val & ~((uint_type)-1 << len)); else return (uint64)val; } // reduce methods bool and_reduce() const; bool nand_reduce() const { return !and_reduce(); } bool or_reduce() const; bool nor_reduce() const { return or_reduce(); } bool xor_reduce() const; bool xnor_reduce() const { return xor_reduce(); } // implicit conversion to uint_type operator uint_type () const; // explicit conversions uint_type value() const { return operator uint_type(); } int to_int() const; unsigned int to_uint() const; long to_long() const; unsigned long to_ulong() const; int64 to_int64() const; uint64 to_uint64() const; double to_double() const; // explicit conversion to character string const std::string to_string(sc_numrep numrep=SC_DEC) const; const std::string to_string(sc_numrep numrep, bool w_prefix) const; // other methods void print(::std::ostream &os=::std::cout) const { os << to_string(sc_io_base(os, SC_DEC), sc_io_show_base(os)); } protected: int m_left; sc_int_base *m_obj_p; int m_right; private: const sc_int_subref_r &operator = (const sc_int_subref_r &); }; inline ::std::ostream &operator << (::std::ostream &, const sc_int_subref_r &); // ---------------------------------------------------------------------------- // CLASS : sc_int_subref // // Proxy class for sc_int part selection (r-value and l-value). // ---------------------------------------------------------------------------- class sc_int_subref : public sc_int_subref_r { friend class sc_int_base; friend class sc_core::sc_vpool; protected: // constructor sc_int_subref() : sc_int_subref_r() {} public: // copy constructor sc_int_subref(const sc_int_subref &a) : sc_int_subref_r(a) {} // assignment operators sc_int_subref &operator = (int_type v); sc_int_subref &operator = (const sc_int_base &a); sc_int_subref & operator = (const sc_int_subref_r &a) { return operator = (a.operator uint_type()); } sc_int_subref & operator = (const sc_int_subref &a) { return operator = (a.operator uint_type()); } template< class T > sc_int_subref & operator = (const sc_generic_base &a) { return operator = (a->to_int64()); } sc_int_subref &operator = (const char *a); sc_int_subref & operator = (unsigned long a) { return operator = ((int_type)a); } sc_int_subref & operator = (long a) { return operator = ((int_type)a); } sc_int_subref & operator = (unsigned int a) { return operator = ((int_type)a); } sc_int_subref & operator = (int a) { return operator = ((int_type)a); } sc_int_subref & operator = (uint64 a) { return operator = ((int_type)a); } sc_int_subref & operator = (double a) { return operator = ((int_type)a); } sc_int_subref &operator = (const sc_signed &); sc_int_subref &operator = (const sc_unsigned &); sc_int_subref &operator = (const sc_bv_base &); sc_int_subref &operator = (const sc_lv_base &); // concatenation methods virtual void concat_set(int64 src, int low_i); virtual void concat_set(const sc_signed &src, int low_i); virtual void concat_set(const sc_unsigned &src, int low_i); virtual void concat_set(uint64 src, int low_i); // other methods void scan(::std::istream &is=::std::cin); public: static sc_core::sc_vpool m_pool; }; inline ::std::istream &operator >> (::std::istream &, sc_int_subref &); // ---------------------------------------------------------------------------- // CLASS : sc_int_base // // Base class for sc_int. // ---------------------------------------------------------------------------- class sc_int_base : public sc_value_base { friend class sc_int_bitref_r; friend class sc_int_bitref; friend class sc_int_subref_r; friend class sc_int_subref; // support methods void invalid_length() const; void invalid_index(int i) const; void invalid_range(int l, int r) const; void check_length() const { if (m_len <= 0 || m_len > SC_INTWIDTH) { invalid_length(); } } void check_index(int i) const { if (i < 0 || i >= m_len) { invalid_index(i); } } void check_range(int l, int r) const { if (r < 0 || l >= m_len || l < r) { invalid_range(l, r); } } void check_value() const; void extend_sign() { #ifdef DEBUG_SYSTEMC check_value(); #endif m_val = (m_val << m_ulen >> m_ulen); } public: // constructors explicit sc_int_base(int w=sc_length_param().len()) : m_val(0), m_len(w), m_ulen(SC_INTWIDTH - m_len) { check_length(); } sc_int_base(int_type v, int w) : m_val(v), m_len(w), m_ulen(SC_INTWIDTH - m_len) { check_length(); extend_sign(); } sc_int_base(const sc_int_base &a) : sc_value_base(a), m_val(a.m_val), m_len(a.m_len), m_ulen(a.m_ulen) {} explicit sc_int_base(const sc_int_subref_r &a) : m_val(a), m_len(a.length()), m_ulen(SC_INTWIDTH - m_len) { extend_sign(); } template< class T > explicit sc_int_base(const sc_generic_base &a) : m_val(a->to_int64()), m_len(a->length()), m_ulen(SC_INTWIDTH - m_len) { check_length(); extend_sign(); } explicit sc_int_base(const sc_signed &a); explicit sc_int_base(const sc_unsigned &a); explicit sc_int_base(const sc_bv_base &v); explicit sc_int_base(const sc_lv_base &v); explicit sc_int_base(const sc_uint_subref_r &v); explicit sc_int_base(const sc_signed_subref_r &v); explicit sc_int_base(const sc_unsigned_subref_r &v); // destructor virtual ~sc_int_base() {} // assignment operators sc_int_base & operator = (int_type v) { m_val = v; extend_sign(); return *this; } sc_int_base & operator = (const sc_int_base &a) { m_val = a.m_val; extend_sign(); return *this; } sc_int_base & operator = (const sc_int_subref_r &a) { m_val = a; extend_sign(); return *this; } template sc_int_base & operator = (const sc_generic_base &a) { m_val = a->to_int64(); extend_sign(); return *this; } sc_int_base &operator = (const sc_signed &a); sc_int_base &operator = (const sc_unsigned &a); sc_int_base &operator = (const sc_fxval &a); sc_int_base &operator = (const sc_fxval_fast &a); sc_int_base &operator = (const sc_fxnum &a); sc_int_base &operator = (const sc_fxnum_fast &a); sc_int_base &operator = (const sc_bv_base &a); sc_int_base &operator = (const sc_lv_base &a); sc_int_base &operator = (const char *a); sc_int_base & operator = (unsigned long a) { m_val = a; extend_sign(); return *this; } sc_int_base & operator = (long a) { m_val = a; extend_sign(); return *this; } sc_int_base & operator = (unsigned int a) { m_val = a; extend_sign(); return *this; } sc_int_base & operator = (int a) { m_val = a; extend_sign(); return *this; } sc_int_base & operator = (uint64 a) { m_val = a; extend_sign(); return *this; } sc_int_base & operator = (double a) { m_val = (int_type)a; extend_sign(); return *this; } // arithmetic assignment operators sc_int_base & operator += (int_type v) { m_val += v; extend_sign(); return *this; } sc_int_base & operator -= (int_type v) { m_val -= v; extend_sign(); return *this; } sc_int_base & operator *= (int_type v) { m_val *= v; extend_sign(); return *this; } sc_int_base & operator /= (int_type v) { m_val /= v; extend_sign(); return *this; } sc_int_base & operator %= (int_type v) { m_val %= v; extend_sign(); return *this; } // bitwise assignment operators sc_int_base & operator &= (int_type v) { m_val &= v; extend_sign(); return *this; } sc_int_base & operator |= (int_type v) { m_val |= v; extend_sign(); return *this; } sc_int_base & operator ^= (int_type v) { m_val ^= v; extend_sign(); return *this; } sc_int_base & operator <<= (int_type v) { m_val <<= v; extend_sign(); return *this; } sc_int_base & operator >>= (int_type v) { m_val >>= v; /* no sign extension needed */ return *this; } // prefix and postfix increment and decrement operators sc_int_base & operator ++ () // prefix { ++m_val; extend_sign(); return *this; } const sc_int_base operator ++ (int) // postfix { sc_int_base tmp(*this); ++m_val; extend_sign(); return tmp; } sc_int_base & operator -- () // prefix { --m_val; extend_sign(); return *this; } const sc_int_base operator -- ( int ) // postfix { sc_int_base tmp(*this); --m_val; extend_sign(); return tmp; } // relational operators friend bool operator == (const sc_int_base &a, const sc_int_base &b) { return a.m_val == b.m_val; } friend bool operator != (const sc_int_base &a, const sc_int_base &b) { return a.m_val != b.m_val; } friend bool operator < (const sc_int_base &a, const sc_int_base &b) { return a.m_val < b.m_val; } friend bool operator <= (const sc_int_base &a, const sc_int_base &b) { return a.m_val <= b.m_val; } friend bool operator > (const sc_int_base &a, const sc_int_base &b) { return a.m_val > b.m_val; } friend bool operator >= (const sc_int_base &a, const sc_int_base &b) { return a.m_val >= b.m_val; } // bit selection sc_int_bitref &operator [] (int i); const sc_int_bitref_r &operator [] (int i) const; sc_int_bitref &bit(int i); const sc_int_bitref_r &bit(int i) const; // part selection sc_int_subref &operator () (int left, int right); const sc_int_subref_r &operator () (int left, int right) const; sc_int_subref &range(int left, int right); const sc_int_subref_r &range(int left, int right) const; // bit access, without bounds checking or sign extension bool test(int i) const { return (0 != (m_val & (UINT_ONE << i))); } void set(int i) { m_val |= (UINT_ONE << i); } void set(int i, bool v) { v ? m_val |= (UINT_ONE << i) : m_val &= ~(UINT_ONE << i); } // capacity int length() const { return m_len; } // concatenation support virtual int concat_length(bool* xz_present_p) const { if (xz_present_p) *xz_present_p = false; return length(); } virtual bool concat_get_ctrl( sc_digit* dst_p, int low_i ) const; virtual bool concat_get_data( sc_digit* dst_p, int low_i ) const; virtual uint64 concat_get_uint64() const { if (m_len < 64) return (uint64)(m_val & ~((uint_type) - 1 << m_len)); else return (uint64)m_val; } virtual void concat_set(int64 src, int low_i); virtual void concat_set(const sc_signed &src, int low_i); virtual void concat_set(const sc_unsigned &src, int low_i); virtual void concat_set(uint64 src, int low_i); // reduce methods bool and_reduce() const; bool nand_reduce() const { return !and_reduce(); } bool or_reduce() const; bool nor_reduce() const { return !or_reduce(); } bool xor_reduce() const; bool xnor_reduce() const { return !xor_reduce(); } // implicit conversion to int_type operator int_type() const { return m_val; } // explicit conversions int_type value() const { return operator int_type(); } int to_int() const { return (int)m_val; } unsigned int to_uint() const { return (unsigned int)m_val; } long to_long() const { return (long)m_val; } unsigned long to_ulong() const { return (unsigned long)m_val; } int64 to_int64() const { return (int64)m_val; } uint64 to_uint64() const { return (uint64)m_val; } double to_double() const { return (double)m_val; } long long_low() const { return (long)(m_val & UINT64_32ONES); } long long_high() const { return (long)((m_val >> 32) & UINT64_32ONES); } // explicit conversion to character string const std::string to_string(sc_numrep numrep=SC_DEC) const; const std::string to_string(sc_numrep numrep, bool w_prefix) const; // other methods void print(::std::ostream &os=::std::cout) const { os << to_string(sc_io_base(os, SC_DEC), sc_io_show_base(os)); } void scan(::std::istream &is=::std::cin); protected: int_type m_val; // value int m_len; // length int m_ulen; // unused length }; inline ::std::ostream &operator << (::std::ostream &, const sc_int_base &); inline ::std::istream &operator >> (::std::istream &, sc_int_base &); // ---------------------------------------------------------------------------- // CLASS : sc_int_bitref_r // // Proxy class for sc_int bit selection (r-value only). // ---------------------------------------------------------------------------- // implicit conversion to uint64 inline sc_int_bitref_r::operator uint64 () const { return m_obj_p->test(m_index); } inline bool sc_int_bitref_r::operator ! () const { return ! m_obj_p->test(m_index); } inline bool sc_int_bitref_r::operator ~ () const { return !m_obj_p->test(m_index); } inline ::std::ostream & operator << (::std::ostream &os, const sc_int_bitref_r &a) { a.print(os); return os; } // ---------------------------------------------------------------------------- // CLASS : sc_int_bitref // // Proxy class for sc_int bit selection (r-value and l-value). // ---------------------------------------------------------------------------- // assignment operators inline sc_int_bitref & sc_int_bitref::operator = (const sc_int_bitref_r &b) { m_obj_p->set(m_index, (bool)b); m_obj_p->extend_sign(); return *this; } inline sc_int_bitref & sc_int_bitref::operator = (const sc_int_bitref &b) { m_obj_p->set(m_index, (bool)b); m_obj_p->extend_sign(); return *this; } inline sc_int_bitref & sc_int_bitref::operator = (bool b) { m_obj_p->set(m_index, b); m_obj_p->extend_sign(); return *this; } inline sc_int_bitref & sc_int_bitref::operator &= (bool b) { if (!b) { m_obj_p->set(m_index, b); m_obj_p->extend_sign(); } return *this; } inline sc_int_bitref & sc_int_bitref::operator |= (bool b) { if (b) { m_obj_p->set(m_index, b); m_obj_p->extend_sign(); } return *this; } inline sc_int_bitref & sc_int_bitref::operator ^= (bool b) { if (b) { m_obj_p->m_val ^= (UINT_ONE << m_index); m_obj_p->extend_sign(); } return *this; } inline ::std::istream & operator >> (::std::istream &is, sc_int_bitref &a) { a.scan(is); return is; } // ---------------------------------------------------------------------------- // CLASS : sc_int_subref_r // // Proxy class for sc_int part selection (r-value only). // ---------------------------------------------------------------------------- // implicit conversion to int_type inline sc_int_subref_r::operator uint_type() const { uint_type /*int_type*/ val = m_obj_p->m_val; int uleft = SC_INTWIDTH - (m_left + 1); int uright = uleft + m_right; return (val << uleft >> uright); } // reduce methods inline bool sc_int_subref_r::and_reduce() const { sc_int_base a(*this); return a.and_reduce(); } inline bool sc_int_subref_r::or_reduce() const { sc_int_base a(*this); return a.or_reduce(); } inline bool sc_int_subref_r::xor_reduce() const { sc_int_base a(*this); return a.xor_reduce(); } // explicit conversions inline int sc_int_subref_r::to_int() const { int result = static_cast(operator uint_type()); return result; } inline unsigned int sc_int_subref_r::to_uint() const { unsigned int result = static_cast(operator uint_type()); return result; } inline long sc_int_subref_r::to_long() const { long result = static_cast(operator uint_type()); return result; } inline unsigned long sc_int_subref_r::to_ulong() const { unsigned long result = static_cast(operator uint_type()); return result; } inline int64 sc_int_subref_r::to_int64() const { int64 result = operator uint_type(); return result; } inline uint64 sc_int_subref_r::to_uint64() const { uint64 result = operator uint_type(); return result; } inline double sc_int_subref_r::to_double() const { double result = static_cast(operator uint_type()); return result; } // explicit conversion to character string inline const std::string sc_int_subref_r::to_string(sc_numrep numrep) const { sc_uint_base a(length()); a = operator uint_type(); return a.to_string(numrep); } inline const std::string sc_int_subref_r::to_string(sc_numrep numrep, bool w_prefix) const { sc_uint_base a(length()); a = operator uint_type(); return a.to_string(numrep, w_prefix); } // functional notation for the reduce methods inline bool and_reduce(const sc_int_subref_r &a) { return a.and_reduce(); } inline bool nand_reduce(const sc_int_subref_r &a) { return a.nand_reduce(); } inline bool or_reduce(const sc_int_subref_r &a) { return a.or_reduce(); } inline bool nor_reduce(const sc_int_subref_r &a) { return a.nor_reduce(); } inline bool xor_reduce(const sc_int_subref_r &a) { return a.xor_reduce(); } inline bool xnor_reduce(const sc_int_subref_r &a) { return a.xnor_reduce(); } inline ::std::ostream & operator << (::std::ostream &os, const sc_int_subref_r &a) { a.print(os); return os; } // ---------------------------------------------------------------------------- // CLASS : sc_int_subref // // Proxy class for sc_int part selection (r-value and l-value). // ---------------------------------------------------------------------------- // assignment operators inline sc_int_subref & sc_int_subref::operator = (const sc_int_base &a) { return operator = (a.operator int_type()); } inline sc_int_subref & sc_int_subref::operator = (const char *a) { sc_int_base aa(length()); return (*this = aa = a); } inline ::std::istream & operator >> (::std::istream &is, sc_int_subref &a) { a.scan(is); return is; } // ---------------------------------------------------------------------------- // CLASS : sc_int_base // // Base class for sc_int. // ---------------------------------------------------------------------------- // bit selection inline sc_int_bitref & sc_int_base::operator [] (int i) { check_index(i); sc_int_bitref *result_p = sc_int_bitref::m_pool.allocate(); result_p->initialize(this, i); return *result_p; } inline const sc_int_bitref_r & sc_int_base::operator [] (int i) const { check_index(i); sc_int_bitref *result_p = sc_int_bitref::m_pool.allocate(); result_p->initialize(this, i); return *result_p; } inline sc_int_bitref & sc_int_base::bit(int i) { check_index(i); sc_int_bitref *result_p = sc_int_bitref::m_pool.allocate(); result_p->initialize(this, i); return *result_p; } inline const sc_int_bitref_r & sc_int_base::bit(int i) const { check_index(i); sc_int_bitref *result_p = sc_int_bitref::m_pool.allocate(); result_p->initialize(this, i); return *result_p; } // part selection inline sc_int_subref & sc_int_base::operator () (int left, int right) { check_range(left, right); sc_int_subref *result_p = sc_int_subref::m_pool.allocate(); result_p->initialize(this, left, right); return *result_p; } inline const sc_int_subref_r & sc_int_base::operator () (int left, int right) const { check_range(left, right); sc_int_subref *result_p = sc_int_subref::m_pool.allocate(); result_p->initialize(this, left, right); return *result_p; } inline sc_int_subref & sc_int_base::range(int left, int right) { check_range(left, right); sc_int_subref *result_p = sc_int_subref::m_pool.allocate(); result_p->initialize(this, left, right); return *result_p; } inline const sc_int_subref_r & sc_int_base::range(int left, int right) const { check_range(left, right); sc_int_subref *result_p = sc_int_subref::m_pool.allocate(); result_p->initialize(this, left, right); return *result_p; } // functional notation for the reduce methods inline bool and_reduce(const sc_int_base &a) { return a.and_reduce(); } inline bool nand_reduce(const sc_int_base &a) { return a.nand_reduce(); } inline bool or_reduce(const sc_int_base &a) { return a.or_reduce(); } inline bool nor_reduce(const sc_int_base &a) { return a.nor_reduce(); } inline bool xor_reduce(const sc_int_base &a) { return a.xor_reduce(); } inline bool xnor_reduce(const sc_int_base &a) { return a.xnor_reduce(); } inline ::std::ostream & operator << (::std::ostream &os, const sc_int_base &a) { a.print(os); return os; } inline ::std::istream & operator >> (::std::istream &is, sc_int_base &a) { a.scan(is); return is; } } // namespace sc_dt #endif // __SYSTEMC_EXT_DT_INT_SC_INT_BASE_HH__