/*++ Copyright (c) 2015 Microsoft Corporation Module Name: scoped_vector.h Abstract: Vector that restores during backtracking. Author: Nikolaj Bjorner (nbjorner) 2015-12-13 Revision History: --*/ #pragma once #include "util/vector.h" template class scoped_vector { unsigned m_size; unsigned m_elems_start; unsigned_vector m_sizes; vector m_elems; unsigned_vector m_elems_lim; unsigned_vector m_index; unsigned_vector m_src, m_dst; unsigned_vector m_src_lim; public: scoped_vector(): m_size(0), m_elems_start(0) {} // m_index : External-Index -> Internal-Index // m_index.size() = max(m_sizes) // m_src[i] -> m_dst[i] // trail into m_index updates // m_src_lim last index to be updated. void push_scope() { m_elems_start = m_elems.size(); m_sizes.push_back(m_size); m_src_lim.push_back(m_src.size()); m_elems_lim.push_back(m_elems_start); } void pop_scope(unsigned num_scopes) { if (num_scopes == 0) return; unsigned new_size = m_sizes.size() - num_scopes; unsigned src_lim = m_src_lim[new_size]; for (unsigned i = m_src.size(); i > src_lim; ) { --i; m_index[m_src[i]] = m_dst[i]; } m_src.shrink(src_lim); m_dst.shrink(src_lim); m_src_lim.shrink(new_size); m_elems.shrink(m_elems_lim[new_size]); m_elems_lim.resize(new_size); m_elems_start = m_elems.size(); m_size = m_sizes[new_size]; m_sizes.shrink(new_size); } T const& operator[](unsigned idx) const { SASSERT(idx < m_size); return m_elems[m_index[idx]]; } // breaks abstraction, caller must ensure backtracking. T& ref(unsigned idx) { SASSERT(idx < m_size); return m_elems[m_index[idx]]; } void set(unsigned idx, T const& t) { SASSERT(idx < m_size); unsigned n = m_index[idx]; if (n >= m_elems_start) { m_elems[n] = t; } else { set_index(idx, m_elems.size()); m_elems.push_back(t); } SASSERT(invariant()); } void set(unsigned idx, T && t) { SASSERT(idx < m_size); unsigned n = m_index[idx]; if (n >= m_elems_start) { m_elems[n] = std::move(t); } else { set_index(idx, m_elems.size()); m_elems.push_back(std::move(t)); } SASSERT(invariant()); } class iterator { scoped_vector const& m_vec; unsigned m_index; public: iterator(scoped_vector const& v, unsigned idx): m_vec(v), m_index(idx) {} bool operator==(iterator const& other) const { return &other.m_vec == &m_vec && other.m_index == m_index; } bool operator!=(iterator const& other) const { return &other.m_vec != &m_vec || other.m_index != m_index; } T const& operator*() { return m_vec[m_index]; } iterator & operator++() { ++m_index; return *this; } iterator operator++(int) { iterator r = *this; ++m_index; return r; } }; iterator begin() const { return iterator(*this, 0); } iterator end() const { return iterator(*this, m_size); } void push_back(T const& t) { set_index(m_size, m_elems.size()); m_elems.push_back(t); ++m_size; SASSERT(invariant()); } void push_back(T && t) { set_index(m_size, m_elems.size()); m_elems.push_back(std::move(t)); ++m_size; SASSERT(invariant()); } void pop_back() { SASSERT(m_size > 0); if (m_index[m_size-1] == m_elems.size()-1 && m_elems.size() > m_elems_start) { m_elems.pop_back(); } --m_size; SASSERT(invariant()); } void erase_and_swap(unsigned i) { if (i + 1 < size()) { auto n = m_elems[m_index[size() - 1]]; set(i, std::move(n)); } pop_back(); } unsigned size() const { return m_size; } bool empty() const { return m_size == 0; } private: void set_index(unsigned src, unsigned dst) { while (src >= m_index.size()) { m_index.push_back(0); } SASSERT(src < m_index.size()); if (src < m_elems_start) { m_src.push_back(src); m_dst.push_back(m_index[src]); } m_index[src] = dst; } bool invariant() const { return m_size <= m_elems.size() && m_elems_start <= m_elems.size(); } };