/* Copyright (c) 2013 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Leonardo de Moura */ #include #include #include "util/buffer.h" #include "util/int64.h" #include "util/memory_pool.h" #include "kernel/justification.h" #include "kernel/metavar.h" #ifndef LEAN_DEFAULT_DEPENDS_ON_CACHE_CAPACITY #define LEAN_DEFAULT_DEPENDS_ON_CACHE_CAPACITY 1024*8 #endif namespace lean { format to_pos(optional const & e, pos_info_provider const * p) { if (!p || !e) return format(); format f = p->pp(*e); if (!f) return format(); return f + space(); } typedef uint64 approx_set; static approx_set mk_empty_set() { return 0; } static approx_set mk_union(approx_set s1, approx_set s2) { return s1 | s2; } static approx_set mk_intersection(approx_set s1, approx_set s2) { return s1 & s2; } static approx_set mk_singleton(unsigned i) { return static_cast(1) << (i % 64); } static approx_set may_contain(approx_set s, unsigned i) { return mk_intersection(s, mk_singleton(i)) != 0ull; } enum class justification_kind { Asserted, Composite, ExtComposite, Assumption, ExtAssumption }; approx_set get_approx_assumption_set(justification const & j); LEAN_THREAD_VALUE(unsigned, g_hash_alloc_jst_counter, 0); struct justification_cell { MK_LEAN_RC(); justification_kind m_kind; unsigned m_hash_alloc; void dealloc(); justification_cell(justification_kind k):m_rc(0), m_kind(k) { m_hash_alloc = g_hash_alloc_jst_counter; g_hash_alloc_jst_counter++; } bool is_asserted() const { return m_kind == justification_kind::Asserted; } bool is_assumption() const { return m_kind == justification_kind::Assumption || m_kind == justification_kind::ExtAssumption; } bool is_composite() const { return m_kind == justification_kind::Composite || m_kind == justification_kind::ExtComposite; } bool is_ext_assumption() const { return m_kind == justification_kind::ExtAssumption; } bool is_ext_composite() const { return m_kind == justification_kind::ExtComposite; } }; struct asserted_cell : public justification_cell { pp_jst_fn m_fn; optional m_expr; asserted_cell(pp_jst_fn const & fn, optional const & e): justification_cell(justification_kind::Asserted), m_fn(fn), m_expr(e) {} }; struct composite_cell : public justification_cell { approx_set m_assumption_set; // approximated set of assumptions contained in child1 and child2 justification m_child[2]; composite_cell(justification_kind k, justification const & j1, justification const & j2): justification_cell(k) { m_child[0] = j1; m_child[1] = j2; m_assumption_set = mk_union(get_approx_assumption_set(j1), get_approx_assumption_set(j2)); } composite_cell(justification const & j1, justification const & j2): composite_cell(justification_kind::Composite, j1, j2) {} }; struct ext_composite_cell : public composite_cell { pp_jst_fn m_fn; optional m_expr; ext_composite_cell(justification const & j1, justification const & j2, pp_jst_fn const & fn, optional const & e): composite_cell(justification_kind::ExtComposite, j1, j2), m_fn(fn), m_expr(e) {} }; struct assumption_cell : public justification_cell { unsigned m_idx; assumption_cell(justification_kind k, unsigned idx): justification_cell(k), m_idx(idx) {} assumption_cell(unsigned idx): assumption_cell(justification_kind::Assumption, idx) {} }; struct ext_assumption_cell : public assumption_cell { pp_jst_fn m_fn; optional m_expr; ext_assumption_cell(unsigned idx, pp_jst_fn const & fn, optional const & e): assumption_cell(justification_kind::ExtAssumption, idx), m_fn(fn), m_expr(e) {} }; asserted_cell * to_asserted(justification_cell * j) { lean_assert(j && j->is_asserted()); return static_cast(j); } assumption_cell * to_assumption(justification_cell * j) { lean_assert(j && j->is_assumption()); return static_cast(j); } ext_assumption_cell * to_ext_assumption(justification_cell * j) { lean_assert(j && j->is_ext_assumption()); return static_cast(j); } composite_cell * to_composite(justification_cell * j) { lean_assert(j && j->is_composite()); return static_cast(j); } ext_composite_cell * to_ext_composite(justification_cell * j) { lean_assert(j && j->is_composite()); return static_cast(j); } approx_set get_approx_assumption_set(justification const & j) { justification_cell * it = j.raw(); if (!it) return mk_empty_set(); switch (it->m_kind) { case justification_kind::Asserted: return mk_empty_set(); case justification_kind::Assumption: case justification_kind::ExtAssumption: return mk_singleton(to_assumption(it)->m_idx); case justification_kind::Composite: case justification_kind::ExtComposite: return to_composite(it)->m_assumption_set; } lean_unreachable(); // LCOV_EXCL_LINE } DEF_THREAD_MEMORY_POOL(get_asserted_allocator, sizeof(asserted_cell)); DEF_THREAD_MEMORY_POOL(get_composite_allocator, sizeof(composite_cell)); DEF_THREAD_MEMORY_POOL(get_ext_composite_allocator, sizeof(ext_composite_cell)); DEF_THREAD_MEMORY_POOL(get_assumption_allocator, sizeof(assumption_cell)); DEF_THREAD_MEMORY_POOL(get_ext_assumption_allocator, sizeof(ext_assumption_cell)); void justification_cell::dealloc() { switch (m_kind) { case justification_kind::Asserted: to_asserted(this)->~asserted_cell(); get_asserted_allocator().recycle(this); break; case justification_kind::Assumption: to_assumption(this)->~assumption_cell(); get_assumption_allocator().recycle(this); break; case justification_kind::ExtAssumption: to_ext_assumption(this)->~ext_assumption_cell(); get_ext_assumption_allocator().recycle(this); break; case justification_kind::Composite: to_composite(this)->~composite_cell(); get_composite_allocator().recycle(this); break; case justification_kind::ExtComposite: to_ext_composite(this)->~ext_composite_cell(); get_ext_composite_allocator().recycle(this); break; } } struct depends_on_cache { unsigned m_capacity; std::vector m_cache; std::vector m_used; depends_on_cache(unsigned c):m_capacity(c), m_cache(c, nullptr) {} bool visited(justification_cell const * j) { unsigned i = j->m_hash_alloc % m_capacity; if (m_cache[i]) { if (m_cache[i] == j) { return true; } else { m_cache[i] = j; return false; } } else { m_cache[i] = j; m_used.push_back(i); return false; } } void clear() { for (unsigned i : m_used) { lean_assert(m_cache[i]); m_cache[i] = nullptr; } m_used.clear(); } }; MK_THREAD_LOCAL_GET(depends_on_cache, get_depends_on_cache, LEAN_DEFAULT_DEPENDS_ON_CACHE_CAPACITY); struct depends_on_cache_ref { depends_on_cache & m_cache; depends_on_cache_ref():m_cache(get_depends_on_cache()) {} ~depends_on_cache_ref() { m_cache.clear(); } depends_on_cache * operator->() { return &m_cache; } }; bool depends_on(justification const & j, unsigned i) { if (!may_contain(get_approx_assumption_set(j), i)) return false; depends_on_cache_ref cache; buffer todo; todo.push_back(j.raw()); while (!todo.empty()) { justification_cell * curr = todo.back(); todo.pop_back(); switch (curr->m_kind) { case justification_kind::Asserted: break; case justification_kind::Assumption: case justification_kind::ExtAssumption: if (to_assumption(curr)->m_idx == i) return true; break; case justification_kind::Composite: case justification_kind::ExtComposite: for (unsigned k = 0; k < 2; k++) { justification c = to_composite(curr)->m_child[k]; if (!cache->visited(c.raw()) && may_contain(get_approx_assumption_set(c), i)) todo.push_back(c.raw()); } } } return false; } justification const & composite_child1(justification const & j) { lean_assert(j.is_composite()); return to_composite(j.raw())->m_child[0]; } justification const & composite_child2(justification const & j) { lean_assert(j.is_composite()); return to_composite(j.raw())->m_child[1]; } unsigned assumption_idx(justification const & j) { lean_assert(j.is_assumption()); return to_assumption(j.raw())->m_idx; } justification::justification():m_ptr(nullptr) {} justification::justification(justification_cell * ptr):m_ptr(ptr) { if (m_ptr) m_ptr->inc_ref(); } justification::justification(justification const & s):m_ptr(s.m_ptr) { if (m_ptr) m_ptr->inc_ref(); } justification::justification(justification && s):m_ptr(s.m_ptr) { s.m_ptr = nullptr; } justification::~justification() { if (m_ptr) m_ptr->dec_ref(); } bool justification::is_none() const { return m_ptr == nullptr; } bool justification::is_asserted() const { return m_ptr && m_ptr->is_asserted(); } bool justification::is_assumption() const { return m_ptr && m_ptr->is_assumption(); } bool justification::is_composite() const { return m_ptr && m_ptr->is_composite(); } justification & justification::operator=(justification const & s) { LEAN_COPY_REF(s); } justification & justification::operator=(justification && s) { LEAN_MOVE_REF(s); } optional justification::get_main_expr() const { justification_cell * it = m_ptr; while (true) { if (!it) return none_expr(); switch (it->m_kind) { case justification_kind::Asserted: return to_asserted(it)->m_expr; case justification_kind::ExtAssumption: return to_ext_assumption(it)->m_expr; case justification_kind::ExtComposite: return to_ext_composite(it)->m_expr; case justification_kind::Assumption: return none_expr(); case justification_kind::Composite: it = to_composite(it)->m_child[0].raw(); break; } } } format justification::pp(formatter const & fmt, pos_info_provider const * p, substitution const & s) const { justification_cell * it = m_ptr; while (true) { if (!it) return format(); switch (it->m_kind) { case justification_kind::Asserted: return to_asserted(it)->m_fn(fmt, p, s); case justification_kind::ExtAssumption: return to_ext_assumption(it)->m_fn(fmt, p, s); case justification_kind::ExtComposite: return to_ext_composite(it)->m_fn(fmt, p, s); case justification_kind::Assumption: return format(format("Assumption "), format(to_assumption(it)->m_idx)); case justification_kind::Composite: it = to_composite(it)->m_child[0].raw(); break; } } } justification mk_composite(justification const & j1, justification const & j2, optional const & s, pp_jst_fn const & fn) { if (j1.is_none()) return j2; if (j2.is_none()) return j1; return justification(new (get_ext_composite_allocator().allocate()) ext_composite_cell(j1, j2, fn, s)); } justification mk_composite1(justification const & j1, justification const & j2) { if (j1.is_none()) return j2; if (j2.is_none()) return j1; return justification(new (get_composite_allocator().allocate()) composite_cell(j1, j2)); } justification mk_assumption_justification(unsigned idx, optional const & s, pp_jst_fn const & fn) { return justification(new (get_ext_assumption_allocator().allocate()) ext_assumption_cell(idx, fn, s)); } justification mk_assumption_justification(unsigned idx) { return justification(new (get_assumption_allocator().allocate()) assumption_cell(idx)); } justification mk_justification(optional const & s, pp_jst_fn const & fn) { return justification(new (get_asserted_allocator().allocate()) asserted_cell(fn, s)); } justification mk_justification(optional const & s, pp_jst_sfn const & fn) { return mk_justification(s, [=](formatter const & fmt, pos_info_provider const *, substitution const & subst) { // Remark: we are not using to_pos(s, p) anymore because we don't try to display complicated error messages anymore. // return compose(to_pos(s, p), fn(fmt, subst)); return fn(fmt, subst); }); } justification mk_justification(char const * msg, optional const & s) { std::string _msg(msg); return mk_justification(s, [=](formatter const &, pos_info_provider const *, substitution const &) { return format(_msg); }); } std::ostream & operator<<(std::ostream & out, justification const & j) { if (j.is_none()) { out << "none"; } else if (j.is_asserted()) { out << "asserted"; } else if (j.is_assumption()) { out << "(assumption " << assumption_idx(j) << ")"; } else if (j.is_composite()) { out << "(join " << composite_child1(j) << " " << composite_child2(j) << ")"; } else { out << "unexpected"; } return out; } }