/*
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 <atomic>
#include "environment.h"
#include "toplevel.h"
#include "map.h"
#include "state.h"
#include "sstream.h"
#include "exception.h"
#include "lean_operator_info.h"
#include "lean_frontend.h"
#include "lean_notation.h"
#include "lean_pp.h"

namespace lean {
static std::vector<bool> g_empty_vector;
/** \brief Implementation of the Lean frontend */
struct frontend::imp {
    typedef std::pair<std::vector<bool>, name> implicit_info;
    // Remark: only named objects are stored in the dictionary.
    typedef std::unordered_map<name, operator_info, name_hash, name_eq> operator_table;
    typedef std::unordered_map<name, implicit_info, name_hash, name_eq> implicit_table;
    typedef std::unordered_map<expr, operator_info, expr_hash, std::equal_to<expr>> expr_to_operator;
    std::atomic<unsigned> m_num_children;
    std::shared_ptr<imp>  m_parent;
    environment           m_env;
    operator_table        m_nud; // nud table for Pratt's parser
    operator_table        m_led; // led table for Pratt's parser
    expr_to_operator      m_expr_to_operator; // map denotations to operators (this is used for pretty printing)
    implicit_table        m_implicit_table; // track the number of implicit arguments for a symbol.
    state                 m_state;

    bool has_children() const { return m_num_children > 0; }
    void inc_children() { m_num_children++; }
    void dec_children() { m_num_children--; }

    bool has_parent() const { return m_parent != nullptr; }

    /** \brief Return the nud operator for the given symbol. */
    operator_info find_nud(name const & n) const {
        auto it = m_nud.find(n);
        if (it != m_nud.end())
            return it->second;
        else if (has_parent())
            return m_parent->find_nud(n);
        else
            return operator_info();
    }

    /** \brief Return the led operator for the given symbol. */
    operator_info find_led(name const & n) const {
        auto it = m_led.find(n);
        if (it != m_led.end())
            return it->second;
        else if (has_parent())
            return m_parent->find_led(n);
        else
            return operator_info();
    }

    /**
        \brief Return true if the given operator is defined in this
        frontend object (parent frontends are ignored).
    */
    bool defined_here(operator_info const & n, bool led) const {
        if (led)
            return m_led.find(n.get_op_name()) != m_led.end();
        else
            return m_nud.find(n.get_op_name()) != m_nud.end();
    }

    /** \brief Return the led/nud operator for the given symbol. */
    operator_info find_op(name const & n, bool led) const {
        return led ? find_led(n) : find_nud(n);
    }

    /** \brief Insert a new led/nud operator. */
    void insert_op(operator_info const & op, bool led) {
        if (led)
            insert(m_led, op.get_op_name(), op);
        else
            insert(m_nud, op.get_op_name(), op);
    }

    /** \brief Find the operator that is used as notation for the given expression. */
    operator_info find_op_for(expr const & e) const {
        auto it = m_expr_to_operator.find(e);
        if (it != m_expr_to_operator.end())
            return it->second;
        else if (has_parent())
            return m_parent->find_op_for(e);
        else
            return operator_info();
    }

    void diagnostic_msg(char const * msg) {
        // TODO
    }

    void report_op_redefined(operator_info const & old_op, operator_info const & new_op) {
        // TODO
    }

    /** \brief Remove all internal denotations that are associated with the given operator symbol (aka notation) */
    void remove_bindings(operator_info const & op) {
        for (expr const & d : op.get_exprs()) {
            if (has_parent() && m_parent->find_op_for(d)) {
                // parent has an association for d... we must hide it.
                insert(m_expr_to_operator, d, operator_info());
            } else {
                m_expr_to_operator.erase(d);
            }
        }
    }

    /** \brief Register the new operator in the tables for parsing and pretty printing. */
    void register_new_op(operator_info new_op, expr const & d, bool led) {
        new_op.add_expr(d);
        insert_op(new_op, led);
        insert(m_expr_to_operator, d, new_op);
    }

    /**
        \brief Add a new operator and save information as object.

        If the new operator does not conflict with existing operators,
        then we just register it.
        If it conflicts, there are two options:
        1) It is an overload (we just add the internal name \c n as
        new option.
        2) It is a real conflict, and report the issue in the
        diagnostic channel, and override the existing operator (aka notation).
    */
    void add_op(operator_info new_op, expr const & d, bool led) {
        name const & opn = new_op.get_op_name();
        operator_info old_op = find_op(opn, led);
        if (!old_op) {
            register_new_op(new_op, d, led);
        } else if (old_op == new_op) {
            // overload
            if (defined_here(old_op, led)) {
                old_op.add_expr(d);
            } else {
                // we must copy the operator because it was defined in
                // a parent frontend.
                new_op = old_op.copy();
                register_new_op(new_op, d, led);
            }
        } else {
            report_op_redefined(old_op, new_op);
            remove_bindings(old_op);
            register_new_op(new_op, d, led);
        }
        m_env.add_neutral_object(new notation_declaration(new_op, d));
    }

    void add_infix(name const & opn, unsigned p, expr const & d)  { add_op(infix(opn, p), d, true); }
    void add_infixl(name const & opn, unsigned p, expr const & d) { add_op(infixl(opn, p), d, true); }
    void add_infixr(name const & opn, unsigned p, expr const & d) { add_op(infixr(opn, p), d, true); }
    void add_prefix(name const & opn, unsigned p, expr const & d) { add_op(prefix(opn, p), d, false); }
    void add_postfix(name const & opn, unsigned p, expr const & d) { add_op(postfix(opn, p), d, true); }
    void add_mixfixl(unsigned sz, name const * opns, unsigned p, expr const & d) { add_op(mixfixl(sz, opns, p), d, false); }
    void add_mixfixr(unsigned sz, name const * opns, unsigned p, expr const & d) { add_op(mixfixr(sz, opns, p), d, true);  }
    void add_mixfixc(unsigned sz, name const * opns, unsigned p, expr const & d) { add_op(mixfixc(sz, opns, p), d, false); }

    void mark_implicit_arguments(name const & n, unsigned sz, bool const * implicit) {
        if (has_children())
            throw exception(sstream() << "failed to mark implicit arguments, frontend object is read-only");
        object const & obj = m_env.get_object(n);
        if (obj.kind() != object_kind::Definition && obj.kind() != object_kind::Postulate)
            throw exception(sstream() << "failed to mark implicit arguments, the object '" << n << "' is not a definition or postulate");
        if (has_implicit_arguments(n))
            throw exception(sstream() << "the object '" << n << "' already has implicit argument information associated with it");
        name explicit_version(n, "explicit");
        if (m_env.find_object(explicit_version))
            throw exception(sstream() << "failed to mark implicit arguments for '" << n << "', the frontend already has an object named '" << explicit_version << "'");
        expr const & type = obj.get_type();
        unsigned num_args = 0;
        expr it = type;
        while (is_pi(it)) { num_args++; it = abst_body(it); }
        if (sz > num_args)
            throw exception(sstream() << "failed to mark implicit arguments for '" << n << "', object has only " << num_args << " arguments, but trying to mark " << sz << " arguments");
        std::vector<bool> v(implicit, implicit+sz);
        m_implicit_table[n] = mk_pair(v, explicit_version);
        if (obj.is_axiom() || obj.is_theorem()) {
            m_env.add_theorem(explicit_version, type, mk_constant(n));
        } else {
            m_env.add_definition(explicit_version, type, mk_constant(n));
        }
    }

    bool has_implicit_arguments(name const & n) {
        if (m_implicit_table.find(n) != m_implicit_table.end()) {
            return true;
        } else if (has_parent()) {
            return m_parent->has_implicit_arguments(n);
        } else {
            return false;
        }
    }

    std::vector<bool> const & get_implicit_arguments(name const & n) {
        auto it = m_implicit_table.find(n);
        if (it != m_implicit_table.end()) {
            return it->second.first;
        } else if (has_parent()) {
            return m_parent->get_implicit_arguments(n);
        } else {
            return g_empty_vector;
        }
    }

    name const & get_explicit_version(name const & n) {
        auto it = m_implicit_table.find(n);
        if (it != m_implicit_table.end()) {
            return it->second.second;
        } else if (has_parent()) {
            return m_parent->get_explicit_version(n);
        } else {
            return name::anonymous();
        }
    }

    void set_interrupt(bool flag) {
        m_env.set_interrupt(flag);
        m_state.set_interrupt(flag);
    }

    imp(frontend & fe):
        m_num_children(0) {
    }

    explicit imp(std::shared_ptr<imp> const & parent):
        m_num_children(0),
        m_parent(parent),
        m_env(m_parent->m_env.mk_child()),
        m_state(m_parent->m_state) {
        m_parent->inc_children();
    }

    ~imp() {
        if (m_parent)
            m_parent->dec_children();
    }
};

frontend::frontend():m_imp(new imp(*this)) {
    init_builtin_notation(*this);
    init_toplevel(m_imp->m_env);
    m_imp->m_state.set_formatter(mk_pp_formatter(*this));
}
frontend::frontend(imp * new_ptr):m_imp(new_ptr) {
    m_imp->m_state.set_formatter(mk_pp_formatter(*this));
}
frontend::frontend(std::shared_ptr<imp> const & ptr):m_imp(ptr) {}
frontend::~frontend() {}

frontend frontend::mk_child() const { return frontend(new imp(m_imp)); }
bool frontend::has_children() const { return m_imp->has_children(); }
bool frontend::has_parent() const { return m_imp->has_parent(); }
frontend frontend::parent() const { lean_assert(has_parent()); return frontend(m_imp->m_parent); }

environment const & frontend::get_environment() const { return m_imp->m_env; }

level frontend::add_uvar(name const & n, level const & l) { return m_imp->m_env.add_uvar(n, l); }
level frontend::add_uvar(name const & n) { return m_imp->m_env.add_uvar(n); }
level frontend::get_uvar(name const & n) const { return m_imp->m_env.get_uvar(n); }

void frontend::add_definition(name const & n, expr const & t, expr const & v, bool opaque) {
    return m_imp->m_env.add_definition(n, t, v, opaque);
}
void frontend::add_theorem(name const & n, expr const & t, expr const & v) { return m_imp->m_env.add_theorem(n, t, v); }
void frontend::add_definition(name const & n, expr const & v, bool opaque) { return m_imp->m_env.add_definition(n, v, opaque); }
void frontend::add_axiom(name const & n, expr const & t) { return m_imp->m_env.add_axiom(n, t); }
void frontend::add_var(name const & n, expr const & t) { return m_imp->m_env.add_var(n, t); }
object const & frontend::get_object(name const & n) const { return m_imp->m_env.get_object(n); }
object const & frontend::find_object(name const & n) const { return m_imp->m_env.find_object(n); }
bool frontend::has_object(name const & n) const { return m_imp->m_env.has_object(n); }
frontend::object_iterator frontend::begin_objects() const { return m_imp->m_env.begin_objects(); }
frontend::object_iterator frontend::end_objects() const { return m_imp->m_env.end_objects(); }
frontend::object_iterator frontend::begin_local_objects() const { return m_imp->m_env.begin_local_objects(); }
frontend::object_iterator frontend::end_local_objects() const { return m_imp->m_env.end_local_objects(); }

void frontend::add_infix(name const & opn, unsigned p, expr const & d)  { m_imp->add_infix(opn, p, d); }
void frontend::add_infixl(name const & opn, unsigned p, expr const & d)  { m_imp->add_infixl(opn, p, d); }
void frontend::add_infixr(name const & opn, unsigned p, expr const & d)  { m_imp->add_infixr(opn, p, d); }
void frontend::add_prefix(name const & opn, unsigned p, expr const & d)  { m_imp->add_prefix(opn, p, d); }
void frontend::add_postfix(name const & opn, unsigned p, expr const & d) { m_imp->add_postfix(opn, p, d); }
void frontend::add_mixfixl(unsigned sz, name const * opns, unsigned p, expr const & d) { m_imp->add_mixfixl(sz, opns, p, d); }
void frontend::add_mixfixr(unsigned sz, name const * opns, unsigned p, expr const & d) { m_imp->add_mixfixr(sz, opns, p, d); }
void frontend::add_mixfixc(unsigned sz, name const * opns, unsigned p, expr const & d) { m_imp->add_mixfixc(sz, opns, p, d); }
operator_info frontend::find_op_for(expr const & n) const { return m_imp->find_op_for(n); }
operator_info frontend::find_nud(name const & n) const { return m_imp->find_nud(n); }
operator_info frontend::find_led(name const & n) const { return m_imp->find_led(n); }

void frontend::mark_implicit_arguments(name const & n, unsigned sz, bool const * implicit) { m_imp->mark_implicit_arguments(n, sz, implicit); }
void frontend::mark_implicit_arguments(name const & n, std::initializer_list<bool> const & l) { mark_implicit_arguments(n, l.size(), l.begin()); }
bool frontend::has_implicit_arguments(name const & n) const { return m_imp->has_implicit_arguments(n); }
std::vector<bool> const & frontend::get_implicit_arguments(name const & n) const { return m_imp->get_implicit_arguments(n); }
name const & frontend::get_explicit_version(name const & n) const { return m_imp->get_explicit_version(n); }

state const & frontend::get_state() const { return m_imp->m_state; }
state & frontend::get_state_core() { return m_imp->m_state; }
void frontend::set_options(options const & opts) { return m_imp->m_state.set_options(opts); }
void frontend::set_regular_channel(std::shared_ptr<output_channel> const & out) { return m_imp->m_state.set_regular_channel(out); }
void frontend::set_diagnostic_channel(std::shared_ptr<output_channel> const & out) { return m_imp->m_state.set_diagnostic_channel(out); }

void frontend::set_interrupt(bool flag) { m_imp->set_interrupt(flag); }
}