2aaa9a5273
Now, we can write Pi (x y : A), R x y -> R y x instead of Pi (x y : A), (R x y) -> (R y x) Signed-off-by: Leonardo de Moura <leonardo@microsoft.com>
573 lines
23 KiB
C++
573 lines
23 KiB
C++
/*
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Copyright (c) 2013 Microsoft Corporation. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Author: Leonardo de Moura
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*/
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#include <vector>
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#include <utility>
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#include <functional>
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#include "util/thread.h"
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#include "util/map.h"
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#include "util/sstream.h"
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#include "util/exception.h"
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#include "util/name_map.h"
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#include "kernel/environment.h"
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#include "kernel/expr_maps.h"
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#include "kernel/expr_sets.h"
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#include "library/expr_pair.h"
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#include "library/expr_pair_maps.h"
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#include "library/io_state.h"
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#include "library/all/all.h"
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#include "frontends/lean/operator_info.h"
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#include "frontends/lean/coercion.h"
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#include "frontends/lean/frontend.h"
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#include "frontends/lean/notation.h"
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#include "frontends/lean/pp.h"
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namespace lean {
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static std::vector<bool> g_empty_vector;
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/**
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\brief Environment extension object for the Lean default frontend.
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*/
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struct lean_extension : public environment_extension {
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typedef std::pair<std::vector<bool>, name> implicit_info;
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// Remark: only named objects are stored in the dictionary.
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typedef name_map<operator_info> operator_table;
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typedef name_map<implicit_info> implicit_table;
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typedef name_map<unsigned> precedence_table;
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typedef expr_struct_map<list<operator_info>> expr_to_operators;
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typedef expr_pair_struct_map<expr> coercion_map;
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typedef expr_struct_map<list<expr_pair>> expr_to_coercions;
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typedef expr_struct_set coercion_set;
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operator_table m_nud; // nud table for Pratt's parser
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operator_table m_led; // led table for Pratt's parser
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// The following table stores the precedence of other operator parts.
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// The m_nud and m_led only map the first part of an operator to its definition.
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precedence_table m_other_lbp;
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expr_to_operators m_expr_to_operators; // map denotations to operators (this is used for pretty printing)
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implicit_table m_implicit_table; // track the number of implicit arguments for a symbol.
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coercion_map m_coercion_map; // mapping from (given_type, expected_type) -> coercion
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coercion_set m_coercion_set; // Set of coercions
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expr_to_coercions m_type_coercions; // mapping type -> list (to-type, function)
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lean_extension const * get_parent() const {
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return environment_extension::get_parent<lean_extension>();
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}
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/** \brief Return the nud operator for the given symbol. */
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operator_info find_nud(name const & n) const {
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auto it = m_nud.find(n);
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if (it != m_nud.end())
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return it->second;
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->find_nud(n);
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else
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return operator_info();
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}
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/** \brief Return the led operator for the given symbol. */
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operator_info find_led(name const & n) const {
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auto it = m_led.find(n);
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if (it != m_led.end())
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return it->second;
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->find_led(n);
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else
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return operator_info();
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}
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optional<unsigned> get_other_lbp(name const & n) const {
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auto it = m_other_lbp.find(n);
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if (it != m_other_lbp.end())
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return some(it->second);
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->get_other_lbp(n);
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else
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return optional<unsigned>();
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}
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/** \brief Return the precedence (aka binding power) of the given name. */
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optional<unsigned> get_lbp(name const & n) const {
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operator_info info = find_led(n);
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if (info)
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return some(info.get_precedence());
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else
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return get_other_lbp(n);
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}
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/**
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\brief Return true if the given operator is defined in this
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frontend object (parent frontends are ignored).
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*/
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bool defined_here(operator_info const & n, bool led) const {
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if (led)
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return m_led.find(n.get_op_name()) != m_led.end();
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else
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return m_nud.find(n.get_op_name()) != m_nud.end();
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}
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/** \brief Return the led/nud operator for the given symbol. */
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operator_info find_op(name const & n, bool led) const {
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return led ? find_led(n) : find_nud(n);
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}
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/** \brief Insert a new led/nud operator. */
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void insert_op(operator_info const & op, bool led) {
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if (led)
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insert(m_led, op.get_op_name(), op);
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else
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insert(m_nud, op.get_op_name(), op);
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}
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/** \brief Find the operator that is used as notation for the given expression. */
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operator_info find_op_for(expr const & e, bool unicode) const {
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auto it = m_expr_to_operators.find(e);
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if (it != m_expr_to_operators.end()) {
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auto l = it->second;
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for (auto op : l) {
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if (unicode || op.is_safe_ascii())
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return op;
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}
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}
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->find_op_for(e, unicode);
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else
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return operator_info();
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}
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/** \brief Remove all internal denotations that are associated with the given operator symbol (aka notation) */
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void remove_bindings(operator_info const & op) {
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lean_extension const * parent = get_parent();
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for (expr const & d : op.get_denotations()) {
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if (parent && parent->find_op_for(d, true)) {
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// parent has an association for d... we must hide it.
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insert(m_expr_to_operators, d, list<operator_info>(operator_info()));
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} else {
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m_expr_to_operators.erase(d);
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}
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}
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}
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/** \brief Add a new entry d -> op in the mapping m_expr_to_operators */
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void insert_expr_to_operator_entry(expr const & d, operator_info const & op) {
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list<operator_info> & l = m_expr_to_operators[d];
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l = cons(op, l);
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}
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void check_precedence(name const & n, unsigned prec, io_state & st) const {
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auto old_prec = get_lbp(n);
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if (old_prec && *old_prec != prec)
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diagnostic(st) << "The precedence of '" << n << "' changed from " << *old_prec << " to " << prec << ".\n";
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}
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/** \brief Register the new operator in the tables for parsing and pretty printing. */
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void register_new_op(operator_info new_op, expr const & d, bool led, io_state & st) {
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new_op.add_expr(d);
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insert_op(new_op, led);
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insert_expr_to_operator_entry(d, new_op);
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auto parts = new_op.get_op_name_parts();
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auto prec = new_op.get_precedence();
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if (led)
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check_precedence(head(parts), prec, st);
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for (name const & part : tail(parts)) {
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check_precedence(part, prec, st);
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m_other_lbp[part] = prec;
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}
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}
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/**
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\brief Two operator (aka notation) denotations are compatible
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iff after ignoring all implicit arguments in the prefix and
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explicit arguments in the suffix, the remaining implicit arguments
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occur in the same positions.
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Let us denote implicit arguments with a '_' and explicit with a '*'.
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Then a denotation can be associated with a pattern containing one or more
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'_' and '*'.
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Two denotations are compatible, if we have the same pattern after
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removed the '_' from the prefix and '*' from the suffix.
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Here is an example of compatible denotations
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f : Int -> Int -> Int Pattern * *
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g : Pi {A : Type}, A -> A -> A Pattern _ * *
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h : Pi {A B : Type}, A -> B -> A Pattern _ _ * *
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They are compatible, because after we remove the _ from the prefix, and * from the suffix,
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all of them reduce to the empty sequence
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Here is another example of compatible denotations:
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f : Pi {A : Type} (a : A) {B : Type} (b : B), A Pattern _ * _ *
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g : Pi (i : Int) {T : Type} (x : T), T Pattern * _ *
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They are compatible, because after we remove the _ from the prefix, and * from the suffix,
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we get the same sequence: * _
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The following two are not compatible
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f : Pi {A : Type} (a : A) {B : Type} (b : B), A Pattern _ * _ *
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g : Pi {A B : Type} (a : A) (b : B), A Pattern _ _ * *
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Remark: we remove the explicit suffix at mark_implicit_arguments.
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*/
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bool compatible_denotation(expr const & d1, expr const & d2) {
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auto imp1 = get_implicit_arguments(d1);
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auto imp2 = get_implicit_arguments(d2);
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auto it1 = std::find(imp1.begin(), imp1.end(), false);
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auto it2 = std::find(imp2.begin(), imp2.end(), false);
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for (; it1 != imp1.end() && it2 != imp2.end() && *it1 == *it2; ++it1, ++it2) {}
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return it1 == imp1.end() && it2 == imp2.end();
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}
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/**
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\brief Return true iff the existing denotations (aka
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overloads) for an operator op are compatible with the new
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denotation d.
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The compatibility is only an issue if implicit arguments are
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used. If one of the denotations has implicit arguments, then
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all of them should have implicit arguments, and the implicit
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arguments should occur in the same positions.
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*/
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bool compatible_denotations(operator_info const & op, expr const & d) {
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return std::all_of(op.get_denotations().begin(), op.get_denotations().end(), [&](expr const & prev_d) { return compatible_denotation(prev_d, d); });
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}
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/**
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\brief Add a new operator and save information as object.
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If the new operator does not conflict with existing operators,
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then we just register it.
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If it conflicts, there are two options:
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1) It is an overload (we just add the internal name \c n as
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new option.
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2) It is a real conflict, and report the issue in the
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diagnostic channel, and override the existing operator (aka notation).
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*/
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void add_op(operator_info new_op, expr const & d, bool led, environment const & env, io_state & st) {
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name const & opn = new_op.get_op_name();
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operator_info old_op = find_op(opn, led);
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if (!old_op) {
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register_new_op(new_op, d, led, st);
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} else if (old_op == new_op) {
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if (compatible_denotations(old_op, d)) {
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// overload
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if (defined_here(old_op, led)) {
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old_op.add_expr(d);
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insert_expr_to_operator_entry(d, old_op);
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} else {
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// we must copy the operator because it was defined in
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// a parent frontend.
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new_op = old_op.copy();
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register_new_op(new_op, d, led, st);
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}
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} else {
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diagnostic(st) << "The denotation(s) for the existing notation:\n " << old_op
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<< "\nhave been replaced with the new denotation:\n " << d
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<< "\nbecause they conflict on how implicit arguments are used.\n";
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remove_bindings(old_op);
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register_new_op(new_op, d, led, st);
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}
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} else {
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diagnostic(st) << "Notation has been redefined, the existing notation:\n " << old_op
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<< "\nhas been replaced with:\n " << new_op << "\nbecause they conflict with each other.\n";
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remove_bindings(old_op);
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register_new_op(new_op, d, led, st);
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}
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env->add_neutral_object(new notation_declaration(new_op, d));
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}
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expr mk_explicit_definition_body(expr type, name const & n, unsigned i, unsigned sz) {
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if (i == sz) {
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buffer<expr> args;
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args.push_back(mk_constant(n));
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unsigned j = sz;
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while (j > 0) { --j; args.push_back(mk_var(j)); }
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return mk_app(args);
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} else {
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lean_assert(is_pi(type));
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return mk_lambda(abst_name(type), abst_domain(type), mk_explicit_definition_body(abst_body(type), n, i+1, sz));
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}
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}
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void mark_implicit_arguments(name const & n, unsigned sz, bool const * implicit, environment const & env) {
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if (env->has_children())
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throw exception(sstream() << "failed to mark implicit arguments, frontend object is read-only");
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object const & obj = env->get_object(n);
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if (obj.kind() != object_kind::Definition && obj.kind() != object_kind::Postulate && obj.kind() != object_kind::Builtin)
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throw exception(sstream() << "failed to mark implicit arguments, the object '" << n << "' is not a definition or postulate");
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if (has_implicit_arguments(n))
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throw exception(sstream() << "the object '" << n << "' already has implicit argument information associated with it");
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name explicit_version(n, "explicit");
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if (env->find_object(explicit_version))
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throw exception(sstream() << "failed to mark implicit arguments for '" << n << "', the frontend already has an object named '" << explicit_version << "'");
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expr const & type = obj.get_type();
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unsigned num_args = 0;
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expr it = type;
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while (is_pi(it)) { num_args++; it = abst_body(it); }
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if (sz > num_args)
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throw exception(sstream() << "failed to mark implicit arguments for '" << n << "', object has only " << num_args << " arguments, but trying to mark " << sz << " arguments");
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// remove explicit suffix
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while (sz > 0 && !implicit[sz - 1]) sz--;
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if (sz == 0)
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throw exception(sstream() << "failed to mark implicit arguments for '" << n << "', all arguments are explicit");
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std::vector<bool> v(implicit, implicit+sz);
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m_implicit_table[n] = mk_pair(v, explicit_version);
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expr body = mk_explicit_definition_body(type, n, 0, num_args);
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if (obj.is_axiom() || obj.is_theorem()) {
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env->add_theorem(explicit_version, type, body);
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} else {
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env->add_definition(explicit_version, type, body);
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}
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}
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bool has_implicit_arguments(name const & n) const {
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if (m_implicit_table.find(n) != m_implicit_table.end())
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return true;
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->has_implicit_arguments(n);
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else
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return false;
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}
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std::vector<bool> const & get_implicit_arguments(name const & n) const {
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auto it = m_implicit_table.find(n);
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if (it != m_implicit_table.end())
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return it->second.first;
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->get_implicit_arguments(n);
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else
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return g_empty_vector;
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}
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std::vector<bool> const & get_implicit_arguments(expr const & n) const {
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if (is_constant(n))
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return get_implicit_arguments(const_name(n));
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else
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return g_empty_vector;
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}
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name const & get_explicit_version(name const & n) const {
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auto it = m_implicit_table.find(n);
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if (it != m_implicit_table.end())
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return it->second.second;
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->get_explicit_version(n);
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else
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return name::anonymous();
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}
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bool is_explicit(name const & n) const {
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return !n.is_atomic() && get_explicit_version(n.get_prefix()) == n;
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}
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void add_coercion(expr const & f, environment const & env) {
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expr type = env->infer_type(f);
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expr norm_type = env->normalize(type);
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if (!is_arrow(norm_type))
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throw exception("invalid coercion declaration, a coercion must have an arrow type (i.e., a non-dependent functional type)");
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expr from = abst_domain(norm_type);
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expr to = abst_body(norm_type);
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if (from == to)
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throw exception("invalid coercion declaration, 'from' and 'to' types are the same");
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if (get_coercion(from, to))
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throw exception("invalid coercion declaration, frontend already has a coercion for the given types");
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m_coercion_map[expr_pair(from, to)] = f;
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m_coercion_set.insert(f);
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list<expr_pair> l = get_coercions(from);
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insert(m_type_coercions, from, cons(expr_pair(to, f), l));
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env->add_neutral_object(new coercion_declaration(f));
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}
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optional<expr> get_coercion(expr const & from_type, expr const & to_type) const {
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expr_pair p(from_type, to_type);
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auto it = m_coercion_map.find(p);
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if (it != m_coercion_map.end())
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return some_expr(it->second);
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->get_coercion(from_type, to_type);
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else
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return none_expr();
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}
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list<expr_pair> get_coercions(expr const & from_type) const {
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auto r = m_type_coercions.find(from_type);
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if (r != m_type_coercions.end())
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return r->second;
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lean_extension const * parent = get_parent();
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if (parent)
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return parent->get_coercions(from_type);
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else
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return list<expr_pair>();
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}
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bool is_coercion(expr const & f) const {
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if (m_coercion_set.find(f) != m_coercion_set.end())
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return true;
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lean_extension const * parent = get_parent();
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return parent && parent->is_coercion(f);
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}
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};
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struct lean_extension_initializer {
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unsigned m_extid;
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lean_extension_initializer() {
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m_extid = environment_cell::register_extension([](){ return std::unique_ptr<environment_extension>(new lean_extension()); });
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}
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};
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static lean_extension_initializer g_lean_extension_initializer;
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static lean_extension const & to_ext(ro_environment const & env) {
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return env->get_extension<lean_extension>(g_lean_extension_initializer.m_extid);
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}
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static lean_extension & to_ext(environment const & env) {
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return env->get_extension<lean_extension>(g_lean_extension_initializer.m_extid);
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}
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bool is_explicit(ro_environment const & env, name const & n) {
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return to_ext(env).is_explicit(n);
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}
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bool has_implicit_arguments(ro_environment const & env, name const & n) {
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return to_ext(env).has_implicit_arguments(n);
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}
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name const & get_explicit_version(ro_environment const & env, name const & n) {
|
|
return to_ext(env).get_explicit_version(n);
|
|
}
|
|
|
|
std::vector<bool> const & get_implicit_arguments(ro_environment const & env, name const & n) {
|
|
return to_ext(env).get_implicit_arguments(n);
|
|
}
|
|
|
|
bool is_coercion(ro_environment const & env, expr const & f) {
|
|
return to_ext(env).is_coercion(f);
|
|
}
|
|
|
|
operator_info find_op_for(ro_environment const & env, expr const & n, bool unicode) {
|
|
operator_info r = to_ext(env).find_op_for(n, unicode);
|
|
if (r || !is_constant(n)) {
|
|
return r;
|
|
} else {
|
|
optional<object> obj = env->find_object(const_name(n));
|
|
if (obj && obj->is_builtin() && obj->get_name() == const_name(n))
|
|
return to_ext(env).find_op_for(obj->get_value(), unicode);
|
|
else
|
|
return r;
|
|
}
|
|
}
|
|
|
|
frontend::frontend() {
|
|
m_state.set_formatter(mk_pp_formatter(m_env));
|
|
import_all(m_env);
|
|
init_builtin_notation(*this);
|
|
}
|
|
frontend::frontend(environment const & env, io_state const & s):m_env(env), m_state(s) {
|
|
import_all(m_env);
|
|
init_builtin_notation(*this);
|
|
}
|
|
|
|
void frontend::add_infix(name const & opn, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(infix(opn, p), d, true, m_env, m_state);
|
|
}
|
|
void frontend::add_infixl(name const & opn, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(infixl(opn, p), d, true, m_env, m_state);
|
|
}
|
|
void frontend::add_infixr(name const & opn, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(infixr(opn, p), d, true, m_env, m_state);
|
|
}
|
|
void frontend::add_prefix(name const & opn, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(prefix(opn, p), d, false, m_env, m_state);
|
|
}
|
|
void frontend::add_postfix(name const & opn, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(postfix(opn, p), d, true, m_env, m_state);
|
|
}
|
|
void frontend::add_mixfixl(unsigned sz, name const * opns, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(mixfixl(sz, opns, p), d, false, m_env, m_state);
|
|
}
|
|
void frontend::add_mixfixr(unsigned sz, name const * opns, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(mixfixr(sz, opns, p), d, true, m_env, m_state);
|
|
}
|
|
void frontend::add_mixfixc(unsigned sz, name const * opns, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(mixfixc(sz, opns, p), d, false, m_env, m_state);
|
|
}
|
|
void frontend::add_mixfixo(unsigned sz, name const * opns, unsigned p, expr const & d) {
|
|
to_ext(m_env).add_op(mixfixo(sz, opns, p), d, true, m_env, m_state);
|
|
}
|
|
operator_info frontend::find_op_for(expr const & n, bool unicode) const {
|
|
return ::lean::find_op_for(m_env, n, unicode);
|
|
}
|
|
operator_info frontend::find_nud(name const & n) const {
|
|
return to_ext(m_env).find_nud(n);
|
|
}
|
|
operator_info frontend::find_led(name const & n) const {
|
|
return to_ext(m_env).find_led(n);
|
|
}
|
|
optional<unsigned> frontend::get_lbp(name const & n) const {
|
|
return to_ext(m_env).get_lbp(n);
|
|
}
|
|
void frontend::mark_implicit_arguments(name const & n, unsigned sz, bool const * implicit) {
|
|
to_ext(m_env).mark_implicit_arguments(n, sz, implicit, m_env);
|
|
}
|
|
void frontend::mark_implicit_arguments(name const & n, unsigned prefix_sz) {
|
|
buffer<bool> implicit; implicit.resize(prefix_sz, true);
|
|
mark_implicit_arguments(n, implicit.size(), implicit.data());
|
|
}
|
|
void frontend::mark_implicit_arguments(expr const & n, unsigned prefix_sz) {
|
|
if (is_constant(n)) {
|
|
mark_implicit_arguments(const_name(n), prefix_sz);
|
|
} else {
|
|
lean_assert(is_value(n));
|
|
mark_implicit_arguments(to_value(n).get_name(), prefix_sz);
|
|
}
|
|
}
|
|
void frontend::mark_implicit_arguments(name const & n, std::initializer_list<bool> const & l) {
|
|
mark_implicit_arguments(n, l.size(), l.begin());
|
|
}
|
|
void frontend::mark_implicit_arguments(expr const & n, std::initializer_list<bool> const & l) {
|
|
if (is_constant(n)) {
|
|
mark_implicit_arguments(const_name(n), l);
|
|
} else {
|
|
lean_assert(is_value(n));
|
|
mark_implicit_arguments(to_value(n).get_name(), l);
|
|
}
|
|
}
|
|
bool frontend::has_implicit_arguments(name const & n) const {
|
|
return to_ext(m_env).has_implicit_arguments(n);
|
|
}
|
|
std::vector<bool> const & frontend::get_implicit_arguments(name const & n) const {
|
|
return to_ext(m_env).get_implicit_arguments(n);
|
|
}
|
|
std::vector<bool> const & frontend::get_implicit_arguments(expr const & n) const {
|
|
if (is_constant(n))
|
|
return get_implicit_arguments(const_name(n));
|
|
else
|
|
return g_empty_vector;
|
|
}
|
|
name const & frontend::get_explicit_version(name const & n) const {
|
|
return to_ext(m_env).get_explicit_version(n);
|
|
}
|
|
bool frontend::is_explicit(name const & n) const {
|
|
return to_ext(m_env).is_explicit(n);
|
|
}
|
|
void frontend::add_coercion(expr const & f) {
|
|
to_ext(m_env).add_coercion(f, m_env);
|
|
}
|
|
optional<expr> frontend::get_coercion(expr const & from_type, expr const & to_type) const {
|
|
return to_ext(m_env).get_coercion(from_type, to_type);
|
|
}
|
|
list<expr_pair> frontend::get_coercions(expr const & from_type) const {
|
|
return to_ext(m_env).get_coercions(from_type);
|
|
}
|
|
bool frontend::is_coercion(expr const & f) const {
|
|
return to_ext(m_env).is_coercion(f);
|
|
}
|
|
}
|