lean2/src/library/hop_match.cpp

/*
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 "util/optional.h"
#include "util/buffer.h"
#include "kernel/free_vars.h"
#include "kernel/instantiate.h"
#include "library/eq_heq.h"
#include "library/kernel_bindings.h"

namespace lean {

class hop_match_fn {
    buffer<optional<expr>> & m_subst;
    buffer<expr>             m_vars;

    bool is_free_var(expr const & x, unsigned ctx_size) const {
        return is_var(x) && var_idx(x) >= ctx_size;
    }

    bool is_locally_bound(expr const & x, unsigned ctx_size) const {
        return is_var(x) && var_idx(x) < ctx_size;
    }

    optional<expr> get_subst(expr const & x, unsigned ctx_size) const {
        lean_assert(is_free_var(x, ctx_size));
        unsigned vidx = var_idx(x) - ctx_size;
        unsigned sz = m_subst.size();
        if (vidx >= sz)
            throw exception("ill-formed higher-order matching problem");
        return m_subst[sz - vidx - 1];
    }

    bool has_locally_bound_var(expr const & t, unsigned ctx_size) const {
        return has_free_var(t, 0, ctx_size);
    }

    void assign(expr const & p, expr const & t, unsigned ctx_size) {
        lean_assert(is_free_var(p, ctx_size));
        lean_assert(!get_subst(p, ctx_size));
        unsigned vidx = var_idx(p) - ctx_size;
        unsigned sz = m_subst.size();
        m_subst[sz - vidx - 1] = t;
    }

    bool args_are_distinct_locally_bound_vars(expr const & p, unsigned ctx_size, buffer<expr> & vars) {
        lean_assert(is_app(p));
        vars.clear();
        unsigned num = num_args(p);
        for (unsigned i = 1; i < num; i++) {
            expr const & v = arg(p, i);
            if (!is_locally_bound(v, ctx_size))
                return false;
            if (std::find(vars.begin(), vars.end(), v) != vars.end())
                return false;
            vars.push_back(v);
        }
        return true;
    }


    /**
       \brief Return t' when all locally bound variables in \c t occur in vars at positions [0, vars_size).
       The locally bound variables occurring in \c t are replaced using the following mapping:

             vars[vars_size - 1] ==> #0
             ...
             vars[0]             ==> #vars_size - 1

       None is returned if \c t contains a locally bound variable that does not occur in \c vars.
       Remark: vars_size <= vars.size()
     */
    optional<expr> proj_core(expr const & t, unsigned ctx_size, buffer<expr> const & vars, unsigned vars_size) {
        bool failed = false;
        expr r = replace(t, [&](expr const & e, unsigned offset) -> expr {
                if (is_var(e)) {
                    unsigned vidx = var_idx(e);
                    if (vidx < offset)
                        return e;
                    vidx -= offset;
                    if (vidx < ctx_size) {
                        // e is locally bound
                        for (unsigned i = 0; i < vars_size; i++) {
                            if (var_idx(vars[i]) == vidx)
                                return mk_var(offset + vars_size - i - 1);
                        }
                        failed = true;
                        return e;
                    } else if (ctx_size != vars_size) {
                        return mk_var(offset + vidx - ctx_size + vars_size);
                    } else {
                        return e;
                    }
                } else {
                    return e;
                }
            });
        if (failed)
            return none_expr();
        else
            return some_expr(r);
    }

    /**
       \brief Return <tt>(fun (x1 ... xn) t')</tt> if all locally bound variables in \c t occur in vars.
       \c n is the size of \c vars.
       None is returned if \c t contains a locally bound variable that does not occur in \c vars.
    */
    optional<expr> proj(expr const & t, context const & ctx, unsigned ctx_size, buffer<expr> const & vars) {
        optional<expr> t_prime = proj_core(t, ctx_size, vars, vars.size());
        if (!t_prime)
            return none_expr();
        expr r     = *t_prime;
        unsigned i = vars.size();
        while (i > 0) {
            --i;
            unsigned vidx = var_idx(vars[i]);
            auto p = lookup_ext(ctx, vidx);
            context_entry const & entry = p.first;
            context entry_ctx = p.second;
            if (!entry.get_domain())
                return none_expr();
            expr d     = *entry.get_domain();
            optional<expr> new_d = proj_core(d, entry_ctx.size(), vars, i);
            if (!new_d)
                return none_expr();
            r = mk_lambda(entry.get_name(), *new_d, r);
        }
        return some_expr(r);
    }

    bool match(expr const & p, expr const & t, context const & ctx, unsigned ctx_size) {
        lean_assert(ctx.size() == ctx_size);
        if (is_free_var(p, ctx_size)) {
            auto s = get_subst(p, ctx_size);
            if (s) {
                return match(lift_free_vars(*s, ctx_size), t, ctx, ctx_size);
            } else if (has_locally_bound_var(t, ctx_size)) {
                return false;
            } else {
                assign(p, lower_free_vars(t, ctx_size, ctx_size), ctx_size);
                return true;
            }
        } else if (is_app(p) && is_free_var(arg(p, 0), ctx_size)) {
            auto s = get_subst(arg(p, 0), ctx_size);
            unsigned num = num_args(p);
            if (s) {
                expr f     = lift_free_vars(*s, ctx_size);
                expr new_p = apply_beta(f, num - 1, &(arg(p, 1)));
                return match(new_p, t, ctx, ctx_size);
            } else {
                // Check if p is a higher-order pattern.
                // That is, all arguments are distinct locally bound variables
                if (args_are_distinct_locally_bound_vars(p, ctx_size, m_vars)) {
                    optional<expr> new_t = proj(t, ctx, ctx_size, m_vars);
                    if (new_t) {
                        assign(arg(p, 0), *new_t, ctx_size);
                        return true;
                    } else {
                        return false;
                    }
                }
            }
        }

        if (p == t)
            return true;

        if (is_eq_heq(p) && is_eq_heq(t)) {
            expr_pair p1 = eq_heq_args(p);
            expr_pair p2 = eq_heq_args(t);
            return match(p1.first, p2.first, ctx, ctx_size) && match(p1.second, p2.second, ctx, ctx_size);
        } else {
            if (p.kind() != t.kind())
                return false;
            switch (p.kind()) {
            case expr_kind::Var: case expr_kind::Constant: case expr_kind::Type:
            case expr_kind::Value: case expr_kind::MetaVar:
                return false;
            case expr_kind::App: {
                unsigned i1 = num_args(p);
                unsigned i2 = num_args(t);
                while (i1 > 0 && i2 > 0) {
                    --i1;
                    --i2;
                    if (i1 == 0 && i2 > 0) {
                        if (!match(arg(p, i1), mk_app(i2+1, begin_args(t)), ctx, ctx_size))
                            return false;
                    } else if (i2 == 0 && i1 > 0) {
                        if (!match(mk_app(i1+1, begin_args(p)), arg(t, i2), ctx, ctx_size))
                            return false;
                    } else {
                        if (!match(arg(p, i1), arg(t, i2), ctx, ctx_size))
                            return false;
                    }
                }
                return true;
            }
            case expr_kind::HEq:
                lean_unreachable(); break; // LCOV_EXCL_LINE
            case expr_kind::Lambda: case expr_kind::Pi:
                return
                    match(abst_domain(p), abst_domain(t), ctx, ctx_size) &&
                    match(abst_body(p), abst_body(t), extend(ctx, abst_name(t), abst_domain(t)), ctx_size+1);
            case expr_kind::Let:
                // TODO(Leo)
                return false;
            }
        }
        lean_unreachable();
    }
public:
    hop_match_fn(buffer<optional<expr>> & subst):m_subst(subst) {}

    bool operator()(expr const & p, expr const & t) {
        return match(p, t, context(), 0);
    }
};

bool hop_match(expr const & p, expr const & t, buffer<optional<expr>> & subst) {
    return hop_match_fn(subst)(p, t);
}

static int hop_match(lua_State * L) {
    int nargs = lua_gettop(L);
    expr p    = to_expr(L, 1);
    expr t    = to_expr(L, 2);
    int k     = 0;
    if (nargs == 3) {
        k = luaL_checkinteger(L, 3);
        if (k < 0)
            throw exception("hop_match, arg #3 must be non-negative");
    } else {
        k = free_var_range(p);
    }
    buffer<optional<expr>> subst;
    subst.resize(k);
    if (hop_match(p, t, subst)) {
        lua_newtable(L);
        int i = 1;
        for (auto s : subst) {
            if (s) {
                push_expr(L, *s);
            } else {
                lua_pushnil(L);
            }
            lua_rawseti(L, -2, i);
            i = i + 1;
        }
    } else {
        lua_pushnil(L);
    }
    return 1;
}

void open_hop_match(lua_State * L) {
    SET_GLOBAL_FUN(hop_match, "hop_match");
}
}
feat(library): match procedure for higher-order patterns Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-01-13 01:45:24 +00:00			`/*`
			`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 "util/optional.h"`
			`#include "util/buffer.h"`
			`#include "kernel/free_vars.h"`
			`#include "kernel/instantiate.h"`
			`#include "library/eq_heq.h"`
			`#include "library/kernel_bindings.h"`

			`namespace lean {`

			`class hop_match_fn {`
			`buffer<optional<expr>> & m_subst;`
			`buffer<expr> m_vars;`

			`bool is_free_var(expr const & x, unsigned ctx_size) const {`
			`return is_var(x) && var_idx(x) >= ctx_size;`
			`}`

			`bool is_locally_bound(expr const & x, unsigned ctx_size) const {`
			`return is_var(x) && var_idx(x) < ctx_size;`
			`}`

			`optional<expr> get_subst(expr const & x, unsigned ctx_size) const {`
			`lean_assert(is_free_var(x, ctx_size));`
			`unsigned vidx = var_idx(x) - ctx_size;`
			`unsigned sz = m_subst.size();`
			`if (vidx >= sz)`
			`throw exception("ill-formed higher-order matching problem");`
			`return m_subst[sz - vidx - 1];`
			`}`

			`bool has_locally_bound_var(expr const & t, unsigned ctx_size) const {`
			`return has_free_var(t, 0, ctx_size);`
			`}`

			`void assign(expr const & p, expr const & t, unsigned ctx_size) {`
			`lean_assert(is_free_var(p, ctx_size));`
			`lean_assert(!get_subst(p, ctx_size));`
			`unsigned vidx = var_idx(p) - ctx_size;`
			`unsigned sz = m_subst.size();`
fix(library/hop_match): in locally bound variable management Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-01-14 02:06:23 +00:00			`m_subst[sz - vidx - 1] = t;`
feat(library): match procedure for higher-order patterns Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-01-13 01:45:24 +00:00			`}`

			`bool args_are_distinct_locally_bound_vars(expr const & p, unsigned ctx_size, buffer<expr> & vars) {`
			`lean_assert(is_app(p));`
			`vars.clear();`
			`unsigned num = num_args(p);`
			`for (unsigned i = 1; i < num; i++) {`
			`expr const & v = arg(p, i);`
			`if (!is_locally_bound(v, ctx_size))`
			`return false;`
			`if (std::find(vars.begin(), vars.end(), v) != vars.end())`
			`return false;`
			`vars.push_back(v);`
			`}`
			`return true;`
			`}`


			`/**`
			`\brief Return t' when all locally bound variables in \c t occur in vars at positions [0, vars_size).`
			`The locally bound variables occurring in \c t are replaced using the following mapping:`

			`vars[vars_size - 1] ==> #0`
			`...`
			`vars[0] ==> #vars_size - 1`

			`None is returned if \c t contains a locally bound variable that does not occur in \c vars.`
			`Remark: vars_size <= vars.size()`
			`*/`
			`optional<expr> proj_core(expr const & t, unsigned ctx_size, buffer<expr> const & vars, unsigned vars_size) {`
			`bool failed = false;`
			`expr r = replace(t, [&](expr const & e, unsigned offset) -> expr {`
			`if (is_var(e)) {`
			`unsigned vidx = var_idx(e);`
			`if (vidx < offset)`
			`return e;`
			`vidx -= offset;`
			`if (vidx < ctx_size) {`
			`// e is locally bound`
			`for (unsigned i = 0; i < vars_size; i++) {`
			`if (var_idx(vars[i]) == vidx)`
			`return mk_var(offset + vars_size - i - 1);`
			`}`
			`failed = true;`
			`return e;`
			`} else if (ctx_size != vars_size) {`
			`return mk_var(offset + vidx - ctx_size + vars_size);`
			`} else {`
			`return e;`
			`}`
			`} else {`
			`return e;`
			`}`
			`});`
			`if (failed)`
			`return none_expr();`
			`else`
			`return some_expr(r);`
			`}`

			`/**`
			`\brief Return <tt>(fun (x1 ... xn) t')</tt> if all locally bound variables in \c t occur in vars.`
			`\c n is the size of \c vars.`
			`None is returned if \c t contains a locally bound variable that does not occur in \c vars.`
			`*/`
			`optional<expr> proj(expr const & t, context const & ctx, unsigned ctx_size, buffer<expr> const & vars) {`
			`optional<expr> t_prime = proj_core(t, ctx_size, vars, vars.size());`
			`if (!t_prime)`
			`return none_expr();`
			`expr r = *t_prime;`
			`unsigned i = vars.size();`
			`while (i > 0) {`
			`--i;`
			`unsigned vidx = var_idx(vars[i]);`
			`auto p = lookup_ext(ctx, vidx);`
			`context_entry const & entry = p.first;`
			`context entry_ctx = p.second;`
			`if (!entry.get_domain())`
			`return none_expr();`
			`expr d = *entry.get_domain();`
			`optional<expr> new_d = proj_core(d, entry_ctx.size(), vars, i);`
			`if (!new_d)`
			`return none_expr();`
			`r = mk_lambda(entry.get_name(), *new_d, r);`
			`}`
			`return some_expr(r);`
			`}`

			`bool match(expr const & p, expr const & t, context const & ctx, unsigned ctx_size) {`
			`lean_assert(ctx.size() == ctx_size);`
			`if (is_free_var(p, ctx_size)) {`
			`auto s = get_subst(p, ctx_size);`
			`if (s) {`
			`return match(lift_free_vars(*s, ctx_size), t, ctx, ctx_size);`
			`} else if (has_locally_bound_var(t, ctx_size)) {`
			`return false;`
			`} else {`
fix(library/hop_match): in locally bound variable management Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-01-14 02:06:23 +00:00			`assign(p, lower_free_vars(t, ctx_size, ctx_size), ctx_size);`
feat(library): match procedure for higher-order patterns Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2014-01-13 01:45:24 +00:00			`return true;`
			`}`
			`} else if (is_app(p) && is_free_var(arg(p, 0), ctx_size)) {`
			`auto s = get_subst(arg(p, 0), ctx_size);`
			`unsigned num = num_args(p);`
			`if (s) {`
			`expr f = lift_free_vars(*s, ctx_size);`
			`expr new_p = apply_beta(f, num - 1, &(arg(p, 1)));`
			`return match(new_p, t, ctx, ctx_size);`
			`} else {`
			`// Check if p is a higher-order pattern.`
			`// That is, all arguments are distinct locally bound variables`
			`if (args_are_distinct_locally_bound_vars(p, ctx_size, m_vars)) {`
			`optional<expr> new_t = proj(t, ctx, ctx_size, m_vars);`
			`if (new_t) {`
			`assign(arg(p, 0), *new_t, ctx_size);`
			`return true;`
			`} else {`
			`return false;`
			`}`
			`}`
			`}`
			`}`

			`if (p == t)`
			`return true;`

			`if (is_eq_heq(p) && is_eq_heq(t)) {`
			`expr_pair p1 = eq_heq_args(p);`
			`expr_pair p2 = eq_heq_args(t);`
			`return match(p1.first, p2.first, ctx, ctx_size) && match(p1.second, p2.second, ctx, ctx_size);`
			`} else {`
			`if (p.kind() != t.kind())`
			`return false;`
			`switch (p.kind()) {`
			`case expr_kind::Var: case expr_kind::Constant: case expr_kind::Type:`
			`case expr_kind::Value: case expr_kind::MetaVar:`
			`return false;`
			`case expr_kind::App: {`
			`unsigned i1 = num_args(p);`
			`unsigned i2 = num_args(t);`
			`while (i1 > 0 && i2 > 0) {`
			`--i1;`
			`--i2;`
			`if (i1 == 0 && i2 > 0) {`
			`if (!match(arg(p, i1), mk_app(i2+1, begin_args(t)), ctx, ctx_size))`
			`return false;`
			`} else if (i2 == 0 && i1 > 0) {`
			`if (!match(mk_app(i1+1, begin_args(p)), arg(t, i2), ctx, ctx_size))`
			`return false;`
			`} else {`
			`if (!match(arg(p, i1), arg(t, i2), ctx, ctx_size))`
			`return false;`
			`}`
			`}`
			`return true;`
			`}`
			`case expr_kind::HEq:`
			`lean_unreachable(); break; // LCOV_EXCL_LINE`
			`case expr_kind::Lambda: case expr_kind::Pi:`
			`return`
			`match(abst_domain(p), abst_domain(t), ctx, ctx_size) &&`
			`match(abst_body(p), abst_body(t), extend(ctx, abst_name(t), abst_domain(t)), ctx_size+1);`
			`case expr_kind::Let:`
			`// TODO(Leo)`
			`return false;`
			`}`
			`}`
			`lean_unreachable();`
			`}`
			`public:`
			`hop_match_fn(buffer<optional<expr>> & subst):m_subst(subst) {}`

			`bool operator()(expr const & p, expr const & t) {`
			`return match(p, t, context(), 0);`
			`}`
			`};`

			`bool hop_match(expr const & p, expr const & t, buffer<optional<expr>> & subst) {`
			`return hop_match_fn(subst)(p, t);`
			`}`

			`static int hop_match(lua_State * L) {`
			`int nargs = lua_gettop(L);`
			`expr p = to_expr(L, 1);`
			`expr t = to_expr(L, 2);`
			`int k = 0;`
			`if (nargs == 3) {`
			`k = luaL_checkinteger(L, 3);`
			`if (k < 0)`
			`throw exception("hop_match, arg #3 must be non-negative");`
			`} else {`
			`k = free_var_range(p);`
			`}`
			`buffer<optional<expr>> subst;`
			`subst.resize(k);`
			`if (hop_match(p, t, subst)) {`
			`lua_newtable(L);`
			`int i = 1;`
			`for (auto s : subst) {`
			`if (s) {`
			`push_expr(L, *s);`
			`} else {`
			`lua_pushnil(L);`
			`}`
			`lua_rawseti(L, -2, i);`
			`i = i + 1;`
			`}`
			`} else {`
			`lua_pushnil(L);`
			`}`
			`return 1;`
			`}`

			`void open_hop_match(lua_State * L) {`
			`SET_GLOBAL_FUN(hop_match, "hop_match");`
			`}`
			`}`