/*++ Copyright (c) 2011 Microsoft Corporation Module Name: array_rewriter.cpp Abstract: Basic rewriting rules for Arrays. Author: Leonardo (leonardo) 2011-04-06 Notes: --*/ #include"array_rewriter.h" #include"ast_lt.h" #include"ast_pp.h" void array_rewriter::updt_params(params_ref const & p) { m_sort_store = p.get_bool(":sort-store", false); m_expand_select_store = p.get_bool(":expand-select-store", false); } void array_rewriter::get_param_descrs(param_descrs & r) { r.insert(":expand-select-store", CPK_BOOL, "(default: false) replace a (select (store ...) ...) term by an if-then-else term."); r.insert(":sort-store", CPK_BOOL, "(default: false) sort nested stores when the indices are known to be different."); } br_status array_rewriter::mk_app_core(func_decl * f, unsigned num_args, expr * const * args, expr_ref & result) { SASSERT(f->get_family_id() == get_fid()); TRACE("array_rewriter", tout << mk_pp(f, m()) << "\n"; for (unsigned i = 0; i < num_args; ++i) { tout << mk_pp(args[i], m()) << "\n"; }); switch (f->get_decl_kind()) { case OP_SELECT: return mk_select_core(num_args, args, result); case OP_STORE: return mk_store_core(num_args, args, result); case OP_ARRAY_MAP: SASSERT(f->get_num_parameters() == 1); SASSERT(f->get_parameter(0).is_ast()); SASSERT(is_func_decl(f->get_parameter(0).get_ast())); return mk_map_core(to_func_decl(f->get_parameter(0).get_ast()), num_args, args, result); case OP_SET_UNION: return mk_set_union(num_args, args, result); case OP_SET_INTERSECT: return mk_set_intersect(num_args, args, result); case OP_SET_SUBSET: SASSERT(num_args == 2); return mk_set_subset(args[0], args[1], result); case OP_SET_COMPLEMENT: SASSERT(num_args == 1); return mk_set_complement(args[0], result); case OP_SET_DIFFERENCE: SASSERT(num_args == 2); return mk_set_difference(args[0], args[1], result); default: return BR_FAILED; } } // l_true -- all equal // l_false -- at least one disequal // l_undef -- don't know template lbool array_rewriter::compare_args(unsigned num_args, expr * const * args1, expr * const * args2) { for (unsigned i = 0; i < num_args; i++) { if (args1[i] == args2[i]) continue; if (CHECK_DISEQ && m().are_distinct(args1[i], args2[i])) return l_false; return l_undef; } return l_true; } br_status array_rewriter::mk_store_core(unsigned num_args, expr * const * args, expr_ref & result) { SASSERT(num_args >= 3); if (m_util.is_store(args[0])) { lbool r = m_sort_store ? compare_args(num_args - 2, args + 1, to_app(args[0])->get_args() + 1) : compare_args(num_args - 2, args + 1, to_app(args[0])->get_args() + 1); switch (r) { case l_true: { // // store(store(a,i,v),i,w) --> store(a,i,w) // ptr_buffer new_args; new_args.push_back(to_app(args[0])->get_arg(0)); new_args.append(num_args-1, args+1); SASSERT(new_args.size() == num_args); result = m().mk_app(get_fid(), OP_STORE, num_args, new_args.c_ptr()); return BR_DONE; } case l_false: SASSERT(m_sort_store); // // store(store(a,i,v),j,w) -> store(store(a,j,w),i,v) // if i, j are different, lt(i,j) // if (lex_lt(num_args-2, args+1, to_app(args[0])->get_args() + 1)) { ptr_buffer new_args; new_args.push_back(to_app(args[0])->get_arg(0)); new_args.append(num_args-1, args+1); expr * nested_store = m().mk_app(get_fid(), OP_STORE, num_args, new_args.c_ptr()); new_args.reset(); new_args.push_back(nested_store); new_args.append(num_args - 1, to_app(args[0])->get_args() + 1); result = m().mk_app(get_fid(), OP_STORE, num_args, new_args.c_ptr()); return BR_REWRITE2; } break; case l_undef: break; } } // // store(const(v),i,v) --> const(v) // if (m_util.is_const(args[0]) && to_app(args[0])->get_arg(0) == args[num_args-1]) { result = args[0]; return BR_DONE; } expr * v = args[num_args-1]; // // store(a, i, select(a, i)) --> a // if (m_util.is_select(v) && compare_args(num_args-1, args, to_app(v)->get_args())) { result = args[0]; return BR_DONE; } return BR_FAILED; } br_status array_rewriter::mk_select_core(unsigned num_args, expr * const * args, expr_ref & result) { SASSERT(num_args >= 2); if (m_util.is_store(args[0])) { SASSERT(to_app(args[0])->get_num_args() == num_args+1); switch (compare_args(num_args - 1, args+1, to_app(args[0])->get_args()+1)) { case l_true: // select(store(a, I, v), I) --> v result = to_app(args[0])->get_arg(num_args); return BR_DONE; case l_false: { // select(store(a, I, v), J) --> select(a, J) if I != J ptr_buffer new_args; new_args.push_back(to_app(args[0])->get_arg(0)); new_args.append(num_args-1, args+1); result = m().mk_app(get_fid(), OP_SELECT, num_args, new_args.c_ptr()); return BR_REWRITE1; } default: if (m_expand_select_store) { // select(store(a, I, v), J) --> ite(I=J, v, select(a, J)) ptr_buffer new_args; new_args.push_back(to_app(args[0])->get_arg(0)); new_args.append(num_args-1, args+1); expr * sel_a_j = m().mk_app(get_fid(), OP_SELECT, num_args, new_args.c_ptr()); expr * v = to_app(args[0])->get_arg(num_args); ptr_buffer eqs; unsigned num_indices = num_args-1; for (unsigned i = 0; i < num_indices; i++) { eqs.push_back(m().mk_eq(to_app(args[0])->get_arg(i+1), args[i+1])); } if (num_indices == 1) { result = m().mk_ite(eqs[0], v, sel_a_j); return BR_REWRITE2; } else { result = m().mk_ite(m().mk_and(eqs.size(), eqs.c_ptr()), v, sel_a_j); return BR_REWRITE3; } } return BR_FAILED; } } if (m_util.is_const(args[0])) { // select(const(v), I) --> v result = to_app(args[0])->get_arg(0); return BR_DONE; } if (m_util.is_as_array(args[0])) { // select(as-array[f], I) --> f(I) func_decl * f = m_util.get_as_array_func_decl(to_app(args[0])); result = m().mk_app(f, num_args - 1, args + 1); return BR_REWRITE1; } return BR_FAILED; } br_status array_rewriter::mk_map_core(func_decl * f, unsigned num_args, expr * const * args, expr_ref & result) { SASSERT(num_args >= 0); bool is_store0 = m_util.is_store(args[0]); bool is_const0 = m_util.is_const(args[0]); if (num_args == 1) { // // map_f (store a j v) = (store (map_f a) j (f v)) // if (is_store0) { app * store_expr = to_app(args[0]); unsigned num_args = store_expr->get_num_args(); SASSERT(num_args >= 3); expr * a = store_expr->get_arg(0); expr * v = store_expr->get_arg(num_args-1); ptr_buffer new_args; new_args.push_back(m_util.mk_map(f, 1, &a)); // (map_f a) new_args.append(num_args - 2, store_expr->get_args() + 1); // j new_args.push_back(m().mk_app(f, v)); // (f v) result = m().mk_app(get_fid(), OP_STORE, new_args.size(), new_args.c_ptr()); return BR_REWRITE2; } // // map_f (const v) = (const (f v)) // if (is_const0) { expr * fv = m().mk_app(f, to_app(args[0])->get_arg(0)); result = m_util.mk_const_array(m().get_sort(args[0]), fv); return BR_REWRITE2; } return BR_FAILED; } SASSERT(num_args > 1); if (is_store0) { unsigned num_indices = to_app(args[0])->get_num_args() - 2; unsigned i; for (i = 1; i < num_args; i++) { if (!m_util.is_store(args[i])) break; unsigned j; for (j = 1; j < num_indices+1; j++) { if (to_app(args[0])->get_arg(j) != to_app(args[i])->get_arg(j)) break; } if (j < num_indices+1) break; } // // map_f (store a_1 j v_1) ... (store a_n j v_n) --> (store (map_f a_1 ... a_n) j (f v_1 ... v_n)) // if (i == num_args) { ptr_buffer arrays; ptr_buffer values; for (unsigned i = 0; i < num_args; i++) { arrays.push_back(to_app(args[i])->get_arg(0)); values.push_back(to_app(args[i])->get_arg(num_indices+1)); } ptr_buffer new_args; new_args.push_back(m_util.mk_map(f, arrays.size(), arrays.c_ptr())); new_args.append(num_indices, to_app(args[0])->get_args() + 1); new_args.push_back(m().mk_app(f, values.size(), values.c_ptr())); result = m().mk_app(get_fid(), OP_STORE, new_args.size(), new_args.c_ptr()); return BR_REWRITE2; } return BR_FAILED; } if (is_const0) { unsigned i; for (i = 1; i < num_args; i++) { if (!m_util.is_const(args[i])) break; } if (i == num_args) { // // map_f (const v_1) ... (const v_n) = (const (f v_1 ... v_n)) // ptr_buffer values; for (unsigned i = 0; i < num_args; i++) { values.push_back(to_app(args[i])->get_arg(0)); } expr * fv = m().mk_app(f, values.size(), values.c_ptr()); parameter p(m().get_sort(args[0])); result = m().mk_app(get_fid(), OP_CONST_ARRAY, 1, &p, 1, &fv); return BR_REWRITE2; } return BR_FAILED; } return BR_FAILED; } void array_rewriter::mk_store(unsigned num_args, expr * const * args, expr_ref & result) { if (mk_store_core(num_args, args, result) == BR_FAILED) result = m().mk_app(get_fid(), OP_STORE, num_args, args); } void array_rewriter::mk_select(unsigned num_args, expr * const * args, expr_ref & result) { if (mk_select_core(num_args, args, result) == BR_FAILED) result = m().mk_app(get_fid(), OP_SELECT, num_args, args); } void array_rewriter::mk_map(func_decl * f, unsigned num_args, expr * const * args, expr_ref & result) { if (mk_map_core(f, num_args, args, result) == BR_FAILED) result = m_util.mk_map(f, num_args, args); } br_status array_rewriter::mk_set_union(unsigned num_args, expr * const * args, expr_ref & result) { SASSERT(num_args > 0); if (num_args == 1) { result = args[0]; return BR_DONE; } SASSERT(num_args >= 2); br_status r = unsigned2br_status(num_args - 2); result = m_util.mk_map(m().mk_or_decl(), num_args, args); return r; } br_status array_rewriter::mk_set_intersect(unsigned num_args, expr * const * args, expr_ref & result) { SASSERT(num_args > 0); if (num_args == 1) { result = args[0]; return BR_DONE; } SASSERT(num_args >= 2); br_status r = unsigned2br_status(num_args - 2); result = m_util.mk_map(m().mk_and_decl(), num_args, args); return r; } br_status array_rewriter::mk_set_complement(expr * arg, expr_ref & result) { return mk_map_core(m().mk_not_decl(), 1, &arg, result); } br_status array_rewriter::mk_set_difference(expr * arg1, expr * arg2, expr_ref & result) { expr * args[2] = { arg1, m_util.mk_map(m().mk_not_decl(), 1, &arg2) }; result = m_util.mk_map(m().mk_and_decl(), 2, args); return BR_REWRITE2; } br_status array_rewriter::mk_set_subset(expr * arg1, expr * arg2, expr_ref & result) { mk_set_difference(arg1, arg2, result); result = m().mk_eq(result.get(), m_util.mk_empty_set(m().get_sort(arg1))); return BR_REWRITE3; }