rust/src/rustc/middle/borrowck/categorization.rs

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/*!
* # Categorization
*
* The job of the categorization module is to analyze an expression to
* determine what kind of memory is used in evaluating it (for example,
* where dereferences occur and what kind of pointer is dereferenced;
* whether the memory is mutable; etc)
*
* Categorization effectively transforms all of our expressions into
* expressions of the following forms (the actual enum has many more
* possibilities, naturally, but they are all variants of these base
* forms):
*
* E = rvalue // some computed rvalue
* | x // address of a local variable, arg, or upvar
* | *E // deref of a ptr
* | E.comp // access to an interior component
*
* Imagine a routine ToAddr(Expr) that evaluates an expression and returns an
* address where the result is to be found. If Expr is an lvalue, then this
* is the address of the lvalue. If Expr is an rvalue, this is the address of
* some temporary spot in memory where the result is stored.
*
* Now, cat_expr() classies the expression Expr and the address A=ToAddr(Expr)
* as follows:
*
* - cat: what kind of expression was this? This is a subset of the
* full expression forms which only includes those that we care about
* for the purpose of the analysis.
* - mutbl: mutability of the address A
* - ty: the type of data found at the address A
*
* The resulting categorization tree differs somewhat from the expressions
* themselves. For example, auto-derefs are explicit. Also, an index a[b] is
* decomposed into two operations: a derefence to reach the array data and
* then an index to jump forward to the relevant item.
*/
export public_methods;
export opt_deref_kind;
// Categorizes a derefable type. Note that we include vectors and strings as
// derefable (we model an index as the combination of a deref and then a
// pointer adjustment).
fn opt_deref_kind(t: ty::t) -> option<deref_kind> {
alt ty::get(t).struct {
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ty::ty_uniq(*) |
ty::ty_evec(_, ty::vstore_uniq) |
ty::ty_estr(ty::vstore_uniq) {
some(deref_ptr(uniq_ptr))
}
ty::ty_rptr(*) |
ty::ty_evec(_, ty::vstore_slice(_)) |
ty::ty_estr(ty::vstore_slice(_)) {
some(deref_ptr(region_ptr))
}
ty::ty_box(*) |
ty::ty_evec(_, ty::vstore_box) |
ty::ty_estr(ty::vstore_box) {
some(deref_ptr(gc_ptr))
}
ty::ty_ptr(*) {
some(deref_ptr(unsafe_ptr))
}
ty::ty_enum(did, _) {
some(deref_comp(comp_variant(did)))
}
ty::ty_evec(mt, ty::vstore_fixed(_)) {
some(deref_comp(comp_index(t, mt.mutbl)))
}
ty::ty_estr(ty::vstore_fixed(_)) {
some(deref_comp(comp_index(t, m_imm)))
}
_ {
none
}
}
}
fn deref_kind(tcx: ty::ctxt, t: ty::t) -> deref_kind {
alt opt_deref_kind(t) {
some(k) {k}
none {
tcx.sess.bug(
#fmt["deref_cat() invoked on non-derefable type %s",
ty_to_str(tcx, t)]);
}
}
}
impl public_methods for borrowck_ctxt {
fn cat_borrow_of_expr(expr: @ast::expr) -> cmt {
// a borrowed expression must be either an @, ~, or a @vec, ~vec
let expr_ty = ty::expr_ty(self.tcx, expr);
alt ty::get(expr_ty).struct {
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ty::ty_evec(*) | ty::ty_estr(*) {
self.cat_index(expr, expr)
}
ty::ty_uniq(*) | ty::ty_box(*) | ty::ty_rptr(*) {
let cmt = self.cat_expr(expr);
self.cat_deref(expr, cmt, 0u, true).get()
}
/*
ty::ty_fn({proto, _}) {
self.cat_call(expr, expr, proto)
}
*/
_ {
self.tcx.sess.span_bug(
expr.span,
#fmt["Borrowing of non-derefable type `%s`",
ty_to_str(self.tcx, expr_ty)]);
}
}
}
fn cat_expr(expr: @ast::expr) -> cmt {
#debug["cat_expr: id=%d expr=%s",
expr.id, pprust::expr_to_str(expr)];
let tcx = self.tcx;
let expr_ty = tcx.ty(expr);
alt expr.node {
ast::expr_unary(ast::deref, e_base) {
if self.method_map.contains_key(expr.id) {
ret self.cat_rvalue(expr, expr_ty);
}
let base_cmt = self.cat_expr(e_base);
alt self.cat_deref(expr, base_cmt, 0u, true) {
some(cmt) { ret cmt; }
none {
tcx.sess.span_bug(
e_base.span,
#fmt["Explicit deref of non-derefable type `%s`",
ty_to_str(tcx, tcx.ty(e_base))]);
}
}
}
ast::expr_field(base, f_name, _) {
if self.method_map.contains_key(expr.id) {
ret self.cat_method_ref(expr, expr_ty);
}
let base_cmt = self.cat_autoderef(base);
self.cat_field(expr, base_cmt, f_name)
}
ast::expr_index(base, _) {
if self.method_map.contains_key(expr.id) {
ret self.cat_rvalue(expr, expr_ty);
}
self.cat_index(expr, base)
}
ast::expr_path(_) {
let def = self.tcx.def_map.get(expr.id);
self.cat_def(expr.id, expr.span, expr_ty, def)
}
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ast::expr_addr_of(*) | ast::expr_call(*) |
ast::expr_swap(*) | ast::expr_move(*) | ast::expr_assign(*) |
ast::expr_assign_op(*) | ast::expr_fn(*) | ast::expr_fn_block(*) |
ast::expr_assert(*) | ast::expr_ret(*) |
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ast::expr_loop_body(*) | ast::expr_do_body(*) | ast::expr_unary(*) |
ast::expr_copy(*) | ast::expr_cast(*) | ast::expr_fail(*) |
ast::expr_vstore(*) | ast::expr_vec(*) | ast::expr_tup(*) |
ast::expr_if(*) | ast::expr_log(*) |
ast::expr_new(*) | ast::expr_binary(*) | ast::expr_while(*) |
ast::expr_block(*) | ast::expr_loop(*) | ast::expr_alt(*) |
ast::expr_lit(*) | ast::expr_break | ast::expr_mac(*) |
ast::expr_again | ast::expr_rec(*) | ast::expr_struct(*) {
ret self.cat_rvalue(expr, expr_ty);
}
}
}
fn cat_def(id: ast::node_id,
span: span,
expr_ty: ty::t,
def: ast::def) -> cmt {
alt def {
ast::def_fn(*) | ast::def_mod(_) |
ast::def_foreign_mod(_) | ast::def_const(_) |
ast::def_use(_) | ast::def_variant(*) |
ast::def_ty(_) | ast::def_prim_ty(_) |
ast::def_ty_param(*) | ast::def_class(*) |
ast::def_typaram_binder(*) | ast::def_region(_) {
@{id:id, span:span,
cat:cat_special(sk_static_item), lp:none,
mutbl:m_imm, ty:expr_ty}
}
ast::def_arg(vid, mode) {
// Idea: make this could be rewritten to model by-ref
// stuff as `&const` and `&mut`?
// m: mutability of the argument
// lp: loan path, must be none for aliasable things
let {m,lp} = alt ty::resolved_mode(self.tcx, mode) {
ast::by_mutbl_ref {
{m: m_mutbl, lp: none}
}
ast::by_move | ast::by_copy {
{m: m_imm, lp: some(@lp_arg(vid))}
}
ast::by_ref {
{m: m_imm, lp: none}
}
ast::by_val {
// by-value is this hybrid mode where we have a
// pointer but we do not own it. This is not
// considered loanable because, for example, a by-ref
// and and by-val argument might both actually contain
// the same unique ptr.
{m: m_imm, lp: none}
}
};
@{id:id, span:span,
cat:cat_arg(vid), lp:lp,
mutbl:m, ty:expr_ty}
}
ast::def_self(_) {
@{id:id, span:span,
cat:cat_special(sk_self), lp:none,
mutbl:m_imm, ty:expr_ty}
}
ast::def_upvar(upvid, inner, fn_node_id) {
let ty = ty::node_id_to_type(self.tcx, fn_node_id);
let proto = ty::ty_fn_proto(ty);
alt proto {
ast::proto_any | ast::proto_block {
let upcmt = self.cat_def(id, span, expr_ty, *inner);
@{id:id, span:span,
cat:cat_stack_upvar(upcmt), lp:upcmt.lp,
mutbl:upcmt.mutbl, ty:upcmt.ty}
}
ast::proto_bare | ast::proto_uniq | ast::proto_box {
// FIXME #2152 allow mutation of moved upvars
@{id:id, span:span,
cat:cat_special(sk_heap_upvar), lp:none,
mutbl:m_imm, ty:expr_ty}
}
}
}
ast::def_local(vid, mutbl) {
let m = if mutbl {m_mutbl} else {m_imm};
@{id:id, span:span,
cat:cat_local(vid), lp:some(@lp_local(vid)),
mutbl:m, ty:expr_ty}
}
ast::def_binding(pid) {
// bindings are "special" since they are implicit pointers.
// lookup the mutability for this binding that we found in
// gather_loans when we categorized it
let mutbl = self.binding_map.get(pid);
@{id:id, span:span,
cat:cat_binding(pid), lp:none,
mutbl:mutbl, ty:expr_ty}
}
}
}
fn cat_variant<N: ast_node>(arg: N,
enum_did: ast::def_id,
cmt: cmt) -> cmt {
@{id: arg.id(), span: arg.span(),
cat: cat_comp(cmt, comp_variant(enum_did)),
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lp: cmt.lp.map(|l| @lp_comp(l, comp_variant(enum_did)) ),
mutbl: cmt.mutbl, // imm iff in an immutable context
ty: self.tcx.ty(arg)}
}
fn cat_rvalue(expr: @ast::expr, expr_ty: ty::t) -> cmt {
@{id:expr.id, span:expr.span,
cat:cat_rvalue, lp:none,
mutbl:m_imm, ty:expr_ty}
}
fn cat_discr(cmt: cmt, alt_id: ast::node_id) -> cmt {
ret @{cat:cat_discr(cmt, alt_id) with *cmt};
}
/// inherited mutability: used in cases where the mutability of a
/// component is inherited from the base it is a part of. For
/// example, a record field is mutable if it is declared mutable
/// or if the container is mutable.
fn inherited_mutability(base_m: ast::mutability,
comp_m: ast::mutability) -> ast::mutability {
alt comp_m {
m_imm => {base_m} // imm: as mutable as the container
m_mutbl | m_const => {comp_m}
}
}
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fn cat_field<N:ast_node>(node: N, base_cmt: cmt,
f_name: ast::ident) -> cmt {
let f_mutbl = alt field_mutbl(self.tcx, base_cmt.ty, f_name) {
some(f_mutbl) { f_mutbl }
none {
self.tcx.sess.span_bug(
node.span(),
#fmt["Cannot find field `%s` in type `%s`",
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*f_name, ty_to_str(self.tcx, base_cmt.ty)]);
}
};
let m = self.inherited_mutability(base_cmt.mutbl, f_mutbl);
let f_comp = comp_field(f_name, f_mutbl);
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let lp = base_cmt.lp.map(|lp| @lp_comp(lp, f_comp) );
@{id: node.id(), span: node.span(),
cat: cat_comp(base_cmt, f_comp), lp:lp,
mutbl: m, ty: self.tcx.ty(node)}
}
fn cat_deref<N:ast_node>(node: N, base_cmt: cmt, derefs: uint,
expl: bool) -> option<cmt> {
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do ty::deref(self.tcx, base_cmt.ty, expl).map |mt| {
alt deref_kind(self.tcx, base_cmt.ty) {
deref_ptr(ptr) {
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let lp = do base_cmt.lp.chain |l| {
// Given that the ptr itself is loanable, we can
// loan out deref'd uniq ptrs as the data they are
// the only way to reach the data they point at.
// Other ptr types admit aliases and are therefore
// not loanable.
alt ptr {
uniq_ptr => {some(@lp_deref(l, ptr))}
gc_ptr | region_ptr | unsafe_ptr => {none}
}
};
// for unique ptrs, we inherit mutability from the
// owning reference.
let m = alt ptr {
uniq_ptr => {
self.inherited_mutability(base_cmt.mutbl, mt.mutbl)
}
gc_ptr | region_ptr | unsafe_ptr => {
mt.mutbl
}
};
@{id:node.id(), span:node.span(),
cat:cat_deref(base_cmt, derefs, ptr), lp:lp,
mutbl:m, ty:mt.ty}
}
deref_comp(comp) {
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let lp = base_cmt.lp.map(|l| @lp_comp(l, comp) );
let m = self.inherited_mutability(base_cmt.mutbl, mt.mutbl);
@{id:node.id(), span:node.span(),
cat:cat_comp(base_cmt, comp), lp:lp,
mutbl:m, ty:mt.ty}
}
}
}
}
fn cat_index(expr: @ast::expr, base: @ast::expr) -> cmt {
let base_cmt = self.cat_autoderef(base);
let mt = alt ty::index(self.tcx, base_cmt.ty) {
some(mt) { mt }
none {
self.tcx.sess.span_bug(
expr.span,
#fmt["Explicit index of non-index type `%s`",
ty_to_str(self.tcx, base_cmt.ty)]);
}
};
ret alt deref_kind(self.tcx, base_cmt.ty) {
deref_ptr(ptr) {
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// (a) the contents are loanable if the base is loanable
// and this is a *unique* vector
let deref_lp = alt ptr {
uniq_ptr => {base_cmt.lp.map(|lp| @lp_deref(lp, uniq_ptr))}
_ => {none}
};
// (b) for unique ptrs, we inherit mutability from the
// owning reference.
let m = alt ptr {
uniq_ptr => {
self.inherited_mutability(base_cmt.mutbl, mt.mutbl)
}
gc_ptr | region_ptr | unsafe_ptr => {
mt.mutbl
}
};
// (c) the deref is explicit in the resulting cmt
let deref_cmt = @{id:expr.id, span:expr.span,
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cat:cat_deref(base_cmt, 0u, ptr), lp:deref_lp,
mutbl:m, ty:mt.ty};
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comp(expr, deref_cmt, base_cmt.ty, m, mt.ty)
}
deref_comp(_) {
// fixed-length vectors have no deref
comp(expr, base_cmt, base_cmt.ty, mt.mutbl, mt.ty)
}
};
fn comp(expr: @ast::expr, of_cmt: cmt,
vect: ty::t, mutbl: ast::mutability, ty: ty::t) -> cmt {
let comp = comp_index(vect, mutbl);
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let index_lp = of_cmt.lp.map(|lp| @lp_comp(lp, comp) );
@{id:expr.id, span:expr.span,
cat:cat_comp(of_cmt, comp), lp:index_lp,
mutbl:mutbl, ty:ty}
}
}
fn cat_tuple_elt<N: ast_node>(elt: N, cmt: cmt) -> cmt {
@{id: elt.id(), span: elt.span(),
cat: cat_comp(cmt, comp_tuple),
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lp: cmt.lp.map(|l| @lp_comp(l, comp_tuple) ),
mutbl: cmt.mutbl, // imm iff in an immutable context
ty: self.tcx.ty(elt)}
}
}
impl private_methods for borrowck_ctxt {
fn cat_method_ref(expr: @ast::expr, expr_ty: ty::t) -> cmt {
@{id:expr.id, span:expr.span,
cat:cat_special(sk_method), lp:none,
mutbl:m_imm, ty:expr_ty}
}
fn cat_autoderef(base: @ast::expr) -> cmt {
// Creates a string of implicit derefences so long as base is
// dereferencable. n.b., it is important that these dereferences are
// associated with the field/index that caused the autoderef (expr).
// This is used later to adjust ref counts and so forth in trans.
// Given something like base.f where base has type @m1 @m2 T, we want
// to yield the equivalent categories to (**base).f.
let mut cmt = self.cat_expr(base);
let mut ctr = 0u;
loop {
ctr += 1u;
alt self.cat_deref(base, cmt, ctr, false) {
none { ret cmt; }
some(cmt1) { cmt = cmt1; }
}
}
}
}
fn field_mutbl(tcx: ty::ctxt,
base_ty: ty::t,
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f_name: ast::ident) -> option<ast::mutability> {
// Need to refactor so that records/class fields can be treated uniformly.
alt ty::get(base_ty).struct {
ty::ty_rec(fields) {
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for fields.each |f| {
if f.ident == f_name {
ret some(f.mt.mutbl);
}
}
}
ty::ty_class(did, substs) {
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for ty::lookup_class_fields(tcx, did).each |fld| {
if fld.ident == f_name {
let m = alt fld.mutability {
ast::class_mutable { ast::m_mutbl }
ast::class_immutable { ast::m_imm }
};
ret some(m);
}
}
}
_ { }
}
ret none;
}