// Copyright 2012 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. /*! # Translation of expressions. ## Recommended entry point If you wish to translate an expression, the preferred way to do so is to use: expr::trans_into(block, expr, Dest) -> block This will generate code that evaluates `expr`, storing the result into `Dest`, which must either be the special flag ignore (throw the result away) or be a pointer to memory of the same type/size as the expression. It returns the resulting basic block. This form will handle all automatic adjustments for you. The value will be moved if its type is linear and copied otherwise. ## Translation to a datum In some cases, `trans_into()` is too narrow of an interface. Generally this occurs either when you know that the result value is going to be a scalar, or when you need to evaluate the expression into some memory location so you can go and inspect it (e.g., assignments, `match` expressions, the `&` operator). In such cases, you want the following function: trans_to_datum(block, expr) -> DatumBlock This function generates code to evaluate the expression and return a `Datum` describing where the result is to be found. This function tries to return its result in the most efficient way possible, without introducing extra copies or sacrificing information. Therefore, for lvalue expressions, you always get a by-ref `Datum` in return that points at the memory for this lvalue. For rvalue expressions, we will return a by-value `Datum` whenever possible, but it is often necessary to allocate a stack slot, store the result of the rvalue in there, and then return a pointer to the slot (see the discussion later on about the different kinds of rvalues). NB: The `trans_to_datum()` function does perform adjustments, but since it returns a pointer to the value "in place" it does not handle moves. If you wish to copy/move the value returned into a new location, you should use the Datum method `store_to()` (move or copy depending on type). You can also use `move_to()` (force move) or `copy_to()` (force copy) for special situations. ## Translating local variables `trans_local_var()` can be used to trans a ref to a local variable that is not an expression. This is needed for captures. ## Ownership and cleanups The current system for cleanups associates required cleanups with block contexts. Block contexts are structured into a tree that resembles the code itself. Not every block context has cleanups associated with it, only those blocks that have a kind of `block_scope`. See `common::block_kind` for more details. If you invoke `trans_into()`, no cleanup is scheduled for you. The value is written into the given destination and is assumed to be owned by that destination. When you invoke `trans_to_datum()` on an rvalue, the resulting datum/value will have an appropriate cleanup scheduled for the innermost cleanup scope. If you later use `move_to()` or `drop_val()`, this cleanup will be canceled. During the evaluation of an expression, temporary cleanups are created and later canceled. These represent intermediate or partial results which must be cleaned up in the event of task failure. ## Implementation details We divide expressions into three categories, based on how they are most naturally implemented: 1. Lvalues 2. Datum rvalues 3. DPS rvalues 4. Statement rvalues Lvalues always refer to user-assignable memory locations. Translating those always results in a by-ref datum; this introduces no inefficiencies into the generated code, because all lvalues are naturally addressable. Datum rvalues are rvalues that always generate datums as a result. These are generally scalar results, such as `a+b` where `a` and `b` are integers. DPS rvalues are rvalues that, when translated, must be given a memory location to write into (or the Ignore flag). These are generally expressions that produce structural results that are larger than one word (e.g., a struct literal), but also expressions (like `if`) that involve control flow (otherwise we'd have to generate phi nodes). Finally, statement rvalues are rvalues that always produce a nil return type, such as `while` loops or assignments (`a = b`). */ use back::abi; use lib::llvm::{ValueRef, llvm, SetLinkage, ExternalLinkage}; use lib; use metadata::csearch; use middle::trans::_match; use middle::trans::adt; use middle::trans::asm; use middle::trans::base::*; use middle::trans::base; use middle::trans::build::*; use middle::trans::callee::DoAutorefArg; use middle::trans::callee; use middle::trans::closure; use middle::trans::common::*; use middle::trans::consts; use middle::trans::controlflow; use middle::trans::datum::*; use middle::trans::debuginfo; use middle::trans::machine; use middle::trans::meth; use middle::trans::tvec; use middle::trans::type_of; use middle::ty::struct_fields; use middle::ty::{AutoDerefRef, AutoAddEnv}; use middle::ty::{AutoPtr, AutoBorrowVec, AutoBorrowVecRef, AutoBorrowFn, AutoUnsafe}; use middle::ty; use util::common::indenter; use util::ppaux::Repr; use middle::trans::machine::llsize_of; use middle::trans::type_::Type; use std::hashmap::HashMap; use std::vec; use syntax::print::pprust::{expr_to_str}; use syntax::ast; use syntax::codemap; // Destinations // These are passed around by the code generating functions to track the // destination of a computation's value. #[deriving(Eq)] pub enum Dest { SaveIn(ValueRef), Ignore, } impl Dest { pub fn to_str(&self, ccx: &CrateContext) -> ~str { match *self { SaveIn(v) => fmt!("SaveIn(%s)", ccx.tn.val_to_str(v)), Ignore => ~"Ignore" } } } fn drop_and_cancel_clean(bcx: @mut Block, dat: Datum) -> @mut Block { let bcx = dat.drop_val(bcx); dat.cancel_clean(bcx); return bcx; } pub fn trans_to_datum(bcx: @mut Block, expr: @ast::expr) -> DatumBlock { debug!("trans_to_datum(expr=%s)", bcx.expr_to_str(expr)); let mut bcx = bcx; let mut datum = unpack_datum!(bcx, trans_to_datum_unadjusted(bcx, expr)); let adjustment = match bcx.tcx().adjustments.find_copy(&expr.id) { None => { return DatumBlock {bcx: bcx, datum: datum}; } Some(adj) => { adj } }; debug!("unadjusted datum: %s", datum.to_str(bcx.ccx())); match *adjustment { AutoAddEnv(*) => { datum = unpack_datum!(bcx, add_env(bcx, expr, datum)); } AutoDerefRef(ref adj) => { if adj.autoderefs > 0 { datum = unpack_datum!( bcx, datum.autoderef(bcx, expr.span, expr.id, adj.autoderefs)); } datum = match adj.autoref { None => { datum } Some(AutoUnsafe(*)) | // region + unsafe ptrs have same repr Some(AutoPtr(*)) => { unpack_datum!(bcx, auto_ref(bcx, datum)) } Some(AutoBorrowVec(*)) => { unpack_datum!(bcx, auto_slice(bcx, adj.autoderefs, expr, datum)) } Some(AutoBorrowVecRef(*)) => { unpack_datum!(bcx, auto_slice_and_ref(bcx, adj.autoderefs, expr, datum)) } Some(AutoBorrowFn(*)) => { let adjusted_ty = ty::adjust_ty(bcx.tcx(), expr.span, datum.ty, Some(adjustment)); unpack_datum!(bcx, auto_borrow_fn(bcx, adjusted_ty, datum)) } }; } } debug!("after adjustments, datum=%s", datum.to_str(bcx.ccx())); return DatumBlock {bcx: bcx, datum: datum}; fn auto_ref(bcx: @mut Block, datum: Datum) -> DatumBlock { DatumBlock {bcx: bcx, datum: datum.to_rptr(bcx)} } fn auto_borrow_fn(bcx: @mut Block, adjusted_ty: ty::t, datum: Datum) -> DatumBlock { // Currently, all closure types are represented precisely the // same, so no runtime adjustment is required, but we still // must patchup the type. DatumBlock {bcx: bcx, datum: Datum {val: datum.val, ty: adjusted_ty, mode: datum.mode}} } fn auto_slice(bcx: @mut Block, autoderefs: uint, expr: &ast::expr, datum: Datum) -> DatumBlock { // This is not the most efficient thing possible; since slices // are two words it'd be better if this were compiled in // 'dest' mode, but I can't find a nice way to structure the // code and keep it DRY that accommodates that use case at the // moment. let tcx = bcx.tcx(); let unit_ty = ty::sequence_element_type(tcx, datum.ty); let (bcx, base, len) = datum.get_vec_base_and_len(bcx, expr.span, expr.id, autoderefs+1); // this type may have a different region/mutability than the // real one, but it will have the same runtime representation let slice_ty = ty::mk_evec(tcx, ty::mt { ty: unit_ty, mutbl: ast::m_imm }, ty::vstore_slice(ty::re_static)); let scratch = scratch_datum(bcx, slice_ty, "__adjust", false); Store(bcx, base, GEPi(bcx, scratch.val, [0u, abi::slice_elt_base])); Store(bcx, len, GEPi(bcx, scratch.val, [0u, abi::slice_elt_len])); DatumBlock {bcx: bcx, datum: scratch} } fn add_env(bcx: @mut Block, expr: &ast::expr, datum: Datum) -> DatumBlock { // This is not the most efficient thing possible; since closures // are two words it'd be better if this were compiled in // 'dest' mode, but I can't find a nice way to structure the // code and keep it DRY that accommodates that use case at the // moment. let tcx = bcx.tcx(); let closure_ty = expr_ty_adjusted(bcx, expr); debug!("add_env(closure_ty=%s)", closure_ty.repr(tcx)); let scratch = scratch_datum(bcx, closure_ty, "__adjust", false); let llfn = GEPi(bcx, scratch.val, [0u, abi::fn_field_code]); assert_eq!(datum.appropriate_mode(tcx), ByValue); Store(bcx, datum.to_appropriate_llval(bcx), llfn); let llenv = GEPi(bcx, scratch.val, [0u, abi::fn_field_box]); Store(bcx, base::null_env_ptr(bcx), llenv); DatumBlock {bcx: bcx, datum: scratch} } fn auto_slice_and_ref(bcx: @mut Block, autoderefs: uint, expr: &ast::expr, datum: Datum) -> DatumBlock { let DatumBlock { bcx, datum } = auto_slice(bcx, autoderefs, expr, datum); auto_ref(bcx, datum) } } pub fn trans_into(bcx: @mut Block, expr: @ast::expr, dest: Dest) -> @mut Block { if bcx.tcx().adjustments.contains_key(&expr.id) { // use trans_to_datum, which is mildly less efficient but // which will perform the adjustments: let datumblock = trans_to_datum(bcx, expr); return match dest { Ignore => datumblock.bcx, SaveIn(lldest) => datumblock.store_to(INIT, lldest) }; } let ty = expr_ty(bcx, expr); debug!("trans_into_unadjusted(expr=%s, dest=%s)", bcx.expr_to_str(expr), dest.to_str(bcx.ccx())); let _indenter = indenter(); debuginfo::update_source_pos(bcx, expr.span); let dest = { if ty::type_is_nil(ty) || ty::type_is_bot(ty) { Ignore } else { dest } }; let kind = bcx.expr_kind(expr); debug!("expr kind = %?", kind); return match kind { ty::LvalueExpr => { let datumblock = trans_lvalue_unadjusted(bcx, expr); match dest { Ignore => datumblock.bcx, SaveIn(lldest) => datumblock.store_to(INIT, lldest) } } ty::RvalueDatumExpr => { let datumblock = trans_rvalue_datum_unadjusted(bcx, expr); match dest { Ignore => datumblock.drop_val(), // When processing an rvalue, the value will be newly // allocated, so we always `move_to` so as not to // unnecessarily inc ref counts and so forth: SaveIn(lldest) => datumblock.move_to(INIT, lldest) } } ty::RvalueDpsExpr => { trans_rvalue_dps_unadjusted(bcx, expr, dest) } ty::RvalueStmtExpr => { trans_rvalue_stmt_unadjusted(bcx, expr) } }; } fn trans_lvalue(bcx: @mut Block, expr: @ast::expr) -> DatumBlock { /*! * * Translates an lvalue expression, always yielding a by-ref * datum. Generally speaking you should call trans_to_datum() * instead, but sometimes we call trans_lvalue() directly as a * means of asserting that a particular expression is an lvalue. */ return match bcx.tcx().adjustments.find(&expr.id) { None => trans_lvalue_unadjusted(bcx, expr), Some(_) => { bcx.sess().span_bug( expr.span, fmt!("trans_lvalue() called on an expression \ with adjustments")); } }; } fn trans_to_datum_unadjusted(bcx: @mut Block, expr: @ast::expr) -> DatumBlock { /*! * Translates an expression into a datum. If this expression * is an rvalue, this will result in a temporary value being * created. If you plan to store the value somewhere else, * you should prefer `trans_into()` instead. */ let mut bcx = bcx; debug!("trans_to_datum_unadjusted(expr=%s)", bcx.expr_to_str(expr)); let _indenter = indenter(); debuginfo::update_source_pos(bcx, expr.span); match ty::expr_kind(bcx.tcx(), bcx.ccx().maps.method_map, expr) { ty::LvalueExpr => { return trans_lvalue_unadjusted(bcx, expr); } ty::RvalueDatumExpr => { let datum = unpack_datum!(bcx, { trans_rvalue_datum_unadjusted(bcx, expr) }); datum.add_clean(bcx); return DatumBlock {bcx: bcx, datum: datum}; } ty::RvalueStmtExpr => { bcx = trans_rvalue_stmt_unadjusted(bcx, expr); return nil(bcx, expr_ty(bcx, expr)); } ty::RvalueDpsExpr => { let ty = expr_ty(bcx, expr); if ty::type_is_nil(ty) || ty::type_is_bot(ty) { bcx = trans_rvalue_dps_unadjusted(bcx, expr, Ignore); return nil(bcx, ty); } else { let scratch = scratch_datum(bcx, ty, "", false); bcx = trans_rvalue_dps_unadjusted( bcx, expr, SaveIn(scratch.val)); // Note: this is not obviously a good idea. It causes // immediate values to be loaded immediately after a // return from a call or other similar expression, // which in turn leads to alloca's having shorter // lifetimes and hence larger stack frames. However, // in turn it can lead to more register pressure. // Still, in practice it seems to increase // performance, since we have fewer problems with // morestack churn. let scratch = scratch.to_appropriate_datum(bcx); scratch.add_clean(bcx); return DatumBlock {bcx: bcx, datum: scratch}; } } } fn nil(bcx: @mut Block, ty: ty::t) -> DatumBlock { let datum = immediate_rvalue(C_nil(), ty); DatumBlock {bcx: bcx, datum: datum} } } fn trans_rvalue_datum_unadjusted(bcx: @mut Block, expr: @ast::expr) -> DatumBlock { let _icx = push_ctxt("trans_rvalue_datum_unadjusted"); trace_span!(bcx, expr.span, shorten(bcx.expr_to_str(expr))); match expr.node { ast::expr_path(_) | ast::expr_self => { return trans_def_datum_unadjusted(bcx, expr, bcx.def(expr.id)); } ast::expr_vstore(contents, ast::expr_vstore_box) | ast::expr_vstore(contents, ast::expr_vstore_mut_box) => { return tvec::trans_uniq_or_managed_vstore(bcx, heap_managed, expr, contents); } ast::expr_vstore(contents, ast::expr_vstore_uniq) => { let heap = heap_for_unique(bcx, expr_ty(bcx, contents)); return tvec::trans_uniq_or_managed_vstore(bcx, heap, expr, contents); } ast::expr_lit(lit) => { return trans_immediate_lit(bcx, expr, *lit); } ast::expr_binary(_, op, lhs, rhs) => { // if overloaded, would be RvalueDpsExpr assert!(!bcx.ccx().maps.method_map.contains_key(&expr.id)); return trans_binary(bcx, expr, op, lhs, rhs); } ast::expr_unary(_, op, x) => { return trans_unary_datum(bcx, expr, op, x); } ast::expr_addr_of(_, x) => { return trans_addr_of(bcx, expr, x); } ast::expr_cast(val, _) => { return trans_imm_cast(bcx, val, expr.id); } ast::expr_paren(e) => { return trans_rvalue_datum_unadjusted(bcx, e); } _ => { bcx.tcx().sess.span_bug( expr.span, fmt!("trans_rvalue_datum_unadjusted reached \ fall-through case: %?", expr.node)); } } } fn trans_rvalue_stmt_unadjusted(bcx: @mut Block, expr: @ast::expr) -> @mut Block { let mut bcx = bcx; let _icx = push_ctxt("trans_rvalue_stmt"); if bcx.unreachable { return bcx; } trace_span!(bcx, expr.span, shorten(bcx.expr_to_str(expr))); match expr.node { ast::expr_break(label_opt) => { return controlflow::trans_break(bcx, label_opt); } ast::expr_again(label_opt) => { return controlflow::trans_cont(bcx, label_opt); } ast::expr_ret(ex) => { return controlflow::trans_ret(bcx, ex); } ast::expr_log(lvl, a) => { return controlflow::trans_log(expr, lvl, bcx, a); } ast::expr_while(cond, ref body) => { return controlflow::trans_while(bcx, cond, body); } ast::expr_loop(ref body, opt_label) => { return controlflow::trans_loop(bcx, body, opt_label); } ast::expr_assign(dst, src) => { let src_datum = unpack_datum!( bcx, trans_to_datum(bcx, src)); let dst_datum = unpack_datum!( bcx, trans_lvalue(bcx, dst)); return src_datum.store_to_datum( bcx, DROP_EXISTING, dst_datum); } ast::expr_assign_op(callee_id, op, dst, src) => { return trans_assign_op(bcx, expr, callee_id, op, dst, src); } ast::expr_paren(a) => { return trans_rvalue_stmt_unadjusted(bcx, a); } ast::expr_inline_asm(ref a) => { return asm::trans_inline_asm(bcx, a); } _ => { bcx.tcx().sess.span_bug( expr.span, fmt!("trans_rvalue_stmt_unadjusted reached \ fall-through case: %?", expr.node)); } }; } fn trans_rvalue_dps_unadjusted(bcx: @mut Block, expr: @ast::expr, dest: Dest) -> @mut Block { let _icx = push_ctxt("trans_rvalue_dps_unadjusted"); let tcx = bcx.tcx(); trace_span!(bcx, expr.span, shorten(bcx.expr_to_str(expr))); match expr.node { ast::expr_paren(e) => { return trans_rvalue_dps_unadjusted(bcx, e, dest); } ast::expr_path(_) | ast::expr_self => { return trans_def_dps_unadjusted(bcx, expr, bcx.def(expr.id), dest); } ast::expr_if(cond, ref thn, els) => { return controlflow::trans_if(bcx, cond, thn, els, dest); } ast::expr_match(discr, ref arms) => { return _match::trans_match(bcx, expr, discr, *arms, dest); } ast::expr_block(ref blk) => { return do base::with_scope(bcx, blk.info(), "block-expr body") |bcx| { controlflow::trans_block(bcx, blk, dest) }; } ast::expr_struct(_, ref fields, base) => { return trans_rec_or_struct(bcx, (*fields), base, expr.span, expr.id, dest); } ast::expr_tup(ref args) => { let repr = adt::represent_type(bcx.ccx(), expr_ty(bcx, expr)); let numbered_fields: ~[(uint, @ast::expr)] = args.iter().enumerate().transform(|(i, arg)| (i, *arg)).collect(); return trans_adt(bcx, repr, 0, numbered_fields, None, dest); } ast::expr_lit(@codemap::spanned {node: ast::lit_str(s), _}) => { return tvec::trans_lit_str(bcx, expr, s, dest); } ast::expr_vstore(contents, ast::expr_vstore_slice) | ast::expr_vstore(contents, ast::expr_vstore_mut_slice) => { return tvec::trans_slice_vstore(bcx, expr, contents, dest); } ast::expr_vec(*) | ast::expr_repeat(*) => { return tvec::trans_fixed_vstore(bcx, expr, expr, dest); } ast::expr_fn_block(ref decl, ref body) => { let expr_ty = expr_ty(bcx, expr); let sigil = ty::ty_closure_sigil(expr_ty); debug!("translating fn_block %s with type %s", expr_to_str(expr, tcx.sess.intr()), expr_ty.repr(tcx)); return closure::trans_expr_fn(bcx, sigil, decl, body, expr.id, expr.id, None, dest); } ast::expr_do_body(blk) => { return trans_into(bcx, blk, dest); } ast::expr_call(f, ref args, _) => { return callee::trans_call( bcx, expr, f, callee::ArgExprs(*args), expr.id, dest); } ast::expr_method_call(callee_id, rcvr, _, _, ref args, _) => { return callee::trans_method_call(bcx, expr, callee_id, rcvr, callee::ArgExprs(*args), dest); } ast::expr_binary(callee_id, _, lhs, rhs) => { // if not overloaded, would be RvalueDatumExpr return trans_overloaded_op(bcx, expr, callee_id, lhs, ~[rhs], expr_ty(bcx, expr), dest); } ast::expr_unary(callee_id, _, subexpr) => { // if not overloaded, would be RvalueDatumExpr return trans_overloaded_op(bcx, expr, callee_id, subexpr, ~[], expr_ty(bcx, expr), dest); } ast::expr_index(callee_id, base, idx) => { // if not overloaded, would be RvalueDatumExpr return trans_overloaded_op(bcx, expr, callee_id, base, ~[idx], expr_ty(bcx, expr), dest); } ast::expr_cast(val, _) => { match ty::get(node_id_type(bcx, expr.id)).sty { ty::ty_trait(_, _, store, _, _) => { return meth::trans_trait_cast(bcx, val, expr.id, dest, store); } _ => { bcx.tcx().sess.span_bug(expr.span, "expr_cast of non-trait"); } } } ast::expr_assign_op(callee_id, op, dst, src) => { return trans_assign_op(bcx, expr, callee_id, op, dst, src); } _ => { bcx.tcx().sess.span_bug( expr.span, fmt!("trans_rvalue_dps_unadjusted reached fall-through case: %?", expr.node)); } } } fn trans_def_dps_unadjusted(bcx: @mut Block, ref_expr: &ast::expr, def: ast::def, dest: Dest) -> @mut Block { let _icx = push_ctxt("trans_def_dps_unadjusted"); let ccx = bcx.ccx(); let lldest = match dest { SaveIn(lldest) => lldest, Ignore => { return bcx; } }; match def { ast::def_variant(tid, vid) => { let variant_info = ty::enum_variant_with_id(ccx.tcx, tid, vid); if variant_info.args.len() > 0u { // N-ary variant. let fn_data = callee::trans_fn_ref(bcx, vid, ref_expr.id); Store(bcx, fn_data.llfn, lldest); return bcx; } else { // Nullary variant. let ty = expr_ty(bcx, ref_expr); let repr = adt::represent_type(ccx, ty); adt::trans_start_init(bcx, repr, lldest, variant_info.disr_val); return bcx; } } ast::def_struct(*) => { let ty = expr_ty(bcx, ref_expr); match ty::get(ty).sty { ty::ty_struct(did, _) if ty::has_dtor(ccx.tcx, did) => { let repr = adt::represent_type(ccx, ty); adt::trans_start_init(bcx, repr, lldest, 0); } _ => {} } return bcx; } _ => { bcx.tcx().sess.span_bug(ref_expr.span, fmt!( "Non-DPS def %? referened by %s", def, bcx.node_id_to_str(ref_expr.id))); } } } fn trans_def_datum_unadjusted(bcx: @mut Block, ref_expr: &ast::expr, def: ast::def) -> DatumBlock { let _icx = push_ctxt("trans_def_datum_unadjusted"); match def { ast::def_fn(did, _) | ast::def_static_method(did, None, _) => { let fn_data = callee::trans_fn_ref(bcx, did, ref_expr.id); return fn_data_to_datum(bcx, ref_expr, did, fn_data); } ast::def_static_method(impl_did, Some(trait_did), _) => { let fn_data = meth::trans_static_method_callee(bcx, impl_did, trait_did, ref_expr.id); return fn_data_to_datum(bcx, ref_expr, impl_did, fn_data); } _ => { bcx.tcx().sess.span_bug(ref_expr.span, fmt!( "Non-DPS def %? referened by %s", def, bcx.node_id_to_str(ref_expr.id))); } } fn fn_data_to_datum(bcx: @mut Block, ref_expr: &ast::expr, def_id: ast::def_id, fn_data: callee::FnData) -> DatumBlock { /*! * * Translates a reference to a top-level fn item into a rust * value. This is just a fn pointer. */ let is_extern = { let fn_tpt = ty::lookup_item_type(bcx.tcx(), def_id); ty::ty_fn_purity(fn_tpt.ty) == ast::extern_fn }; let (rust_ty, llval) = if is_extern { let rust_ty = ty::mk_ptr( bcx.tcx(), ty::mt { ty: ty::mk_mach_uint(ast::ty_u8), mutbl: ast::m_imm }); // *u8 (rust_ty, PointerCast(bcx, fn_data.llfn, Type::i8p())) } else { let fn_ty = expr_ty(bcx, ref_expr); (fn_ty, fn_data.llfn) }; return DatumBlock { bcx: bcx, datum: Datum {val: llval, ty: rust_ty, mode: ByValue} }; } } fn trans_lvalue_unadjusted(bcx: @mut Block, expr: @ast::expr) -> DatumBlock { /*! * * Translates an lvalue expression, always yielding a by-ref * datum. Does not apply any adjustments. */ let _icx = push_ctxt("trans_lval"); let mut bcx = bcx; debug!("trans_lvalue(expr=%s)", bcx.expr_to_str(expr)); let _indenter = indenter(); trace_span!(bcx, expr.span, shorten(bcx.expr_to_str(expr))); return match expr.node { ast::expr_paren(e) => { trans_lvalue_unadjusted(bcx, e) } ast::expr_path(_) | ast::expr_self => { trans_def_lvalue(bcx, expr, bcx.def(expr.id)) } ast::expr_field(base, ident, _) => { trans_rec_field(bcx, base, ident) } ast::expr_index(_, base, idx) => { trans_index(bcx, expr, base, idx) } ast::expr_unary(_, ast::deref, base) => { let basedatum = unpack_datum!(bcx, trans_to_datum(bcx, base)); basedatum.deref(bcx, expr, 0) } _ => { bcx.tcx().sess.span_bug( expr.span, fmt!("trans_lvalue reached fall-through case: %?", expr.node)); } }; fn trans_rec_field(bcx: @mut Block, base: @ast::expr, field: ast::ident) -> DatumBlock { //! Translates `base.field`. let mut bcx = bcx; let _icx = push_ctxt("trans_rec_field"); let base_datum = unpack_datum!(bcx, trans_to_datum(bcx, base)); let repr = adt::represent_type(bcx.ccx(), base_datum.ty); do with_field_tys(bcx.tcx(), base_datum.ty, None) |discr, field_tys| { let ix = ty::field_idx_strict(bcx.tcx(), field, field_tys); DatumBlock { datum: do base_datum.get_element(bcx, field_tys[ix].mt.ty, ZeroMem) |srcval| { adt::trans_field_ptr(bcx, repr, srcval, discr, ix) }, bcx: bcx } } } fn trans_index(bcx: @mut Block, index_expr: &ast::expr, base: @ast::expr, idx: @ast::expr) -> DatumBlock { //! Translates `base[idx]`. let _icx = push_ctxt("trans_index"); let ccx = bcx.ccx(); let base_ty = expr_ty(bcx, base); let mut bcx = bcx; let base_datum = unpack_datum!(bcx, trans_to_datum(bcx, base)); // Translate index expression and cast to a suitable LLVM integer. // Rust is less strict than LLVM in this regard. let Result {bcx, val: ix_val} = trans_to_datum(bcx, idx).to_result(); let ix_size = machine::llbitsize_of_real(bcx.ccx(), val_ty(ix_val)); let int_size = machine::llbitsize_of_real(bcx.ccx(), ccx.int_type); let ix_val = { if ix_size < int_size { if ty::type_is_signed(expr_ty(bcx, idx)) { SExt(bcx, ix_val, ccx.int_type) } else { ZExt(bcx, ix_val, ccx.int_type) } } else if ix_size > int_size { Trunc(bcx, ix_val, ccx.int_type) } else { ix_val } }; let vt = tvec::vec_types(bcx, base_datum.ty); base::maybe_name_value(bcx.ccx(), vt.llunit_size, "unit_sz"); let scaled_ix = Mul(bcx, ix_val, vt.llunit_size); base::maybe_name_value(bcx.ccx(), scaled_ix, "scaled_ix"); let (bcx, base, len) = base_datum.get_vec_base_and_len(bcx, index_expr.span, index_expr.id, 0); let mut len = len; if ty::type_is_str(base_ty) { // acccount for null terminator in the case of string len = Sub(bcx, len, C_uint(bcx.ccx(), 1u)); } debug!("trans_index: base %s", bcx.val_to_str(base)); debug!("trans_index: len %s", bcx.val_to_str(len)); let bounds_check = ICmp(bcx, lib::llvm::IntUGE, scaled_ix, len); let bcx = do with_cond(bcx, bounds_check) |bcx| { let unscaled_len = UDiv(bcx, len, vt.llunit_size); controlflow::trans_fail_bounds_check(bcx, index_expr.span, ix_val, unscaled_len) }; let elt = InBoundsGEP(bcx, base, [ix_val]); let elt = PointerCast(bcx, elt, vt.llunit_ty.ptr_to()); return DatumBlock { bcx: bcx, datum: Datum {val: elt, ty: vt.unit_ty, mode: ByRef(ZeroMem)} }; } fn trans_def_lvalue(bcx: @mut Block, ref_expr: &ast::expr, def: ast::def) -> DatumBlock { //! Translates a reference to a path. let _icx = push_ctxt("trans_def_lvalue"); match def { ast::def_static(did, _) => { let const_ty = expr_ty(bcx, ref_expr); fn get_val(bcx: @mut Block, did: ast::def_id, const_ty: ty::t) -> ValueRef { // For external constants, we don't inline. if did.crate == ast::LOCAL_CRATE { // The LLVM global has the type of its initializer, // which may not be equal to the enum's type for // non-C-like enums. let val = base::get_item_val(bcx.ccx(), did.node); let pty = type_of(bcx.ccx(), const_ty).ptr_to(); PointerCast(bcx, val, pty) } else { { let extern_const_values = &bcx.ccx().extern_const_values; match extern_const_values.find(&did) { None => {} // Continue. Some(llval) => { return *llval; } } } unsafe { let llty = type_of(bcx.ccx(), const_ty); let symbol = csearch::get_symbol( bcx.ccx().sess.cstore, did); let llval = do symbol.as_c_str |buf| { llvm::LLVMAddGlobal(bcx.ccx().llmod, llty.to_ref(), buf) }; SetLinkage(llval, ExternalLinkage); let extern_const_values = &mut bcx.ccx().extern_const_values; extern_const_values.insert(did, llval); llval } } } let val = get_val(bcx, did, const_ty); DatumBlock { bcx: bcx, datum: Datum {val: val, ty: const_ty, mode: ByRef(ZeroMem)} } } _ => { DatumBlock { bcx: bcx, datum: trans_local_var(bcx, def) } } } } } pub fn trans_local_var(bcx: @mut Block, def: ast::def) -> Datum { let _icx = push_ctxt("trans_local_var"); return match def { ast::def_upvar(nid, _, _, _) => { // Can't move upvars, so this is never a ZeroMemLastUse. let local_ty = node_id_type(bcx, nid); match bcx.fcx.llupvars.find(&nid) { Some(&val) => { Datum { val: val, ty: local_ty, mode: ByRef(ZeroMem) } } None => { bcx.sess().bug(fmt!( "trans_local_var: no llval for upvar %? found", nid)); } } } ast::def_arg(nid, _) => { take_local(bcx, bcx.fcx.llargs, nid) } ast::def_local(nid, _) | ast::def_binding(nid, _) => { take_local(bcx, bcx.fcx.lllocals, nid) } ast::def_self(nid, _) => { let self_info: ValSelfData = match bcx.fcx.llself { Some(ref self_info) => *self_info, None => { bcx.sess().bug(fmt!( "trans_local_var: reference to self \ out of context with id %?", nid)); } }; debug!("def_self() reference, self_info.t=%s", self_info.t.repr(bcx.tcx())); Datum { val: self_info.v, ty: self_info.t, mode: ByRef(ZeroMem) } } _ => { bcx.sess().unimpl(fmt!( "unsupported def type in trans_local_var: %?", def)); } }; fn take_local(bcx: @mut Block, table: &HashMap, nid: ast::NodeId) -> Datum { let v = match table.find(&nid) { Some(&v) => v, None => { bcx.sess().bug(fmt!( "trans_local_var: no llval for local/arg %? found", nid)); } }; let ty = node_id_type(bcx, nid); debug!("take_local(nid=%?, v=%s, ty=%s)", nid, bcx.val_to_str(v), bcx.ty_to_str(ty)); Datum { val: v, ty: ty, mode: ByRef(ZeroMem) } } } // The optional node ID here is the node ID of the path identifying the enum // variant in use. If none, this cannot possibly an enum variant (so, if it // is and `node_id_opt` is none, this function fails). pub fn with_field_tys(tcx: ty::ctxt, ty: ty::t, node_id_opt: Option, op: &fn(uint, (&[ty::field])) -> R) -> R { match ty::get(ty).sty { ty::ty_struct(did, ref substs) => { op(0, struct_fields(tcx, did, substs)) } ty::ty_enum(_, ref substs) => { // We want the *variant* ID here, not the enum ID. match node_id_opt { None => { tcx.sess.bug(fmt!( "cannot get field types from the enum type %s \ without a node ID", ty.repr(tcx))); } Some(node_id) => { match tcx.def_map.get_copy(&node_id) { ast::def_variant(enum_id, variant_id) => { let variant_info = ty::enum_variant_with_id( tcx, enum_id, variant_id); op(variant_info.disr_val, struct_fields(tcx, variant_id, substs)) } _ => { tcx.sess.bug("resolve didn't map this expr to a \ variant ID") } } } } } _ => { tcx.sess.bug(fmt!( "cannot get field types from the type %s", ty.repr(tcx))); } } } fn trans_rec_or_struct(bcx: @mut Block, fields: &[ast::Field], base: Option<@ast::expr>, expr_span: codemap::span, id: ast::NodeId, dest: Dest) -> @mut Block { let _icx = push_ctxt("trans_rec"); let bcx = bcx; let ty = node_id_type(bcx, id); let tcx = bcx.tcx(); do with_field_tys(tcx, ty, Some(id)) |discr, field_tys| { let mut need_base = vec::from_elem(field_tys.len(), true); let numbered_fields = do fields.map |field| { let opt_pos = field_tys.iter().position(|field_ty| field_ty.ident == field.ident); match opt_pos { Some(i) => { need_base[i] = false; (i, field.expr) } None => { tcx.sess.span_bug(field.span, "Couldn't find field in struct type") } } }; let optbase = match base { Some(base_expr) => { let mut leftovers = ~[]; for (i, b) in need_base.iter().enumerate() { if *b { leftovers.push((i, field_tys[i].mt.ty)) } } Some(StructBaseInfo {expr: base_expr, fields: leftovers }) } None => { if need_base.iter().any(|b| *b) { tcx.sess.span_bug(expr_span, "missing fields and no base expr") } None } }; let repr = adt::represent_type(bcx.ccx(), ty); trans_adt(bcx, repr, discr, numbered_fields, optbase, dest) } } /** * Information that `trans_adt` needs in order to fill in the fields * of a struct copied from a base struct (e.g., from an expression * like `Foo { a: b, ..base }`. * * Note that `fields` may be empty; the base expression must always be * evaluated for side-effects. */ struct StructBaseInfo { /// The base expression; will be evaluated after all explicit fields. expr: @ast::expr, /// The indices of fields to copy paired with their types. fields: ~[(uint, ty::t)] } /** * Constructs an ADT instance: * * - `fields` should be a list of field indices paired with the * expression to store into that field. The initializers will be * evaluated in the order specified by `fields`. * * - `optbase` contains information on the base struct (if any) from * which remaining fields are copied; see comments on `StructBaseInfo`. */ fn trans_adt(bcx: @mut Block, repr: &adt::Repr, discr: uint, fields: &[(uint, @ast::expr)], optbase: Option, dest: Dest) -> @mut Block { let _icx = push_ctxt("trans_adt"); let mut bcx = bcx; let addr = match dest { Ignore => { for &(_i, e) in fields.iter() { bcx = trans_into(bcx, e, Ignore); } for sbi in optbase.iter() { // FIXME #7261: this moves entire base, not just certain fields bcx = trans_into(bcx, sbi.expr, Ignore); } return bcx; } SaveIn(pos) => pos }; let mut temp_cleanups = ~[]; adt::trans_start_init(bcx, repr, addr, discr); for &(i, e) in fields.iter() { let dest = adt::trans_field_ptr(bcx, repr, addr, discr, i); let e_ty = expr_ty(bcx, e); bcx = trans_into(bcx, e, SaveIn(dest)); add_clean_temp_mem(bcx, dest, e_ty); temp_cleanups.push(dest); } for base in optbase.iter() { // FIXME #6573: is it sound to use the destination's repr on the base? // And, would it ever be reasonable to be here with discr != 0? let base_datum = unpack_datum!(bcx, trans_to_datum(bcx, base.expr)); for &(i, t) in base.fields.iter() { let datum = do base_datum.get_element(bcx, t, ZeroMem) |srcval| { adt::trans_field_ptr(bcx, repr, srcval, discr, i) }; let dest = adt::trans_field_ptr(bcx, repr, addr, discr, i); bcx = datum.store_to(bcx, INIT, dest); } } for cleanup in temp_cleanups.iter() { revoke_clean(bcx, *cleanup); } return bcx; } fn trans_immediate_lit(bcx: @mut Block, expr: @ast::expr, lit: ast::lit) -> DatumBlock { // must not be a string constant, that is a RvalueDpsExpr let _icx = push_ctxt("trans_immediate_lit"); let ty = expr_ty(bcx, expr); immediate_rvalue_bcx(bcx, consts::const_lit(bcx.ccx(), expr, lit), ty) } fn trans_unary_datum(bcx: @mut Block, un_expr: &ast::expr, op: ast::unop, sub_expr: @ast::expr) -> DatumBlock { let _icx = push_ctxt("trans_unary_datum"); // if deref, would be LvalueExpr assert!(op != ast::deref); // if overloaded, would be RvalueDpsExpr assert!(!bcx.ccx().maps.method_map.contains_key(&un_expr.id)); let un_ty = expr_ty(bcx, un_expr); let sub_ty = expr_ty(bcx, sub_expr); return match op { ast::not => { let Result {bcx, val} = trans_to_datum(bcx, sub_expr).to_result(); // If this is a boolean type, we must not use the LLVM Not // instruction, as that is a *bitwise* not and we want *logical* // not on our 8-bit boolean values. let llresult = match ty::get(un_ty).sty { ty::ty_bool => { let llcond = ICmp(bcx, lib::llvm::IntEQ, val, C_bool(false)); Select(bcx, llcond, C_bool(true), C_bool(false)) } _ => Not(bcx, val) }; immediate_rvalue_bcx(bcx, llresult, un_ty) } ast::neg => { let Result {bcx, val} = trans_to_datum(bcx, sub_expr).to_result(); let llneg = { if ty::type_is_fp(un_ty) { FNeg(bcx, val) } else { Neg(bcx, val) } }; immediate_rvalue_bcx(bcx, llneg, un_ty) } ast::box(_) => { trans_boxed_expr(bcx, un_ty, sub_expr, sub_ty, heap_managed) } ast::uniq => { let heap = heap_for_unique(bcx, un_ty); trans_boxed_expr(bcx, un_ty, sub_expr, sub_ty, heap) } ast::deref => { bcx.sess().bug("deref expressions should have been \ translated using trans_lvalue(), not \ trans_unary_datum()") } }; fn trans_boxed_expr(bcx: @mut Block, box_ty: ty::t, contents: @ast::expr, contents_ty: ty::t, heap: heap) -> DatumBlock { let _icx = push_ctxt("trans_boxed_expr"); if heap == heap_exchange { let llty = type_of(bcx.ccx(), contents_ty); let size = llsize_of(bcx.ccx(), llty); let Result { bcx: bcx, val: val } = malloc_raw_dyn(bcx, contents_ty, heap_exchange, size); add_clean_free(bcx, val, heap_exchange); let bcx = trans_into(bcx, contents, SaveIn(val)); revoke_clean(bcx, val); return immediate_rvalue_bcx(bcx, val, box_ty); } else { let base::MallocResult { bcx, box: bx, body } = base::malloc_general(bcx, contents_ty, heap); add_clean_free(bcx, bx, heap); let bcx = trans_into(bcx, contents, SaveIn(body)); revoke_clean(bcx, bx); return immediate_rvalue_bcx(bcx, bx, box_ty); } } } fn trans_addr_of(bcx: @mut Block, expr: &ast::expr, subexpr: @ast::expr) -> DatumBlock { let _icx = push_ctxt("trans_addr_of"); let mut bcx = bcx; let sub_datum = unpack_datum!(bcx, trans_to_datum(bcx, subexpr)); let llval = sub_datum.to_ref_llval(bcx); return immediate_rvalue_bcx(bcx, llval, expr_ty(bcx, expr)); } // Important to get types for both lhs and rhs, because one might be _|_ // and the other not. fn trans_eager_binop(bcx: @mut Block, binop_expr: &ast::expr, binop_ty: ty::t, op: ast::binop, lhs_datum: &Datum, rhs_datum: &Datum) -> DatumBlock { let _icx = push_ctxt("trans_eager_binop"); let lhs = lhs_datum.to_appropriate_llval(bcx); let lhs_t = lhs_datum.ty; let rhs = rhs_datum.to_appropriate_llval(bcx); let rhs_t = rhs_datum.ty; let mut intype = { if ty::type_is_bot(lhs_t) { rhs_t } else { lhs_t } }; let tcx = bcx.tcx(); if ty::type_is_simd(tcx, intype) { intype = ty::simd_type(tcx, intype); } let is_float = ty::type_is_fp(intype); let signed = ty::type_is_signed(intype); let rhs = base::cast_shift_expr_rhs(bcx, op, lhs, rhs); let mut bcx = bcx; let val = match op { ast::add => { if is_float { FAdd(bcx, lhs, rhs) } else { Add(bcx, lhs, rhs) } } ast::subtract => { if is_float { FSub(bcx, lhs, rhs) } else { Sub(bcx, lhs, rhs) } } ast::mul => { if is_float { FMul(bcx, lhs, rhs) } else { Mul(bcx, lhs, rhs) } } ast::div => { if is_float { FDiv(bcx, lhs, rhs) } else { // Only zero-check integers; fp /0 is NaN bcx = base::fail_if_zero(bcx, binop_expr.span, op, rhs, rhs_t); if signed { SDiv(bcx, lhs, rhs) } else { UDiv(bcx, lhs, rhs) } } } ast::rem => { if is_float { FRem(bcx, lhs, rhs) } else { // Only zero-check integers; fp %0 is NaN bcx = base::fail_if_zero(bcx, binop_expr.span, op, rhs, rhs_t); if signed { SRem(bcx, lhs, rhs) } else { URem(bcx, lhs, rhs) } } } ast::bitor => Or(bcx, lhs, rhs), ast::bitand => And(bcx, lhs, rhs), ast::bitxor => Xor(bcx, lhs, rhs), ast::shl => Shl(bcx, lhs, rhs), ast::shr => { if signed { AShr(bcx, lhs, rhs) } else { LShr(bcx, lhs, rhs) } } ast::eq | ast::ne | ast::lt | ast::ge | ast::le | ast::gt => { if ty::type_is_bot(rhs_t) { C_bool(false) } else { if !ty::type_is_scalar(rhs_t) { bcx.tcx().sess.span_bug(binop_expr.span, "non-scalar comparison"); } let cmpr = base::compare_scalar_types(bcx, lhs, rhs, rhs_t, op); bcx = cmpr.bcx; ZExt(bcx, cmpr.val, Type::i8()) } } _ => { bcx.tcx().sess.span_bug(binop_expr.span, "unexpected binop"); } }; return immediate_rvalue_bcx(bcx, val, binop_ty); } // refinement types would obviate the need for this enum lazy_binop_ty { lazy_and, lazy_or } fn trans_lazy_binop(bcx: @mut Block, binop_expr: &ast::expr, op: lazy_binop_ty, a: @ast::expr, b: @ast::expr) -> DatumBlock { let _icx = push_ctxt("trans_lazy_binop"); let binop_ty = expr_ty(bcx, binop_expr); let bcx = bcx; let Result {bcx: past_lhs, val: lhs} = { do base::with_scope_result(bcx, a.info(), "lhs") |bcx| { trans_to_datum(bcx, a).to_result() } }; if past_lhs.unreachable { return immediate_rvalue_bcx(past_lhs, lhs, binop_ty); } let join = base::sub_block(bcx, "join"); let before_rhs = base::sub_block(bcx, "rhs"); let lhs_i1 = bool_to_i1(past_lhs, lhs); match op { lazy_and => CondBr(past_lhs, lhs_i1, before_rhs.llbb, join.llbb), lazy_or => CondBr(past_lhs, lhs_i1, join.llbb, before_rhs.llbb) } let Result {bcx: past_rhs, val: rhs} = { do base::with_scope_result(before_rhs, b.info(), "rhs") |bcx| { trans_to_datum(bcx, b).to_result() } }; if past_rhs.unreachable { return immediate_rvalue_bcx(join, lhs, binop_ty); } Br(past_rhs, join.llbb); let phi = Phi(join, Type::bool(), [lhs, rhs], [past_lhs.llbb, past_rhs.llbb]); return immediate_rvalue_bcx(join, phi, binop_ty); } fn trans_binary(bcx: @mut Block, binop_expr: &ast::expr, op: ast::binop, lhs: @ast::expr, rhs: @ast::expr) -> DatumBlock { let _icx = push_ctxt("trans_binary"); match op { ast::and => { trans_lazy_binop(bcx, binop_expr, lazy_and, lhs, rhs) } ast::or => { trans_lazy_binop(bcx, binop_expr, lazy_or, lhs, rhs) } _ => { let mut bcx = bcx; let lhs_datum = unpack_datum!(bcx, trans_to_datum(bcx, lhs)); let rhs_datum = unpack_datum!(bcx, trans_to_datum(bcx, rhs)); let binop_ty = expr_ty(bcx, binop_expr); trans_eager_binop(bcx, binop_expr, binop_ty, op, &lhs_datum, &rhs_datum) } } } fn trans_overloaded_op(bcx: @mut Block, expr: &ast::expr, callee_id: ast::NodeId, rcvr: @ast::expr, args: ~[@ast::expr], ret_ty: ty::t, dest: Dest) -> @mut Block { let origin = bcx.ccx().maps.method_map.get_copy(&expr.id); let fty = node_id_type(bcx, callee_id); callee::trans_call_inner(bcx, expr.info(), fty, ret_ty, |bcx| { meth::trans_method_callee(bcx, callee_id, rcvr, origin) }, callee::ArgExprs(args), Some(dest), DoAutorefArg).bcx } fn int_cast(bcx: @mut Block, lldsttype: Type, llsrctype: Type, llsrc: ValueRef, signed: bool) -> ValueRef { let _icx = push_ctxt("int_cast"); unsafe { let srcsz = llvm::LLVMGetIntTypeWidth(llsrctype.to_ref()); let dstsz = llvm::LLVMGetIntTypeWidth(lldsttype.to_ref()); return if dstsz == srcsz { BitCast(bcx, llsrc, lldsttype) } else if srcsz > dstsz { TruncOrBitCast(bcx, llsrc, lldsttype) } else if signed { SExtOrBitCast(bcx, llsrc, lldsttype) } else { ZExtOrBitCast(bcx, llsrc, lldsttype) }; } } fn float_cast(bcx: @mut Block, lldsttype: Type, llsrctype: Type, llsrc: ValueRef) -> ValueRef { let _icx = push_ctxt("float_cast"); let srcsz = llsrctype.float_width(); let dstsz = lldsttype.float_width(); return if dstsz > srcsz { FPExt(bcx, llsrc, lldsttype) } else if srcsz > dstsz { FPTrunc(bcx, llsrc, lldsttype) } else { llsrc }; } #[deriving(Eq)] pub enum cast_kind { cast_pointer, cast_integral, cast_float, cast_enum, cast_other, } pub fn cast_type_kind(t: ty::t) -> cast_kind { match ty::get(t).sty { ty::ty_float(*) => cast_float, ty::ty_ptr(*) => cast_pointer, ty::ty_rptr(*) => cast_pointer, ty::ty_int(*) => cast_integral, ty::ty_uint(*) => cast_integral, ty::ty_bool => cast_integral, ty::ty_enum(*) => cast_enum, _ => cast_other } } fn trans_imm_cast(bcx: @mut Block, expr: @ast::expr, id: ast::NodeId) -> DatumBlock { let _icx = push_ctxt("trans_cast"); let ccx = bcx.ccx(); let t_out = node_id_type(bcx, id); let mut bcx = bcx; let llexpr = unpack_result!(bcx, trans_to_datum(bcx, expr).to_result()); let ll_t_in = val_ty(llexpr); let t_in = expr_ty(bcx, expr); let ll_t_out = type_of::type_of(ccx, t_out); let k_in = cast_type_kind(t_in); let k_out = cast_type_kind(t_out); let s_in = k_in == cast_integral && ty::type_is_signed(t_in); let newval = match (k_in, k_out) { (cast_integral, cast_integral) => { int_cast(bcx, ll_t_out, ll_t_in, llexpr, s_in) } (cast_float, cast_float) => { float_cast(bcx, ll_t_out, ll_t_in, llexpr) } (cast_integral, cast_float) => { if s_in { SIToFP(bcx, llexpr, ll_t_out) } else { UIToFP(bcx, llexpr, ll_t_out) } } (cast_float, cast_integral) => { if ty::type_is_signed(t_out) { FPToSI(bcx, llexpr, ll_t_out) } else { FPToUI(bcx, llexpr, ll_t_out) } } (cast_integral, cast_pointer) => { IntToPtr(bcx, llexpr, ll_t_out) } (cast_pointer, cast_integral) => { PtrToInt(bcx, llexpr, ll_t_out) } (cast_pointer, cast_pointer) => { PointerCast(bcx, llexpr, ll_t_out) } (cast_enum, cast_integral) | (cast_enum, cast_float) => { let bcx = bcx; let repr = adt::represent_type(ccx, t_in); let lldiscrim_a = adt::trans_get_discr(bcx, repr, llexpr); match k_out { cast_integral => int_cast(bcx, ll_t_out, val_ty(lldiscrim_a), lldiscrim_a, true), cast_float => SIToFP(bcx, lldiscrim_a, ll_t_out), _ => ccx.sess.bug("translating unsupported cast.") } } _ => ccx.sess.bug("translating unsupported cast.") }; return immediate_rvalue_bcx(bcx, newval, t_out); } fn trans_assign_op(bcx: @mut Block, expr: @ast::expr, callee_id: ast::NodeId, op: ast::binop, dst: @ast::expr, src: @ast::expr) -> @mut Block { let _icx = push_ctxt("trans_assign_op"); let mut bcx = bcx; debug!("trans_assign_op(expr=%s)", bcx.expr_to_str(expr)); // Evaluate LHS (destination), which should be an lvalue let dst_datum = unpack_datum!(bcx, trans_lvalue_unadjusted(bcx, dst)); // A user-defined operator method if bcx.ccx().maps.method_map.find(&expr.id).is_some() { // FIXME(#2528) evaluates the receiver twice!! let scratch = scratch_datum(bcx, dst_datum.ty, "__assign_op", false); let bcx = trans_overloaded_op(bcx, expr, callee_id, dst, ~[src], dst_datum.ty, SaveIn(scratch.val)); return scratch.move_to_datum(bcx, DROP_EXISTING, dst_datum); } // Evaluate RHS (source) let src_datum = unpack_datum!(bcx, trans_to_datum(bcx, src)); // Perform computation and store the result let result_datum = unpack_datum!(bcx, trans_eager_binop( bcx, expr, dst_datum.ty, op, &dst_datum, &src_datum)); return result_datum.copy_to_datum(bcx, DROP_EXISTING, dst_datum); } fn shorten(x: &str) -> @str { (if x.char_len() > 60 {x.slice_chars(0, 60)} else {x}).to_managed() }