Difference between revisions of "DIP38"
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− | == DIP38: Safe | + | == DIP38: Safe references without runtime checks. == |
{| class="wikitable" | {| class="wikitable" | ||
!Title: | !Title: | ||
− | !''Safe | + | !''Safe references without runtime checks'' |
|- | |- | ||
|DIP: | |DIP: | ||
Line 18: | Line 18: | ||
|- | |- | ||
|Last Modified: | |Last Modified: | ||
− | |2013-05- | + | |2013-05-10 |
|- | |- | ||
|Author: | |Author: | ||
Line 28: | Line 28: | ||
== Abstract == | == Abstract == | ||
− | + | Dconf13 introduced safe references enabled by a runtime check (see email thread from Walter: ([http://forum.dlang.org/post/km3k8v$80p$1@digitalmars.com 'Rvalue references - The resolution']). We propose a formulation that is safe (guaranteed safety at compile time), efficient (doesn't require any runtime bounds checks) and simple. | |
− | + | ||
− | + | We introduce 2 types of references for ref input arguments of ref return functions: inref and outref (the exact keywords can be discussed later) to distinguish whether a given input argument can be escaped or not (possibly via field accesses): | |
− | + | ref fun(int inref a, int outref b, int outref c, int d); | |
− | + | indicates that b and c can be escaped by ref return (there could indeed be multiple return statements), but not a. | |
+ | |||
+ | We argue that these annotations (inref and outref) are sufficient for guaranteeing ref safety, simply by typechecking a program under a set of allowable conversions. | ||
+ | |||
+ | We propose two schemes: | ||
+ | |||
+ | * scheme A: the user annotates the ref return functions on his own (just a choice between inref or outref is needed for each ref input arg) | ||
+ | * scheme B: the compiler takes care of the annotations via a proposed procedural analysis | ||
+ | |||
+ | If the function is a method or internal function, the function itself is marked as inref or outref as reference to the implicit 'this' parameter. | ||
− | + | The annotations are part of the type system and written in the automatically generated di interface files. | |
− | |||
− | |||
− | + | == Examples == | |
<syntaxhighlight lang="d"> | <syntaxhighlight lang="d"> | ||
struct U{T x;} | struct U{T x;} | ||
− | ref T foo(ref T a, ref T b, ref U c, | + | ref T foo(ref T a, ref T b, ref U c, int d){ |
− | if( | + | static T e; |
− | + | if(...) return a; | |
− | else if( | + | else if(...) return c.x; |
− | + | else return e; | |
− | else | ||
− | |||
} | } | ||
</syntaxhighlight> | </syntaxhighlight> | ||
− | + | shall have the new signature: | |
<syntaxhighlight lang="d"> | <syntaxhighlight lang="d"> | ||
− | ref | + | ref T foo(outref T a, inref T b, outref U c, int d); |
</syntaxhighlight> | </syntaxhighlight> | ||
− | indicating that ref | + | indicating that it may return by ref a and c only (dependency on c is via field access). |
− | Second example: when the function is a member (say of a struct), the 'this' parameter is | + | Second example: when the function is a member (say of a struct), the 'this' parameter is implicit, and the same rules apply: |
<syntaxhighlight lang="d"> | <syntaxhighlight lang="d"> | ||
− | struct S { T t; ref T fooc(ref T a) { if( | + | struct S { T t; ref T fooc(ref T a) { if(...) return t; else return a;} } |
</syntaxhighlight> | </syntaxhighlight> | ||
− | + | shall have the new signature: | |
<syntaxhighlight lang="d"> | <syntaxhighlight lang="d"> | ||
− | struct S { T t; ref | + | struct S { T t; ref T fooc(outref T a) outref; } |
</syntaxhighlight> | </syntaxhighlight> | ||
− | + | indicating that it may return by ref a and the hidden 'this' parameter. The annotation for 'this' is at the method level, same as where const would be. | |
− | + | The di file will also have those inref/outref annotations. | |
− | + | == Safe ref validation at compile time == | |
− | |||
− | |||
− | |||
− | |||
− | Examples | + | Given those inref/outref annotations, it is easy to validate/invalidate ref safety; we simply check whether the program typechecks under the following conversion rules: |
+ | |||
+ | Allowed type conversions: | ||
+ | |||
+ | * global => outref //global: gc-allocated, static, etc. | ||
+ | * outref 'dot' field => outref // field access | ||
+ | * ref function(args) where each outref arg is an outref expression => outref | ||
+ | * ref function(args) where at least one outref arg is not an outref expression => local | ||
+ | * inref => local | ||
+ | * return outref => outref | ||
+ | * return local => local // compile error if this is a ref return function | ||
+ | |||
+ | Examples taken from Walter's above mentioned email. Each one yields an error, and an explanation is given. | ||
<syntaxhighlight lang="d"> | <syntaxhighlight lang="d"> | ||
Line 85: | Line 98: | ||
//Case A: | //Case A: | ||
ref T fooa(ref T t) { return t; } | ref T fooa(ref T t) { return t; } | ||
− | //=> ref | + | //=> ref T fooa(outref T t); |
− | ref T bar() { T t; return fooa(t); } // | + | ref T bar() { T t; return fooa(t); } // T t: local; fooa(t): local because ref fooa takes t as outref and t is a local expression. return fooa(t) therefore returns a local, which is an error. |
//Case B: | //Case B: | ||
ref T foob(ref U u) { return u.t; } | ref T foob(ref U u) { return u.t; } | ||
− | //=>ref | + | //=>ref T foob(outref U u) { return u.t; } |
− | ref U bar() { T t; return foob(t); } // | + | ref U bar() { T t; return foob(t); } // same as above, using rule 'outref 'dot' field => outref'. |
//Case C: | //Case C: | ||
struct S { T t; ref T fooc() { return t; } } | struct S { T t; ref T fooc() { return t; } } | ||
− | //=>struct S { T t; ref | + | //=>struct S { T t; ref T fooc() outref; } //outref refers to hidden this parameter |
− | ref T bar() { S s; return s.fooc(); } // | + | ref T bar() { S s; return s.fooc(); } // same as above |
//Case D: | //Case D: | ||
− | |||
− | |||
ref T food() { | ref T food() { | ||
T t; | T t; | ||
ref T bar() { return t; } | ref T bar() { return t; } | ||
− | //=>ref | + | //=>ref T bar() outref; //outref refers to hidden this parameter, this could be rewritten as: ref T bar(outref void*this) ; |
− | return bar(); //error since | + | return bar(); // same error as above (since 'this' refers to local stack) |
} | } | ||
//case E: | //case E: | ||
Transitively calling other functions: | Transitively calling other functions: | ||
+ | ref T fooe(T t) { return fooa(t); } //same error because t is a local. | ||
+ | </syntaxhighlight> | ||
+ | |||
+ | == scheme A: the user annotates the ref return functions on his own== | ||
+ | Just a choice between inref or outref is needed for each ref input arg. | ||
+ | |||
+ | == scheme B: the compiler takes care of the annotations via a proposed procedural analysis == | ||
+ | We sketch an algorithm to infer inref/outref attributes. Let's take the following example for illustration: | ||
+ | <syntaxhighlight lang="d"> | ||
+ | ref T foo1(ref T a, T b, ref T c) { if(...) return foo2(a); else return foo2(c); } | ||
+ | ref T foo2(ref T a) { return a; } | ||
+ | </syntaxhighlight> | ||
+ | |||
+ | The propagation algorithm goes as follows | ||
− | + | * initialize each ref argument of ref-return functions with 'ref' (ie we don't know yet whether it's inref or outref) | |
+ | * construct an oriented graph: | ||
+ | * nodes are ref-return functions | ||
+ | * edges are ref-return dependencies (one edge per return statement in a ref return function): with example above, there is a graph with 2 nodes (foo1 and foo2) and a single edge (foo1 -> foo2). | ||
+ | * while some ref annotations have changed do: | ||
+ | * for each node with a 'ref' annotation | ||
+ | * recompute annotations and remove uncertainty if all all outgoing edges have no uncertainty (ie ref instead of inref or outref) | ||
+ | * case A1) if there are no nodes with ref annotations, then we have succeeded in compile time inference of ref dependency | ||
+ | * case A2) otherwise, for each node with ref annotations, then there are loops in the graph, and for these nodes we fall back in runtime check on return addresses as proposed in Dconf13. This case should be rare in practice. However there might be a slightly more complex algorithm in that case too that doesn't require runtime check (will think about it). | ||
+ | For the above example we have: | ||
+ | iteration 0(initialization): | ||
+ | foo1(ref T a, T b, ref T c); | ||
+ | foo2(ref T a); | ||
+ | |||
+ | iteration 1: | ||
+ | foo1(ref T a, T b, ref T c); | ||
+ | foo2(outref T a); | ||
+ | |||
+ | iteration 2: | ||
+ | foo1(outref T a, T b, outref T c); | ||
+ | foo2(outref T a); | ||
+ | |||
+ | Loops in the graph (case A2) correspond to the case of mutually recursive ref return functions. For example: | ||
+ | <syntaxhighlight lang="d"> | ||
+ | ref T foo1(ref T a, T b, ref T c) { if(...) return foo2(a,0,c); else return a; } | ||
+ | ref T foo2(ref T a, T b, ref T c) { if(...) return foo1(a,1,c); else return c; } | ||
</syntaxhighlight> | </syntaxhighlight> | ||
+ | == Rvalue references == | ||
− | + | See DIP39 for how to handle those safely in conjunction with this DIP38. | |
== Copyright == | == Copyright == |
Latest revision as of 16:48, 26 May 2013
Contents
DIP38: Safe references without runtime checks.
Title: | Safe references without runtime checks |
---|---|
DIP: | 38 |
Version: | 1 |
Status: | Draft |
Created: | 2013-05-06 |
Last Modified: | 2013-05-10 |
Author: | Timothee Cour |
Links: |
Abstract
Dconf13 introduced safe references enabled by a runtime check (see email thread from Walter: ('Rvalue references - The resolution'). We propose a formulation that is safe (guaranteed safety at compile time), efficient (doesn't require any runtime bounds checks) and simple.
We introduce 2 types of references for ref input arguments of ref return functions: inref and outref (the exact keywords can be discussed later) to distinguish whether a given input argument can be escaped or not (possibly via field accesses): ref fun(int inref a, int outref b, int outref c, int d); indicates that b and c can be escaped by ref return (there could indeed be multiple return statements), but not a.
We argue that these annotations (inref and outref) are sufficient for guaranteeing ref safety, simply by typechecking a program under a set of allowable conversions.
We propose two schemes:
- scheme A: the user annotates the ref return functions on his own (just a choice between inref or outref is needed for each ref input arg)
- scheme B: the compiler takes care of the annotations via a proposed procedural analysis
If the function is a method or internal function, the function itself is marked as inref or outref as reference to the implicit 'this' parameter.
The annotations are part of the type system and written in the automatically generated di interface files.
Examples
struct U{T x;}
ref T foo(ref T a, ref T b, ref U c, int d){
static T e;
if(...) return a;
else if(...) return c.x;
else return e;
}
shall have the new signature:
ref T foo(outref T a, inref T b, outref U c, int d);
indicating that it may return by ref a and c only (dependency on c is via field access).
Second example: when the function is a member (say of a struct), the 'this' parameter is implicit, and the same rules apply:
struct S { T t; ref T fooc(ref T a) { if(...) return t; else return a;} }
shall have the new signature:
struct S { T t; ref T fooc(outref T a) outref; }
indicating that it may return by ref a and the hidden 'this' parameter. The annotation for 'this' is at the method level, same as where const would be.
The di file will also have those inref/outref annotations.
Safe ref validation at compile time
Given those inref/outref annotations, it is easy to validate/invalidate ref safety; we simply check whether the program typechecks under the following conversion rules:
Allowed type conversions:
- global => outref //global: gc-allocated, static, etc.
- outref 'dot' field => outref // field access
- ref function(args) where each outref arg is an outref expression => outref
- ref function(args) where at least one outref arg is not an outref expression => local
- inref => local
- return outref => outref
- return local => local // compile error if this is a ref return function
Examples taken from Walter's above mentioned email. Each one yields an error, and an explanation is given.
//Case A:
ref T fooa(ref T t) { return t; }
//=> ref T fooa(outref T t);
ref T bar() { T t; return fooa(t); } // T t: local; fooa(t): local because ref fooa takes t as outref and t is a local expression. return fooa(t) therefore returns a local, which is an error.
//Case B:
ref T foob(ref U u) { return u.t; }
//=>ref T foob(outref U u) { return u.t; }
ref U bar() { T t; return foob(t); } // same as above, using rule 'outref 'dot' field => outref'.
//Case C:
struct S { T t; ref T fooc() { return t; } }
//=>struct S { T t; ref T fooc() outref; } //outref refers to hidden this parameter
ref T bar() { S s; return s.fooc(); } // same as above
//Case D:
ref T food() {
T t;
ref T bar() { return t; }
//=>ref T bar() outref; //outref refers to hidden this parameter, this could be rewritten as: ref T bar(outref void*this) ;
return bar(); // same error as above (since 'this' refers to local stack)
}
//case E:
Transitively calling other functions:
ref T fooe(T t) { return fooa(t); } //same error because t is a local.
scheme A: the user annotates the ref return functions on his own
Just a choice between inref or outref is needed for each ref input arg.
scheme B: the compiler takes care of the annotations via a proposed procedural analysis
We sketch an algorithm to infer inref/outref attributes. Let's take the following example for illustration:
ref T foo1(ref T a, T b, ref T c) { if(...) return foo2(a); else return foo2(c); }
ref T foo2(ref T a) { return a; }
The propagation algorithm goes as follows
- initialize each ref argument of ref-return functions with 'ref' (ie we don't know yet whether it's inref or outref)
- construct an oriented graph:
* nodes are ref-return functions * edges are ref-return dependencies (one edge per return statement in a ref return function): with example above, there is a graph with 2 nodes (foo1 and foo2) and a single edge (foo1 -> foo2).
- while some ref annotations have changed do:
* for each node with a 'ref' annotation * recompute annotations and remove uncertainty if all all outgoing edges have no uncertainty (ie ref instead of inref or outref)
- case A1) if there are no nodes with ref annotations, then we have succeeded in compile time inference of ref dependency
- case A2) otherwise, for each node with ref annotations, then there are loops in the graph, and for these nodes we fall back in runtime check on return addresses as proposed in Dconf13. This case should be rare in practice. However there might be a slightly more complex algorithm in that case too that doesn't require runtime check (will think about it).
For the above example we have: iteration 0(initialization): foo1(ref T a, T b, ref T c); foo2(ref T a);
iteration 1: foo1(ref T a, T b, ref T c); foo2(outref T a);
iteration 2: foo1(outref T a, T b, outref T c); foo2(outref T a);
Loops in the graph (case A2) correspond to the case of mutually recursive ref return functions. For example:
ref T foo1(ref T a, T b, ref T c) { if(...) return foo2(a,0,c); else return a; }
ref T foo2(ref T a, T b, ref T c) { if(...) return foo1(a,1,c); else return c; }
Rvalue references
See DIP39 for how to handle those safely in conjunction with this DIP38.
Copyright
This document has been placed in the Public Domain.