// Copyright 2013 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package pointer import "go/types" type constraint interface { // For a complex constraint, returns the nodeid of the pointer // to which it is attached. For addr and copy, returns dst. ptr() nodeid // renumber replaces each nodeid n in the constraint by mapping[n]. renumber(mapping []nodeid) // presolve is a hook for constraint-specific behaviour during // pre-solver optimization. Typical implementations mark as // indirect the set of nodes to which the solver will add copy // edges or PTS labels. presolve(h *hvn) // solve is called for complex constraints when the pts for // the node to which they are attached has changed. solve(a *analysis, delta *nodeset) String() string } // dst = &src // pts(dst) ⊇ {src} // A base constraint used to initialize the solver's pt sets type addrConstraint struct { dst nodeid // (ptr) src nodeid } func (c *addrConstraint) ptr() nodeid { return c.dst } func (c *addrConstraint) renumber(mapping []nodeid) { c.dst = mapping[c.dst] c.src = mapping[c.src] } // dst = src // A simple constraint represented directly as a copyTo graph edge. type copyConstraint struct { dst nodeid // (ptr) src nodeid } func (c *copyConstraint) ptr() nodeid { return c.dst } func (c *copyConstraint) renumber(mapping []nodeid) { c.dst = mapping[c.dst] c.src = mapping[c.src] } // dst = src[offset] // A complex constraint attached to src (the pointer) type loadConstraint struct { offset uint32 dst nodeid src nodeid // (ptr) } func (c *loadConstraint) ptr() nodeid { return c.src } func (c *loadConstraint) renumber(mapping []nodeid) { c.dst = mapping[c.dst] c.src = mapping[c.src] } // dst[offset] = src // A complex constraint attached to dst (the pointer) type storeConstraint struct { offset uint32 dst nodeid // (ptr) src nodeid } func (c *storeConstraint) ptr() nodeid { return c.dst } func (c *storeConstraint) renumber(mapping []nodeid) { c.dst = mapping[c.dst] c.src = mapping[c.src] } // dst = &src.f or dst = &src[0] // A complex constraint attached to dst (the pointer) type offsetAddrConstraint struct { offset uint32 dst nodeid src nodeid // (ptr) } func (c *offsetAddrConstraint) ptr() nodeid { return c.src } func (c *offsetAddrConstraint) renumber(mapping []nodeid) { c.dst = mapping[c.dst] c.src = mapping[c.src] } // dst = src.(typ) where typ is an interface // A complex constraint attached to src (the interface). // No representation change: pts(dst) and pts(src) contains tagged objects. type typeFilterConstraint struct { typ types.Type // an interface type dst nodeid src nodeid // (ptr) } func (c *typeFilterConstraint) ptr() nodeid { return c.src } func (c *typeFilterConstraint) renumber(mapping []nodeid) { c.dst = mapping[c.dst] c.src = mapping[c.src] } // dst = src.(typ) where typ is a concrete type // A complex constraint attached to src (the interface). // // If exact, only tagged objects identical to typ are untagged. // If !exact, tagged objects assignable to typ are untagged too. // The latter is needed for various reflect operators, e.g. Send. // // This entails a representation change: // pts(src) contains tagged objects, // pts(dst) contains their payloads. type untagConstraint struct { typ types.Type // a concrete type dst nodeid src nodeid // (ptr) exact bool } func (c *untagConstraint) ptr() nodeid { return c.src } func (c *untagConstraint) renumber(mapping []nodeid) { c.dst = mapping[c.dst] c.src = mapping[c.src] } // src.method(params...) // A complex constraint attached to iface. type invokeConstraint struct { method *types.Func // the abstract method iface nodeid // (ptr) the interface params nodeid // the start of the identity/params/results block } func (c *invokeConstraint) ptr() nodeid { return c.iface } func (c *invokeConstraint) renumber(mapping []nodeid) { c.iface = mapping[c.iface] c.params = mapping[c.params] }