// Copyright 2019 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 ssa // fuseIntegerComparisons optimizes inequalities such as '1 <= x && x < 5', // which can be optimized to 'unsigned(x-1) < 4'. // // Look for branch structure like: // // p // |\ // | b // |/ \ // s0 s1 // // In our example, p has control '1 <= x', b has control 'x < 5', // and s0 and s1 are the if and else results of the comparison. // // This will be optimized into: // // p // \ // b // / \ // s0 s1 // // where b has the combined control value 'unsigned(x-1) < 4'. // Later passes will then fuse p and b. func fuseIntegerComparisons(b *Block) bool { if len(b.Preds) != 1 { return false } p := b.Preds[0].Block() if b.Kind != BlockIf || p.Kind != BlockIf { return false } // Don't merge control values if b is likely to be bypassed anyway. if p.Likely == BranchLikely && p.Succs[0].Block() != b { return false } if p.Likely == BranchUnlikely && p.Succs[1].Block() != b { return false } // Check if the control values combine to make an integer inequality that // can be further optimized later. bc := b.Controls[0] pc := p.Controls[0] if !areMergeableInequalities(bc, pc) { return false } // If the first (true) successors match then we have a disjunction (||). // If the second (false) successors match then we have a conjunction (&&). for i, op := range [2]Op{OpOrB, OpAndB} { if p.Succs[i].Block() != b.Succs[i].Block() { continue } // TODO(mundaym): should we also check the cost of executing b? // Currently we might speculatively execute b even if b contains // a lot of instructions. We could just check that len(b.Values) // is lower than a fixed amount. Bear in mind however that the // other optimization passes might yet reduce the cost of b // significantly so we shouldn't be overly conservative. if !canSpeculativelyExecute(b) { return false } // Logically combine the control values for p and b. v := b.NewValue0(bc.Pos, op, bc.Type) v.AddArg(pc) v.AddArg(bc) // Set the combined control value as the control value for b. b.SetControl(v) // Modify p so that it jumps directly to b. p.removeEdge(i) p.Kind = BlockPlain p.Likely = BranchUnknown p.ResetControls() return true } // TODO: could negate condition(s) to merge controls. return false } // getConstIntArgIndex returns the index of the first argument that is a // constant integer or -1 if no such argument exists. func getConstIntArgIndex(v *Value) int { for i, a := range v.Args { switch a.Op { case OpConst8, OpConst16, OpConst32, OpConst64: return i } } return -1 } // isSignedInequality reports whether op represents the inequality < or ≤ // in the signed domain. func isSignedInequality(v *Value) bool { switch v.Op { case OpLess64, OpLess32, OpLess16, OpLess8, OpLeq64, OpLeq32, OpLeq16, OpLeq8: return true } return false } // isUnsignedInequality reports whether op represents the inequality < or ≤ // in the unsigned domain. func isUnsignedInequality(v *Value) bool { switch v.Op { case OpLess64U, OpLess32U, OpLess16U, OpLess8U, OpLeq64U, OpLeq32U, OpLeq16U, OpLeq8U: return true } return false } func areMergeableInequalities(x, y *Value) bool { // We need both inequalities to be either in the signed or unsigned domain. // TODO(mundaym): it would also be good to merge when we have an Eq op that // could be transformed into a Less/Leq. For example in the unsigned // domain 'x == 0 || 3 < x' is equivalent to 'x <= 0 || 3 < x' inequalityChecks := [...]func(*Value) bool{ isSignedInequality, isUnsignedInequality, } for _, f := range inequalityChecks { if !f(x) || !f(y) { continue } // Check that both inequalities are comparisons with constants. xi := getConstIntArgIndex(x) if xi < 0 { return false } yi := getConstIntArgIndex(y) if yi < 0 { return false } // Check that the non-constant arguments to the inequalities // are the same. return x.Args[xi^1] == y.Args[yi^1] } return false }