Call 2-base deletion-insertion as two adjacent SNPs.

[lightning.git] / hgvs / diff.go

// Copyright (C) The Lightning Authors. All rights reserved.
//
// SPDX-License-Identifier: AGPL-3.0

package hgvs

import (
        "fmt"
        "strings"
        "time"

        "github.com/sergi/go-diff/diffmatchpatch"
)

type Variant struct {
        Position int
        Ref      string
        New      string
        Left     string // base preceding an indel, if Ref or New is empty
}

func (v *Variant) String() string {
        switch {
        case len(v.New) == 0 && len(v.Ref) == 0:
                return fmt.Sprintf("%d=", v.Position)
        case len(v.New) == 1 && v.New == v.Ref:
                return fmt.Sprintf("%d=", v.Position)
        case v.New == v.Ref:
                return fmt.Sprintf("%d_%d=", v.Position, v.Position+len(v.Ref)-1)
        case len(v.New) == 0 && len(v.Ref) == 1:
                return fmt.Sprintf("%ddel", v.Position)
        case len(v.New) == 0:
                return fmt.Sprintf("%d_%ddel", v.Position, v.Position+len(v.Ref)-1)
        case len(v.Ref) == 1 && len(v.New) == 1:
                return fmt.Sprintf("%d%s>%s", v.Position, v.Ref, v.New)
        case len(v.Ref) == 0:
                return fmt.Sprintf("%d_%dins%s", v.Position-1, v.Position, v.New)
        case len(v.Ref) == 1 && len(v.New) > 0:
                return fmt.Sprintf("%ddelins%s", v.Position, v.New)
        default:
                return fmt.Sprintf("%d_%ddelins%s", v.Position, v.Position+len(v.Ref)-1, v.New)
        }
}

// PadLeft returns a Variant that is equivalent to v but (if possible)
// uses the stashed preceding base (the Left field) to avoid having a
// non-empty Ref or New part, even for an insertion or deletion.
//
// For example, if v is {Position: 45, Ref: "", New: "A"}, PadLeft
// might return {Position: 44, Ref: "T", New: "TA"}.
func (v *Variant) PadLeft() Variant {
        if len(v.Ref) == 0 || len(v.New) == 0 {
                return Variant{
                        Position: v.Position - len(v.Left),
                        Ref:      v.Left + v.Ref,
                        New:      v.Left + v.New,
                }
        } else {
                return *v
        }
}

func Diff(a, b string, timeout time.Duration) ([]Variant, bool) {
        dmp := diffmatchpatch.New()
        var deadline time.Time
        if timeout > 0 {
                deadline = time.Now().Add(timeout)
        }
        diffs := dmp.DiffBisect(a, b, deadline)
        timedOut := false
        if timeout > 0 && time.Now().After(deadline) {
                timedOut = true
        }
        diffs = cleanup(dmp.DiffCleanupEfficiency(diffs))
        pos := 1
        var variants []Variant
        for i := 0; i < len(diffs); {
                left := "" // last char before an insertion or deletion
                for ; i < len(diffs) && diffs[i].Type == diffmatchpatch.DiffEqual; i++ {
                        pos += len(diffs[i].Text)
                        if tlen := len(diffs[i].Text); tlen > 0 {
                                left = diffs[i].Text[tlen-1:]
                        }
                }
                if i >= len(diffs) {
                        break
                }
                v := Variant{Position: pos, Left: left}
                for ; i < len(diffs) && diffs[i].Type != diffmatchpatch.DiffEqual; i++ {
                        if diffs[i].Type == diffmatchpatch.DiffDelete {
                                v.Ref += diffs[i].Text
                        } else {
                                v.New += diffs[i].Text
                        }
                }
                if len(v.Ref) == 2 && len(v.New) == 2 {
                        v1 := v
                        v1.Ref = v1.Ref[:1]
                        v1.New = v1.New[:1]
                        v.Ref = v.Ref[1:]
                        v.New = v.New[1:]
                        v.Position++
                        v.Left = v1.Ref
                        pos++
                        variants = append(variants, v1)
                }
                pos += len(v.Ref)
                variants = append(variants, v)
                left = ""
        }
        return variants, timedOut
}

func cleanup(in []diffmatchpatch.Diff) (out []diffmatchpatch.Diff) {
        out = make([]diffmatchpatch.Diff, 0, len(in))
        for i := 0; i < len(in); i++ {
                d := in[i]
                // Merge consecutive entries of same type (e.g.,
                // "insert A; insert B")
                for i < len(in)-1 && in[i].Type == in[i+1].Type {
                        d.Text += in[i+1].Text
                        i++
                }
                out = append(out, d)
        }
        in, out = out, make([]diffmatchpatch.Diff, 0, len(in))
        for i := 0; i < len(in); i++ {
                d := in[i]
                // diffmatchpatch solves diff("AAX","XTX") with
                // [delAA,=X,insTX] but we prefer to spell it
                // [delAA,insXT,=X].
                //
                // So, when we see a [del,=,ins] sequence where the
                // "=" part is a suffix of the "ins" part -- e.g.,
                // [delAAA,=CGG,insTTTCGG] -- we rearrange it to the
                // equivalent spelling [delAAA,insCGGTTT,=CGG].
                if i < len(in)-2 &&
                        d.Type == diffmatchpatch.DiffDelete &&
                        in[i+1].Type == diffmatchpatch.DiffEqual &&
                        in[i+2].Type == diffmatchpatch.DiffInsert &&
                        strings.HasSuffix(in[i+2].Text, in[i+1].Text) {
                        eq, ins := in[i+1], in[i+2]
                        ins.Text = eq.Text + ins.Text[:len(ins.Text)-len(eq.Text)]
                        in[i+1] = ins
                        in[i+2] = eq
                }
                // diffmatchpatch solves diff("AXX","XXX") with
                // [delA,=XX,insX] but we prefer to spell it
                // [delA,insX,=XX].
                //
                // So, when we see a [del,=,ins] sequence that has the
                // same effect after swapping the "=" and "ins" parts,
                // we swap them.
                if i < len(in)-2 &&
                        d.Type == diffmatchpatch.DiffDelete &&
                        in[i+1].Type == diffmatchpatch.DiffEqual &&
                        in[i+2].Type == diffmatchpatch.DiffInsert &&
                        in[i+1].Text+in[i+2].Text == in[i+2].Text+in[i+1].Text {
                        in[i+2], in[i+1] = in[i+1], in[i+2]
                }
                // when diffmatchpatch says [delAAA, insXAY] and
                // len(X)==1, we prefer to treat the A>X as a snp.
                if i < len(in)-1 &&
                        d.Type == diffmatchpatch.DiffDelete &&
                        in[i+1].Type == diffmatchpatch.DiffInsert &&
                        len(d.Text) >= 2 &&
                        len(in[i+1].Text) >= 2 &&
                        d.Text[1] == in[i+1].Text[1] {
                        eqend := 2
                        for ; eqend < len(d.Text) && eqend < len(in[i+1].Text) && d.Text[eqend] == in[i+1].Text[eqend]; eqend++ {
                        }
                        out = append(out,
                                diffmatchpatch.Diff{diffmatchpatch.DiffDelete, d.Text[:1]},
                                diffmatchpatch.Diff{diffmatchpatch.DiffInsert, in[i+1].Text[:1]},
                                diffmatchpatch.Diff{diffmatchpatch.DiffEqual, d.Text[1:eqend]})
                        in[i].Text, in[i+1].Text = in[i].Text[eqend:], in[i+1].Text[eqend:]
                        i--
                        continue
                }
                // when diffmatchpatch says [delAAA, insXaY] and
                // len(Y)==1, we prefer to treat the A>Y as a snp.
                if i < len(in)-1 &&
                        d.Type == diffmatchpatch.DiffDelete &&
                        in[i+1].Type == diffmatchpatch.DiffInsert &&
                        len(d.Text) >= 2 &&
                        len(in[i+1].Text) >= 2 &&
                        d.Text[len(d.Text)-2] == in[i+1].Text[len(in[i+1].Text)-2] {
                        // eqstart will be the number of equal chars
                        // before the terminal snp, plus 1 for the snp
                        // itself. Example, for [delAAAA, insTTAAG],
                        // eqstart will be 3.
                        eqstart := 2
                        for ; eqstart < len(d.Text) && eqstart < len(in[i+1].Text) && d.Text[len(d.Text)-eqstart] == in[i+1].Text[len(in[i+1].Text)-eqstart]; eqstart++ {
                        }
                        eqstart--
                        out = append(out,
                                diffmatchpatch.Diff{diffmatchpatch.DiffDelete, d.Text[:len(d.Text)-eqstart]},
                                diffmatchpatch.Diff{diffmatchpatch.DiffInsert, in[i+1].Text[:len(in[i+1].Text)-eqstart]},
                                diffmatchpatch.Diff{diffmatchpatch.DiffEqual, d.Text[len(d.Text)-eqstart : len(d.Text)-1]},
                                diffmatchpatch.Diff{diffmatchpatch.DiffDelete, d.Text[len(d.Text)-1:]},
                                diffmatchpatch.Diff{diffmatchpatch.DiffInsert, in[i+1].Text[len(in[i+1].Text)-1:]})
                        i++
                        continue
                }
                out = append(out, d)
        }
        // for i := 0; i < len(out)-1; i++ {
        //      if out[i].Type == diffmatchpatch.DiffDelete && len(out[i].Text) == 2 &&
        //              out[i+1].Type == diffmatchpatch.DiffInsert && len(out[i+1].Text) == 2 {
        //              out = append(out, diffmatchpatch.Diff{}, diffmatchpatch.Diff{})
        //              copy(out[i+4:], out[i+2:])
        //              out[i+2] = diffmatchpatch.Diff{diffmatchpatch.DiffDelete, out[i].Text[1:]}
        //              out[i+3] = diffmatchpatch.Diff{diffmatchpatch.DiffInsert, out[i+1].Text[1:]}
        //              out[i].Text = out[i].Text[:1]
        //              out[i+1].Text = out[i+1].Text[:1]
        //      }
        // }
        return
}

func Less(a, b Variant) bool {
        if a.Position != b.Position {
                return a.Position < b.Position
        } else if a.New != b.New {
                return a.New < b.New
        } else {
                return a.Ref < b.Ref
        }
}