package eval import ( "fmt" "os" "sync" "sync/atomic" "src.elv.sh/pkg/diag" "src.elv.sh/pkg/eval/errs" "src.elv.sh/pkg/eval/vals" "src.elv.sh/pkg/eval/vars" "src.elv.sh/pkg/fsutil" "src.elv.sh/pkg/parse" "src.elv.sh/pkg/parse/cmpd" ) // An operation with some side effects. type effectOp interface{ exec(*Frame) Exception } func (cp *compiler) chunkOp(n *parse.Chunk) effectOp { return chunkOp{n.Range(), cp.pipelineOps(n.Pipelines)} } type chunkOp struct { diag.Ranging subops []effectOp } func (op chunkOp) exec(fm *Frame) Exception { for _, subop := range op.subops { exc := subop.exec(fm) if exc != nil { return exc } } // Check for interrupts after the chunk. // We also check for interrupts before each pipeline, so there is no // need to check it before the chunk or after each pipeline. if fm.IsInterrupted() { return fm.errorp(op, ErrInterrupted) } return nil } func (cp *compiler) pipelineOp(n *parse.Pipeline) effectOp { formOps := cp.formOps(n.Forms) return &pipelineOp{n.Range(), n.Background, parse.SourceText(n), formOps} } func (cp *compiler) pipelineOps(ns []*parse.Pipeline) []effectOp { ops := make([]effectOp, len(ns)) for i, n := range ns { ops[i] = cp.pipelineOp(n) } return ops } type pipelineOp struct { diag.Ranging bg bool source string subops []effectOp } const pipelineChanBufferSize = 32 func (op *pipelineOp) exec(fm *Frame) Exception { if fm.IsInterrupted() { return fm.errorp(op, ErrInterrupted) } if op.bg { fm = fm.Fork("background job" + op.source) fm.intCh = nil fm.background = true fm.Evaler.addNumBgJobs(1) } nforms := len(op.subops) var wg sync.WaitGroup wg.Add(nforms) excs := make([]Exception, nforms) var nextIn *Port // For each form, create a dedicated evalCtx and run asynchronously for i, formOp := range op.subops { newFm := fm.Fork("[form op]") inputIsPipe := i > 0 outputIsPipe := i < nforms-1 if inputIsPipe { newFm.ports[0] = nextIn } if outputIsPipe { // Each internal port pair consists of a (byte) pipe pair and a // channel. // os.Pipe sets O_CLOEXEC, which is what we want. reader, writer, e := os.Pipe() if e != nil { return fm.errorpf(op, "failed to create pipe: %s", e) } ch := make(chan interface{}, pipelineChanBufferSize) sendStop := make(chan struct{}) sendError := new(error) readerGone := new(int32) newFm.ports[1] = &Port{ File: writer, Chan: ch, closeFile: true, closeChan: true, sendStop: sendStop, sendError: sendError, readerGone: readerGone} nextIn = &Port{ File: reader, Chan: ch, closeFile: true, closeChan: false, // Store in input port for ease of retrieval later sendStop: sendStop, sendError: sendError, readerGone: readerGone} } f := func(formOp effectOp, pexc *Exception) { exc := formOp.exec(newFm) if exc != nil && !(outputIsPipe && isReaderGone(exc)) { *pexc = exc } if inputIsPipe { input := newFm.ports[0] *input.sendError = errs.ReaderGone{} close(input.sendStop) atomic.StoreInt32(input.readerGone, 1) } newFm.Close() wg.Done() } if i == nforms-1 && !op.bg { f(formOp, &excs[i]) } else { go f(formOp, &excs[i]) } } if op.bg { // Background job, wait for form termination asynchronously. go func() { wg.Wait() fm.Evaler.addNumBgJobs(-1) if notify := fm.Evaler.BgJobNotify; notify != nil { msg := "job " + op.source + " finished" err := MakePipelineError(excs) if err != nil { msg += ", errors = " + err.Error() } if fm.Evaler.getNotifyBgJobSuccess() || err != nil { notify(msg) } } }() return nil } wg.Wait() return fm.errorp(op, MakePipelineError(excs)) } func isReaderGone(exc Exception) bool { _, ok := exc.Reason().(errs.ReaderGone) return ok } func (cp *compiler) formOp(n *parse.Form) effectOp { var tempLValues []lvalue var assignmentOps []effectOp if len(n.Assignments) > 0 { assignmentOps = cp.assignmentOps(n.Assignments) if n.Head == nil { cp.errorpf(n, `using the syntax of temporary assignment for non-temporary assignment is no longer supported; use "var" or "set" instead`) return nopOp{} } for _, a := range n.Assignments { lvalues := cp.parseIndexingLValue(a.Left, setLValue|newLValue) tempLValues = append(tempLValues, lvalues.lvalues...) } logger.Println("temporary assignment of", len(n.Assignments), "pairs") } redirOps := cp.redirOps(n.Redirs) body := cp.formBody(n) return &formOp{n.Range(), tempLValues, assignmentOps, redirOps, body} } func (cp *compiler) formBody(n *parse.Form) formBody { if n.Head == nil { // Compiling an incomplete form node, return an empty body. return formBody{} } // Determine if this form is a special command. if head, ok := cmpd.StringLiteral(n.Head); ok { special, _ := resolveCmdHeadInternally(cp, head, n.Head) if special != nil { specialOp := special(cp, n) return formBody{specialOp: specialOp} } } // Determine if the form is a legacy assignment form, by looking for an // argument whose source is a literal "=". for i, arg := range n.Args { if parse.SourceText(arg) == "=" { cp.deprecate(n, "legacy assignment form is deprecated, use var or set instead; migrate scripts with https://go.elv.sh/u0.17", 17) lhsNodes := make([]*parse.Compound, i+1) lhsNodes[0] = n.Head copy(lhsNodes[1:], n.Args[:i]) lhs := cp.parseCompoundLValues(lhsNodes, setLValue|newLValue) rhsOps := cp.compoundOps(n.Args[i+1:]) var rhsRange diag.Ranging if len(rhsOps) > 0 { rhsRange = diag.MixedRanging(rhsOps[0], rhsOps[len(rhsOps)-1]) } else { rhsRange = diag.PointRanging(n.Range().To) } rhs := seqValuesOp{rhsRange, rhsOps} return formBody{assignOp: &assignOp{n.Range(), lhs, rhs, false}} } } var headOp valuesOp if head, ok := cmpd.StringLiteral(n.Head); ok { // Head is a literal string: resolve to function or external (special // commands are already handled above). if _, fnRef := resolveCmdHeadInternally(cp, head, n.Head); fnRef != nil { headOp = variableOp{n.Head.Range(), false, head + FnSuffix, fnRef} } else if cp.currentPragma().unknownCommandIsExternal || fsutil.DontSearch(head) { headOp = literalValues(n.Head, NewExternalCmd(head)) } else { cp.errorpf(n.Head, "unknown command disallowed by current pragma") } } else { // Head is not a literal string: evaluate as a normal expression. headOp = cp.compoundOp(n.Head) } argOps := cp.compoundOps(n.Args) optsOp := cp.mapPairs(n.Opts) return formBody{ordinaryCmd: ordinaryCmd{headOp, argOps, optsOp}} } func (cp *compiler) formOps(ns []*parse.Form) []effectOp { ops := make([]effectOp, len(ns)) for i, n := range ns { ops[i] = cp.formOp(n) } return ops } type formOp struct { diag.Ranging tempLValues []lvalue tempAssignOps []effectOp redirOps []effectOp body formBody } type formBody struct { // Exactly one field will be populated. specialOp effectOp assignOp effectOp ordinaryCmd ordinaryCmd } type ordinaryCmd struct { headOp valuesOp argOps []valuesOp optsOp *mapPairsOp } func (op *formOp) exec(fm *Frame) (errRet Exception) { // fm here is always a sub-frame created in compiler.pipeline, so it can // be safely modified. // Temporary assignment. if len(op.tempLValues) > 0 { // There is a temporary assignment. // Save variables. var saveVars []vars.Var var saveVals []interface{} for _, lv := range op.tempLValues { variable, err := derefLValue(fm, lv) if err != nil { return fm.errorp(op, err) } saveVars = append(saveVars, variable) } for i, v := range saveVars { // TODO(xiaq): If the variable to save is a elemVariable, save // the outermost variable instead. if u := vars.HeadOfElement(v); u != nil { v = u saveVars[i] = v } val := v.Get() saveVals = append(saveVals, val) logger.Printf("saved %s = %s", v, val) } // Do assignment. for _, subop := range op.tempAssignOps { exc := subop.exec(fm) if exc != nil { return exc } } // Defer variable restoration. Will be executed even if an error // occurs when evaling other part of the form. defer func() { for i, v := range saveVars { val := saveVals[i] if val == nil { // TODO(xiaq): Old value is nonexistent. We should delete // the variable. However, since the compiler now doesn't // delete it, we don't delete it in the evaler either. val = "" } err := v.Set(val) if err != nil { errRet = fm.errorp(op, err) } logger.Printf("restored %s = %s", v, val) } }() } // Redirections. for _, redirOp := range op.redirOps { exc := redirOp.exec(fm) if exc != nil { return exc } } if op.body.specialOp != nil { return op.body.specialOp.exec(fm) } if op.body.assignOp != nil { return op.body.assignOp.exec(fm) } // Ordinary command: evaluate head, arguments and options. cmd := op.body.ordinaryCmd // Special case: evaluating an incomplete form node. Return directly. if cmd.headOp == nil { return nil } headFn, err := evalForCommand(fm, cmd.headOp, "command") if err != nil { return fm.errorp(cmd.headOp, err) } var args []interface{} for _, argOp := range cmd.argOps { moreArgs, exc := argOp.exec(fm) if exc != nil { return exc } args = append(args, moreArgs...) } // TODO(xiaq): This conversion should be avoided. convertedOpts := make(map[string]interface{}) exc := cmd.optsOp.exec(fm, func(k, v interface{}) Exception { if ks, ok := k.(string); ok { convertedOpts[ks] = v return nil } // TODO(xiaq): Point to the particular key. return fm.errorp(op, errs.BadValue{ What: "option key", Valid: "string", Actual: vals.Kind(k)}) }) if exc != nil { return exc } fm.traceback = fm.addTraceback(op) err = headFn.Call(fm, args, convertedOpts) if exc, ok := err.(Exception); ok { return exc } return &exception{err, fm.traceback} } func evalForCommand(fm *Frame, op valuesOp, what string) (Callable, error) { value, err := evalForValue(fm, op, what) if err != nil { return nil, err } switch value := value.(type) { case Callable: return value, nil case string: if fsutil.DontSearch(value) { return NewExternalCmd(value), nil } } return nil, fm.errorp(op, errs.BadValue{ What: what, Valid: "callable or string containing slash", Actual: vals.Repr(value, vals.NoPretty)}) } func allTrue(vs []interface{}) bool { for _, v := range vs { if !vals.Bool(v) { return false } } return true } func (cp *compiler) assignmentOp(n *parse.Assignment) effectOp { lhs := cp.parseIndexingLValue(n.Left, setLValue|newLValue) rhs := cp.compoundOp(n.Right) return &assignOp{n.Range(), lhs, rhs, false} } func (cp *compiler) assignmentOps(ns []*parse.Assignment) []effectOp { ops := make([]effectOp, len(ns)) for i, n := range ns { ops[i] = cp.assignmentOp(n) } return ops } const defaultFileRedirPerm = 0644 // redir compiles a Redir into a op. func (cp *compiler) redirOp(n *parse.Redir) effectOp { var dstOp valuesOp if n.Left != nil { dstOp = cp.compoundOp(n.Left) } flag := makeFlag(n.Mode) if flag == -1 { // TODO: Record and get redirection sign position cp.errorpf(n, "bad redirection sign") } return &redirOp{n.Range(), dstOp, cp.compoundOp(n.Right), n.RightIsFd, n.Mode, flag} } func (cp *compiler) redirOps(ns []*parse.Redir) []effectOp { ops := make([]effectOp, len(ns)) for i, n := range ns { ops[i] = cp.redirOp(n) } return ops } func makeFlag(m parse.RedirMode) int { switch m { case parse.Read: return os.O_RDONLY case parse.Write: return os.O_WRONLY | os.O_CREATE | os.O_TRUNC case parse.ReadWrite: return os.O_RDWR | os.O_CREATE case parse.Append: return os.O_WRONLY | os.O_CREATE | os.O_APPEND default: return -1 } } type redirOp struct { diag.Ranging dstOp valuesOp srcOp valuesOp srcIsFd bool mode parse.RedirMode flag int } type InvalidFD struct{ FD int } func (err InvalidFD) Error() string { return fmt.Sprintf("invalid fd: %d", err.FD) } func (op *redirOp) exec(fm *Frame) Exception { var dst int if op.dstOp == nil { // No explicit FD destination specified; use default destinations switch op.mode { case parse.Read: dst = 0 case parse.Write, parse.ReadWrite, parse.Append: dst = 1 default: return fm.errorpf(op, "bad RedirMode; parser bug") } } else { // An explicit FD destination specified, evaluate it. var err error dst, err = evalForFd(fm, op.dstOp, false, "redirection destination") if err != nil { return fm.errorp(op, err) } } growPorts(&fm.ports, dst+1) fm.ports[dst].close() if op.srcIsFd { src, err := evalForFd(fm, op.srcOp, true, "redirection source") if err != nil { return fm.errorp(op, err) } switch { case src == -1: // close fm.ports[dst] = &Port{ // Ensure that writing to value output throws an exception sendStop: closedSendStop, sendError: &ErrNoValueOutput} case src >= len(fm.ports) || fm.ports[src] == nil: return fm.errorp(op, InvalidFD{FD: src}) default: fm.ports[dst] = fm.ports[src].fork() } return nil } src, err := evalForValue(fm, op.srcOp, "redirection source") if err != nil { return fm.errorp(op, err) } switch src := src.(type) { case string: f, err := os.OpenFile(src, op.flag, defaultFileRedirPerm) if err != nil { return fm.errorpf(op, "failed to open file %s: %s", vals.Repr(src, vals.NoPretty), err) } fm.ports[dst] = fileRedirPort(op.mode, f, true) case vals.File: fm.ports[dst] = fileRedirPort(op.mode, src, false) case vals.Pipe: var f *os.File switch op.mode { case parse.Read: f = src.ReadEnd case parse.Write: f = src.WriteEnd default: return fm.errorpf(op, "can only use < or > with pipes") } fm.ports[dst] = fileRedirPort(op.mode, f, false) default: return fm.errorp(op.srcOp, errs.BadValue{ What: "redirection source", Valid: "string, file or pipe", Actual: vals.Kind(src)}) } return nil } // Creates a port that only have a file component, populating the // channel-related fields with suitable values depending on the redirection // mode. func fileRedirPort(mode parse.RedirMode, f *os.File, closeFile bool) *Port { if mode == parse.Read { return &Port{ File: f, closeFile: closeFile, // ClosedChan produces no values when reading. Chan: ClosedChan, } } return &Port{ File: f, closeFile: closeFile, // Throws errValueOutputIsClosed when writing. Chan: nil, sendStop: closedSendStop, sendError: &ErrNoValueOutput, } } // Makes the size of *ports at least n, adding nil's if necessary. func growPorts(ports *[]*Port, n int) { if len(*ports) >= n { return } oldPorts := *ports *ports = make([]*Port, n) copy(*ports, oldPorts) } func evalForFd(fm *Frame, op valuesOp, closeOK bool, what string) (int, error) { value, err := evalForValue(fm, op, what) if err != nil { return -1, err } switch value { case "stdin": return 0, nil case "stdout": return 1, nil case "stderr": return 2, nil } var fd int if vals.ScanToGo(value, &fd) == nil { return fd, nil } else if value == "-" && closeOK { return -1, nil } valid := "fd name or number" if closeOK { valid = "fd name or number or '-'" } return -1, fm.errorp(op, errs.BadValue{ What: what, Valid: valid, Actual: vals.Repr(value, vals.NoPretty)}) } type seqOp struct{ subops []effectOp } func (op seqOp) exec(fm *Frame) Exception { for _, subop := range op.subops { exc := subop.exec(fm) if exc != nil { return exc } } return nil } type nopOp struct{} func (nopOp) exec(fm *Frame) Exception { return nil }