Documentation ¶
Index ¶
Constants ¶
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Variables ¶
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var ErrEmptyNode = errors.New("no data or links in this node")
ErrEmptyNode is returned when the input to 'ipfs object put' contains no data
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var ErrObjectTooLarge = errors.New("input object was too large. limit is 512kbytes")
ErrObjectTooLarge is returned when too much data was read from stdin. current limit 512k
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var ErrUnknownObjectEnc = errors.New("unknown object encoding")
ErrUnknownObjectEnc is returned if a invalid encoding is supplied
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var ObjectCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Interact with ipfs objects.", ShortDescription: ` 'ipfs object' is a plumbing command used to manipulate DAG objects directly.`, }, Subcommands: map[string]*cmds.Command{ "data": ObjectDataCmd, "diff": ObjectDiffCmd, "get": ObjectGetCmd, "links": ObjectLinksCmd, "new": ObjectNewCmd, "patch": ObjectPatchCmd, "put": ObjectPutCmd, "stat": ObjectStatCmd, }, }
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var ObjectDataCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Outputs the raw bytes in an IPFS object.", ShortDescription: ` 'ipfs object data' is a plumbing command for retrieving the raw bytes stored in a DAG node. It outputs to stdout, and <key> is a base58 encoded multihash. `, LongDescription: ` 'ipfs object data' is a plumbing command for retrieving the raw bytes stored in a DAG node. It outputs to stdout, and <key> is a base58 encoded multihash. Note that the "--encoding" option does not affect the output, since the output is the raw data of the object. `, }, Arguments: []cmds.Argument{ cmds.StringArg("key", true, false, "Key of the object to retrieve, in base58-encoded multihash format."), }, Run: func(req cmds.Request, res cmds.Response) { n, err := req.InvocContext().GetNode() if err != nil { res.SetError(err, cmds.ErrNormal) return } fpath := path.Path(req.Arguments()[0]) node, err := core.Resolve(req.Context(), n, fpath) if err != nil { res.SetError(err, cmds.ErrNormal) return } res.SetOutput(bytes.NewReader(node.Data)) }, }
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var ObjectDiffCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Takes a diff of the two given objects.", ShortDescription: ` 'ipfs object diff' is a command used to show the differences between two ipfs objects.`, LongDescription: ` 'ipfs object diff' is a command used to show the differences between two ipfs objects. Example: > ls foo bar baz/ giraffe > ipfs add -r foo ... Added QmegHcnrPgMwC7tBiMxChD54fgQMBUecNw9nE9UUU4x1bz foo > OBJ_A=QmegHcnrPgMwC7tBiMxChD54fgQMBUecNw9nE9UUU4x1bz > echo "different content" > foo/bar > ipfs add -r foo ... Added QmcmRptkSPWhptCttgHg27QNDmnV33wAJyUkCnAvqD3eCD foo > OBJ_B=QmcmRptkSPWhptCttgHg27QNDmnV33wAJyUkCnAvqD3eCD > ipfs object diff -v $OBJ_A $OBJ_B Changed "bar" from QmNgd5cz2jNftnAHBhcRUGdtiaMzb5Rhjqd4etondHHST8 to QmRfFVsjSXkhFxrfWnLpMae2M4GBVsry6VAuYYcji5MiZb. `, }, Arguments: []cmds.Argument{ cmds.StringArg("obj_a", true, false, "Object to diff against."), cmds.StringArg("obj_b", true, false, "Object to diff."), }, Options: []cmds.Option{ cmds.BoolOption("verbose", "v", "Print extra information."), }, Run: func(req cmds.Request, res cmds.Response) { node, err := req.InvocContext().GetNode() if err != nil { res.SetError(err, cmds.ErrNormal) return } a := req.Arguments()[0] b := req.Arguments()[1] pa, err := path.ParsePath(a) if err != nil { res.SetError(err, cmds.ErrNormal) return } pb, err := path.ParsePath(b) if err != nil { res.SetError(err, cmds.ErrNormal) return } ctx := req.Context() obj_a, err := core.Resolve(ctx, node, pa) if err != nil { res.SetError(err, cmds.ErrNormal) return } obj_b, err := core.Resolve(ctx, node, pb) if err != nil { res.SetError(err, cmds.ErrNormal) return } changes, err := dagutils.Diff(ctx, node.DAG, obj_a, obj_b) if err != nil { res.SetError(err, cmds.ErrNormal) return } res.SetOutput(&Changes{changes}) }, Type: Changes{}, Marshalers: cmds.MarshalerMap{ cmds.Text: func(res cmds.Response) (io.Reader, error) { verbose, _, _ := res.Request().Option("v").Bool() changes := res.Output().(*Changes) buf := new(bytes.Buffer) for _, change := range changes.Changes { if verbose { switch change.Type { case dagutils.Add: fmt.Fprintf(buf, "Added new link %q pointing to %s.\n", change.Path, change.After) case dagutils.Mod: fmt.Fprintf(buf, "Changed %q from %s to %s.\n", change.Path, change.Before, change.After) case dagutils.Remove: fmt.Fprintf(buf, "Removed link %q (was %s).\n", change.Path, change.Before) } } else { switch change.Type { case dagutils.Add: fmt.Fprintf(buf, "+ %s %q\n", change.After, change.Path) case dagutils.Mod: fmt.Fprintf(buf, "~ %s %s %q\n", change.Before, change.After, change.Path) case dagutils.Remove: fmt.Fprintf(buf, "- %s %q\n", change.Before, change.Path) } } } return buf, nil }, }, }
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var ObjectGetCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Get and serialize the DAG node named by <key>.", ShortDescription: ` 'ipfs object get' is a plumbing command for retrieving DAG nodes. It serializes the DAG node to the format specified by the "--encoding" flag. It outputs to stdout, and <key> is a base58 encoded multihash. `, LongDescription: ` 'ipfs object get' is a plumbing command for retrieving DAG nodes. It serializes the DAG node to the format specified by the "--encoding" flag. It outputs to stdout, and <key> is a base58 encoded multihash. This command outputs data in the following encodings: * "protobuf" * "json" * "xml" (Specified by the "--encoding" or "-enc" flag)`, }, Arguments: []cmds.Argument{ cmds.StringArg("key", true, false, "Key of the object to retrieve, in base58-encoded multihash format."), }, Run: func(req cmds.Request, res cmds.Response) { n, err := req.InvocContext().GetNode() if err != nil { res.SetError(err, cmds.ErrNormal) return } fpath := path.Path(req.Arguments()[0]) object, err := core.Resolve(req.Context(), n, fpath) if err != nil { res.SetError(err, cmds.ErrNormal) return } node := &Node{ Links: make([]Link, len(object.Links)), Data: string(object.Data), } for i, link := range object.Links { node.Links[i] = Link{ Hash: link.Hash.B58String(), Name: link.Name, Size: link.Size, } } res.SetOutput(node) }, Type: Node{}, Marshalers: cmds.MarshalerMap{ cmds.Protobuf: func(res cmds.Response) (io.Reader, error) { node := res.Output().(*Node) object, err := deserializeNode(node, "text") if err != nil { return nil, err } marshaled, err := object.Marshal() if err != nil { return nil, err } return bytes.NewReader(marshaled), nil }, }, }
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var ObjectLinksCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Outputs the links pointed to by the specified object.", ShortDescription: ` 'ipfs object links' is a plumbing command for retrieving the links from a DAG node. It outputs to stdout, and <key> is a base58 encoded multihash. `, }, Arguments: []cmds.Argument{ cmds.StringArg("key", true, false, "Key of the object to retrieve, in base58-encoded multihash format."), }, Options: []cmds.Option{ cmds.BoolOption("headers", "v", "Print table headers (Hash, Size, Name).").Default(false), }, Run: func(req cmds.Request, res cmds.Response) { n, err := req.InvocContext().GetNode() if err != nil { res.SetError(err, cmds.ErrNormal) return } if _, _, err := req.Option("headers").Bool(); err != nil { res.SetError(err, cmds.ErrNormal) return } fpath := path.Path(req.Arguments()[0]) node, err := core.Resolve(req.Context(), n, fpath) if err != nil { res.SetError(err, cmds.ErrNormal) return } output, err := getOutput(node) if err != nil { res.SetError(err, cmds.ErrNormal) return } res.SetOutput(output) }, Marshalers: cmds.MarshalerMap{ cmds.Text: func(res cmds.Response) (io.Reader, error) { object := res.Output().(*Object) buf := new(bytes.Buffer) w := tabwriter.NewWriter(buf, 1, 2, 1, ' ', 0) headers, _, _ := res.Request().Option("headers").Bool() if headers { fmt.Fprintln(w, "Hash\tSize\tName\t") } for _, link := range object.Links { fmt.Fprintf(w, "%s\t%v\t%s\t\n", link.Hash, link.Size, link.Name) } w.Flush() return buf, nil }, }, Type: Object{}, }
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var ObjectNewCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Creates a new object from an ipfs template.", ShortDescription: ` 'ipfs object new' is a plumbing command for creating new DAG nodes. `, LongDescription: ` 'ipfs object new' is a plumbing command for creating new DAG nodes. By default it creates and returns a new empty merkledag node, but you may pass an optional template argument to create a preformatted node. Available templates: * unixfs-dir `, }, Arguments: []cmds.Argument{ cmds.StringArg("template", false, false, "Template to use. Optional."), }, Run: func(req cmds.Request, res cmds.Response) { n, err := req.InvocContext().GetNode() if err != nil { res.SetError(err, cmds.ErrNormal) return } node := new(dag.Node) if len(req.Arguments()) == 1 { template := req.Arguments()[0] var err error node, err = nodeFromTemplate(template) if err != nil { res.SetError(err, cmds.ErrNormal) return } } k, err := n.DAG.Add(node) if err != nil { res.SetError(err, cmds.ErrNormal) return } res.SetOutput(&Object{Hash: k.B58String()}) }, Marshalers: cmds.MarshalerMap{ cmds.Text: func(res cmds.Response) (io.Reader, error) { object := res.Output().(*Object) return strings.NewReader(object.Hash + "\n"), nil }, }, Type: Object{}, }
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var ObjectPatchCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Create a new merkledag object based on an existing one.", ShortDescription: ` 'ipfs object patch <root> <cmd> <args>' is a plumbing command used to build custom DAG objects. It mutates objects, creating new objects as a result. This is the Merkle-DAG version of modifying an object. `, }, Arguments: []cmds.Argument{}, Subcommands: map[string]*cmds.Command{ "append-data": patchAppendDataCmd, "add-link": patchAddLinkCmd, "rm-link": patchRmLinkCmd, "set-data": patchSetDataCmd, }, }
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var ObjectPutCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Stores input as a DAG object, outputs its key.", ShortDescription: ` 'ipfs object put' is a plumbing command for storing DAG nodes. It reads from stdin, and the output is a base58 encoded multihash. `, LongDescription: ` 'ipfs object put' is a plumbing command for storing DAG nodes. It reads from stdin, and the output is a base58 encoded multihash. Data should be in the format specified by the --inputenc flag. --inputenc may be one of the following: * "protobuf" * "json" (default) Examples: $ echo '{ "Data": "abc" }' | ipfs object put This creates a node with the data 'abc' and no links. For an object with links, create a file named 'node.json' with the contents: { "Data": "another", "Links": [ { "Name": "some link", "Hash": "QmXg9Pp2ytZ14xgmQjYEiHjVjMFXzCVVEcRTWJBmLgR39V", "Size": 8 } ] } And then run: $ ipfs object put node.json `, }, Arguments: []cmds.Argument{ cmds.FileArg("data", true, false, "Data to be stored as a DAG object.").EnableStdin(), }, Options: []cmds.Option{ cmds.StringOption("inputenc", "Encoding type of input data. One of: {\"protobuf\", \"json\"}.").Default("json"), cmds.StringOption("datafieldenc", "Encoding type of the data field, either \"text\" or \"base64\".").Default("text"), }, Run: func(req cmds.Request, res cmds.Response) { n, err := req.InvocContext().GetNode() if err != nil { res.SetError(err, cmds.ErrNormal) return } input, err := req.Files().NextFile() if err != nil && err != io.EOF { res.SetError(err, cmds.ErrNormal) return } inputenc, _, err := req.Option("inputenc").String() if err != nil { res.SetError(err, cmds.ErrNormal) return } datafieldenc, _, err := req.Option("datafieldenc").String() if err != nil { res.SetError(err, cmds.ErrNormal) return } output, err := objectPut(n, input, inputenc, datafieldenc) if err != nil { errType := cmds.ErrNormal if err == ErrUnknownObjectEnc { errType = cmds.ErrClient } res.SetError(err, errType) return } res.SetOutput(output) }, Marshalers: cmds.MarshalerMap{ cmds.Text: func(res cmds.Response) (io.Reader, error) { object := res.Output().(*Object) return strings.NewReader("added " + object.Hash + "\n"), nil }, }, Type: Object{}, }
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var ObjectStatCmd = &cmds.Command{ Helptext: cmds.HelpText{ Tagline: "Get stats for the DAG node named by <key>.", ShortDescription: ` 'ipfs object stat' is a plumbing command to print DAG node statistics. <key> is a base58 encoded multihash. It outputs to stdout: NumLinks int number of links in link table BlockSize int size of the raw, encoded data LinksSize int size of the links segment DataSize int size of the data segment CumulativeSize int cumulative size of object and its references `, }, Arguments: []cmds.Argument{ cmds.StringArg("key", true, false, "Key of the object to retrieve, in base58-encoded multihash format."), }, Run: func(req cmds.Request, res cmds.Response) { n, err := req.InvocContext().GetNode() if err != nil { res.SetError(err, cmds.ErrNormal) return } fpath := path.Path(req.Arguments()[0]) object, err := core.Resolve(req.Context(), n, fpath) if err != nil { res.SetError(err, cmds.ErrNormal) return } ns, err := object.Stat() if err != nil { res.SetError(err, cmds.ErrNormal) return } res.SetOutput(ns) }, Type: dag.NodeStat{}, Marshalers: cmds.MarshalerMap{ cmds.Text: func(res cmds.Response) (io.Reader, error) { ns := res.Output().(*dag.NodeStat) buf := new(bytes.Buffer) w := func(s string, n int) { fmt.Fprintf(buf, "%s: %d\n", s, n) } w("NumLinks", ns.NumLinks) w("BlockSize", ns.BlockSize) w("LinksSize", ns.LinksSize) w("DataSize", ns.DataSize) w("CumulativeSize", ns.CumulativeSize) return buf, nil }, }, }
Functions ¶
Types ¶
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