vendor/github.com/hashicorp/consul/api/kv.go - voltha-go - Gitiles

 package api

 import (
 	"bytes"
 	"fmt"
 	"io"
 	"net/http"
 	"strconv"
 	"strings"
 )

 // KVPair is used to represent a single K/V entry
 type KVPair struct {
 	// Key is the name of the key. It is also part of the URL path when accessed
 	// via the API.
 	Key string

 	// CreateIndex holds the index corresponding the creation of this KVPair. This
 	// is a read-only field.
 	CreateIndex uint64

 	// ModifyIndex is used for the Check-And-Set operations and can also be fed
 	// back into the WaitIndex of the QueryOptions in order to perform blocking
 	// queries.
 	ModifyIndex uint64

 	// LockIndex holds the index corresponding to a lock on this key, if any. This
 	// is a read-only field.
 	LockIndex uint64

 	// Flags are any user-defined flags on the key. It is up to the implementer
 	// to check these values, since Consul does not treat them specially.
 	Flags uint64

 	// Value is the value for the key. This can be any value, but it will be
 	// base64 encoded upon transport.
 	Value []byte

 	// Session is a string representing the ID of the session. Any other
 	// interactions with this key over the same session must specify the same
 	// session ID.
 	Session string
 }

 // KVPairs is a list of KVPair objects
 type KVPairs []*KVPair

 // KVOp constants give possible operations available in a KVTxn.
 type KVOp string

 const (
 	KVSet            KVOp = "set"
 	KVDelete         KVOp = "delete"
 	KVDeleteCAS      KVOp = "delete-cas"
 	KVDeleteTree     KVOp = "delete-tree"
 	KVCAS            KVOp = "cas"
 	KVLock           KVOp = "lock"
 	KVUnlock         KVOp = "unlock"
 	KVGet            KVOp = "get"
 	KVGetTree        KVOp = "get-tree"
 	KVCheckSession   KVOp = "check-session"
 	KVCheckIndex     KVOp = "check-index"
 	KVCheckNotExists KVOp = "check-not-exists"
 )

 // KVTxnOp defines a single operation inside a transaction.
 type KVTxnOp struct {
 	Verb    KVOp
 	Key     string
 	Value   []byte
 	Flags   uint64
 	Index   uint64
 	Session string
 }

 // KVTxnOps defines a set of operations to be performed inside a single
 // transaction.
 type KVTxnOps []*KVTxnOp

 // KVTxnResponse has the outcome of a transaction.
 type KVTxnResponse struct {
 	Results []*KVPair
 	Errors  TxnErrors
 }

 // KV is used to manipulate the K/V API
 type KV struct {
 	c *Client
 }

 // KV is used to return a handle to the K/V apis
 func (c *Client) KV() *KV {
 	return &KV{c}
 }

 // Get is used to lookup a single key. The returned pointer
 // to the KVPair will be nil if the key does not exist.
 func (k *KV) Get(key string, q *QueryOptions) (*KVPair, *QueryMeta, error) {
 	resp, qm, err := k.getInternal(key, nil, q)
 	if err != nil {
 		return nil, nil, err
 	}
 	if resp == nil {
 		return nil, qm, nil
 	}
 	defer resp.Body.Close()

 	var entries []*KVPair
 	if err := decodeBody(resp, &entries); err != nil {
 		return nil, nil, err
 	}
 	if len(entries) > 0 {
 		return entries[0], qm, nil
 	}
 	return nil, qm, nil
 }

 // List is used to lookup all keys under a prefix
 func (k *KV) List(prefix string, q *QueryOptions) (KVPairs, *QueryMeta, error) {
 	resp, qm, err := k.getInternal(prefix, map[string]string{"recurse": ""}, q)
 	if err != nil {
 		return nil, nil, err
 	}
 	if resp == nil {
 		return nil, qm, nil
 	}
 	defer resp.Body.Close()

 	var entries []*KVPair
 	if err := decodeBody(resp, &entries); err != nil {
 		return nil, nil, err
 	}
 	return entries, qm, nil
 }

 // Keys is used to list all the keys under a prefix. Optionally,
 // a separator can be used to limit the responses.
 func (k *KV) Keys(prefix, separator string, q *QueryOptions) ([]string, *QueryMeta, error) {
 	params := map[string]string{"keys": ""}
 	if separator != "" {
 		params["separator"] = separator
 	}
 	resp, qm, err := k.getInternal(prefix, params, q)
 	if err != nil {
 		return nil, nil, err
 	}
 	if resp == nil {
 		return nil, qm, nil
 	}
 	defer resp.Body.Close()

 	var entries []string
 	if err := decodeBody(resp, &entries); err != nil {
 		return nil, nil, err
 	}
 	return entries, qm, nil
 }

 func (k *KV) getInternal(key string, params map[string]string, q *QueryOptions) (*http.Response, *QueryMeta, error) {
 	r := k.c.newRequest("GET", "/v1/kv/"+strings.TrimPrefix(key, "/"))
 	r.setQueryOptions(q)
 	for param, val := range params {
 		r.params.Set(param, val)
 	}
 	rtt, resp, err := k.c.doRequest(r)
 	if err != nil {
 		return nil, nil, err
 	}

 	qm := &QueryMeta{}
 	parseQueryMeta(resp, qm)
 	qm.RequestTime = rtt

 	if resp.StatusCode == 404 {
 		resp.Body.Close()
 		return nil, qm, nil
 	} else if resp.StatusCode != 200 {
 		resp.Body.Close()
 		return nil, nil, fmt.Errorf("Unexpected response code: %d", resp.StatusCode)
 	}
 	return resp, qm, nil
 }

 // Put is used to write a new value. Only the
 // Key, Flags and Value is respected.
 func (k *KV) Put(p *KVPair, q *WriteOptions) (*WriteMeta, error) {
 	params := make(map[string]string, 1)
 	if p.Flags != 0 {
 		params["flags"] = strconv.FormatUint(p.Flags, 10)
 	}
 	_, wm, err := k.put(p.Key, params, p.Value, q)
 	return wm, err
 }

 // CAS is used for a Check-And-Set operation. The Key,
 // ModifyIndex, Flags and Value are respected. Returns true
 // on success or false on failures.
 func (k *KV) CAS(p *KVPair, q *WriteOptions) (bool, *WriteMeta, error) {
 	params := make(map[string]string, 2)
 	if p.Flags != 0 {
 		params["flags"] = strconv.FormatUint(p.Flags, 10)
 	}
 	params["cas"] = strconv.FormatUint(p.ModifyIndex, 10)
 	return k.put(p.Key, params, p.Value, q)
 }

 // Acquire is used for a lock acquisition operation. The Key,
 // Flags, Value and Session are respected. Returns true
 // on success or false on failures.
 func (k *KV) Acquire(p *KVPair, q *WriteOptions) (bool, *WriteMeta, error) {
 	params := make(map[string]string, 2)
 	if p.Flags != 0 {
 		params["flags"] = strconv.FormatUint(p.Flags, 10)
 	}
 	params["acquire"] = p.Session
 	return k.put(p.Key, params, p.Value, q)
 }

 // Release is used for a lock release operation. The Key,
 // Flags, Value and Session are respected. Returns true
 // on success or false on failures.
 func (k *KV) Release(p *KVPair, q *WriteOptions) (bool, *WriteMeta, error) {
 	params := make(map[string]string, 2)
 	if p.Flags != 0 {
 		params["flags"] = strconv.FormatUint(p.Flags, 10)
 	}
 	params["release"] = p.Session
 	return k.put(p.Key, params, p.Value, q)
 }

 func (k *KV) put(key string, params map[string]string, body []byte, q *WriteOptions) (bool, *WriteMeta, error) {
 	if len(key) > 0 && key[0] == '/' {
 		return false, nil, fmt.Errorf("Invalid key. Key must not begin with a '/': %s", key)
 	}

 	r := k.c.newRequest("PUT", "/v1/kv/"+key)
 	r.setWriteOptions(q)
 	for param, val := range params {
 		r.params.Set(param, val)
 	}
 	r.body = bytes.NewReader(body)
 	rtt, resp, err := requireOK(k.c.doRequest(r))
 	if err != nil {
 		return false, nil, err
 	}
 	defer resp.Body.Close()

 	qm := &WriteMeta{}
 	qm.RequestTime = rtt

 	var buf bytes.Buffer
 	if _, err := io.Copy(&buf, resp.Body); err != nil {
 		return false, nil, fmt.Errorf("Failed to read response: %v", err)
 	}
 	res := strings.Contains(buf.String(), "true")
 	return res, qm, nil
 }

 // Delete is used to delete a single key
 func (k *KV) Delete(key string, w *WriteOptions) (*WriteMeta, error) {
 	_, qm, err := k.deleteInternal(key, nil, w)
 	return qm, err
 }

 // DeleteCAS is used for a Delete Check-And-Set operation. The Key
 // and ModifyIndex are respected. Returns true on success or false on failures.
 func (k *KV) DeleteCAS(p *KVPair, q *WriteOptions) (bool, *WriteMeta, error) {
 	params := map[string]string{
 		"cas": strconv.FormatUint(p.ModifyIndex, 10),
 	}
 	return k.deleteInternal(p.Key, params, q)
 }

 // DeleteTree is used to delete all keys under a prefix
 func (k *KV) DeleteTree(prefix string, w *WriteOptions) (*WriteMeta, error) {
 	_, qm, err := k.deleteInternal(prefix, map[string]string{"recurse": ""}, w)
 	return qm, err
 }

 func (k *KV) deleteInternal(key string, params map[string]string, q *WriteOptions) (bool, *WriteMeta, error) {
 	r := k.c.newRequest("DELETE", "/v1/kv/"+strings.TrimPrefix(key, "/"))
 	r.setWriteOptions(q)
 	for param, val := range params {
 		r.params.Set(param, val)
 	}
 	rtt, resp, err := requireOK(k.c.doRequest(r))
 	if err != nil {
 		return false, nil, err
 	}
 	defer resp.Body.Close()

 	qm := &WriteMeta{}
 	qm.RequestTime = rtt

 	var buf bytes.Buffer
 	if _, err := io.Copy(&buf, resp.Body); err != nil {
 		return false, nil, fmt.Errorf("Failed to read response: %v", err)
 	}
 	res := strings.Contains(buf.String(), "true")
 	return res, qm, nil
 }

 // TxnOp is the internal format we send to Consul. It's not specific to KV,
 // though currently only KV operations are supported.
 type TxnOp struct {
 	KV *KVTxnOp
 }

 // TxnOps is a list of transaction operations.
 type TxnOps []*TxnOp

 // TxnResult is the internal format we receive from Consul.
 type TxnResult struct {
 	KV *KVPair
 }

 // TxnResults is a list of TxnResult objects.
 type TxnResults []*TxnResult

 // TxnError is used to return information about an operation in a transaction.
 type TxnError struct {
 	OpIndex int
 	What    string
 }

 // TxnErrors is a list of TxnError objects.
 type TxnErrors []*TxnError

 // TxnResponse is the internal format we receive from Consul.
 type TxnResponse struct {
 	Results TxnResults
 	Errors  TxnErrors
 }

 // Txn is used to apply multiple KV operations in a single, atomic transaction.
 //
 // Note that Go will perform the required base64 encoding on the values
 // automatically because the type is a byte slice. Transactions are defined as a
 // list of operations to perform, using the KVOp constants and KVTxnOp structure
 // to define operations. If any operation fails, none of the changes are applied
 // to the state store. Note that this hides the internal raw transaction interface
 // and munges the input and output types into KV-specific ones for ease of use.
 // If there are more non-KV operations in the future we may break out a new
 // transaction API client, but it will be easy to keep this KV-specific variant
 // supported.
 //
 // Even though this is generally a write operation, we take a QueryOptions input
 // and return a QueryMeta output. If the transaction contains only read ops, then
 // Consul will fast-path it to a different endpoint internally which supports
 // consistency controls, but not blocking. If there are write operations then
 // the request will always be routed through raft and any consistency settings
 // will be ignored.
 //
 // Here's an example:
 //
 //	   ops := KVTxnOps{
 //		   &KVTxnOp{
 //			   Verb:    KVLock,
 //			   Key:     "test/lock",
 //			   Session: "adf4238a-882b-9ddc-4a9d-5b6758e4159e",
 //			   Value:   []byte("hello"),
 //		   },
 //		   &KVTxnOp{
 //			   Verb:    KVGet,
 //			   Key:     "another/key",
 //		   },
 //	   }
 //	   ok, response, _, err := kv.Txn(&ops, nil)
 //
 // If there is a problem making the transaction request then an error will be
 // returned. Otherwise, the ok value will be true if the transaction succeeded
 // or false if it was rolled back. The response is a structured return value which
 // will have the outcome of the transaction. Its Results member will have entries
 // for each operation. Deleted keys will have a nil entry in the, and to save
 // space, the Value of each key in the Results will be nil unless the operation
 // is a KVGet. If the transaction was rolled back, the Errors member will have
 // entries referencing the index of the operation that failed along with an error
 // message.
 func (k *KV) Txn(txn KVTxnOps, q *QueryOptions) (bool, *KVTxnResponse, *QueryMeta, error) {
 	r := k.c.newRequest("PUT", "/v1/txn")
 	r.setQueryOptions(q)

 	// Convert into the internal format since this is an all-KV txn.
 	ops := make(TxnOps, 0, len(txn))
 	for _, kvOp := range txn {
 		ops = append(ops, &TxnOp{KV: kvOp})
 	}
 	r.obj = ops
 	rtt, resp, err := k.c.doRequest(r)
 	if err != nil {
 		return false, nil, nil, err
 	}
 	defer resp.Body.Close()

 	qm := &QueryMeta{}
 	parseQueryMeta(resp, qm)
 	qm.RequestTime = rtt

 	if resp.StatusCode == http.StatusOK || resp.StatusCode == http.StatusConflict {
 		var txnResp TxnResponse
 		if err := decodeBody(resp, &txnResp); err != nil {
 			return false, nil, nil, err
 		}

 		// Convert from the internal format.
 		kvResp := KVTxnResponse{
 			Errors: txnResp.Errors,
 		}
 		for _, result := range txnResp.Results {
 			kvResp.Results = append(kvResp.Results, result.KV)
 		}
 		return resp.StatusCode == http.StatusOK, &kvResp, qm, nil
 	}

 	var buf bytes.Buffer
 	if _, err := io.Copy(&buf, resp.Body); err != nil {
 		return false, nil, nil, fmt.Errorf("Failed to read response: %v", err)
 	}
 	return false, nil, nil, fmt.Errorf("Failed request: %s", buf.String())
 }
	package api

	import (
	"bytes"
	"fmt"
	"io"
	"net/http"
	"strconv"
	"strings"
	)

	// KVPair is used to represent a single K/V entry
	type KVPair struct {
	// Key is the name of the key. It is also part of the URL path when accessed
	// via the API.
	Key string

	// CreateIndex holds the index corresponding the creation of this KVPair. This
	// is a read-only field.
	CreateIndex uint64

	// ModifyIndex is used for the Check-And-Set operations and can also be fed
	// back into the WaitIndex of the QueryOptions in order to perform blocking
	// queries.
	ModifyIndex uint64

	// LockIndex holds the index corresponding to a lock on this key, if any. This
	// is a read-only field.
	LockIndex uint64

	// Flags are any user-defined flags on the key. It is up to the implementer
	// to check these values, since Consul does not treat them specially.
	Flags uint64

	// Value is the value for the key. This can be any value, but it will be
	// base64 encoded upon transport.
	Value []byte

	// Session is a string representing the ID of the session. Any other
	// interactions with this key over the same session must specify the same
	// session ID.
	Session string
	}

	// KVPairs is a list of KVPair objects
	type KVPairs []*KVPair

	// KVOp constants give possible operations available in a KVTxn.
	type KVOp string

	const (
	KVSet KVOp = "set"
	KVDelete KVOp = "delete"
	KVDeleteCAS KVOp = "delete-cas"
	KVDeleteTree KVOp = "delete-tree"
	KVCAS KVOp = "cas"
	KVLock KVOp = "lock"
	KVUnlock KVOp = "unlock"
	KVGet KVOp = "get"
	KVGetTree KVOp = "get-tree"
	KVCheckSession KVOp = "check-session"
	KVCheckIndex KVOp = "check-index"
	KVCheckNotExists KVOp = "check-not-exists"
	)

	// KVTxnOp defines a single operation inside a transaction.
	type KVTxnOp struct {
	Verb KVOp
	Key string
	Value []byte
	Flags uint64
	Index uint64
	Session string
	}

	// KVTxnOps defines a set of operations to be performed inside a single
	// transaction.
	type KVTxnOps []*KVTxnOp

	// KVTxnResponse has the outcome of a transaction.
	type KVTxnResponse struct {
	Results []*KVPair
	Errors TxnErrors
	}

	// KV is used to manipulate the K/V API
	type KV struct {
	c *Client
	}

	// KV is used to return a handle to the K/V apis
	func (c Client) KV() KV {
	return &KV{c}
	}

	// Get is used to lookup a single key. The returned pointer
	// to the KVPair will be nil if the key does not exist.
	func (k KV) Get(key string, q QueryOptions) (KVPair, QueryMeta, error) {
	resp, qm, err := k.getInternal(key, nil, q)
	if err != nil {
	return nil, nil, err
	}
	if resp == nil {
	return nil, qm, nil
	}
	defer resp.Body.Close()

	var entries []*KVPair
	if err := decodeBody(resp, &entries); err != nil {
	return nil, nil, err
	}
	if len(entries) > 0 {
	return entries[0], qm, nil
	}
	return nil, qm, nil
	}

	// List is used to lookup all keys under a prefix
	func (k KV) List(prefix string, q QueryOptions) (KVPairs, *QueryMeta, error) {
	resp, qm, err := k.getInternal(prefix, map[string]string{"recurse": ""}, q)
	if err != nil {
	return nil, nil, err
	}
	if resp == nil {
	return nil, qm, nil
	}
	defer resp.Body.Close()

	var entries []*KVPair
	if err := decodeBody(resp, &entries); err != nil {
	return nil, nil, err
	}
	return entries, qm, nil
	}

	// Keys is used to list all the keys under a prefix. Optionally,
	// a separator can be used to limit the responses.
	func (k KV) Keys(prefix, separator string, q QueryOptions) ([]string, *QueryMeta, error) {
	params := map[string]string{"keys": ""}
	if separator != "" {
	params["separator"] = separator
	}
	resp, qm, err := k.getInternal(prefix, params, q)
	if err != nil {
	return nil, nil, err
	}
	if resp == nil {
	return nil, qm, nil
	}
	defer resp.Body.Close()

	var entries []string
	if err := decodeBody(resp, &entries); err != nil {
	return nil, nil, err
	}
	return entries, qm, nil
	}

	func (k KV) getInternal(key string, params map[string]string, q QueryOptions) (http.Response, QueryMeta, error) {
	r := k.c.newRequest("GET", "/v1/kv/"+strings.TrimPrefix(key, "/"))
	r.setQueryOptions(q)
	for param, val := range params {
	r.params.Set(param, val)
	}
	rtt, resp, err := k.c.doRequest(r)
	if err != nil {
	return nil, nil, err
	}

	qm := &QueryMeta{}
	parseQueryMeta(resp, qm)
	qm.RequestTime = rtt

	if resp.StatusCode == 404 {
	resp.Body.Close()
	return nil, qm, nil
	} else if resp.StatusCode != 200 {
	resp.Body.Close()
	return nil, nil, fmt.Errorf("Unexpected response code: %d", resp.StatusCode)
	}
	return resp, qm, nil
	}

	// Put is used to write a new value. Only the
	// Key, Flags and Value is respected.
	func (k KV) Put(p KVPair, q WriteOptions) (WriteMeta, error) {
	params := make(map[string]string, 1)
	if p.Flags != 0 {
	params["flags"] = strconv.FormatUint(p.Flags, 10)
	}
	_, wm, err := k.put(p.Key, params, p.Value, q)
	return wm, err
	}

	// CAS is used for a Check-And-Set operation. The Key,
	// ModifyIndex, Flags and Value are respected. Returns true
	// on success or false on failures.
	func (k KV) CAS(p KVPair, q WriteOptions) (bool, WriteMeta, error) {
	params := make(map[string]string, 2)
	if p.Flags != 0 {
	params["flags"] = strconv.FormatUint(p.Flags, 10)
	}
	params["cas"] = strconv.FormatUint(p.ModifyIndex, 10)
	return k.put(p.Key, params, p.Value, q)
	}

	// Acquire is used for a lock acquisition operation. The Key,
	// Flags, Value and Session are respected. Returns true
	// on success or false on failures.
	func (k KV) Acquire(p KVPair, q WriteOptions) (bool, WriteMeta, error) {
	params := make(map[string]string, 2)
	if p.Flags != 0 {
	params["flags"] = strconv.FormatUint(p.Flags, 10)
	}
	params["acquire"] = p.Session
	return k.put(p.Key, params, p.Value, q)
	}

	// Release is used for a lock release operation. The Key,
	// Flags, Value and Session are respected. Returns true
	// on success or false on failures.
	func (k KV) Release(p KVPair, q WriteOptions) (bool, WriteMeta, error) {
	params := make(map[string]string, 2)
	if p.Flags != 0 {
	params["flags"] = strconv.FormatUint(p.Flags, 10)
	}
	params["release"] = p.Session
	return k.put(p.Key, params, p.Value, q)
	}

	func (k KV) put(key string, params map[string]string, body []byte, q WriteOptions) (bool, *WriteMeta, error) {
	if len(key) > 0 && key[0] == '/' {
	return false, nil, fmt.Errorf("Invalid key. Key must not begin with a '/': %s", key)
	}

	r := k.c.newRequest("PUT", "/v1/kv/"+key)
	r.setWriteOptions(q)
	for param, val := range params {
	r.params.Set(param, val)
	}
	r.body = bytes.NewReader(body)
	rtt, resp, err := requireOK(k.c.doRequest(r))
	if err != nil {
	return false, nil, err
	}
	defer resp.Body.Close()

	qm := &WriteMeta{}
	qm.RequestTime = rtt

	var buf bytes.Buffer
	if _, err := io.Copy(&buf, resp.Body); err != nil {
	return false, nil, fmt.Errorf("Failed to read response: %v", err)
	}
	res := strings.Contains(buf.String(), "true")
	return res, qm, nil
	}

	// Delete is used to delete a single key
	func (k KV) Delete(key string, w WriteOptions) (*WriteMeta, error) {
	_, qm, err := k.deleteInternal(key, nil, w)
	return qm, err
	}

	// DeleteCAS is used for a Delete Check-And-Set operation. The Key
	// and ModifyIndex are respected. Returns true on success or false on failures.
	func (k KV) DeleteCAS(p KVPair, q WriteOptions) (bool, WriteMeta, error) {
	params := map[string]string{
	"cas": strconv.FormatUint(p.ModifyIndex, 10),
	}
	return k.deleteInternal(p.Key, params, q)
	}

	// DeleteTree is used to delete all keys under a prefix
	func (k KV) DeleteTree(prefix string, w WriteOptions) (*WriteMeta, error) {
	_, qm, err := k.deleteInternal(prefix, map[string]string{"recurse": ""}, w)
	return qm, err
	}

	func (k KV) deleteInternal(key string, params map[string]string, q WriteOptions) (bool, *WriteMeta, error) {
	r := k.c.newRequest("DELETE", "/v1/kv/"+strings.TrimPrefix(key, "/"))
	r.setWriteOptions(q)
	for param, val := range params {
	r.params.Set(param, val)
	}
	rtt, resp, err := requireOK(k.c.doRequest(r))
	if err != nil {
	return false, nil, err
	}
	defer resp.Body.Close()

	qm := &WriteMeta{}
	qm.RequestTime = rtt

	var buf bytes.Buffer
	if _, err := io.Copy(&buf, resp.Body); err != nil {
	return false, nil, fmt.Errorf("Failed to read response: %v", err)
	}
	res := strings.Contains(buf.String(), "true")
	return res, qm, nil
	}

	// TxnOp is the internal format we send to Consul. It's not specific to KV,
	// though currently only KV operations are supported.
	type TxnOp struct {
	KV *KVTxnOp
	}

	// TxnOps is a list of transaction operations.
	type TxnOps []*TxnOp

	// TxnResult is the internal format we receive from Consul.
	type TxnResult struct {
	KV *KVPair
	}

	// TxnResults is a list of TxnResult objects.
	type TxnResults []*TxnResult

	// TxnError is used to return information about an operation in a transaction.
	type TxnError struct {
	OpIndex int
	What string
	}

	// TxnErrors is a list of TxnError objects.
	type TxnErrors []*TxnError

	// TxnResponse is the internal format we receive from Consul.
	type TxnResponse struct {
	Results TxnResults
	Errors TxnErrors
	}

	// Txn is used to apply multiple KV operations in a single, atomic transaction.
	//
	// Note that Go will perform the required base64 encoding on the values
	// automatically because the type is a byte slice. Transactions are defined as a
	// list of operations to perform, using the KVOp constants and KVTxnOp structure
	// to define operations. If any operation fails, none of the changes are applied
	// to the state store. Note that this hides the internal raw transaction interface
	// and munges the input and output types into KV-specific ones for ease of use.
	// If there are more non-KV operations in the future we may break out a new
	// transaction API client, but it will be easy to keep this KV-specific variant
	// supported.
	//
	// Even though this is generally a write operation, we take a QueryOptions input
	// and return a QueryMeta output. If the transaction contains only read ops, then
	// Consul will fast-path it to a different endpoint internally which supports
	// consistency controls, but not blocking. If there are write operations then
	// the request will always be routed through raft and any consistency settings
	// will be ignored.
	//
	// Here's an example:
	//
	// ops := KVTxnOps{
	// &KVTxnOp{
	// Verb: KVLock,
	// Key: "test/lock",
	// Session: "adf4238a-882b-9ddc-4a9d-5b6758e4159e",
	// Value: []byte("hello"),
	// },
	// &KVTxnOp{
	// Verb: KVGet,
	// Key: "another/key",
	// },
	// }
	// ok, response, _, err := kv.Txn(&ops, nil)
	//
	// If there is a problem making the transaction request then an error will be
	// returned. Otherwise, the ok value will be true if the transaction succeeded
	// or false if it was rolled back. The response is a structured return value which
	// will have the outcome of the transaction. Its Results member will have entries
	// for each operation. Deleted keys will have a nil entry in the, and to save
	// space, the Value of each key in the Results will be nil unless the operation
	// is a KVGet. If the transaction was rolled back, the Errors member will have
	// entries referencing the index of the operation that failed along with an error
	// message.
	func (k KV) Txn(txn KVTxnOps, q QueryOptions) (bool, KVTxnResponse, QueryMeta, error) {
	r := k.c.newRequest("PUT", "/v1/txn")
	r.setQueryOptions(q)

	// Convert into the internal format since this is an all-KV txn.
	ops := make(TxnOps, 0, len(txn))
	for _, kvOp := range txn {
	ops = append(ops, &TxnOp{KV: kvOp})
	}
	r.obj = ops
	rtt, resp, err := k.c.doRequest(r)
	if err != nil {
	return false, nil, nil, err
	}
	defer resp.Body.Close()

	qm := &QueryMeta{}
	parseQueryMeta(resp, qm)
	qm.RequestTime = rtt

	if resp.StatusCode == http.StatusOK \|\| resp.StatusCode == http.StatusConflict {
	var txnResp TxnResponse
	if err := decodeBody(resp, &txnResp); err != nil {
	return false, nil, nil, err
	}

	// Convert from the internal format.
	kvResp := KVTxnResponse{
	Errors: txnResp.Errors,
	}
	for _, result := range txnResp.Results {
	kvResp.Results = append(kvResp.Results, result.KV)
	}
	return resp.StatusCode == http.StatusOK, &kvResp, qm, nil
	}

	var buf bytes.Buffer
	if _, err := io.Copy(&buf, resp.Body); err != nil {
	return false, nil, nil, fmt.Errorf("Failed to read response: %v", err)
	}
	return false, nil, nil, fmt.Errorf("Failed request: %s", buf.String())
	}