package api import ( "bytes" "compress/gzip" "context" "crypto/tls" "encoding/json" "errors" "fmt" "io" "net" "net/http" "net/url" "os" "strconv" "strings" "time" "github.com/gorilla/websocket" cleanhttp "github.com/hashicorp/go-cleanhttp" rootcerts "github.com/hashicorp/go-rootcerts" ) var ( // ClientConnTimeout is the timeout applied when attempting to contact a // client directly before switching to a connection through the Nomad // server. ClientConnTimeout = 1 * time.Second ) const ( // AllNamespacesNamespace is a sentinel Namespace value to indicate that api should search for // jobs and allocations in all the namespaces the requester can access. AllNamespacesNamespace = "*" ) // QueryOptions are used to parametrize a query type QueryOptions struct { // Providing a datacenter overwrites the region provided // by the Config Region string // Namespace is the target namespace for the query. Namespace string // AllowStale allows any Nomad server (non-leader) to service // a read. This allows for lower latency and higher throughput AllowStale bool // WaitIndex is used to enable a blocking query. Waits // until the timeout or the next index is reached WaitIndex uint64 // WaitTime is used to bound the duration of a wait. // Defaults to that of the Config, but can be overridden. WaitTime time.Duration // If set, used as prefix for resource list searches Prefix string // Set HTTP parameters on the query. Params map[string]string // AuthToken is the secret ID of an ACL token AuthToken string // PerPage is the number of entries to be returned in queries that support // paginated lists. PerPage int32 // NextToken is the token used indicate where to start paging for queries // that support paginated lists. NextToken string // ctx is an optional context pass through to the underlying HTTP // request layer. Use Context() and WithContext() to manage this. ctx context.Context } // WriteOptions are used to parametrize a write type WriteOptions struct { // Providing a datacenter overwrites the region provided // by the Config Region string // Namespace is the target namespace for the write. Namespace string // AuthToken is the secret ID of an ACL token AuthToken string // ctx is an optional context pass through to the underlying HTTP // request layer. Use Context() and WithContext() to manage this. ctx context.Context // IdempotencyToken can be used to ensure the write is idempotent. IdempotencyToken string } // QueryMeta is used to return meta data about a query type QueryMeta struct { // LastIndex. This can be used as a WaitIndex to perform // a blocking query LastIndex uint64 // Time of last contact from the leader for the // server servicing the request LastContact time.Duration // Is there a known leader KnownLeader bool // How long did the request take RequestTime time.Duration } // WriteMeta is used to return meta data about a write type WriteMeta struct { // LastIndex. This can be used as a WaitIndex to perform // a blocking query LastIndex uint64 // How long did the request take RequestTime time.Duration } // HttpBasicAuth is used to authenticate http client with HTTP Basic Authentication type HttpBasicAuth struct { // Username to use for HTTP Basic Authentication Username string // Password to use for HTTP Basic Authentication Password string } // Config is used to configure the creation of a client type Config struct { // Address is the address of the Nomad agent Address string // Region to use. If not provided, the default agent region is used. Region string // SecretID to use. This can be overwritten per request. SecretID string // Namespace to use. If not provided the default namespace is used. Namespace string // HttpClient is the client to use. Default will be used if not provided. // // If set, it expected to be configured for tls already, and TLSConfig is ignored. // You may use ConfigureTLS() function to aid with initialization. HttpClient *http.Client // HttpAuth is the auth info to use for http access. HttpAuth *HttpBasicAuth // WaitTime limits how long a Watch will block. If not provided, // the agent default values will be used. WaitTime time.Duration // TLSConfig provides the various TLS related configurations for the http // client. // // TLSConfig is ignored if HttpClient is set. TLSConfig *TLSConfig Headers http.Header } // ClientConfig copies the configuration with a new client address, region, and // whether the client has TLS enabled. func (c *Config) ClientConfig(region, address string, tlsEnabled bool) *Config { scheme := "http" if tlsEnabled { scheme = "https" } config := &Config{ Address: fmt.Sprintf("%s://%s", scheme, address), Region: region, Namespace: c.Namespace, HttpClient: c.HttpClient, SecretID: c.SecretID, HttpAuth: c.HttpAuth, WaitTime: c.WaitTime, TLSConfig: c.TLSConfig.Copy(), } // Update the tls server name for connecting to a client if tlsEnabled && config.TLSConfig != nil { config.TLSConfig.TLSServerName = fmt.Sprintf("client.%s.nomad", region) } return config } // TLSConfig contains the parameters needed to configure TLS on the HTTP client // used to communicate with Nomad. type TLSConfig struct { // CACert is the path to a PEM-encoded CA cert file to use to verify the // Nomad server SSL certificate. CACert string // CAPath is the path to a directory of PEM-encoded CA cert files to verify // the Nomad server SSL certificate. CAPath string // CACertPem is the PEM-encoded CA cert to use to verify the Nomad server // SSL certificate. CACertPEM []byte // ClientCert is the path to the certificate for Nomad communication ClientCert string // ClientCertPEM is the PEM-encoded certificate for Nomad communication ClientCertPEM []byte // ClientKey is the path to the private key for Nomad communication ClientKey string // ClientKeyPEM is the PEM-encoded private key for Nomad communication ClientKeyPEM []byte // TLSServerName, if set, is used to set the SNI host when connecting via // TLS. TLSServerName string // Insecure enables or disables SSL verification Insecure bool } func (t *TLSConfig) Copy() *TLSConfig { if t == nil { return nil } nt := new(TLSConfig) *nt = *t return nt } func defaultHttpClient() *http.Client { httpClient := cleanhttp.DefaultClient() transport := httpClient.Transport.(*http.Transport) transport.TLSHandshakeTimeout = 10 * time.Second transport.TLSClientConfig = &tls.Config{ MinVersion: tls.VersionTLS12, } return httpClient } // DefaultConfig returns a default configuration for the client func DefaultConfig() *Config { config := &Config{ Address: "http://127.0.0.1:4646", TLSConfig: &TLSConfig{}, } if addr := os.Getenv("NOMAD_ADDR"); addr != "" { config.Address = addr } if v := os.Getenv("NOMAD_REGION"); v != "" { config.Region = v } if v := os.Getenv("NOMAD_NAMESPACE"); v != "" { config.Namespace = v } if auth := os.Getenv("NOMAD_HTTP_AUTH"); auth != "" { var username, password string if strings.Contains(auth, ":") { split := strings.SplitN(auth, ":", 2) username = split[0] password = split[1] } else { username = auth } config.HttpAuth = &HttpBasicAuth{ Username: username, Password: password, } } // Read TLS specific env vars if v := os.Getenv("NOMAD_CACERT"); v != "" { config.TLSConfig.CACert = v } if v := os.Getenv("NOMAD_CAPATH"); v != "" { config.TLSConfig.CAPath = v } if v := os.Getenv("NOMAD_CLIENT_CERT"); v != "" { config.TLSConfig.ClientCert = v } if v := os.Getenv("NOMAD_CLIENT_KEY"); v != "" { config.TLSConfig.ClientKey = v } if v := os.Getenv("NOMAD_TLS_SERVER_NAME"); v != "" { config.TLSConfig.TLSServerName = v } if v := os.Getenv("NOMAD_SKIP_VERIFY"); v != "" { if insecure, err := strconv.ParseBool(v); err == nil { config.TLSConfig.Insecure = insecure } } if v := os.Getenv("NOMAD_TOKEN"); v != "" { config.SecretID = v } return config } // cloneWithTimeout returns a cloned httpClient with set timeout if positive; // otherwise, returns the same client func cloneWithTimeout(httpClient *http.Client, t time.Duration) (*http.Client, error) { if httpClient == nil { return nil, fmt.Errorf("nil HTTP client") } else if httpClient.Transport == nil { return nil, fmt.Errorf("nil HTTP client transport") } if t.Nanoseconds() < 0 { return httpClient, nil } tr, ok := httpClient.Transport.(*http.Transport) if !ok { return nil, fmt.Errorf("unexpected HTTP transport: %T", httpClient.Transport) } // copy all public fields, to avoid copying transient state and locks ntr := &http.Transport{ Proxy: tr.Proxy, DialContext: tr.DialContext, Dial: tr.Dial, DialTLS: tr.DialTLS, TLSClientConfig: tr.TLSClientConfig, TLSHandshakeTimeout: tr.TLSHandshakeTimeout, DisableKeepAlives: tr.DisableKeepAlives, DisableCompression: tr.DisableCompression, MaxIdleConns: tr.MaxIdleConns, MaxIdleConnsPerHost: tr.MaxIdleConnsPerHost, MaxConnsPerHost: tr.MaxConnsPerHost, IdleConnTimeout: tr.IdleConnTimeout, ResponseHeaderTimeout: tr.ResponseHeaderTimeout, ExpectContinueTimeout: tr.ExpectContinueTimeout, TLSNextProto: tr.TLSNextProto, ProxyConnectHeader: tr.ProxyConnectHeader, MaxResponseHeaderBytes: tr.MaxResponseHeaderBytes, } // apply timeout ntr.DialContext = (&net.Dialer{ Timeout: t, KeepAlive: 30 * time.Second, }).DialContext // clone http client with new transport nc := *httpClient nc.Transport = ntr return &nc, nil } // ConfigureTLS applies a set of TLS configurations to the the HTTP client. func ConfigureTLS(httpClient *http.Client, tlsConfig *TLSConfig) error { if tlsConfig == nil { return nil } if httpClient == nil { return fmt.Errorf("config HTTP Client must be set") } var clientCert tls.Certificate foundClientCert := false if tlsConfig.ClientCert != "" || tlsConfig.ClientKey != "" { if tlsConfig.ClientCert != "" && tlsConfig.ClientKey != "" { var err error clientCert, err = tls.LoadX509KeyPair(tlsConfig.ClientCert, tlsConfig.ClientKey) if err != nil { return err } foundClientCert = true } else { return fmt.Errorf("Both client cert and client key must be provided") } } else if len(tlsConfig.ClientCertPEM) != 0 || len(tlsConfig.ClientKeyPEM) != 0 { if len(tlsConfig.ClientCertPEM) != 0 && len(tlsConfig.ClientKeyPEM) != 0 { var err error clientCert, err = tls.X509KeyPair(tlsConfig.ClientCertPEM, tlsConfig.ClientKeyPEM) if err != nil { return err } foundClientCert = true } else { return fmt.Errorf("Both client cert and client key must be provided") } } clientTLSConfig := httpClient.Transport.(*http.Transport).TLSClientConfig rootConfig := &rootcerts.Config{ CAFile: tlsConfig.CACert, CAPath: tlsConfig.CAPath, CACertificate: tlsConfig.CACertPEM, } if err := rootcerts.ConfigureTLS(clientTLSConfig, rootConfig); err != nil { return err } clientTLSConfig.InsecureSkipVerify = tlsConfig.Insecure if foundClientCert { clientTLSConfig.Certificates = []tls.Certificate{clientCert} } if tlsConfig.TLSServerName != "" { clientTLSConfig.ServerName = tlsConfig.TLSServerName } return nil } // Client provides a client to the Nomad API type Client struct { httpClient *http.Client config Config } // NewClient returns a new client func NewClient(config *Config) (*Client, error) { // bootstrap the config defConfig := DefaultConfig() if config.Address == "" { config.Address = defConfig.Address } else if _, err := url.Parse(config.Address); err != nil { return nil, fmt.Errorf("invalid address '%s': %v", config.Address, err) } httpClient := config.HttpClient if httpClient == nil { httpClient = defaultHttpClient() if err := ConfigureTLS(httpClient, config.TLSConfig); err != nil { return nil, err } } client := &Client{ config: *config, httpClient: httpClient, } return client, nil } // Address return the address of the Nomad agent func (c *Client) Address() string { return c.config.Address } // SetRegion sets the region to forward API requests to. func (c *Client) SetRegion(region string) { c.config.Region = region } // SetNamespace sets the namespace to forward API requests to. func (c *Client) SetNamespace(namespace string) { c.config.Namespace = namespace } // GetNodeClient returns a new Client that will dial the specified node. If the // QueryOptions is set, its region will be used. func (c *Client) GetNodeClient(nodeID string, q *QueryOptions) (*Client, error) { return c.getNodeClientImpl(nodeID, -1, q, c.Nodes().Info) } // GetNodeClientWithTimeout returns a new Client that will dial the specified // node using the specified timeout. If the QueryOptions is set, its region will // be used. func (c *Client) GetNodeClientWithTimeout( nodeID string, timeout time.Duration, q *QueryOptions) (*Client, error) { return c.getNodeClientImpl(nodeID, timeout, q, c.Nodes().Info) } // nodeLookup is the definition of a function used to lookup a node. This is // largely used to mock the lookup in tests. type nodeLookup func(nodeID string, q *QueryOptions) (*Node, *QueryMeta, error) // getNodeClientImpl is the implementation of creating a API client for // contacting a node. It takes a function to lookup the node such that it can be // mocked during tests. func (c *Client) getNodeClientImpl(nodeID string, timeout time.Duration, q *QueryOptions, lookup nodeLookup) (*Client, error) { node, _, err := lookup(nodeID, q) if err != nil { return nil, err } if node.Status == "down" { return nil, NodeDownErr } if node.HTTPAddr == "" { return nil, fmt.Errorf("http addr of node %q (%s) is not advertised", node.Name, nodeID) } var region string switch { case q != nil && q.Region != "": // Prefer the region set in the query parameter region = q.Region case c.config.Region != "": // If the client is configured for a particular region use that region = c.config.Region default: // No region information is given so use GlobalRegion as the default. region = GlobalRegion } // Get an API client for the node conf := c.config.ClientConfig(region, node.HTTPAddr, node.TLSEnabled) // set timeout - preserve old behavior where errors are ignored and use untimed one httpClient, err := cloneWithTimeout(c.httpClient, timeout) // on error, fallback to using current http client if err != nil { httpClient = c.httpClient } conf.HttpClient = httpClient return NewClient(conf) } // SetSecretID sets the ACL token secret for API requests. func (c *Client) SetSecretID(secretID string) { c.config.SecretID = secretID } // request is used to help build up a request type request struct { config *Config method string url *url.URL params url.Values token string body io.Reader obj interface{} ctx context.Context header http.Header } // setQueryOptions is used to annotate the request with // additional query options func (r *request) setQueryOptions(q *QueryOptions) { if q == nil { return } if q.Region != "" { r.params.Set("region", q.Region) } if q.Namespace != "" { r.params.Set("namespace", q.Namespace) } if q.AuthToken != "" { r.token = q.AuthToken } if q.AllowStale { r.params.Set("stale", "") } if q.WaitIndex != 0 { r.params.Set("index", strconv.FormatUint(q.WaitIndex, 10)) } if q.WaitTime != 0 { r.params.Set("wait", durToMsec(q.WaitTime)) } if q.Prefix != "" { r.params.Set("prefix", q.Prefix) } for k, v := range q.Params { r.params.Set(k, v) } r.ctx = q.Context() } // durToMsec converts a duration to a millisecond specified string func durToMsec(dur time.Duration) string { return fmt.Sprintf("%dms", dur/time.Millisecond) } // setWriteOptions is used to annotate the request with // additional write options func (r *request) setWriteOptions(q *WriteOptions) { if q == nil { return } if q.Region != "" { r.params.Set("region", q.Region) } if q.Namespace != "" { r.params.Set("namespace", q.Namespace) } if q.AuthToken != "" { r.token = q.AuthToken } if q.IdempotencyToken != "" { r.params.Set("idempotency_token", q.IdempotencyToken) } r.ctx = q.Context() } // toHTTP converts the request to an HTTP request func (r *request) toHTTP() (*http.Request, error) { // Encode the query parameters r.url.RawQuery = r.params.Encode() // Check if we should encode the body if r.body == nil && r.obj != nil { if b, err := encodeBody(r.obj); err != nil { return nil, err } else { r.body = b } } ctx := func() context.Context { if r.ctx != nil { return r.ctx } return context.Background() }() // Create the HTTP request req, err := http.NewRequestWithContext(ctx, r.method, r.url.RequestURI(), r.body) if err != nil { return nil, err } req.Header = r.header // Optionally configure HTTP basic authentication if r.url.User != nil { username := r.url.User.Username() password, _ := r.url.User.Password() req.SetBasicAuth(username, password) } else if r.config.HttpAuth != nil { req.SetBasicAuth(r.config.HttpAuth.Username, r.config.HttpAuth.Password) } req.Header.Add("Accept-Encoding", "gzip") if r.token != "" { req.Header.Set("X-Nomad-Token", r.token) } req.URL.Host = r.url.Host req.URL.Scheme = r.url.Scheme req.Host = r.url.Host return req, nil } // newRequest is used to create a new request func (c *Client) newRequest(method, path string) (*request, error) { base, _ := url.Parse(c.config.Address) u, err := url.Parse(path) if err != nil { return nil, err } r := &request{ config: &c.config, method: method, url: &url.URL{ Scheme: base.Scheme, User: base.User, Host: base.Host, Path: u.Path, RawPath: u.RawPath, }, header: make(http.Header), params: make(map[string][]string), } if c.config.Region != "" { r.params.Set("region", c.config.Region) } if c.config.Namespace != "" { r.params.Set("namespace", c.config.Namespace) } if c.config.WaitTime != 0 { r.params.Set("wait", durToMsec(r.config.WaitTime)) } if c.config.SecretID != "" { r.token = r.config.SecretID } // Add in the query parameters, if any for key, values := range u.Query() { for _, value := range values { r.params.Add(key, value) } } for key, values := range c.config.Headers { r.header[key] = values } return r, nil } // multiCloser is to wrap a ReadCloser such that when close is called, multiple // Closes occur. type multiCloser struct { reader io.Reader inorderClose []io.Closer } func (m *multiCloser) Close() error { for _, c := range m.inorderClose { if err := c.Close(); err != nil { return err } } return nil } func (m *multiCloser) Read(p []byte) (int, error) { return m.reader.Read(p) } // doRequest runs a request with our client func (c *Client) doRequest(r *request) (time.Duration, *http.Response, error) { req, err := r.toHTTP() if err != nil { return 0, nil, err } start := time.Now() resp, err := c.httpClient.Do(req) diff := time.Since(start) // If the response is compressed, we swap the body's reader. if resp != nil && resp.Header != nil { var reader io.ReadCloser switch resp.Header.Get("Content-Encoding") { case "gzip": greader, err := gzip.NewReader(resp.Body) if err != nil { return 0, nil, err } // The gzip reader doesn't close the wrapped reader so we use // multiCloser. reader = &multiCloser{ reader: greader, inorderClose: []io.Closer{greader, resp.Body}, } default: reader = resp.Body } resp.Body = reader } return diff, resp, err } // rawQuery makes a GET request to the specified endpoint but returns just the // response body. func (c *Client) rawQuery(endpoint string, q *QueryOptions) (io.ReadCloser, error) { r, err := c.newRequest("GET", endpoint) if err != nil { return nil, err } r.setQueryOptions(q) _, resp, err := requireOK(c.doRequest(r)) if err != nil { return nil, err } return resp.Body, nil } // websocket makes a websocket request to the specific endpoint func (c *Client) websocket(endpoint string, q *QueryOptions) (*websocket.Conn, *http.Response, error) { transport, ok := c.httpClient.Transport.(*http.Transport) if !ok { return nil, nil, fmt.Errorf("unsupported transport") } dialer := websocket.Dialer{ ReadBufferSize: 4096, WriteBufferSize: 4096, HandshakeTimeout: c.httpClient.Timeout, // values to inherit from http client configuration NetDial: transport.Dial, NetDialContext: transport.DialContext, Proxy: transport.Proxy, TLSClientConfig: transport.TLSClientConfig, } // build request object for header and parameters r, err := c.newRequest("GET", endpoint) if err != nil { return nil, nil, err } r.setQueryOptions(q) rhttp, err := r.toHTTP() if err != nil { return nil, nil, err } // convert scheme wsScheme := "" switch rhttp.URL.Scheme { case "http": wsScheme = "ws" case "https": wsScheme = "wss" default: return nil, nil, fmt.Errorf("unsupported scheme: %v", rhttp.URL.Scheme) } rhttp.URL.Scheme = wsScheme conn, resp, err := dialer.Dial(rhttp.URL.String(), rhttp.Header) // check resp status code, as it's more informative than handshake error we get from ws library if resp != nil && resp.StatusCode != 101 { var buf bytes.Buffer if resp.Header.Get("Content-Encoding") == "gzip" { greader, err := gzip.NewReader(resp.Body) if err != nil { return nil, nil, fmt.Errorf("Unexpected response code: %d", resp.StatusCode) } io.Copy(&buf, greader) } else { io.Copy(&buf, resp.Body) } resp.Body.Close() return nil, nil, fmt.Errorf("Unexpected response code: %d (%s)", resp.StatusCode, buf.Bytes()) } return conn, resp, err } // query is used to do a GET request against an endpoint // and deserialize the response into an interface using // standard Nomad conventions. func (c *Client) query(endpoint string, out interface{}, q *QueryOptions) (*QueryMeta, error) { r, err := c.newRequest("GET", endpoint) if err != nil { return nil, err } r.setQueryOptions(q) rtt, resp, err := requireOK(c.doRequest(r)) if err != nil { return nil, err } defer resp.Body.Close() qm := &QueryMeta{} parseQueryMeta(resp, qm) qm.RequestTime = rtt if err := decodeBody(resp, out); err != nil { return nil, err } return qm, nil } // putQuery is used to do a PUT request when doing a read against an endpoint // and deserialize the response into an interface using standard Nomad // conventions. func (c *Client) putQuery(endpoint string, in, out interface{}, q *QueryOptions) (*QueryMeta, error) { r, err := c.newRequest("PUT", endpoint) if err != nil { return nil, err } r.setQueryOptions(q) r.obj = in rtt, resp, err := requireOK(c.doRequest(r)) if err != nil { return nil, err } defer resp.Body.Close() qm := &QueryMeta{} parseQueryMeta(resp, qm) qm.RequestTime = rtt if err := decodeBody(resp, out); err != nil { return nil, err } return qm, nil } // write is used to do a PUT request against an endpoint // and serialize/deserialized using the standard Nomad conventions. func (c *Client) write(endpoint string, in, out interface{}, q *WriteOptions) (*WriteMeta, error) { r, err := c.newRequest("PUT", endpoint) if err != nil { return nil, err } r.setWriteOptions(q) r.obj = in rtt, resp, err := requireOK(c.doRequest(r)) if err != nil { return nil, err } defer resp.Body.Close() wm := &WriteMeta{RequestTime: rtt} parseWriteMeta(resp, wm) if out != nil { if err := decodeBody(resp, &out); err != nil { return nil, err } } return wm, nil } // delete is used to do a DELETE request against an endpoint // and serialize/deserialized using the standard Nomad conventions. func (c *Client) delete(endpoint string, out interface{}, q *WriteOptions) (*WriteMeta, error) { r, err := c.newRequest("DELETE", endpoint) if err != nil { return nil, err } r.setWriteOptions(q) rtt, resp, err := requireOK(c.doRequest(r)) if err != nil { return nil, err } defer resp.Body.Close() wm := &WriteMeta{RequestTime: rtt} parseWriteMeta(resp, wm) if out != nil { if err := decodeBody(resp, &out); err != nil { return nil, err } } return wm, nil } // parseQueryMeta is used to help parse query meta-data func parseQueryMeta(resp *http.Response, q *QueryMeta) error { header := resp.Header // Parse the X-Nomad-Index index, err := strconv.ParseUint(header.Get("X-Nomad-Index"), 10, 64) if err != nil { return fmt.Errorf("Failed to parse X-Nomad-Index: %v", err) } q.LastIndex = index // Parse the X-Nomad-LastContact last, err := strconv.ParseUint(header.Get("X-Nomad-LastContact"), 10, 64) if err != nil { return fmt.Errorf("Failed to parse X-Nomad-LastContact: %v", err) } q.LastContact = time.Duration(last) * time.Millisecond // Parse the X-Nomad-KnownLeader switch header.Get("X-Nomad-KnownLeader") { case "true": q.KnownLeader = true default: q.KnownLeader = false } return nil } // parseWriteMeta is used to help parse write meta-data func parseWriteMeta(resp *http.Response, q *WriteMeta) error { header := resp.Header // Parse the X-Nomad-Index index, err := strconv.ParseUint(header.Get("X-Nomad-Index"), 10, 64) if err != nil { return fmt.Errorf("Failed to parse X-Nomad-Index: %v", err) } q.LastIndex = index return nil } // decodeBody is used to JSON decode a body func decodeBody(resp *http.Response, out interface{}) error { switch resp.ContentLength { case 0: if out == nil { return nil } return errors.New("Got 0 byte response with non-nil decode object") default: dec := json.NewDecoder(resp.Body) return dec.Decode(out) } } // encodeBody prepares the reader to serve as the request body. // // Returns the `obj` input if it is a raw io.Reader object; otherwise // returns a reader of the json format of the passed argument. func encodeBody(obj interface{}) (io.Reader, error) { if reader, ok := obj.(io.Reader); ok { return reader, nil } buf := bytes.NewBuffer(nil) enc := json.NewEncoder(buf) if err := enc.Encode(obj); err != nil { return nil, err } return buf, nil } // requireOK is used to wrap doRequest and check for a 200 func requireOK(d time.Duration, resp *http.Response, e error) (time.Duration, *http.Response, error) { if e != nil { if resp != nil { resp.Body.Close() } return d, nil, e } if resp.StatusCode != 200 { var buf bytes.Buffer io.Copy(&buf, resp.Body) resp.Body.Close() return d, nil, fmt.Errorf("Unexpected response code: %d (%s)", resp.StatusCode, buf.Bytes()) } return d, resp, nil } // Context returns the context used for canceling HTTP requests related to this query func (o *QueryOptions) Context() context.Context { if o != nil && o.ctx != nil { return o.ctx } return context.Background() } // WithContext creates a copy of the query options using the provided context to cancel related HTTP requests func (o *QueryOptions) WithContext(ctx context.Context) *QueryOptions { o2 := new(QueryOptions) if o != nil { *o2 = *o } o2.ctx = ctx return o2 } // Context returns the context used for canceling HTTP requests related to this write func (o *WriteOptions) Context() context.Context { if o != nil && o.ctx != nil { return o.ctx } return context.Background() } // WithContext creates a copy of the write options using the provided context to cancel related HTTP requests func (o *WriteOptions) WithContext(ctx context.Context) *WriteOptions { o2 := new(WriteOptions) if o != nil { *o2 = *o } o2.ctx = ctx return o2 }