1.1. API Basics

The CouchDB API is the primary method of interfacing to a CouchDB instance. Requests are made using HTTP and requests are used to request information from the database, store new data, and perform views and formatting of the information stored within the documents.

Requests to the API can be categorised by the different areas of the CouchDB system that you are accessing, and the HTTP method used to send the request. Different methods imply different operations, for example retrieval of information from the database is typically handled by the GET operation, while updates are handled by either a POST or PUT request. There are some differences between the information that must be supplied for the different methods. For a guide to the basic HTTP methods and request structure, see Request Format and Responses.

For nearly all operations, the submitted data, and the returned data structure, is defined within a JavaScript Object Notation (JSON) object. Basic information on the content and data types for JSON are provided in JSON Basics.

Errors when accessing the CouchDB API are reported using standard HTTP Status Codes. A guide to the generic codes returned by CouchDB are provided in HTTP Status Codes.

When accessing specific areas of the CouchDB API, specific information and examples on the HTTP methods and request, JSON structures, and error codes are provided.

1.1.1. Request Format and Responses

CouchDB supports the following HTTP request methods:

  • GET

    Request the specified item. As with normal HTTP requests, the format of the URL defines what is returned. With CouchDB this can include static items, database documents, and configuration and statistical information. In most cases the information is returned in the form of a JSON document.

  • HEAD

    The HEAD method is used to get the HTTP header of a GET request without the body of the response.

  • POST

    Upload data. Within CouchDB POST is used to set values, including uploading documents, setting document values, and starting certain administration commands.

  • PUT

    Used to put a specified resource. In CouchDB PUT is used to create new objects, including databases, documents, views and design documents.

  • DELETE

    Deletes the specified resource, including documents, views, and design documents.

  • COPY

    A special method that can be used to copy documents and objects.

If you use an unsupported HTTP request type with an URL that does not support the specified type then a 405 - Method Not Allowed will be returned, listing the supported HTTP methods. For example:

  1. {
  2. "error":"method_not_allowed",
  3. "reason":"Only GET,HEAD allowed"
  4. }

1.1.2. HTTP Headers

Because CouchDB uses HTTP for all communication, you need to ensure that the correct HTTP headers are supplied (and processed on retrieval) so that you get the right format and encoding. Different environments and clients will be more or less strict on the effect of these HTTP headers (especially when not present). Where possible you should be as specific as possible.

1.1.2.1. Request Headers

  • Accept

    Specifies the list of accepted data types to be returned by the server (i.e. that are accepted/understandable by the client). The format should be a list of one or more MIME types, separated by colons.

    For the majority of requests the definition should be for JSON data (application/json). For attachments you can either specify the MIME type explicitly, or use */* to specify that all file types are supported. If the Accept header is not supplied, then the */* MIME type is assumed (i.e. client accepts all formats).

    The use of Accept in queries for CouchDB is not required, but is highly recommended as it helps to ensure that the data returned can be processed by the client.

    If you specify a data type using the Accept header, CouchDB will honor the specified type in the Content-type header field returned. For example, if you explicitly request application/json in the Accept of a request, the returned HTTP headers will use the value in the returned Content-type field.

    For example, when sending a request without an explicit Accept header, or when specifying */*:

    1. GET /recipes HTTP/1.1
    2. Host: couchdb:5984
    3. Accept: */*

    The returned headers are:

    1. HTTP/1.1 200 OK
    2. Server: CouchDB (Erlang/OTP)
    3. Date: Thu, 13 Jan 2011 13:39:34 GMT
    4. Content-Type: text/plain;charset=utf-8
    5. Content-Length: 227
    6. Cache-Control: must-revalidate

    Note

    The returned content type is text/plain even though the information returned by the request is in JSON format.

    Explicitly specifying the Accept header:

    1. GET /recipes HTTP/1.1
    2. Host: couchdb:5984
    3. Accept: application/json

    The headers returned include the application/json content type:

    1. HTTP/1.1 200 OK
    2. Server: CouchDB (Erlang/OTP)
    3. Date: Thu, 13 Jan 2013 13:40:11 GMT
    4. Content-Type: application/json
    5. Content-Length: 227
    6. Cache-Control: must-revalidate
  • Content-type

    Specifies the content type of the information being supplied within the request. The specification uses MIME type specifications. For the majority of requests this will be JSON (application/json). For some settings the MIME type will be plain text. When uploading attachments it should be the corresponding MIME type for the attachment or binary (application/octet-stream).

    The use of the Content-type on a request is highly recommended.

1.1.2.2. Response Headers

Response headers are returned by the server when sending back content and include a number of different header fields, many of which are standard HTTP response header and have no significance to CouchDB operation. The list of response headers important to CouchDB are listed below.

  • Cache-control

    The cache control HTTP response header provides a suggestion for client caching mechanisms on how to treat the returned information. CouchDB typically returns the must-revalidate, which indicates that the information should be revalidated if possible. This is used to ensure that the dynamic nature of the content is correctly updated.

  • Content-length

    The length (in bytes) of the returned content.

  • Content-type

    Specifies the MIME type of the returned data. For most request, the returned MIME type is text/plain. All text is encoded in Unicode (UTF-8), and this is explicitly stated in the returned Content-type, as text/plain;charset=utf-8.

  • Etag

    The Etag HTTP header field is used to show the revision for a document, or a view.

    ETags have been assigned to a map/reduce group (the collection of views in a single design document). Any change to any of the indexes for those views would generate a new ETag for all view URLs in a single design doc, even if that specific view’s results had not changed.

    Each _view URL has its own ETag which only gets updated when changes are made to the database that effect that index. If the index for that specific view does not change, that view keeps the original ETag head (therefore sending back 304 - Not Modified more often).

  • Transfer-Encoding

    If the response uses an encoding, then it is specified in this header field.

    Transfer-Encoding: chunked means that the response is sent in parts, a method known as chunked transfer encoding. This is used when CouchDB does not know beforehand the size of the data it will send (for example, the changes feed).

  • X-CouchDB-Body-Time

    Time spent receiving the request body in milliseconds.

    Available when body content is included in the request.

  • X-Couch-Request-ID

    Unique identifier for the request.

1.1.3. JSON Basics

The majority of requests and responses to CouchDB use the JavaScript Object Notation (JSON) for formatting the content and structure of the data and responses.

JSON is used because it is the simplest and easiest solution for working with data within a web browser, as JSON structures can be evaluated and used as JavaScript objects within the web browser environment. JSON also integrates with the server-side JavaScript used within CouchDB.

JSON supports the same basic types as supported by JavaScript, these are:

  • Array - a list of values enclosed in square brackets. For example:

    1. ["one", "two", "three"]
  • Boolean - a true or false value. You can use these strings directly. For example:

    1. { "value": true}
  • Number - an integer or floating-point number.

  • Object - a set of key/value pairs (i.e. an associative array, or hash). The key must be a string, but the value can be any of the supported JSON values. For example:

    1. {
    2. "servings" : 4,
    3. "subtitle" : "Easy to make in advance, and then cook when ready",
    4. "cooktime" : 60,
    5. "title" : "Chicken Coriander"
    6. }

    In CouchDB, the JSON object is used to represent a variety of structures, including the main CouchDB document.

  • String - this should be enclosed by double-quotes and supports Unicode characters and backslash escaping. For example:

    1. "A String"

Parsing JSON into a JavaScript object is supported through the JSON.parse() function in JavaScript, or through various libraries that will perform the parsing of the content into a JavaScript object for you. Libraries for parsing and generating JSON are available in many languages, including Perl, Python, Ruby, Erlang and others.

Warning

Care should be taken to ensure that your JSON structures are valid, invalid structures will cause CouchDB to return an HTTP status code of 500 (server error).

1.1.3.1. Number Handling

Developers and users new to computer handling of numbers often encounter surprises when expecting that a number stored in JSON format does not necessarily return as the same number as compared character by character.

Any numbers defined in JSON that contain a decimal point or exponent will be passed through the Erlang VM’s idea of the “double” data type. Any numbers that are used in views will pass through the view server’s idea of a number (the common JavaScript case means even integers pass through a double due to JavaScript’s definition of a number).

Consider this document that we write to CouchDB:

  1. {
  2. "_id":"30b3b38cdbd9e3a587de9b8122000cff",
  3. "number": 1.1
  4. }

Now let’s read that document back from CouchDB:

  1. {
  2. "_id":"30b3b38cdbd9e3a587de9b8122000cff",
  3. "_rev":"1-f065cee7c3fd93aa50f6c97acde93030",
  4. "number":1.1000000000000000888
  5. }

What happens is CouchDB is changing the textual representation of the result of decoding what it was given into some numerical format. In most cases this is an IEEE 754 double precision floating point number which is exactly what almost all other languages use as well.

What Erlang does a bit differently than other languages is that it does not attempt to pretty print the resulting output to use the shortest number of characters. For instance, this is why we have this relationship:

  1. ejson:encode(ejson:decode(<<"1.1">>)).
  2. <<"1.1000000000000000888">>

What can be confusing here is that internally those two formats decode into the same IEEE-754 representation. And more importantly, it will decode into a fairly close representation when passed through all major parsers that we know about.

While we’ve only been discussing cases where the textual representation changes, another important case is when an input value contains more precision than can actually represented in a double. (You could argue that this case is actually “losing” data if you don’t accept that numbers are stored in doubles).

Here’s a log for a couple of the more common JSON libraries that happen to be on the author’s machine:

Ejson (CouchDB’s current parser) at CouchDB sha 168a663b:

  1. $ ./utils/run -i
  2. Erlang R14B04 (erts-5.8.5) [source] [64-bit] [smp:2:2] [rq:2]
  3. [async-threads:4] [hipe] [kernel-poll:true]
  4. Eshell V5.8.5 (abort with ^G)
  5. 1> ejson:encode(ejson:decode(<<"1.01234567890123456789012345678901234567890">>)).
  6. <<"1.0123456789012346135">>
  7. 2> F = ejson:encode(ejson:decode(<<"1.01234567890123456789012345678901234567890">>)).
  8. <<"1.0123456789012346135">>
  9. 3> ejson:encode(ejson:decode(F)).
  10. <<"1.0123456789012346135">>

Node:

  1. $ node -v
  2. v0.6.15
  3. $ node
  4. JSON.stringify(JSON.parse("1.01234567890123456789012345678901234567890"))
  5. '1.0123456789012346'
  6. var f = JSON.stringify(JSON.parse("1.01234567890123456789012345678901234567890"))
  7. undefined
  8. JSON.stringify(JSON.parse(f))
  9. '1.0123456789012346'

Python:

  1. $ python
  2. Python 2.7.2 (default, Jun 20 2012, 16:23:33)
  3. [GCC 4.2.1 Compatible Apple Clang 4.0 (tags/Apple/clang-418.0.60)] on darwin
  4. Type "help", "copyright", "credits" or "license" for more information.
  5. import json
  6. json.dumps(json.loads("1.01234567890123456789012345678901234567890"))
  7. '1.0123456789012346'
  8. f = json.dumps(json.loads("1.01234567890123456789012345678901234567890"))
  9. json.dumps(json.loads(f))
  10. '1.0123456789012346'

Ruby:

  1. $ irb --version
  2. irb 0.9.5(05/04/13)
  3. require 'JSON'
  4. => true
  5. JSON.dump(JSON.load("[1.01234567890123456789012345678901234567890]"))
  6. => "[1.01234567890123]"
  7. f = JSON.dump(JSON.load("[1.01234567890123456789012345678901234567890]"))
  8. => "[1.01234567890123]"
  9. JSON.dump(JSON.load(f))
  10. => "[1.01234567890123]"

Note

A small aside on Ruby, it requires a top level object or array, so I just wrapped the value. Should be obvious it doesn’t affect the result of parsing the number though.

Spidermonkey:

  1. $ js -h 2>&1 | head -n 1
  2. JavaScript-C 1.8.5 2011-03-31
  3. $ js
  4. js> JSON.stringify(JSON.parse("1.01234567890123456789012345678901234567890"))
  5. "1.0123456789012346"
  6. js> var f = JSON.stringify(JSON.parse("1.01234567890123456789012345678901234567890"))
  7. js> JSON.stringify(JSON.parse(f))
  8. "1.0123456789012346"

As you can see they all pretty much behave the same except for Ruby actually does appear to be losing some precision over the other libraries.

The astute observer will notice that ejson (the CouchDB JSON library) reported an extra three digits. While its tempting to think that this is due to some internal difference, its just a more specific case of the 1.1 input as described above.

The important point to realize here is that a double can only hold a finite number of values. What we’re doing here is generating a string that when passed through the “standard” floating point parsing algorithms (ie, strtod) will result in the same bit pattern in memory as we started with. Or, slightly different, the bytes in a JSON serialized number are chosen such that they refer to a single specific value that a double can represent.

The important point to understand is that we’re mapping from one infinite set onto a finite set. An easy way to see this is by reflecting on this:

  1. 1.0 == 1.00 == 1.000 = 1.(infinite zeros)

Obviously a computer can’t hold infinite bytes so we have to decimate our infinitely sized set to a finite set that can be represented concisely.

The game that other JSON libraries are playing is merely:

“How few characters do I have to use to select this specific value for a double”

And that game has lots and lots of subtle details that are difficult to duplicate in C without a significant amount of effort (it took Python over a year to get it sorted with their fancy build systems that automatically run on a number of different architectures).

Hopefully we’ve shown that CouchDB is not doing anything “funky” by changing input. Its behaving the same as any other common JSON library does, its just not pretty printing its output.

On the other hand, if you actually are in a position where an IEEE-754 double is not a satisfactory data type for your numbers, then the answer as has been stated is to not pass your numbers through this representation. In JSON this is accomplished by encoding them as a string or by using integer types (although integer types can still bite you if you use a platform that has a different integer representation than normal, ie, JavaScript).

Further information can be found easily, including the Floating Point Guide, and David Goldberg’s Reference.

Also, if anyone is really interested in changing this behavior, we’re all ears for contributions to jiffy (which is theoretically going to replace ejson when we get around to updating the build system). The places we’ve looked for inspiration are TCL and Python. If you know a decent implementation of this float printing algorithm give us a holler.

1.1.4. HTTP Status Codes

With the interface to CouchDB working through HTTP, error codes and statuses are reported using a combination of the HTTP status code number, and corresponding data in the body of the response data.

A list of the error codes returned by CouchDB, and generic descriptions of the related errors are provided below. The meaning of different status codes for specific request types are provided in the corresponding API call reference.

  • 200 - OK

    Request completed successfully.

  • 201 - Created

    Document created successfully.

  • 202 - Accepted

    Request has been accepted, but the corresponding operation may not have completed. This is used for background operations, such as database compaction.

  • 304 - Not Modified

    The additional content requested has not been modified. This is used with the ETag system to identify the version of information returned.

  • 400 - Bad Request

    Bad request structure. The error can indicate an error with the request URL, path or headers. Differences in the supplied MD5 hash and content also trigger this error, as this may indicate message corruption.

  • 401 - Unauthorized

    The item requested was not available using the supplied authorization, or authorization was not supplied.

  • 403 - Forbidden

    The requested item or operation is forbidden.

  • 404 - Not Found

    The requested content could not be found. The content will include further information, as a JSON object, if available. The structure will contain two keys, error and reason. For example:

    1. {"error":"not_found","reason":"no_db_file"}
  • 405 - Method Not Allowed

    A request was made using an invalid HTTP request type for the URL requested. For example, you have requested a PUT when a POST is required. Errors of this type can also triggered by invalid URL strings.

  • 406 - Not Acceptable

    The requested content type is not supported by the server.

  • 409 - Conflict

    Request resulted in an update conflict.

  • 412 - Precondition Failed

    The request headers from the client and the capabilities of the server do not match.

  • 413 - Request Entity Too Large

    A document exceeds the configured couchdb/max_document_size value or the entire request exceeds the chttpd/max_http_request_size value.

  • 415 - Unsupported Media Type

    The content types supported, and the content type of the information being requested or submitted indicate that the content type is not supported.

  • 416 - Requested Range Not Satisfiable

    The range specified in the request header cannot be satisfied by the server.

  • 417 - Expectation Failed

    When sending documents in bulk, the bulk load operation failed.

  • 500 - Internal Server Error

    The request was invalid, either because the supplied JSON was invalid, or invalid information was supplied as part of the request.