doc/thrift.tex

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%               Thrift whitepaper
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% Name:         thrift.tex
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% Authors:      Mark Slee (mcslee@facebook.com)
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% Created:      05 March 2007
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\begin{document}

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\title{Thrift: Scalable Cross-Language Services Implementation}
\subtitle{}

\authorinfo{Mark Slee, Aditya Agarwal and Marc Kwiatkowski}
           {Facebook, 156 University Ave, Palo Alto, CA}
           {\{mcslee,aditya,marc\}@facebook.com}

\maketitle

\begin{abstract}
Thrift is a software library and set of code-generation tools developed at
Facebook to expedite development and implementation of efficient and scalable
backend services. Its primary goal is to enable efficient and reliable
communication across programming languages by abstracting the portions of each
language that tend to require the most customization into a common library
that is implemented in each language. Specifically, Thrift allows developers to
define data types and service interfaces in a single language-neutral file
and generate all the necessary code to build RPC clients and servers.

This paper details the motivations and design choices we made in Thrift, as
well as some of the more interesting implementation details. It is not
intended to be taken as research, but rather it is an exposition on what we did
and why.
\end{abstract}

% \category{D.3.3}{Programming Languages}{Language constructs and features}

%\terms
%Languages, serialization, remote procedure call

%\keywords
%Data description language, interface definition language, remote procedure call

\section{Introduction}
As Facebook's traffic and network structure have scaled, the resource
demands of many operations on the site (i.e. search, 
ad selection and delivery, event logging) have presented technical requirements
drastically outside the scope of the LAMP framework. In our implementation of
these services, various programming languages have been selected to
optimize for the right combination of performance, ease and speed of
development, availability of existing libraries, etc. By and large,
Facebook's engineering culture has tended towards choosing the best
tools and implementations avaiable over standardizing on any one
programming language and begrudgingly accepting its inherent limitations.

Given this design choice, we were presented with the challenge of building
a transparent, high-performance bridge across many programming languages.
We found that most available solutions were either too limited, did not offer
sufficient data type freedom, or suffered from subpar performance.
\footnote{See Appendix A for a discussion of alternative systems.}

The solution that we have implemented combines a language-neutral software
stack implemented across numerous programming languages and an associated code
generation engine that transforms a simple interface and data definition
language into client and server remote procedure call libraries.
Choosing static code generation over a dynamic system allows us to create
validated code with implicit guarantees that can be run without the need for
any advanced intropsecive run-time type checking. It is also designed to
be as simple as possible for the developer, who can typically define all
the necessary data structures and interfaces for a complex service in a single
short file.

Surprised that a robust open solution to these relatively common problems
did not yet exist, we committed early on to making the Thrift implementation
open source.

In evaluating the challenges of cross-language interaction in a networked
environment, some key components were identified:

\textit{Types.} A common type system must exist across programming languages
without requiring that the application developer use custom Thrift data types
or write their own serialization code. That is,
a C++ programmer should be able to transparently exchange a strongly typed
STL map for a dynamic Python dictionary. Neither
programmer should be forced to write any code below the application layer
to achieve this. Section 2 details the Thrift type system. 

\textit{Transport.} Each language must have a common interface to
bidirectional raw data transport. The specifics of how a given
transport is implemented should not matter to the service developer.
The same application code should be able to run against TCP stream sockets,
raw data in memory, or files on disk. Section 3 details the Thrift Transport
layer.

\textit{Protocol.} Data types must have some way of using the Transport
layer to encode and decode themselves. Again, the application
developer need not be concerned by this layer. Whether the service uses
an XML or binary protocol is immaterial to the application code.
All that matters is that the data can be read and written in a consistent,
deterministic matter. Section 4 details the Thrift Protocol layer.

\textit{Versioning.} For robust services, the involved data types must
provide a mechanism for versioning themselves. Specifically,
it should be possible to add or remove fields in an object or alter the
argument list of a function without any interruption in service (or,
worse yet, nasty segmentation faults). Section 5 details Thrift's versioning
system.

\textit{Processors.} Finally, we generate code capable of processing data
streams to accomplish remote procedure call. Section 6 details the generated
code and TProcessor paradigm.

Section 7 discusses implementation details, and Section 8 describes
our conclusions.

\section{Types}

The goal of the Thrift type system is to enable programmers to develop using
completely natively defined types, no matter what programming language they
use. By design, the Thrift type system does not introduce any special dynamic
types or wrapper objects. It also does not require that the developer write
any code for object serialization or transport. The Thrift IDL file is
logically a way for developers to annotate their data structures with the
minimal amount of extra information necessary to tell a code generator
how to safely transport the objects across languages.

\subsection{Base Types}

The type system rests upon a few base types. In considering which types to
support, we aimed for clarity and simplicity over abundance, focusing
on the key types available in all programming languages, ommitting any
niche types available only in specific languages.

The base types supported by Thrift are:
\begin{itemize}
\item \texttt{bool} A boolean value, true or false
\item \texttt{byte} A signed byte
\item \texttt{i16} A 16-bit signed integer
\item \texttt{i32} A 32-bit signed integer
\item \texttt{i64} A 64-bit signed integer
\item \texttt{double} A 64-bit floating point number
\item \texttt{string} An encoding-agnostic text or binary string
\end{itemize}

Of particular note is the absence of unsigned integer types. Because these
types have no direct translation to native primitive types in many languages,
the advantages they afford are lost. Further, there is no way to prevent the
application developer in a language like Python from assigning a negative value
to an integer variable, leading to unpredictable behavior. From a design
standpoint, we observed that unsigned integers were very rarely, if ever, used
for arithmetic purposes, but in practice were much more often used as keys or
identifiers. In this case, the sign is irrelevant. Signed integers serve this
same purpose and can be safely cast to their unsigned counterparts (most
commonly in C++) when absolutely necessary.

\subsection{Containers}

Thrift containers are strongly typed containers that map to the most commonly
used containers in common programming languages. They are annotated using
C++ template (or Java Generics) style. There are three types available:
\begin{itemize}
\item \texttt{list<type>} An ordered list of elements. Translates directly into
an STL vector, Java ArrayList, or native array in scripting languages. May
contain duplicates.
\item \texttt{set<type>} An unordered set of unique elements. Translates into
an STL set, Java HashSet, or native dictionary in PHP/Python/Ruby.
\item \texttt{map<type1,type2>} A map of strictly unique keys to values
Translates into an STL map, Java HashMap, PHP associative array,
or Python/Ruby dictionary.
\end{itemize}

While defaults are provided, the type mappings are not explicitly fixed. Custom
code generator directives have been added to substitute custom types in
destination languages (i.e.
\texttt{hash\_map}, or Google's sparse hash map can be used in C++). The
only requirement is that the custom types support all the necessary iteration
primitives. Container elements may be of any valid Thrift type, including other
containers or structs.

\subsection{Structs}

A Thrift struct defines a common objects to be used across languages. A struct
is essentially equivalent to a class in object oriented programming
languages. A struct has a set of strongly typed fields, each with a unique
name identifier. The basic syntax for defining a Thrift struct looks very
similar to a C struct definition. Fields may be annotated with an integer field
identifier (unique to the scope of that struct) and optional default values.
Field identifiers will be automatically assigned if omitted, though they are
strongly encouraged for versioning reasons discussed later.

\begin{verbatim}
struct Example {
  1:i32 number=10,
  2:i64 bigNumber,
  3:double decimals,
  4:string name="thrifty"
}\end{verbatim}

In the target language, each definition generates a type with two methods,
\texttt{read} and \texttt{write}, which perform serialization and transport
of the objects using a Thrift TProtocol object.

\subsection{Exceptions}

Exceptions are syntactically and functionally equivalent to structs except
that they are declared using the \texttt{exception} keyword instead of the
\texttt{struct} keyword.

The generated objects inherit from an exception base class as appropriate
in each target programming language, the goal being to offer seamless
integration with native exception handling for the developer in any given
language. Again, the design emphasis is on making the code familiar to the
application developer.

\subsection{Services}

Services are defined using Thrift types. Definition of a service is
semantically equivalent to defining a pure virtual interface in object oriented
programming. The Thrift compiler generates fully functional client and
server stubs that implement the interface. Services are defined as follows:

\begin{verbatim}
service <name> {
  <returntype> <name>(<arguments>)
    [throws (<exceptions>)]
  ...
}\end{verbatim}

An example:

\begin{verbatim}
service StringCache {
  void set(1:i32 key, 2:string value),
  string get(1:i32 key) throws (1:KeyNotFound knf),
  void delete(1:i32 key) 
}
\end{verbatim}

Note that \texttt{void} is a valid type for a function return, in addition to
all other defined Thrift types. Additionally, an \texttt{async} modifier
keyword may be added to a void function, which will generate code that does
not wait for a response from the server. Note that a pure \texttt{void}
function will return a response to the client which guarantees that the
operation has completed on the server side. With \texttt{async} method calls
the client can only be guaranteed that the request succeeded at the
transport layer. (In many transport scenarios this is inherently unreliable
due to the Byzantine Generals' Problem. Therefore, application developers
should take care only to use the async optimization in cases where dopped
method calls are acceptable or the transport is known to be reliable.)

Also of note is the fact that argument and exception lists to functions are
implemented as Thrift structs. They are identical in both notation and
behavior.

\section{Transport}

The transport layer is used by the generated code to facilitate data transfer.

\subsection{Interface}

A key design choice in the implementation of Thrift was to abstract the
transport layer from the code generation layer. Though Thrift is typically
used on top of the TCP/IP stack with streaming sockets as the base layer of
communication, there was no compelling reason to build that constraint into 
the system. The performance tradeoff incurred by an abstracted I/O layer
(roughly one virtual method lookup / function call per operation) was
immaterial compared to the cost of actual I/O operations (typically invoking
system calls).

Fundamentally, generated Thrift code just needs to know how to read and
write data. Where the data is going is irrelevant, it may be a socket, a
segment of shared memory, or a file on the local disk. The Thrift transport
interface supports the following methods.

\begin{itemize}
\item \texttt{open()} Opens the tranpsort
\item \texttt{close()} Closes the tranport
\item \texttt{isOpen()} Whether the transport is open
\item \texttt{read()} Reads from the transport
\item \texttt{write()} Writes to the transport
\item \texttt{flush()} Force any pending writes
\end{itemize}

There are a few additional methods not documented here which are used to aid
in batching reads and optionally signaling completion of reading or writing
chunks of data by the generated code.

In addition to the above
\texttt{TTransport} interface, there is a \texttt{TServerTransport} interface
used to accept or create primitive transport objects. Its interface is as
follows:

\begin{itemize}
\item \texttt{open()} Opens the tranpsort
\item \texttt{listen()} Begins listening for connections
\item \texttt{accept()} Returns a new client transport
\item \texttt{close()} Closes the transport

\end{itemize}

\subsection{Implementation}

The transport interface is designed for simple implementation in any
programming language. New transport mechanisms can be easily defined as needed
by application developers.

\subsubsection{TSocket}

The \texttt{TSocket} class is implemented across all target languages. It
provides a common, simple interface to a TCP/IP stream socket.

\subsubsection{TFileTransport}

The \texttt{TFileTransport} is an abstraction of an on-disk file to a data
stream. It allows Thrift data structures to be used as historical log data.
Essentially, an application developer can use a \texttt{TFileTransport} to
write out a set of
requests to a file on disk. Later, this data may be replayed from the log,
either for post-processing or for recreation and simulation of previous events.

\subsubsection{Utilities}

The Transport interface is designed to support easy extension using common
OOP techniques such as composition. Some simple utilites include the
\texttt{TBufferedTransport}, which buffers writes and reads on an underlying
transport, the \texttt{TFramedTransport}, which transmits data with frame
size headers for chunking optimzation or nonblocking operation, and the
\texttt{TMemoryBuffer}, which allows reading and writing directly from heap or
stack memory owned by the process.

\section{Protocol}

A second major abstraction in Thrift is the separation of data structure from
transport representation. Thrift enforces a certain messaging structure when
transporting data, but it is agnostic to the protocol encoding in use. That is,
it does not matter whether data is encoded in XML, human-readable ASCII, or a
dense binary format, so long as the data supports a fixed set of operations
that allow generated code to deterministically read and write.

\subsection{Interface}

The Thrift Protocol interface is very straightforward. It fundamentally
supports two things: 1) bidirectional sequenced messaging, and
2) encoding of base types, containers, and structs.

\begin{verbatim}
writeMessageBegin(name, type, seq)
writeMessageEnd()
writeStructBegin(name)
writeStructEnd()
writeFieldBegin(name, type, id)
writeFieldEnd()
writeFieldStop()
writeMapBegin(ktype, vtype, size)
writeMapEnd()
writeListBegin(etype, size)
writeListEnd()
writeSetBegin(etype, size)
writeSetEnd()
writeBool(bool)
writeByte(byte)
writeI16(i16)
writeI32(i32)
writeI64(i64)
writeDouble(double)
writeString(string)

name, type, seq = readMessageBegin()
                  readMessageEnd()
name =            readStructBegin()
                  readStructEnd()
name, type, id =  readFieldBegin()
                  readFieldEnd()
k, v, size =      readMapBegin()
                  readMapEnd()
etype, size =     readListBegin()
                  readListEnd()
etype, size =     readSetBegin()
                  readSetEnd()
bool =            readBool()
byte =            readByte()
i16 =             readI16()
i32 =             readI32()
i64 =             readI64()
double =          readDouble()
string =          readString()
\end{verbatim}

Note that every write function has exactly one read function counterpart, with
the exception of the \texttt{writeFieldStop()} method. This is a special method
that signals the end of a struct. The procedure for reading a struct is to
\texttt{readFieldBegin()} until the stop field is encountered, and to then
\texttt{readStructEnd()}.  The
generated code relies upon this structure to ensure that everything written by
a protocol encoder can be read by a matching protocol decoder. Further note
that this set of functions is by design more robust than necessary.
For example, \texttt{writeStructEnd()} is not strictly necessary, as the end of
a struct may be implied by the stop field. This method is a convenience for
verbose protocols where it is cleaner to separate these calls (i.e. a closing
\texttt{</struct>} tag in XML).

\subsection{Structure}

Thrift structures are designed to support encoding into a streaming
protocol. That is, the implementation should never need to frame or compute the
entire data length of a structure prior to encoding it. This is critical to
performance in many scenarios. Consider a long list of relatively large
strings. If the protocol interface required reading or writing a list as an
atomic operation, then the implementation would require a linear pass over the
entire list before encoding any data. However, if the list can be written
as iteration is performed, the corresponding read may begin in parallel,
theoretically offering an end-to-end speedup of $kN - C$, where $N$ is the size
of the list, $k$ the cost factor associated with serializing a single
element, and $C$ is fixed offset for the delay between data being written
and becoming available to read.

Similarly, structs do not encode their data lengths a priori. Instead, they are
encoded as a sequence of fields, with each field having a type specifier and a
unique field identifier. Note that the inclusion of type specifiers enables
the protocol to be safely parsed and decoded without any generated code
or access to the original IDL file. Structs are terminated by a field header
with a special \texttt{STOP} type. Because all the basic types can be read
deterministically, all structs (including those with nested structs) can be
read deterministically. The Thrift protocol is self-delimiting without any
framing and regardless of the encoding format.

In situations where streaming is unnecessary or framing is advantageous, it
can be very simply added into the transport layer, using the
\texttt{TFramedTransport} abstraction.

\subsection{Implementation}

Facebook has implemented and deployed a space-efficient binary protocol which
is used by most backend services. Essentially, it writes all data
in a flat binary format. Integer types are converted to network byte order,
strings are prepended with their byte length, and all message and field headers
are written using the primitive integer serialization constructs. String names
for fields are omitted - when using generated code, field identifiers are
sufficient.

We decided against some extreme storage optimizations (i.e. packing
small integers into ASCII or using a 7-bit continuation format) for the sake
of simplicity and clarity in the code. These alterations can easily be made
if and when we encounter a performance critical use case that demands them.

\section{Versioning}

Thrift is robust in the face of versioning and data definition changes. This
is critical to enable a staged rollout of changes to deployed services. The
system must be able to support reading of old data from logfiles, as well as
requests from out of date clients to new servers, or vice versa.

\subsection{Field Identifiers}

Versioning in Thrift is implemented via field identifiers. The field header
for every member of a struct in Thrift is encoded with a unique field
identifier. The combination of this field identifier and its type specifier
is used to uniquely identify the field. The Thrift definition language
supports automatic assignment of field identifiers, but it is good
programming practice to always explicitly specify field identifiers.
Identifiers are specified as follows:

\begin{verbatim}
struct Example {
  1:i32 number=10,
  2:i64 bigNumber,
  3:double decimals,
  4:string name="thrifty"
}\end{verbatim}

To avoid conflicts, fields with omitted identifiers are automatically assigned
decrementing from -1, and the language only supports the manual assignment of
positive identifiers.

When data is being deserialized, the generated code can use these identifiers
to properly identify the field and determine whether it aligns with a field in
its definition file. If a field identifier is not recognized, the generated
code can use the type specifier to skip the unknown field without any error.
Again, this is possible due to the fact that all data types are self
delimiting.

Field identifiers can (and should) also be specified in function argument
lists. In fact, argument lists are not only represented as structs on the
backend, but actually share the same code in the compiler frontend. This
allows for version-safe modification of method parameters

\begin{verbatim}
service StringCache {
  void set(1:i32 key, 2:string value),
  string get(1:i32 key) throws (1:KeyNotFound knf),
  void delete(1:i32 key) 
}
\end{verbatim}

The syntax for specifying field identifiers was chosen to echo their structure.
Structs can be thought of as a dictionary where the identifiers are keys, and
the values are strongly typed, named fields.

Field identifiers internally use the \texttt{i16} Thrift type. Note, however,
that the \texttt{TProtocol} abstraction may encode identifiers in any format.

\subsection{Isset}

When an unexpected field is encountered, it can be safely ignored and
discarded. When an expected field is not found, there must be some way to
signal to the developer that it was not present. This is implemented via an
inner \texttt{isset} structure inside the defined objects. (In PHP, this is
implicit with a \texttt{null} value, or \texttt{None} in Python
and \texttt{nil} in Ruby.) Essentially,
the inner \texttt{isset} object of each Thrift struct contains a boolean value
for each field which denotes whether or not that field is present in the
struct. When a reader receives a struct, it should check for a field being set
before operating directly on it.

\begin{verbatim}
class Example {
 public:
  Example() :
    number(10),
    bigNumber(0),
    decimals(0),
    name("thrifty") {} 

  int32_t number;
  int64_t bigNumber;
  double decimals;
  std::string name;

  struct __isset {
    __isset() :
      number(false),
      bigNumber(false),
      decimals(false),
      name(false) {}
    bool number;
    bool bigNumber;
    bool decimals;
    bool name;
  } __isset;
...
}
\end{verbatim} 

\subsection{Case Analysis}

There are four cases in which version mismatches may occur.

\begin{enumerate}
\item \textit{Added field, old client, new server.} In this case, the old
client does not send the new field. The new server recognizes that the field
is not set, and implements default behavior for out of date requests.
\item \textit{Removed field, old client, new server.} In this case, the old
client sends the removed field. The new server simply ignores it.
\item \textit{Added field, new client, old server.} The new client sends a
field that the old server does not recognize. The old server simply ignores
it and processes as normal.
\item \textit{Removed field, new client, old server.} This is the most
dangerous case, as the old server is unlikely to have suitable default
behavior implemented for the missing field. It is recommended that in this
situation the new server be rolled out prior to the new clients.
\end{enumerate}

\subsection{Protocol/Transport Versioning}
The \texttt{TProtocol} abstractions are also designed to give protocol
implementations the freedom to version themselves in whatever manner they
see fit. Specifically, any protocol implementation is free to send whatever
it likes in the \texttt{writeMessageBegin()} call. It is entirely up to the
implementor how to handle versioning at the protocol level. The key point is
that protocol encoding changes are safely isolated from interface definition
version changes.

Note that the exact same is true of the \texttt{TTransport} interface. For
example, if we wished to add some new checksumming or error detection to the
\texttt{TFileTransport}, we could simply add a version header into the
data it writes to the file in such a way that it would still accept old
logfiles without the given header.

\section{RPC Implementation}

\subsection{TProcessor}

The last core interface in the Thrift design is the \texttt{TProcessor},
perhaps the most simple of the constructs. The interface is as follows:

\begin{verbatim}
interface TProcessor {
  bool process(TProtocol in, TProtocol out)
    throws TException
}
\end{verbatim}

The key design idea here is that the complex systems we build can fundamentally
be broken down into agents or services that operate on inputs and outputs. In
most cases, there is actually just one input and output (an RPC client) that
needs handling.

\subsection{Generated Code}

When a service is defined, we generate a
\texttt{TProcessor} instance capable of handling RPC requests to that service,
using a few helpers. The fundamental structure (illustrated in pseudo-C++) is
as follows:

\begin{verbatim}
Service.thrift
 => Service.cpp
     interface ServiceIf
     class ServiceClient : virtual ServiceIf
       TProtocol in
       TProtocol out
     class ServiceProcessor : TProcessor
       ServiceIf handler

ServiceHandler.cpp
 class ServiceHandler : virtual ServiceIf

TServer.cpp
 TServer(TProcessor processor,
         TServerTransport transport,
         TTransportFactory tfactory,
         TProtocolFactory pfactory)
 serve()
\end{verbatim}

From the thrift definition file, we generate the virtual service interface.
A client class is generated, which implements the interface and
uses two \texttt{TProtocol} instances to perform the I/O operations. The
generated processor implements the \texttt{TProcessor} interface. The generated
code has all the logic to handle RPC invocations via the \texttt{process()}
call, and takes as a parameter an instance of the service interface,
implemented by the application developer.

The user provides an implementation of the application interface in their own,
non-generated source file.

\subsection{TServer}

Finally, the Thrift core libraries provide a \texttt{TServer} abstraction.
The \texttt{TServer} object generally works as follows.

\begin{itemize}
\item Use the \texttt{TServerTransport} to get a \texttt{TTransport}
\item Use the \texttt{TTransportFactory} to optionally convert the primitive
transport into a suitable application transport (typically the
\texttt{TBufferedTransportFactory} is used here)
\item Use the \texttt{TProtocolFactory} to create an input and output protocol
for the \texttt{TTransport}
\item Invoke the \texttt{process()} method of the \texttt{TProcessor} object
\end{itemize}

The layers are appropriately separated such that the server code needs to know
nothing about any of the transports, encodings, or applications in play. The
server encapsulates the logic around connection handling, threading, etc.
while the processor deals with RPC. The only code written by the application
developer lives in the definitional thrift file and the interface
implementation.

Facebook has deployed multiple \texttt{TServer} implementations, including
the single-threaded \texttt{TSimpleServer}, thread-per-connection
\texttt{TThreadedServer}, and thread-pooling \texttt{TThreadPoolServer}.

The \texttt{TProcessor} interface is very general by design. There is no
requirement that a \texttt{TServer} take a generated \texttt{TProcessor}
object. Thrift allows the application developer to easily write any type of
server that operates on \texttt{TProtocol} objects (for instance, a server
could simply stream a certain type of object without any actual RPC method
invocation).

\section{Implementation Details}
\subsection{Target Languages}
Thrift currently supports five target languages: C++, Java, Python, Ruby, and
PHP. At Facebook, we have deployed servers predominantly in C++, Java, and
Python. Thrift services implemented in PHP have also been embedded into the
Apache web server, providing transparent backend access to many of our
frontend constructs using a \texttt{THttpClient} implementation of the
\texttt{TTransport} interface.

Though Thrift was explicitly designed to be much more efficient and robust
than typical web technologies, as we were designing our XML-based REST web
services API we noticed that Thrift could be easily used to define our
service interface. Though we do not currently employ SOAP envelopes (in the
author's opinion there is already far too much repetetive enterprise Java
software to do that sort of thing), we were able to quickly extend Thrift to
generate XML Schema Definition files for our service, as well as a framework
for versioning different implementations of our web service. Though public
web services are admittedly tangential to Thrift's core use case and design,
Thrift facilitated rapid iteration and affords us the ability to quickly
migrate our entire XML-based web service onto a higher performance system
should the future need arise.

\subsection{Generated Structs}
We made a conscious decision to make our generated structs as transparent as
possible. All fields are publicly accessible; there are no \texttt{set()} and
\texttt{get()} methods. Similarly, use of the \texttt{isset} object is not
enforced. We do not include any \texttt{FieldNotSetException} construct.
Developers have the option to use these fields to write more robust code, but
the system is robust to the developer ignoring the \texttt{isset} construct
entirely and will provide suitable default behavior in all cases.

The reason for this choice was for ease of application development. Our stated
goal is not to make developers learn a rich new library in their language of
choice, but rather to generate code that allow them to work with the constructs
that are most familiar in each language.

We also made the \texttt{read()} and \texttt{write()} methods of the generated
objects public members so that the objects can be used outside of the context
of RPC clients and servers. Thrift is a useful tool simply for generating
objects that are easily serializable across programming languages.

\subsection{RPC Method Identification}
Method calls in RPC are implemented by sending the method name as a string. One
issue with this approach is that longer method names require more bandwidth.
We experimented with using fixed-size hashes to identify methods, but in the
end concluded that the savings were not worth the headaches incurred. Reliably
dealing with conflicts across versions of an interface definition file is
impossible without a meta-storage system (i.e. to generate non-conflicting
hashes for the current version of a file, we would have to know about all
conflicts that ever existed in any previous version of the file).

We wanted to avoid too many unnecessary string comparisons upon
method invocation. To deal with this, we generate maps from strings to function
pointers, so that invocation is effectively accomplished via a constant-time
hash lookup in the common case. This requires the use of a couple interesting
code constructs. Because Java does not have function pointers, process
functions are all private member classes implementing a common interface.

\begin{verbatim}
private class ping implements ProcessFunction {
  public void process(int seqid,
                      TProtocol iprot,
                      TProtocol oprot)
    throws TException
  { ...}
}

HashMap<String,ProcessFunction> processMap_ =
  new HashMap<String,ProcessFunction>();
\end{verbatim}

In C++, we use a relatively esoteric language construct: member function
pointers.

\begin{verbatim}
std::map<std::string,
  void (ExampleServiceProcessor::*)(int32_t,
  facebook::thrift::protocol::TProtocol*,
  facebook::thrift::protocol::TProtocol*)>
 processMap_;
\end{verbatim}

Using these techniques, the cost of string processing is minimized, and we
reap the benefit of being able to easily debug corrupt or misunderstood data by
looking for string contents.

\subsection{Servers and Multithreading}
MARC TO WRITE THIS SECTION ON THE C++ concurrency PACKAGE AND
BASIC TThreadPoolServer PERFORMANCE ETC. (ie. 140K req/second, that kind of
thing)

\subsection{Nonblocking Operation}
Though the Thrift transport interfaces map more directly to a blocking I/O
model, we have implemented a high performance \texttt{TNonBlockingServer}
in C++ based upon \texttt{libevent} and the \texttt{TFramedTransport}. We
implemented this by moving all I/O into one tight event loop using a
state machine. Essentially, the event loop reads framed requests into
\texttt{TMemoryBuffer} objects. Once entire requests are ready, they are
dispatched to the \texttt{TProcessor} object which can read directly from
the data in memory.

\subsection{Compiler}
The Thrift compiler is implemented in C++ using standard lex/yacc style
tokenization and parsing. Though it could have been implemented with fewer
lines of code in another language (i.e. Python/PLY or ocamlyacc), using C++
forces explicit definition of the language constructs. Strongly typing the
parse tree elements (debatably) makes the code more approachable for new
developers.

Code generation is done using two passes. The first pass looks only for
include files and type definitions. Type definitions are not checked during
this phase, since they may depend upon include files. All included files
are sequentially scanned in a first pass. Once the include tree has been
resolved, a second pass is taken over all files which inserts type definitions
into the parse tree and raises an error on any undefined types. The program is
then generated against the parse tree.

Due to inherent complexities and potential for circular dependencies,
we explicitly disallow forward declaration. Two Thrift structs cannot
each contain an instance of the other. (Since we do not allow \texttt{null}
struct instances in the generated C++ code, this would actually be impossible.)

\section{Conclusions}
Thrift has enabled Facebook to build scalable backend
services efficiently by enabling engineers to divide and conquer. Application
developers can focus upon application code without worrying about the
sockets layer. We avoid duplicated work by writing buffering and I/O logic
in one place, rather than interspersing it in each application.

Thrift has been employed in a wide variety of applications at Facebook,
including search, logging, mobile, ads, and platform. We have
found that the marginal performance cost incurred by an extra layer of
software abstraction is eclipsed by the gains in developer efficiency and
systems reliability.

\appendix

\section{Similar Systems}
The following are software systems similar to Thrift. Each is (very!) briefly
described:

\begin{itemize}
\item \textit{SOAP.} XML-based. Designed for web services via HTTP, excessive
XML parsing overhead.
\item \textit{CORBA.} Relatively comprehensive, debatably overdesigned and
heavyweight. Comparably cumbersome software installation.
\item \textit{COM.} Embraced mainly in Windows client softare. Not an entirely
open solution.
\item \textit{Pillar.} Lightweight and high-performance, but missing versioning
and abstraction.
\item \textit{Protocol Buffers.} Closed-source, owned by Google. Described in
Sawzall paper.
\end{itemize}

\acks

Many thanks for feedback on Thrift (and extreme trial by fire) are due to
Martin Smith, Karl Voskuil, and Yishan Wong.

Thrift is a successor to Pillar, a similar system developed
by Adam D'Angelo, first while at Caltech and continued later at Facebook.
Thrift simply would not have happened without Adam's insights.

%\begin{thebibliography}{}

%\bibitem{smith02}
%Smith, P. Q. reference text

%\end{thebibliography}

\end{document}