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Endian Home     Conversion Functions     Arithmetic Types     Buffer Types     Choosing Approach

Contents
Introduction
Choosing between conversion functions,
  buffer types, and arithmetic types
   Characteristics
      Endianness invariants
      Conversion explicitness
      Arithmetic operations
      Sizes
      Alignments
   Design patterns
      Convert only as needed (i.e. lazy)
      Convert in anticipation of need
      Generally as needed, locally in anticipation
   Use case examples
      Porting endian unaware codebase
      Porting endian aware codebase
      Reliability and arithmetic-speed
      Reliability and ease-of-use

Introduction

Deciding which is the best endianness approach (conversion functions, buffer types, or arithmetic types) for a particular application involves complex engineering trade-offs. It is hard to assess those trade-offs without some understanding of the different interfaces, so you might want to read the conversion functions, buffer types, and arithmetic types pages before diving into this page.

Choosing between conversion functions, buffer types, and arithmetic types

The best approach to endianness for a particular application depends on the interaction between the application's needs and the characteristics of each of the three approaches.

Recommendation: If you are new to endianness, uncertain, or don't want to invest the time to study engineering trade-offs, use endian arithmetic types. They are safe, easy to use, and easy to maintain. Use the anticipating need design pattern locally around performance hot spots like lengthy loops, if needed.

Background

A dealing with endianness usually implies a program portability or a data portability requirement, and often both. That means real programs dealing with endianness are usually complex, so the examples shown here would really be written as multiple functions spread across multiple translation units. They would involve interfaces that can not be altered as they are supplied by third-parties or the standard library.

Characteristics

The characteristics that differentiate the three approaches to endianness are the endianness invariants, conversion explicitness, arithmetic operations, sizes available, and alignment requirements.

Endianness invariants

Endian conversion functions use objects of the ordinary C++ arithmetic types like int or unsigned short to hold values. That breaks the implicit invariant that the C++ language rules apply. The usual language rules only apply if the endianness of the object is currently set to the native endianness for the platform. That can make it very hard to reason about logic flow, and result in difficult to find bugs.

For example:

struct data_t  // big endian
{
  int32_t   v1;  // description ...
  int32_t   v2;  // description ...
  ... additional character data members (i.e. non-endian)
  int32_t   v3;  // description ...
};

data_t data;

read(data);
big_to_native_inplace(data.v1);
big_to_native_inplace(data.v2);

... 

++v1;
third_party::func(data.v2);

... 

native_to_big_inplace(data.v1);
native_to_big_inplace(data.v2);
write(data);

The programmer didn't bother to convert data.v3 to native endianness because that member isn't used. A later maintainer needs to pass data.v3 to the third-party function, so adds third_party::func(data.v3); somewhere deep in the code. This causes a silent failure because the usual invariant that an object of type int32_t holds a value as described by the C++ core language does not apply.

Endian buffer and arithmetic types hold values internally as arrays of characters with an invariant that the endianness of the array never changes. That makes these types easier to use and programs easier to maintain.

Here is the same example, using an endian arithmetic type:

struct data_t
{
  big_int32_t   v1;  // description ...
  big_int32_t   v2;  // description ...
  ... additional character data members (i.e. non-endian)
  big_int32_t   v3;  // description ...
};

data_t data;

read(data);

... 

++v1;
third_party::func(data.v2);

... 

write(data);

A later maintainer can add third_party::func(data.v3)and it will just-work.

Conversion explicitness

Endian conversion functions and buffer types never perform implicit conversions. This gives users explicit control of when conversion occurs, and may help avoid unnecessary conversions.

Endian arithmetic types perform conversion implicitly. That makes these types very easy to use, but can result in unnecessary conversions. Failure to hoist conversions out of inner loops can bring a performance penalty.

Arithmetic operations

Endian conversion functions do not supply arithmetic operations, but this is not a concern since this approach uses ordinary C++ arithmetic types to hold values.

Endian buffer types do not supply arithmetic operations. Although this approach avoids unnecessary conversions, it can result in the introduction of additional variables and confuse maintenance programmers.

Endian arithmetic types do supply arithmetic operations. They are very easy to use if lots of arithmetic is involved.

Sizes

Endianness conversion functions only support 1, 2, 4, and 8 byte integers. That's sufficient for many applications.

Endian buffer and arithmetic types support 1, 2, 3, 4, 5, 6, 7, and 8 byte integers. For an application where memory use or I/O speed is the limiting factor, using sizes tailored to application needs can be useful.

Alignments

Endianness conversion functions only support aligned integer and floating-point types. That's sufficient for most applications.

Endian buffer and arithmetic types support both aligned and unaligned integer and floating-point types. Unaligned types are rarely needed, but when needed they are often very useful and workarounds are painful. For example,

Non-portable code like this:

struct S {
  uint16_t a;  // big endian
  uint32_t b;  // big endian
} __attribute__ ((packed));

Can be replaced with portable code like this:

struct S {
  big_uint16_ut a;
  big_uint32_ut b;
};

Design patterns

Applications often traffic in endian data as records or packets containing multiple endian data elements. For simplicity, we will just call them records.

If desired endianness differs from native endianness, a conversion has to be performed. When should that conversion occur? Three design patterns have evolved.

Convert only as needed (i.e. lazy)

This pattern defers conversion to the point in the code where the data element is actually used.

This pattern is appropriate when which endian element is actually used varies greatly according to record content or other circumstances

Convert in anticipation of need

This pattern performs conversion to native endianness in anticipation of use, such as immediately after reading records. If needed, conversion to the output endianness is performed after all possible needs have passed, such as just before writing records.

One implementation of this pattern is to create a proxy record with endianness converted to native in a read function, and expose only that proxy to the rest of the implementation. If a write function, if needed, handles the conversion from native to the desired output endianness.

This pattern is appropriate when all endian elements in a record are typically used regardless of record content or other circumstances

Convert only as needed, except locally in anticipation of need

This pattern in general defers conversion but for specific local needs does anticipatory conversion. Although particularly appropriate when coupled with the endian buffer or arithmetic types, it also works well with the conversion functions.

Example:

struct data_t
{
  big_int32_t   v1;
  big_int32_t   v2;
  big_int32_t   v3;
};

data_t data;

read(data);

...
++v1;
...

int32_t v3_temp = data.v3;  // hoist conversion out of loop

for (int32_t i = 0; i < large-number; ++i)
{
  ... lengthy computation that accesses v3_temp many times ...
}
data.v3 = v3_temp; 

write(data);

In general the above pseudo-code leaves conversion up to the endian arithmetic type big_int32_t. But to avoid conversion inside the loop, a temporary is created before the loop is entered, and then used to set the new value of data.v3 after the loop is complete.

Question: Won't the compiler's optimizer hoist the conversion out of the loop anyhow?

Answer: VC++ 2015 Preview, and probably others, does not, even for a toy test program. Although the savings is small (two register bswap instructions), the cost might be significant if the loop is repeated enough times. On the other hand, the program may be so dominated by I/O time that even a lengthy loop will be immaterial.

Use case examples

Porting endian unaware codebase

An existing codebase runs on big endian systems. It does not currently deal with endianness. The codebase needs to be modified so it can run on  little endian systems under various operating systems. To ease transition and protect value of existing files, external data will continue to be maintained as big endian.

The endian arithmetic approach is recommended to meet these needs. A relatively small number of header files dealing with binary I/O layouts need to change types. For example,  short or int16_t would change to big_int16_t. No changes are required for .cpp files.

Porting endian aware codebase

An existing codebase runs on little-endian Linux systems. It already deals with endianness via Linux provided functions. Because of a business merger, the codebase has to be quickly modified for Windows and possibly other operating systems, while still supporting Linux. The codebase is reliable and the programmers are all well-aware of endian issues.

These factors all argue for an endian conversion approach that just mechanically changes the calls to htobe32, etc. to boost::endian::native_to_big, etc. and replaces <endian.h> with <boost/endian/conversion.hpp>.

Reliability and arithmetic-speed

A new, complex, multi-threaded application is to be developed that must run on little endian machines, but do big endian network I/O. The developers believe computational speed for endian variable is critical but have seen numerous bugs result from inability to reason about endian conversion state. They are also worried that future maintenance changes could inadvertently introduce a lot of slow conversions if full-blown endian arithmetic types are used.

The endian buffers approach is made-to-order for this use case.

Reliability and ease-of-use

A new, complex, multi-threaded application is to be developed that must run on little endian machines, but do big endian network I/O. The developers believe computational speed for endian variables is not critical but have seen numerous bugs result from inability to reason about endian conversion state. They are also concerned about ease-of-use both during development and long-term maintenance.

Removing concern about conversion speed and adding concern about ease-of-use tips the balance strongly in favor the endian arithmetic approach.


Last revised: 19 January, 2015

© Copyright Beman Dawes, 2011, 2013, 2014

Distributed under the Boost Software License, Version 1.0. See www.boost.org/ LICENSE_1_0.txt