This module describes the digest APIs used in Phobos. All digests follow these APIs. Additionally, this module contains useful helper methods which can be used with every digest type.
Category | Functions |
---|---|
Template API | isDigest DigestType hasPeek hasBlockSize ExampleDigest digest hexDigest makeDigest |
OOP API | Digest |
Helper functions | toHexString |
Implementation helpers | digestLength WrapperDigest |
isDigest
. The OOP API implements digests as classes inheriting the Digest
interface. All digests are named so that the template API struct is called "x" and the OOP API class is called "xDigest". For example we have MD5
<--> MD5Digest
, CRC32
<--> CRC32Digest
, etc. Digest
classes still have to be created using new
which allocates them using the GC. The OOP API is useful to change the digest function and/or digest backend at 'runtime'. The benefit here is that switching e.g. Phobos MD5Digest and an OpenSSLMD5Digest implementation is ABI compatible. If just one specific digest type and backend is needed, the template API is usually a good fit. In this simplest case, the template API can even be used without templates: Just use the "x" structs directly. import std.digest.crc; //Simple example char[8] hexHash = hexDigest!CRC32("The quick brown fox jumps over the lazy dog"); writeln(hexHash); // "39A34F41" //Simple example, using the API manually CRC32 context = makeDigest!CRC32(); context.put(cast(ubyte[])"The quick brown fox jumps over the lazy dog"); ubyte[4] hash = context.finish(); writeln(toHexString(hash)); // "39A34F41"
//Generating the hashes of a file, idiomatic D way import std.digest.crc, std.digest.md, std.digest.sha; import std.stdio; // Digests a file and prints the result. void digestFile(Hash)(string filename) if (isDigest!Hash) { auto file = File(filename); auto result = digest!Hash(file.byChunk(4096 * 1024)); writefln("%s (%s) = %s", Hash.stringof, filename, toHexString(result)); } void main(string[] args) { foreach (name; args[1 .. $]) { digestFile!MD5(name); digestFile!SHA1(name); digestFile!CRC32(name); } }
//Generating the hashes of a file using the template API import std.digest.crc, std.digest.md, std.digest.sha; import std.stdio; // Digests a file and prints the result. void digestFile(Hash)(ref Hash hash, string filename) if (isDigest!Hash) { File file = File(filename); //As digests imlement OutputRange, we could use std.algorithm.copy //Let's do it manually for now foreach (buffer; file.byChunk(4096 * 1024)) hash.put(buffer); auto result = hash.finish(); writefln("%s (%s) = %s", Hash.stringof, filename, toHexString(result)); } void uMain(string[] args) { MD5 md5; SHA1 sha1; CRC32 crc32; md5.start(); sha1.start(); crc32.start(); foreach (arg; args[1 .. $]) { digestFile(md5, arg); digestFile(sha1, arg); digestFile(crc32, arg); } }
import std.digest.crc, std.digest.md, std.digest.sha; import std.stdio; // Digests a file and prints the result. void digestFile(Digest hash, string filename) { File file = File(filename); //As digests implement OutputRange, we could use std.algorithm.copy //Let's do it manually for now foreach (buffer; file.byChunk(4096 * 1024)) hash.put(buffer); ubyte[] result = hash.finish(); writefln("%s (%s) = %s", typeid(hash).toString(), filename, toHexString(result)); } void umain(string[] args) { auto md5 = new MD5Digest(); auto sha1 = new SHA1Digest(); auto crc32 = new CRC32Digest(); foreach (arg; args[1 .. $]) { digestFile(md5, arg); digestFile(sha1, arg); digestFile(crc32, arg); } }
This documents the general structure of a Digest in the template API. All digest implementations should implement the following members and therefore pass the isDigest
test.
isDigest
test.isDigest
test is always an OutputRange
//Using the OutputRange feature import std.algorithm.mutation : copy; import std.digest.md; import std.range : repeat; auto oneMillionRange = repeat!ubyte(cast(ubyte)'a', 1000000); auto ctx = makeDigest!MD5(); copy(oneMillionRange, &ctx); //Note: You must pass a pointer to copy! writeln(ctx.finish().toHexString()); // "7707D6AE4E027C70EEA2A935C2296F21"
Use this to feed the digest with data
. Also implements the std.range.primitives.isOutputRange
interface for ubyte
and const(ubyte)[]
. The following usages of put
must work for any type which passes isDigest
:
ExampleDigest dig; dig.put(cast(ubyte) 0); //single ubyte dig.put(cast(ubyte) 0, cast(ubyte) 0); //variadic ubyte[10] buf; dig.put(buf); //buffer
This function is used to (re)initialize the digest. It must be called before using the digest and it also works as a 'reset' function if the digest has already processed data.
The finish
function returns the final hash sum and resets the Digest.
finish
depends on the digest implementation. ubyte[16]
is just used as an example. It is guaranteed that the type is a static array of ubytes. DigestType
to obtain the actual return type.digestLength
to obtain the length of the ubyte array.Use this to check if a type is a digest. See ExampleDigest
to see what a type must provide to pass this check.
import std.digest.crc; static assert(isDigest!CRC32);
import std.digest.crc; void myFunction(T)() if (isDigest!T) { T dig; dig.start(); auto result = dig.finish(); } myFunction!CRC32();
Use this template to get the type which is returned by a digest's finish
method.
import std.digest.crc; assert(is(DigestType!(CRC32) == ubyte[4]));
import std.digest.crc; CRC32 dig; dig.start(); DigestType!CRC32 result = dig.finish();
Used to check if a digest supports the peek
method. Peek has exactly the same function signatures as finish, but it doesn't reset the digest's internal state.
isDigest
import std.digest.crc, std.digest.md; assert(!hasPeek!(MD5)); assert(hasPeek!CRC32);
import std.digest.crc; void myFunction(T)() if (hasPeek!T) { T dig; dig.start(); auto result = dig.peek(); } myFunction!CRC32();
Checks whether the digest has a blockSize
member, which contains the digest's internal block size in bits. It is primarily used by std.digest.hmac.HMAC
.
import std.digest.hmac, std.digest.md; static assert(hasBlockSize!MD5 && MD5.blockSize == 512); static assert(hasBlockSize!(HMAC!MD5) && HMAC!MD5.blockSize == 512);
This is a convenience function to calculate a hash using the template API. Every digest
passing the isDigest
test can be used with this function.
Range range
| an InputRange with ElementType ubyte , ubyte[] or ubyte[num]
|
import std.digest.md; import std.range : repeat; auto testRange = repeat!ubyte(cast(ubyte)'a', 100); auto md5 = digest!MD5(testRange);
This overload of the digest
function handles arrays.
T data
| one or more arrays of any type |
import std.digest.crc, std.digest.md, std.digest.sha; auto md5 = digest!MD5( "The quick brown fox jumps over the lazy dog"); auto sha1 = digest!SHA1( "The quick brown fox jumps over the lazy dog"); auto crc32 = digest!CRC32("The quick brown fox jumps over the lazy dog"); writeln(toHexString(crc32)); // "39A34F41"
import std.digest.crc; auto crc32 = digest!CRC32("The quick ", "brown ", "fox jumps over the lazy dog"); writeln(toHexString(crc32)); // "39A34F41"
This is a convenience function similar to digest
, but it returns the string representation of the hash. Every digest passing the isDigest
test can be used with this function.
order | the order in which the bytes are processed (see toHexString ) |
Range range
| an InputRange with ElementType ubyte , ubyte[] or ubyte[num]
|
import std.digest.md; import std.range : repeat; auto testRange = repeat!ubyte(cast(ubyte)'a', 100); writeln(hexDigest!MD5(testRange)); // "36A92CC94A9E0FA21F625F8BFB007ADF"
This overload of the hexDigest
function handles arrays.
order | the order in which the bytes are processed (see toHexString ) |
T data
| one or more arrays of any type |
import std.digest.crc; // "414FA339" writeln(hexDigest!(CRC32, Order.decreasing)("The quick brown fox jumps over the lazy dog"));
import std.digest.crc; // "414FA339" writeln(hexDigest!(CRC32, Order.decreasing)("The quick ", "brown ", "fox jumps over the lazy dog"));
This is a convenience function which returns an initialized digest, so it's not necessary to call start manually.
import std.digest.md; auto md5 = makeDigest!MD5(); md5.put(0); writeln(toHexString(md5.finish())); // "93B885ADFE0DA089CDF634904FD59F71"
This describes the OOP API. To understand when to use the template API and when to use the OOP API, see the module documentation at the top of this page.
The Digest
interface is the base interface which is implemented by all digests.
Digest
implementation is always an OutputRange
//Using the OutputRange feature import std.algorithm.mutation : copy; import std.digest.md; import std.range : repeat; auto oneMillionRange = repeat!ubyte(cast(ubyte)'a', 1000000); auto ctx = new MD5Digest(); copy(oneMillionRange, ctx); writeln(ctx.finish().toHexString()); // "7707D6AE4E027C70EEA2A935C2296F21"
import std.digest.crc, std.digest.md, std.digest.sha; ubyte[] md5 = (new MD5Digest()).digest("The quick brown fox jumps over the lazy dog"); ubyte[] sha1 = (new SHA1Digest()).digest("The quick brown fox jumps over the lazy dog"); ubyte[] crc32 = (new CRC32Digest()).digest("The quick brown fox jumps over the lazy dog"); writeln(crcHexString(crc32)); // "414FA339"
import std.digest.crc; ubyte[] crc32 = (new CRC32Digest()).digest("The quick ", "brown ", "fox jumps over the lazy dog"); writeln(crcHexString(crc32)); // "414FA339"
void test(Digest dig) { dig.put(cast(ubyte) 0); //single ubyte dig.put(cast(ubyte) 0, cast(ubyte) 0); //variadic ubyte[10] buf; dig.put(buf); //buffer }
Use this to feed the digest with data
. Also implements the std.range.primitives.isOutputRange
interface for ubyte
and const(ubyte)[]
.
void test(Digest dig) { dig.put(cast(ubyte) 0); //single ubyte dig.put(cast(ubyte) 0, cast(ubyte) 0); //variadic ubyte[10] buf; dig.put(buf); //buffer }
Resets the internal state of the digest.
This is the length
in bytes of the hash value which is returned by finish
. It's also the required size of a buffer passed to finish
.
The finish
function returns the hash value. It takes an optional buffer to copy the data into. If a buffer is passed, it must be at least length
bytes big.
This is a convenience function to calculate the hash of a value using the OOP API.
See toHexString
Used to convert a hash value (a static or dynamic array of ubytes) to a string. Can be used with the OOP and with the template API.
The additional order parameter can be used to specify the order of the input data. By default the data is processed in increasing order, starting at index 0. To process it in the opposite order, pass Order.decreasing as a parameter.
The additional letterCase parameter can be used to specify the case of the output data. By default the output is in upper case. To change it to the lower case pass LetterCase.lower as a parameter.
import std.digest.crc; //Test with template API: auto crc32 = digest!CRC32("The quick ", "brown ", "fox jumps over the lazy dog"); //Lower case variant: writeln(toHexString!(LetterCase.lower)(crc32)); // "39a34f41" //Usually CRCs are printed in this order, though: writeln(toHexString!(Order.decreasing)(crc32)); // "414FA339" writeln(toHexString!(LetterCase.lower, Order.decreasing)(crc32)); // "414fa339"
import std.digest.crc; // With OOP API auto crc32 = (new CRC32Digest()).digest("The quick ", "brown ", "fox jumps over the lazy dog"); //Usually CRCs are printed in this order, though: writeln(toHexString!(Order.decreasing)(crc32)); // "414FA339"
Wraps a template API hash struct into a Digest interface. Modules providing digest implementations will usually provide an alias for this template (e.g. MD5Digest, SHA1Digest, ...).
import std.digest.md; //Simple example auto hash = new WrapperDigest!MD5(); hash.put(cast(ubyte) 0); auto result = hash.finish();
//using a supplied buffer import std.digest.md; ubyte[16] buf; auto hash = new WrapperDigest!MD5(); hash.put(cast(ubyte) 0); auto result = hash.finish(buf[]); //The result is now in result (and in buf). If you pass a buffer which is bigger than //necessary, result will have the correct length, but buf will still have it's original //length
Initializes the digest.
Use this to feed the digest with data
. Also implements the std.range.primitives.isOutputRange
interface for ubyte
and const(ubyte)[]
.
Resets the internal state of the digest.
This is the length
in bytes of the hash value which is returned by finish
. It's also the required size of a buffer passed to finish
.
The finish
function returns the hash value. It takes an optional buffer to copy the data into. If a buffer is passed, it must have a length at least length
bytes.
import std.digest.md; ubyte[16] buf; auto hash = new WrapperDigest!MD5(); hash.put(cast(ubyte) 0); auto result = hash.finish(buf[]); //The result is now in result (and in buf). If you pass a buffer which is bigger than //necessary, result will have the correct length, but buf will still have it's original //length
Works like finish
but does not reset the internal state, so it's possible to continue putting data into this WrapperDigest after a call to peek
.
These functions are only available if hasPeek!T
is true
.
Securely compares two digest representations while protecting against timing attacks. Do not use ==
to compare digest representations.
The attack happens as follows:
"0000000000000000000000000000000000000000"
, then "1000000000000000000000000000000000000000"
, and so on.==
string comparison, which returns false
as soon as the first wrong element is found. If a wrong element is found, then a rejection is sent back to the sender.n
) for ranges of the same length. R1 r1
| A digest representation |
R2 r2
| A digest representation |
true
if both representations are equal, false
otherwise import std.digest.hmac : hmac; import std.digest.sha : SHA1; import std.string : representation; // a typical HMAC data integrity verification auto secret = "A7GZIP6TAQA6OHM7KZ42KB9303CEY0MOV5DD6NTV".representation; auto data = "data".representation; string hex1 = data.hmac!SHA1(secret).toHexString; string hex2 = data.hmac!SHA1(secret).toHexString; string hex3 = "data1".representation.hmac!SHA1(secret).toHexString; assert( secureEqual(hex1, hex2)); assert(!secureEqual(hex1, hex3));
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Licensed under the Boost License 1.0.
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