[linux-2.6-block.git] / Documentation / crc32.txt

A brief CRC tutorial.

A CRC is a long-division remainder.  You add the CRC to the message,
and the whole thing (message+CRC) is a multiple of the given
CRC polynomial.  To check the CRC, you can either check that the
CRC matches the recomputed value, *or* you can check that the
remainder computed on the message+CRC is 0.  This latter approach
is used by a lot of hardware implementations, and is why so many
protocols put the end-of-frame flag after the CRC.

It's actually the same long division you learned in school, except that
- We're working in binary, so the digits are only 0 and 1, and
- When dividing polynomials, there are no carries.  Rather than add and
  subtract, we just xor.  Thus, we tend to get a bit sloppy about
  the difference between adding and subtracting.

Like all division, the remainder is always smaller than the divisor.
To produce a 32-bit CRC, the divisor is actually a 33-bit CRC polynomial.
Since it's 33 bits long, bit 32 is always going to be set, so usually the
CRC is written in hex with the most significant bit omitted.  (If you're
familiar with the IEEE 754 floating-point format, it's the same idea.)

Note that a CRC is computed over a string of *bits*, so you have
to decide on the endianness of the bits within each byte.  To get
the best error-detecting properties, this should correspond to the
order they're actually sent.  For example, standard RS-232 serial is
little-endian; the most significant bit (sometimes used for parity)
is sent last.  And when appending a CRC word to a message, you should
do it in the right order, matching the endianness.

Just like with ordinary division, you proceed one digit (bit) at a time.
Each step of the division you take one more digit (bit) of the dividend
and append it to the current remainder.  Then you figure out the
appropriate multiple of the divisor to subtract to being the remainder
back into range.  In binary, this is easy - it has to be either 0 or 1,
and to make the XOR cancel, it's just a copy of bit 32 of the remainder.

When computing a CRC, we don't care about the quotient, so we can
throw the quotient bit away, but subtract the appropriate multiple of
the polynomial from the remainder and we're back to where we started,
ready to process the next bit.

A big-endian CRC written this way would be coded like:
for (i = 0; i < input_bits; i++) {
	multiple = remainder & 0x80000000 ? CRCPOLY : 0;
	remainder = (remainder << 1 | next_input_bit()) ^ multiple;
}

Notice how, to get at bit 32 of the shifted remainder, we look
at bit 31 of the remainder *before* shifting it.

But also notice how the next_input_bit() bits we're shifting into
the remainder don't actually affect any decision-making until
32 bits later.  Thus, the first 32 cycles of this are pretty boring.
Also, to add the CRC to a message, we need a 32-bit-long hole for it at
the end, so we have to add 32 extra cycles shifting in zeros at the
end of every message,

These details lead to a standard trick: rearrange merging in the
next_input_bit() until the moment it's needed.  Then the first 32 cycles
can be precomputed, and merging in the final 32 zero bits to make room
for the CRC can be skipped entirely.  This changes the code to:

for (i = 0; i < input_bits; i++) {
	remainder ^= next_input_bit() << 31;
	multiple = (remainder & 0x80000000) ? CRCPOLY : 0;
	remainder = (remainder << 1) ^ multiple;
}

With this optimization, the little-endian code is particularly simple:
for (i = 0; i < input_bits; i++) {
	remainder ^= next_input_bit();
	multiple = (remainder & 1) ? CRCPOLY : 0;
	remainder = (remainder >> 1) ^ multiple;
}

The most significant coefficient of the remainder polynomial is stored
in the least significant bit of the binary "remainder" variable.
The other details of endianness have been hidden in CRCPOLY (which must
be bit-reversed) and next_input_bit().

As long as next_input_bit is returning the bits in a sensible order, we don't
*have* to wait until the last possible moment to merge in additional bits.
We can do it 8 bits at a time rather than 1 bit at a time:
for (i = 0; i < input_bytes; i++) {
	remainder ^= next_input_byte() << 24;
	for (j = 0; j < 8; j++) {
		multiple = (remainder & 0x80000000) ? CRCPOLY : 0;
		remainder = (remainder << 1) ^ multiple;
	}
}

Or in little-endian:
for (i = 0; i < input_bytes; i++) {
	remainder ^= next_input_byte();
	for (j = 0; j < 8; j++) {
		multiple = (remainder & 1) ? CRCPOLY : 0;
		remainder = (remainder >> 1) ^ multiple;
	}
}

If the input is a multiple of 32 bits, you can even XOR in a 32-bit
word at a time and increase the inner loop count to 32.

You can also mix and match the two loop styles, for example doing the
bulk of a message byte-at-a-time and adding bit-at-a-time processing
for any fractional bytes at the end.

To reduce the number of conditional branches, software commonly uses
the byte-at-a-time table method, popularized by Dilip V. Sarwate,
"Computation of Cyclic Redundancy Checks via Table Look-Up", Comm. ACM
v.31 no.8 (August 1998) p. 1008-1013.

Here, rather than just shifting one bit of the remainder to decide
in the correct multiple to subtract, we can shift a byte at a time.
This produces a 40-bit (rather than a 33-bit) intermediate remainder,
and the correct multiple of the polynomial to subtract is found using
a 256-entry lookup table indexed by the high 8 bits.

(The table entries are simply the CRC-32 of the given one-byte messages.)

When space is more constrained, smaller tables can be used, e.g. two
4-bit shifts followed by a lookup in a 16-entry table.

It is not practical to process much more than 8 bits at a time using this
technique, because tables larger than 256 entries use too much memory and,
more importantly, too much of the L1 cache.

To get higher software performance, a "slicing" technique can be used.
See "High Octane CRC Generation with the Intel Slicing-by-8 Algorithm",
ftp://download.intel.com/technology/comms/perfnet/download/slicing-by-8.pdf

This does not change the number of table lookups, but does increase
the parallelism.  With the classic Sarwate algorithm, each table lookup
must be completed before the index of the next can be computed.

A "slicing by 2" technique would shift the remainder 16 bits at a time,
producing a 48-bit intermediate remainder.  Rather than doing a single
lookup in a 65536-entry table, the two high bytes are looked up in
two different 256-entry tables.  Each contains the remainder required
to cancel out the corresponding byte.  The tables are different because the
polynomials to cancel are different.  One has non-zero coefficients from
x^32 to x^39, while the other goes from x^40 to x^47.

Since modern processors can handle many parallel memory operations, this
takes barely longer than a single table look-up and thus performs almost
twice as fast as the basic Sarwate algorithm.

This can be extended to "slicing by 4" using 4 256-entry tables.
Each step, 32 bits of data is fetched, XORed with the CRC, and the result
broken into bytes and looked up in the tables.  Because the 32-bit shift
leaves the low-order bits of the intermediate remainder zero, the
final CRC is simply the XOR of the 4 table look-ups.

But this still enforces sequential execution: a second group of table
look-ups cannot begin until the previous groups 4 table look-ups have all
been completed.  Thus, the processor's load/store unit is sometimes idle.

To make maximum use of the processor, "slicing by 8" performs 8 look-ups
in parallel.  Each step, the 32-bit CRC is shifted 64 bits and XORed
with 64 bits of input data.  What is important to note is that 4 of
those 8 bytes are simply copies of the input data; they do not depend
on the previous CRC at all.  Thus, those 4 table look-ups may commence
immediately, without waiting for the previous loop iteration.

By always having 4 loads in flight, a modern superscalar processor can
be kept busy and make full use of its L1 cache.

Two more details about CRC implementation in the real world:

Normally, appending zero bits to a message which is already a multiple
of a polynomial produces a larger multiple of that polynomial.  Thus,
a basic CRC will not detect appended zero bits (or bytes).  To enable
a CRC to detect this condition, it's common to invert the CRC before
appending it.  This makes the remainder of the message+crc come out not
as zero, but some fixed non-zero value.  (The CRC of the inversion
pattern, 0xffffffff.)

The same problem applies to zero bits prepended to the message, and a
similar solution is used.  Instead of starting the CRC computation with
a remainder of 0, an initial remainder of all ones is used.  As long as
you start the same way on decoding, it doesn't make a difference.
Commit	Line	Data
fbedceb1 BP	1	A brief CRC tutorial.
	2
	3	A CRC is a long-division remainder. You add the CRC to the message,
	4	and the whole thing (message+CRC) is a multiple of the given
	5	CRC polynomial. To check the CRC, you can either check that the
	6	CRC matches the recomputed value, or you can check that the
	7	remainder computed on the message+CRC is 0. This latter approach
	8	is used by a lot of hardware implementations, and is why so many
	9	protocols put the end-of-frame flag after the CRC.
	10
	11	It's actually the same long division you learned in school, except that
	12	- We're working in binary, so the digits are only 0 and 1, and
	13	- When dividing polynomials, there are no carries. Rather than add and
	14	subtract, we just xor. Thus, we tend to get a bit sloppy about
	15	the difference between adding and subtracting.
	16
	17	Like all division, the remainder is always smaller than the divisor.
	18	To produce a 32-bit CRC, the divisor is actually a 33-bit CRC polynomial.
	19	Since it's 33 bits long, bit 32 is always going to be set, so usually the
	20	CRC is written in hex with the most significant bit omitted. (If you're
	21	familiar with the IEEE 754 floating-point format, it's the same idea.)
	22
	23	Note that a CRC is computed over a string of bits, so you have
	24	to decide on the endianness of the bits within each byte. To get
	25	the best error-detecting properties, this should correspond to the
	26	order they're actually sent. For example, standard RS-232 serial is
	27	little-endian; the most significant bit (sometimes used for parity)
	28	is sent last. And when appending a CRC word to a message, you should
	29	do it in the right order, matching the endianness.
	30
	31	Just like with ordinary division, you proceed one digit (bit) at a time.
	32	Each step of the division you take one more digit (bit) of the dividend
	33	and append it to the current remainder. Then you figure out the
	34	appropriate multiple of the divisor to subtract to being the remainder
	35	back into range. In binary, this is easy - it has to be either 0 or 1,
	36	and to make the XOR cancel, it's just a copy of bit 32 of the remainder.
	37
	38	When computing a CRC, we don't care about the quotient, so we can
	39	throw the quotient bit away, but subtract the appropriate multiple of
	40	the polynomial from the remainder and we're back to where we started,
	41	ready to process the next bit.
	42
	43	A big-endian CRC written this way would be coded like:
	44	for (i = 0; i < input_bits; i++) {
	45	multiple = remainder & 0x80000000 ? CRCPOLY : 0;
	46	remainder = (remainder << 1 \| next_input_bit()) ^ multiple;
	47	}
	48
	49	Notice how, to get at bit 32 of the shifted remainder, we look
	50	at bit 31 of the remainder before shifting it.
	51
	52	But also notice how the next_input_bit() bits we're shifting into
	53	the remainder don't actually affect any decision-making until
	54	32 bits later. Thus, the first 32 cycles of this are pretty boring.
	55	Also, to add the CRC to a message, we need a 32-bit-long hole for it at
	56	the end, so we have to add 32 extra cycles shifting in zeros at the
	57	end of every message,
	58
	59	These details lead to a standard trick: rearrange merging in the
	60	next_input_bit() until the moment it's needed. Then the first 32 cycles
	61	can be precomputed, and merging in the final 32 zero bits to make room
	62	for the CRC can be skipped entirely. This changes the code to:
	63
	64	for (i = 0; i < input_bits; i++) {
65	remainder ^= next_input_bit() << 31;
66	multiple = (remainder & 0x80000000) ? CRCPOLY : 0;
67	remainder = (remainder << 1) ^ multiple;
68	}
69
70	With this optimization, the little-endian code is particularly simple:
71	for (i = 0; i < input_bits; i++) {
72	remainder ^= next_input_bit();
73	multiple = (remainder & 1) ? CRCPOLY : 0;
74	remainder = (remainder >> 1) ^ multiple;
75	}
76
77	The most significant coefficient of the remainder polynomial is stored
78	in the least significant bit of the binary "remainder" variable.
79	The other details of endianness have been hidden in CRCPOLY (which must
80	be bit-reversed) and next_input_bit().
81
82	As long as next_input_bit is returning the bits in a sensible order, we don't
83	have to wait until the last possible moment to merge in additional bits.
84	We can do it 8 bits at a time rather than 1 bit at a time:
85	for (i = 0; i < input_bytes; i++) {
86	remainder ^= next_input_byte() << 24;
87	for (j = 0; j < 8; j++) {
88	multiple = (remainder & 0x80000000) ? CRCPOLY : 0;
89	remainder = (remainder << 1) ^ multiple;
90	}
91	}
92
93	Or in little-endian:
94	for (i = 0; i < input_bytes; i++) {
95	remainder ^= next_input_byte();
96	for (j = 0; j < 8; j++) {
97	multiple = (remainder & 1) ? CRCPOLY : 0;
98	remainder = (remainder >> 1) ^ multiple;
99	}
100	}
101
102	If the input is a multiple of 32 bits, you can even XOR in a 32-bit
103	word at a time and increase the inner loop count to 32.
104
105	You can also mix and match the two loop styles, for example doing the
106	bulk of a message byte-at-a-time and adding bit-at-a-time processing
107	for any fractional bytes at the end.
108
109	To reduce the number of conditional branches, software commonly uses
110	the byte-at-a-time table method, popularized by Dilip V. Sarwate,
111	"Computation of Cyclic Redundancy Checks via Table Look-Up", Comm. ACM
112	v.31 no.8 (August 1998) p. 1008-1013.
113
114	Here, rather than just shifting one bit of the remainder to decide
115	in the correct multiple to subtract, we can shift a byte at a time.
116	This produces a 40-bit (rather than a 33-bit) intermediate remainder,
117	and the correct multiple of the polynomial to subtract is found using
118	a 256-entry lookup table indexed by the high 8 bits.
119
120	(The table entries are simply the CRC-32 of the given one-byte messages.)
121
122	When space is more constrained, smaller tables can be used, e.g. two
123	4-bit shifts followed by a lookup in a 16-entry table.
124
125	It is not practical to process much more than 8 bits at a time using this
126	technique, because tables larger than 256 entries use too much memory and,
127	more importantly, too much of the L1 cache.
128
129	To get higher software performance, a "slicing" technique can be used.
130	See "High Octane CRC Generation with the Intel Slicing-by-8 Algorithm",
131	ftp://download.intel.com/technology/comms/perfnet/download/slicing-by-8.pdf
132
133	This does not change the number of table lookups, but does increase
134	the parallelism. With the classic Sarwate algorithm, each table lookup
135	must be completed before the index of the next can be computed.
136
137	A "slicing by 2" technique would shift the remainder 16 bits at a time,
138	producing a 48-bit intermediate remainder. Rather than doing a single
139	lookup in a 65536-entry table, the two high bytes are looked up in
140	two different 256-entry tables. Each contains the remainder required
141	to cancel out the corresponding byte. The tables are different because the
142	polynomials to cancel are different. One has non-zero coefficients from
143	x^32 to x^39, while the other goes from x^40 to x^47.
144
145	Since modern processors can handle many parallel memory operations, this
146	takes barely longer than a single table look-up and thus performs almost
147	twice as fast as the basic Sarwate algorithm.
148
149	This can be extended to "slicing by 4" using 4 256-entry tables.
150	Each step, 32 bits of data is fetched, XORed with the CRC, and the result
151	broken into bytes and looked up in the tables. Because the 32-bit shift
152	leaves the low-order bits of the intermediate remainder zero, the
153	final CRC is simply the XOR of the 4 table look-ups.
154
155	But this still enforces sequential execution: a second group of table
156	look-ups cannot begin until the previous groups 4 table look-ups have all
157	been completed. Thus, the processor's load/store unit is sometimes idle.
158
159	To make maximum use of the processor, "slicing by 8" performs 8 look-ups
160	in parallel. Each step, the 32-bit CRC is shifted 64 bits and XORed
161	with 64 bits of input data. What is important to note is that 4 of
162	those 8 bytes are simply copies of the input data; they do not depend
163	on the previous CRC at all. Thus, those 4 table look-ups may commence
164	immediately, without waiting for the previous loop iteration.
165
166	By always having 4 loads in flight, a modern superscalar processor can
167	be kept busy and make full use of its L1 cache.
168
169	Two more details about CRC implementation in the real world:
170
171	Normally, appending zero bits to a message which is already a multiple
172	of a polynomial produces a larger multiple of that polynomial. Thus,
173	a basic CRC will not detect appended zero bits (or bytes). To enable
174	a CRC to detect this condition, it's common to invert the CRC before
175	appending it. This makes the remainder of the message+crc come out not
176	as zero, but some fixed non-zero value. (The CRC of the inversion
177	pattern, 0xffffffff.)
178
179	The same problem applies to zero bits prepended to the message, and a
180	similar solution is used. Instead of starting the CRC computation with
181	a remainder of 0, an initial remainder of all ones is used. As long as
182	you start the same way on decoding, it doesn't make a difference.