Re: [PATCH v7 00/11] kallsyms: Optimizes the performance of lookup symbols

From: Leizhen (ThunderTown)
Date: Sat Oct 29 2022 - 04:11:05 EST



On 2022/10/27 14:27, Leizhen (ThunderTown) wrote:
>
>
> On 2022/10/27 11:26, Leizhen (ThunderTown) wrote:
>>
>>
>> On 2022/10/27 3:03, Luis Chamberlain wrote:
>>> On Wed, Oct 26, 2022 at 02:44:36PM +0800, Leizhen (ThunderTown) wrote:
>>>> On 2022/10/26 1:53, Luis Chamberlain wrote:
>>>>> This answers how we don't use a hash table, the question was *should* we
>>>>> use one?
>>>>
>>>> I'm not the original author, and I can only answer now based on my understanding. Maybe
>>>> the original author didn't think of the hash method, or he has weighed it out.
>>>>
>>>> Hash is a good solution if only performance is required and memory overhead is not
>>>> considered. Using hash will increase the memory size by up to "4 * kallsyms_num_syms +
>>>> 4 * ARRAY_SIZE(hashtable)" bytes, kallsyms_num_syms is about 1-2 million.
>
> Sorry, 1-2 million ==> 0.1~0.2 million
>
>>>>
>>>> Because I don't know what hash algorithm will be used, the cost of generating the
>>>> hash value corresponding to the symbol name is unknown now. But I think it's gonna
>>>> be small. But it definitely needs a simpler algorithm, the tool needs to implement
>>>> the same hash algorithm.
>>>
>>> For instance, you can look at evaluating if alloc_large_system_hash() would help.
>>

The following three hash algorithms are compared. The kernel is compiled by defconfig
on arm64.

|---------------------------------------------------------------------------------------|
| | hash &= HASH_TABLE_SIZE - 1 |
| | number of conflicts >= 1000 |
|---------------------------------------------------------------------------------------|
| ARRAY_SIZE(hash_table) | crc16 | jhash_one_at_a_time | string hash_32 |
|---------------------------------------------------------------------------------------|
| | 345b: 3905 | 0d40: 1013 | 4a4c: 6548 |
| | 35bb: 1016 | 35ce: 6549 | 883a: 1015 |
| 0x10000 | 385b: 6548 | 4440: 19126 | d05f: 19129 |
| | f0ba: 19127 | 7ebe: 3916 | ecda: 3903 |
|---------------------------------------------------------------------------------------|
| | 0ba: 19168 | 440: 19165 | 05f: 19170 |
| | 45b: 3955 | 5ce: 6577 | 83a: 1066 |
| 0x1000 | 5bb: 1069 | d40: 1052 | a4c: 6609 |
| | 85b: 6582 | ebe: 3938 | cda: 3924 |
|---------------------------------------------------------------------------------------|

Based on the above test results, I conclude that:
1. For the worst-case scenario, the three algorithms are not much different. But the kernel
only implements crc16 and string hash_32. The latter is not processed byte-by-byte, so
it is coupled with byte order and sizeof(long). So crc16 is the best choice.
2. For the worst-case scenario, there are almost 19K strings are mapped to the same hash
value,just over 1/10 of the total. And with my current compression-then-comparison
approach, it's 25-30 times faster. So there's still a need for my current approach, and
they can be combined.
if (nr_conflicts(key) >= CONST_N) {
newname = compress(name);
for_each_name_in_slot(key): compare(new_name)
} else {
for_each_name_in_slot(key): compare(name)
}

Above CONST_N can be roughly calculated:
time_of_compress(name) + N * time_of_compare(new_name) <= N * time_of_compare(name)
3. For the worst-case scenario, there is no obvious difference between ARRAY_SIZE(hash_table)
0x10000 and 0x1000. So ARRAY_SIZE(hash_table)=0x1000 is enough.
Statistic information:
|------------------------------------------------------|
| nr_conflicts(key) | ARRAY_SIZE(hash_table) |
|------------------------------------------------------|
| <= ? | 0x1000 | 0x10000 |
|------------------------------------------------------|
| 0 | 0 | 7821 |
| 20 | 19 | 57375 |
| 40 | 2419 | 124 |
| 60 | 1343 | 70 |
| 80 | 149 | 73 |
| 100 | 38 | 49 |
| 200 | 108 | 16 |
| 400 | 14 | 2 |
| 600 | 2 | 2 |
| 800 | 0 | 0 |
| 1000 | 0 | 0 |
| 100000 | 4 | 4 |
|------------------------------------------------------|


Also, I re-calculated:
Using hash will increase the memory size by up to "6 * kallsyms_num_syms + 4 * ARRAY_SIZE(hashtable)"
|---- What I said earlier was 4
The increased size is close to 1 MB if CONFIG_KALLSYMS_ALL=y.

Hi, Luis:
For the reasons of the above-mentioned second conclusion. And except for patches 4-6,
even if only the hash method is used, other patches and option "--lto-clang" in patch 6/11
are also needed. If you don't mind, I'd like to use hash at the next stage. The current
patch set is already huge.


>> OK, I found the right hash function. In this way, the tool does not need to consider
>> the byte order.
>
> https://en.wikipedia.org/wiki/Jenkins_hash_function
>
> Let's go with jenkins_one_at_a_time_hash(), which looks simpler and doesn't even
> have to think about sizeof(long). It seems to be closest to our current needs.
>
> uint32_t jenkins_one_at_a_time_hash(const uint8_t* key, size_t length) {
> size_t i = 0;
> uint32_t hash = 0;
>
> while (i != length) {
> hash += key[i++];
> hash += hash << 10;
> hash ^= hash >> 6;
> }
> hash += hash << 3;
> hash ^= hash >> 11;
> hash += hash << 15;
>
> return hash;
> }
>
>>
>> include/linux/stringhash.h
>>
>> /*
>> * Version 1: one byte at a time. Example of use:
>> *
>> * unsigned long hash = init_name_hash;
>> * while (*p)
>> * hash = partial_name_hash(tolower(*p++), hash);
>> * hash = end_name_hash(hash);
>>
>>
>>>
>>> Luis
>>> .
>>>
>>
>

--
Regards,
Zhen Lei