I general, I am aware multiple data types in single array typically not allowed in strongly typed language like Java.
I would like to know why technically multiple data type in single array is not possible in terms of data structure (storing in memory location).
Will different datatype hold different bit?. Due to this indexing element will be an problem for multiple data type array?
All strongly typed languages are produce virtual address space at compile time. Strongly typed languages like C , Java compiler should know the data time so that it will will create address space. Its all compiler dependent. All assignments, whether explicit or via parameter passing in method calls, are checked for type compatibility. There are no automatic corrections or conversions of conflicting types as in some languages.
Thanks,
Ram
Very good question.
Array generally means you can access any element by index into the array in constant time i.e. O(1).
In C/C++, if you create array of 200, 32-bit integers they are all stored in
consecutive memory locations.
So if you want to access 10th element you can compute memory address of 10th element as
base address of the array + 4 * 9 . Then read 32 bytes at that address as your 10th integer. This is what a[9] does.
Suppose you allow storage of elements of different types in an array, you won't be able to do this address jumping because different types of items will have different sizes and you won't know what to multiply with.
This breaks the promise that items can be found in O(1).
That is why we don't put items of different types in an array even though its possible. Its definitely possible to do.
I'm trying to answer two questions in a definitive list:
What are the underlying data structures used for Redis?
And what are the main advantages/disadvantages/use cases for each type?
So, I've read the Redis lists are actually implemented with linked lists. But for other types, I'm not able to dig up any information. Also, if someone were to stumble upon this question and not have a high level summary of the pros and cons of modifying or accessing different data structures, they'd have a complete list of when to best use specific types to reference as well.
Specifically, I'm looking to outline all types: string, list, set, zset and hash.
Oh, I've looked at these article, among others, so far:
http://redis.io/topics/data-types
http://redis.io/topics/data-types-intro
http://redis.io/topics/faq
I'll try to answer your question, but I'll start with something that may look strange at first: if you are not interested in Redis internals you should not care about how data types are implemented internally. This is for a simple reason: for every Redis operation you'll find the time complexity in the documentation and, if you have the set of operations and the time complexity, the only other thing you need is some clue about memory usage (and because we do many optimizations that may vary depending on data, the best way to get these latter figures are doing a few trivial real world tests).
But since you asked, here is the underlying implementation of every Redis data type.
Strings are implemented using a C dynamic string library so that we don't pay (asymptotically speaking) for allocations in append operations. This way we have O(N) appends, for instance, instead of having quadratic behavior.
Lists are implemented with linked lists.
Sets and Hashes are implemented with hash tables.
Sorted sets are implemented with skip lists (a peculiar type of balanced trees).
But when lists, sets, and sorted sets are small in number of items and size of the largest values, a different, much more compact encoding is used. This encoding differs for different types, but has the feature that it is a compact blob of data that often forces an O(N) scan for every operation. Since we use this format only for small objects this is not an issue; scanning a small O(N) blob is cache oblivious so practically speaking it is very fast, and when there are too many elements the encoding is automatically switched to the native encoding (linked list, hash, and so forth).
But your question was not really just about internals, your point was What type to use to accomplish what?.
Strings
This is the base type of all the types. It's one of the four types but is also the base type of the complex types, because a List is a list of strings, a Set is a set of strings, and so forth.
A Redis string is a good idea in all the obvious scenarios where you want to store an HTML page, but also when you want to avoid converting your already encoded data. So for instance, if you have JSON or MessagePack you may just store objects as strings. In Redis 2.6 you can even manipulate this kind of object server side using Lua scripts.
Another interesting usage of strings is bitmaps, and in general random access arrays of bytes, since Redis exports commands to access random ranges of bytes, or even single bits. For instance check this good blog post: Fast Easy real time metrics using Redis.
Lists
Lists are good when you are likely to touch only the extremes of the list: near tail, or near head. Lists are not very good to paginate stuff, because random access is slow, O(N).
So good uses of lists are plain queues and stacks, or processing items in a loop using RPOPLPUSH with same source and destination to "rotate" a ring of items.
Lists are also good when we want just to create a capped collection of N items where usually we access just the top or bottom items, or when N is small.
Sets
Sets are an unordered data collection, so they are good every time you have a collection of items and it is very important to check for existence or size of the collection in a very fast way. Another cool thing about sets is support for peeking or popping random elements (SRANDMEMBER and SPOP commands).
Sets are also good to represent relations, e.g., "What are friends of user X?" and so forth. But other good data structures for this kind of stuff are sorted sets as we'll see.
Sets support complex operations like intersections, unions, and so forth, so this is a good data structure for using Redis in a "computational" manner, when you have data and you want to perform transformations on that data to obtain some output.
Small sets are encoded in a very efficient way.
Hashes
Hashes are the perfect data structure to represent objects, composed of fields and values. Fields of hashes can also be atomically incremented using HINCRBY. When you have objects such as users, blog posts, or some other kind of item, hashes are likely the way to go if you don't want to use your own encoding like JSON or similar.
However, keep in mind that small hashes are encoded very efficiently by Redis, and you can ask Redis to atomically GET, SET or increment individual fields in a very fast fashion.
Hashes can also be used to represent linked data structures, using references. For instance check the lamernews.com implementation of comments.
Sorted Sets
Sorted sets are the only other data structures, besides lists, to maintain ordered elements. You can do a number of cool stuff with sorted sets. For instance, you can have all kinds of Top Something lists in your web application. Top users by score, top posts by pageviews, top whatever, but a single Redis instance will support tons of insertion and get-top-elements operations per second.
Sorted sets, like regular sets, can be used to describe relations, but they also allow you to paginate the list of items and to remember the ordering. For instance, if I remember friends of user X with a sorted set I can easily remember them in order of accepted friendship.
Sorted sets are good for priority queues.
Sorted sets are like more powerful lists where inserting, removing, or getting ranges from the the middle of the list is always fast. But they use more memory, and are O(log(N)) data structures.
Conclusion
I hope that I provided some info in this post, but it is far better to download the source code of lamernews from http://github.com/antirez/lamernews and understand how it works. Many data structures from Redis are used inside Lamer News, and there are many clues about what to use to solve a given task.
Sorry for grammar typos, it's midnight here and too tired to review the post ;)
Most of the time, you don't need to understand the underlying data structures used by Redis. But a bit of knowledge helps you make CPU v/s Memory trade offs. It also helps you model your data in an efficient manner.
Internally, Redis uses the following data structures :
String
Dictionary
Doubly Linked List
Skip List
Zip List
Int Sets
Zip Maps (deprecated in favour of zip list since Redis 2.6)
To find the encoding used by a particular key, use the command object encoding <key>.
1. Strings
In Redis, Strings are called Simple Dynamic Strings, or SDS. It's a smallish wrapper over a char * that allows you to store the length of the string and number of free bytes as a prefix.
Because the length of the string is stored, strlen is an O(1) operation. Also, because the length is known, Redis strings are binary safe. It is perfectly legal for a string to contain the null character.
Strings are the most versatile data structure available in Redis. A String is all of the following:
A string of characters that can store text. See SET and GET commands.
A byte array that can store binary data.
A long that can store numbers. See INCR, DECR, INCRBY and DECRBY commands.
An Array (of chars, ints, longs or any other data type) that can allow efficient random access. See SETRANGE and GETRANGE commands.
A bit array that allows you to set or get individual bits. See SETBIT and GETBIT commands.
A block of memory that you can use to build other data structures. This is used internally to build ziplists and intsets, which are compact, memory-efficient data structures for small number of elements. More on this below.
2. Dictionary
Redis uses a Dictionary for the following:
To map a key to its associated value, where value can be a string, hash, set, sorted set or list.
To map a key to its expiry timestamp.
To implement Hash, Set and Sorted Set data types.
To map Redis commands to the functions that handle those commands.
To map a Redis key to a list of clients that are blocked on that key. See BLPOP.
Redis Dictionaries are implemented using Hash Tables. Instead of explaining the implementation, I will just explain the Redis specific things :
Dictionaries use a structure called dictType to extend the behaviour of a hash table. This structure has function pointers, and so the following operations are extendable: a) hash function, b) key comparison, c) key destructor, and d) value destructor.
Dictionaries use the murmurhash2. (Previously they used the djb2 hash function, with seed=5381, but then the hash function was switched to murmur2. See this question for an explanation of the djb2 hash algorithm.)
Redis uses Incremental Hashing, also known as Incremental Resizing. The dictionary has two hash tables. Every time the dictionary is touched, one bucket is migrated from the first (smaller) hash table to the second. This way, Redis prevents an expensive resize operation.
The Set data structure uses a Dictionary to guarantee there are no duplicates. The Sorted Set uses a dictionary to map an element to its score, which is why ZSCORE is an O(1) operation.
3. Doubly Linked Lists
The list data type is implemented using Doubly Linked Lists. Redis' implementation is straight-from-the-algorithm-textbook. The only change is that Redis stores the length in the list data structure. This ensures that LLEN has O(1) complexity.
4. Skip Lists
Redis uses Skip Lists as the underlying data structure for Sorted Sets. Wikipedia has a good introduction. William Pugh's paper Skip Lists: A Probabilistic Alternative to Balanced Trees has more details.
Sorted Sets use both a Skip List and a Dictionary. The dictionary stores the score of each element.
Redis' Skip List implementation is different from the standard implementation in the following ways:
Redis allows duplicate scores. If two nodes have the same score, they are sorted by the lexicographical order.
Each node has a back pointer at level 0. This allows you to traverse elements in reverse order of the score.
5. Zip List
A Zip List is like a doubly linked list, except it does not use pointers and stores the data inline.
Each node in a doubly linked list has at 3 pointers - one forward pointer, one backward pointer and one pointer to reference the data stored at that node. Pointers require memory (8 bytes on a 64 bit system), and so for small lists, a doubly linked list is very inefficient.
A Zip List stores elements sequentially in a Redis String. Each element has a small header that stores the length and data type of the element, the offset to the next element and the offset to the previous element. These offsets replace the forward and backward pointers. Since the data is stored inline, we don't need a data pointer.
The Zip list is used to store small lists, sorted sets and hashes. Sorted sets are flattened into a list like [element1, score1, element2, score2, element3, score3] and stored in the Zip List. Hashes are flattened into a list like [key1, value1, key2, value2] etc.
With Zip Lists you have the power to make a tradeoff between CPU and Memory. Zip Lists are memory-efficient, but they use more CPU than a linked list (or Hash table/Skip List). Finding an element in the zip list is O(n). Inserting a new element requires reallocating memory. Because of this, Redis uses this encoding only for small lists, hashes and sorted sets. You can tweak this behaviour by altering the values of <datatype>-max-ziplist-entries and <datatype>-max-ziplist-value> in redis.conf. See Redis Memory Optimization, section "Special encoding of small aggregate data types" for more information.
The comments on ziplist.c are excellent, and you can understand this data structure completely without having to read the code.
6. Int Sets
Int Sets are a fancy name for "Sorted Integer Arrays".
In Redis, sets are usually implemented using hash tables. For small sets, a hash table is inefficient memory wise. When the set is composed of integers only, an array is often more efficient.
An Int Set is a sorted array of integers. To find an element a binary search algorithm is used. This has a complexity of O(log N). Adding new integers to this array may require a memory reallocation, which can become expensive for large integer arrays.
As a further memory optimization, Int Sets come in 3 variants with different integer sizes: 16 bits, 32 bits and 64 bits. Redis is smart enough to use the right variant depending on the size of the elements. When a new element is added and it exceeds the current size, Redis automatically migrates it to the next size. If a string is added, Redis automatically converts the Int Set to a regular Hash Table based set.
Int Sets are a tradeoff between CPU and Memory. Int Sets are extremely memory efficient, and for small sets they are faster than a hash table. But after a certain number of elements, the O(log N) retrieval time and the cost of reallocating memory become too much. Based on experiments, the optimal threshold to switch over to a regular hash table was found to be 512. However, you can increase this threshold (decreasing it doesn't make sense) based on your application's needs. See set-max-intset-entries in redis.conf.
7. Zip Maps
Zip Maps are dictionaries flattened and stored in a list. They are very similar to Zip Lists.
Zip Maps have been deprecated since Redis 2.6, and small hashes are stored in Zip Lists. To learn more about this encoding, refer to the comments in zipmap.c.
Redis stores keys pointing to values. Keys can be any binary value up to a reasonable size (using short ASCII strings is recommended for readability and debugging purposes). Values are one of five native Redis data types.
1.strings — a sequence of binary safe bytes up to 512 MB
2.hashes — a collection of key value pairs
3.lists — an in-insertion-order collection of strings
4.sets — a collection of unique strings with no ordering
5.sorted sets — a collection of unique strings ordered by user defined scoring
Strings
A Redis string is a sequence of bytes.
Strings in Redis are binary safe (meaning they have a known length not determined by any special terminating characters), so you can store anything up to 512 megabytes in one string.
Strings are the cannonical "key value store" concept. You have a key pointing to a value, where both key and value are text or binary strings.
For all possible operations on strings, see the
http://redis.io/commands/#string
Hashes
A Redis hash is a collection of key value pairs.
A Redis hash holds many key value pairs, where each key and value is a string. Redis hashes do not support complex values directly (meaning, you can't have a hash field have a value of a list or set or another hash), but you can use hash fields to point to other top level complex values. The only special operation you can perform on hash field values is atomic increment/decrement of numeric contents.
You can think of a Redis hashes in two ways: as a direct object representation and as a way to store many small values compactly.
Direct object representations are simple to understand. Objects have a name (the key of the hash) and a collection of internal keys with values. See the example below for, well, an example.
Storing many small values using a hash is a clever Redis massive data storage technique. When a hash has a small number of fields (~100), Redis optimizes the storage and access efficency of the entire hash. Redis's small hash storage optimization raises an interesting behavior: it's more efficient to have 100 hashes each with 100 internal keys and values rather than having 10,000 top level keys pointing to string values. Using Redis hashes to optimize your data storage this way does require additional programming overhead for tracking where data ends up, but if your data storage is primarly string based, you can save a lot of memory overhead using this one weird trick.
For all possible operations on hashes, see the hash docs
Lists
Redis lists act like linked lists.
You can insert to, delete from, and traverse lists from either the head or tail of a list.
Use lists when you need to maintain values in the order they were inserted. (Redis does give you the option to insert into any arbitrary list position if you need to, but your insertion performance will degrade if you insert far from your start position.)
Redis lists are often used as producer/consumer queues. Insert items into a list then pop items from the list. What happens if your consumers try to pop from a list with no elements? You can ask Redis to wait for an element to appear and return it to you immediately when it gets added. This turns Redis into a real time message queue/event/job/task/notification system.
You can atomically remove elements off either end of a list, enabling any list to be treated as a stack or a queue.
You can also maintain fixed-length lists (capped collections) by trimming your list to a specific size after every insertion.
For all possible operations on lists, see the lists docs
Sets
Redis sets are, well, sets.
A Redis set contains unique unordered Redis strings where each string only exists once per set. If you add the same element ten times to a set, it will only show up once. Sets are great for lazily ensuring something exists at least once without worrying about duplicate elements accumulating and wasting space. You can add the same string as many times as you like without needing to check if it already exists.
Sets are fast for membership checking, insertion, and deletion of members in the set.
Sets have efficient set operations, as you would expect. You can take the union, intersection, and difference of multiple sets at once. Results can either be returned to the caller or results can be stored in a new set for later usage.
Sets have constant time access for membership checks (unlike lists), and Redis even has convenient random member removal and returning ("pop a random element from the set") or random member returning without replacement ("give me 30 random-ish unique users") or with replacement ("give me 7 cards, but after each selection, put the card back so it can potentially be sampled again").
For all possible operations on sets, see the sets docs.
Sorted Sets
Redis sorted sets are sets with a user-defined ordering.
For simplicity, you can think of a sorted set as a binary tree with unique elements. (Redis sorted sets are actually skip lists.) The sort order of elements is defined by each element's score.
Sorted sets are still sets. Elements may only appear once in a set. An element, for uniqueness purposes, is defined by its string contents. Inserting element "apple" with sorting score 3, then inserting element "apple" with sorting score 500 results in one element "apple" with sorting score 500 in your sorted set. Sets are only unique based on Data, not based on (Score, Data) pairs.
Make sure your data model relies on the string contents and not the element's score for uniqueness. Scores are allowed to be repeated (or even zero), but, one last time, set elements can only exist once per sorted set. For example, if you try to store the history of every user login as a sorted set by making the score the epoch of the login and the value the user id, you will end up storing only the last login epoch for all your users. Your set would grow to size of your userbase and not your desired size of userbase * logins.
Elements are added to your set with scores. You can update the score of any element at any time, just add the element again with a new score. Scores are represented by floating point doubles, so you can specify granularity of high precision timestamps if needed. Multiple elements may have the same score.
You can retrieve elements in a few different ways. Since everything is sorted, you can ask for elements starting at the lowest scores. You can ask for elements starting at the highest scores ("in reverse"). You can ask for elements by their sort score either in natural or reverse order.
For all possible operations on sorted sets, see the sorted sets docs.
Given two files containing list of words(around million), We need to find out the words that are in common.
Use Some efficient algorithm, also not enough memory availble(1 million, certainly not).. Some basic C Programming code, if possible, would help.
The files are not sorted.. We can use some sort of algorithm... Please support it with basic code...
Sorting the external file...... with minimum memory available,, how can it be implement with C programming.
Anybody game for external sorting of a file... Please share some code for this.
Yet another approach.
General. first, notice that doing this sequentially takes O(N^2). With N=1,000,000, this is a LOT. Sorting each list would take O(N*log(N)); then you can find the intersection in one pass by merging the files (see below). So the total is O(2N*log(N) + 2N) = O(N*log(N)).
Sorting a file. Now let's address the fact that working with files is much slower than with memory, especially when sorting where you need to move things around. One way to solve this is - decide the size of the chunk that can be loaded into memory. Load the file one chunk at a time, sort it efficiently and save into a separate temporary file. The sorted chunks can be merged (again, see below) into one sorted file in one pass.
Merging. When you have 2 sorted lists (files or not), you can merge them into one sorted list easily in one pass: have 2 "pointers", initially pointing to the first entry in each list. In each step, compare the values the pointers point to. Move the smaller value to the merged list (the one you are constructing) and advance its pointer.
You can modify the merge algorithm easily to make it find the intersection - if pointed values are equal move it to the results (consider how do you want to deal with duplicates).
For merging more than 2 lists (as in sorting the file above) you can generalize the algorithm for using k pointers.
If you had enough memory to read the first file completely into RAM, I would suggest reading it into a dictionary (word -> index of that word ), loop over the words of the second file and test if the word is contained in that dictionary. Memory for a million words is not much today.
If you have not enough memory, split the first file into chunks that fit into memory and do as I said above for each of that chunk. For example, fill the dictionary with the first 100.000 words, find every common word for that, then read the file a second time extracting word 100.001 up to 200.000, find the common words for that part, and so on.
And now the hard part: you need a dictionary structure, and you said "basic C". When you are willing to use "basic C++", there is the hash_map data structure provided as an extension to the standard library by common compiler vendors. In basic C, you should also try to use a ready-made library for that, read this SO post to find a link to a free library which seems to support that.
Your problem is: Given two sets of items, find the intersaction (items common to both), while staying within the constraints of inadequate RAM (less than the size of any set).
Since finding an intersaction requires comparing/searching each item in another set, you must have enough RAM to store at least one of the sets (the smaller one) to have an efficient algorithm.
Assume that you know for a fact that the intersaction is much smaller than both sets and fits completely inside available memory -- otherwise you'll have to do further work in flushing the results to disk.
If you are working under memory constraints, partition the larger set into parts that fit inside 1/3 of the available memory. Then partition the smaller set into parts the fit the second 1/3. The remaining 1/3 memory is used to store the results.
Optimize by finding the max and min of the partition for the larger set. This is the set that you are comparing from. Then when loading the corresponding partition of the smaller set, skip all items outside the min-max range.
First find the intersaction of both partitions through a double-loop, storing common items to the results set and removing them from the original sets to save on comparisons further down the loop.
Then replace the partition in the smaller set with the second partition (skipping items outside the min-max). Repeat. Notice that the partition in the larger set is reduced -- with common items already removed.
After running through the entire smaller set, repeat with the next partition of the larger set.
Now, if you do not need to preserve the two original sets (e.g. you can overwrite both files), then you can further optimize by removing common items from disk as well. This way, those items no longer need to be compared in further partitions. You then partition the sets by skipping over removed ones.
I would give prefix trees (aka tries) a shot.
My initial approach would be to determine a maximum depth for the trie that would fit nicely within my RAM limits. Pick an arbitrary depth (say 3, you can tweak it later) and construct a trie up to that depth, for the smaller file. Each leaf would be a list of "file pointers" to words that start with the prefix encoded by the path you followed to reach the leaf. These "file pointers" would keep an offset into the file and the word length.
Then process the second file by reading each word from it and trying to find it in the first file using the trie you constructed. It would allow you to fail faster on words that don't match. The deeper your trie, the faster you can fail, but the more memory you would consume.
Of course, like Stephen Chung said, you still need RAM to store enough information to describe at least one of the files, if you really need an efficient algorithm. If you don't have enough memory -- and you probably don't, because I estimate my approach would require approximately the same amount of memory you would need to load a file whose words were 14-22 characters long -- then you have to process even the first file by parts. In that case, I would actually recommend using the trie for the larger file, not the smaller. Just partition it in parts that are no bigger than the smaller file (or no bigger than your RAM constraints allow, really) and do the whole process I described for each part.
Despite the length, this is sort of off the top of my head. I might be horribly wrong in some details, but this is how I would initially approach the problem and then see where it would take me.
If you're looking for memory efficiency with this sort of thing you'll be hard pushed to get time efficiency. My example will be written in python, but should be relatively easy to implement in any language.
with open(file1) as file_1:
current_word_1 = read_to_delim(file_1, delim)
while current_word_1:
with open(file2) as file_2:
current_word_2 = read_to_delim(file_2, delim)
while current_word_2:
if current_word_2 == current_word_1:
print current_word_2
current_word_2 = read_to_delim(file_2, delim)
current_word_1 = read_to_delim(file_1, delim)
I leave read_to_delim to you, but this is the extreme case that is memory-optimal but time-least-optimal.
depending on your application of course you could load the two files in a database, perform a left outer join, and discard the rows for which one of the two columns is null
I would like to quickly retrieve the median value from a boost multi_index container with an ordered_unique index, however the index iterators aren't random access (I don't understand why they can't be, though this is consistent with std::set...).
Is there a faster/neater way to do this other than incrementing an iterator container.size() / 2 times?
Boost.MultiIndex provide random access indexes, but these index don't take care directly of any order. You can however sort these index, using the sort member function, after inserting a new element, so you will be able to get the median efficiently.
It seems you should make a request to Boost.MultiIndex so the insertion can be done using an order directly, as this should be much more efficient.
I ran into the same problem in a different context. It seems that the STL and Boost don't provide an ordered container that has random access to make use of the ordering (e.g. for comparing).
My (not so pretty) solution was to use a Class that performed the input and "filtered" it in a set. After the input operation was finished it just copied all iterators of the set to a vector and used this for random access.
This solution only works in a very limited context: You perform input on the container once. If you change add to the container again all iterators would have to be copied again. It really was very clumsy to use but worked.