I was reading the following post on another forum from a guy who seems to know a lot about C++ internals regarding inserting thousands of keys in to "dictionaries":
e) Map and Set look-up is done with Red-Black or Balanced Tree's and each item is allocated "individually", so if you're allocating 500,000 Instruments [by symbol] with a pointer to an instrument Object-class associated, you have 'N' number of bytes [plus overhead] for the string and 4-bytes [plus overhead] for the pointer. And include; one-minute, five-second, one-second price time-series on all instruments and full trade-history on ALL those Instruments in STD Containers. That's a lot of memory and a hell of a lot More Wasted due to small object Allocation overhead!
f) Notoriously, STD Map & Set walk thru all of the keys to FIND using LowerBound [Less Than Compare] which is slow as hell.
g) Some Genius may say "No, they use an Unsorted Map"...well they don't, but even if they did they are STILL doing a String Compare on a discretely allocated element.
What I do in C++ is the following (example);
a) Create a "custom" in-place String Class-object, which has two personalities; a) a Byte array, and b) an Integer array [of Modulus 4 and Aligned on the Native Boundary]. b) Use Custom Map & Set, which are Hash based in 2x Dimensions with Nodes allocated in a Flat Contiguous Memory region [which may & can dynamically re-size]. c) String [in Integer format] Hashing is done by Integer to pipeline the CPU and Key Comparison is done similarly.
With these techniques, which can only be done in C++, C or ASM there are at least 4-5x ORDERS OF MAGNITUDE the performance of the same thing done in .NET, C# or Java.
If I know roughly how many keys I will be inserting, what techniques are there which I could use to design my own unordered_map implementation which is more efficient than the standard one for my particular usage?
(any 101s about designing hash functions are most welcome)