Short answer: For a single byte delimiter,
explode’s time complexeity is in Ο(N); but for multiple byte delimiters, its time complexity is Ο(N2).
implode is clearly in Ο(N) as it simply glues the pieces together.
Extended answer: The basic algorithm of
explode is to search for occurrences of delimiter in string and copy the enclosed substrings into a new array.
To find the positions of delimiter in string, it uses the internal function
php_memnstr is just an alias for
zebd_memnstr). For a single byte, it simply calls
memchr that does a linear search (thus in Ο(N)).
But for delimiter values longer than one byte, it calls
memchr to search for positions of the first byte of delimiter in string, tests if the last byte of delimiter is present at the expected position in string, and calls
memcmp to also check the bytes in between. So it basically checks whether delimiter is contained in string for any possible position. This already sounds suspiciously like Ο(N2).
Now let’s have a look at the worst case for this algorithm where both the first and the last byte of the pattern fit but the second-last doesn’t, e.g.:
X represents a mismatch in
? unknown bytes. The value in parentheses is the time complexity in uniform measure. This would sum up to
Σ (2+i) for i from M-floor(N/2) to ceil(N/2)
(N-M+1)·2 + Σ i - Σ j for i from 1 to ceil(N/2), j from 1 to M-floor(N/2)-1.
Since Σ i for i from 1 to N can be expressed by N·(N+1)/2 = (N2+N)/2, we can also write:
(N-M+1)·2 + (ceil(N/2)2+ceil(N/2))/2 - ((M-floor(N/2)-1)2+(M-floor(N/2)-1))/2
For simplicity, let’s assume both N and M are always even, so we can omit the ‘ceil’s and ‘floor’s:
(N-M+1)·2 + ((N/2+1)2+N/2+1)/2 - ((M-N/2-1)2+(M-N/2)-1)/2
= (N-M+1)·2 + N2/8+3·N/4+1 - ((M-N/2-1)2+(M-N/2)-1)/2
Furthermore, we can estimate the values up: N-M < N and M-N/2-1 < N. Thus we get:
N·2 + N2/8+3·N/4+1 - (N2+N)/2
< N·2 + N2+4·N - N2+N
This proofs that
explode with multiple byte delimiters is in Ο(N2).