Fortran bindings to hashmap.c
Modified to the extreme for Fortran use only.
If you want to C the original github: https://github.com/tidwall/hashmap.c
-
Complete rebuild of the handling of the heap.
-
Original hashing algorithm has been ripped out and replaced with rapid_hash. Todo: put link here.
-
Complete redesign to be highly ergonomic with Fortran.
If you like what I do, and would like to support me: My Patreon
- String key hashmap.
- c_int64_t key hashmap.
- Concurrent string key hashmap.
- Concurrent c_int64_t key hashmap.
With concurrent hashmaps, basically you need to call lock before you do something then unlock it.
In your fpm.toml add:
[dependencies]
hashmap_f90 = { git = "https://github.com/jordan4ibanez/hashmap_f90" }This is a sample of what you can do with it. The tutorials are also included in the /src/ directory, so you can run them.
You can run the example with: make test
module tutorial_1_module
use, intrinsic :: iso_c_binding
implicit none
!* Our cool type. 8)
!* Notice: No GC is required here because we aren't
!* pointing at anything.
type :: cool
integer(c_int) :: i = 0
end type cool
contains
function int_to_string(i) result(output)
implicit none
integer(c_int) :: i
character(len = :, kind = c_char), allocatable :: output
! If the number is any bigger than this, wat.
allocate(character(11) :: output)
write(output, "(i11)") i
! Now we shift the whole thing left and trim it to fit.
output = trim(adjustl(output))
end function int_to_string
logical(c_bool) function iter_func_test(raw_c_ptr) result(early_return)
implicit none
type(c_ptr), intent(in), value :: raw_c_ptr
integer(c_int), pointer :: gotten_data
call c_f_pointer(raw_c_ptr, gotten_data)
print*,"hello from iter func: ", gotten_data
early_return = .false.
end function iter_func_test
end module tutorial_1_module
program tutorial_1
use :: tutorial_1_module
use :: hashmap_str
use, intrinsic :: iso_c_binding
implicit none
type(hashmap_string_key) :: map
integer(c_int), pointer :: gotten_data
type(c_ptr) :: raw_ptr
character(len = :, kind = c_char), pointer :: string_pointer
integer(c_int) :: i
!* Basic usage.
!* Create the hashmap.
map = new_hashmap_string_key(sizeof(10))
!* We shall set 100 values.
do i = 1,100
!* Set a value in the heap of the hashmap.
!* This utilizes memcpy under the hood, so you can utilize
!* the EXTREME performance of stack variables.
!* You can also utilize pointers, if you want, but that will
!* make it more complex for no reason.
!*
!* In tutorial 2 which uses the integer hashmap key type,
!* I'll show you how to GC derived types with Fortran pointers.
call map%set("hi"//int_to_string(i), i)
!* We can get them immediately after they're set.
!* You can see this reads like a Rust if-let statement.
if (map%get("hi"//int_to_string(i), raw_ptr)) then
call c_f_pointer(raw_ptr, gotten_data)
print*,gotten_data
end if
!* This is just to show you it is double checking the hashmap
!* heap to ensure the value is there as I was prototyping it.
if (.not. map%has_key("hi"//int_to_string(i))) then
error stop "FAILED"
end if
end do
!* Let's get how many elements the hashmap has.
print*,map%count()
!* Now let us remove, how about, [hi55]
call map%remove("hi"//int_to_string(55))
!* Now let us enforce this has 99 elements.
if (map%count() /= 99) then
error stop "FAILED"
end if
!* But why stop there?
if (map%has_key("hi"//int_to_string(55))) then
error stop "FAILED"
end if
!* Iteration tutorial:
!? Remember, when you're using a regular iterator (non func)
!? you must initialize the iterator.
!*
!* I had two options with this:
!* 1.) Make you make an integer key and set it to 0 and pass it to the iterator.
!* 2.) Make you call a subroutine to reset it.
!*
!* 1 required more coding and you might still forget to initialize the integer.
!* 2 you just might forget to initialize the function.
!*
!* As you can see, this is a bit easier.
call map%initialize_iterator()
!* Now we can iterate with value only.
do while(map%iterate(raw_ptr))
call c_f_pointer(raw_ptr, gotten_data)
print*,gotten_data
end do
!* You can also iterate through the hashmap by key and value.
!* This uses some pointer magic under the hood so it never allocates.
!* I would not attempt to change the key as that will yield severe UB.
call map%initialize_iterator()
do while (map%iterate_kv(string_pointer, raw_ptr))
call c_f_pointer(raw_ptr, gotten_data)
print*,string_pointer, len(string_pointer), gotten_data
end do
!* This version when you're checking for something.
if (map%iterate_with_func(iter_func_test)) then
! This means that we've broken out of the iteration early.
! If you return true when changing the iterator func, you can make this print "got ya".
print*,"got ya!"
end if
!* This version when you don't feel like initializing an iterator.
!* Or if you have a different design in mind.
call map%iterate_with_func_discard(iter_func_test)
!* Now you have two options:
!* 1.) If you want to keep reusing the map but want to empty it:
!* This calls the GC.
call map%clear()
!* 2.) You're done with the map and want to free all the memory.
!* This calls the GC.
call map%destroy()
!* Just don't call that twice.
!* Uncomment this to see what happens. :P
! call map%destroy()
!* Tutorial 2 shows you more things.
end program tutorial_1module tutorial_2_module
use, intrinsic :: iso_c_binding
implicit none
!* Our pointy type. =>
!* Notice: This one requires a GC.
!* But, if you like memory leaks, don't bother with it lol.
type :: pointy
integer(c_int), pointer :: i => null()
character(:, c_char), pointer :: text => null()
end type pointy
contains
function int_to_string(i) result(output)
implicit none
integer(c_int) :: i
character(len = :, kind = c_char), allocatable :: output
! If the number is any bigger than this, wat.
allocate(character(11) :: output)
write(output, "(i11)") i
! Now we shift the whole thing left and trim it to fit.
output = trim(adjustl(output))
end function int_to_string
subroutine my_cool_gc(c_raw_ptr)
implicit none
type(c_ptr), intent(in), value :: c_raw_ptr
type(pointy), pointer :: gc_data
call c_f_pointer(c_raw_ptr, gc_data)
deallocate(gc_data%i)
deallocate(gc_data%text)
end subroutine my_cool_gc
end module tutorial_2_module
program tutorial_2
use :: tutorial_2_module
use :: hashmap_int
use, intrinsic :: iso_c_binding
implicit none
type(hashmap_integer_key) :: map
type(pointy) :: stack_data
integer(c_int) :: i
type(c_ptr) :: c_raw_data
type(pointy), pointer :: pointer_data
!* Integer keys (c_int64_t) are for when you want to FLY.
!* I designed them to be as fast as I could get it.
!* Initialize it, with a GC this time.
map = new_hashmap_integer_key(sizeof(stack_data), my_cool_gc)
!* Putting 10,000 elements into the hashmap.
do i = 1,10000
!* We're going to be pointing all over the place now.
allocate(stack_data%i)
allocate(character(len = 20, kind = c_char) :: stack_data%text)
stack_data%i = i
stack_data%text = "I am text: "//int_to_string(i)
call map%set(int(i, c_int64_t), stack_data)
end do
!* Then we print it out.
call map%initialize_iterator()
do while(map%iterate(c_raw_data))
call c_f_pointer(c_raw_data, pointer_data)
print*,pointer_data%i, pointer_data%text
end do
!* Now we're done, we can free the underlying C memory.
call map%destroy()
end program tutorial_2