asinghvi17 · April 14, 2024 14:18
diff --git a/proj_trans_generic.jl b/proj_trans_generic.jl
 using Proj, BenchmarkTools
 import GeometryOps as GO

 # using proj_trans_generic on a vector of tuples - or could be GB.Point or SVector or GI.Point with arbitrary metadata, doesn't matter!

 points = tuple.(rand(10000), rand(10000))

 t = Proj.Transformation("+proj=longlat", "+proj=natearth"; always_xy = true)
 function batch_project_numsfirst!(points, projection)
    # GC.@preserve points begin # not technically necessary
        ptr = pointer(points) # we use `pointer` and not `Ref` here because we need to do pointer arithmetic.
        x_ptr = ptr
        y_ptr = ptr + sizeof(Float64) # see above, we do pointer arithmetic here to offset y by 1 Float64

        stride = sizeof(first(points)) # it's assumed this is equal for all points
        n_points = length(points)      # regular C pointer-as-array semantics
        z_ptr, z_stride, z_num = if GI.is3d(first(points)) # only populate Z if 3D.
            ptr + 2*sizeof(Float64), stride, length(points)
        else
            typeof(ptr)(C_NULL), 0, 0
        end


        @ccall Proj.libproj.proj_trans_generic(
            projection.pj::Ptr{Cvoid},              # P
            projection.direction::Proj.PJ_DIRECTION,# direction
            x_ptr::Ptr{Cdouble},                    # x
            stride::Csize_t,                        # sx
            n_points::Csize_t,                      # nx
            y_ptr::Ptr{Cdouble},                    # y
            stride::Csize_t,                        # sy
            n_points::Csize_t,                      # ny
            z_ptr::Ptr{Cdouble},                    # z
            z_stride::Csize_t,                      # sz
            z_num::Csize_t,                         # nz
            C_NULL::Ptr{Cdouble},                   # t - we ignore it here, but could potentially include
            0::Csize_t,                             # st
            0::Csize_t,                             # nt
        )::Csize_t

    # end
    return points
 end

 batch_project_numsfirst!(tuple.(rand(10000), rand(10000)), t)

 @benchmark batch_project_numsfirst!(dt, $t) setup=(dt=tuple.(rand(10000), rand(10000))) evals=1

 @benchmark GO.reproject(points, t)
	using Proj, BenchmarkTools
	import GeometryOps as GO

	# using proj_trans_generic on a vector of tuples - or could be GB.Point or SVector or GI.Point with arbitrary metadata, doesn't matter!

	points = tuple.(rand(10000), rand(10000))

	t = Proj.Transformation("+proj=longlat", "+proj=natearth"; always_xy = true)
	function batch_project_numsfirst!(points, projection)
	# GC.@preserve points begin # not technically necessary
	ptr = pointer(points) # we use `pointer` and not `Ref` here because we need to do pointer arithmetic.
	x_ptr = ptr
	y_ptr = ptr + sizeof(Float64) # see above, we do pointer arithmetic here to offset y by 1 Float64

	stride = sizeof(first(points)) # it's assumed this is equal for all points
	n_points = length(points) # regular C pointer-as-array semantics
	z_ptr, z_stride, z_num = if GI.is3d(first(points)) # only populate Z if 3D.
	ptr + 2*sizeof(Float64), stride, length(points)
	else
	typeof(ptr)(C_NULL), 0, 0
	end


	@ccall Proj.libproj.proj_trans_generic(
	projection.pj::Ptr{Cvoid}, # P
	projection.direction::Proj.PJ_DIRECTION,# direction
	x_ptr::Ptr{Cdouble}, # x
	stride::Csize_t, # sx
	n_points::Csize_t, # nx
	y_ptr::Ptr{Cdouble}, # y
	stride::Csize_t, # sy
	n_points::Csize_t, # ny
	z_ptr::Ptr{Cdouble}, # z
	z_stride::Csize_t, # sz
	z_num::Csize_t, # nz
	C_NULL::Ptr{Cdouble}, # t - we ignore it here, but could potentially include
	0::Csize_t, # st
	0::Csize_t, # nt
	)::Csize_t

	# end
	return points
	end

	batch_project_numsfirst!(tuple.(rand(10000), rand(10000)), t)

	@benchmark batch_project_numsfirst!(dt, $t) setup=(dt=tuple.(rand(10000), rand(10000))) evals=1

	@benchmark GO.reproject(points, t)