lbm.py


1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137

import pyopencl as cl
mf = cl.mem_flags

import numpy
import sympy

from mako.template import Template
from pathlib import Path

class Geometry:
    def __init__(self, size_x, size_y, size_z = 1):
        self.size_x = size_x
        self.size_y = size_y
        self.size_z = size_z
        self.volume = size_x * size_y * size_z

    def inner_cells(self):
        if self.size_z == 1:
            for y in range(1,self.size_y-1):
                for x in range(1,self.size_x-1):
                    yield x, y
        else:
            for z in range(1,self.size_z-1):
                for y in range(1,self.size_y-1):
                    for x in range(1,self.size_x-1):
                        yield x, y, z

    def span(self):
        if self.size_z == 1:
            return (self.size_x, self.size_y)
        else:
            return (self.size_x, self.size_y, self.size_z)

    def inner_span(self):
        if self.size_z == 1:
            return (self.size_x-2, self.size_y-2)
        else:
            return (self.size_x-2, self.size_y-2, self.size_z-2)


class Lattice:
    def __init__(self, descriptor, geometry, moments, collide, pop_eq_src = '', boundary_src = ''):
        self.descriptor = descriptor
        self.geometry   = geometry

        self.moments = moments
        self.collide = collide

        self.pop_eq_src = pop_eq_src
        self.boundary_src = boundary_src

        self.platform = cl.get_platforms()[0]
        self.context  = cl.Context(properties=[(cl.context_properties.PLATFORM, self.platform)])
        self.queue = cl.CommandQueue(self.context)

        self.np_material = numpy.ndarray(shape=(self.geometry.volume, 1), dtype=numpy.int32)

        self.tick = True

        self.pop_size     = descriptor.q     * self.geometry.volume * numpy.float32(0).nbytes
        self.moments_size = (descriptor.d+1) * self.geometry.volume * numpy.float32(0).nbytes

        self.cl_pop_a = cl.Buffer(self.context, mf.READ_WRITE, size=self.pop_size)
        self.cl_pop_b = cl.Buffer(self.context, mf.READ_WRITE, size=self.pop_size)

        self.cl_moments  = cl.Buffer(self.context, mf.WRITE_ONLY, size=self.moments_size)
        self.cl_material = cl.Buffer(self.context, mf.READ_ONLY | mf.USE_HOST_PTR, hostbuf=self.np_material)

        self.build_kernel()

        if descriptor.d == 2:
            self.layout = (32,1)
        elif descriptor.d == 3:
            self.layout = (32,1,1)

        self.program.equilibrilize(
            self.queue, self.geometry.span(), self.layout, self.cl_pop_a, self.cl_pop_b).wait()

    def idx(self, x, y, z = 0):
        return z * (self.geometry.size_x*self.geometry.size_y) + y * self.geometry.size_x + x;

    def setup_geometry(self, material_at):
        if self.descriptor.d == 2:
            for x, y in self.geometry.inner_cells():
                self.np_material[self.idx(x,y)] = material_at(self.geometry, x, y)
        elif self.descriptor.d == 3:
            for x, y, z in self.geometry.inner_cells():
                self.np_material[self.idx(x,y,z)] = material_at(self.geometry, x, y, z)

        cl.enqueue_copy(self.queue, self.cl_material, self.np_material).wait();

    def build_kernel(self):
        program_src = Template(filename = str(Path(__file__).parent/'template/kernel.mako')).render(
            descriptor = self.descriptor,
            geometry   = self.geometry,

            moments_subexpr    = self.moments[0],
            moments_assignment = self.moments[1],
            collide_subexpr    = self.collide[0],
            collide_assignment = self.collide[1],

            pop_eq_src = Template(self.pop_eq_src).render(
                descriptor = self.descriptor,
                geometry   = self.geometry
            ),
            boundary_src = Template(self.boundary_src).render(
                descriptor = self.descriptor,
                geometry   = self.geometry
            ),

            ccode = sympy.ccode
        )
        self.program = cl.Program(self.context, program_src).build('-cl-single-precision-constant -cl-fast-relaxed-math')

    def evolve(self):
        if self.tick:
            self.tick = False
            self.program.collide_and_stream(
                self.queue, self.geometry.span(), self.layout, self.cl_pop_a, self.cl_pop_b, self.cl_material)
        else:
            self.tick = True
            self.program.collide_and_stream(
                self.queue, self.geometry.span(), self.layout, self.cl_pop_b, self.cl_pop_a, self.cl_material)

    def sync(self):
        self.queue.finish()

    def get_moments(self):
        moments = numpy.ndarray(shape=(self.descriptor.d+1, self.geometry.volume), dtype=numpy.float32)
        if self.tick:
            self.program.collect_moments(
                self.queue, self.geometry.span(), self.layout, self.cl_pop_b, self.cl_moments)
        else:
            self.program.collect_moments(
                self.queue, self.geometry.span(), self.layout, self.cl_pop_a, self.cl_moments)
        cl.enqueue_copy(self.queue, moments, self.cl_moments).wait();
        return moments