A final checkin before restarting the project

2025-02-05 11:40:04 -05:00 · 2011-04-28 10:47:42 -04:00 · 2011-04-28 10:47:42 -04:00 · 04351d6582
commit 04351d6582
parent 97180003a4
3 changed files with 103 additions and 208 deletions
--- a/cuburn/device_code.py
+++ b/cuburn/device_code.py
@ -18,6 +18,9 @@ class IterThread(object):
        self.mwc = MWCRNG(entry)
        self.cp = util.DataStream(entry)
        self.vars = Variations(features)
        self.camera = CameraTransform(features)
        self.hist = HistScatter(entry, features)
        self.shuf = ShufflePoints(entry)
        entry.add_param('u32', 'num_cps')
        entry.add_ptr_param('u32', 'cp_started_count')
@ -35,7 +38,7 @@ class IterThread(object):
        # If this number is negative, we're still fusing points, so this
        # behaves slightly differently (see ``fuse_loop_start``)
        # TODO: replace (or at least simplify) this logic
-        e.declare_mem('shared', 'f32', 'num_samples')
+        e.declare_mem('shared', 'u32', 'num_samples')
        # The per-warp transform selection indices
        e.declare_mem('shared', 'f32', 'xf_sel', e.nwarps_cta)
@ -66,7 +69,7 @@ class IterThread(object):
        e.comment("Check to see if this CP is valid (if not, we're done)")
        all_cps_done = e.forward_label()
-        with cp_idx < p.num_cps:
+        with cp_idx < p.num_cps.val:
            o.bra.uni(all_cps_done)
        self.cp.addr = p.cp_data[cp_idx * self.cp.stream_size]
@ -99,11 +102,11 @@ class IterThread(object):
        e.comment("Determine write location, and whether point is valid")
        e.declare_label(xforms_done)
-        histidx, is_valid = self.camera.get_index(r.x, r.y)
+        histidx, is_valid = self.camera.get_index(e, self.cp, r.x, r.y)
        is_valid &= (r.consec_bad >= 0)
        e.comment("Scatter point to pointbuffer")
-        self.hist.scatter(histidx, r.color, 0, is_valid)
+        self.hist.scatter(self.cp, histidx, r.color, 0, is_valid)
        done_picking_new_point = e.forward_label()
        with ~is_valid:
@ -119,15 +122,14 @@ class IterThread(object):
        e.declare_label(done_picking_new_point)
        e.comment("Determine number of good samples, and whether we're done")
-        num_samples = o.ld(m.num_samples)
+        num_samples = o.ld(m.num_samples.addr)
        num_samples += o.bar.red.popc(0, is_valid)
        with s.tid_x == 0:
            o.st(m.num_samples, num_samples)
-        with num_samples >= self.cp.get('nsamples'):
+        with num_samples >= self.cp.get.u32('nsamples'):
            o.bra.uni(cp_loop_start)
-        comment('Shuffle points between threads')
+        self.shuf.shuffle(e, r.x, r.y, r.color, r.consec_bad)
        shuf.shuffle(x, y, color, consec_bad)
        with s.tid_x < e.nwarps_cta:
            o.bra(choose_xform)
@ -180,123 +182,75 @@ class IterThread(object):
        print "CPs started:", cps_started
 class CameraTransform(object):
-    shortname = 'camera'
+    def __init__(self, features):
-    def deps(self):
+        self.features = features
        return [CPDataStream]
-    def rotate(self, rotated_x, rotated_y, x, y):
+    def rotate(self, cp, x, y):
        """
        Rotate an IFS-space coordinate as defined by the camera.
        """
-        if features.camera_rotation:
+        if not self.features.camera_rotation:
-            assert rotated_x.name != x.name and rotated_y.name != y.name
+            return x, y
-            with block("Rotate %s, %s to camera alignment" % (x, y)):
+        rot_center_x, rot_center_y = cp.get.v2.f32('cp.rot_center[0]',
-                reg.f32('rot_center_x rot_center_y')
+                                                   'cp.rot_center[1]')
-                cp.get_v2(cpA, rot_center_x, 'cp.rot_center[0]',
+        tx, ty = x - rot_center_x, y - rot_center_y
-                                      rot_center_y, 'cp.rot_center[1]')
+        rot_cos_t, rot_sin_t = cp.get.v2.f32('cos(cp.rotate * 2 * pi / 360.)',
-                op.sub.f32(x, x, rot_center_x)
+                                            '-sin(cp.rotate * 2 * pi / 360.)')
-                op.sub.f32(y, y, rot_center_y)
+        rx = tx * rot_cos_t    + ty * rot_sin_t + rot_center_x
        ry = tx * (-rot_sin_t) + ty * rot_cos_t + rot_center_y
        return rx, ry
-                reg.f32('rot_sin_t rot_cos_t rot_old_x rot_old_y')
+    def get_norm(self, cp, x, y):
                cp.get_v2(cpA, rot_cos_t,  'cos(cp.rotate * 2 * pi / 360.)',
                               rot_sin_t, '-sin(cp.rotate * 2 * pi / 360.)')
                comment('rotated_x = x * cos(t) - y * sin(t) + rot_center_x')
                op.fma.rn.f32(rotated_x, x, rot_cos_t, rot_center_x)
                op.fma.rn.f32(rotated_x, y, rot_sin_t, rotated_x)
                op.neg.f32(rot_sin_t, rot_sin_t)
                comment('rotated_y = x * sin(t) + y * cos(t) + rot_center_y')
                op.fma.rn.f32(rotated_y, x, rot_sin_t, rot_center_y)
                op.fma.rn.f32(rotated_y, y, rot_cos_t, rotated_y)
                # TODO: if this is a register-critical section, reloading
                # rot_center_[xy] here should save two regs. OTOH, if this is
                # *not* reg-crit, moving the subtraction above to new variables
                # may save a few clocks
                op.add.f32(x, x, rot_center_x)
                op.add.f32(y, y, rot_center_y)
        else:
            comment("No camera rotation in this kernel")
            op.mov.f32(rotated_x, x)
            op.mov.f32(rotated_y, y)
    def get_norm(self, norm_x, norm_y, x, y):
        """
        Find the [0,1]-normalized floating-point histogram coordinates
        ``norm_x, norm_y`` from the given IFS-space coordinates ``x, y``.
        """
-        self.rotate(norm_x, norm_y, x, y)
+        rx, ry = self.rotate(cp, x, y)
-        with block("Scale rotated points to [0,1]-normalized coordinates"):
+        cam_scale, cam_offset = cp.get.v2.f32(
-            reg.f32('cam_scale cam_offset')
+                'cp.camera.norm_scale[0]', 'cp.camera.norm_offset[0]')
-            cp.get_v2(cpA, cam_scale,  'cp.camera.norm_scale[0]',
+        norm_x = rx * cam_scale + cam_offset
-                           cam_offset, 'cp.camera.norm_offset[0]')
+        cam_scale, cam_offset = cp.get.v2.f32(
-            op.fma.f32(norm_x, norm_x, cam_scale, cam_offset)
+                'cp.camera.norm_scale[1]', 'cp.camera.norm_offset[1]')
-            cp.get_v2(cpA, cam_scale,  'cp.camera.norm_scale[1]',
+        norm_y = ry * cam_scale + cam_offset
-                           cam_offset, 'cp.camera.norm_offset[1]')
+        return norm_x, norm_y
            op.fma.f32(norm_y, norm_y, cam_scale, cam_offset)
-    def get_index(self, index, x, y, pred=None):
+    def get_index(self, entry, cp, x, y):
        """
        Find the histogram index (as a u32) from the IFS spatial coordinate in
-        ``x, y``.
+        ``x, y``. Returns ``index, oob``, where ``oob`` is a predicate value
-
+        that is set if the result is out of bounds.
        If the coordinates are out of bounds, 0xffffffff will be stored to
        ``index``. If ``pred`` is given, it will be set if the point is valid,
        and cleared if not.
        """
-        # A few instructions could probably be shaved off of this one
+        o = entry.ops
-        with block("Find histogram index"):
+        rx, ry = self.rotate(cp, x, y)
-            reg.f32('norm_x norm_y')
+        cam_scale, cam_offset = cp.get.v2.f32(
-            self.rotate(norm_x, norm_y, x, y)
+                'cp.camera.idx_scale[0]', 'cp.camera.idx_offset[0]')
-            comment('Scale and offset from IFS to index coordinates')
+        idx_x = rx * cam_scale + cam_offset
-            reg.f32('cam_scale cam_offset')
+        cam_scale, cam_offset = cp.get.v2.f32(
-            cp.get_v2(cpA, cam_scale,  'cp.camera.idx_scale[0]',
+                'cp.camera.idx_scale[1]', 'cp.camera.idx_offset[1]')
-                           cam_offset, 'cp.camera.idx_offset[0]')
+        idx_y = ry * cam_scale + cam_offset
            op.fma.rn.f32(norm_x, norm_x, cam_scale, cam_offset)
-            cp.get_v2(cpA, cam_scale,  'cp.camera.idx_scale[1]',
+        idx_x_u32 = o.cvt.rzi.s32(idx_x)
-                           cam_offset, 'cp.camera.idx_offset[1]')
+        idx_y_u32 = o.cvt.rzi.s32(idx_y)
-            op.fma.rn.f32(norm_y, norm_y, cam_scale, cam_offset)
+        oob = o.setp.lt.u32(idx_x_u32, self.features.hist_width)
        oob |= o.setp.lt.u32(idx_y_u32, self.features.hist_height)
-            comment('Check for bad value')
+        idx = idx_y_u32 * self.features.hist_stride + idx_x_u32
-            reg.u32('index_x index_y')
+        return idx, oob
            if not pred:
                pred = reg.pred('p_valid')
            op.cvt.rzi.s32.f32(index_x, norm_x)
            op.setp.ge.s32(pred, index_x, 0)
            op.setp.lt.and_.s32(pred, index_x, features.hist_width, pred)
            op.cvt.rzi.s32.f32(index_y, norm_y)
            op.setp.ge.and_.s32(pred, index_y, 0, pred)
            op.setp.lt.and_.s32(pred, index_y, features.hist_height, pred)
            op.mad.lo.u32(index, index_y, features.hist_stride, index_x)
            op.mov.u32(index, 0xffffffff, ifnotp=pred)
 class PaletteLookup(object):
-    shortname = "palette"
+    def __init__(self, entry, features):
-    # Resolution of texture on device. Bigger = more palette rez, maybe slower
+        self.entry, self.features = entry, features
-    texheight = 16
+        #entry.declare_mem('global', 'texref', 'palette')
-    def __init__(self):
+    def look_up(self, color, norm_time):
        self.texref = None
    def deps(self):
        return [CPDataStream]
    def module_setup(self):
        mem.global_.texref('t_palette')
    def look_up(self, r, g, b, a, color, norm_time, ifp):
        """
        Look up the values of ``r, g, b, a`` corresponding to ``color_coord``
        at the CP indexed in ``timestamp_idx``. Note that both ``color_coord``
        and ``timestamp_idx`` should be [0,1]-normalized floats.
        """
-        op.tex._2d.v4.f32.f32(vec(r, g, b, a),
+        n = self.entry.ops.mov.f32
-                addr([t_palette, ', ',  vec(norm_time, color)]), ifp=ifp)
+        return n(1), n(1), n(1), n(1)
        #o.tex._2d.v4.f32.f32(m.palette, norm_time, color)
        if features.non_box_temporal_filter:
            raise NotImplementedError("Non-box temporal filters not supported")
@ -333,112 +287,52 @@ class PaletteLookup(object):
        assert self.texref, "Must upload palette texture before launch!"
 class HistScatter(object):
-    shortname = "hist"
+    def __init__(self, entry, features):
-    def deps(self):
+        self.entry, self.features = entry, features
-        return [CPDataStream, CameraTransform, PaletteLookup]
+        self.palette = PaletteLookup(entry, features)
        entry.add_ptr_param('f32', 'hist_bins')
-    def module_setup(self):
+    def scatter(self, cp, hist_index, color, xf_idx, p_valid):
        mem.global_.f32('g_hist_bins',
                        features.hist_height * features.hist_stride * 4)
        comment("Target to ensure fake local values get written")
        mem.global_.f32('g_hist_dummy')
    def entry_setup(self):
        comment("Fake bins for fake scatter")
        mem.local.f32('l_scatter_fake_adr')
        mem.local.f32('l_scatter_fake_alpha')
    def entry_teardown(self):
        with block("Store fake histogram bins to dummy global"):
            reg.b32('hist_dummy')
            op.ld.local.b32(hist_dummy, addr(l_scatter_fake_adr))
            op.st.volatile.b32(addr(g_hist_dummy), hist_dummy)
            op.ld.local.b32(hist_dummy, addr(l_scatter_fake_alpha))
            op.st.volatile.b32(addr(g_hist_dummy), hist_dummy)
    def scatter(self, hist_index, color, xf_idx, p_valid, type='ldst'):
        """
-        Scatter the given point directly to the histogram bins. I think this
+        Scatter the given point directly to the histogram bins.
        technique has the worst performance of all of 'em. Accesses ``cpA``
        directly.
        """
-        with block("Scatter directly to buffer"):
+        e, r, o, m, p, s = self.entry.locals
-            reg.u32('hist_bin_addr')
+        norm_time = cp.get.f32('cp.norm_time')
-            op.mov.u32(hist_bin_addr, g_hist_bins)
+        base = p.hist_bins[4*hist_index]
-            op.mad.lo.u32(hist_bin_addr, hist_index, 16, hist_bin_addr)
+        colors = self.palette.look_up(color, norm_time)
-
+        g_colors = o.ld.v4(base)
-            if type == 'fake_notex':
+        for col, gcol in zip(colors, g_colors):
-                op.st.local.u32(addr(l_scatter_fake_adr), hist_bin_addr)
+            gcol += col
-                op.st.local.f32(addr(l_scatter_fake_alpha), color)
+        o.st.v4(base, *g_colors)
                return
            reg.f32('r g b a norm_time')
            cp.get(cpA, norm_time, 'cp.norm_time')
            palette.look_up(r, g, b, a, color, norm_time, ifp=p_valid)
            # TODO: look up, scale by xform visibility
            # TODO: Make this more performant
            if type == 'ldst':
                reg.f32('gr gg gb ga')
                op.ld.v4.f32(vec(gr, gg, gb, ga), addr(hist_bin_addr),
                             ifp=p_valid)
                op.add.f32(gr, gr, r)
                op.add.f32(gg, gg, g)
                op.add.f32(gb, gb, b)
                op.add.f32(ga, ga, a)
                op.st.v4.f32(addr(hist_bin_addr), vec(gr, gg, gb, ga),
                             ifp=p_valid)
            elif type == 'red':
                for i, val in enumerate([r, g, b, a]):
                    op.red.add.f32(addr(hist_bin_addr,4*i), val, ifp=p_valid)
            elif type == 'fake':
                op.st.local.u32(addr(l_scatter_fake_adr), hist_bin_addr)
                op.st.local.f32(addr(l_scatter_fake_alpha), a)
    def call_setup(self, ctx):
        hist_bins_dp, hist_bins_l = ctx.mod.get_global('g_hist_bins')
        cuda.memset_d32(hist_bins_dp, 0, hist_bins_l/4)
    def get_bins(self, ctx, features):
        hist_bins_dp, hist_bins_l = ctx.mod.get_global('g_hist_bins')
        return cuda.from_device(hist_bins_dp,
                (features.hist_height, features.hist_stride, 4),
                dtype=np.float32)
 class ShufflePoints(object):
    """
    Shuffle points in shared memory. See helpers/shuf.py for details.
    """
-    shortname = "shuf"
+    def __init__(self, entry):
        entry.declare_mem('shared', 'b32', 'shuf_data', entry.nthreads_cta)
-    def module_setup(self):
+    def shuffle(self, entry, *args, **kwargs):
        # TODO: if needed, merge this shared memory block with others
        mem.shared.f32('s_shuf_data', ctx.threads_per_cta)
    def shuffle(self, *args, **kwargs):
        """
        Shuffle the data from each register in args across threads. Keyword
-        argument ``bar`` specifies which barrier to use (default is 2).
+        argument ``bar`` specifies which barrier to use (default is 0). Each
        register is overwritten in place.
        """
-        bar = kwargs.pop('bar', 2)
+        e, r, o, m, p, s = entry.locals
-        with block("Shuffle across threads"):
+        bar = kwargs.pop('bar', 0)
-            reg.u32('shuf_read shuf_write')
+        assert not kwargs, "Unrecognized keyword arguments."
            with block("Calculate read and write offsets"):
                reg.u32('shuf_off shuf_laneid')
                op.mov.u32(shuf_off, '%tid.x')
                op.mov.u32(shuf_write, s_shuf_data)
                op.mad.lo.u32(shuf_write, shuf_off, 4, shuf_write)
                op.mov.u32(shuf_laneid, '%laneid')
                op.mad.lo.u32(shuf_off, shuf_laneid, 32, shuf_off)
                op.and_.b32(shuf_off, shuf_off, ctx.threads_per_cta - 1)
                op.mov.u32(shuf_read, s_shuf_data)
                op.mad.lo.u32(shuf_read, shuf_off, 4, shuf_read)
            for var in args:
                op.bar.sync(bar)
                op.st.volatile.shared.b32(addr(shuf_write), var)
                op.bar.sync(bar)
                op.ld.volatile.shared.b32(var, addr(shuf_read))
        e.comment("Calculate read and write offsets for shuffle")
        # See helpers/shuf.py for details
        shuf_write = m.shuf_data[s.tid_x]
        shuf_read = m.shuf_data[(s.tid_x + (32 * s.laneid)) &
                                (e.nthreads_cta - 1)]
        for var in args:
            o.bar.sync(bar)
            o.st.volatile(shuf_write, var)
            o.bar.sync(bar)
            var.val = o.ld.volatile(shuf_read)
 class MWCRNG(object):
    """
@ -553,7 +447,7 @@ class MWCRNGTest(object):
        r.sum = r.u64(0)
        r.count = r.f32(self.rounds)
        start = e.label()
-        r.sum = r.sum + o.cvt.u64.u32(self.mwc.next_b32(e))
+        r.sum = r.sum + o.cvt.u64.u32(self.mwc.next_b32())
        r.count = r.count - 1
        with r.count > 0:
            o.bra.uni(start)
--- a/cuburn/render.py
+++ b/cuburn/render.py
@ -153,6 +153,10 @@ class Animation(object):
        # TODO: automatic optimization of block parameters
        entry = ptx.Entry("iterate", 512)
        iter = IterThread(entry, self.features)
        entry.finalize()
        iter.cp.finalize()
        srcmod = ptx.Module([entry])
        util.disass(srcmod)
        self.mod = run.Module([entry])
    def render_frame(self, time=0):
@ -214,6 +218,13 @@ class Features(object):
    # Maximum consecutive out-of-frame points before picking new point
    max_bad = 3
    # Height of the texture pallete which gets uploaded to the GPU (assuming
    # that palette-from-texture is enabled). For most genomes, this doesn't
    # need to be very large at all. However, since only an easily-cached
    # fraction of this will be accessed per SM, larger values shouldn't hurt
    # performance too much. Power-of-two, please.
    palette_height = 16
    def __init__(self, genomes, flt):
        any = lambda l: bool(filter(None, map(l, genomes)))
        self.max_ntemporal_samples = max(
@ -272,4 +283,3 @@ class Camera(object):
        self.norm_offset = -self.norm_scale * self.lower_bounds
        self.idx_scale = size * self.norm_scale
        self.idx_offset = size * self.norm_offset
--- a/main.py
+++ b/main.py
@ -17,7 +17,7 @@ from ctypes import *
 import numpy as np
 np.set_printoptions(precision=5, edgeitems=20)
-from pyptx import ptx, run
+from pyptx import ptx, run, util
 from cuburn.device_code import *
 from fr0stlib.pyflam3 import *
@ -32,16 +32,6 @@ def dump_3d(nda):
            f.write('  |  '.join([' '.join(
                ['%4.1g\t' % x for x in pt]) for pt in row]) + '\n')
 def disass(mod):
    import subprocess
    sys.stdout.flush()
    with open('/tmp/pyptx.ptx', 'w') as fp:
        fp.write(mod.source)
    subprocess.check_call('ptxas -arch sm_21 /tmp/pyptx.ptx '
                          '-o /tmp/elf.o'.split())
    subprocess.check_call('/home/steven/code/decuda/elfToCubin.py --nouveau '
                          '/tmp/elf.o'.split())
 def mwctest():
    mwcent = ptx.Entry("mwc_test", 512)
    mwctest = MWCRNGTest(mwcent)
@ -49,7 +39,7 @@ def mwctest():
    # Get the source for saving and disassembly before potentially crashing
    mod = ptx.Module([mwcent])
    print '\n'.join(['%4d %s' % t for t in enumerate(mod.source.split('\n'))])
-    disass(mod)
+    util.disass(mod)
    mod = run.Module([mwcent])
    mod.print_func_info()
@ -58,6 +48,7 @@ def mwctest():
    mwctest.run_test(ctx)
 def main(args):
    #mwctest()
    with open(args[-1]) as fp:
        genomes = Genome.from_string(fp.read())
    anim = Animation(genomes)