def mux_2d(mat, col_select, row_select, col_size, row_size, width=1):
ret_list = []
for line in mat:
for j in range(col_size):
ret = vg.Int(0, width=width)
for i in reversed(range(len(line))):
ret = vg.Mux(
col_select == i,
# line[(i + j) % col_size], ret)
line[(j + col_size - i) % col_size],
ret)
ret_list.append(ret)
mat = transpose_2d(line_to_2d(ret_list, col_size))
ret_list = []
for line in mat:
for j in range(row_size):
ret = vg.Int(0, width=width)
for i in reversed(range(len(line))):
ret = vg.Mux(
row_select == i,
# line[(i + j) % row_size], ret)
line[(j + row_size - i) % row_size],
ret)
ret_list.append(ret)
return transpose_2d(line_to_2d(ret_list, row_size))
def mux_1d(line, select, size, width=1):
ret_list = []
for j in range(size):
ret = vg.Int(0, width=width)
for i in reversed(range(len(line))):
ret = vg.Mux(select == i, line[(j + size - i) % size], ret)
ret_list.append(ret)
return ret_list
def control_sequence(self, fsm):
ksize_ch = self.ksize[-1]
ksize_col = self.ksize[-2]
ksize_row = self.ksize[-3]
ksize_bat = self.ksize[-4]
self.stride_bat = 1
act_rams = self.input_rams
out_ram = self.output_rams[0]
act_base_offset = self.m.Wire(self._name('act_base_offset'),
self.maxi.addrwidth,
signed=True)
act_base_offset_row = self.m.Reg(self._name('act_base_offset_row'),
self.maxi.addrwidth,
initval=0,
signed=True)
act_base_offset_bat = self.m.Reg(self._name('act_base_offset_bat'),
self.maxi.addrwidth,
initval=0,
signed=True)
act_base_offset.assign(act_base_offset_row + act_base_offset_bat)
out_base_offset = self.m.Wire(self._name('out_base_offset'),
self.maxi.addrwidth,
signed=True)
out_base_offset_row = self.m.Reg(self._name('out_base_offset_row'),
self.maxi.addrwidth,
initval=0,
signed=True)
out_base_offset_bat = self.m.Reg(self._name('out_base_offset_bat'),
self.maxi.addrwidth,
initval=0,
signed=True)
out_base_offset.assign(out_base_offset_row + out_base_offset_bat)
dma_flags = [
self.m.Reg(self._name('dma_flag_%d' % i), initval=0)
for i in range(ksize_row)
]
col_count = self.m.Reg(self._name('col_count'),
self.maxi.addrwidth,
initval=0)
row_count = self.m.Reg(self._name('row_count'),
self.maxi.addrwidth,
initval=0)
bat_count = self.m.Reg(self._name('bat_count'),
self.maxi.addrwidth,
initval=0)
col_select = self.m.Reg(self._name('col_select'),
bt.log_width(ksize_col),
initval=0)
row_select = self.m.Reg(self._name('row_select'),
bt.log_width(ksize_row),
initval=0)
prev_row_count = self.m.Reg(self._name('prev_row_count'),
self.maxi.addrwidth,
initval=0)
prev_bat_count = self.m.Reg(self._name('prev_bat_count'),
self.maxi.addrwidth,
initval=0)
prev_row_select = self.m.Reg(self._name('prev_row_select'),
bt.log_width(ksize_row),
initval=0)
stream_act_locals = [
self.m.Reg(self._name('stream_act_local_%d' % i),
self.maxi.addrwidth,
initval=0) for i in range(len(act_rams))
]
stream_out_local = self.m.Reg(self._name('stream_out_local'),
self.maxi.addrwidth,
initval=0)
# double buffer control
act_pages = [
self.m.Reg(self._name('act_page_%d' % i), initval=0)
for i in range(ksize_row)
]
act_page_comp_offsets = [
self.m.Reg(self._name('act_page_comp_offset_%d' % i),
self.maxi.addrwidth,
initval=0) for i in range(ksize_row)
]
act_page_dma_offsets = [
self.m.Reg(self._name('act_page_dma_offset_%d' % i),
self.maxi.addrwidth,
initval=0) for i in range(ksize_row)
]
out_page = self.m.Reg(self._name('out_page'), initval=0)
out_page_comp_offset = self.m.Reg(self._name('out_page_comp_offset'),
self.maxi.addrwidth,
initval=0)
out_page_dma_offset = self.m.Reg(self._name('out_page_dma_offset'),
self.maxi.addrwidth,
initval=0)
act_page_size = act_rams[0].length // 2
out_page_size = out_ram.length // 2
skip_read_act = self.m.Reg(self._name('skip_read_act'), initval=0)
skip_comp = self.m.Reg(self._name('skip_comp'), initval=0)
skip_write_out = self.m.Reg(self._name('skip_write_out'), initval=0)
comp_count = self.m.Reg(self._name('comp_count'),
self.maxi.addrwidth,
initval=0)
out_count = self.m.Reg(self._name('out_count'),
self.maxi.addrwidth,
initval=0)
# --------------------
# initialization phase
# --------------------
# ReadAct: offset
fsm(act_base_offset_row(0), act_base_offset_bat(0))
act_offsets = []
for v in self.act_offset_values:
act_offset = act_base_offset + v
act_offsets.append(act_offset)
# ReadAct: DMA flag
for y, dma_flag in enumerate(dma_flags):
fsm(dma_flag(1))
dma_pad_masks = []
for y in range(ksize_row):
v = vg.Ors((row_count + y < self.pad_row_top),
(row_count + y >= self.act_num_row + self.pad_row_top))
dma_pad_mask = self.m.Wire(self._name('dma_pad_mask_%d' % y))
dma_pad_mask.assign(v)
dma_pad_masks.append(dma_pad_mask)
# ReadAct: double buffer control
fsm([act_page(0) for act_page in act_pages], [
act_page_comp_offset(0)
for act_page_comp_offset in act_page_comp_offsets
], [
act_page_dma_offset(0)
for act_page_dma_offset in act_page_dma_offsets
])
# WriteOutput: offset
fsm(out_base_offset_row(0), out_base_offset_bat(0))
out_offset = out_base_offset
# WriteOut: double buffer control
fsm(out_page(0), out_page_comp_offset(0), out_page_dma_offset(0))
# counter
fsm(row_count(0), bat_count(0), row_select(0), prev_row_count(0),
prev_bat_count(0), prev_row_select(0))
# double buffer control
fsm(skip_read_act(0), skip_comp(0), skip_write_out(1))
fsm(out_count(0))
state_init = fsm.current
fsm.goto_next()
# --------------------
# ReadAct phase
# --------------------
state_read_act = fsm.current
act_gaddrs = []
for act_offset in act_offsets:
act_gaddr = self.arg_objaddrs[0] + act_offset
act_gaddrs.append(act_gaddr)
act_rams_2d = line_to_2d(act_rams, ksize_col)
mux_act_gaddr_values = mux_1d(act_gaddrs, row_select, ksize_row)
mux_act_gaddrs = []
for i, mux_act_gaddr_value in enumerate(mux_act_gaddr_values):
mux_act_gaddr = self.m.Wire(self._name('mux_act_gaddr_%d' % i),
self.maxi.addrwidth)
mux_act_gaddr.assign(mux_act_gaddr_value)
mux_act_gaddrs.append(mux_act_gaddr)
mux_dma_pad_mask_values = mux_1d(dma_pad_masks, row_select, ksize_row)
mux_dma_pad_masks = []
for i, mux_dma_pad_mask_value in enumerate(mux_dma_pad_mask_values):
mux_dma_pad_mask = self.m.Wire(
self._name('mux_dma_pad_mask_%d' % i))
mux_dma_pad_mask.assign(mux_dma_pad_mask_value)
mux_dma_pad_masks.append(mux_dma_pad_mask)
# determined at the previous phase
mux_dma_flag_values = mux_1d(dma_flags, prev_row_select, ksize_row)
mux_dma_flags = []
for i, mux_dma_flag_value in enumerate(mux_dma_flag_values):
mux_dma_flag = self.m.Wire(self._name('mux_dma_flag_%d' % i))
mux_dma_flag.assign(mux_dma_flag_value)
mux_dma_flags.append(mux_dma_flag)
bt.bus_lock(self.maxi, fsm)
for (act_rams_row, act_gaddr, act_page_dma_offset, dma_pad_mask,
dma_flag) in zip(act_rams_2d, mux_act_gaddrs,
act_page_dma_offsets, mux_dma_pad_masks,
mux_dma_flags):
act_laddr = act_page_dma_offset
begin_state_read = fsm.current
fsm.goto_next()
if len(act_rams_row) == 1:
bt.dma_read(self.maxi,
fsm,
act_rams_row[0],
act_laddr,
act_gaddr,
self.act_read_size,
port=1)
else:
bt.dma_read_block(self.maxi,
fsm,
act_rams_row,
act_laddr,
act_gaddr,
self.act_read_size,
self.act_read_block,
port=1)
end_state_read = fsm.current
fsm.If(vg.Ors(dma_pad_mask,
vg.Not(dma_flag))).goto_from(begin_state_read,
end_state_read)
bt.bus_unlock(self.maxi, fsm)
fsm.goto_next()
state_read_act_end = fsm.current
fsm.If(skip_read_act).goto_from(state_read_act, state_read_act_end)
# --------------------
# Comp phase
# --------------------
state_comp = fsm.current
# Stream Control FSM
comp_fsm = vg.FSM(self.m, self._name('comp_fsm'), self.clk, self.rst)
comp_state_init = comp_fsm.current
comp_fsm.If(fsm.state == state_comp, vg.Not(skip_comp)).goto_next()
fsm.If(comp_fsm.state == comp_state_init).goto_next()
# local address
stream_act_locals_2d = line_to_2d(stream_act_locals, ksize_col)
for y, stream_act_locals_row in enumerate(stream_act_locals_2d):
for x, stream_act_local in enumerate(stream_act_locals_row):
comp_fsm(stream_act_local(0))
comp_fsm.If(self.stream_act_local_small_flags[x])(
stream_act_local(self.stream_act_local_small_offset))
comp_fsm.If(self.stream_act_local_large_flags[x])(
stream_act_local(self.stream_act_local_large_offset))
comp_fsm(stream_out_local(0))
# count and sel
comp_fsm(col_count(0))
comp_fsm(col_select(self.col_select_initval))
act_page_comp_offset_bufs = [
self.m.Reg(self._name('act_page_comp_offset_buf_%d' % i),
self.maxi.addrwidth,
initval=0) for i in range(ksize_row)
]
out_page_comp_offset_buf = self.m.Reg(
self._name('out_page_comp_offset_buf'),
self.maxi.addrwidth,
initval=0)
row_count_buf = self.m.Reg(self._name('row_count_buf'),
self.maxi.addrwidth,
initval=0)
row_select_buf = self.m.Reg(self._name('row_select_buf'),
bt.log_width(ksize_row),
initval=0)
comp_fsm([
act_page_comp_offset_buf(act_page_comp_offset)
for act_page_comp_offset_buf, act_page_comp_offset in zip(
act_page_comp_offset_bufs, act_page_comp_offsets)
], out_page_comp_offset_buf(out_page_comp_offset),
row_count_buf(row_count), row_select_buf(row_select))
comp_fsm.goto_next()
# repeat comp
comp_state_rep = comp_fsm.current
# pad_mask
stream_pad_masks = []
for y in range(ksize_row):
for x in range(ksize_col):
stream_col_count = col_count + x
stream_row_count = row_count_buf + y
v = vg.Ors(
(stream_col_count < self.pad_col_left),
(stream_col_count >= self.act_num_col + self.pad_col_left),
(stream_row_count < self.pad_row_top),
(stream_row_count >= self.act_num_row + self.pad_row_top))
stream_pad_mask = self.m.Wire(
self._name('stream_pad_mask_%d_%d' % (y, x)))
stream_pad_mask.assign(v)
stream_pad_masks.append(stream_pad_mask)
stream_pad_mask_2d = line_to_2d(stream_pad_masks, ksize_col)
stream_pad_mask_2d_mux = mux_2d(stream_pad_mask_2d, col_select,
row_select_buf, ksize_col, ksize_row)
stream_pad_masks = [
flatten for inner in stream_pad_mask_2d_mux for flatten in inner
]
stream_pad_masks_reg = self.m.Reg(self._name('stream_pad_masks'),
len(stream_pad_masks),
initval=0)
comp_fsm(stream_pad_masks_reg(vg.Cat(*reversed(stream_pad_masks))))
comp_fsm.goto_next()
# busy check
self.stream.source_join(comp_fsm)
stream_masks = stream_pad_masks_reg
# set_constant
name = list(self.stream.constants.keys())[0]
self.stream.set_constant(comp_fsm, name, stream_masks)
comp_fsm.set_index(comp_fsm.current - 1)
# set_source
act_page_comp_offset_bufs_dup = []
for act_page_comp_offset_buf in act_page_comp_offset_bufs:
act_page_comp_offset_bufs_dup.extend([act_page_comp_offset_buf] *
ksize_col)
for name, ram, stream_act_local, act_page_comp_offset_buf in zip(
self.stream.sources.keys(), act_rams, stream_act_locals,
act_page_comp_offset_bufs_dup):
local = stream_act_local + act_page_comp_offset_buf
self.stream.set_source(comp_fsm, name, ram, local,
self.stream_size)
comp_fsm.set_index(comp_fsm.current - 1)
# set_sink
name = list(self.stream.sinks.keys())[0]
local = stream_out_local + out_page_comp_offset_buf
self.stream.set_sink(comp_fsm, name, out_ram, local, self.stream_size)
# stream run (async)
self.stream.run(comp_fsm)
# stream_act_local
stream_act_locals_2d = line_to_2d(stream_act_locals, ksize_col)
i = 0
for y, stream_act_locals_row in enumerate(stream_act_locals_2d):
for x, stream_act_local in enumerate(stream_act_locals_row):
patterns = []
for col in range(ksize_col):
val = self.inc_act_laddr_conds[i]
i += 1
pat = (col_select == col, val)
patterns.append(pat)
patterns.append((None, 0))
v = vg.PatternMux(*patterns)
comp_fsm.If(vg.Not(v))(stream_act_local.add(
self.inc_act_laddr_small))
comp_fsm.If(v)(stream_act_local.add(self.inc_act_laddr_large))
comp_fsm.If(col_count >= self.max_col_count)(
stream_act_local(0))
comp_fsm.If(col_count >= self.max_col_count,
self.stream_act_local_small_flags[x])(
stream_act_local(
self.stream_act_local_small_offset))
comp_fsm.If(col_count >= self.max_col_count,
self.stream_act_local_large_flags[x])(
stream_act_local(
self.stream_act_local_large_offset))
# stream_out_local
comp_fsm(stream_out_local.add(self.inc_out_laddr))
comp_fsm.If(col_count >= self.max_col_count)(stream_out_local(0))
# counter
comp_fsm(col_count.add(self.stride_col))
comp_fsm.If(col_count >= self.max_col_count)(col_count(0))
comp_fsm(col_select.add(self.stride_col_mod_ksize))
comp_fsm.If(col_select + self.stride_col_mod_ksize >= ksize_col)(
col_select.sub(self.ksize_col_minus_stride_col_mod))
comp_fsm.If(col_count >= self.max_col_count)(col_select(
self.col_select_initval), )
# repeat
comp_fsm.goto(comp_state_rep)
comp_fsm.If(col_count >= self.max_col_count).goto_init()
# sync with WriteOut control
comp_fsm.seq.If(fsm.state == state_init)(comp_count(0))
comp_fsm.seq.If(self.stream.end_flag)(comp_count.add(
self.inc_out_laddr))
# --------------------
# WriteOut phase
# --------------------
state_write_out = fsm.current
# sync with Comp control
fsm.If(comp_count >= out_count + self.out_write_size).goto_next()
out_laddr = out_page_dma_offset
out_gaddr = self.objaddr + out_offset
bt.bus_lock(self.maxi, fsm)
bt.dma_write(self.maxi,
fsm,
out_ram,
out_laddr,
out_gaddr,
self.out_write_size,
port=1,
use_async=True)
bt.bus_unlock(self.maxi, fsm)
fsm(out_count.add(self.out_write_size))
fsm.goto_next()
state_write_out_end = fsm.current
fsm.If(skip_write_out).goto_from(state_write_out, state_write_out_end)
# --------------------
# update for next iteration
# --------------------
# ReadAct: offset
fsm(act_base_offset_row.add(self.act_row_step))
fsm.If(row_count >= self.max_row_count)(act_base_offset_row(0),
act_base_offset_bat.add(
self.act_bat_step))
fsm.If(row_count >= self.max_row_count,
bat_count >= self.max_bat_count)(act_base_offset_bat(0))
# ReadAct: DMA flag
next_dma_flags = []
for dma_flag, dma_flag_cond in zip(dma_flags, self.dma_flag_conds):
fsm(dma_flag(dma_flag_cond))
fsm.If(row_count >= self.max_row_count)(dma_flag(1))
next_dma_flags.append(
vg.Mux(row_count >= self.max_row_count, 1, dma_flag_cond))
# ReadAct: counter
fsm(row_count.add(self.stride_row))
fsm.If(row_count >= self.max_row_count)(row_count(0),
bat_count.add(self.stride_bat))
fsm.If(row_count >= self.max_row_count,
bat_count >= self.max_bat_count)(bat_count(0))
fsm.If(self.stride_row < ksize_row)(row_select.add(self.stride_row),
prev_row_select(row_select))
fsm.If(self.stride_row < ksize_row,
row_select + self.stride_row >= ksize_row)(
row_select(row_select -
(vg.Int(ksize_row) - self.stride_row)),
prev_row_select(row_select))
fsm.If(vg.Not(self.stride_row < ksize_row))(row_select(0),
prev_row_select(0))
fsm.If(row_count >= self.max_row_count)(row_select(0),
prev_row_select(0))
# ReadAct and Comp: double buffer
mux_next_dma_flag_values = mux_1d(next_dma_flags, row_select,
ksize_row)
mux_next_dma_flags = []
for i, mux_next_dma_flag_value in enumerate(mux_next_dma_flag_values):
mux_next_dma_flag = self.m.Wire(
self._name('mux_next_dma_flag_%d' % i))
mux_next_dma_flag.assign(mux_next_dma_flag_value)
mux_next_dma_flags.append(mux_next_dma_flag)
for (act_page, act_page_comp_offset, act_page_dma_offset,
mux_next_dma_flag) in zip(act_pages, act_page_comp_offsets,
act_page_dma_offsets,
mux_next_dma_flags):
fsm.If(vg.Not(act_page),
mux_next_dma_flag)(act_page_comp_offset(act_page_size),
act_page_dma_offset(act_page_size),
act_page(1))
fsm.If(act_page, mux_next_dma_flag)(act_page_comp_offset(0),
act_page_dma_offset(0),
act_page(0))
# WriteOut: counter
fsm.If(vg.Not(skip_write_out))(out_base_offset_row.add(
self.out_row_step))
fsm.If(vg.Not(skip_write_out), prev_row_count >= self.max_row_count)(
out_base_offset_row(0), out_base_offset_bat.add(self.out_bat_step))
fsm.If(vg.Not(skip_write_out), prev_row_count >= self.max_row_count,
prev_bat_count >= self.max_bat_count)(out_base_offset_bat(0))
# WriteOut and Comp: double buffer
fsm.If(vg.Not(out_page))(out_page_comp_offset(out_page_size),
out_page_dma_offset(0), out_page(1))
fsm.If(out_page)(out_page_comp_offset(0),
out_page_dma_offset(out_page_size), out_page(0))
# ReadAct and WriteOut: prev
fsm(prev_row_count(row_count), prev_bat_count(bat_count))
# ReadAct, Comp, WriteOut: skip
fsm.If(row_count >= self.max_row_count,
bat_count >= self.max_bat_count)(skip_read_act(1))
fsm.If(row_count >= self.max_row_count,
bat_count >= self.max_bat_count)(skip_comp(1))
fsm.If(skip_write_out, prev_row_count == 0,
prev_bat_count == 0)(skip_write_out(0))
fsm.goto(state_read_act)
fsm.If(vg.Not(skip_write_out), prev_row_count >= self.max_row_count,
prev_bat_count >= self.max_bat_count).goto_next()
# wait for last DMA write
bt.dma_wait_write(self.maxi, fsm)
def control_sequence(self, fsm):
ksize_ch = self.ksize[-1]
ksize_col = self.ksize[-2]
ksize_row = self.ksize[-3]
ksize_bat = self.ksize[-4]
self.stride_bat = 1
act_ram = self.input_rams[0]
out_ram = self.output_rams[0]
act_base_offset = self.m.Wire(self._name('act_base_offset'),
self.maxi.addrwidth, signed=True)
act_base_offset_row = self.m.Reg(self._name('act_base_offset_row'),
self.maxi.addrwidth, initval=0, signed=True)
act_base_offset_bat = self.m.Reg(self._name('act_base_offset_bat'),
self.maxi.addrwidth, initval=0, signed=True)
act_base_offset.assign(act_base_offset_row
+ act_base_offset_bat)
out_base_offset = self.m.Wire(self._name('out_base_offset'),
self.maxi.addrwidth, signed=True)
out_base_offset_row = self.m.Reg(self._name('out_base_offset_row'),
self.maxi.addrwidth, initval=0, signed=True)
out_base_offset_bat = self.m.Reg(self._name('out_base_offset_bat'),
self.maxi.addrwidth, initval=0, signed=True)
out_base_offset.assign(out_base_offset_row
+ out_base_offset_bat)
col_count = self.m.Reg(self._name('col_count'),
self.maxi.addrwidth, initval=0)
row_count = self.m.Reg(self._name('row_count'),
self.maxi.addrwidth, initval=0)
bat_count = self.m.Reg(self._name('bat_count'),
self.maxi.addrwidth, initval=0)
if not self.no_reuse:
col_select = self.m.Reg(self._name('col_select'),
bt.log_width(ksize_col),
initval=0)
row_select = self.m.Reg(self._name('row_select'),
bt.log_width(ksize_row),
initval=0)
prev_row_count = self.m.Reg(self._name('prev_row_count'),
self.maxi.addrwidth, initval=0)
prev_bat_count = self.m.Reg(self._name('prev_bat_count'),
self.maxi.addrwidth, initval=0)
if not self.no_reuse:
prev_row_select = self.m.Reg(self._name('prev_row_select'),
bt.log_width(ksize_row),
initval=0)
stream_act_local = self.m.Reg(self._name('stream_act_local'),
self.maxi.addrwidth, initval=0)
stream_out_local = self.m.Reg(self._name('stream_out_local'),
self.maxi.addrwidth, initval=0)
# double buffer control
act_page = self.m.Reg(self._name('act_page'), initval=0)
act_page_comp_offset = self.m.Reg(self._name('act_page_comp_offset'),
self.maxi.addrwidth, initval=0)
act_page_dma_offset = self.m.Reg(self._name('act_page_dma_offset'),
self.maxi.addrwidth, initval=0)
out_page = self.m.Reg(self._name('out_page'), initval=0)
out_page_comp_offset = self.m.Reg(self._name('out_page_comp_offset'),
self.maxi.addrwidth, initval=0)
out_page_dma_offset = self.m.Reg(self._name('out_page_dma_offset'),
self.maxi.addrwidth, initval=0)
act_page_size = act_ram.length // 2
out_page_size = out_ram.length // 2
skip_read_act = self.m.Reg(self._name('skip_read_act'), initval=0)
skip_comp = self.m.Reg(self._name('skip_comp'), initval=0)
skip_write_out = self.m.Reg(self._name('skip_write_out'), initval=0)
comp_count = self.m.Reg(self._name('comp_count'),
self.maxi.addrwidth, initval=0)
out_count = self.m.Reg(self._name('out_count'),
self.maxi.addrwidth, initval=0)
# --------------------
# initialization phase
# --------------------
# ReadAct: offset
fsm(
act_base_offset_row(0),
act_base_offset_bat(0)
)
act_offsets = []
for v in self.act_offset_values:
act_offset = act_base_offset + v
act_offsets.append(act_offset)
# ReadAct: DMA flag
dma_pad_masks = []
for y in range(ksize_row):
v = vg.Ors((row_count + y < self.pad_row_top),
(row_count + y >= self.act_num_row + self.pad_row_top))
dma_pad_mask = self.m.Wire(
self._name('dma_pad_mask_%d' % y))
dma_pad_mask.assign(v)
dma_pad_masks.append(dma_pad_mask)
# ReadAct: double buffer control
fsm(
act_page(0),
act_page_comp_offset(0),
act_page_dma_offset(0)
)
# WriteOutput: offset
fsm(
out_base_offset_row(0),
out_base_offset_bat(0)
)
out_offset = out_base_offset
# WriteOut: double buffer control
fsm(
out_page(0),
out_page_comp_offset(0),
out_page_dma_offset(0)
)
# counter
fsm(
row_count(0),
bat_count(0),
prev_row_count(0),
prev_bat_count(0)
)
if not self.no_reuse:
fsm(
row_select(0),
prev_row_select(0)
)
# double buffer control
fsm(
skip_read_act(0),
skip_comp(0),
skip_write_out(1)
)
fsm(
out_count(0)
)
state_init = fsm.current
fsm.goto_next()
# --------------------
# ReadAct phase
# --------------------
state_read_act = fsm.current
act_gaddrs = []
for act_offset in act_offsets:
act_gaddr = self.arg_objaddrs[0] + act_offset
act_gaddrs.append(act_gaddr)
if not self.no_reuse:
mux_act_gaddr_values = mux_1d(act_gaddrs, row_select, ksize_row)
mux_act_gaddrs = []
for i, mux_act_gaddr_value in enumerate(mux_act_gaddr_values):
mux_act_gaddr = self.m.Wire(self._name('mux_act_gaddr_%d' % i),
self.maxi.addrwidth)
mux_act_gaddr.assign(mux_act_gaddr_value)
mux_act_gaddrs.append(mux_act_gaddr)
mux_dma_pad_mask_values = mux_1d(
dma_pad_masks, row_select, ksize_row)
mux_dma_pad_masks = []
for i, mux_dma_pad_mask_value in enumerate(mux_dma_pad_mask_values):
mux_dma_pad_mask = self.m.Wire(
self._name('mux_dma_pad_mask_%d' % i))
mux_dma_pad_mask.assign(mux_dma_pad_mask_value)
mux_dma_pad_masks.append(mux_dma_pad_mask)
else:
mux_act_gaddrs = act_gaddrs
mux_dma_pad_masks = dma_pad_masks
bt.bus_lock(self.maxi, fsm)
act_laddr = act_page_dma_offset
for (act_gaddr, dma_pad_mask) in zip(
mux_act_gaddrs, mux_dma_pad_masks):
begin_state_read = fsm.current
fsm.goto_next()
bt.dma_read(self.maxi, fsm, act_ram, act_laddr,
act_gaddr, self.act_read_size, port=1)
end_state_read = fsm.current
fsm.If(dma_pad_mask).goto_from(
begin_state_read, end_state_read)
act_laddr += self.act_read_size
bt.bus_unlock(self.maxi, fsm)
fsm.goto_next()
state_read_act_end = fsm.current
fsm.If(skip_read_act).goto_from(state_read_act, state_read_act_end)
# --------------------
# Comp phase
# --------------------
state_comp = fsm.current
# Stream Control FSM
comp_fsm = vg.FSM(self.m, self._name('comp_fsm'), self.clk, self.rst)
comp_state_init = comp_fsm.current
comp_fsm.If(fsm.state == state_comp, vg.Not(skip_comp)).goto_next()
fsm.If(comp_fsm.state == comp_state_init).goto_next()
# local address
comp_fsm(
stream_act_local(self.local_pad_offset)
)
comp_fsm(
stream_out_local(0)
)
# count and sel
comp_fsm(
col_count(0)
)
if not self.no_reuse:
comp_fsm(
col_select(self.col_select_initval)
)
act_page_comp_offset_buf = self.m.Reg(self._name('act_page_comp_offset_buf'),
self.maxi.addrwidth, initval=0)
out_page_comp_offset_buf = self.m.Reg(self._name('out_page_comp_offset_buf'),
self.maxi.addrwidth, initval=0)
row_count_buf = self.m.Reg(self._name('row_count_buf'),
self.maxi.addrwidth, initval=0)
if not self.no_reuse:
row_select_buf = self.m.Reg(self._name('row_select_buf'),
bt.log_width(ksize_row),
initval=0)
comp_fsm(
act_page_comp_offset_buf(act_page_comp_offset),
out_page_comp_offset_buf(out_page_comp_offset),
row_count_buf(row_count)
)
if not self.no_reuse:
comp_fsm(
row_select_buf(row_select)
)
comp_fsm.goto_next()
# repeat comp
comp_state_rep = comp_fsm.current
# pad_mask
stream_pad_masks = []
for y in range(ksize_row):
for x in range(ksize_col):
stream_col_count = col_count + x
stream_row_count = row_count_buf + y
v = vg.Ors((stream_col_count < self.pad_col_left),
(stream_col_count >= self.act_num_col + self.pad_col_left),
(stream_row_count < self.pad_row_top),
(stream_row_count >= self.act_num_row + self.pad_row_top))
stream_pad_mask = self.m.Wire(
self._name('stream_pad_mask_%d_%d' % (y, x)))
stream_pad_mask.assign(v)
stream_pad_masks.append(stream_pad_mask)
if not self.no_reuse:
stream_pad_mask_2d = line_to_2d(stream_pad_masks, ksize_col)
stream_pad_mask_2d_mux = mux_2d(stream_pad_mask_2d,
col_select, row_select_buf,
ksize_col, ksize_row)
stream_pad_masks = [flatten for inner in stream_pad_mask_2d_mux
for flatten in inner]
stream_pad_masks_reg = self.m.Reg(self._name('stream_pad_masks'),
len(stream_pad_masks), initval=0)
comp_fsm(
stream_pad_masks_reg(vg.Cat(*reversed(stream_pad_masks)))
)
comp_fsm.goto_next()
# busy check
self.stream.source_join(comp_fsm)
stream_masks = stream_pad_masks_reg
# set_constant
name = list(self.stream.constants.keys())[0]
self.stream.set_constant(comp_fsm, name, ksize_col * ksize_row)
comp_fsm.set_index(comp_fsm.current - 1)
name = list(self.stream.constants.keys())[1]
self.stream.set_constant(comp_fsm, name, stream_masks)
comp_fsm.set_index(comp_fsm.current - 1)
# set_source
name = list(self.stream.sources.keys())[0]
local = stream_act_local + act_page_comp_offset_buf
pat = ((ksize_col, self.act_read_block),
(ksize_row, self.act_read_size),
(self.stream_size, 1))
self.stream.set_source_pattern(comp_fsm, name, act_ram,
local, pat)
comp_fsm.set_index(comp_fsm.current - 1)
# set_sink
name = list(self.stream.sinks.keys())[0]
local = stream_out_local + out_page_comp_offset_buf
self.stream.set_sink(comp_fsm, name, out_ram, local, self.stream_size)
# stream run (async)
self.stream.run(comp_fsm)
# stream_act_local
comp_fsm(
stream_act_local.add(self.inc_act_laddr)
)
comp_fsm.If(col_count >= self.max_col_count)(
stream_act_local(self.local_pad_offset)
)
# stream_out_local
comp_fsm(
stream_out_local.add(self.inc_out_laddr)
)
comp_fsm.If(col_count >= self.max_col_count)(
stream_out_local(0)
)
# counter
comp_fsm(
col_count.add(self.stride_col)
)
comp_fsm.If(col_count >= self.max_col_count)(
col_count(0)
)
if not self.no_reuse:
comp_fsm(
col_select.add(self.stride_col_mod_ksize)
)
comp_fsm.If(col_select + self.stride_col_mod_ksize >= ksize_col)(
col_select.sub(self.ksize_col_minus_stride_col_mod)
)
comp_fsm.If(col_count >= self.max_col_count)(
col_select(self.col_select_initval)
)
# repeat
comp_fsm.goto(comp_state_rep)
comp_fsm.If(col_count >= self.max_col_count).goto_init()
# sync with WriteOut control
comp_fsm.seq.If(fsm.state == state_init)(
comp_count(0)
)
comp_fsm.seq.If(self.stream.end_flag)(
comp_count.add(self.inc_out_laddr)
)
# --------------------
# WriteOut phase
# --------------------
state_write_out = fsm.current
# sync with Comp control
fsm.If(comp_count >= out_count + self.out_write_size).goto_next()
out_laddr = out_page_dma_offset
out_gaddr = self.objaddr + out_offset
bt.bus_lock(self.maxi, fsm)
bt.dma_write(self.maxi, fsm, out_ram, out_laddr,
out_gaddr, self.out_write_size, port=1, use_async=True)
bt.bus_unlock(self.maxi, fsm)
fsm(
out_count.add(self.out_write_size)
)
fsm.goto_next()
state_write_out_end = fsm.current
fsm.If(skip_write_out).goto_from(state_write_out, state_write_out_end)
# --------------------
# update for next iteration
# --------------------
# ReadAct: offset
fsm(
act_base_offset_row.add(self.act_row_step)
)
fsm.If(row_count >= self.max_row_count)(
act_base_offset_row(0),
act_base_offset_bat.add(self.act_bat_step)
)
fsm.If(row_count >= self.max_row_count,
bat_count >= self.max_bat_count)(
act_base_offset_bat(0)
)
# ReadAct: counter
fsm(
row_count.add(self.stride_row)
)
fsm.If(row_count >= self.max_row_count)(
row_count(0),
bat_count.add(self.stride_bat)
)
fsm.If(row_count >= self.max_row_count,
bat_count >= self.max_bat_count)(
bat_count(0)
)
if not self.no_reuse:
fsm.If(self.stride_row < ksize_row)(
row_select.add(self.stride_row),
prev_row_select(row_select)
)
fsm.If(self.stride_row < ksize_row,
row_select + self.stride_row >= ksize_row)(
row_select(row_select - (vg.Int(ksize_row) - self.stride_row)),
prev_row_select(row_select)
)
fsm.If(vg.Not(self.stride_row < ksize_row))(
row_select(0),
prev_row_select(0)
)
fsm.If(row_count >= self.max_row_count)(
row_select(0),
prev_row_select(0)
)
# ReadAct and Comp: double buffer
fsm.If(vg.Not(act_page))(
act_page_comp_offset(act_page_size),
act_page_dma_offset(act_page_size),
act_page(1)
)
fsm.If(act_page)(
act_page_comp_offset(0),
act_page_dma_offset(0),
act_page(0)
)
# WriteOut: counter
fsm.If(vg.Not(skip_write_out))(
out_base_offset_row.add(self.out_row_step)
)
fsm.If(vg.Not(skip_write_out),
prev_row_count >= self.max_row_count)(
out_base_offset_row(0),
out_base_offset_bat.add(self.out_bat_step)
)
fsm.If(vg.Not(skip_write_out),
prev_row_count >= self.max_row_count,
prev_bat_count >= self.max_bat_count)(
out_base_offset_bat(0)
)
# WriteOut and Comp: double buffer
fsm.If(vg.Not(out_page))(
out_page_comp_offset(out_page_size),
out_page_dma_offset(0),
out_page(1)
)
fsm.If(out_page)(
out_page_comp_offset(0),
out_page_dma_offset(out_page_size),
out_page(0)
)
# ReadAct and WriteOut: prev
fsm(
prev_row_count(row_count),
prev_bat_count(bat_count)
)
# ReadAct, Comp, WriteOut: skip
fsm.If(row_count >= self.max_row_count,
bat_count >= self.max_bat_count)(
skip_read_act(1)
)
fsm.If(row_count >= self.max_row_count,
bat_count >= self.max_bat_count)(
skip_comp(1)
)
fsm.If(skip_write_out,
prev_row_count == 0,
prev_bat_count == 0)(
skip_write_out(0)
)
fsm.goto(state_read_act)
fsm.If(vg.Not(skip_write_out),
prev_row_count >= self.max_row_count,
prev_bat_count >= self.max_bat_count).goto_next()
# wait for last DMA write
bt.dma_wait_write(self.maxi, fsm)
import veriloggen as vg
import veriloggen.resolver.resolver as resolver
#-------------------------------------------------------------------------------
exclude_modules = ['cpr_.*']
target_modules = { # module_type : (port_name, port_width)
"cpr_ram.*" :
(('ext_addr', 'Input', vg.AnyType(name='ADDR_WIDTH')),
('ext_rdata', 'Output', vg.AnyType(name='DATA_WIDTH')),
('ext_wdata', 'Input', vg.AnyType(name='DATA_WIDTH')),
('ext_wvalid', 'Input', None),),
"cpr_master_bus" :
(('ext_awvalid', 'Output', vg.Int(1)),
('ext_awaddr', 'Output', vg.AnyType(name='ADDR_WIDTH')),
('ext_awlen', 'Output', vg.Int(8)),
('ext_awready', 'Input', vg.Int(1)),
('ext_wdata', 'Output', vg.AnyType(name='DATA_WIDTH')),
('ext_wstrb', 'Output', vg.Divide(vg.AnyType(name='DATA_WIDTH'), vg.Int(8))),
('ext_wlast', 'Output', vg.Int(1)),
('ext_wvalid', 'Output', vg.Int(1)),
('ext_wready', 'Input', vg.Int(1)),
('ext_arvalid', 'Output', vg.Int(1)),
('ext_araddr', 'Output', vg.AnyType(name='ADDR_WIDTH')),
('ext_arlen', 'Output', vg.Int(8)),
('ext_arready', 'Input', vg.Int(1)),