1 """LOAD / STORE Computation Unit.
3 This module covers POWER9-compliant Load and Store operations,
4 with selection on each between immediate and indexed mode as
5 options for the calculation of the Effective Address (EA),
6 and also "update" mode which optionally stores that EA into
7 an additional register.
10 Note: it took 15 attempts over several weeks to redraw the diagram
11 needed to capture this FSM properly. To understand it fully, please
12 take the time to review the links, video, and diagram.
15 Stores are activated when Go_Store is enabled, and use a sync'd "ADD" to
16 compute the "Effective Address", and, when ready the operand (src3_i)
17 is stored in the computed address (passed through to the PortInterface)
19 Loads are activated when Go_Write[0] is enabled. The EA is computed,
20 and (as long as there was no exception) the data comes out (at any
21 time from the PortInterface), and is captured by the LDCompSTUnit.
23 Both LD and ST may request that the address be computed from summing
24 operand1 (src[0]) with operand2 (src[1]) *or* by summing operand1 with
25 the immediate (from the opcode).
27 Both LD and ST may also request "update" mode (op_is_update) which
28 activates the use of Go_Write[1] to control storage of the EA into
29 a *second* operand in the register file.
31 Thus this module has *TWO* write-requests to the register file and
32 *THREE* read-requests to the register file (not all at the same time!)
33 The regfile port usage is:
45 It's a multi-level Finite State Machine that (unfortunately) nmigen.FSM
46 is not suited to (nmigen.FSM is clock-driven, and some aspects of
47 the nested FSMs below are *combinatorial*).
49 * One FSM covers Operand collection and communication address-side
50 with the LD/ST PortInterface. its role ends when "RD_DONE" is asserted
52 * A second FSM activates to cover LD. it activates if op_is_ld is true
54 * A third FSM activates to cover ST. it activates if op_is_st is true
56 * The "overall" (fourth) FSM coordinates the progression and completion
57 of the three other FSMs, firing "WR_RESET" which switches off "busy"
61 https://libre-soc.org/3d_gpu/ld_st_comp_unit.jpg
63 Links including to walk-through videos:
65 * https://libre-soc.org/3d_gpu/architecture/6600scoreboard/
66 * http://libre-soc.org/openpower/isa/fixedload
67 * http://libre-soc.org/openpower/isa/fixedstore
71 * https://bugs.libre-soc.org/show_bug.cgi?id=302
72 * https://bugs.libre-soc.org/show_bug.cgi?id=216
76 * EA - Effective Address
81 from nmigen
.compat
.sim
import run_simulation
82 from nmigen
.cli
import verilog
, rtlil
83 from nmigen
import Module
, Signal
, Mux
, Cat
, Elaboratable
, Array
, Repl
84 from nmigen
.hdl
.rec
import Record
, Layout
86 from nmutil
.latch
import SRLatch
, latchregister
87 from nmutil
.byterev
import byte_reverse
89 from soc
.experiment
.compalu_multi
import go_record
, CompUnitRecord
90 from soc
.experiment
.l0_cache
import PortInterface
91 from soc
.fu
.regspec
import RegSpecAPI
93 from soc
.decoder
.power_enums
import MicrOp
, Function
, LDSTMode
94 from soc
.fu
.ldst
.ldst_input_record
import CompLDSTOpSubset
95 from soc
.decoder
.power_decoder2
import Data
98 class LDSTCompUnitRecord(CompUnitRecord
):
99 def __init__(self
, rwid
, opsubset
=CompLDSTOpSubset
, name
=None):
100 CompUnitRecord
.__init
__(self
, opsubset
, rwid
,
101 n_src
=3, n_dst
=2, name
=name
)
103 self
.ad
= go_record(1, name
="cu_ad") # address go in, req out
104 self
.st
= go_record(1, name
="cu_st") # store go in, req out
106 self
.addr_exc_o
= Signal(reset_less
=True) # address exception
108 self
.ld_o
= Signal(reset_less
=True) # operation is a LD
109 self
.st_o
= Signal(reset_less
=True) # operation is a ST
111 # hmm... are these necessary?
112 self
.load_mem_o
= Signal(reset_less
=True) # activate memory LOAD
113 self
.stwd_mem_o
= Signal(reset_less
=True) # activate memory STORE
116 class LDSTCompUnit(RegSpecAPI
, Elaboratable
):
117 """LOAD / STORE Computation Unit
122 * :pi: a PortInterface to the memory subsystem (read-write capable)
123 * :rwid: register width
124 * :awid: address width
128 * :src_i: Source Operands (RA/RB/RC) - managed by rd[0-3] go/req
132 * :data_o: Dest out (LD) - managed by wr[0] go/req
133 * :addr_o: Address out (LD or ST) - managed by wr[1] go/req
134 * :addr_exc_o: Address/Data Exception occurred. LD/ST must terminate
136 TODO: make addr_exc_o a data-type rather than a single-bit signal
142 * :oper_i: operation being carried out (POWER9 decode LD/ST subset)
143 * :issue_i: LD/ST is being "issued".
144 * :shadown_i: Inverted-shadow is being held (stops STORE *and* WRITE)
145 * :go_rd_i: read is being actioned (latches in src regs)
146 * :go_wr_i: write mode (exactly like ALU CompUnit)
147 * :go_ad_i: address is being actioned (triggers actual mem LD)
148 * :go_st_i: store is being actioned (triggers actual mem STORE)
149 * :go_die_i: resets the unit back to "wait for issue"
151 Control Signals (Out)
152 ---------------------
154 * :busy_o: function unit is busy
155 * :rd_rel_o: request src1/src2
156 * :adr_rel_o: request address (from mem)
157 * :sto_rel_o: request store (to mem)
158 * :req_rel_o: request write (result)
159 * :load_mem_o: activate memory LOAD
160 * :stwd_mem_o: activate memory STORE
162 Note: load_mem_o, stwd_mem_o and req_rel_o MUST all be acknowledged
163 in a single cycle and the CompUnit set back to doing another op.
164 This means deasserting go_st_i, go_ad_i or go_wr_i as appropriate
165 depending on whether the operation is a ST or LD.
167 Note: LDSTCompUnit takes care of LE/BE normalisation:
168 * LD data is normalised after receipt from the PortInterface
169 * ST data is normalised *prior* to sending onto the PortInterface
170 TODO: use one module for the byte-reverse as it's quite expensive in gates
173 def __init__(self
, pi
=None, rwid
=64, awid
=48, opsubset
=CompLDSTOpSubset
,
174 debugtest
=False, name
=None):
175 super().__init
__(rwid
)
178 self
.cu
= cu
= LDSTCompUnitRecord(rwid
, opsubset
, name
=name
)
179 self
.debugtest
= debugtest
181 # POWER-compliant LD/ST has index and update: *fixed* number of ports
182 self
.n_src
= n_src
= 3 # RA, RB, RT/RS
183 self
.n_dst
= n_dst
= 2 # RA, RT/RS
185 # set up array of src and dest signals
186 for i
in range(n_src
):
187 j
= i
+ 1 # name numbering to match src1/src2
189 setattr(self
, name
, getattr(cu
, name
))
192 for i
in range(n_dst
):
193 j
= i
+ 1 # name numbering to match dest1/2...
194 name
= "dest%d_o" % j
195 setattr(self
, name
, getattr(cu
, name
))
200 self
.rdmaskn
= cu
.rdmaskn
201 self
.wrmask
= cu
.wrmask
206 # HACK: get data width from dest[0]. this is used across the board
207 # (it really shouldn't be)
208 self
.data_wid
= self
.dest
[0].shape()
210 self
.go_rd_i
= self
.rd
.go_i
# temporary naming
211 self
.go_wr_i
= self
.wr
.go_i
# temporary naming
212 self
.go_ad_i
= self
.ad
.go_i
# temp naming: go address in
213 self
.go_st_i
= self
.st
.go_i
# temp naming: go store in
215 self
.rd_rel_o
= self
.rd
.rel_o
# temporary naming
216 self
.req_rel_o
= self
.wr
.rel_o
# temporary naming
217 self
.adr_rel_o
= self
.ad
.rel_o
# request address (from mem)
218 self
.sto_rel_o
= self
.st
.rel_o
# request store (to mem)
220 self
.issue_i
= cu
.issue_i
221 self
.shadown_i
= cu
.shadown_i
222 self
.go_die_i
= cu
.go_die_i
224 self
.oper_i
= cu
.oper_i
225 self
.src_i
= cu
._src
_i
227 self
.data_o
= Data(self
.data_wid
, name
="o") # Dest1 out: RT
228 self
.addr_o
= Data(self
.data_wid
, name
="ea") # Addr out: Update => RA
229 self
.addr_exc_o
= cu
.addr_exc_o
230 self
.done_o
= cu
.done_o
231 self
.busy_o
= cu
.busy_o
236 self
.load_mem_o
= cu
.load_mem_o
237 self
.stwd_mem_o
= cu
.stwd_mem_o
239 def elaborate(self
, platform
):
245 issue_i
= self
.issue_i
247 #####################
248 # latches for the FSM.
249 m
.submodules
.opc_l
= opc_l
= SRLatch(sync
=False, name
="opc")
250 m
.submodules
.src_l
= src_l
= SRLatch(False, self
.n_src
, name
="src")
251 m
.submodules
.alu_l
= alu_l
= SRLatch(sync
=False, name
="alu")
252 m
.submodules
.adr_l
= adr_l
= SRLatch(sync
=False, name
="adr")
253 m
.submodules
.lod_l
= lod_l
= SRLatch(sync
=False, name
="lod")
254 m
.submodules
.sto_l
= sto_l
= SRLatch(sync
=False, name
="sto")
255 m
.submodules
.wri_l
= wri_l
= SRLatch(sync
=False, name
="wri")
256 m
.submodules
.upd_l
= upd_l
= SRLatch(sync
=False, name
="upd")
257 m
.submodules
.rst_l
= rst_l
= SRLatch(sync
=False, name
="rst")
258 m
.submodules
.lsd_l
= lsd_l
= SRLatch(sync
=False, name
="lsd") # done
264 op_is_ld
= Signal(reset_less
=True)
265 op_is_st
= Signal(reset_less
=True)
267 # ALU/LD data output control
268 alu_valid
= Signal(reset_less
=True) # ALU operands are valid
269 alu_ok
= Signal(reset_less
=True) # ALU out ok (1 clock delay valid)
270 addr_ok
= Signal(reset_less
=True) # addr ok (from PortInterface)
271 ld_ok
= Signal(reset_less
=True) # LD out ok from PortInterface
272 wr_any
= Signal(reset_less
=True) # any write (incl. store)
273 rda_any
= Signal(reset_less
=True) # any read for address ops
274 rd_done
= Signal(reset_less
=True) # all *necessary* operands read
275 wr_reset
= Signal(reset_less
=True) # final reset condition
278 alu_o
= Signal(self
.data_wid
, reset_less
=True)
279 ldd_o
= Signal(self
.data_wid
, reset_less
=True)
281 ##############################
282 # reset conditions for latches
284 # temporaries (also convenient when debugging)
285 reset_o
= Signal(reset_less
=True) # reset opcode
286 reset_w
= Signal(reset_less
=True) # reset write
287 reset_u
= Signal(reset_less
=True) # reset update
288 reset_a
= Signal(reset_less
=True) # reset adr latch
289 reset_i
= Signal(reset_less
=True) # issue|die (use a lot)
290 reset_r
= Signal(self
.n_src
, reset_less
=True) # reset src
291 reset_s
= Signal(reset_less
=True) # reset store
293 comb
+= reset_i
.eq(issue_i | self
.go_die_i
) # various
294 comb
+= reset_o
.eq(wr_reset | self
.go_die_i
) # opcode reset
295 comb
+= reset_w
.eq(self
.wr
.go_i
[0] | self
.go_die_i
) # write reg 1
296 comb
+= reset_u
.eq(self
.wr
.go_i
[1] | self
.go_die_i
) # update (reg 2)
297 comb
+= reset_s
.eq(self
.go_st_i | self
.go_die_i
) # store reset
298 comb
+= reset_r
.eq(self
.rd
.go_i |
Repl(self
.go_die_i
, self
.n_src
))
299 comb
+= reset_a
.eq(self
.go_ad_i | self
.go_die_i
)
301 p_st_go
= Signal(reset_less
=True)
302 sync
+= p_st_go
.eq(self
.st
.go_i
)
304 ##########################
305 # FSM implemented through sequence of latches. approximately this:
307 # - src_l[0] : operands
309 # - alu_l : looks after add of src1/2/imm (EA)
310 # - adr_l : waits for add (EA)
311 # - upd_l : waits for adr and Regfile (port 2)
313 # - lod_l : waits for adr (EA) and for LD Data
314 # - wri_l : waits for LD Data and Regfile (port 1)
315 # - st_l : waits for alu and operand2
316 # - rst_l : waits for all FSM paths to converge.
317 # NOTE: use sync to stop combinatorial loops.
319 # opcode latch - inverted so that busy resets to 0
320 # note this MUST be sync so as to avoid a combinatorial loop
321 # between busy_o and issue_i on the reset latch (rst_l)
322 sync
+= opc_l
.s
.eq(issue_i
) # XXX NOTE: INVERTED FROM book!
323 sync
+= opc_l
.r
.eq(reset_o
) # XXX NOTE: INVERTED FROM book!
326 sync
+= src_l
.s
.eq(Repl(issue_i
, self
.n_src
))
327 sync
+= src_l
.r
.eq(reset_r
)
329 # alu latch. use sync-delay between alu_ok and valid to generate pulse
330 comb
+= alu_l
.s
.eq(reset_i
)
331 comb
+= alu_l
.r
.eq(alu_ok
& ~alu_valid
& ~rda_any
)
334 comb
+= adr_l
.s
.eq(reset_i
)
335 sync
+= adr_l
.r
.eq(reset_a
)
338 comb
+= lod_l
.s
.eq(reset_i
)
339 comb
+= lod_l
.r
.eq(ld_ok
)
342 comb
+= wri_l
.s
.eq(issue_i
)
343 sync
+= wri_l
.r
.eq(reset_w |
Repl(self
.done_o
, self
.n_dst
))
345 # update-mode operand latch (EA written to reg 2)
346 sync
+= upd_l
.s
.eq(reset_i
)
347 sync
+= upd_l
.r
.eq(reset_u
)
350 comb
+= sto_l
.s
.eq(addr_ok
& op_is_st
)
351 sync
+= sto_l
.r
.eq(reset_s | p_st_go
)
353 # ld/st done. needed to stop LD/ST from activating repeatedly
354 comb
+= lsd_l
.s
.eq(issue_i
)
355 sync
+= lsd_l
.r
.eq(reset_s | p_st_go | ld_ok
)
358 comb
+= rst_l
.s
.eq(addr_ok
) # start when address is ready
359 comb
+= rst_l
.r
.eq(issue_i
)
361 # create a latch/register for the operand
362 oper_r
= CompLDSTOpSubset(name
="oper_r") # Dest register
363 latchregister(m
, self
.oper_i
, oper_r
, self
.issue_i
, name
="oper_l")
366 ldd_r
= Signal(self
.data_wid
, reset_less
=True) # Dest register
367 latchregister(m
, ldd_o
, ldd_r
, ld_ok
, name
="ldo_r")
369 # and for each input from the incoming src operands
371 for i
in range(self
.n_src
):
373 src_r
= Signal(self
.data_wid
, name
=name
, reset_less
=True)
374 latchregister(m
, self
.src_i
[i
], src_r
, src_l
.q
[i
], name
+ '_l')
377 # and one for the output from the ADD (for the EA)
378 addr_r
= Signal(self
.data_wid
, reset_less
=True) # Effective Address
379 latchregister(m
, alu_o
, addr_r
, alu_l
.q
, "ea_r")
381 # select either zero or src1 if opcode says so
382 op_is_z
= oper_r
.zero_a
383 src1_or_z
= Signal(self
.data_wid
, reset_less
=True)
384 m
.d
.comb
+= src1_or_z
.eq(Mux(op_is_z
, 0, srl
[0]))
386 # select either immediate or src2 if opcode says so
387 op_is_imm
= oper_r
.imm_data
.imm_ok
388 src2_or_imm
= Signal(self
.data_wid
, reset_less
=True)
389 m
.d
.comb
+= src2_or_imm
.eq(Mux(op_is_imm
, oper_r
.imm_data
.imm
, srl
[1]))
391 # now do the ALU addr add: one cycle, and say "ready" (next cycle, too)
392 sync
+= alu_o
.eq(src1_or_z
+ src2_or_imm
) # actual EA
393 sync
+= alu_ok
.eq(alu_valid
) # keep ack in sync with EA
395 # decode bits of operand (latched)
396 comb
+= op_is_st
.eq(oper_r
.insn_type
== MicrOp
.OP_STORE
) # ST
397 comb
+= op_is_ld
.eq(oper_r
.insn_type
== MicrOp
.OP_LOAD
) # LD
398 op_is_update
= oper_r
.ldst_mode
== LDSTMode
.update
# UPDATE
399 op_is_cix
= oper_r
.ldst_mode
== LDSTMode
.cix
# cache-inhibit
400 comb
+= self
.load_mem_o
.eq(op_is_ld
& self
.go_ad_i
)
401 comb
+= self
.stwd_mem_o
.eq(op_is_st
& self
.go_st_i
)
402 comb
+= self
.ld_o
.eq(op_is_ld
)
403 comb
+= self
.st_o
.eq(op_is_st
)
405 ############################
406 # Control Signal calculation
410 comb
+= self
.busy_o
.eq(opc_l
.q
) # | self.pi.busy_o) # busy out
412 # 1st operand read-request only when zero not active
413 # 2nd operand only needed when immediate is not active
414 slg
= Cat(op_is_z
, op_is_imm
)
415 bro
= Repl(self
.busy_o
, self
.n_src
)
416 comb
+= self
.rd
.rel_o
.eq(src_l
.q
& bro
& ~slg
& ~self
.rdmaskn
)
418 # note when the address-related read "go" signals are active
419 comb
+= rda_any
.eq(self
.rd
.go_i
[0] | self
.rd
.go_i
[1])
421 # alu input valid when 1st and 2nd ops done (or imm not active)
422 comb
+= alu_valid
.eq(busy_o
& ~
(self
.rd
.rel_o
[0] | self
.rd
.rel_o
[1]))
424 # 3rd operand only needed when operation is a store
425 comb
+= self
.rd
.rel_o
[2].eq(src_l
.q
[2] & busy_o
& op_is_st
)
427 # all reads done when alu is valid and 3rd operand needed
428 comb
+= rd_done
.eq(alu_valid
& ~self
.rd
.rel_o
[2])
430 # address release only if addr ready, but Port must be idle
431 comb
+= self
.adr_rel_o
.eq(alu_valid
& adr_l
.q
& busy_o
)
433 # store release when st ready *and* all operands read (and no shadow)
434 comb
+= self
.st
.rel_o
.eq(sto_l
.q
& busy_o
& rd_done
& op_is_st
&
437 # request write of LD result. waits until shadow is dropped.
438 comb
+= self
.wr
.rel_o
[0].eq(rd_done
& wri_l
.q
& busy_o
& lod_l
.qn
&
439 op_is_ld
& self
.shadown_i
)
441 # request write of EA result only in update mode
442 comb
+= self
.wr
.rel_o
[1].eq(upd_l
.q
& busy_o
& op_is_update
&
443 alu_valid
& self
.shadown_i
)
445 # provide "done" signal: select req_rel for non-LD/ST, adr_rel for LD/ST
446 comb
+= wr_any
.eq(self
.st
.go_i | p_st_go |
447 self
.wr
.go_i
[0] | self
.wr
.go_i
[1])
448 comb
+= wr_reset
.eq(rst_l
.q
& busy_o
& self
.shadown_i
&
449 ~
(self
.st
.rel_o | self
.wr
.rel_o
[0] |
451 (lod_l
.qn | op_is_st
))
452 comb
+= self
.done_o
.eq(wr_reset
)
454 ######################
455 # Data/Address outputs
457 # put the LD-output register directly onto the output bus on a go_write
458 comb
+= self
.data_o
.data
.eq(self
.dest
[0])
459 with m
.If(self
.wr
.go_i
[0]):
460 comb
+= self
.dest
[0].eq(ldd_r
)
462 # "update" mode, put address out on 2nd go-write
463 comb
+= self
.addr_o
.data
.eq(self
.dest
[1])
464 with m
.If(op_is_update
& self
.wr
.go_i
[1]):
465 comb
+= self
.dest
[1].eq(addr_r
)
467 # need to look like MultiCompUnit: put wrmask out.
468 # XXX may need to make this enable only when write active
469 comb
+= self
.wrmask
.eq(bro
& Cat(op_is_ld
, op_is_update
))
471 ###########################
472 # PortInterface connections
475 # connect to LD/ST PortInterface.
476 comb
+= pi
.is_ld_i
.eq(op_is_ld
& busy_o
) # decoded-LD
477 comb
+= pi
.is_st_i
.eq(op_is_st
& busy_o
) # decoded-ST
478 comb
+= pi
.data_len
.eq(self
.oper_i
.data_len
) # data_len
480 comb
+= pi
.addr
.data
.eq(addr_r
) # EA from adder
481 comb
+= pi
.addr
.ok
.eq(alu_ok
& lsd_l
.q
) # "do address stuff" (once)
482 comb
+= self
.addr_exc_o
.eq(pi
.addr_exc_o
) # exception occurred
483 comb
+= addr_ok
.eq(self
.pi
.addr_ok_o
) # no exc, address fine
486 with m
.If(self
.oper_i
.byte_reverse
):
487 # byte-reverse the data based on ld/st width (turn it to LE)
488 data_len
= self
.oper_i
.data_len
489 lddata_r
= byte_reverse(m
, 'lddata_r', pi
.ld
.data
, data_len
)
490 comb
+= ldd_o
.eq(lddata_r
) # put reversed- data out
492 comb
+= ldd_o
.eq(pi
.ld
.data
) # put data out, straight (as BE)
493 # ld - ld gets latched in via lod_l
494 comb
+= ld_ok
.eq(pi
.ld
.ok
) # ld.ok *closes* (freezes) ld data
497 op3
= srl
[2] # 3rd operand latch
498 with m
.If(self
.oper_i
.byte_reverse
):
499 # byte-reverse the data based on width
500 data_len
= self
.oper_i
.data_len
501 stdata_r
= byte_reverse(m
, 'stdata_r', op3
, data_len
)
502 comb
+= pi
.st
.data
.eq(stdata_r
)
504 comb
+= pi
.st
.data
.eq(op3
)
505 # store - data goes in based on go_st
506 comb
+= pi
.st
.ok
.eq(self
.st
.go_i
) # go store signals st data valid
510 def get_out(self
, i
):
511 """make LDSTCompUnit look like RegSpecALUAPI"""
516 # return self.dest[i]
518 def get_fu_out(self
, i
):
519 return self
.get_out(i
)
529 yield from self
.oper_i
.ports()
530 yield from self
.src_i
536 yield from self
.data_o
.ports()
537 yield from self
.addr_o
.ports()
538 yield self
.load_mem_o
539 yield self
.stwd_mem_o
545 def wait_for(sig
, wait
=True, test1st
=False):
547 print("wait for", sig
, v
, wait
, test1st
)
548 if test1st
and bool(v
) == wait
:
553 #print("...wait for", sig, v)
558 def store(dut
, src1
, src2
, src3
, imm
, imm_ok
=True, update
=False,
560 print("ST", src1
, src2
, src3
, imm
, imm_ok
, update
)
561 yield dut
.oper_i
.insn_type
.eq(MicrOp
.OP_STORE
)
562 yield dut
.oper_i
.data_len
.eq(2) # half-word
563 yield dut
.oper_i
.byte_reverse
.eq(byterev
)
564 yield dut
.src1_i
.eq(src1
)
565 yield dut
.src2_i
.eq(src2
)
566 yield dut
.src3_i
.eq(src3
)
567 yield dut
.oper_i
.imm_data
.imm
.eq(imm
)
568 yield dut
.oper_i
.imm_data
.imm_ok
.eq(imm_ok
)
569 yield dut
.oper_i
.update
.eq(update
)
570 yield dut
.issue_i
.eq(1)
572 yield dut
.issue_i
.eq(0)
578 # wait for all active rel signals to come up
580 rel
= yield dut
.rd
.rel_o
581 if rel
== active_rel
:
584 yield dut
.rd
.go
.eq(active_rel
)
586 yield dut
.rd
.go
.eq(0)
588 yield from wait_for(dut
.adr_rel_o
, False, test1st
=True)
589 # yield from wait_for(dut.adr_rel_o)
590 # yield dut.ad.go.eq(1)
592 # yield dut.ad.go.eq(0)
595 yield from wait_for(dut
.wr
.rel_o
[1])
596 yield dut
.wr
.go
.eq(0b10)
598 addr
= yield dut
.addr_o
600 yield dut
.wr
.go
.eq(0)
604 yield from wait_for(dut
.sto_rel_o
)
605 yield dut
.go_st_i
.eq(1)
607 yield dut
.go_st_i
.eq(0)
608 yield from wait_for(dut
.busy_o
, False)
609 # wait_for(dut.stwd_mem_o)
614 def load(dut
, src1
, src2
, imm
, imm_ok
=True, update
=False, zero_a
=False,
616 print("LD", src1
, src2
, imm
, imm_ok
, update
)
617 yield dut
.oper_i
.insn_type
.eq(MicrOp
.OP_LOAD
)
618 yield dut
.oper_i
.data_len
.eq(2) # half-word
619 yield dut
.oper_i
.byte_reverse
.eq(byterev
)
620 yield dut
.src1_i
.eq(src1
)
621 yield dut
.src2_i
.eq(src2
)
622 yield dut
.oper_i
.zero_a
.eq(zero_a
)
623 yield dut
.oper_i
.imm_data
.imm
.eq(imm
)
624 yield dut
.oper_i
.imm_data
.imm_ok
.eq(imm_ok
)
625 yield dut
.issue_i
.eq(1)
627 yield dut
.issue_i
.eq(0)
630 # set up read-operand flags
632 if not imm_ok
: # no immediate means RB register needs to be read
634 if not zero_a
: # no zero-a means RA needs to be read
637 # wait for the operands (RA, RB, or both)
639 yield dut
.rd
.go
.eq(rd
)
640 yield from wait_for(dut
.rd
.rel_o
)
641 yield dut
.rd
.go
.eq(0)
643 yield from wait_for(dut
.adr_rel_o
, False, test1st
=True)
644 # yield dut.ad.go.eq(1)
646 # yield dut.ad.go.eq(0)
649 yield from wait_for(dut
.wr
.rel_o
[1])
650 yield dut
.wr
.go
.eq(0b10)
652 addr
= yield dut
.addr_o
654 yield dut
.wr
.go
.eq(0)
658 yield from wait_for(dut
.wr
.rel_o
[0], test1st
=True)
659 yield dut
.wr
.go
.eq(1)
661 data
= yield dut
.data_o
663 yield dut
.wr
.go
.eq(0)
664 yield from wait_for(dut
.busy_o
)
666 # wait_for(dut.stwd_mem_o)
675 # two STs (different addresses)
676 yield from store(dut
, 4, 0, 3, 2) # ST reg4 into addr rfile[reg3]+2
677 yield from store(dut
, 2, 0, 9, 2) # ST reg4 into addr rfile[reg9]+2
679 # two LDs (deliberately LD from the 1st address then 2nd)
680 data
, addr
= yield from load(dut
, 4, 0, 2)
681 assert data
== 0x0003, "returned %x" % data
682 data
, addr
= yield from load(dut
, 2, 0, 2)
683 assert data
== 0x0009, "returned %x" % data
687 yield from store(dut
, 9, 5, 3, 0, imm_ok
=False)
688 data
, addr
= yield from load(dut
, 9, 5, 0, imm_ok
=False)
689 assert data
== 0x0003, "returned %x" % data
691 # update-immediate version
692 addr
= yield from store(dut
, 9, 6, 3, 2, update
=True)
693 assert addr
== 0x000b, "returned %x" % addr
695 # update-indexed version
696 data
, addr
= yield from load(dut
, 9, 5, 0, imm_ok
=False, update
=True)
697 assert data
== 0x0003, "returned %x" % data
698 assert addr
== 0x000e, "returned %x" % addr
700 # immediate *and* zero version
701 data
, addr
= yield from load(dut
, 1, 4, 8, imm_ok
=True, zero_a
=True)
702 assert data
== 0x0008, "returned %x" % data
705 class TestLDSTCompUnit(LDSTCompUnit
):
707 def __init__(self
, rwid
):
708 from soc
.experiment
.l0_cache
import TstL0CacheBuffer
709 self
.l0
= l0
= TstL0CacheBuffer()
710 pi
= l0
.l0
.dports
[0].pi
711 LDSTCompUnit
.__init
__(self
, pi
, rwid
, 4)
713 def elaborate(self
, platform
):
714 m
= LDSTCompUnit
.elaborate(self
, platform
)
715 m
.submodules
.l0
= self
.l0
716 m
.d
.comb
+= self
.ad
.go
.eq(self
.ad
.rel
) # link addr-go direct to rel
720 def test_scoreboard():
722 dut
= TestLDSTCompUnit(16)
723 vl
= rtlil
.convert(dut
, ports
=dut
.ports())
724 with
open("test_ldst_comp.il", "w") as f
:
727 run_simulation(dut
, ldst_sim(dut
), vcd_name
='test_ldst_comp.vcd')
730 class TestLDSTCompUnitRegSpec(LDSTCompUnit
):
733 from soc
.experiment
.l0_cache
import TstL0CacheBuffer
734 from soc
.fu
.ldst
.pipe_data
import LDSTPipeSpec
735 regspec
= LDSTPipeSpec
.regspec
736 self
.l0
= l0
= TstL0CacheBuffer()
737 pi
= l0
.l0
.dports
[0].pi
738 LDSTCompUnit
.__init
__(self
, pi
, regspec
, 4)
740 def elaborate(self
, platform
):
741 m
= LDSTCompUnit
.elaborate(self
, platform
)
742 m
.submodules
.l0
= self
.l0
743 m
.d
.comb
+= self
.ad
.go
.eq(self
.ad
.rel
) # link addr-go direct to rel
747 def test_scoreboard_regspec():
749 dut
= TestLDSTCompUnitRegSpec()
750 vl
= rtlil
.convert(dut
, ports
=dut
.ports())
751 with
open("test_ldst_comp.il", "w") as f
:
754 run_simulation(dut
, ldst_sim(dut
), vcd_name
='test_ldst_regspec.vcd')
757 if __name__
== '__main__':
758 test_scoreboard_regspec()