from collections import namedtuple
from copy import deepcopy
from functools import wraps
+import os
+import sys
+from elftools.elf.elffile import ELFFile # for isinstance
from nmigen.sim import Settle
+import openpower.syscalls
from openpower.consts import (MSRb, PIb, # big-endian (PowerISA versions)
SVP64CROffs, SVP64MODEb)
from openpower.decoder.helpers import (ISACallerHelper, ISAFPHelpers, exts,
- gtu, undefined)
-from openpower.decoder.isa.mem import Mem, MemException
+ gtu, undefined, copy_assign_rhs)
+from openpower.decoder.isa.mem import Mem, MemMMap, MemException, LoadedELF
from openpower.decoder.isa.radixmmu import RADIX
from openpower.decoder.isa.svshape import SVSHAPE
from openpower.decoder.isa.svstate import SVP64State
from openpower.decoder.selectable_int import (FieldSelectableInt,
SelectableInt, selectconcat,
EFFECTIVELY_UNLIMITED)
+from openpower.consts import DEFAULT_MSR
from openpower.fpscr import FPSCRState
from openpower.xer import XERState
-from openpower.util import LogKind, log
+from openpower.util import LogType, log
LDST_UPDATE_INSNS = ['ldu', 'lwzu', 'lbzu', 'lhzu', 'lhau', 'lfsu', 'lfdu',
'stwu', 'stbu', 'sthu', 'stfsu', 'stfdu', 'stdu',
return retval
+def create_full_args(*, read_regs, special_regs, uninit_regs, write_regs,
+ extra=None):
+ return create_args([
+ *read_regs, *uninit_regs, *write_regs, *special_regs], extra=extra)
+
+
class GPR(dict):
def __init__(self, decoder, isacaller, svstate, regfile):
dict.__init__(self)
rnum = rnum.value
dict.__setitem__(self, rnum, value)
- def getz(self, rnum):
+ def getz(self, rnum, rvalue=None):
# rnum = rnum.value # only SelectableInt allowed
- log("GPR getzero?", rnum)
+ log("GPR getzero?", rnum, rvalue)
+ if rvalue is not None:
+ if rnum == 0:
+ return SelectableInt(0, rvalue.bits)
+ return rvalue
if rnum == 0:
return SelectableInt(0, 64)
return self[rnum]
for j in range(8):
s.append("%08x" % res[i+j])
s = ' '.join(s)
- print("reg", "%2d" % i, s)
+ log("reg", "%2d" % i, s, kind=LogType.InstrInOuts)
return res
class SPR(dict):
- def __init__(self, dec2, initial_sprs={}):
+ def __init__(self, dec2, initial_sprs={}, gpr=None):
self.sd = dec2
+ self.gpr = gpr # for SVSHAPE[0-3]
dict.__init__(self)
for key, v in initial_sprs.items():
if isinstance(key, SelectableInt):
self.__setitem__('SRR1', value)
if key == 1:
value = XERState(value)
+ if key in ('SVSHAPE0', 'SVSHAPE1', 'SVSHAPE2', 'SVSHAPE3'):
+ value = SVSHAPE(value, self.gpr)
log("setting spr", key, value)
dict.__setitem__(self, key, value)
if RC1:
log("get_cr_out RC1 mode")
if name == 'CR0':
- return 0, True # XXX TODO: offset CR0 from SVSTATE SPR
+ return 0, True # XXX TODO: offset CR0 from SVSTATE SPR
if name == 'CR1':
- return 1, True # XXX TODO: offset CR1 from SVSTATE SPR
+ return 1, True # XXX TODO: offset CR1 from SVSTATE SPR
# nope - not found.
log("get_cr_out not found", name)
return None, False
log(" new dststep", dststep)
+class ExitSyscallCalled(Exception):
+ pass
+
+
+class SyscallEmulator(openpower.syscalls.Dispatcher):
+ def __init__(self, isacaller):
+ self.__isacaller = isacaller
+
+ host = os.uname().machine
+ bits = (64 if (sys.maxsize > (2**32)) else 32)
+ host = openpower.syscalls.architecture(arch=host, bits=bits)
+
+ return super().__init__(guest="ppc64", host=host)
+
+ def __call__(self, identifier, *arguments):
+ (identifier, *arguments) = map(int, (identifier, *arguments))
+ return super().__call__(identifier, *arguments)
+
+ def sys_exit_group(self, status, *rest):
+ self.__isacaller.halted = True
+ raise ExitSyscallCalled(status)
+
+ def sys_write(self, fd, buf, count, *rest):
+ buf = self.__isacaller.mem.get_ctypes(buf, count, is_write=False)
+ try:
+ return os.write(fd, buf)
+ except OSError as e:
+ return -e.errno
+
+
class ISACaller(ISACallerHelper, ISAFPHelpers, StepLoop):
# decoder2 - an instance of power_decoder2
# regfile - a list of initial values for the registers
mmu=False,
icachemmu=False,
initial_fpscr=0,
- insnlog=None):
+ insnlog=None,
+ use_mmap_mem=False,
+ use_syscall_emu=False,
+ emulating_mmap=False):
+ if use_syscall_emu:
+ self.syscall = SyscallEmulator(isacaller=self)
+ if not use_mmap_mem:
+ log("forcing use_mmap_mem due to use_syscall_emu active")
+ use_mmap_mem = True
+ else:
+ self.syscall = None
+
+ # we will eventually be able to load ELF files without use_syscall_emu
+ # (e.g. the linux kernel), so do it in a separate if block
+ if isinstance(initial_insns, ELFFile):
+ if not use_mmap_mem:
+ log("forcing use_mmap_mem due to loading an ELF file")
+ use_mmap_mem = True
+ if not emulating_mmap:
+ log("forcing emulating_mmap due to loading an ELF file")
+ emulating_mmap = True
# trace log file for model output. if None do nothing
self.insnlog = insnlog
if initial_insns is None:
initial_insns = {}
assert self.respect_pc == False, "instructions required to honor pc"
+ if initial_msr is None:
+ initial_msr = DEFAULT_MSR
log("ISACaller insns", respect_pc, initial_insns, disassembly)
log("ISACaller initial_msr", initial_msr)
initial_sprs = deepcopy(initial_sprs) # so as not to get modified
self.gpr = GPR(decoder2, self, self.svstate, regfile)
self.fpr = GPR(decoder2, self, self.svstate, fpregfile)
- self.spr = SPR(decoder2, initial_sprs) # initialise SPRs before MMU
+ # initialise SPRs before MMU
+ self.spr = SPR(decoder2, initial_sprs, gpr=self.gpr)
# set up 4 dummy SVSHAPEs if they aren't already set up
for i in range(4):
sname = 'SVSHAPE%d' % i
val = self.spr.get(sname, 0)
- # make sure it's an SVSHAPE
- self.spr[sname] = SVSHAPE(val, self.gpr)
+ # make sure it's an SVSHAPE -- conversion done by SPR.__setitem__
+ self.spr[sname] = val
self.last_op_svshape = False
# "raw" memory
- self.mem = Mem(row_bytes=8, initial_mem=initial_mem, misaligned_ok=True)
- self.mem.log_fancy(kind=LogKind.InstrInOuts)
- self.imem = Mem(row_bytes=4, initial_mem=initial_insns)
+ if use_mmap_mem:
+ self.mem = MemMMap(row_bytes=8,
+ initial_mem=initial_mem,
+ misaligned_ok=True,
+ emulating_mmap=emulating_mmap)
+ self.imem = self.mem
+ lelf = self.mem.initialize(row_bytes=4, initial_mem=initial_insns)
+ if isinstance(lelf, LoadedELF): # stuff parsed from ELF
+ initial_pc = lelf.pc
+ for k, v in lelf.gprs.items():
+ self.gpr[k] = SelectableInt(v, 64)
+ initial_fpscr = lelf.fpscr
+ self.mem.log_fancy(kind=LogType.InstrInOuts)
+ else:
+ self.mem = Mem(row_bytes=8, initial_mem=initial_mem,
+ misaligned_ok=True)
+ self.mem.log_fancy(kind=LogType.InstrInOuts)
+ self.imem = Mem(row_bytes=4, initial_mem=initial_insns)
# MMU mode, redirect underlying Mem through RADIX
if mmu:
self.mem = RADIX(self.mem, self)
super().__init__(XLEN=self.namespace["XLEN"], FPSCR=self.fpscr)
def trace(self, out):
- if self.insnlog is None: return
+ if self.insnlog is None:
+ return
self.insnlog.write(out)
@property
TRAP function is callable from inside the pseudocode itself,
hence the default arguments. when calling from inside ISACaller
it is best to use call_trap()
+
+ trap_addr: int | SelectableInt
+ the address to go to (before any modifications from `KAIVB`)
+ trap_bit: int | None
+ the bit in `SRR1` to set, `None` means don't set any bits.
"""
+ if isinstance(trap_addr, SelectableInt):
+ trap_addr = trap_addr.value
# https://bugs.libre-soc.org/show_bug.cgi?id=859
kaivb = self.spr['KAIVB'].value
msr = self.namespace['MSR'].value
if self.is_svp64_mode:
self.spr['SVSRR0'] = self.namespace['SVSTATE'].value
self.trap_nia = SelectableInt(trap_addr | (kaivb & ~0x1fff), 64)
- self.spr['SRR1'][trap_bit] = 1 # change *copy* of MSR in SRR1
+ if trap_bit is not None:
+ self.spr['SRR1'][trap_bit] = 1 # change *copy* of MSR in SRR1
# set exception bits. TODO: this should, based on the address
# in figure 66 p1065 V3.0B and the table figure 65 p1063 set these
self.cr_backup = self.cr.value
# sv.bc* need some extra fields
- if self.is_svp64_mode and insn_name.startswith("sv.bc"):
- # blegh grab bits manually
- mode = yield self.dec2.rm_dec.rm_in.mode
- # convert to SelectableInt before test
- mode = SelectableInt(mode, 5)
- bc_vlset = mode[SVP64MODEb.BC_VLSET] != 0
- bc_vli = mode[SVP64MODEb.BC_VLI] != 0
- bc_snz = mode[SVP64MODEb.BC_SNZ] != 0
- bc_vsb = yield self.dec2.rm_dec.bc_vsb
- bc_lru = yield self.dec2.rm_dec.bc_lru
- bc_gate = yield self.dec2.rm_dec.bc_gate
- sz = yield self.dec2.rm_dec.pred_sz
- self.namespace['mode'] = SelectableInt(mode, 5)
- self.namespace['ALL'] = SelectableInt(bc_gate, 1)
- self.namespace['VSb'] = SelectableInt(bc_vsb, 1)
- self.namespace['LRu'] = SelectableInt(bc_lru, 1)
- self.namespace['VLSET'] = SelectableInt(bc_vlset, 1)
- self.namespace['VLI'] = SelectableInt(bc_vli, 1)
- self.namespace['sz'] = SelectableInt(sz, 1)
- self.namespace['SNZ'] = SelectableInt(bc_snz, 1)
+ if not self.is_svp64_mode or not insn_name.startswith("sv.bc"):
+ return
+
+ # blegh grab bits manually
+ mode = yield self.dec2.rm_dec.rm_in.mode
+ # convert to SelectableInt before test
+ mode = SelectableInt(mode, 5)
+ bc_vlset = mode[SVP64MODEb.BC_VLSET] != 0
+ bc_vli = mode[SVP64MODEb.BC_VLI] != 0
+ bc_snz = mode[SVP64MODEb.BC_SNZ] != 0
+ bc_vsb = yield self.dec2.rm_dec.bc_vsb
+ bc_ctrtest = yield self.dec2.rm_dec.bc_ctrtest
+ bc_lru = yield self.dec2.rm_dec.bc_lru
+ bc_gate = yield self.dec2.rm_dec.bc_gate
+ sz = yield self.dec2.rm_dec.pred_sz
+ self.namespace['mode'] = SelectableInt(mode, 5)
+ self.namespace['ALL'] = SelectableInt(bc_gate, 1)
+ self.namespace['VSb'] = SelectableInt(bc_vsb, 1)
+ self.namespace['LRu'] = SelectableInt(bc_lru, 1)
+ self.namespace['CTRtest'] = SelectableInt(bc_ctrtest, 1)
+ self.namespace['VLSET'] = SelectableInt(bc_vlset, 1)
+ self.namespace['VLI'] = SelectableInt(bc_vli, 1)
+ self.namespace['sz'] = SelectableInt(sz, 1)
+ self.namespace['SNZ'] = SelectableInt(bc_snz, 1)
def get_kludged_op_add_ca_ov(self, inputs, inp_ca_ov):
""" this was not at all necessary to do. this function massively
return ca64, ca32, ov64, ov32
def handle_carry_(self, inputs, output, ca, ca32, inp_ca_ov):
+ if ca is not None and ca32 is not None:
+ return
op = yield self.dec2.e.do.insn_type
if op == MicrOp.OP_ADD.value and ca is None and ca32 is None:
retval = yield from self.get_kludged_op_add_ca_ov(
# TODO: if 32-bit mode, set ov to ov32
self.spr['XER'][XER_bits['OV']] = ov
self.spr['XER'][XER_bits['OV32']] = ov32
+ log(f"write OV/OV32 OV={ov} OV32={ov32}",
+ kind=LogType.InstrInOuts)
else:
# TODO: if 32-bit mode, set ca to ca32
self.spr['XER'][XER_bits['CA']] = ca
self.spr['XER'][XER_bits['CA32']] = ca32
+ log(f"write CA/CA32 CA={ca} CA32={ca32}",
+ kind=LogType.InstrInOuts)
return
inv_a = yield self.dec2.e.do.invert_in
if inv_a:
else:
SO = self.spr['XER'][XER_bits['SO']]
log("handle_comparison SO", SO.value,
- "overflow", overflow,
- "zero", zero.value,
- "+ve", positive.value,
- "-ve", negative.value)
+ "overflow", overflow,
+ "zero", zero.value,
+ "+ve", positive.value,
+ "-ve", negative.value)
# alternative overflow checking (setvl mainly at the moment)
if overflow is not None and overflow == 1:
SO = SelectableInt(1, 1)
dec_insn = yield self.dec2.e.do.insn
return dec_insn & (1 << 20) != 0 # sigh - XFF.spr[-1]?
- def call(self, name):
+ def call(self, name, syscall_emu_active=False):
"""call(opcode) - the primary execution point for instructions
"""
self.last_st_addr = None # reset the last known store address
# TODO, asmregs is from the spec, e.g. add RT,RA,RB
# see http://bugs.libre-riscv.org/show_bug.cgi?id=282
asmop = yield from self.get_assembly_name()
- log("call", ins_name, asmop)
+ log("call", ins_name, asmop,
+ kind=LogType.InstrInOuts)
# sv.setvl is *not* a loop-function. sigh
log("is_svp64_mode", self.is_svp64_mode, asmop)
self.halted = True
return
+ # User mode system call emulation consists of several steps:
+ # 1. Detect whether instruction is sc or scv.
+ # 2. Call the HDL implementation which invokes trap.
+ # 3. Reroute the guest system call to host system call.
+ # 4. Force return from the interrupt as if we had guest OS.
+ if ((asmop in ("sc", "scv")) and
+ (self.syscall is not None) and
+ not syscall_emu_active):
+ # Memoize PC and trigger an interrupt
+ if self.respect_pc:
+ pc = self.pc.CIA.value
+ else:
+ pc = self.fake_pc
+ yield from self.call(asmop, syscall_emu_active=True)
+
+ # Reroute the syscall to host OS
+ identifier = self.gpr(0)
+ arguments = map(self.gpr, range(3, 9))
+ result = self.syscall(identifier, *arguments)
+ self.gpr.write(3, result, False, self.namespace["XLEN"])
+
+ # Return from interrupt
+ yield from self.call("rfid", syscall_emu_active=True)
+ return
+ elif ((name in ("rfid", "hrfid")) and syscall_emu_active):
+ asmop = "rfid"
+
# check illegal instruction
illegal = False
if ins_name not in ['mtcrf', 'mtocrf']:
"brh", "brw", "brd",
'setvl', 'svindex', 'svremap', 'svstep',
'svshape', 'svshape2',
- 'ternlogi', 'bmask', 'cprop',
+ 'ternlogi', 'bmask', 'cprop', 'gbbd',
'absdu', 'absds', 'absdacs', 'absdacu', 'avgadd',
'fmvis', 'fishmv', 'pcdec', "maddedu", "divmod2du",
"dsld", "dsrd", "maddedus",
illegal = False
ins_name = dotstrp
+ # match against instructions treated as nop, see nop below
+ if asmop.startswith("dcbt"):
+ illegal = False
+ ins_name = "nop"
+
# branch-conditional redirects to sv.bc
if asmop.startswith('bc') and self.is_svp64_mode:
ins_name = 'sv.%s' % ins_name
ew_src = 8 << (3-int(ew_src)) # convert to bitlength
ew_dst = 8 << (3-int(ew_dst)) # convert to bitlength
xlen = max(ew_src, ew_dst)
- log("elwdith", ew_src, ew_dst)
+ log("elwidth", ew_src, ew_dst)
log("XLEN:", self.is_svp64_mode, xlen)
# look up instruction in ISA.instrs, prepare namespace
yield from self.prep_namespace(ins_name, info.form, info.op_fields,
xlen)
+ # dict retains order
+ inputs = dict.fromkeys(create_full_args(
+ read_regs=info.read_regs, special_regs=info.special_regs,
+ uninit_regs=info.uninit_regs, write_regs=info.write_regs))
+
# preserve order of register names
- input_names = create_args(list(info.read_regs) +
- list(info.uninit_regs))
+ write_without_special_regs = OrderedSet(info.write_regs)
+ write_without_special_regs -= OrderedSet(info.special_regs)
+ input_names = create_args([
+ *info.read_regs, *info.uninit_regs, *write_without_special_regs])
log("input names", input_names)
# get SVP64 entry for the current instruction
if self.is_svp64_mode and vl == 0:
self.pc.update(self.namespace, self.is_svp64_mode)
log("SVP64: VL=0, end of call", self.namespace['CIA'],
- self.namespace['NIA'], kind=LogKind.InstrInOuts)
+ self.namespace['NIA'], kind=LogType.InstrInOuts)
return
# for when SVREMAP is active, using pre-arranged schedule.
remap_active = yield self.dec2.remap_active
else:
remap_active = False
- log("remap active", bin(remap_active))
+ log("remap active", bin(remap_active), self.is_svp64_mode)
+
+ # LDST does *not* allow elwidth overrides on RA (Effective Address).
+ # this has to be detected. XXX TODO: RB for ldst-idx *may* need
+ # conversion (to 64-bit) also.
+ # see write reg this *HAS* to also override XLEN to 64 on LDST/Update
+ sv_mode = yield self.dec2.rm_dec.sv_mode
+ is_ldst = (sv_mode in [SVMode.LDST_IDX.value, SVMode.LDST_IMM.value] \
+ and self.is_svp64_mode)
+ log("is_ldst", sv_mode, is_ldst)
# main input registers (RT, RA ...)
- inputs = []
for name in input_names:
- regval = (yield from self.get_input(name, ew_src))
- log("regval name", name, regval)
- inputs.append(regval)
+ if name == "overflow":
+ inputs[name] = SelectableInt(0, 1)
+ elif name == "FPSCR":
+ inputs[name] = self.FPSCR
+ elif name in ("CA", "CA32", "OV", "OV32"):
+ inputs[name] = self.spr['XER'][XER_bits[name]]
+ elif name in "CR0":
+ inputs[name] = self.crl[0]
+ elif name in spr_byname:
+ inputs[name] = self.spr[name]
+ elif is_ldst and name == 'RA':
+ regval = (yield from self.get_input(name, ew_src, 64))
+ log("EA (RA) regval name", name, regval)
+ inputs[name] = regval
+ else:
+ regval = (yield from self.get_input(name, ew_src, xlen))
+ log("regval name", name, regval)
+ inputs[name] = regval
# arrrrgh, awful hack, to get _RT into namespace
if ins_name in ['setvl', 'svstep']:
# "special" registers
for special in info.special_regs:
if special in special_sprs:
- inputs.append(self.spr[special])
+ inputs[special] = self.spr[special]
else:
- inputs.append(self.namespace[special])
+ inputs[special] = self.namespace[special]
# clear trap (trap) NIA
self.trap_nia = None
# check if this was an sv.bc* and create an indicator that
# this is the last check to be made as a loop. combined with
- # the ALL/ANY mode we can early-exit
+ # the ALL/ANY mode we can early-exit. note that BI (to test)
+ # is an input so there is no termination if BI is scalar
+ # (because early-termination is for *output* scalars)
if self.is_svp64_mode and ins_name.startswith("sv.bc"):
- no_in_vec = yield self.dec2.no_in_vec # BI is scalar
- end_loop = no_in_vec or srcstep == vl-1 or dststep == vl-1
+ end_loop = srcstep == vl-1 or dststep == vl-1
self.namespace['end_loop'] = SelectableInt(end_loop, 1)
inp_ca_ov = (self.spr['XER'][XER_bits['CA']].value,
self.spr['XER'][XER_bits['OV']].value)
+ for k, v in inputs.items():
+ if v is None:
+ v = SelectableInt(0, self.XLEN)
+ # prevent pseudo-code from modifying input registers
+ v = copy_assign_rhs(v)
+ if isinstance(v, SelectableInt):
+ v.ok = False
+ inputs[k] = v
+
# execute actual instruction here (finally)
log("inputs", inputs)
+ inputs = list(inputs.values())
results = info.func(self, *inputs)
output_names = create_args(info.write_regs)
outs = {}
+ # record .ok before anything after the pseudo-code can modify it
+ outs_ok = {}
for out, n in zip(results or [], output_names):
outs[n] = out
+ outs_ok[n] = True
+ if isinstance(out, SelectableInt):
+ outs_ok[n] = out.ok
log("results", outs)
+ log("results ok", outs_ok)
# "inject" decorator takes namespace from function locals: we need to
# overwrite NIA being overwritten (sigh)
# XXX TODO: now that CR0 is supported, sort out svstep's pseudocode
# to write directly to CR0 instead of in ISACaller. hooyahh.
if rc_en and ins_name not in ['svstep']:
+ if outs_ok.get('FPSCR', False):
+ FPSCR = outs['FPSCR']
+ else:
+ FPSCR = self.FPSCR
yield from self.do_rc_ov(
- ins_name, results[0], overflow, cr0, cr1, output_names)
+ ins_name, results[0], overflow, cr0, cr1, FPSCR)
# check failfirst
ffirst_hit = False, False
sv_mode = yield self.dec2.rm_dec.sv_mode
is_cr = sv_mode == SVMode.CROP.value
chk = rc_en or is_cr
+ if outs_ok.get('CR', False):
+ # early write so check_ffirst can see value
+ self.namespace['CR'].eq(outs['CR'])
ffirst_hit = (yield from self.check_ffirst(info, chk, srcstep))
+ # any modified return results?
+ yield from self.do_outregs(
+ info, outs, carry_en, ffirst_hit, ew_dst, outs_ok)
+
# check if a FP Exception occurred. TODO for DD-FFirst, check VLi
# and raise the exception *after* if VLi=1 but if VLi=0 then
- # truncate and make the exception "disappear".
+ # truncate and make the exception "disappear".
if self.FPSCR.FEX and (self.msr[MSRb.FE0] or self.msr[MSRb.FE1]):
self.call_trap(0x700, PIb.FP)
return
- # any modified return results?
- yield from self.do_outregs_nia(asmop, ins_name, info, outs,
- carry_en, rc_en, ffirst_hit, ew_dst)
+ yield from self.do_nia(asmop, ins_name, rc_en, ffirst_hit)
def check_ffirst(self, info, rc_en, srcstep):
"""fail-first mode: checks a bit of Rc Vector, truncates VL
yield Settle() # let decoder update
return True, vli_
- def do_rc_ov(self, ins_name, result, overflow, cr0, cr1, output_names):
+ def do_rc_ov(self, ins_name, result, overflow, cr0, cr1, FPSCR):
cr_out = yield self.dec2.op.cr_out
if cr_out == CROutSel.CR1.value:
rc_reg = "CR1"
is_setvl = ins_name in ('svstep', 'setvl')
if is_setvl:
result = SelectableInt(result.vl, 64)
- #else:
+ # else:
# overflow = None # do not override overflow except in setvl
if rc_reg == "CR1":
if cr1 is None:
- cr1 = int(self.FPSCR.FX) << 3
- cr1 |= int(self.FPSCR.FEX) << 2
- cr1 |= int(self.FPSCR.VX) << 1
- cr1 |= int(self.FPSCR.OX)
+ cr1 = int(FPSCR.FX) << 3
+ cr1 |= int(FPSCR.FEX) << 2
+ cr1 |= int(FPSCR.VX) << 1
+ cr1 |= int(FPSCR.OX)
log("default fp cr1", cr1)
else:
log("explicit cr1", cr1)
log("explicit rc0", cr0)
self.crl[regnum].eq(cr0)
- def do_outregs_nia(self, asmop, ins_name, info, outs,
- ca_en, rc_en, ffirst_hit, ew_dst):
+ def do_outregs(self, info, outs, ca_en, ffirst_hit, ew_dst, outs_ok):
ffirst_hit, vli = ffirst_hit
# write out any regs for this instruction, but only if fail-first is ok
# XXX TODO: allow CR-vector to be written out even if ffirst fails
if not ffirst_hit or vli:
for name, output in outs.items():
+ if not outs_ok[name]:
+ log("skipping writing output with .ok=False", name, output)
+ continue
yield from self.check_write(info, name, output, ca_en, ew_dst)
# restore the CR value on non-VLI failfirst (from sv.cmp and others
# which write directly to CR in the pseudocode (gah, what a mess)
# if ffirst_hit and not vli:
# self.cr.value = self.cr_backup
+ def do_nia(self, asmop, ins_name, rc_en, ffirst_hit):
+ ffirst_hit, vli = ffirst_hit
if ffirst_hit:
self.svp64_reset_loop()
nia_update = True
else:
# check advancement of src/dst/sub-steps and if PC needs updating
- nia_update = (yield from self.check_step_increment(rc_en,
- asmop, ins_name))
+ nia_update = (yield from self.check_step_increment(
+ rc_en, asmop, ins_name))
if nia_update:
self.update_pc_next()
else:
self.namespace['D'] = imm
- def get_input(self, name, ew_src):
+ def get_input(self, name, ew_src, xlen):
# using PowerDecoder2, first, find the decoder index.
# (mapping name RA RB RC RS to in1, in2, in3)
regnum, is_vec = yield from get_idx_in(self.dec2, name, True)
regname = "_" + name
if not self.is_svp64_mode or ew_src == 64:
self.namespace[regname] = regnum
- elif regname in self.namespace:
- del self.namespace[regname]
+ else:
+ # FIXME: we're trying to access a sub-register, plain register
+ # numbers don't work for that. for now, just pass something that
+ # can be compared to 0 and probably will cause an error if misused.
+ # see https://bugs.libre-soc.org/show_bug.cgi?id=1221
+ self.namespace[regname] = regnum * 10000
if not self.is_svp64_mode or not self.pred_src_zero:
log('reading reg %s %s' % (name, str(regnum)), is_vec)
if name in fregs:
- reg_val = SelectableInt(self.fpr(base, is_vec, offs, ew_src))
- log("read reg %d/%d: 0x%x" % (base, offs, reg_val.value))
+ fval = self.fpr(base, is_vec, offs, ew_src)
+ reg_val = SelectableInt(fval)
+ assert ew_src == XLEN, "TODO fix elwidth conversion"
self.trace("r:FPR:%d:%d:%d " % (base, offs, ew_src))
+ log("read fp reg %d/%d: 0x%x" % (base, offs, reg_val.value),
+ kind=LogType.InstrInOuts)
elif name is not None:
- reg_val = SelectableInt(self.gpr(base, is_vec, offs, ew_src))
+ gval = self.gpr(base, is_vec, offs, ew_src)
+ reg_val = SelectableInt(gval.value, bits=xlen)
self.trace("r:GPR:%d:%d:%d " % (base, offs, ew_src))
- log("read reg %d/%d: 0x%x" % (base, offs, reg_val.value))
+ log("read int reg %d/%d: 0x%x" % (base, offs, reg_val.value),
+ kind=LogType.InstrInOuts)
else:
log('zero input reg %s %s' % (name, str(regnum)), is_vec)
reg_val = SelectableInt(0, ew_src)
# write special SPRs
if name in info.special_regs:
log('writing special %s' % name, output, special_sprs)
- log("write reg %s 0x%x" % (name, output.value))
+ log("write reg %s 0x%x" % (name, output.value),
+ kind=LogType.InstrInOuts)
if name in special_sprs:
self.spr[name] = output
else:
output = SelectableInt(0, EFFECTIVELY_UNLIMITED)
log("write reg %s%s 0x%x ew %d" % (reg_prefix, str(regnum),
output.value, ew_dst),
- kind=LogKind.InstrInOuts)
+ kind=LogType.InstrInOuts)
# zero-extend tov64 bit begore storing (should use EXT oh well)
if output.bits > 64:
output = SelectableInt(output.value, 64)
if name in fregs:
self.fpr.write(regnum, output, is_vec, ew_dst)
self.trace("w:FPR:%d:%d:%d " % (rnum, offset, ew_dst))
- else:
- self.gpr.write(regnum, output, is_vec, ew_dst)
- self.trace("w:GPR:%d:%d:%d " % (rnum, offset, ew_dst))
+ return
+
+ # LDST/Update does *not* allow elwidths on RA (Effective Address).
+ # this has to be detected, and overridden. see get_input (related)
+ sv_mode = yield self.dec2.rm_dec.sv_mode
+ is_ldst = (sv_mode in [SVMode.LDST_IDX.value, SVMode.LDST_IMM.value] \
+ and self.is_svp64_mode)
+ if is_ldst and name in ['EA', 'RA']:
+ op = self.dec2.dec.op
+ if hasattr(op, "upd"):
+ # update mode LD/ST uses read-reg A also as an output
+ upd = yield op.upd
+ log("write is_ldst is_update", sv_mode, is_ldst, upd)
+ if upd == LDSTMode.update.value:
+ ew_dst = 64 # override for RA (EA) to 64-bit
+
+ self.gpr.write(regnum, output, is_vec, ew_dst)
+ self.trace("w:GPR:%d:%d:%d " % (rnum, offset, ew_dst))
def check_step_increment(self, rc_en, asmop, ins_name):
# check if it is the SVSTATE.src/dest step that needs incrementing
vfirst = self.svstate.vfirst
log(" SV Vertical First", vf, vfirst)
if not vf and vfirst == 1:
+ if insn_name.startswith("sv.bc"):
+ self.update_pc_next()
+ return False
self.update_nia()
return True
# not an SVP64 branch, so fix PC (NIA==CIA) for next loop
# (by default, NIA is CIA+4 if v3.0B or CIA+8 if SVP64)
# this way we keep repeating the same instruction (with new steps)
- self.pc.NIA.value = self.pc.CIA.value
+ self.pc.NIA.eq(self.pc.CIA)
self.namespace['NIA'] = self.pc.NIA
log("end of sub-pc call", self.namespace['CIA'], self.namespace['NIA'])
return False # DO NOT allow PC update whilst Sub-PC loop running