* https://bugs.libre-soc.org/show_bug.cgi?id=424
"""
+import re
from nmigen.back.pysim import Settle
from functools import wraps
-from copy import copy
+from copy import copy, deepcopy
from openpower.decoder.orderedset import OrderedSet
-from openpower.decoder.selectable_int import (FieldSelectableInt, SelectableInt,
- selectconcat)
+from openpower.decoder.selectable_int import (
+ SelectableIntMapping,
+ FieldSelectableInt,
+ SelectableInt,
+ selectconcat,
+)
from openpower.decoder.power_enums import (spr_dict, spr_byname, XER_bits,
- insns, MicrOp, In1Sel, In2Sel, In3Sel,
- OutSel, CROutSel, LDSTMode,
- SVP64RMMode, SVP64PredMode,
- SVP64PredInt, SVP64PredCR,
- SVP64LDSTmode)
+ insns, MicrOp,
+ In1Sel, In2Sel, In3Sel,
+ OutSel, CRInSel, CROutSel, LDSTMode,
+ SVP64RMMode, SVP64PredMode,
+ SVP64PredInt, SVP64PredCR,
+ SVP64LDSTmode)
from openpower.decoder.power_enums import SVPtype
-from openpower.decoder.helpers import (exts, gtu, ltu, undefined, bitrev)
+from openpower.decoder.helpers import (exts, gtu, ltu, undefined,
+ ISACallerHelper, ISAFPHelpers)
from openpower.consts import PIb, MSRb # big-endian (PowerISA versions)
-from openpower.consts import SVP64CROffs
+from openpower.consts import (SVP64MODE,
+ SVP64CROffs,
+ )
from openpower.decoder.power_svp64 import SVP64RM, decode_extra
from openpower.decoder.isa.radixmmu import RADIX
from openpower.decoder.isa.mem import Mem, swap_order, MemException
+from openpower.decoder.isa.svshape import SVSHAPE
+from openpower.decoder.isa.svstate import SVP64State
+
from openpower.util import log
"RB": 0,
"RC": 0,
"RS": 0,
+ "BI": 0,
"CR": 0,
"LR": 0,
"CTR": 0,
"TAR": 0,
"MSR": 0,
"SVSTATE": 0,
+ "SVSHAPE0": 0,
+ "SVSHAPE1": 0,
+ "SVSHAPE2": 0,
+ "SVSHAPE3": 0,
"CA": 0,
"CA32": 0,
- "overflow": 7, # should definitely be last
+ "overflow": 7, # should definitely be last
}
fregs = ['FRA', 'FRB', 'FRC', 'FRS', 'FRT']
return retval
-
class GPR(dict):
def __init__(self, decoder, isacaller, svstate, regfile):
dict.__init__(self)
self[i] = SelectableInt(regfile[i], 64)
def __call__(self, ridx):
+ if isinstance(ridx, SelectableInt):
+ ridx = ridx.value
return self[ridx]
def set_form(self, form):
self.form = form
+ def __setitem__(self, rnum, value):
+ # rnum = rnum.value # only SelectableInt allowed
+ log("GPR setitem", rnum, value)
+ if isinstance(rnum, SelectableInt):
+ rnum = rnum.value
+ dict.__setitem__(self, rnum, value)
+
def getz(self, rnum):
# rnum = rnum.value # only SelectableInt allowed
log("GPR getzero?", rnum)
def dump(self, printout=True):
res = []
keys = list(self.keys())
- #keys.sort()
+ # keys.sort()
for k in keys:
sprname = spr_dict.get(k, None)
if sprname is None:
class PC:
def __init__(self, pc_init=0):
self.CIA = SelectableInt(pc_init, 64)
- self.NIA = self.CIA + SelectableInt(4, 64) # only true for v3.0B!
+ self.NIA = self.CIA + SelectableInt(4, 64) # only true for v3.0B!
def update_nia(self, is_svp64):
increment = 8 if is_svp64 else 4
namespace['NIA'] = self.NIA
-# Simple-V: see https://libre-soc.org/openpower/sv
-class SVP64State:
- def __init__(self, init=0):
- self.spr = SelectableInt(init, 32)
- # fields of SVSTATE, see https://libre-soc.org/openpower/sv/sprs/
- self.maxvl = FieldSelectableInt(self.spr, tuple(range(0,7)))
- self.vl = FieldSelectableInt(self.spr, tuple(range(7,14)))
- self.srcstep = FieldSelectableInt(self.spr, tuple(range(14,21)))
- self.dststep = FieldSelectableInt(self.spr, tuple(range(21,28)))
- self.subvl = FieldSelectableInt(self.spr, tuple(range(28,30)))
- self.svstep = FieldSelectableInt(self.spr, tuple(range(30,32)))
-
-
# SVP64 ReMap field
-class SVP64RMFields:
- def __init__(self, init=0):
- self.spr = SelectableInt(init, 24)
- # SVP64 RM fields: see https://libre-soc.org/openpower/sv/svp64/
- self.mmode = FieldSelectableInt(self.spr, [0])
- self.mask = FieldSelectableInt(self.spr, tuple(range(1,4)))
- self.elwidth = FieldSelectableInt(self.spr, tuple(range(4,6)))
- self.ewsrc = FieldSelectableInt(self.spr, tuple(range(6,8)))
- self.subvl = FieldSelectableInt(self.spr, tuple(range(8,10)))
- self.extra = FieldSelectableInt(self.spr, tuple(range(10,19)))
- self.mode = FieldSelectableInt(self.spr, tuple(range(19,24)))
- # these cover the same extra field, split into parts as EXTRA2
- self.extra2 = list(range(4))
- self.extra2[0] = FieldSelectableInt(self.spr, tuple(range(10,12)))
- self.extra2[1] = FieldSelectableInt(self.spr, tuple(range(12,14)))
- self.extra2[2] = FieldSelectableInt(self.spr, tuple(range(14,16)))
- self.extra2[3] = FieldSelectableInt(self.spr, tuple(range(16,18)))
- self.smask = FieldSelectableInt(self.spr, tuple(range(16,19)))
- # and here as well, but EXTRA3
- self.extra3 = list(range(3))
- self.extra3[0] = FieldSelectableInt(self.spr, tuple(range(10,13)))
- self.extra3[1] = FieldSelectableInt(self.spr, tuple(range(13,16)))
- self.extra3[2] = FieldSelectableInt(self.spr, tuple(range(16,19)))
-
-
-SVP64RM_MMODE_SIZE = len(SVP64RMFields().mmode.br)
-SVP64RM_MASK_SIZE = len(SVP64RMFields().mask.br)
-SVP64RM_ELWIDTH_SIZE = len(SVP64RMFields().elwidth.br)
-SVP64RM_EWSRC_SIZE = len(SVP64RMFields().ewsrc.br)
-SVP64RM_SUBVL_SIZE = len(SVP64RMFields().subvl.br)
-SVP64RM_EXTRA2_SPEC_SIZE = len(SVP64RMFields().extra2[0].br)
-SVP64RM_EXTRA3_SPEC_SIZE = len(SVP64RMFields().extra3[0].br)
-SVP64RM_SMASK_SIZE = len(SVP64RMFields().smask.br)
-SVP64RM_MODE_SIZE = len(SVP64RMFields().mode.br)
+class SVP64RMFields(SelectableIntMapping, bits=24, fields={
+ "spr": range(24),
+ # SVP64 RM fields: see https://libre-soc.org/openpower/sv/svp64/
+ "mmode": (0,),
+ "mask": range(1, 4),
+ "elwidth": range(4, 6),
+ "ewsrc": range(6, 8),
+ "subvl": range(8, 10),
+ "extra": range(10, 19),
+ "mode": range(19, 24),
+ # these cover the same extra field, split into parts as EXTRA2
+ "extra2": dict(enumerate([
+ range(10, 12),
+ range(12, 14),
+ range(14, 16),
+ range(16, 18),
+ ])),
+ "smask": range(16, 19),
+ # and here as well, but EXTRA3
+ "extra3": dict(enumerate([
+ range(10, 13),
+ range(13, 16),
+ range(16, 19),
+ ])),
+}):
+
+ def __init__(self, value=0):
+ super().__init__(value=value)
+ self.spr = self
+
+
+SVP64RM_MMODE_SIZE = len(SVP64RMFields.mmode)
+SVP64RM_MASK_SIZE = len(SVP64RMFields.mask)
+SVP64RM_ELWIDTH_SIZE = len(SVP64RMFields.elwidth)
+SVP64RM_EWSRC_SIZE = len(SVP64RMFields.ewsrc)
+SVP64RM_SUBVL_SIZE = len(SVP64RMFields.subvl)
+SVP64RM_EXTRA2_SPEC_SIZE = len(SVP64RMFields.extra2[0])
+SVP64RM_EXTRA3_SPEC_SIZE = len(SVP64RMFields.extra3[0])
+SVP64RM_SMASK_SIZE = len(SVP64RMFields.smask)
+SVP64RM_MODE_SIZE = len(SVP64RMFields.mode)
# SVP64 Prefix fields: see https://libre-soc.org/openpower/sv/svp64/
-class SVP64PrefixFields:
- def __init__(self):
- self.insn = SelectableInt(0, 32)
- # 6 bit major opcode EXT001, 2 bits "identifying" (7, 9), 24 SV ReMap
- self.major = FieldSelectableInt(self.insn, tuple(range(0,6)))
- self.pid = FieldSelectableInt(self.insn, (7, 9)) # must be 0b11
- rmfields = [6, 8] + list(range(10,32)) # SVP64 24-bit RM (ReMap)
- self.rm = FieldSelectableInt(self.insn, rmfields)
+class SVP64PrefixFields(SelectableIntMapping, bits=32, fields={
+ "insn": range(32),
+ # 6 bit major opcode EXT001, 2 bits "identifying" (7, 9), 24 SV ReMap
+ "major": range(0, 6),
+ "pid": (7, 9),
+ # SVP64 24-bit RM (ReMap)
+ "rm": ((6, 8) + tuple(range(10, 32))),
+}):
+
+ def __init__(self, value=0):
+ super().__init__(value=value)
+ self.insn = self
-SV64P_MAJOR_SIZE = len(SVP64PrefixFields().major.br)
-SV64P_PID_SIZE = len(SVP64PrefixFields().pid.br)
-SV64P_RM_SIZE = len(SVP64PrefixFields().rm.br)
+SV64P_MAJOR_SIZE = len(SVP64PrefixFields.major)
+SV64P_PID_SIZE = len(SVP64PrefixFields.pid)
+SV64P_RM_SIZE = len(SVP64PrefixFields.rm)
# CR register fields
self.crl.append(_cr)
# decode SVP64 predicate integer to reg number and invert
+
+
def get_predint(gpr, mask):
r10 = gpr(10)
r30 = gpr(30)
- log ("get_predint", mask, SVP64PredInt.ALWAYS.value)
+ log("get_predint", mask, SVP64PredInt.ALWAYS.value)
if mask == SVP64PredInt.ALWAYS.value:
- return 0xffff_ffff_ffff_ffff
+ return 0xffff_ffff_ffff_ffff # 64 bits of 1
if mask == SVP64PredInt.R3_UNARY.value:
return 1 << (gpr(3).value & 0b111111)
if mask == SVP64PredInt.R3.value:
return ~gpr(30).value
# decode SVP64 predicate CR to reg number and invert status
+
+
def _get_predcr(mask):
if mask == SVP64PredCR.LT.value:
return 0, 1
# read individual CR fields (0..VL-1), extract the required bit
# and construct the mask
+
+
def get_predcr(crl, mask, vl):
idx, noninv = _get_predcr(mask)
mask = 0
for i in range(vl):
cr = crl[i+SVP64CROffs.CRPred]
if cr[idx].value == noninv:
- mask |= (1<<i)
+ mask |= (1 << i)
return mask
in1_isvec = yield dec2.in1_isvec
in2_isvec = yield dec2.in2_isvec
in3_isvec = yield dec2.in3_isvec
- log ("get_pdecode_idx_in in1", name, in1_sel, In1Sel.RA.value,
- in1, in1_isvec)
- log ("get_pdecode_idx_in in2", name, in2_sel, In2Sel.RB.value,
- in2, in2_isvec)
- log ("get_pdecode_idx_in in3", name, in3_sel, In3Sel.RS.value,
- in3, in3_isvec)
- log ("get_pdecode_idx_in FRS in3", name, in3_sel, In3Sel.FRS.value,
- in3, in3_isvec)
- log ("get_pdecode_idx_in FRC in3", name, in3_sel, In3Sel.FRC.value,
- in3, in3_isvec)
+ log("get_pdecode_idx_in in1", name, in1_sel, In1Sel.RA.value,
+ in1, in1_isvec)
+ log("get_pdecode_idx_in in2", name, in2_sel, In2Sel.RB.value,
+ in2, in2_isvec)
+ log("get_pdecode_idx_in in3", name, in3_sel, In3Sel.RS.value,
+ in3, in3_isvec)
+ log("get_pdecode_idx_in FRS in3", name, in3_sel, In3Sel.FRS.value,
+ in3, in3_isvec)
+ log("get_pdecode_idx_in FRB in2", name, in2_sel, In2Sel.FRB.value,
+ in2, in2_isvec)
+ log("get_pdecode_idx_in FRC in3", name, in3_sel, In3Sel.FRC.value,
+ in3, in3_isvec)
# identify which regnames map to in1/2/3
if name == 'RA':
if (in1_sel == In1Sel.RA.value or
- (in1_sel == In1Sel.RA_OR_ZERO.value and in1 != 0)):
+ (in1_sel == In1Sel.RA_OR_ZERO.value and in1 != 0)):
return in1, in1_isvec
if in1_sel == In1Sel.RA_OR_ZERO.value:
return in1, in1_isvec
return None, False
+# TODO, really should just be using PowerDecoder2
+def get_pdecode_cr_in(dec2, name):
+ op = dec2.dec.op
+ in_sel = yield op.cr_in
+ in_bitfield = yield dec2.dec_cr_in.cr_bitfield.data
+ sv_cr_in = yield op.sv_cr_in
+ spec = yield dec2.crin_svdec.spec
+ sv_override = yield dec2.dec_cr_in.sv_override
+ # get the IN1/2/3 from the decoder (includes SVP64 remap and isvec)
+ in1 = yield dec2.e.read_cr1.data
+ cr_isvec = yield dec2.cr_in_isvec
+ log("get_pdecode_cr_in", in_sel, CROutSel.CR0.value, in1, cr_isvec)
+ log(" sv_cr_in", sv_cr_in)
+ log(" cr_bf", in_bitfield)
+ log(" spec", spec)
+ log(" override", sv_override)
+ # identify which regnames map to in / o2
+ if name == 'BI':
+ if in_sel == CRInSel.BI.value:
+ return in1, cr_isvec
+ log("get_pdecode_cr_in not found", name)
+ return None, False
+
+
# TODO, really should just be using PowerDecoder2
def get_pdecode_cr_out(dec2, name):
op = dec2.dec.op
# get the IN1/2/3 from the decoder (includes SVP64 remap and isvec)
out = yield dec2.e.write_cr.data
o_isvec = yield dec2.o_isvec
- log ("get_pdecode_cr_out", out_sel, CROutSel.CR0.value, out, o_isvec)
- log (" sv_cr_out", sv_cr_out)
- log (" cr_bf", out_bitfield)
- log (" spec", spec)
- log (" override", sv_override)
+ log("get_pdecode_cr_out", out_sel, CROutSel.CR0.value, out, o_isvec)
+ log(" sv_cr_out", sv_cr_out)
+ log(" cr_bf", out_bitfield)
+ log(" spec", spec)
+ log(" override", sv_override)
# identify which regnames map to out / o2
if name == 'CR0':
if out_sel == CROutSel.CR0.value:
return out, o_isvec
- log ("get_pdecode_cr_out not found", name)
+ log("get_pdecode_cr_out not found", name)
return None, False
o_isvec = yield dec2.o_isvec
# identify which regnames map to out / o2
if name == 'RA':
- log ("get_pdecode_idx_out", out_sel, OutSel.RA.value, out, o_isvec)
+ log("get_pdecode_idx_out", out_sel, OutSel.RA.value, out, o_isvec)
if out_sel == OutSel.RA.value:
return out, o_isvec
elif name == 'RT':
- log ("get_pdecode_idx_out", out_sel, OutSel.RT.value,
- OutSel.RT_OR_ZERO.value, out, o_isvec)
+ log("get_pdecode_idx_out", out_sel, OutSel.RT.value,
+ OutSel.RT_OR_ZERO.value, out, o_isvec,
+ dec2.dec.RT)
if out_sel == OutSel.RT.value:
return out, o_isvec
+ elif name == 'RT_OR_ZERO':
+ log("get_pdecode_idx_out", out_sel, OutSel.RT.value,
+ OutSel.RT_OR_ZERO.value, out, o_isvec,
+ dec2.dec.RT)
+ if out_sel == OutSel.RT_OR_ZERO.value:
+ return out, o_isvec
elif name == 'FRA':
- log ("get_pdecode_idx_out", out_sel, OutSel.FRA.value, out, o_isvec)
+ log("get_pdecode_idx_out", out_sel, OutSel.FRA.value, out, o_isvec)
if out_sel == OutSel.FRA.value:
return out, o_isvec
elif name == 'FRT':
- log ("get_pdecode_idx_out", out_sel, OutSel.FRT.value,
- OutSel.FRT.value, out, o_isvec)
+ log("get_pdecode_idx_out", out_sel, OutSel.FRT.value,
+ OutSel.FRT.value, out, o_isvec)
if out_sel == OutSel.FRT.value:
return out, o_isvec
- log ("get_pdecode_idx_out not found", name, out_sel, out, o_isvec)
+ log("get_pdecode_idx_out not found", name, out_sel, out, o_isvec)
return None, False
# TODO, really should just be using PowerDecoder2
def get_pdecode_idx_out2(dec2, name):
# check first if register is activated for write
- out_ok = yield dec2.e.write_ea.ok
- if not out_ok:
- return None, False
-
op = dec2.dec.op
out_sel = yield op.out_sel
out = yield dec2.e.write_ea.data
o_isvec = yield dec2.o2_isvec
- log ("get_pdecode_idx_out2", name, out_sel, out, o_isvec)
+ out_ok = yield dec2.e.write_ea.ok
+ log("get_pdecode_idx_out2", name, out_sel, out, out_ok, o_isvec)
+ if not out_ok:
+ return None, False
+
if name == 'RA':
if hasattr(op, "upd"):
# update mode LD/ST uses read-reg A also as an output
upd = yield op.upd
- log ("get_pdecode_idx_out2", upd, LDSTMode.update.value,
- out_sel, OutSel.RA.value,
- out, o_isvec)
+ log("get_pdecode_idx_out2", upd, LDSTMode.update.value,
+ out_sel, OutSel.RA.value,
+ out, o_isvec)
if upd == LDSTMode.update.value:
return out, o_isvec
+ if name == 'FRS':
+ int_op = yield dec2.dec.op.internal_op
+ fft_en = yield dec2.use_svp64_fft
+ # if int_op == MicrOp.OP_FP_MADD.value and fft_en:
+ if fft_en:
+ log("get_pdecode_idx_out2", out_sel, OutSel.FRS.value,
+ out, o_isvec)
+ return out, o_isvec
return None, False
-class ISACaller:
+class ISACaller(ISACallerHelper, ISAFPHelpers):
# decoder2 - an instance of power_decoder2
# regfile - a list of initial values for the registers
# initial_{etc} - initial values for SPRs, Condition Register, Mem, MSR
self.msr = SelectableInt(initial_msr, 64) # underlying reg
self.pc = PC()
# GPR FPR SPR registers
+ 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
+ self.spr = SPR(decoder2, initial_sprs) # initialise SPRs before MMU
+
+ # set up 4 dummy SVSHAPEs if they aren't already set up
+ for i in range(4):
+ sname = 'SVSHAPE%d' % i
+ if sname not in self.spr:
+ val = 0
+ else:
+ val = self.spr[sname].value
+ # make sure it's an SVSHAPE
+ self.spr[sname] = SVSHAPE(val, self.gpr)
+ self.last_op_svshape = False
+
# "raw" memory
self.mem = Mem(row_bytes=8, initial_mem=initial_mem)
self.imem = Mem(row_bytes=4, initial_mem=initial_insns)
self.cr = self.cr_fields.cr
# "undefined", just set to variable-bit-width int (use exts "max")
- #self.undefined = SelectableInt(0, 256) # TODO, not hard-code 256!
+ # self.undefined = SelectableInt(0, 256) # TODO, not hard-code 256!
self.namespace = {}
self.namespace.update(self.spr)
'memassign': self.memassign,
'NIA': self.pc.NIA,
'CIA': self.pc.CIA,
- 'SVSTATE': self.svstate.spr,
+ 'SVSTATE': self.svstate,
+ 'SVSHAPE0': self.spr['SVSHAPE0'],
+ 'SVSHAPE1': self.spr['SVSHAPE1'],
+ 'SVSHAPE2': self.spr['SVSHAPE2'],
+ 'SVSHAPE3': self.spr['SVSHAPE3'],
'CR': self.cr,
'MSR': self.msr,
'undefined': undefined,
'mode_is_64bit': True,
- 'SO': XER_bits['SO']
+ 'SO': XER_bits['SO'],
+ 'XLEN': 64 # elwidth overrides, later
})
# update pc to requested start point
self.decoder = decoder2.dec
self.dec2 = decoder2
+ super().__init__(XLEN=self.namespace["XLEN"])
+
+ @property
+ def XLEN(self):
+ return self.namespace["XLEN"]
+
def call_trap(self, trap_addr, trap_bit):
"""calls TRAP and sets up NIA to the new execution location.
next instruction will begin at trap_addr.
hence the default arguments. when calling from inside ISACaller
it is best to use call_trap()
"""
- log("TRAP:", hex(trap_addr), hex(self.namespace['MSR'].value))
+ # https://bugs.libre-soc.org/show_bug.cgi?id=859
+ kaivb = self.spr['KAIVB'].value
+ msr = self.namespace['MSR'].value
+ log("TRAP:", hex(trap_addr), hex(msr), "kaivb", hex(kaivb))
# store CIA(+4?) in SRR0, set NIA to 0x700
# store MSR in SRR1, set MSR to um errr something, have to check spec
# store SVSTATE (if enabled) in SVSRR0
self.spr['SRR0'].value = self.pc.CIA.value
- self.spr['SRR1'].value = self.namespace['MSR'].value
+ self.spr['SRR1'].value = msr
if self.is_svp64_mode:
self.spr['SVSRR0'] = self.namespace['SVSTATE'].value
- self.trap_nia = SelectableInt(trap_addr, 64)
+ self.trap_nia = SelectableInt(trap_addr | (kaivb&~0x1fff), 64)
self.spr['SRR1'][trap_bit] = 1 # change *copy* of MSR in SRR1
# set exception bits. TODO: this should, based on the address
def memassign(self, ea, sz, val):
self.mem.memassign(ea, sz, val)
- def prep_namespace(self, formname, op_fields):
+ def prep_namespace(self, insn_name, formname, op_fields):
# TODO: get field names from form in decoder*1* (not decoder2)
# decoder2 is hand-created, and decoder1.sigform is auto-generated
# from spec
# then "yield" fields only from op_fields rather than hard-coded
# list, here.
fields = self.decoder.sigforms[formname]
+ log("prep_namespace", formname, op_fields)
for name in op_fields:
- if name == 'spr':
- sig = getattr(fields, name.upper())
- else:
+ # CR immediates. deal with separately. needs modifying
+ # pseudocode
+ if self.is_svp64_mode and name in ['BI']: # TODO, more CRs
+ # BI is a 5-bit, must reconstruct the value
+ regnum, is_vec = yield from get_pdecode_cr_in(self.dec2, name)
sig = getattr(fields, name)
- val = yield sig
+ val = yield sig
+ # low 2 LSBs (CR field selector) remain same, CR num extended
+ assert regnum <= 7, "sigh, TODO, 128 CR fields"
+ val = (val & 0b11) | (regnum << 2)
+ else:
+ if name == 'spr':
+ sig = getattr(fields, name.upper())
+ else:
+ sig = getattr(fields, name)
+ val = yield sig
# these are all opcode fields involved in index-selection of CR,
# and need to do "standard" arithmetic. CR[BA+32] for example
# would, if using SelectableInt, only be 5-bit.
self.namespace['CA32'] = self.spr['XER'][XER_bits['CA32']].value
# add some SVSTATE convenience variables
- vl = self.svstate.vl.asint(msb0=True)
- srcstep = self.svstate.srcstep.asint(msb0=True)
+ vl = self.svstate.vl
+ srcstep = self.svstate.srcstep
self.namespace['VL'] = vl
self.namespace['srcstep'] = srcstep
+ # 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
+ bc_vlset = (mode & SVP64MODE.BC_VLSET) != 0
+ bc_vli = (mode & SVP64MODE.BC_VLI) != 0
+ bc_snz = (mode & SVP64MODE.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['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)
+
def handle_carry_(self, inputs, outputs, already_done):
inv_a = yield self.dec2.e.do.invert_in
if inv_a:
SO = self.spr['XER'][XER_bits['SO']]
log("handle_comparison SO", SO)
cr_field = selectconcat(negative, positive, zero, SO)
+ log("handle_comparison cr_field", self.cr, cr_idx, cr_field)
self.crl[cr_idx].eq(cr_field)
def set_pc(self, pc_val):
yield self.dec2.state.msr.eq(self.msr.value)
yield self.dec2.state.pc.eq(pc)
if self.svstate is not None:
- yield self.dec2.state.svstate.eq(self.svstate.spr.value)
+ yield self.dec2.state.svstate.eq(self.svstate.value)
# SVP64. first, check if the opcode is EXT001, and SVP64 id bits set
yield Settle()
opcode = yield self.dec2.dec.opcode_in
- pfx = SVP64PrefixFields() # TODO should probably use SVP64PrefixDecoder
+ pfx = SVP64PrefixFields() # TODO should probably use SVP64PrefixDecoder
pfx.insn.value = opcode
- major = pfx.major.asint(msb0=True) # MSB0 inversion
- log ("prefix test: opcode:", major, bin(major),
- pfx.insn[7] == 0b1, pfx.insn[9] == 0b1)
+ major = pfx.major.asint(msb0=True) # MSB0 inversion
+ log("prefix test: opcode:", major, bin(major),
+ pfx.insn[7] == 0b1, pfx.insn[9] == 0b1)
self.is_svp64_mode = ((major == 0b000001) and
pfx.insn[7].value == 0b1 and
pfx.insn[9].value == 0b1)
self.pc.update_nia(self.is_svp64_mode)
+ # set SVP64 decode
+ yield self.dec2.is_svp64_mode.eq(self.is_svp64_mode)
self.namespace['NIA'] = self.pc.NIA
- self.namespace['SVSTATE'] = self.svstate.spr
+ self.namespace['SVSTATE'] = self.svstate
if not self.is_svp64_mode:
return
# in SVP64 mode. decode/print out svp64 prefix, get v3.0B instruction
- log ("svp64.rm", bin(pfx.rm.asint(msb0=True)))
- log (" svstate.vl", self.svstate.vl.asint(msb0=True))
- log (" svstate.mvl", self.svstate.maxvl.asint(msb0=True))
+ log("svp64.rm", bin(pfx.rm.asint(msb0=True)))
+ log(" svstate.vl", self.svstate.vl)
+ log(" svstate.mvl", self.svstate.maxvl)
sv_rm = pfx.rm.asint(msb0=True)
ins = self.imem.ld(pc+4, 4, False, True, instr_fetch=True)
log(" svsetup: 0x%x 0x%x %s" % (pc+4, ins & 0xffffffff, bin(ins)))
- yield self.dec2.dec.raw_opcode_in.eq(ins & 0xffffffff) # v3.0B suffix
+ yield self.dec2.dec.raw_opcode_in.eq(ins & 0xffffffff) # v3.0B suffix
yield self.dec2.sv_rm.eq(sv_rm) # svp64 prefix
yield Settle()
try:
yield from self.call(opname) # execute the instruction
except MemException as e: # check for memory errors
- if e.args[0] != 'unaligned': # only doing aligned at the mo
- raise e # ... re-raise
- # run a Trap but set DAR first
- print ("memory unaligned exception, DAR", e.dar)
- self.spr['DAR'] = SelectableInt(e.dar, 64)
- self.call_trap(0x600, PIb.PRIV) # 0x600, privileged
- return
+ if e.args[0] == 'unaligned': # alignment error
+ # run a Trap but set DAR first
+ print("memory unaligned exception, DAR", e.dar)
+ self.spr['DAR'] = SelectableInt(e.dar, 64)
+ self.call_trap(0x600, PIb.PRIV) # 0x600, privileged
+ return
+ elif e.args[0] == 'invalid': # invalid
+ # run a Trap but set DAR first
+ log("RADIX MMU memory invalid error, mode %s" % e.mode)
+ if e.mode == 'EXECUTE':
+ # XXX TODO: must set a few bits in SRR1,
+ # see microwatt loadstore1.vhdl
+ # if m_in.segerr = '0' then
+ # v.srr1(47 - 33) := m_in.invalid;
+ # v.srr1(47 - 35) := m_in.perm_error; -- noexec fault
+ # v.srr1(47 - 44) := m_in.badtree;
+ # v.srr1(47 - 45) := m_in.rc_error;
+ # v.intr_vec := 16#400#;
+ # else
+ # v.intr_vec := 16#480#;
+ self.call_trap(0x400, PIb.PRIV) # 0x400, privileged
+ else:
+ self.call_trap(0x300, PIb.PRIV) # 0x300, privileged
+ return
+ # not supported yet:
+ raise e # ... re-raise
# don't use this except in special circumstances
if not self.respect_pc:
self.fake_pc += 4
- log("execute one, CIA NIA", self.pc.CIA.value, self.pc.NIA.value)
+ log("execute one, CIA NIA", hex(self.pc.CIA.value),
+ hex(self.pc.NIA.value))
def get_assembly_name(self):
# TODO, asmregs is from the spec, e.g. add RT,RA,RB
asmcode = yield self.dec2.dec.op.asmcode
int_op = yield self.dec2.dec.op.internal_op
log("get assembly name asmcode", asmcode, int_op,
- hex(dec_insn), bin(insn_1_11))
+ hex(dec_insn), bin(insn_1_11))
asmop = insns.get(asmcode, None)
# sigh reconstruct the assembly instruction name
rc_ok = False
# grrrr have to special-case MUL op (see DecodeOE)
log("ov %d en %d rc %d en %d op %d" %
- (ov_ok, ov_en, rc_ok, rc_en, int_op))
+ (ov_ok, ov_en, rc_ok, rc_en, int_op))
if int_op in [MicrOp.OP_MUL_H64.value, MicrOp.OP_MUL_H32.value]:
log("mul op")
if rc_en & rc_ok:
asmop = 'mtcrf'
return asmop
+ def get_remap_indices(self):
+ """WARNING, this function stores remap_idxs and remap_loopends
+ in the class for later use. this to avoid problems with yield
+ """
+ # go through all iterators in lock-step, advance to next remap_idx
+ srcstep, dststep, ssubstep, dsubstep = self.get_src_dststeps()
+ # get four SVSHAPEs. here we are hard-coding
+ SVSHAPE0 = self.spr['SVSHAPE0']
+ SVSHAPE1 = self.spr['SVSHAPE1']
+ SVSHAPE2 = self.spr['SVSHAPE2']
+ SVSHAPE3 = self.spr['SVSHAPE3']
+ # set up the iterators
+ remaps = [(SVSHAPE0, SVSHAPE0.get_iterator()),
+ (SVSHAPE1, SVSHAPE1.get_iterator()),
+ (SVSHAPE2, SVSHAPE2.get_iterator()),
+ (SVSHAPE3, SVSHAPE3.get_iterator()),
+ ]
+
+ self.remap_loopends = [0] * 4
+ self.remap_idxs = [0, 1, 2, 3]
+ dbg = []
+ for i, (shape, remap) in enumerate(remaps):
+ # zero is "disabled"
+ if shape.value == 0x0:
+ self.remap_idxs[i] = 0
+ # pick src or dststep depending on reg num (0-2=in, 3-4=out)
+ step = dststep if (i in [3, 4]) else srcstep
+ # this is terrible. O(N^2) looking for the match. but hey.
+ for idx, (remap_idx, loopends) in enumerate(remap):
+ if idx == step:
+ break
+ self.remap_idxs[i] = remap_idx
+ self.remap_loopends[i] = loopends
+ dbg.append((i, step, remap_idx, loopends))
+ for (i, step, remap_idx, loopends) in dbg:
+ log("SVSHAPE %d idx, end" % i, step, remap_idx, bin(loopends))
+ return remaps
+
def get_spr_msb(self):
dec_insn = yield self.dec2.e.do.insn
return dec_insn & (1 << 20) != 0 # sigh - XFF.spr[-1]?
def call(self, name):
"""call(opcode) - the primary execution point for instructions
"""
- self.last_st_addr = None # reset the last known store address
- self.last_ld_addr = None # etc.
+ self.last_st_addr = None # reset the last known store address
+ self.last_ld_addr = None # etc.
- name = name.strip() # remove spaces if not already done so
+ ins_name = name.strip() # remove spaces if not already done so
if self.halted:
- log("halted - not executing", name)
+ log("halted - not executing", ins_name)
return
# 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", name, asmop)
+ log("call", ins_name, asmop)
# check privileged
int_op = yield self.dec2.dec.op.internal_op
instr_is_privileged = True
log("is priv", instr_is_privileged, hex(self.msr.value),
- self.msr[MSRb.PR])
+ self.msr[MSRb.PR])
# check MSR priv bit and whether op is privileged: if so, throw trap
if instr_is_privileged and self.msr[MSRb.PR] == 1:
self.call_trap(0x700, PIb.PRIV)
return
# check halted condition
- if name == 'attn':
+ if ins_name == 'attn':
self.halted = True
return
# check illegal instruction
illegal = False
- if name not in ['mtcrf', 'mtocrf']:
- illegal = name != asmop
-
- # sigh deal with setvl not being supported by binutils (.long)
- if asmop.startswith('setvl'):
+ if ins_name not in ['mtcrf', 'mtocrf']:
+ illegal = ins_name != asmop
+
+ # list of instructions not being supported by binutils (.long)
+ dotstrp = asmop[:-1] if asmop[-1] == '.' else asmop
+ if dotstrp in [ 'fsins', 'fcoss',
+ 'ffmadds', 'fdmadds', 'ffadds',
+ 'mins', 'maxs', 'minu', 'maxu',
+ 'setvl', 'svindex', 'svremap', 'svstep', 'svshape',
+ 'grev', 'ternlogi', 'bmask', 'cprop',
+ 'absdu', 'absds', 'absdacs', 'absdacu', 'avgadd',
+ 'fmvis', 'fishmv',
+ ]:
illegal = False
- name = 'setvl'
+ ins_name = dotstrp
+
+ # branch-conditional redirects to sv.bc
+ if asmop.startswith('bc') and self.is_svp64_mode:
+ ins_name = 'sv.%s' % ins_name
+ log(" post-processed name", dotstrp, ins_name, asmop)
+
+ # illegal instructions call TRAP at 0x700
if illegal:
- print("illegal", name, asmop)
+ print("illegal", ins_name, asmop)
self.call_trap(0x700, PIb.ILLEG)
print("name %s != %s - calling ILLEGAL trap, PC: %x" %
- (name, asmop, self.pc.CIA.value))
+ (ins_name, asmop, self.pc.CIA.value))
return
+ # this is for setvl "Vertical" mode: if set true,
+ # srcstep/dststep is explicitly advanced. mode says which SVSTATE to
+ # test for Rc=1 end condition. 3 bits of all 3 loops are put into CR0
+ self.allow_next_step_inc = False
+ self.svstate_next_mode = 0
+
# nop has to be supported, we could let the actual op calculate
# but PowerDecoder has a pattern for nop
- if name is 'nop':
+ if ins_name is 'nop':
self.update_pc_next()
return
- info = self.instrs[name]
- yield from self.prep_namespace(info.form, info.op_fields)
+ # look up instruction in ISA.instrs, prepare namespace
+ info = self.instrs[ins_name]
+ yield from self.prep_namespace(ins_name, info.form, info.op_fields)
# preserve order of register names
input_names = create_args(list(info.read_regs) +
list(info.uninit_regs))
- log(input_names)
+ log("input names", input_names)
# get SVP64 entry for the current instruction
- sv_rm = self.svp64rm.instrs.get(name)
+ sv_rm = self.svp64rm.instrs.get(ins_name)
if sv_rm is not None:
dest_cr, src_cr, src_byname, dest_byname = decode_extra(sv_rm)
else:
dest_cr, src_cr, src_byname, dest_byname = False, False, {}, {}
- log ("sv rm", sv_rm, dest_cr, src_cr, src_byname, dest_byname)
+ log("sv rm", sv_rm, dest_cr, src_cr, src_byname, dest_byname)
- # get SVSTATE VL (oh and print out some debug stuff)
- if self.is_svp64_mode:
- vl = self.svstate.vl.asint(msb0=True)
- srcstep = self.svstate.srcstep.asint(msb0=True)
- dststep = self.svstate.dststep.asint(msb0=True)
- sv_a_nz = yield self.dec2.sv_a_nz
- in1 = yield self.dec2.e.read_reg1.data
- log ("SVP64: VL, srcstep, dststep, sv_a_nz, in1",
- vl, srcstep, dststep, sv_a_nz, in1)
-
- # get predicate mask
- srcmask = dstmask = 0xffff_ffff_ffff_ffff
+ # see if srcstep/dststep need skipping over masked-out predicate bits
+ if (self.is_svp64_mode or ins_name == 'setvl' or
+ ins_name in ['svremap', 'svstate']):
+ yield from self.svstate_pre_inc()
if self.is_svp64_mode:
- pmode = yield self.dec2.rm_dec.predmode
- reverse_gear = yield self.dec2.rm_dec.reverse_gear
- sv_ptype = yield self.dec2.dec.op.SV_Ptype
- srcpred = yield self.dec2.rm_dec.srcpred
- dstpred = yield self.dec2.rm_dec.dstpred
- pred_src_zero = yield self.dec2.rm_dec.pred_sz
- pred_dst_zero = yield self.dec2.rm_dec.pred_dz
- if pmode == SVP64PredMode.INT.value:
- srcmask = dstmask = get_predint(self.gpr, dstpred)
- if sv_ptype == SVPtype.P2.value:
- srcmask = get_predint(self.gpr, srcpred)
- elif pmode == SVP64PredMode.CR.value:
- srcmask = dstmask = get_predcr(self.crl, dstpred, vl)
- if sv_ptype == SVPtype.P2.value:
- srcmask = get_predcr(self.crl, srcpred, vl)
- log (" pmode", pmode)
- log (" reverse", reverse_gear)
- log (" ptype", sv_ptype)
- log (" srcpred", bin(srcpred))
- log (" dstpred", bin(dstpred))
- log (" srcmask", bin(srcmask))
- log (" dstmask", bin(dstmask))
- log (" pred_sz", bin(pred_src_zero))
- log (" pred_dz", bin(pred_dst_zero))
-
- # okaaay, so here we simply advance srcstep (TODO dststep)
- # until the predicate mask has a "1" bit... or we run out of VL
- # let srcstep==VL be the indicator to move to next instruction
- if not pred_src_zero:
- while (((1<<srcstep) & srcmask) == 0) and (srcstep != vl):
- log (" skip", bin(1<<srcstep))
- srcstep += 1
- # same for dststep
- if not pred_dst_zero:
- while (((1<<dststep) & dstmask) == 0) and (dststep != vl):
- log (" skip", bin(1<<dststep))
- dststep += 1
-
- # now work out if the relevant mask bits require zeroing
- if pred_dst_zero:
- pred_dst_zero = ((1<<dststep) & dstmask) == 0
- if pred_src_zero:
- pred_src_zero = ((1<<srcstep) & srcmask) == 0
-
- # update SVSTATE with new srcstep
- self.svstate.srcstep[0:7] = srcstep
- self.svstate.dststep[0:7] = dststep
- self.namespace['SVSTATE'] = self.svstate.spr
- yield self.dec2.state.svstate.eq(self.svstate.spr.value)
- yield Settle() # let decoder update
- srcstep = self.svstate.srcstep.asint(msb0=True)
- dststep = self.svstate.dststep.asint(msb0=True)
- log (" srcstep", srcstep)
- log (" dststep", dststep)
-
- # check if end reached (we let srcstep overrun, above)
- # nothing needs doing (TODO zeroing): just do next instruction
- if srcstep == vl or dststep == vl:
+ pre = yield from self.update_new_svstate_steps()
+ if pre:
self.svp64_reset_loop()
+ self.update_nia()
self.update_pc_next()
return
+ srcstep, dststep, ssubstep, dsubstep = self.get_src_dststeps()
+ pred_dst_zero = self.pred_dst_zero
+ pred_src_zero = self.pred_src_zero
+ vl = self.svstate.vl
+ subvl = yield self.dec2.rm_dec.rm_in.subvl
# VL=0 in SVP64 mode means "do nothing: skip 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'])
+ self.namespace['NIA'])
return
+ # for when SVREMAP is active, using pre-arranged schedule.
+ # note: modifying PowerDecoder2 needs to "settle"
+ remap_en = self.svstate.SVme
+ persist = self.svstate.RMpst
+ active = (persist or self.last_op_svshape) and remap_en != 0
+ if self.is_svp64_mode:
+ yield self.dec2.remap_active.eq(remap_en if active else 0)
+ yield Settle()
+ if persist or self.last_op_svshape:
+ remaps = self.get_remap_indices()
+ if self.is_svp64_mode and (persist or self.last_op_svshape):
+ yield from self.remap_debug(remaps)
+ # after that, settle down (combinatorial) to let Vector reg numbers
+ # work themselves out
+ yield Settle()
+ if self.is_svp64_mode:
+ remap_active = yield self.dec2.remap_active
+ else:
+ remap_active = False
+ log("remap active", bin(remap_active))
+
# main input registers (RT, RA ...)
inputs = []
for name in input_names:
- # using PowerDecoder2, first, find the decoder index.
- # (mapping name RA RB RC RS to in1, in2, in3)
- regnum, is_vec = yield from get_pdecode_idx_in(self.dec2, name)
- if regnum is None:
- # doing this is not part of svp64, it's because output
- # registers, to be modified, need to be in the namespace.
- regnum, is_vec = yield from get_pdecode_idx_out(self.dec2, name)
- if regnum is None:
- regnum, is_vec = yield from get_pdecode_idx_out2(self.dec2,
- name)
-
- # in case getting the register number is needed, _RA, _RB
- regname = "_" + name
- self.namespace[regname] = regnum
- if not self.is_svp64_mode or not pred_src_zero:
- log('reading reg %s %s' % (name, str(regnum)), is_vec)
- if name in fregs:
- reg_val = self.fpr(regnum)
- else:
- reg_val = self.gpr(regnum)
- else:
- log('zero input reg %s %s' % (name, str(regnum)), is_vec)
- reg_val = 0
- inputs.append(reg_val)
+ print("name", name)
+ regval = (yield from self.get_input(name))
+ print("regval", regval)
+ inputs.append(regval)
+
+ # arrrrgh, awful hack, to get _RT into namespace
+ if ins_name in ['setvl', 'svstep']:
+ regname = "_RT"
+ RT = yield self.dec2.dec.RT
+ self.namespace[regname] = SelectableInt(RT, 5)
+ if RT == 0:
+ self.namespace["RT"] = SelectableInt(0, 5)
+ regnum, is_vec = yield from get_pdecode_idx_out(self.dec2, "RT")
+ log('hack input reg %s %s' % (name, str(regnum)), is_vec)
# in SVP64 mode for LD/ST work out immediate
# XXX TODO: replace_ds for DS-Form rather than D-Form.
# use info.form to detect
- replace_d = False # update / replace constant in pseudocode
if self.is_svp64_mode:
- ldstmode = yield self.dec2.rm_dec.ldstmode
- # bitreverse mode reads SVD (or SVDS - TODO)
- # *BUT*... because this is "overloading" of LD operations,
- # it gets *STORED* into D (or DS, TODO)
- if ldstmode == SVP64LDSTmode.BITREVERSE.value:
- imm = yield self.dec2.dec.fields.FormSVD.SVD[0:11]
- imm = exts(imm, 11) # sign-extend to integer
- print ("bitrev SVD", imm)
- replace_d = True
- else:
- imm = yield self.dec2.dec.fields.FormD.D[0:16]
- imm = exts(imm, 16) # sign-extend to integer
- # get the right step. LD is from srcstep, ST is dststep
- op = yield self.dec2.e.do.insn_type
- offsmul = 0
- if op == MicrOp.OP_LOAD.value:
- offsmul = srcstep
- log("D-field src", imm, offsmul)
- elif op == MicrOp.OP_STORE.value:
- offsmul = dststep
- log("D-field dst", imm, offsmul)
- # bit-reverse mode
- if ldstmode == SVP64LDSTmode.BITREVERSE.value:
- # manually look up RC, sigh
- RC = yield self.dec2.dec.RC[0:5]
- RC = self.gpr(RC)
- log ("RC", RC.value, "imm", imm, "offs", bin(offsmul),
- "rev", bin(bitrev(offsmul, vl)))
- imm = SelectableInt((imm * bitrev(offsmul, vl)) << RC.value, 32)
- # Unit-Strided LD/ST adds offset*width to immediate
- elif ldstmode == SVP64LDSTmode.UNITSTRIDE.value:
- ldst_len = yield self.dec2.e.do.data_len
- imm = SelectableInt(imm + offsmul * ldst_len, 32)
- replace_d = True
- # Element-strided multiplies the immediate by element step
- elif ldstmode == SVP64LDSTmode.ELSTRIDE.value:
- imm = SelectableInt(imm * offsmul, 32)
- replace_d = True
- ldst_ra_vec = yield self.dec2.rm_dec.ldst_ra_vec
- ldst_imz_in = yield self.dec2.rm_dec.ldst_imz_in
- log("LDSTmode", ldstmode, SVP64LDSTmode.BITREVERSE.value,
- offsmul, imm, ldst_ra_vec, ldst_imz_in)
- # new replacement D
- if replace_d:
- self.namespace['D'] = imm
+ yield from self.check_replace_d(info, remap_active)
# "special" registers
for special in info.special_regs:
# 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
+ 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
+ self.namespace['end_loop'] = SelectableInt(end_loop, 1)
+
# execute actual instruction here (finally)
log("inputs", inputs)
results = info.func(self, *inputs)
# check if op was a LD/ST so that debugging can check the
# address
if int_op in [MicrOp.OP_STORE.value,
- ]:
+ ]:
self.last_st_addr = self.mem.last_st_addr
if int_op in [MicrOp.OP_LOAD.value,
- ]:
+ ]:
self.last_ld_addr = self.mem.last_ld_addr
- log ("op", int_op, MicrOp.OP_STORE.value, MicrOp.OP_LOAD.value,
- self.last_st_addr, self.last_ld_addr)
+ log("op", int_op, MicrOp.OP_STORE.value, MicrOp.OP_LOAD.value,
+ self.last_st_addr, self.last_ld_addr)
# detect if CA/CA32 already in outputs (sra*, basically)
already_done = 0
if carry_en:
yield from self.handle_carry_(inputs, results, already_done)
- if not self.is_svp64_mode: # yeah just no. not in parallel processing
+ if not self.is_svp64_mode: # yeah just no. not in parallel processing
# detect if overflow was in return result
overflow = None
if info.write_regs:
if not self.is_svp64_mode or not pred_dst_zero:
if hasattr(self.dec2.e.do, "rc"):
rc_en = yield self.dec2.e.do.rc.rc
- if rc_en:
+ if rc_en and ins_name not in ['svstep']:
regnum, is_vec = yield from get_pdecode_cr_out(self.dec2, "CR0")
self.handle_comparison(results, regnum)
# any modified return results?
if info.write_regs:
for name, output in zip(output_names, results):
- if name == 'overflow': # ignore, done already (above)
- continue
- if isinstance(output, int):
- output = SelectableInt(output, 256)
- if name in ['CA', 'CA32']:
- if carry_en:
- log("writing %s to XER" % name, output)
- self.spr['XER'][XER_bits[name]] = output.value
- else:
- log("NOT writing %s to XER" % name, output)
- elif name in info.special_regs:
- log('writing special %s' % name, output, special_sprs)
- if name in special_sprs:
- self.spr[name] = output
- else:
- self.namespace[name].eq(output)
- if name == 'MSR':
- log('msr written', hex(self.msr.value))
+ yield from self.check_write(info, name, output, carry_en)
+
+ nia_update = (yield from self.check_step_increment(results, rc_en,
+ asmop, ins_name))
+ if nia_update:
+ self.update_pc_next()
+
+ def check_replace_d(self, info, remap_active):
+ replace_d = False # update / replace constant in pseudocode
+ ldstmode = yield self.dec2.rm_dec.ldstmode
+ vl = self.svstate.vl
+ subvl = yield self.dec2.rm_dec.rm_in.subvl
+ srcstep, dststep = self.new_srcstep, self.new_dststep
+ ssubstep, dsubstep = self.new_ssubstep, self.new_dsubstep
+ if info.form == 'DS':
+ # DS-Form, multiply by 4 then knock 2 bits off after
+ imm = yield self.dec2.dec.fields.FormDS.DS[0:14] * 4
+ else:
+ imm = yield self.dec2.dec.fields.FormD.D[0:16]
+ imm = exts(imm, 16) # sign-extend to integer
+ # get the right step. LD is from srcstep, ST is dststep
+ op = yield self.dec2.e.do.insn_type
+ offsmul = 0
+ if op == MicrOp.OP_LOAD.value:
+ if remap_active:
+ offsmul = yield self.dec2.in1_step
+ log("D-field REMAP src", imm, offsmul)
+ else:
+ offsmul = (srcstep * (subvl+1)) + ssubstep
+ log("D-field src", imm, offsmul)
+ elif op == MicrOp.OP_STORE.value:
+ # XXX NOTE! no bit-reversed STORE! this should not ever be used
+ offsmul = (dststep * (subvl+1)) + dsubstep
+ log("D-field dst", imm, offsmul)
+ # Unit-Strided LD/ST adds offset*width to immediate
+ if ldstmode == SVP64LDSTmode.UNITSTRIDE.value:
+ ldst_len = yield self.dec2.e.do.data_len
+ imm = SelectableInt(imm + offsmul * ldst_len, 32)
+ replace_d = True
+ # Element-strided multiplies the immediate by element step
+ elif ldstmode == SVP64LDSTmode.ELSTRIDE.value:
+ imm = SelectableInt(imm * offsmul, 32)
+ replace_d = True
+ if replace_d:
+ ldst_ra_vec = yield self.dec2.rm_dec.ldst_ra_vec
+ ldst_imz_in = yield self.dec2.rm_dec.ldst_imz_in
+ log("LDSTmode", SVP64LDSTmode(ldstmode),
+ offsmul, imm, ldst_ra_vec, ldst_imz_in)
+ # new replacement D... errr.. DS
+ if replace_d:
+ if info.form == 'DS':
+ # TODO: assert 2 LSBs are zero?
+ log("DS-Form, TODO, assert 2 LSBs zero?", bin(imm.value))
+ imm.value = imm.value >> 2
+ self.namespace['DS'] = imm
+ else:
+ self.namespace['D'] = imm
+
+ def get_input(self, name):
+ # using PowerDecoder2, first, find the decoder index.
+ # (mapping name RA RB RC RS to in1, in2, in3)
+ regnum, is_vec = yield from get_pdecode_idx_in(self.dec2, name)
+ if regnum is None:
+ # doing this is not part of svp64, it's because output
+ # registers, to be modified, need to be in the namespace.
+ regnum, is_vec = yield from get_pdecode_idx_out(self.dec2, name)
+ if regnum is None:
+ regnum, is_vec = yield from get_pdecode_idx_out2(self.dec2, name)
+
+ # in case getting the register number is needed, _RA, _RB
+ regname = "_" + name
+ self.namespace[regname] = regnum
+ 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(regnum))
+ elif name is not None:
+ reg_val = SelectableInt(self.gpr(regnum))
+ else:
+ log('zero input reg %s %s' % (name, str(regnum)), is_vec)
+ reg_val = 0
+ return reg_val
+
+ def remap_debug(self, remaps):
+ # just some convenient debug info
+ for i in range(4):
+ sname = 'SVSHAPE%d' % i
+ shape = self.spr[sname]
+ log(sname, bin(shape.value))
+ log(" lims", shape.lims)
+ log(" mode", shape.mode)
+ log(" skip", shape.skip)
+
+ # set up the list of steps to remap
+ mi0 = self.svstate.mi0
+ mi1 = self.svstate.mi1
+ mi2 = self.svstate.mi2
+ mo0 = self.svstate.mo0
+ mo1 = self.svstate.mo1
+ steps = [(self.dec2.in1_step, mi0), # RA
+ (self.dec2.in2_step, mi1), # RB
+ (self.dec2.in3_step, mi2), # RC
+ (self.dec2.o_step, mo0), # RT
+ (self.dec2.o2_step, mo1), # EA
+ ]
+ remap_idxs = self.remap_idxs
+ rremaps = []
+ # now cross-index the required SHAPE for each of 3-in 2-out regs
+ rnames = ['RA', 'RB', 'RC', 'RT', 'EA']
+ for i, (dstep, shape_idx) in enumerate(steps):
+ (shape, remap) = remaps[shape_idx]
+ remap_idx = remap_idxs[shape_idx]
+ # zero is "disabled"
+ if shape.value == 0x0:
+ continue
+ # now set the actual requested step to the current index
+ yield dstep.eq(remap_idx)
+
+ # debug printout info
+ rremaps.append((shape.mode, i, rnames[i], shape_idx, remap_idx))
+ for x in rremaps:
+ log("shape remap", x)
+
+ def check_write(self, info, name, output, carry_en):
+ if name == 'overflow': # ignore, done already (above)
+ return
+ if isinstance(output, int):
+ output = SelectableInt(output, 256)
+ if name in ['CA', 'CA32']:
+ if carry_en:
+ log("writing %s to XER" % name, output)
+ self.spr['XER'][XER_bits[name]] = output.value
+ else:
+ log("NOT writing %s to XER" % name, output)
+ elif name in info.special_regs:
+ log('writing special %s' % name, output, special_sprs)
+ if name in special_sprs:
+ self.spr[name] = output
+ else:
+ self.namespace[name].eq(output)
+ if name == 'MSR':
+ log('msr written', hex(self.msr.value))
+ else:
+ regnum, is_vec = yield from get_pdecode_idx_out(self.dec2, name)
+ if regnum is None:
+ regnum, is_vec = yield from get_pdecode_idx_out2(
+ self.dec2, name)
+ if regnum is None:
+ # temporary hack for not having 2nd output
+ regnum = yield getattr(self.decoder, name)
+ is_vec = False
+ if self.is_svp64_mode and self.pred_dst_zero:
+ log('zeroing reg %d %s' % (regnum, str(output)),
+ is_vec)
+ output = SelectableInt(0, 256)
+ else:
+ if name in fregs:
+ ftype = 'fpr'
else:
- regnum, is_vec = yield from get_pdecode_idx_out(self.dec2,
- name)
- if regnum is None:
- regnum, is_vec = yield from get_pdecode_idx_out2(
- self.dec2, name)
- if regnum is None:
- # temporary hack for not having 2nd output
- regnum = yield getattr(self.decoder, name)
- is_vec = False
- if self.is_svp64_mode and pred_dst_zero:
- log('zeroing reg %d %s' % (regnum, str(output)),
- is_vec)
- output = SelectableInt(0, 256)
- else:
- if name in fregs:
- ftype = 'fpr'
- else:
- ftype = 'gpr'
- log('writing %s %s %s' % (regnum, ftype, str(output)),
- is_vec)
- if output.bits > 64:
- output = SelectableInt(output.value, 64)
- if name in fregs:
- self.fpr[regnum] = output
- else:
- self.gpr[regnum] = output
+ ftype = 'gpr'
+ log('writing %s %s %s' % (ftype, regnum, str(output)),
+ is_vec)
+ if output.bits > 64:
+ output = SelectableInt(output.value, 64)
+ if name in fregs:
+ self.fpr[regnum] = output
+ else:
+ self.gpr[regnum] = output
+ def check_step_increment(self, results, rc_en, asmop, ins_name):
# check if it is the SVSTATE.src/dest step that needs incrementing
# this is our Sub-Program-Counter loop from 0 to VL-1
+ pre = False
+ post = False
+ nia_update = True
+ if self.allow_next_step_inc:
+ log("SVSTATE_NEXT: inc requested, mode",
+ self.svstate_next_mode, self.allow_next_step_inc)
+ yield from self.svstate_pre_inc()
+ pre = yield from self.update_new_svstate_steps()
+ if pre:
+ # reset at end of loop including exit Vertical Mode
+ log("SVSTATE_NEXT: end of loop, reset")
+ self.svp64_reset_loop()
+ self.svstate.vfirst = 0
+ self.update_nia()
+ if not rc_en:
+ return True
+ results = [SelectableInt(0, 64)]
+ self.handle_comparison(results) # CR0
+ return True
+ if self.allow_next_step_inc == 2:
+ log("SVSTATE_NEXT: read")
+ nia_update = (yield from self.svstate_post_inc(ins_name))
+ else:
+ log("SVSTATE_NEXT: post-inc")
+ # use actual src/dst-step here to check end, do NOT
+ # use bit-reversed version
+ srcstep, dststep = self.new_srcstep, self.new_dststep
+ ssubstep, dsubstep = self.new_ssubstep, self.new_dsubstep
+ remaps = self.get_remap_indices()
+ remap_idxs = self.remap_idxs
+ vl = self.svstate.vl
+ subvl = yield self.dec2.rm_dec.rm_in.subvl
+ end_src = srcstep == vl-1
+ end_dst = dststep == vl-1
+ if self.allow_next_step_inc != 2:
+ yield from self.advance_svstate_steps(end_src, end_dst)
+ self.namespace['SVSTATE'] = self.svstate.spr
+ # set CR0 (if Rc=1) based on end
+ if rc_en:
+ endtest = 1 if (end_src or end_dst) else 0
+ #results = [SelectableInt(endtest, 64)]
+ # self.handle_comparison(results) # CR0
+
+ # see if svstep was requested, if so, which SVSTATE
+ endings = 0b111
+ if self.svstate_next_mode > 0:
+ shape_idx = self.svstate_next_mode.value-1
+ endings = self.remap_loopends[shape_idx]
+ cr_field = SelectableInt((~endings) << 1 | endtest, 4)
+ print("svstep Rc=1, CR0", cr_field)
+ self.crl[0].eq(cr_field) # CR0
+ if end_src or end_dst:
+ # reset at end of loop including exit Vertical Mode
+ log("SVSTATE_NEXT: after increments, reset")
+ self.svp64_reset_loop()
+ self.svstate.vfirst = 0
+ return nia_update
+
if self.is_svp64_mode:
- # XXX twin predication TODO
- vl = self.svstate.vl.asint(msb0=True)
- mvl = self.svstate.maxvl.asint(msb0=True)
- srcstep = self.svstate.srcstep.asint(msb0=True)
- dststep = self.svstate.dststep.asint(msb0=True)
- rm_mode = yield self.dec2.rm_dec.mode
- reverse_gear = yield self.dec2.rm_dec.reverse_gear
- sv_ptype = yield self.dec2.dec.op.SV_Ptype
- out_vec = not (yield self.dec2.no_out_vec)
- in_vec = not (yield self.dec2.no_in_vec)
- log (" svstate.vl", vl)
- log (" svstate.mvl", mvl)
- log (" svstate.srcstep", srcstep)
- log (" svstate.dststep", dststep)
- log (" mode", rm_mode)
- log (" reverse", reverse_gear)
- log (" out_vec", out_vec)
- log (" in_vec", in_vec)
- log (" sv_ptype", sv_ptype, sv_ptype == SVPtype.P2.value)
- # check if srcstep needs incrementing by one, stop PC advancing
- # svp64 loop can end early if the dest is scalar for single-pred
- # but for 2-pred both src/dest have to be checked.
- # XXX this might not be true! it may just be LD/ST
+ return (yield from self.svstate_post_inc(ins_name))
+
+ # XXX only in non-SVP64 mode!
+ # record state of whether the current operation was an svshape,
+ # OR svindex!
+ # to be able to know if it should apply in the next instruction.
+ # also (if going to use this instruction) should disable ability
+ # to interrupt in between. sigh.
+ self.last_op_svshape = asmop in ['svremap', 'svindex']
+
+ return True
+
+ def SVSTATE_NEXT(self, mode, submode):
+ """explicitly moves srcstep/dststep on to next element, for
+ "Vertical-First" mode. this function is called from
+ setvl pseudo-code, as a pseudo-op "svstep"
+
+ WARNING: this function uses information that was created EARLIER
+ due to it being in the middle of a yield, but this function is
+ *NOT* called from yield (it's called from compiled pseudocode).
+ """
+ self.allow_next_step_inc = submode.value + 1
+ log("SVSTATE_NEXT mode", mode, submode, self.allow_next_step_inc)
+ self.svstate_next_mode = mode
+ if self.svstate_next_mode > 0 and self.svstate_next_mode < 5:
+ shape_idx = self.svstate_next_mode.value-1
+ return SelectableInt(self.remap_idxs[shape_idx], 7)
+ if self.svstate_next_mode == 5:
+ self.svstate_next_mode = 0
+ return SelectableInt(self.svstate.srcstep, 7)
+ if self.svstate_next_mode == 6:
+ self.svstate_next_mode = 0
+ return SelectableInt(self.svstate.dststep, 7)
+ return SelectableInt(0, 7)
+
+ def svstate_pre_inc(self):
+ """check if srcstep/dststep need to skip over masked-out predicate bits
+ note that this is not supposed to do anything to substep,
+ it is purely for skipping masked-out bits
+ """
+ # get SVSTATE VL (oh and print out some debug stuff)
+ vl = self.svstate.vl
+ subvl = yield self.dec2.rm_dec.rm_in.subvl
+ srcstep = self.svstate.srcstep
+ dststep = self.svstate.dststep
+ ssubstep = self.svstate.ssubstep
+ dsubstep = self.svstate.dsubstep
+ sv_a_nz = yield self.dec2.sv_a_nz
+ fft_mode = yield self.dec2.use_svp64_fft
+ in1 = yield self.dec2.e.read_reg1.data
+ log("SVP64: VL, subvl, srcstep, dststep, ssubstep, dsybstep, sv_a_nz, "
+ "in1 fft, svp64",
+ vl, subvl, srcstep, dststep, ssubstep, dsubstep,
+ sv_a_nz, in1, fft_mode,
+ self.is_svp64_mode)
+
+ # get predicate mask (all 64 bits)
+ srcmask = dstmask = 0xffff_ffff_ffff_ffff
+
+ pmode = yield self.dec2.rm_dec.predmode
+ pack = yield self.dec2.rm_dec.pack
+ unpack = yield self.dec2.rm_dec.unpack
+ reverse_gear = yield self.dec2.rm_dec.reverse_gear
+ sv_ptype = yield self.dec2.dec.op.SV_Ptype
+ srcpred = yield self.dec2.rm_dec.srcpred
+ dstpred = yield self.dec2.rm_dec.dstpred
+ pred_src_zero = yield self.dec2.rm_dec.pred_sz
+ pred_dst_zero = yield self.dec2.rm_dec.pred_dz
+ if pmode == SVP64PredMode.INT.value:
+ srcmask = dstmask = get_predint(self.gpr, dstpred)
if sv_ptype == SVPtype.P2.value:
- svp64_is_vector = (out_vec or in_vec)
- else:
- svp64_is_vector = out_vec
- if svp64_is_vector and srcstep != vl-1 and dststep != vl-1:
- self.svstate.srcstep += SelectableInt(1, 7)
- self.svstate.dststep += SelectableInt(1, 7)
- self.pc.NIA.value = self.pc.CIA.value
- self.namespace['NIA'] = self.pc.NIA
- self.namespace['SVSTATE'] = self.svstate.spr
- log("end of sub-pc call", self.namespace['CIA'],
- self.namespace['NIA'])
- return # DO NOT allow PC to update whilst Sub-PC loop running
- # reset loop to zero
+ srcmask = get_predint(self.gpr, srcpred)
+ elif pmode == SVP64PredMode.CR.value:
+ srcmask = dstmask = get_predcr(self.crl, dstpred, vl)
+ if sv_ptype == SVPtype.P2.value:
+ srcmask = get_predcr(self.crl, srcpred, vl)
+ # work out if the ssubsteps are completed
+ ssubstart = ssubstep == 0
+ dsubstart = dsubstep == 0
+ log(" pmode", pmode)
+ log(" pack/unpack", pack, unpack)
+ log(" reverse", reverse_gear)
+ log(" ptype", sv_ptype)
+ log(" srcpred", bin(srcpred))
+ log(" dstpred", bin(dstpred))
+ log(" srcmask", bin(srcmask))
+ log(" dstmask", bin(dstmask))
+ log(" pred_sz", bin(pred_src_zero))
+ log(" pred_dz", bin(pred_dst_zero))
+ log(" ssubstart", ssubstart)
+ log(" dsubstart", dsubstart)
+
+ # okaaay, so here we simply advance srcstep (TODO dststep)
+ # this can ONLY be done at the beginning of the "for" loop
+ # (this is all actually a FSM so it's hell to keep track sigh)
+ if ssubstart:
+ # until the predicate mask has a "1" bit... or we run out of VL
+ # let srcstep==VL be the indicator to move to next instruction
+ if not pred_src_zero:
+ while (((1 << srcstep) & srcmask) == 0) and (srcstep != vl):
+ log(" sskip", bin(1 << srcstep))
+ srcstep += 1
+ if dsubstart:
+ # same for dststep
+ if not pred_dst_zero:
+ while (((1 << dststep) & dstmask) == 0) and (dststep != vl):
+ log(" dskip", bin(1 << dststep))
+ dststep += 1
+
+ # now work out if the relevant mask bits require zeroing
+ if pred_dst_zero:
+ pred_dst_zero = ((1 << dststep) & dstmask) == 0
+ if pred_src_zero:
+ pred_src_zero = ((1 << srcstep) & srcmask) == 0
+
+ # store new srcstep / dststep
+ self.new_srcstep, self.new_dststep = (srcstep, dststep)
+ self.new_ssubstep, self.new_dsubstep = (ssubstep, dsubstep)
+ self.pred_dst_zero, self.pred_src_zero = (pred_dst_zero, pred_src_zero)
+ log(" new srcstep", srcstep)
+ log(" new dststep", dststep)
+ log(" new ssubstep", ssubstep)
+ log(" new dsubstep", dsubstep)
+
+ def get_src_dststeps(self):
+ """gets srcstep, dststep, and ssubstep, dsubstep
+ """
+ return (self.new_srcstep, self.new_dststep,
+ self.new_ssubstep, self.new_dsubstep)
+
+ def update_new_svstate_steps(self):
+ # note, do not get the bit-reversed srcstep here!
+ srcstep, dststep = self.new_srcstep, self.new_dststep
+ ssubstep, dsubstep = self.new_ssubstep, self.new_dsubstep
+
+ # update SVSTATE with new srcstep
+ self.svstate.srcstep = srcstep
+ self.svstate.dststep = dststep
+ self.svstate.ssubstep = ssubstep
+ self.svstate.dsubstep = dsubstep
+ self.namespace['SVSTATE'] = self.svstate
+ yield self.dec2.state.svstate.eq(self.svstate.value)
+ yield Settle() # let decoder update
+ srcstep = self.svstate.srcstep
+ dststep = self.svstate.dststep
+ ssubstep = self.svstate.ssubstep
+ dsubstep = self.svstate.dsubstep
+ vl = self.svstate.vl
+ subvl = yield self.dec2.rm_dec.rm_in.subvl
+ log(" srcstep", srcstep)
+ log(" dststep", dststep)
+ log(" ssubstep", ssubstep)
+ log(" dsubstep", dsubstep)
+ log(" vl", vl)
+ log(" subvl", subvl)
+
+ # check if end reached (we let srcstep overrun, above)
+ # nothing needs doing (TODO zeroing): just do next instruction
+ return srcstep == vl or dststep == vl
+
+ def svstate_post_inc(self, insn_name, vf=0):
+ # check if SV "Vertical First" mode is enabled
+ vfirst = self.svstate.vfirst
+ log(" SV Vertical First", vf, vfirst)
+ if not vf and vfirst == 1:
+ self.update_nia()
+ return True
+
+ # check if it is the SVSTATE.src/dest step that needs incrementing
+ # this is our Sub-Program-Counter loop from 0 to VL-1
+ # XXX twin predication TODO
+ vl = self.svstate.vl
+ subvl = yield self.dec2.rm_dec.rm_in.subvl
+ mvl = self.svstate.maxvl
+ srcstep = self.svstate.srcstep
+ dststep = self.svstate.dststep
+ ssubstep = self.svstate.ssubstep
+ dsubstep = self.svstate.dsubstep
+ rm_mode = yield self.dec2.rm_dec.mode
+ reverse_gear = yield self.dec2.rm_dec.reverse_gear
+ sv_ptype = yield self.dec2.dec.op.SV_Ptype
+ out_vec = not (yield self.dec2.no_out_vec)
+ in_vec = not (yield self.dec2.no_in_vec)
+ log(" svstate.vl", vl)
+ log(" svstate.mvl", mvl)
+ log(" rm.subvl", subvl)
+ log(" svstate.srcstep", srcstep)
+ log(" svstate.dststep", dststep)
+ log(" svstate.ssubstep", ssubstep)
+ log(" svstate.dsubstep", dsubstep)
+ log(" mode", rm_mode)
+ log(" reverse", reverse_gear)
+ log(" out_vec", out_vec)
+ log(" in_vec", in_vec)
+ log(" sv_ptype", sv_ptype, sv_ptype == SVPtype.P2.value)
+ # check if srcstep needs incrementing by one, stop PC advancing
+ # svp64 loop can end early if the dest is scalar for single-pred
+ # but for 2-pred both src/dest have to be checked.
+ # XXX this might not be true! it may just be LD/ST
+ if sv_ptype == SVPtype.P2.value:
+ svp64_is_vector = (out_vec or in_vec)
+ else:
+ svp64_is_vector = out_vec
+ # check if this was an sv.bc* and if so did it succeed
+ if self.is_svp64_mode and insn_name.startswith("sv.bc"):
+ end_loop = self.namespace['end_loop']
+ log("branch %s end_loop" % insn_name, end_loop)
+ if end_loop.value:
+ self.svp64_reset_loop()
+ self.update_pc_next()
+ return False
+ # loops end at the first "hit" (source or dest)
+ loopend = ((srcstep == vl-1 and ssubstep == subvl) or
+ (dststep == vl-1 and dsubstep == subvl))
+ if not svp64_is_vector or loopend:
+ # reset loop to zero and update NIA
self.svp64_reset_loop()
+ self.update_nia()
- self.update_pc_next()
+ return True
+
+ # still looping, advance and update NIA
+ yield from self.advance_svstate_steps()
+ self.namespace['SVSTATE'] = self.svstate
+ # 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.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
+
+ def advance_svstate_steps(self, end_src=False, end_dst=False):
+ """ advance sub/steps. note that Pack/Unpack *INVERTS* the order.
+ TODO when Pack/Unpack is set, substep becomes the *outer* loop
+ """
+ subvl = yield self.dec2.rm_dec.rm_in.subvl
+ # first source step
+ ssubstep = self.svstate.ssubstep
+ end_sub = ssubstep == subvl
+ if end_sub:
+ if not end_src:
+ self.svstate.srcstep += SelectableInt(1, 7)
+ self.svstate.ssubstep = SelectableInt(0, 2) # reset
+ else:
+ self.svstate.ssubstep += SelectableInt(1, 2) # advance ssubstep
+ # now dest step
+ dsubstep = self.svstate.dsubstep
+ end_sub = dsubstep == subvl
+ if end_sub:
+ if not end_dst:
+ self.svstate.dststep += SelectableInt(1, 7)
+ self.svstate.dsubstep = SelectableInt(0, 2) # reset
+ else:
+ self.svstate.dsubstep += SelectableInt(1, 2) # advance ssubstep
def update_pc_next(self):
# UPDATE program counter
self.pc.update(self.namespace, self.is_svp64_mode)
self.svstate.spr = self.namespace['SVSTATE']
log("end of call", self.namespace['CIA'],
- self.namespace['NIA'],
- self.namespace['SVSTATE'])
+ self.namespace['NIA'],
+ self.namespace['SVSTATE'])
def svp64_reset_loop(self):
- self.svstate.srcstep[0:7] = 0
- self.svstate.dststep[0:7] = 0
- log (" svstate.srcstep loop end (PC to update)")
+ self.svstate.srcstep = 0
+ self.svstate.dststep = 0
+ self.svstate.ssubstep = 0
+ self.svstate.dsubstep = 0
+ log(" svstate.srcstep loop end (PC to update)")
+ self.namespace['SVSTATE'] = self.svstate
+
+ def update_nia(self):
self.pc.update_nia(self.is_svp64_mode)
self.namespace['NIA'] = self.pc.NIA
- self.namespace['SVSTATE'] = self.svstate.spr
def inject():
context = args[0].namespace # variables to be injected
saved_values = func_globals.copy() # Shallow copy of dict.
+ log("globals before", context.keys())
func_globals.update(context)
result = func(*args, **kwargs)
log("globals after", func_globals['CIA'], func_globals['NIA'])
log("args[0]", args[0].namespace['CIA'],
- args[0].namespace['NIA'],
- args[0].namespace['SVSTATE'])
+ args[0].namespace['NIA'],
+ args[0].namespace['SVSTATE'])
+ if 'end_loop' in func_globals:
+ log("args[0] end_loop", func_globals['end_loop'])
args[0].namespace = func_globals
#exec (func.__code__, func_globals)
return decorator
return variable_injector
-
-