from openpower.sv.trans.svp64 import SVP64Asm
from openpower.consts import SVP64CROffs
from openpower.decoder.helpers import fp64toselectable
+from openpower.decoder.isa.remap_dct_yield import (halfrev2, reverse_bits,
+ )
from copy import deepcopy
self.assertEqual(sim.gpr(12), SelectableInt(0x1234, 64))
self.assertEqual(sim.gpr(13), SelectableInt(0x1235, 64))
- def test_sv_load_store_bitreverse(self):
+ def test_sv_load_store_shifted(self):
""">>> lst = ["addi 1, 0, 0x0010",
"addi 2, 0, 0x0004",
"addi 3, 0, 0x0002",
"addi 7, 0, 0x303",
"addi 8, 0, 0x404",
"sv.stw 5.v, 0(1)",
- "sv.lwzbr 12.v, 4(1), 2"]
+ "sv.lwzsh 12.v, 4(1), 2"]
- note: bitreverse mode is... odd. it's the butterfly generator
- from Cooley-Tukey FFT:
- https://en.wikipedia.org/wiki/Cooley%E2%80%93Tukey_FFT_algorithm#Data_reordering,_bit_reversal,_and_in-place_algorithms
-
- bitreverse LD is computed as:
+ shifted LD is computed as:
for i in range(VL):
- EA = (RA|0) + (EXTS(D) * LDSTsize * bitreverse(i, VL)) << RC
-
- bitreversal of 0 1 2 3 in binary 0b00 0b01 0b10 0b11
- produces 0 2 1 3 in binary 0b00 0b10 0b01 0b11
-
- and thus creates the butterfly needed for one iteration of FFT.
- the RC (shift) is to be able to offset the LDs by Radix-2 spans
+ EA = (RA|0) + (EXTS(D) * LDSTsize * i) << RC
"""
lst = SVP64Asm(["addi 1, 0, 0x0010",
"addi 2, 0, 0x0000",
"addi 7, 0, 0x303",
"addi 8, 0, 0x404",
"sv.stw 5.v, 0(1)", # scalar r1 + 0 + wordlen*offs
- "sv.lwzbr 12.v, 4(1), 2"]) # bit-reversed
+ "sv.lwzsh 12.v, 4(1), 2"]) # bit-reversed
lst = list(lst)
# SVSTATE (in this case, VL=4)
self.assertEqual(sim.gpr(7), SelectableInt(0x303, 64))
self.assertEqual(sim.gpr(8), SelectableInt(0x404, 64))
# r1=0x10, RC=0, offs=4: contents of memory expected at:
+ # element 0: EA = r1 + 0b00*4 => 0x10 + 0b00*4 => 0x10
+ # element 1: EA = r1 + 0b01*4 => 0x10 + 0b01*4 => 0x18
+ # element 2: EA = r1 + 0b10*4 => 0x10 + 0b10*4 => 0x14
+ # element 3: EA = r1 + 0b11*4 => 0x10 + 0b11*4 => 0x1c
+ # therefore loaded from (bit-reversed indexing):
+ # r9 => mem[0x10] which was stored from r5
+ # r10 => mem[0x18] which was stored from r6
+ # r11 => mem[0x18] which was stored from r7
+ # r12 => mem[0x1c] which was stored from r8
+ self.assertEqual(sim.gpr(12), SelectableInt(0x101, 64))
+ self.assertEqual(sim.gpr(13), SelectableInt(0x202, 64))
+ self.assertEqual(sim.gpr(14), SelectableInt(0x303, 64))
+ self.assertEqual(sim.gpr(15), SelectableInt(0x404, 64))
+
+ def test_sv_load_store_shifted_fp(self):
+ """>>> lst = ["addi 1, 0, 0x0010",
+ "addi 2, 0, 0x0004",
+ "addi 3, 0, 0x0002",
+ "addi 5, 0, 0x101",
+ "addi 6, 0, 0x202",
+ "addi 7, 0, 0x303",
+ "addi 8, 0, 0x404",
+ "sv.std 5.v, 0(1)",
+ "sv.lfdbr 12.v, 4(1), 2"]
+
+ shifted LD is computed as:
+ for i in range(VL):
+ EA = (RA|0) + (EXTS(D) * LDSTsize * i) << RC
+ """
+ lst = SVP64Asm(["addi 1, 0, 0x0010",
+ "addi 2, 0, 0x0000",
+ "addi 5, 0, 0x101",
+ "addi 6, 0, 0x202",
+ "addi 7, 0, 0x303",
+ "addi 8, 0, 0x404",
+ "sv.std 5.v, 0(1)", # scalar r1 + 0 + wordlen*offs
+ "sv.lfdsh 12.v, 8(1), 2"]) # shifted
+ lst = list(lst)
+
+ # SVSTATE (in this case, VL=4)
+ svstate = SVP64State()
+ svstate.vl = 4 # VL
+ svstate.maxvl = 4 # MAXVL
+ print ("SVSTATE", bin(svstate.asint()))
+
+ fprs = [0] * 32
+
+ with Program(lst, bigendian=False) as program:
+ sim = self.run_tst_program(program, svstate=svstate,
+ initial_fprs=fprs)
+ mem = sim.mem.dump(printout=False)
+ print (mem)
+
+ self.assertEqual(mem, [(16, 0x101),
+ (24, 0x202),
+ (32, 0x303),
+ (40, 0x404),
+ ])
+ print(sim.gpr(1))
+ # from STs
+ self.assertEqual(sim.gpr(5), SelectableInt(0x101, 64))
+ self.assertEqual(sim.gpr(6), SelectableInt(0x202, 64))
+ self.assertEqual(sim.gpr(7), SelectableInt(0x303, 64))
+ self.assertEqual(sim.gpr(8), SelectableInt(0x404, 64))
+ # r1=0x10, RC=0, offs=4: contents of memory expected at:
# element 0: EA = r1 + bitrev(0b00)*4 => 0x10 + 0b00*4 => 0x10
# element 1: EA = r1 + bitrev(0b01)*4 => 0x10 + 0b10*4 => 0x18
# element 2: EA = r1 + bitrev(0b10)*4 => 0x10 + 0b01*4 => 0x14
# r10 => mem[0x18] which was stored from r6
# r11 => mem[0x18] which was stored from r7
# r12 => mem[0x1c] which was stored from r8
- self.assertEqual(sim.gpr(12), SelectableInt(0x101, 64))
- self.assertEqual(sim.gpr(13), SelectableInt(0x303, 64))
- self.assertEqual(sim.gpr(14), SelectableInt(0x202, 64))
- self.assertEqual(sim.gpr(15), SelectableInt(0x404, 64))
+ self.assertEqual(sim.fpr(12), SelectableInt(0x101, 64))
+ self.assertEqual(sim.fpr(13), SelectableInt(0x202, 64))
+ self.assertEqual(sim.fpr(14), SelectableInt(0x303, 64))
+ self.assertEqual(sim.fpr(15), SelectableInt(0x404, 64))
- def test_sv_load_store_bitreverse2(self):
+ def test_sv_load_store_shifted2(self):
""">>> lst = ["addi 1, 0, 0x0010",
"addi 2, 0, 0x0004",
"addi 3, 0, 0x0002",
"sv.stfs 4.v, 0(1)",
- "sv.lfsbr 12.v, 4(1), 2"]
-
- note: bitreverse mode is... odd. it's the butterfly generator
- from Cooley-Tukey FFT:
- https://en.wikipedia.org/wiki/Cooley%E2%80%93Tukey_FFT_algorithm#Data_reordering,_bit_reversal,_and_in-place_algorithms
+ "sv.lfssh 12.v, 4(1), 2"]
- bitreverse LD is computed as:
+ shifted LD is computed as:
for i in range(VL):
- EA = (RA|0) + (EXTS(D) * LDSTsize * bitreverse(i, VL)) << RC
+ EA = (RA|0) + (EXTS(D) * LDSTsize * i) << RC
- bitreversal of 0 1 2 3 in binary 0b00 0b01 0b10 0b11
- produces 0 2 1 3 in binary 0b00 0b10 0b01 0b11
-
- and thus creates the butterfly needed for one iteration of FFT.
- the RC (shift) is to be able to offset the LDs by Radix-2 spans
"""
lst = SVP64Asm(["addi 1, 0, 0x0010",
"addi 2, 0, 0x0000",
"sv.stfs 4.v, 0(1)", # scalar r1 + 0 + wordlen*offs
- "sv.lfsbr 12.v, 4(1), 2"]) # bit-reversed
+ "sv.lfssh 12.v, 4(1), 2"]) # shifted (by zero, but hey)
lst = list(lst)
# SVSTATE (in this case, VL=4)
# expected results, remember that bit-reversed load has been done
expected_fprs = deepcopy(fprs)
expected_fprs[12] = fprs[4] # 0b00 -> 0b00
- expected_fprs[13] = fprs[6] # 0b01 -> 0b10
- expected_fprs[14] = fprs[5] # 0b10 -> 0b01
+ expected_fprs[13] = fprs[5] # 0b10 -> 0b01
+ expected_fprs[14] = fprs[6] # 0b01 -> 0b10
expected_fprs[15] = fprs[7] # 0b11 -> 0b11
with Program(lst, bigendian=False) as program:
# (24, 0x040400000303)])
self._check_fpregs(sim, expected_fprs)
- def test_sv_load_store_bitreverse_remap(self):
+ def test_sv_load_store_remap_matrix(self):
""">>> lst = ["addi 1, 0, 0x0010",
"addi 2, 0, 0x0004",
"addi 3, 0, 0x0002",
"addi 6, 0, 0x202",
"addi 7, 0, 0x303",
"addi 8, 0, 0x404",
- "sv.stw 5.v, 0(1)",
- "svshape 4, 4, 4, 0, 0",
- "svremap 31, 1, 2, 3, 0, 0, 0, 0",
- "sv.lwzbr 12.v, 4(1), 2"]
-
- note: bitreverse mode is... odd. it's the butterfly generator
- from Cooley-Tukey FFT:
- https://en.wikipedia.org/wiki/Cooley%E2%80%93Tukey_FFT_algorithm#Data_reordering,_bit_reversal,_and_in-place_algorithms
-
- bitreverse LD is computed as:
- for i in range(VL):
- EA = (RA|0) + (EXTS(D) * LDSTsize * bitreverse(i, VL)) << RC
-
- bitreversal of 0 1 2 3 in binary 0b00 0b01 0b10 0b11
- produces 0 2 1 3 in binary 0b00 0b10 0b01 0b11
+ "sv.stw 4.v, 0(1)", # scalar r1 + 0 + wordlen*offs
+ "svshape 3, 3, 4, 0, 0",
+ "svremap 1, 1, 2, 0, 0, 0, 0, 1",
+ "sv.lwz 20.v, 0(1)",
+ ]
- and thus creates the butterfly needed for one iteration of FFT.
- the RC (shift) is to be able to offset the LDs by Radix-2 spans
+ REMAPed a LD operation via a Matrix Multiply Schedule,
+ which is set up as 3x4 result
"""
lst = SVP64Asm(["addi 1, 0, 0x0010",
"addi 2, 0, 0x0000",
"addi 9, 0, 0x606",
"addi 10, 0, 0x707",
"addi 11, 0, 0x808",
+ "addi 12, 0, 0x909",
+ "addi 13, 0, 0xa0a",
+ "addi 14, 0, 0xb0b",
+ "addi 15, 0, 0xc0c",
+ "addi 16, 0, 0xd0d",
+ "addi 17, 0, 0xe0e",
+ "addi 18, 0, 0xf0f",
"sv.stw 4.v, 0(1)", # scalar r1 + 0 + wordlen*offs
- "svshape 4, 4, 2, 0, 0",
- "svremap 31, 1, 2, 3, 0, 0, 0, 1",
- #"setvl 0, 0, 8, 0, 1, 1",
- "sv.lwzbr 12.v, 4(1), 2"]) # bit-reversed
+ "svshape 3, 3, 4, 0, 0",
+ "svremap 1, 1, 2, 0, 0, 0, 0, 1",
+ "sv.lwz 20.v, 0(1)",
+ #"sv.lwzsh 12.v, 4(1), 2", # bit-reversed
+ ])
lst = list(lst)
# SVSTATE (in this case, VL=4)
svstate = SVP64State()
- svstate.vl = 8 # VL
- svstate.maxvl = 8 # MAXVL
+ svstate.vl = 12 # VL
+ svstate.maxvl = 12 # MAXVL
print ("SVSTATE", bin(svstate.asint()))
regs = [0] * 64
self.assertEqual(mem, [(16, 0x020200000101),
(24, 0x040400000303),
(32, 0x060600000505),
- (40, 0x080800000707)])
+ (40, 0x080800000707),
+ (48, 0x0a0a00000909),
+ (56, 0x0c0c00000b0b)])
print(sim.gpr(1))
# from STs
self.assertEqual(sim.gpr(4), SelectableInt(0x101, 64))
self.assertEqual(sim.gpr(11), SelectableInt(0x808, 64))
# combination of bit-reversed load with a Matrix REMAP
# schedule
- self.assertEqual(sim.gpr(12), SelectableInt(0x101, 64))
- self.assertEqual(sim.gpr(13), SelectableInt(0x505, 64))
- self.assertEqual(sim.gpr(14), SelectableInt(0x303, 64))
- self.assertEqual(sim.gpr(15), SelectableInt(0x707, 64))
- self.assertEqual(sim.gpr(16), SelectableInt(0x202, 64))
- self.assertEqual(sim.gpr(17), SelectableInt(0x606, 64))
- self.assertEqual(sim.gpr(18), SelectableInt(0x404, 64))
- self.assertEqual(sim.gpr(19), SelectableInt(0x808, 64))
+ for i in range(3):
+ self.assertEqual(sim.gpr(20+i), SelectableInt(0x101, 64))
+ self.assertEqual(sim.gpr(23+i), SelectableInt(0x505, 64))
+ self.assertEqual(sim.gpr(26+i), SelectableInt(0x909, 64))
+ self.assertEqual(sim.gpr(29+i), SelectableInt(0x202, 64))
+
+ def test_sv_load_store_bitreverse_remap_halfswap(self):
+ """>>> lst = ["addi 1, 0, 0x0010",
+ "addi 2, 0, 0x0000",
+ "addi 4, 0, 0x101",
+ "addi 5, 0, 0x202",
+ "addi 6, 0, 0x303",
+ "addi 7, 0, 0x404",
+ "addi 8, 0, 0x505",
+ "addi 9, 0, 0x606",
+ "addi 10, 0, 0x707",
+ "addi 11, 0, 0x808",
+ "sv.stw 5.v, 0(1)",
+ "svshape 8, 1, 1, 6, 0",
+ "svremap 31, 1, 2, 3, 0, 0, 0, 0",
+ "sv.lwzsh 12.v, 4(1), 2"]
+
+ shifted LD is computed as:
+ for i in range(VL):
+ EA = (RA|0) + (EXTS(D) * LDSTsize * i) << RC
+
+ bitreversal of 0 1 2 3 in binary 0b00 0b01 0b10 0b11
+ produces 0 2 1 3 in binary 0b00 0b10 0b01 0b11
+
+ and thus creates the butterfly needed for one iteration of FFT.
+ the RC (shift) is to be able to offset the LDs by Radix-2 spans
+
+ on top of the bit-reversal is a REMAP for half-swaps for DCT
+ in-place.
+ """
+ lst = SVP64Asm(["addi 1, 0, 0x0010",
+ "addi 2, 0, 0x0000",
+ "addi 4, 0, 0x001",
+ "addi 5, 0, 0x102",
+ "addi 6, 0, 0x203",
+ "addi 7, 0, 0x304",
+ "addi 8, 0, 0x405",
+ "addi 9, 0, 0x506",
+ "addi 10, 0, 0x607",
+ "addi 11, 0, 0x708",
+ "sv.stw 4.v, 0(1)", # scalar r1 + 0 + wordlen*offs
+ "svshape 8, 1, 1, 6, 0",
+ "svremap 1, 0, 0, 0, 0, 0, 0, 1",
+ #"setvl 0, 0, 8, 0, 1, 1",
+ "sv.lwzsh 12.v, 4(1), 2", # bit-reversed
+ #"sv.lwz 12.v, 0(1)"
+ ])
+ lst = list(lst)
+
+ # SVSTATE (in this case, VL=4)
+ svstate = SVP64State()
+ svstate.vl = 8 # VL
+ svstate.maxvl = 8 # MAXVL
+ print ("SVSTATE", bin(svstate.asint()))
+
+ regs = [0] * 64
+
+ avi = [0x001, 0x102, 0x203, 0x304, 0x405, 0x506, 0x607, 0x708]
+ n = len(avi)
+ levels = n.bit_length() - 1
+ ri = list(range(n))
+ ri = [ri[reverse_bits(i, levels)] for i in range(n)]
+ av = halfrev2(avi, False)
+ av = [av[ri[i]] for i in range(n)]
+
+ with Program(lst, bigendian=False) as program:
+ sim = self.run_tst_program(program, svstate=svstate,
+ initial_regs=regs)
+ mem = sim.mem.dump(printout=False)
+ print ("Mem")
+ print (mem)
+
+ self.assertEqual(mem, [(16, 0x010200000001),
+ (24, 0x030400000203),
+ (32, 0x050600000405),
+ (40, 0x070800000607)])
+ # from STs
+ for i in range(len(avi)):
+ print ("st gpr", i, sim.gpr(i+4), hex(avi[i]))
+ for i in range(len(avi)):
+ self.assertEqual(sim.gpr(i+4), avi[i])
+ # combination of bit-reversed load with a DCT half-swap REMAP
+ # schedule
+ for i in range(len(avi)):
+ print ("ld gpr", i, sim.gpr(i+12), hex(av[i]))
+ for i in range(len(avi)):
+ self.assertEqual(sim.gpr(i+12), av[i])
+
+ def test_sv_load_store_bitreverse_remap_halfswap_idct(self):
+ """>>> lst = ["addi 1, 0, 0x0010",
+ "addi 2, 0, 0x0000",
+ "addi 4, 0, 0x101",
+ "addi 5, 0, 0x202",
+ "addi 6, 0, 0x303",
+ "addi 7, 0, 0x404",
+ "addi 8, 0, 0x505",
+ "addi 9, 0, 0x606",
+ "addi 10, 0, 0x707",
+ "addi 11, 0, 0x808",
+ "sv.stw 5.v, 0(1)",
+ "svshape 8, 1, 1, 6, 0",
+ "svremap 31, 1, 2, 3, 0, 0, 0, 0",
+ "sv.lwzsh 12.v, 4(1), 2"]
+
+ bitreverse LD is computed as:
+ for i in range(VL):
+ EA = (RA|0) + (EXTS(D) * LDSTsize * i) << RC
+
+ bitreversal of 0 1 2 3 in binary 0b00 0b01 0b10 0b11
+ produces 0 2 1 3 in binary 0b00 0b10 0b01 0b11
+
+ and thus creates the butterfly needed for one iteration of FFT.
+ the RC (shift) is to be able to offset the LDs by Radix-2 spans
+
+ on top of the bit-reversal is a REMAP for half-swaps for DCT
+ in-place.
+ """
+ lst = SVP64Asm(["addi 1, 0, 0x0010",
+ "addi 2, 0, 0x0000",
+ "addi 4, 0, 0x001",
+ "addi 5, 0, 0x102",
+ "addi 6, 0, 0x203",
+ "addi 7, 0, 0x304",
+ "addi 8, 0, 0x405",
+ "addi 9, 0, 0x506",
+ "addi 10, 0, 0x607",
+ "addi 11, 0, 0x708",
+ "sv.stw 4.v, 0(1)", # scalar r1 + 0 + wordlen*offs
+ "svshape 8, 1, 1, 14, 0",
+ "svremap 16, 0, 0, 0, 0, 0, 0, 1",
+ #"setvl 0, 0, 8, 0, 1, 1",
+ "sv.lwzsh 12.v, 4(1), 2", # bit-reversed
+ #"sv.lwz 12.v, 0(1)"
+ ])
+ lst = list(lst)
+
+ # SVSTATE (in this case, VL=4)
+ svstate = SVP64State()
+ svstate.vl = 8 # VL
+ svstate.maxvl = 8 # MAXVL
+ print ("SVSTATE", bin(svstate.asint()))
+
+ regs = [0] * 64
+
+ avi = [0x001, 0x102, 0x203, 0x304, 0x405, 0x506, 0x607, 0x708]
+ n = len(avi)
+ levels = n.bit_length() - 1
+ ri = list(range(n))
+ ri = [ri[reverse_bits(i, levels)] for i in range(n)]
+ av = [avi[ri[i]] for i in range(n)]
+ av = halfrev2(av, True)
+
+ with Program(lst, bigendian=False) as program:
+ sim = self.run_tst_program(program, svstate=svstate,
+ initial_regs=regs)
+ mem = sim.mem.dump(printout=False)
+ print ("Mem")
+ print (mem)
+
+ self.assertEqual(mem, [(16, 0x010200000001),
+ (24, 0x030400000203),
+ (32, 0x050600000405),
+ (40, 0x070800000607)])
+ # from STs
+ for i in range(len(avi)):
+ print ("st gpr", i, sim.gpr(i+4), hex(avi[i]))
+ for i in range(len(avi)):
+ self.assertEqual(sim.gpr(i+4), avi[i])
+ # combination of bit-reversed load with a DCT half-swap REMAP
+ # schedule
+ for i in range(len(avi)):
+ print ("ld gpr", i, sim.gpr(i+12), hex(av[i]))
+ for i in range(len(avi)):
+ self.assertEqual(sim.gpr(i+12), av[i])
def run_tst_program(self, prog, initial_regs=None,
svstate=None, initial_fprs=None):
initial_fprs = [0] * 32
simulator = run_tst(prog, initial_regs, svstate=svstate,
initial_fprs=initial_fprs)
+ print ("GPRs")
simulator.gpr.dump()
+ print ("FPRs")
+ simulator.fpr.dump()
return simulator