A result format is a way of representing bits from shots sampled from a circuit. It is some way of converting between a list-of-list-of-bits (a list-of-shots) and a flat string of bytes or characters.
Generally, the result data formats supported by Stim are extremely minimalist. They do not contain metadata about which circuit was run, how many shots were taken, how many bits are in each shot, or even self-identifying information like a header with magic bytes. They produce raw data. Even details about which bits are measurements, which are detection events, and which are observable frame changes must be determined from context.
The major driver for having multiple formats is context-dependent preferences for
binary-vs-human-readable and dense-vs-sparse.
For example, '01
' is a dense text format and 'r8
' is a sparse binary format.
Sometimes you want to be able to eyeball your data, so you want a text format.
Other times you want maximum efficiency, so you want a binary format.
Sometimes your data is high entropy, with as many 1s as 0s, so you use a dense format.
Other times the data is highly biased, with 1s being much rarer and more interesting
than 0s, so you use a sparse format.
The 01 format is a dense human readable format that stores shots as lines of '0' and '1' characters.
The data from each shot is terminated by a newline character '\n'. Each character in the line is a '0' (indicating False) or a '1' (indicating True) corresponding to a measurement result (or a detector result) from a circuit.
This is the default format used by Stim, because it's the easiest to understand.
Example of producing 01 format data using stim's python API:
>>> import pathlib
>>> import stim
>>> import tempfile
>>> with tempfile.TemporaryDirectory() as d:
... path = str(pathlib.Path(d) / "tmp.dat")
... stim.Circuit("""
... X 1
... M 0 0 0 0 1 1 1 1 0 0 1 1 0 1
... """).compile_sampler().sample_write(shots=10, filepath=path, format="01")
... with open(path) as f:
... print(f.read().strip())
00001111001101
00001111001101
00001111001101
00001111001101
00001111001101
00001111001101
00001111001101
00001111001101
00001111001101
00001111001101
Example 01 parsing code (python):
from typing import List
def parse_01(data: str) -> List[List[bool]]:
shots = []
for line in data.split('\n'):
if not line:
continue
shot = []
for c in line:
assert c in '01'
shot.append(c == '1')
shots.append(shot)
return shots
Example 01 saving code (python):
from typing import List
def save_01(shots: List[List[bool]]) -> str:
output = ""
for shot in shots:
for sample in shot:
output += '1' if sample else '0'
output += "\n"
return output
The b8 format is a dense binary format that stores shots as bit-packed bytes.
Each shot is stored into ceil(n / 8) bytes, where n is the number of bits in the shot. Effectively, each shot is padded up to a multiple of 8 by appending False bits, so that shots always start on a byte boundary. Bits are packed into bytes in significance order (the 1s bit is the first bit, the 2s bit is the second, the 4s bit is the third, and so forth until the 128s bit which is the eighth bit).
This format requires the reader to know the number of bits in each shot.
Example of producing b8 format data using stim's python API:
>>> import pathlib
>>> import stim
>>> import tempfile
>>> with tempfile.TemporaryDirectory() as d:
... path = str(pathlib.Path(d) / "tmp.dat")
... stim.Circuit("""
... X 1
... M 0 0 0 0 1 1 1 1 0 0 1 1 0 1
... """).compile_sampler().sample_write(shots=10, filepath=path, format="b8")
... with open(path, 'rb') as f:
... print(' '.join(hex(e)[2:] for e in f.read()))
f0 2c f0 2c f0 2c f0 2c f0 2c f0 2c f0 2c f0 2c f0 2c f0 2c
Example b8 parsing code (python):
from typing import List
def parse_b8(data: bytes, bits_per_shot: int) -> List[List[bool]]:
shots = []
bytes_per_shot = (bits_per_shot + 7) // 8
for offset in range(0, len(data), bytes_per_shot):
shot = []
for k in range(bits_per_shot):
byte = data[offset + k // 8]
bit = (byte >> (k % 8)) % 2 == 1
shot.append(bit)
shots.append(shot)
return shots
Example b8 saving code (python):
from typing import List
def save_b8(shots: List[List[bool]]) -> bytes:
output = b""
for shot in shots:
bytes_per_shot = (len(shot) + 7) // 8
v = 0
for b in reversed(shot):
v <<= 1
v += int(b)
output += v.to_bytes(bytes_per_shot, 'little')
return output
The dets format is a sparse human readable format that stores shots as lines starting with the word 'shot' and then containing space-separated prefixed values like 'D5' and 'L2'. Each value's prefix indicates whether it is a measurement (M), a detector (D), or observable frame change (L) and its integer indicates that the corresponding measurement/detection-event/frame-change was True instead of False.
The data from each shot is started with the text 'shot' and terminated by a newline character '\n'. The rest of the line is a series of integers, separated by spaces and prefixed by a single letter. The prefix letter indicates the type of value ('M' for measurement, 'D' for detector, and 'L' for logical observable). The integer indicates the index of the value. For example, "D1 D3 L0" indicates detectors 1 and 3 fired, and logical observable 0 was flipped.
This format requires the reader to know the number of measurements/detectors/observables in each shot, if the reader wants to produce vectors of bits instead of sets.
Example of producing dets format data using stim's python API:
>>> import pathlib
>>> import stim
>>> import tempfile
>>> with tempfile.TemporaryDirectory() as d:
... path = str(pathlib.Path(d) / "tmp.dat")
... stim.Circuit("""
... X 1
... M 0 0 0 0 1 1 1 1 0 0 1 1 0 1 0 1
... """).compile_sampler().sample_write(shots=3, filepath=path, format="dets")
... with open(path) as f:
... print(f.read().strip())
shot M4 M5 M6 M7 M10 M11 M13 M15
shot M4 M5 M6 M7 M10 M11 M13 M15
shot M4 M5 M6 M7 M10 M11 M13 M15
>>> with tempfile.TemporaryDirectory() as d:
... path = str(pathlib.Path(d) / "tmp.dat")
... stim.Circuit("""
... X_ERROR(1) 1
... M 0 1 2
... DETECTOR rec[-1]
... DETECTOR rec[-2]
... DETECTOR rec[-3]
... OBSERVABLE_INCLUDE(5) rec[-2]
... """).compile_detector_sampler().sample_write(shots=2, filepath=path, format="dets", append_observables=True)
... with open(path) as f:
... print(f.read().strip())
shot D1 L5
shot D1 L5
Example dets parsing code (python):
from typing import List
def parse_dets(data: str, num_detectors: int, num_observables: int) -> List[List[bool]]:
shots = []
for line in data.split('\n'):
if not line.strip():
continue
assert line.startswith('shot')
line = line[4:].strip()
shot = [False] * (num_detectors + num_observables)
if line:
for term in line.split(' '):
c = term[0]
v = int(term[1:])
if c == 'D':
assert 0 <= v < num_detectors
shot[v] = True
elif c == 'L':
assert 0 <= v < num_observables
shot[num_detectors + v] = True
else:
raise NotImplementedError(c)
shots.append(shot)
return shots
Example dets saving code (python):
from typing import List
def save_dets(shots: List[List[bool]], num_detectors: int, num_observables: int):
output = ""
for shot in shots:
assert len(shot) == num_detectors + num_observables
detectors = shot[:num_detectors]
observables = shot[num_detectors:]
output += "shot"
for k in range(num_detectors):
if shot[k]:
output += " D" + str(k)
for k in range(num_observables):
if shot[num_detectors + k]:
output += " L" + str(k)
output += "\n"
return output
The hits format is a dense human readable format that stores shots as a comma-separated list of integers. Each integer indicates the position of a bit that was True. Positions that aren't mentioned had bits that were False.
The data from each shot is terminated by a newline character '\n'. The line is a series of non-negative integers separated by commas, with each integer indicating a bit from the shot that was true.
This format requires the reader to know the number of bits in each shot (if they want to get a list instead of a set). This format requires the reader to know how many trailing newlines, that don't correspond to shots with no hit, are in the text data.
This format is useful in contexts where the number of set bits is expected to be low, e.g. when sampling detection events.
Example of producing hits format data using stim's python API:
>>> import pathlib
>>> import stim
>>> import tempfile
>>> with tempfile.TemporaryDirectory() as d:
... path = str(pathlib.Path(d) / "tmp.dat")
... stim.Circuit("""
... X 1
... M 0 0 0 0 1 1 1 1 0 0 1 1 0 1
... """).compile_sampler().sample_write(shots=10, filepath=path, format="hits")
... with open(path) as f:
... print(f.read().strip())
4,5,6,7,10,11,13
4,5,6,7,10,11,13
4,5,6,7,10,11,13
4,5,6,7,10,11,13
4,5,6,7,10,11,13
4,5,6,7,10,11,13
4,5,6,7,10,11,13
4,5,6,7,10,11,13
4,5,6,7,10,11,13
4,5,6,7,10,11,13
Example hits parsing code (python):
from typing import List
def parse_hits(data: str, bits_per_shot: int) -> List[List[bool]]:
shots = []
if data.endswith('\n'):
data = data[:-1]
for line in data.split('\n'):
shot = [False] * bits_per_shot
if line:
for term in line.split(','):
shot[int(term)] = True
shots.append(shot)
return shots
Example hits saving code (python):
from typing import List
def save_hits(shots: List[List[bool]]) -> str:
output = ""
for shot in shots:
output += ",".join(str(index) for index, bit in enumerate(shot) if bit) + "\n"
return output
The ptb64 format is a dense SIMD-focused binary format that stores shots as partially transposed bit-packed data.
Each 64 bit word (8 bytes) of the data contains bits from the same measurement result across 64 separate shots. The next 8 bytes contain bits for the next measurement result from the 64 separate shots. This continues until the 8 bytes containing the bits from the last measurement result, and then starts over again with data from the next 64 shots (if there are more).
The shots are stored by byte order then significance order. The first shot's data goes into the least significant bit of the first byte of each 8 byte group.
This format requires the number of shots to be a multiple of 64. This format requires the reader to know the number of shots that were taken.
This format is generally more tedious to work with, but useful for achieving good performance on data processing tasks where it is possible to parallelize across shots using SIMD instructions.
Example of producing ptb64 format data using stim's python API:
>>> import pathlib
>>> import stim
>>> import tempfile
>>> with tempfile.TemporaryDirectory() as d:
... path = str(pathlib.Path(d) / "tmp.dat")
... stim.Circuit("""
... X 1
... M 0 1
... """).compile_sampler().sample_write(shots=64, filepath=path, format="ptb64")
... with open(path, 'rb') as f:
... print(' '.join(hex(e)[2:] for e in f.read()))
0 0 0 0 0 0 0 0 ff ff ff ff ff ff ff ff
Example ptb64 parsing code (python):
from typing import List
def parse_ptb64(data: bytes, bits_per_shot: int) -> List[List[bool]]:
num_shot_groups = int(len(data) * 8 / bits_per_shot / 64)
if len(data) * 8 != num_shot_groups * 64 * bits_per_shot:
raise ValueError("Number of shots must be a multiple of 64.")
result = [[False] * bits_per_shot for _ in range(num_shot_groups * 64)]
for group_index in range(num_shot_groups):
group_bit_offset = 64 * bits_per_shot * group_index
for m in range(bits_per_shot):
m_bit_offset = m * 64
for shot in range(64):
bit_offset = group_bit_offset + m_bit_offset + shot
bit = data[bit_offset // 8] & (1 << (bit_offset % 8)) != 0
s = group_index * 64 + shot
result[s][m] = bit
return result
Example ptb64 saving code (python):
from typing import List
def save_ptb64(shots: List[List[bool]]):
if len(shots) % 64 != 0:
raise ValueError("Number of shots must be a multiple of 64.")
output = []
for shot_offset in range(0, len(shots), 64):
bits_per_shot = len(shots[0])
for measure_index in range(bits_per_shot):
v = 0
for k in range(64)[::-1]:
v <<= 1
v += int(shots[shot_offset + k][measure_index])
output.append(v.to_bytes(8, 'little'))
return b''.join(output)
The r8 format is a sparse binary format that stores shots as a series of lengths of runs between 1s.
Each byte in the data indicates how many False bits there are before the next True bit. The maximum byte value (255) is special; it indicates to include 255 False bits but not follow them by a True bit. A shot always has a terminating True bit appended to it before encoding. Decoding of the shot ends (and the next shot begin) when this True bit just past the end of the shot data is reached.
This format requires the reader to know the number of bits in each shot.
This format is useful in contexts where the number of set bits is expected to be low, e.g. when sampling detection events.
Example of producing r8 format data using stim's python API:
>>> import pathlib
>>> import stim
>>> import tempfile
>>> with tempfile.TemporaryDirectory() as d:
... path = str(pathlib.Path(d) / "tmp.dat")
... stim.Circuit("""
... X 1
... M 0 0 0 0 1 1 1 1 0 0 1 1 0 1
... """).compile_sampler().sample_write(shots=10, filepath=path, format="r8")
... with open(path, 'rb') as f:
... print(' '.join(hex(e)[2:] for e in f.read()))
4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0 4 0 0 0 2 0 1 0
>>> with tempfile.TemporaryDirectory() as d:
... path = str(pathlib.Path(d) / "tmp.dat")
... stim.Circuit("""
... X 1
... M 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
... """).compile_sampler().sample_write(shots=10, filepath=path, format="r8")
... with open(path, 'rb') as f:
... print(' '.join(hex(e)[2:] for e in f.read()))
9 1f 9 1f 9 1f 9 1f 9 1f 9 1f 9 1f 9 1f 9 1f 9 1f
Example r8 parsing code (python):
from typing import List
def parse_r8(data: bytes, bits_per_shot: int) -> List[List[bool]]:
shots = []
shot = []
for byte in data:
shot += [False] * byte
if byte != 255:
shot.append(True)
if len(shot) > bits_per_shot:
assert len(shot) == bits_per_shot + 1 and shot[-1]
shot.pop()
shots.append(shot)
shot = []
assert len(shot) == 0
return shots
Example r8 saving code (python):
from typing import List
def save_r8(shots: List[List[bool]]) -> bytes:
output = []
for shot in shots:
gap = 0
for b in list(shot) + [True]:
if b:
while gap >= 255:
gap -= 255
output.append((255).to_bytes(1, 'big'))
output.append(gap.to_bytes(1, 'big'))
gap = 0
else:
gap += 1
return b''.join(output)