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littlefs/scripts/dbgbmap.py
Christopher Haster e3fdc3dbd7 scripts: Added simple mroot cycle detectors to dbg scripts 
These work by keeping a set of all seen mroots as we descend down the
mroot chain. Simple, but it works.

The downside of this approach is that the mroot set grows unbounded, but
it's unlikely we'll ever have enough mroots in a system for this to
really matter.

This fixes scripts like dbgbmap.py getting stuck on intentional mroot
cycles created for testing. It's not a problem for a foreground script
to get stuck in an infinite loop, since you can just kill it, but a
background script getting stuck at 100% CPU is a bit more annoying.
2024-11-07 11:46:39 -06:00

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#!/usr/bin/env python3
import bisect
import collections as co
import functools as ft
import itertools as it
import math as mt
import os
import shutil
import struct
TAG_NULL = 0x0000 ## 0x0000 v--- ---- ---- ----
TAG_CONFIG = 0x0000 ## 0x00tt v--- ---- -ttt tttt
TAG_MAGIC = 0x0003 # 0x0003 v--- ---- ---- --11
TAG_VERSION = 0x0004 # 0x0004 v--- ---- ---- -1--
TAG_RCOMPAT = 0x0005 # 0x0005 v--- ---- ---- -1-1
TAG_WCOMPAT = 0x0006 # 0x0006 v--- ---- ---- -11-
TAG_OCOMPAT = 0x0007 # 0x0007 v--- ---- ---- -111
TAG_GEOMETRY = 0x0009 # 0x0008 v--- ---- ---- 1-rr
TAG_NAMELIMIT = 0x000c # 0x000c v--- ---- ---- 11--
TAG_FILELIMIT = 0x000d # 0x000d v--- ---- ---- 11-1
TAG_GDELTA = 0x0100 ## 0x01tt v--- ---1 -ttt tttt
TAG_GRMDELTA = 0x0100 # 0x0100 v--- ---1 ---- ----
TAG_NAME = 0x0200 ## 0x02tt v--- --1- -ttt tttt
TAG_REG = 0x0201 # 0x0201 v--- --1- ---- ---1
TAG_DIR = 0x0202 # 0x0202 v--- --1- ---- --1-
TAG_BOOKMARK = 0x0204 # 0x0204 v--- --1- ---- -1--
TAG_ORPHAN = 0x0205 # 0x0205 v--- --1- ---- -1-1
TAG_STRUCT = 0x0300 ## 0x03tt v--- --11 -ttt tttt
TAG_DATA = 0x0300 # 0x0300 v--- --11 ---- ----
TAG_BLOCK = 0x0304 # 0x0304 v--- --11 ---- -1rr
TAG_BSHRUB = 0x0308 # 0x0308 v--- --11 ---- 1---
TAG_BTREE = 0x030c # 0x030c v--- --11 ---- 11rr
TAG_MROOT = 0x0311 # 0x0310 v--- --11 ---1 --rr
TAG_MDIR = 0x0315 # 0x0314 v--- --11 ---1 -1rr
TAG_MTREE = 0x031c # 0x031c v--- --11 ---1 11rr
TAG_DID = 0x0320 # 0x0320 v--- --11 --1- ----
TAG_BRANCH = 0x032c # 0x032c v--- --11 --1- 11rr
TAG_ATTR = 0x0400 ## 0x04aa v--- -1-a -aaa aaaa
TAG_UATTR = 0x0400 # 0x04aa v--- -1-- -aaa aaaa
TAG_SATTR = 0x0500 # 0x05aa v--- -1-1 -aaa aaaa
TAG_SHRUB = 0x1000 ## 0x1kkk v--1 kkkk -kkk kkkk
TAG_ALT = 0x4000 ## 0x4kkk v1cd kkkk -kkk kkkk
TAG_B = 0x0000
TAG_R = 0x2000
TAG_LE = 0x0000
TAG_GT = 0x1000
TAG_CKSUM = 0x3000 ## 0x3c0p v-11 cccc ---- --qp
TAG_P = 0x0001
TAG_Q = 0x0002
TAG_NOTE = 0x3100 # 0x3100 v-11 ---1 ---- ----
TAG_ECKSUM = 0x3200 # 0x3200 v-11 --1- ---- ----
CHARS = 'mbd-'
COLORS = ['33', '34', '32', '90']
CHARS_DOTS = " .':"
CHARS_BRAILLE = (
'⠀⢀⡀⣀⠠⢠⡠⣠⠄⢄⡄⣄⠤⢤⡤⣤' '⠐⢐⡐⣐⠰⢰⡰⣰⠔⢔⡔⣔⠴⢴⡴⣴'
'⠂⢂⡂⣂⠢⢢⡢⣢⠆⢆⡆⣆⠦⢦⡦⣦' '⠒⢒⡒⣒⠲⢲⡲⣲⠖⢖⡖⣖⠶⢶⡶⣶'
'⠈⢈⡈⣈⠨⢨⡨⣨⠌⢌⡌⣌⠬⢬⡬⣬' '⠘⢘⡘⣘⠸⢸⡸⣸⠜⢜⡜⣜⠼⢼⡼⣼'
'⠊⢊⡊⣊⠪⢪⡪⣪⠎⢎⡎⣎⠮⢮⡮⣮' '⠚⢚⡚⣚⠺⢺⡺⣺⠞⢞⡞⣞⠾⢾⡾⣾'
'⠁⢁⡁⣁⠡⢡⡡⣡⠅⢅⡅⣅⠥⢥⡥⣥' '⠑⢑⡑⣑⠱⢱⡱⣱⠕⢕⡕⣕⠵⢵⡵⣵'
'⠃⢃⡃⣃⠣⢣⡣⣣⠇⢇⡇⣇⠧⢧⡧⣧' '⠓⢓⡓⣓⠳⢳⡳⣳⠗⢗⡗⣗⠷⢷⡷⣷'
'⠉⢉⡉⣉⠩⢩⡩⣩⠍⢍⡍⣍⠭⢭⡭⣭' '⠙⢙⡙⣙⠹⢹⡹⣹⠝⢝⡝⣝⠽⢽⡽⣽'
'⠋⢋⡋⣋⠫⢫⡫⣫⠏⢏⡏⣏⠯⢯⡯⣯' '⠛⢛⡛⣛⠻⢻⡻⣻⠟⢟⡟⣟⠿⢿⡿⣿')
# some ways of block geometry representations
# 512 -> 512
# 512x16 -> (512, 16)
# 0x200x10 -> (512, 16)
def bdgeom(s):
s = s.strip()
b = 10
if s.startswith('0x') or s.startswith('0X'):
s = s[2:]
b = 16
elif s.startswith('0o') or s.startswith('0O'):
s = s[2:]
b = 8
elif s.startswith('0b') or s.startswith('0B'):
s = s[2:]
b = 2
if 'x' in s:
s, s_ = s.split('x', 1)
return (int(s, b), int(s_, b))
else:
return int(s, b)
# parse some rbyd addr encodings
# 0xa -> (0xa,)
# 0xa.c -> ((0xa, 0xc),)
# 0x{a,b} -> (0xa, 0xb)
# 0x{a,b}.c -> ((0xa, 0xc), (0xb, 0xc))
def rbydaddr(s):
s = s.strip()
b = 10
if s.startswith('0x') or s.startswith('0X'):
s = s[2:]
b = 16
elif s.startswith('0o') or s.startswith('0O'):
s = s[2:]
b = 8
elif s.startswith('0b') or s.startswith('0B'):
s = s[2:]
b = 2
trunk = None
if '.' in s:
s, s_ = s.split('.', 1)
trunk = int(s_, b)
if s.startswith('{') and '}' in s:
ss = s[1:s.find('}')].split(',')
else:
ss = [s]
addr = []
for s in ss:
if trunk is not None:
addr.append((int(s, b), trunk))
else:
addr.append(int(s, b))
return tuple(addr)
def crc32c(data, crc=0):
crc ^= 0xffffffff
for b in data:
crc ^= b
for j in range(8):
crc = (crc >> 1) ^ ((crc & 1) * 0x82f63b78)
return 0xffffffff ^ crc
def popc(x):
return bin(x).count('1')
def parity(x):
return popc(x) & 1
def fromle32(data):
return struct.unpack('<I', data[0:4].ljust(4, b'\0'))[0]
def fromleb128(data):
word = 0
for i, b in enumerate(data):
word |= ((b & 0x7f) << 7*i)
word &= 0xffffffff
if not b & 0x80:
return word, i+1
return word, len(data)
def fromtag(data):
data = data.ljust(4, b'\0')
tag = (data[0] << 8) | data[1]
weight, d = fromleb128(data[2:])
size, d_ = fromleb128(data[2+d:])
return tag>>15, tag&0x7fff, weight, size, 2+d+d_
def frommdir(data):
blocks = []
d = 0
while d < len(data):
block, d_ = fromleb128(data[d:])
blocks.append(block)
d += d_
return tuple(blocks)
def fromshrub(data):
d = 0
weight, d_ = fromleb128(data[d:]); d += d_
trunk, d_ = fromleb128(data[d:]); d += d_
return weight, trunk
def frombranch(data):
d = 0
block, d_ = fromleb128(data[d:]); d += d_
trunk, d_ = fromleb128(data[d:]); d += d_
cksum = fromle32(data[d:]); d += 4
return block, trunk, cksum
def frombtree(data):
d = 0
w, d_ = fromleb128(data[d:]); d += d_
block, trunk, cksum = frombranch(data[d:])
return w, block, trunk, cksum
def frombptr(data):
d = 0
size, d_ = fromleb128(data[d:]); d += d_
block, d_ = fromleb128(data[d:]); d += d_
off, d_ = fromleb128(data[d:]); d += d_
return size, block, off
# space filling Hilbert-curve
#
# note we memoize the last curve since this is a bit expensive
#
@ft.lru_cache(1)
def hilbert_curve(width, height):
# based on generalized Hilbert curves:
# https://github.com/jakubcerveny/gilbert
#
def hilbert_(x, y, a_x, a_y, b_x, b_y):
w = abs(a_x+a_y)
h = abs(b_x+b_y)
a_dx = -1 if a_x < 0 else +1 if a_x > 0 else 0
a_dy = -1 if a_y < 0 else +1 if a_y > 0 else 0
b_dx = -1 if b_x < 0 else +1 if b_x > 0 else 0
b_dy = -1 if b_y < 0 else +1 if b_y > 0 else 0
# trivial row
if h == 1:
for _ in range(w):
yield (x,y)
x, y = x+a_dx, y+a_dy
return
# trivial column
if w == 1:
for _ in range(h):
yield (x,y)
x, y = x+b_dx, y+b_dy
return
a_x_, a_y_ = a_x//2, a_y//2
b_x_, b_y_ = b_x//2, b_y//2
w_ = abs(a_x_+a_y_)
h_ = abs(b_x_+b_y_)
if 2*w > 3*h:
# prefer even steps
if w_ % 2 != 0 and w > 2:
a_x_, a_y_ = a_x_+a_dx, a_y_+a_dy
# split in two
yield from hilbert_(x, y, a_x_, a_y_, b_x, b_y)
yield from hilbert_(x+a_x_, y+a_y_, a_x-a_x_, a_y-a_y_, b_x, b_y)
else:
# prefer even steps
if h_ % 2 != 0 and h > 2:
b_x_, b_y_ = b_x_+b_dx, b_y_+b_dy
# split in three
yield from hilbert_(x, y, b_x_, b_y_, a_x_, a_y_)
yield from hilbert_(x+b_x_, y+b_y_, a_x, a_y, b_x-b_x_, b_y-b_y_)
yield from hilbert_(
x+(a_x-a_dx)+(b_x_-b_dx), y+(a_y-a_dy)+(b_y_-b_dy),
-b_x_, -b_y_, -(a_x-a_x_), -(a_y-a_y_))
if width >= height:
curve = hilbert_(0, 0, +width, 0, 0, +height)
else:
curve = hilbert_(0, 0, 0, +height, +width, 0)
return list(curve)
# space filling Z-curve/Lebesgue-curve
#
# note we memoize the last curve since this is a bit expensive
#
@ft.lru_cache(1)
def lebesgue_curve(width, height):
# we create a truncated Z-curve by simply filtering out the points
# that are outside our region
curve = []
for i in range(2**(2*mt.ceil(mt.log2(max(width, height))))):
# we just operate on binary strings here because it's easier
b = '{:0{}b}'.format(i, 2*mt.ceil(mt.log2(i+1)/2))
x = int(b[1::2], 2) if b[1::2] else 0
y = int(b[0::2], 2) if b[0::2] else 0
if x < width and y < height:
curve.append((x, y))
return curve
# the rendering code is copied from tracebd.py, which is why it may look a
# little funny
#
# each block can be in one of 3 states: mdir, btree, or raw data, we keep track
# of these at the pixel-level via a bitmask
#
class Pixel(int):
__slots__ = ()
def __new__(cls, state=0, *,
mdir=False,
btree=False,
data=False):
return super().__new__(cls,
state
| (1 if mdir else 0)
| (2 if btree else 0)
| (4 if data else 0))
@property
def is_mdir(self):
return (self & 1) != 0
@property
def is_btree(self):
return (self & 2) != 0
@property
def is_data(self):
return (self & 4) != 0
def mdir(self):
return Pixel(int(self) | 1)
def btree(self):
return Pixel(int(self) | 2)
def data(self):
return Pixel(int(self) | 4)
def clear(self):
return Pixel(0)
def __or__(self, other):
return Pixel(int(self) | int(other))
def draw(self, char=None, *,
mdirs=True,
btrees=True,
datas=True,
color=True,
dots=False,
braille=False,
chars=None,
colors=None,
**_):
# fallback to default chars/colors
if chars is None:
chars = CHARS
if len(chars) < len(CHARS):
chars = chars + CHARS[len(chars):]
if colors is None:
colors = COLORS
if len(colors) < len(COLORS):
colors = colors + COLORS[len(colors):]
# compute char/color
c = chars[3]
f = [colors[3]]
if mdirs and self.is_mdir:
c = chars[0]
f.append(colors[0])
elif btrees and self.is_btree:
c = chars[1]
f.append(colors[1])
elif datas and self.is_data:
c = chars[2]
f.append(colors[2])
# override char?
if char:
c = char
# apply colors
if f and color:
c = '%s%s\x1b[m' % (
''.join('\x1b[%sm' % f_ for f_ in f),
c)
return c
class Bmap:
def __init__(self, *,
block_size=1,
block_count=1,
block_window=None,
off_window=None,
width=None,
height=1,
pixels=None):
# default width to block_window or block_size
if width is None:
if block_window is not None:
width = len(block_window)
else:
width = block_count
# allocate pixels if not provided
if pixels is None:
pixels = [Pixel() for _ in range(width*height)]
self.pixels = pixels
self.block_size = block_size
self.block_count = block_count
self.block_window = block_window
self.off_window = off_window
self.width = width
self.height = height
@property
def _block_window(self):
if self.block_window is None:
return range(0, self.block_count)
else:
return self.block_window
@property
def _off_window(self):
if self.off_window is None:
return range(0, self.block_size)
else:
return self.off_window
@property
def _window(self):
return len(self._off_window)*len(self._block_window)
def _op(self, f, block=None, off=None, size=None):
if block is None:
range_ = range(len(self.pixels))
else:
if off is None:
off, size = 0, self.block_size
elif size is None:
off, size = 0, off
# map into our window
if block not in self._block_window:
return
block -= self._block_window.start
size = (max(self._off_window.start,
min(self._off_window.stop, off+size))
- max(self._off_window.start,
min(self._off_window.stop, off)))
off = (max(self._off_window.start,
min(self._off_window.stop, off))
- self._off_window.start)
if size == 0:
return
# map to our block space
range_ = range(
block*len(self._off_window) + off,
block*len(self._off_window) + off+size)
range_ = range(
(range_.start*len(self.pixels)) // self._window,
(range_.stop*len(self.pixels)) // self._window)
range_ = range(
range_.start,
max(range_.stop, range_.start+1))
# apply the op
for i in range_:
self.pixels[i] = f(self.pixels[i])
def mdir(self, block=None, off=None, size=None):
self._op(Pixel.mdir, block, off, size)
def btree(self, block=None, off=None, size=None):
self._op(Pixel.btree, block, off, size)
def data(self, block=None, off=None, size=None):
self._op(Pixel.data, block, off, size)
def clear(self, block=None, off=None, size=None):
self._op(Pixel.clear, block, off, size)
def resize(self, *,
block_size=None,
block_count=None,
width=None,
height=None):
block_size = (block_size if block_size is not None
else self.block_size)
block_count = (block_count if block_count is not None
else self.block_count)
width = width if width is not None else self.width
height = height if height is not None else self.height
if (block_size == self.block_size
and block_count == self.block_count
and width == self.width
and height == self.height):
return
# transform our pixels
self.block_size = block_size
self.block_count = block_count
pixels = []
for x in range(width*height):
# map into our old bd space
range_ = range(
(x*self._window) // (width*height),
((x+1)*self._window) // (width*height))
range_ = range(
range_.start,
max(range_.stop, range_.start+1))
# aggregate state
pixels.append(ft.reduce(
Pixel.__or__,
self.pixels[range_.start:range_.stop],
Pixel()))
self.width = width
self.height = height
self.pixels = pixels
def draw(self, row, *,
mdirs=False,
btrees=False,
datas=False,
hilbert=False,
lebesgue=False,
dots=False,
braille=False,
**args):
# fold via a curve?
if hilbert:
grid = [None]*(self.width*self.height)
for (x,y), p in zip(
hilbert_curve(self.width, self.height),
self.pixels):
grid[x + y*self.width] = p
elif lebesgue:
grid = [None]*(self.width*self.height)
for (x,y), p in zip(
lebesgue_curve(self.width, self.height),
self.pixels):
grid[x + y*self.width] = p
else:
grid = self.pixels
line = []
if braille:
# encode into a byte
for x in range(0, self.width, 2):
byte_p = 0
best_p = Pixel()
for i in range(2*4):
p = grid[x+(2-1-(i%2)) + ((row*4)+(4-1-(i//2)))*self.width]
best_p |= p
if ((mdirs and p.is_mdir)
or (btrees and p.is_btree)
or (datas and p.is_data)):
byte_p |= 1 << i
line.append(best_p.draw(
CHARS_BRAILLE[byte_p],
braille=True,
mdirs=mdirs,
btrees=btrees,
datas=datas,
**args))
elif dots:
# encode into a byte
for x in range(self.width):
byte_p = 0
best_p = Pixel()
for i in range(2):
p = grid[x + ((row*2)+(2-1-i))*self.width]
best_p |= p
if ((mdirs and p.is_mdir)
or (btrees and p.is_btree)
or (datas and p.is_data)):
byte_p |= 1 << i
line.append(best_p.draw(
CHARS_DOTS[byte_p],
dots=True,
mdirs=mdirs,
btrees=btrees,
datas=datas,
**args))
else:
for x in range(self.width):
line.append(grid[x + row*self.width].draw(
mdirs=mdirs,
btrees=btrees,
datas=datas,
**args))
return ''.join(line)
# our core rbyd type
class Rbyd:
def __init__(self, blocks, data, rev, eoff, trunk, weight, cksum):
if isinstance(blocks, int):
blocks = (blocks,)
self.blocks = tuple(blocks)
self.data = data
self.rev = rev
self.eoff = eoff
self.trunk = trunk
self.weight = weight
self.cksum = cksum
@property
def block(self):
return self.blocks[0]
def addr(self):
if len(self.blocks) == 1:
return '0x%x.%x' % (self.block, self.trunk)
else:
return '0x{%s}.%x' % (
','.join('%x' % block for block in self.blocks),
self.trunk)
@classmethod
def fetch(cls, f, block_size, blocks, trunk=None):
if isinstance(blocks, int):
blocks = (blocks,)
if len(blocks) > 1:
# fetch all blocks
rbyds = [cls.fetch(f, block_size, block, trunk)
for block in blocks]
# determine most recent revision
i = 0
for i_, rbyd in enumerate(rbyds):
# compare with sequence arithmetic
if rbyd and (
not rbyds[i]
or not ((rbyd.rev - rbyds[i].rev) & 0x80000000)
or (rbyd.rev == rbyds[i].rev
and rbyd.trunk > rbyds[i].trunk)):
i = i_
# keep track of the other blocks
rbyd = rbyds[i]
rbyd.blocks += tuple(
rbyds[(i+1+j) % len(rbyds)].block
for j in range(len(rbyds)-1))
return rbyd
else:
# block may encode a trunk
block = blocks[0]
if isinstance(block, tuple):
if trunk is None:
trunk = block[1]
block = block[0]
# seek to the block
f.seek(block * block_size)
data = f.read(block_size)
# fetch the rbyd
rev = fromle32(data[0:4])
cksum = 0
cksum_ = crc32c(data[0:4])
cksum__ = cksum_
perturb = False
eoff = 0
eoff_ = None
j_ = 4
trunk_ = 0
trunk__ = 0
trunk___ = 0
weight = 0
weight_ = 0
weight__ = 0
while j_ < len(data) and (not trunk or eoff <= trunk):
# read next tag
v, tag, w, size, d = fromtag(data[j_:])
if v != parity(cksum__):
break
cksum__ ^= 0x00000080 if v else 0
cksum__ = crc32c(data[j_:j_+d], cksum__)
j_ += d
if not tag & TAG_ALT and j_ + size > len(data):
break
# take care of cksums
if not tag & TAG_ALT:
if (tag & 0xff00) != TAG_CKSUM:
cksum__ = crc32c(data[j_:j_+size], cksum__)
# found a cksum?
else:
# check cksum
cksum___ = fromle32(data[j_:j_+4])
if cksum__ != cksum___:
break
# commit what we have
eoff = eoff_ if eoff_ else j_ + size
cksum = cksum_
trunk_ = trunk__
weight = weight_
# update perturb bit
perturb = tag & TAG_P
# revert to data cksum and perturb
cksum__ = cksum_ ^ (0xfca42daf if perturb else 0)
# evaluate trunks
if (tag & 0xf000) != TAG_CKSUM:
if not (trunk and j_-d > trunk and not trunk___):
# new trunk?
if not trunk___:
trunk___ = j_-d
weight__ = 0
# keep track of weight
weight__ += w
# end of trunk?
if not tag & TAG_ALT:
# update trunk/weight unless we found a shrub or an
# explicit trunk (which may be a shrub) is requested
if not tag & TAG_SHRUB or trunk___ == trunk:
trunk__ = trunk___
weight_ = weight__
# keep track of eoff for best matching trunk
if trunk and j_ + size > trunk:
eoff_ = j_ + size
eoff = eoff_
cksum = cksum_
trunk_ = trunk__
weight = weight_
trunk___ = 0
# update canonical checksum, xoring out any perturb state
cksum_ = cksum__ ^ (0xfca42daf if perturb else 0)
if not tag & TAG_ALT:
j_ += size
return cls(block, data, rev, eoff, trunk_, weight, cksum)
def lookup(self, rid, tag):
if not self:
return True, 0, -1, 0, 0, 0, b'', []
tag = max(tag, 0x1)
lower = 0
upper = self.weight
path = []
# descend down tree
j = self.trunk
while True:
_, alt, weight_, jump, d = fromtag(self.data[j:])
# found an alt?
if alt & TAG_ALT:
# follow?
if ((rid, tag & 0xfff) > (upper-weight_-1, alt & 0xfff)
if alt & TAG_GT
else ((rid, tag & 0xfff)
<= (lower+weight_-1, alt & 0xfff))):
lower += upper-lower-weight_ if alt & TAG_GT else 0
upper -= upper-lower-weight_ if not alt & TAG_GT else 0
j = j - jump
# figure out which color
if alt & TAG_R:
_, nalt, _, _, _ = fromtag(self.data[j+jump+d:])
if nalt & TAG_R:
path.append((j+jump, j, True, 'y'))
else:
path.append((j+jump, j, True, 'r'))
else:
path.append((j+jump, j, True, 'b'))
# stay on path
else:
lower += weight_ if not alt & TAG_GT else 0
upper -= weight_ if alt & TAG_GT else 0
j = j + d
# figure out which color
if alt & TAG_R:
_, nalt, _, _, _ = fromtag(self.data[j:])
if nalt & TAG_R:
path.append((j-d, j, False, 'y'))
else:
path.append((j-d, j, False, 'r'))
else:
path.append((j-d, j, False, 'b'))
# found tag
else:
rid_ = upper-1
tag_ = alt
w_ = upper-lower
done = not tag_ or (rid_, tag_) < (rid, tag)
return (done, rid_, tag_, w_, j, d,
self.data[j+d:j+d+jump],
path)
def __bool__(self):
return bool(self.trunk)
def __eq__(self, other):
return self.block == other.block and self.trunk == other.trunk
def __ne__(self, other):
return not self.__eq__(other)
def __iter__(self):
tag = 0
rid = -1
while True:
done, rid, tag, w, j, d, data, _ = self.lookup(rid, tag+0x1)
if done:
break
yield rid, tag, w, j, d, data
# btree lookup with this rbyd as the root
def btree_lookup(self, f, block_size, bid, *,
depth=None):
rbyd = self
rid = bid
depth_ = 1
path = []
# corrupted? return a corrupted block once
if not rbyd:
return bid > 0, bid, 0, rbyd, -1, [], path
while True:
# collect all tags, normally you don't need to do this
# but we are debugging here
name = None
tags = []
branch = None
rid_ = rid
tag = 0
w = 0
for i in it.count():
done, rid__, tag, w_, j, d, data, _ = rbyd.lookup(
rid_, tag+0x1)
if done or (i != 0 and rid__ != rid_):
break
# first tag indicates the branch's weight
if i == 0:
rid_, w = rid__, w_
# catch any branches
if tag & 0xfff == TAG_BRANCH:
branch = (tag, j, d, data)
tags.append((tag, j, d, data))
# keep track of path
path.append((bid + (rid_-rid), w, rbyd, rid_, tags))
# descend down branch?
if branch is not None and (
not depth or depth_ < depth):
tag, j, d, data = branch
block, trunk, cksum = frombranch(data)
rbyd = Rbyd.fetch(f, block_size, block, trunk)
# corrupted? bail here so we can keep traversing the tree
if not rbyd:
return False, bid + (rid_-rid), w, rbyd, -1, [], path
rid -= (rid_-(w-1))
depth_ += 1
else:
return not tags, bid + (rid_-rid), w, rbyd, rid_, tags, path
# mtree lookup with this rbyd as the mroot
def mtree_lookup(self, f, block_size, mbid):
# have mtree?
done, rid, tag, w, j, d, data, _ = self.lookup(-1, TAG_MTREE)
if not done and rid == -1 and tag == TAG_MTREE:
w, block, trunk, cksum = frombtree(data)
mtree = Rbyd.fetch(f, block_size, block, trunk)
# corrupted?
if not mtree:
return True, -1, 0, None
# lookup our mbid
done, mbid, mw, rbyd, rid, tags, path = mtree.btree_lookup(
f, block_size, mbid)
if done:
return True, -1, 0, None
mdir = next(
((tag, j, d, data)
for tag, j, d, data in tags
if tag == TAG_MDIR),
None)
if not mdir:
return True, -1, 0, None
# fetch the mdir
_, _, _, data = mdir
blocks = frommdir(data)
return False, mbid, mw, Rbyd.fetch(f, block_size, blocks)
else:
# have mdir?
done, rid, tag, w, j, _, data, _ = self.lookup(-1, TAG_MDIR)
if not done and rid == -1 and tag == TAG_MDIR:
blocks = frommdir(data)
return False, 0, 0, Rbyd.fetch(f, block_size, blocks)
else:
# I guess we're inlined?
if mbid == -1:
return False, -1, 0, self
else:
return True, -1, 0, None
def main(disk, mroots=None, *,
block_size=None,
block_count=None,
block=None,
off=None,
size=None,
mdirs=False,
btrees=False,
datas=False,
no_header=False,
color='auto',
dots=False,
braille=False,
width=None,
height=None,
lines=None,
hilbert=False,
lebesgue=False,
**args):
# figure out what color should be
if color == 'auto':
color = sys.stdout.isatty()
elif color == 'always':
color = True
else:
color = False
# show all block types by default
if not mdirs and not btrees and not datas:
mdirs = True
btrees = True
datas = True
# assume a reasonable lines/height if not specified
#
# note that we let height = None if neither hilbert or lebesgue
# are specified, this is a bit special as the default may be less
# than one character in height.
if height is None and (hilbert or lebesgue):
if lines is not None:
height = lines
else:
height = 5
if lines is None:
if height is not None:
lines = height
else:
lines = 5
# is bd geometry specified?
if isinstance(block_size, tuple):
block_size, block_count_ = block_size
if block_count is None:
block_count = block_count_
# try to simplify the block/off/size arguments a bit
if not isinstance(block, tuple):
block = block,
if isinstance(off, tuple) and len(off) == 1:
off, = off
if isinstance(size, tuple) and len(size) == 1:
if off is None:
off, = size
size = None
if any(isinstance(b, tuple) and len(b) > 1 for b in block):
print("error: more than one block address?",
file=sys.stderr)
sys.exit(-1)
if isinstance(block[0], tuple):
block = (block[0][0], *block[1:])
if len(block) > 1 and isinstance(block[1], tuple):
block = (block[0], block[1][0])
if isinstance(block[0], tuple):
block, off_ = (block[0][0], *block[1:]), block[0][1]
if off is None:
off = off_
if len(block) > 1 and isinstance(block[1], tuple):
block = (block[0], block[1][0])
if len(block) == 1:
block, = block
if isinstance(off, tuple):
off, size_ = off[0], off[1] - off[0]
if size is None:
size = size_
if isinstance(size, tuple):
off_, size = off[0], off[1] - off[0]
if off is None:
off = off_
# is a block window specified?
block_window = None
if block is not None:
if isinstance(block, tuple):
block_window = range(*block)
else:
block_window = range(block, block+1)
off_window = None
if off is not None or size is not None:
off_ = off if off is not None else 0
size_ = size if size is not None else 1
off_window = range(off_, off_+size_)
# figure out best width/height
if width is None:
width_ = min(80, shutil.get_terminal_size((80, 5))[0])
elif width:
width_ = width
else:
width_ = shutil.get_terminal_size((80, 5))[0]
if height is None:
height_ = 0
elif height:
height_ = height
else:
height_ = shutil.get_terminal_size((80, 5))[1]
# create our block device representation
bmap = Bmap(
block_size=block_size,
block_count=block_count,
block_window=block_window,
off_window=off_window,
# scale if we're printing with dots or braille
width=2*width_ if braille else width_,
height=max(
1,
4*height_ if braille
else 2*height_ if dots
else height_))
# keep track of how many blocks are in use
mdirs_ = 0
btrees_ = 0
datas_ = 0
# flatten mroots, default to 0x{0,1}
if not mroots:
mroots = [(0,1)]
mroots = [block for mroots_ in mroots for block in mroots_]
# we seek around a bunch, so just keep the disk open
with open(disk, 'rb') as f:
# if block_size is omitted, assume the block device is one big block
if block_size is None:
f.seek(0, os.SEEK_END)
block_size = f.tell()
block_count = 1
bmap.resize(
block_size=block_size,
block_count=block_count)
# if block_count is omitted, derive the block_count from our file size
if block_count is None:
f.seek(0, os.SEEK_END)
block_count = f.tell() // block_size
bmap.resize(
block_size=block_size,
block_count=block_count)
#### traverse the filesystem
# fetch the mroot chain
corrupted = False
btrees__ = []
mroot = Rbyd.fetch(f, block_size, mroots)
mdepth = 1
mseen = set()
while True:
# corrupted?
if not mroot:
corrupted = True
break
# cycle detected
elif mroot.blocks in mseen:
corrupted = True
break
mseen.add(mroot.blocks)
# mark mroots in our bmap
for block in mroot.blocks:
bmap.mdir(block,
mroot.eoff if args.get('in_use') else block_size)
mdirs_ += 1;
# find any file btrees in our mroot
for rid, tag, w, j, d, data in mroot:
if (tag == TAG_DATA
or tag == TAG_BLOCK
or tag == TAG_BSHRUB
or tag == TAG_BTREE):
btrees__.append((mroot, tag, data))
# stop here?
if args.get('depth') and mdepth >= args.get('depth'):
break
# fetch the next mroot
done, rid, tag, w, j, d, data, _ = mroot.lookup(-1, TAG_MROOT)
if not (not done and rid == -1 and tag == TAG_MROOT):
break
blocks = frommdir(data)
mroot = Rbyd.fetch(f, block_size, blocks)
mdepth += 1
# fetch the mdir, if there is one
mdir = None
if not args.get('depth') or mdepth < args.get('depth'):
done, rid, tag, w, j, _, data, _ = mroot.lookup(-1, TAG_MDIR)
if not done and rid == -1 and tag == TAG_MDIR:
blocks = frommdir(data)
mdir = Rbyd.fetch(f, block_size, blocks)
# corrupted?
if not mdir:
corrupted = True
else:
# mark mdir in our bmap
for block in mdir.blocks:
bmap.mdir(block,
mdir.eoff if args.get('in_use')
else block_size)
mdirs_ += 1
# find any file btrees in our mdir
for rid, tag, w, j, d, data in mdir:
if (tag == TAG_DATA
or tag == TAG_BLOCK
or tag == TAG_BSHRUB
or tag == TAG_BTREE):
btrees__.append((mdir, tag, data))
# fetch the actual mtree, if there is one
mtree = None
if not args.get('depth') or mdepth < args.get('depth'):
done, rid, tag, w, j, d, data, _ = mroot.lookup(-1, TAG_MTREE)
if not done and rid == -1 and tag == TAG_MTREE:
w, block, trunk, cksum = frombtree(data)
mtree = Rbyd.fetch(f, block_size, block, trunk)
# traverse entries
mbid = -1
ppath = []
while True:
done, mbid, mw, rbyd, rid, tags, path = mtree.btree_lookup(
f, block_size, mbid+1,
depth=args.get('depth', mdepth)-mdepth)
if done:
break
# traverse the inner btree nodes
changed = False
for (x, px) in it.zip_longest(
enumerate(path),
enumerate(ppath)):
if x is None:
break
if not (changed
or px is None
# bid-rid changed?
or (x[1][0]-x[1][3]) != (px[1][0]-px[1][3])):
continue
changed = True
# mark btree inner nodes in our bmap
d, (mid_, w_, rbyd_, rid_, tags_) = x
for block in rbyd_.blocks:
bmap.btree(block,
rbyd_.eoff if args.get('in_use')
else block_size)
btrees_ += 1
ppath = path
# corrupted?
if not rbyd:
corrupted = True
continue
# found an mdir in the tags?
mdir__ = None
if (not args.get('depth')
or mdepth+len(path) < args.get('depth')):
mdir__ = next(
((tag, j, d, data)
for tag, j, d, data in tags
if tag == TAG_MDIR),
None)
if mdir__:
# fetch the mdir
_, _, _, data = mdir__
blocks = frommdir(data)
mdir_ = Rbyd.fetch(f, block_size, blocks)
# corrupted?
if not mdir_:
corrupted = True
else:
# mark mdir in our bmap
for block in mdir_.blocks:
bmap.mdir(block, 0,
mdir_.eoff if args.get('in_use')
else block_size)
mdirs_ += 1
# find any file btrees in our mdir
for rid, tag, w, j, d, data in mdir_:
if (tag == TAG_DATA
or tag == TAG_BLOCK
or tag == TAG_BSHRUB
or tag == TAG_BTREE):
btrees__.append((mdir_, tag, data))
# fetch any file btrees we found
if not args.get('depth') or mdepth < args.get('depth'):
for mdir, tag, data in btrees__:
# inlined data?
if tag == TAG_DATA:
# ignore here
continue
# direct block?
elif tag == TAG_BLOCK:
size, block, off = frombptr(data)
# mark block in our bmap
bmap.data(block,
off if args.get('in_use') else 0,
size if args.get('in_use') else block_size)
datas_ += 1
continue
# inlined bshrub?
elif tag == TAG_BSHRUB:
weight, trunk = fromshrub(data)
btree = Rbyd.fetch(f, block_size, mdir.block, trunk)
shrub = True
# indirect btree?
elif tag == TAG_BTREE:
w, block, trunk, cksum = frombtree(data)
btree = Rbyd.fetch(f, block_size, block, trunk)
shrub = False
else:
assert False
# traverse entries
bid = -1
ppath = []
while True:
(done, bid, w, rbyd, rid, tags, path
) = btree.btree_lookup(
f, block_size, bid+1,
depth=args.get('depth', mdepth)-mdepth)
if done:
break
# traverse the inner btree nodes
changed = False
for (x, px) in it.zip_longest(
enumerate(path),
enumerate(ppath)):
if x is None:
break
if not (changed
or px is None
# bid-rid changed?
or (x[1][0]-x[1][3]) != (px[1][0]-px[1][3])):
continue
changed = True
# mark btree inner nodes in our bmap
d, (bid_, w_, rbyd_, rid_, tags_) = x
# ignore bshrub roots
if shrub and d == 0:
continue
for block in rbyd_.blocks:
bmap.btree(block,
rbyd_.eoff if args.get('in_use')
else block_size)
btrees_ += 1
ppath = path
# corrupted?
if not rbyd:
corrupted = True
continue
# found a block in the tags?
bptr__ = None
if (not args.get('depth')
or mdepth+len(path) < args.get('depth')):
bptr__ = next(
((tag, j, d, data)
for tag, j, d, data in tags
if tag & 0xfff == TAG_BLOCK),
None)
if bptr__:
# fetch the block
_, _, _, data = bptr__
size, block, off = frombptr(data)
# mark blocks in our bmap
bmap.data(block,
off if args.get('in_use') else 0,
size if args.get('in_use') else block_size)
datas_ += 1
#### actual rendering begins here
# print some information about the bmap
if not no_header:
print('bd %dx%d%s%s%s' % (
block_size, block_count,
', %6s mdir' % ('%.1f%%' % (100*mdirs_ / block_count))
if mdirs else '',
', %6s btree' % ('%.1f%%' % (100*btrees_ / block_count))
if btrees else '',
', %6s data' % ('%.1f%%' % (100*datas_ / block_count))
if datas else ''))
# and then print the bmap
for row in range(
mt.ceil(bmap.height/4) if braille
else mt.ceil(bmap.height/2) if dots
else bmap.height):
line = bmap.draw(row,
mdirs=mdirs,
btrees=btrees,
datas=datas,
color=color,
dots=dots,
braille=braille,
hilbert=hilbert,
lebesgue=lebesgue,
**args)
print(line)
if args.get('error_on_corrupt') and corrupted:
sys.exit(2)
if __name__ == "__main__":
import argparse
import sys
parser = argparse.ArgumentParser(
description="Render currently used blocks in a littlefs image.",
allow_abbrev=False)
parser.add_argument(
'disk',
help="File containing the block device.")
parser.add_argument(
'mroots',
nargs='*',
type=rbydaddr,
help="Block address of the mroots. Defaults to 0x{0,1}.")
parser.add_argument(
'-b', '--block-size',
type=bdgeom,
help="Block size/geometry in bytes.")
parser.add_argument(
'--block-count',
type=lambda x: int(x, 0),
help="Block count in blocks.")
parser.add_argument(
'-@', '--block',
nargs='?',
type=lambda x: tuple(
rbydaddr(x) if x.strip() else None
for x in x.split(',')),
help="Optional block to show, may be a range.")
parser.add_argument(
'--off',
type=lambda x: tuple(
int(x, 0) if x.strip() else None
for x in x.split(',')),
help="Show a specific offset, may be a range.")
parser.add_argument(
'--size',
type=lambda x: tuple(
int(x, 0) if x.strip() else None
for x in x.split(',')),
help="Show this many bytes, may be a range.")
parser.add_argument(
'-M', '--mdirs',
action='store_true',
help="Render mdir blocks.")
parser.add_argument(
'-B', '--btrees',
action='store_true',
help="Render btree blocks.")
parser.add_argument(
'-D', '--datas',
action='store_true',
help="Render data blocks.")
parser.add_argument(
'-N', '--no-header',
action='store_true',
help="Don't show the header.")
parser.add_argument(
'--color',
choices=['never', 'always', 'auto'],
default='auto',
help="When to use terminal colors. Defaults to 'auto'.")
parser.add_argument(
'-:', '--dots',
action='store_true',
help="Use 1x2 ascii dot characters.")
parser.add_argument(
'-⣿', '--braille',
action='store_true',
help="Use 2x4 unicode braille characters. Note that braille "
"characters sometimes suffer from inconsistent widths.")
parser.add_argument(
'--chars',
help="Characters to use for mdir, btree, data, unused blocks.")
parser.add_argument(
'--colors',
type=lambda x: [x.strip() for x in x.split(',')],
help="Colors to use for mdir, btree, data, unused blocks.")
parser.add_argument(
'-W', '--width',
nargs='?',
type=lambda x: int(x, 0),
const=0,
help="Width in columns. 0 uses the terminal width. Defaults to "
"min(terminal, 80).")
parser.add_argument(
'-H', '--height',
nargs='?',
type=lambda x: int(x, 0),
const=0,
help="Height in rows. 0 uses the terminal height. Defaults to 1.")
parser.add_argument(
'-n', '--lines',
nargs='?',
type=lambda x: int(x, 0),
const=0,
help="Show this many lines of history. 0 uses the terminal "
"height. Defaults to 5.")
parser.add_argument(
'-U', '--hilbert',
action='store_true',
help="Render as a space-filling Hilbert curve.")
parser.add_argument(
'-Z', '--lebesgue',
action='store_true',
help="Render as a space-filling Z-curve.")
parser.add_argument(
'-i', '--in-use',
action='store_true',
help="Show how much of each block is in use.")
parser.add_argument(
'-z', '--depth',
nargs='?',
type=lambda x: int(x, 0),
const=0,
help="Depth of the filesystem tree to parse.")
parser.add_argument(
'-e', '--error-on-corrupt',
action='store_true',
help="Error if the filesystem is corrupt.")
sys.exit(main(**{k: v
for k, v in vars(parser.parse_intermixed_args()).items()
if v is not None}))
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