py: Implement "common word" compression scheme for error messages.
The idea here is that there's a moderate amount of ROM used up by exception
text. Obviously we try to keep the messages short, and the code can enable
terse errors, but it still adds up. Listed below is the total string data
size for various ports:
bare-arm 2860
minimal 2876
stm32 8926 (PYBV11)
cc3200 3751
esp32 5721
This commit implements compression of these strings. It takes advantage of
the fact that these strings are all 7-bit ascii and extracts the top 128
frequently used words from the messages and stores them packed (dropping
their null-terminator), then uses (0x80 | index) inside strings to refer to
these common words. Spaces are automatically added around words, saving
more bytes. This happens transparently in the build process, mirroring the
steps that are used to generate the QSTR data. The MP_COMPRESSED_ROM_TEXT
macro wraps any literal string that should compressed, and it's
automatically decompressed in mp_decompress_rom_string.
There are many schemes that could be used for the compression, and some are
included in py/makecompresseddata.py for reference (space, Huffman, ngram,
common word). Results showed that the common-word compression gets better
results. This is before counting the increased cost of the Huffman
decoder. This might be slightly counter-intuitive, but this data is
extremely repetitive at a word-level, and the byte-level entropy coder
can't quite exploit that as efficiently. Ideally one would combine both
approaches, but for now the common-word approach is the one that is used.
For additional comparison, the size of the raw data compressed with gzip
and zlib is calculated, as a sort of proxy for a lower entropy bound. With
this scheme we come within 15% on stm32, and 30% on bare-arm (i.e. we use
x% more bytes than the data compressed with gzip -- not counting the code
overhead of a decoder, and how this would be hypothetically implemented).
The feature is disabled by default and can be enabled by setting
MICROPY_ROM_TEXT_COMPRESSION at the Makefile-level.
5 years ago
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from __future__ import print_function
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import collections
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import re
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import sys
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import gzip
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import zlib
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_COMPRESSED_MARKER = 0xFF
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def check_non_ascii(msg):
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for c in msg:
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if ord(c) >= 0x80:
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print(
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'Unable to generate compressed data: message "{}" contains a non-ascii character "{}".'.format(
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msg, c
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),
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file=sys.stderr,
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)
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sys.exit(1)
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# Replace <char><space> with <char | 0x80>.
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# Trival scheme to demo/test.
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def space_compression(error_strings):
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for line in error_strings:
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check_non_ascii(line)
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result = ""
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for i in range(len(line)):
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if i > 0 and line[i] == " ":
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result = result[:-1]
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result += "\\{:03o}".format(ord(line[i - 1]))
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else:
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result += line[i]
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error_strings[line] = result
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return None
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# Replace common words with <0x80 | index>.
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# Index is into a table of words stored as aaaaa<0x80|a>bbb<0x80|b>...
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# Replaced words are assumed to have spaces either side to avoid having to store the spaces in the compressed strings.
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def word_compression(error_strings):
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topn = collections.Counter()
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for line in error_strings.keys():
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check_non_ascii(line)
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for word in line.split(" "):
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topn[word] += 1
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# Order not just by frequency, but by expected saving. i.e. prefer a longer string that is used less frequently.
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# Use the word itself for ties so that compression is deterministic.
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py: Implement "common word" compression scheme for error messages.
The idea here is that there's a moderate amount of ROM used up by exception
text. Obviously we try to keep the messages short, and the code can enable
terse errors, but it still adds up. Listed below is the total string data
size for various ports:
bare-arm 2860
minimal 2876
stm32 8926 (PYBV11)
cc3200 3751
esp32 5721
This commit implements compression of these strings. It takes advantage of
the fact that these strings are all 7-bit ascii and extracts the top 128
frequently used words from the messages and stores them packed (dropping
their null-terminator), then uses (0x80 | index) inside strings to refer to
these common words. Spaces are automatically added around words, saving
more bytes. This happens transparently in the build process, mirroring the
steps that are used to generate the QSTR data. The MP_COMPRESSED_ROM_TEXT
macro wraps any literal string that should compressed, and it's
automatically decompressed in mp_decompress_rom_string.
There are many schemes that could be used for the compression, and some are
included in py/makecompresseddata.py for reference (space, Huffman, ngram,
common word). Results showed that the common-word compression gets better
results. This is before counting the increased cost of the Huffman
decoder. This might be slightly counter-intuitive, but this data is
extremely repetitive at a word-level, and the byte-level entropy coder
can't quite exploit that as efficiently. Ideally one would combine both
approaches, but for now the common-word approach is the one that is used.
For additional comparison, the size of the raw data compressed with gzip
and zlib is calculated, as a sort of proxy for a lower entropy bound. With
this scheme we come within 15% on stm32, and 30% on bare-arm (i.e. we use
x% more bytes than the data compressed with gzip -- not counting the code
overhead of a decoder, and how this would be hypothetically implemented).
The feature is disabled by default and can be enabled by setting
MICROPY_ROM_TEXT_COMPRESSION at the Makefile-level.
5 years ago
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def bytes_saved(item):
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w, n = item
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return -((len(w) + 1) * (n - 1)), w
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py: Implement "common word" compression scheme for error messages.
The idea here is that there's a moderate amount of ROM used up by exception
text. Obviously we try to keep the messages short, and the code can enable
terse errors, but it still adds up. Listed below is the total string data
size for various ports:
bare-arm 2860
minimal 2876
stm32 8926 (PYBV11)
cc3200 3751
esp32 5721
This commit implements compression of these strings. It takes advantage of
the fact that these strings are all 7-bit ascii and extracts the top 128
frequently used words from the messages and stores them packed (dropping
their null-terminator), then uses (0x80 | index) inside strings to refer to
these common words. Spaces are automatically added around words, saving
more bytes. This happens transparently in the build process, mirroring the
steps that are used to generate the QSTR data. The MP_COMPRESSED_ROM_TEXT
macro wraps any literal string that should compressed, and it's
automatically decompressed in mp_decompress_rom_string.
There are many schemes that could be used for the compression, and some are
included in py/makecompresseddata.py for reference (space, Huffman, ngram,
common word). Results showed that the common-word compression gets better
results. This is before counting the increased cost of the Huffman
decoder. This might be slightly counter-intuitive, but this data is
extremely repetitive at a word-level, and the byte-level entropy coder
can't quite exploit that as efficiently. Ideally one would combine both
approaches, but for now the common-word approach is the one that is used.
For additional comparison, the size of the raw data compressed with gzip
and zlib is calculated, as a sort of proxy for a lower entropy bound. With
this scheme we come within 15% on stm32, and 30% on bare-arm (i.e. we use
x% more bytes than the data compressed with gzip -- not counting the code
overhead of a decoder, and how this would be hypothetically implemented).
The feature is disabled by default and can be enabled by setting
MICROPY_ROM_TEXT_COMPRESSION at the Makefile-level.
5 years ago
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top128 = sorted(topn.items(), key=bytes_saved)[:128]
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index = [w for w, _ in top128]
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index_lookup = {w: i for i, w in enumerate(index)}
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for line in error_strings.keys():
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result = ""
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need_space = False
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for word in line.split(" "):
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if word in index_lookup:
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result += "\\{:03o}".format(0b10000000 | index_lookup[word])
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need_space = False
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else:
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if need_space:
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result += " "
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need_space = True
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result += word
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error_strings[line] = result.strip()
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return "".join(w[:-1] + "\\{:03o}".format(0b10000000 | ord(w[-1])) for w in index)
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# Replace chars in text with variable length bit sequence.
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# For comparison only (the table is not emitted).
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def huffman_compression(error_strings):
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# https://github.com/tannewt/huffman
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import huffman
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all_strings = "".join(error_strings)
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cb = huffman.codebook(collections.Counter(all_strings).items())
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for line in error_strings:
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b = "1"
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for c in line:
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b += cb[c]
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n = len(b)
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if n % 8 != 0:
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n += 8 - (n % 8)
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result = ""
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for i in range(0, n, 8):
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result += "\\{:03o}".format(int(b[i : i + 8], 2))
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if len(result) > len(line) * 4:
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result = line
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error_strings[line] = result
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# TODO: This would be the prefix lengths and the table ordering.
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return "_" * (10 + len(cb))
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# Replace common N-letter sequences with <0x80 | index>, where
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# the common sequences are stored in a separate table.
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# This isn't very useful, need a smarter way to find top-ngrams.
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def ngram_compression(error_strings):
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topn = collections.Counter()
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N = 2
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for line in error_strings.keys():
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check_non_ascii(line)
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if len(line) < N:
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continue
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for i in range(0, len(line) - N, N):
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topn[line[i : i + N]] += 1
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def bytes_saved(item):
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w, n = item
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return -(len(w) * (n - 1))
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top128 = sorted(topn.items(), key=bytes_saved)[:128]
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index = [w for w, _ in top128]
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index_lookup = {w: i for i, w in enumerate(index)}
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for line in error_strings.keys():
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result = ""
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for i in range(0, len(line) - N + 1, N):
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word = line[i : i + N]
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if word in index_lookup:
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result += "\\{:03o}".format(0b10000000 | index_lookup[word])
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else:
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result += word
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if len(line) % N != 0:
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result += line[len(line) - len(line) % N :]
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error_strings[line] = result.strip()
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return "".join(index)
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def main(collected_path, fn):
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error_strings = collections.OrderedDict()
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py: Implement "common word" compression scheme for error messages.
The idea here is that there's a moderate amount of ROM used up by exception
text. Obviously we try to keep the messages short, and the code can enable
terse errors, but it still adds up. Listed below is the total string data
size for various ports:
bare-arm 2860
minimal 2876
stm32 8926 (PYBV11)
cc3200 3751
esp32 5721
This commit implements compression of these strings. It takes advantage of
the fact that these strings are all 7-bit ascii and extracts the top 128
frequently used words from the messages and stores them packed (dropping
their null-terminator), then uses (0x80 | index) inside strings to refer to
these common words. Spaces are automatically added around words, saving
more bytes. This happens transparently in the build process, mirroring the
steps that are used to generate the QSTR data. The MP_COMPRESSED_ROM_TEXT
macro wraps any literal string that should compressed, and it's
automatically decompressed in mp_decompress_rom_string.
There are many schemes that could be used for the compression, and some are
included in py/makecompresseddata.py for reference (space, Huffman, ngram,
common word). Results showed that the common-word compression gets better
results. This is before counting the increased cost of the Huffman
decoder. This might be slightly counter-intuitive, but this data is
extremely repetitive at a word-level, and the byte-level entropy coder
can't quite exploit that as efficiently. Ideally one would combine both
approaches, but for now the common-word approach is the one that is used.
For additional comparison, the size of the raw data compressed with gzip
and zlib is calculated, as a sort of proxy for a lower entropy bound. With
this scheme we come within 15% on stm32, and 30% on bare-arm (i.e. we use
x% more bytes than the data compressed with gzip -- not counting the code
overhead of a decoder, and how this would be hypothetically implemented).
The feature is disabled by default and can be enabled by setting
MICROPY_ROM_TEXT_COMPRESSION at the Makefile-level.
5 years ago
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max_uncompressed_len = 0
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num_uses = 0
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# Read in all MP_ERROR_TEXT strings.
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with open(collected_path, "r") as f:
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for line in f:
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line = line.strip()
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if not line:
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continue
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num_uses += 1
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error_strings[line] = None
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max_uncompressed_len = max(max_uncompressed_len, len(line))
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# So that objexcept.c can figure out how big the buffer needs to be.
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print("#define MP_MAX_UNCOMPRESSED_TEXT_LEN ({})".format(max_uncompressed_len))
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# Run the compression.
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compressed_data = fn(error_strings)
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# Print the data table.
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print('MP_COMPRESSED_DATA("{}")'.format(compressed_data))
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# Print the replacements.
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for uncomp, comp in error_strings.items():
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if uncomp == comp:
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prefix = ""
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else:
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prefix = "\\{:03o}".format(_COMPRESSED_MARKER)
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print('MP_MATCH_COMPRESSED("{}", "{}{}")'.format(uncomp, prefix, comp))
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py: Implement "common word" compression scheme for error messages.
The idea here is that there's a moderate amount of ROM used up by exception
text. Obviously we try to keep the messages short, and the code can enable
terse errors, but it still adds up. Listed below is the total string data
size for various ports:
bare-arm 2860
minimal 2876
stm32 8926 (PYBV11)
cc3200 3751
esp32 5721
This commit implements compression of these strings. It takes advantage of
the fact that these strings are all 7-bit ascii and extracts the top 128
frequently used words from the messages and stores them packed (dropping
their null-terminator), then uses (0x80 | index) inside strings to refer to
these common words. Spaces are automatically added around words, saving
more bytes. This happens transparently in the build process, mirroring the
steps that are used to generate the QSTR data. The MP_COMPRESSED_ROM_TEXT
macro wraps any literal string that should compressed, and it's
automatically decompressed in mp_decompress_rom_string.
There are many schemes that could be used for the compression, and some are
included in py/makecompresseddata.py for reference (space, Huffman, ngram,
common word). Results showed that the common-word compression gets better
results. This is before counting the increased cost of the Huffman
decoder. This might be slightly counter-intuitive, but this data is
extremely repetitive at a word-level, and the byte-level entropy coder
can't quite exploit that as efficiently. Ideally one would combine both
approaches, but for now the common-word approach is the one that is used.
For additional comparison, the size of the raw data compressed with gzip
and zlib is calculated, as a sort of proxy for a lower entropy bound. With
this scheme we come within 15% on stm32, and 30% on bare-arm (i.e. we use
x% more bytes than the data compressed with gzip -- not counting the code
overhead of a decoder, and how this would be hypothetically implemented).
The feature is disabled by default and can be enabled by setting
MICROPY_ROM_TEXT_COMPRESSION at the Makefile-level.
5 years ago
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# Used to calculate the "true" length of the (escaped) compressed strings.
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def unescape(s):
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return re.sub(r"\\\d\d\d", "!", s)
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# Stats. Note this doesn't include the cost of the decompressor code.
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uncomp_len = sum(len(s) + 1 for s in error_strings.keys())
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comp_len = sum(1 + len(unescape(s)) + 1 for s in error_strings.values())
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data_len = len(compressed_data) + 1 if compressed_data else 0
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print("// Total input length: {}".format(uncomp_len))
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print("// Total compressed length: {}".format(comp_len))
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print("// Total data length: {}".format(data_len))
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print("// Predicted saving: {}".format(uncomp_len - comp_len - data_len))
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# Somewhat meaningless comparison to zlib/gzip.
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all_input_bytes = "\\0".join(error_strings.keys()).encode()
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print()
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if hasattr(gzip, "compress"):
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gzip_len = len(gzip.compress(all_input_bytes)) + num_uses * 4
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print("// gzip length: {}".format(gzip_len))
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print("// Percentage of gzip: {:.1f}%".format(100 * (comp_len + data_len) / gzip_len))
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if hasattr(zlib, "compress"):
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zlib_len = len(zlib.compress(all_input_bytes)) + num_uses * 4
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print("// zlib length: {}".format(zlib_len))
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print("// Percentage of zlib: {:.1f}%".format(100 * (comp_len + data_len) / zlib_len))
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if __name__ == "__main__":
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main(sys.argv[1], word_compression)
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