Key | Value |
---|---|
FileName | ./usr/lib/python3.8/site-packages/smmap/test/__pycache__/lib.cpython-38.pyc |
FileSize | 2157 |
MD5 | A59D84936055FE5C5806836A2CC99A48 |
SHA-1 | 0A6F6C13249832B3D7E0E8B0EF2F1DB5E764EA5F |
SHA-256 | D4C7AF1865DD576CD6B9A9896C8C95CB7FF96C8D46730BAFDF8888DEE216D9D3 |
SSDEEP | 48:MBKKJ53+YwGGXUVb1O4h9BDLhwd/Aw4zFR7lzA1f:rKJ5BwBIbP9BLOBP4zz7lz4 |
TLSH | T160410F45D7436F57F8DFF6F5D02E5A1992999AFFA35D81524AA8901B3C482800CB29C1 |
hashlookup:parent-total | 8 |
hashlookup:trust | 90 |
The searched file hash is included in 8 parent files which include package known and seen by metalookup. A sample is included below:
Key | Value |
---|---|
MD5 | 0B78723EC5E81953767D08A14F724452 |
PackageArch | noarch |
PackageDescription | When reading from many possibly large files in a fashion similar to random access, it is usually the fastest and most efficient to use memory maps. Although memory maps have many advantages, they represent a very limited system resource as every map uses one file descriptor, whose amount is limited per process. On 32 bit systems, the amount of memory you can have mapped at a time is naturally limited to theoretical 4GB of memory, which may not be enough for some applications. The documentation can be found here: http://packages.python.org/smmap |
PackageMaintainer | https://bugs.opensuse.org |
PackageName | python38-smmap |
PackageRelease | 1.4 |
PackageVersion | 4.0.0 |
SHA-1 | 7E2B8BFC62A62C267C593D4EB0089640E1621E19 |
SHA-256 | B5C5F035C44306C88BD335BD8E563A1C3E43652A475008AE5C743115FC55F20A |
Key | Value |
---|---|
MD5 | 6A4848EAFCBA180005DA41C2FE47E499 |
PackageArch | noarch |
PackageDescription | When reading from many possibly large files in a fashion similar to random access, it is usually the fastest and most efficient to use memory maps. Although memory maps have many advantages, they represent a very limited system resource as every map uses one file descriptor, whose amount is limited per process. On 32 bit systems, the amount of memory you can have mapped at a time is naturally limited to theoretical 4GB of memory, which may not be enough for some applications. The documentation can be found here: http://packages.python.org/smmap |
PackageName | python38-smmap |
PackageRelease | 34.13 |
PackageVersion | 4.0.0 |
SHA-1 | FB660C82FB4A9AB2D4CDE5B94B92FE2C50CB76DB |
SHA-256 | FE6357CC961A4ADBEE0AC963A985865C7E0FA36E2DF31E7607D7CA5D8EFA1A15 |
Key | Value |
---|---|
MD5 | 6C9BB5FBFB8011D4C4B2BA21D15E20CE |
PackageArch | noarch |
PackageDescription | When reading from many possibly large files in a fashion similar to random access, it is usually the fastest and most efficient to use memory maps. Although memory maps have many advantages, they represent a very limited system resource as every map uses one file descriptor, whose amount is limited per process. On 32 bit systems, the amount of memory you can have mapped at a time is naturally limited to theoretical 4GB of memory, which may not be enough for some applications. The documentation can be found here: http://packages.python.org/smmap |
PackageName | python38-smmap |
PackageRelease | 34.12 |
PackageVersion | 4.0.0 |
SHA-1 | C8B01FD5A379065C97E1EFC227C0C5706A7A4B2D |
SHA-256 | 30919EF19C962B673167CF717187E81DF50D16FBC85E9F7AD4D362EF3F02E86C |
Key | Value |
---|---|
MD5 | D57AF2C63B2ACA006E43677959C9B81E |
PackageArch | noarch |
PackageDescription | When reading from many possibly large files in a fashion similar to random access, it is usually the fastest and most efficient to use memory maps. Although memory maps have many advantages, they represent a very limited system resource as every map uses one file descriptor, whose amount is limited per process. On 32 bit systems, the amount of memory you can have mapped at a time is naturally limited to theoretical 4GB of memory, which may not be enough for some applications. The documentation can be found here: http://packages.python.org/smmap |
PackageName | python38-smmap |
PackageRelease | 34.17 |
PackageVersion | 4.0.0 |
SHA-1 | 057EFC9971FF46798195D737A697413055041E6E |
SHA-256 | EC2AEFFF6888CA3FFB7DBDFE3029808FEB1F78489355A5B78F1D00BD3FECC867 |
Key | Value |
---|---|
MD5 | 9A810B7873D0F518EBAD3C9CF8F9B695 |
PackageArch | noarch |
PackageDescription | When reading from many possibly large files in a fashion similar to random access, it is usually the fastest and most efficient to use memory maps. Although memory maps have many advantages, they represent a very limited system resource as every map uses one file descriptor, whose amount is limited per process. On 32 bit systems, the amount of memory you can have mapped at a time is naturally limited to theoretical 4GB of memory, which may not be enough for some applications. The documentation can be found here: http://packages.python.org/smmap |
PackageName | python3-smmap |
PackageRelease | 2.2 |
PackageVersion | 3.0.2 |
SHA-1 | 7DC1FE7856709ACFB815295162BDF95EFDA8F705 |
SHA-256 | 716395FD5EB9B82B93BF83842B9340179600EE9EC505E8455341F59B2B1D09B6 |
Key | Value |
---|---|
MD5 | B3713284030D9270F56F114659203903 |
PackageArch | noarch |
PackageDescription | When reading from many possibly large files in a fashion similar to random access, it is usually the fastest and most efficient to use memory maps. Although memory maps have many advantages, they represent a very limited system resource as every map uses one file descriptor, whose amount is limited per process. On 32 bit systems, the amount of memory you can have mapped at a time is naturally limited to theoretical 4GB of memory, which may not be enough for some applications. The documentation can be found here: http://packages.python.org/smmap |
PackageName | python38-smmap |
PackageRelease | 1.2 |
PackageVersion | 3.0.5 |
SHA-1 | 22FBE5EDE1F4D5A04E47489565B630223F846813 |
SHA-256 | 2581C460CE43CA1C0C44AA8C52B6F629AA219018125D4293CB30B433362CFF81 |
Key | Value |
---|---|
MD5 | 9F192C94EB1A2FEDB6A8E658A5FB1517 |
PackageArch | noarch |
PackageDescription | When reading from many possibly large files in a fashion similar to random access, it is usually the fastest and most efficient to use memory maps. Although memory maps have many advantages, they represent a very limited system resource as every map uses one file descriptor, whose amount is limited per process. On 32 bit systems, the amount of memory you can have mapped at a time is naturally limited to theoretical 4GB of memory, which may not be enough for some applications. The documentation can be found here: http://packages.python.org/smmap |
PackageName | python38-smmap |
PackageRelease | 34.16 |
PackageVersion | 4.0.0 |
SHA-1 | C68C30BF4D569EF23BCE6F4257825A913ECB199A |
SHA-256 | 4B385062A22F62E1BFF25B3C016AB725ACC4269652380C9097EC96877C9C7549 |
Key | Value |
---|---|
MD5 | D6121B79C0755BF6C76DF4C173045C42 |
PackageArch | noarch |
PackageDescription | When reading from many possibly large files in a fashion similar to random access, it is usually the fastest and most efficient to use memory maps. Although memory maps have many advantages, they represent a very limited system resource as every map uses one file descriptor, whose amount is limited per process. On 32 bit systems, the amount of memory you can have mapped at a time is naturally limited to theoretical 4GB of memory, which may not be enough for some applications. The documentation can be found here: http://packages.python.org/smmap |
PackageName | python38-smmap |
PackageRelease | 34.24 |
PackageVersion | 4.0.0 |
SHA-1 | 8BF4B3D8705696F88462BC5B142E50B123FFDE15 |
SHA-256 | 10EAC5E1021452B3512A0A119DFE144BD7279C83B1A07E30D3134373540BE3E7 |