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base: rust:v0.1.0
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rust:main rust:add-basic-uslp-support
rust:v0.14.0 rust:v0.13.1 rust:v0.13.0 rust:v0.12.0 rust:v0.11.2 rust:v0.11.1 rust:v0.11.0 rust:v0.11.0-rc.1 rust:v0.11.0-rc.0 rust:v0.10.0 rust:v0.9.0 rust:v0.8.1 rust:v0.8.0 rust:v0.7.0 rust:v0.7.0-beta.4 rust:v0.7.0-beta.3 rust:v0.7.0-beta.2 rust:v0.7.0-beta.1 rust:v0.7.0-beta.0 rust:v0.6.0 rust:v0.5.3 rust:v0.5.4 rust:v0.5.2 rust:v0.5.1 rust:v0.5.0 rust:v0.4.2 rust:v0.4.1 rust:v0.4.0 rust:v0.3.0 rust:v0.2.0 rust:v0.1.0
...
compare: rust:v0.4.1
Branches Tags
rust:main rust:add-basic-uslp-support
rust:v0.14.0 rust:v0.13.1 rust:v0.13.0 rust:v0.12.0 rust:v0.11.2 rust:v0.11.1 rust:v0.11.0 rust:v0.11.0-rc.1 rust:v0.11.0-rc.0 rust:v0.10.0 rust:v0.9.0 rust:v0.8.1 rust:v0.8.0 rust:v0.7.0 rust:v0.7.0-beta.4 rust:v0.7.0-beta.3 rust:v0.7.0-beta.2 rust:v0.7.0-beta.1 rust:v0.7.0-beta.0 rust:v0.6.0 rust:v0.5.3 rust:v0.5.4 rust:v0.5.2 rust:v0.5.1 rust:v0.5.0 rust:v0.4.2 rust:v0.4.1 rust:v0.4.0 rust:v0.3.0 rust:v0.2.0 rust:v0.1.0

140 Commits
v0.1.0 ... v0.4.1

Author SHA1 Message Date
Robin Mueller
1c702f933f v0.4.1
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2023-01-14 17:22:27 +01:00
Robin Mueller
6989558f93 cargo fmt
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2023-01-14 17:20:14 +01:00
Robin Müller
33e9b40c39 Merge pull request 'bugfix for patch version' (#7) from bugfix_for_v0.4.1 into main
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Reviewed-on: #7
 2023-01-14 17:19:22 +01:00
Robin Mueller
008359ec71 bugfix for patch version
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2023-01-14 17:18:02 +01:00
Robin Mueller
2385e7812b update dockerfile, install nightly
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2023-01-11 00:19:05 +01:00
Robin Mueller
76ea418711 add docs step in jenkinsfile
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2023-01-11 00:16:09 +01:00
Robin Mueller
b68f1c3752 add doc check in CI
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2023-01-11 00:14:23 +01:00
Robin Mueller
7c9bdb4512 add github msrv check
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2023-01-11 00:02:37 +01:00
Robin Mueller
8ffa7efa4d update jenkins CI
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2023-01-10 23:22:09 +01:00
Robin Mueller
d972dd5223 cargo fmt
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2023-01-10 16:59:13 +01:00
Robin Mueller
481de83fdb move lifetime docs further up
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2023-01-10 16:20:50 +01:00
Robin Mueller
09b305f529 better names for lifetimes
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2023-01-10 16:19:21 +01:00
Robin Mueller
78c5787e07 add some more basic docs
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2023-01-10 16:12:20 +01:00
Robin Mueller
e9e33b0335 release this tomorrow
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2023-01-10 00:00:10 +01:00
Robin Mueller
455be77f4a more docs 2023-01-09 23:59:55 +01:00
Robin Mueller
c748657499 allow minor release bump for serde and crc dependency
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2023-01-09 23:49:17 +01:00
Robin Mueller
2e90cba5bd put some ASCII includes behind alloc feature
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2023-01-09 23:47:47 +01:00
Robin Mueller
f290d2a54e re-remove Default impl for CDS time provider
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2023-01-09 23:46:31 +01:00
Robin Mueller
da695e4705 v0.4.0 preparation
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2023-01-09 11:21:07 +01:00
Robin Mueller
5c222735d4 Merge branch 'main' of https://egit.irs.uni-stuttgart.de/rust/spacepackets
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2023-01-09 11:19:16 +01:00
Robin Mueller
1432c298b3 feature list update 2023-01-09 11:19:10 +01:00
Robin Müller
1b45082ace Merge pull request 'Add CUC impl' (#4) from add_cuc_time_impl into main
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Reviewed-on: #4
Reviewed-by: Paul Nehlich <nehlichp@irs.uni-stuttgart.de>
 2023-01-09 11:14:40 +01:00
Robin Mueller
4c20158dcc Merge branch 'main' into add_cuc_time_impl
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2023-01-09 11:12:47 +01:00
Robin Mueller
c879181093 update changelog
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2023-01-09 11:12:07 +01:00
Robin Mueller
6c88e94742 Merge remote-tracking branch 'origin/main' into add_cuc_time_impl
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2023-01-09 11:10:44 +01:00
Robin Müller
3fb2fbd20c Merge pull request 'Improve CDS timecode implementation' (#3) from improve_cds_short_impl into main
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Reviewed-on: #3
 2023-01-09 11:08:11 +01:00
Robin Mueller
ec8a2e1d24 rename pfield preamble constant, add for CUC
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2023-01-09 11:07:43 +01:00
Robin Mueller
192e2f2c76 make pfield public
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2023-01-09 11:06:51 +01:00
Robin Mueller
5df221759f conversion from now bugfix
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2022-12-22 23:55:05 +01:00
Robin Mueller
f137bd2549 improve tests
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2022-12-22 23:45:15 +01:00
Robin Müller
630bffec51 Merge branch 'main' into improve_cds_short_impl
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2022-12-22 23:12:35 +01:00
Robin Müller
a14ae37cac Merge pull request 'added sp header getter function' (#6) from sp_header_getter into main
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Reviewed-on: #6
 2022-12-22 09:06:33 +01:00
Robin Mueller
2758699601 added sp header getter function
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2022-12-21 22:09:45 +01:00
Robin Mueller
b07cec28ea update changelog
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2022-12-21 10:14:58 +01:00
Robin Mueller
51963d0f72 remove default impl for cds TimeProvider 2022-12-21 10:14:13 +01:00
Robin Mueller
83e2cad753 cargo fmt
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2022-12-21 09:47:09 +01:00
Robin Mueller
472bfa9964 add floating point division code
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2022-12-21 01:17:36 +01:00
Robin Mueller
14fa1bad92 add TODO
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2022-12-21 01:03:26 +01:00
Robin Mueller
3828a98c76 important bugfix
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2022-12-21 01:01:05 +01:00
Robin Mueller
f641248ac2 add PR link
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2022-12-20 16:28:10 +01:00
Robin Mueller
884de647ad add PR link
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2022-12-20 16:27:23 +01:00
Robin Mueller
0d8074c6b9 clippy fixes
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2022-12-20 16:26:04 +01:00
Robin Mueller
6798e3a6f5 Merge remote-tracking branch 'origin/main' into improve_cds_short_impl
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2022-12-20 16:23:24 +01:00
Robin Mueller
7e763fe055 Merge remote-tracking branch 'origin/main' into add_cuc_time_impl
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2022-12-20 16:22:23 +01:00
Robin Mueller
4410ee7eec bump changelog
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2022-12-20 16:21:30 +01:00
Robin Müller
2895d7645a Merge pull request 'PTC and PFC extensions' (#5) from ptc_pfc_extension into main
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Reviewed-on: #5
 2022-12-20 16:19:21 +01:00
Robin Müller
692d12e5a5 Merge branch 'main' into ptc_pfc_extension
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2022-12-20 16:15:46 +01:00
Robin Mueller
9e57ce3872 cargo fmt
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2022-12-19 17:02:19 +01:00
Robin Mueller
fd13694904 add PUS service ID enum
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2022-12-19 16:36:18 +01:00
Robin Mueller
976fe9c49b README updates
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2022-12-19 11:02:36 +01:00
Robin Mueller
fbeea41e8f fix in Cargo.toml file 2022-12-19 11:00:45 +01:00
Robin Mueller
177ddba9c5 clippy fixes
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2022-12-19 00:01:07 +01:00
Robin Mueller
f964342556 removed unnecessary casts
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2022-12-18 23:54:13 +01:00
Robin.Mueller
46e2af41d2 PTC and PFC extensions
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- Add Ptc typedefinition for PacketTypeCode enum
- Add `UnsignedPfc` and `RealPfc` PFC enumerations
 2022-12-18 16:21:20 +01:00
Robin Mueller
fc05eaa925 Merge remote-tracking branch 'origin/main' into add_cuc_time_impl
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2022-12-12 11:57:00 +01:00
Robin Mueller
5a878ef6a3 Merge remote-tracking branch 'origin/main' into improve_cds_short_impl
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2022-12-12 11:56:08 +01:00
Paul Nehlich
66d77fda36 Merge pull request 'Add Error impls if std feature is used' (#2) from add_error_impls_for_std_feature into main
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Reviewed-on: #2
 2022-12-12 11:54:51 +01:00
Robin Mueller
ef963187ac update changelog
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2022-12-10 18:27:13 +01:00
Robin Mueller
93159dae45 some more docs
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2022-12-10 18:23:47 +01:00
Robin Mueller
f73edd71fd better structure
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2022-12-10 18:18:41 +01:00
Robin Mueller
6341cf35d3 added doc test / example as well
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2022-12-10 18:09:00 +01:00
Robin Mueller
1d9329ad63 this should cover most basic cases
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2022-12-10 17:39:15 +01:00
Robin Mueller
d889826b79 remove duplicate function
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2022-12-10 16:42:24 +01:00
Robin Mueller
e155ddbcb0 add more tests and additional check
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2022-12-10 16:35:00 +01:00
Robin Mueller
7615e40e43 basic docs
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2022-12-09 17:33:04 +01:00
Robin Mueller
bccbdf65a3 basic impl done, add first unittests
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2022-12-09 17:21:45 +01:00
Robin Mueller
8d0de0dce4 continued cuc impl 2022-12-09 16:51:48 +01:00
Robin Mueller
5958d19eb4 continue cuc impl
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2022-12-09 13:50:04 +01:00
Robin Mueller
4d64394637 split up large source file
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2022-12-08 15:22:19 +01:00
Robin Mueller
c4f8eee8da base line cuc impl done 2022-12-08 14:59:12 +01:00
Robin Mueller
f7f500ea48 Merge branch 'improve_cds_short_impl' into add_cuc_time_impl 2022-12-08 13:04:44 +01:00
Robin Mueller
7f607be5f3 add some missing derives
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2022-12-08 12:56:34 +01:00
Robin Mueller
c60ebc2a6e start baseline CUC Impl 2022-12-08 00:29:07 +01:00
Robin Mueller
48e5b22c27 doc corrections 2022-12-07 22:54:03 +01:00
Robin Mueller
04073a29af Merge remote-tracking branch 'origin/main' into improve_cds_short_impl
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2022-12-07 19:06:57 +01:00
Robin Mueller
66b4bf6013 Merge remote-tracking branch 'origin/main' into add_error_impls_for_std_feature
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2022-12-07 19:05:55 +01:00
Robin Mueller
f5397b8352 add Rust MSRV 1.60
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2022-12-07 19:05:09 +01:00
Robin Mueller
180134c05d update README and lib.rs frontpage docs
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2022-12-07 18:49:19 +01:00
Robin Mueller
3ee237865c Merge remote-tracking branch 'origin/main' into improve_cds_short_impl
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2022-12-07 18:44:06 +01:00
Robin Mueller
afd59b14fc Merge remote-tracking branch 'origin/main' into add_error_impls_for_std_feature
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2022-12-07 18:43:56 +01:00
Robin Mueller
3d5829b9a8 add missing feature flag
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2022-12-07 18:41:45 +01:00
Robin Mueller
1b4934e865 Merge branch 'add_error_impls_for_std_feature' into improve_cds_short_impl
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2022-12-07 14:43:03 +01:00
Robin Mueller
3fa43d46f9 bump changelog
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2022-12-07 14:42:53 +01:00
Robin Mueller
4cd8f143df this is a lot better 2022-12-07 14:42:01 +01:00
Robin Mueller
878f072e9a extended CDS impl 2022-12-07 13:55:43 +01:00
Robin Mueller
25695b39ea add error impls for feature std 2022-12-07 08:14:55 +01:00
Robin Mueller
8c0b78c698 ascii timecodes complete
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2022-12-05 10:14:25 +01:00
Robin Mueller
4e1df03729 bump changelog
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2022-12-05 10:02:50 +01:00
Robin Mueller
f13a2f73eb this should suffice
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2022-12-05 10:01:45 +01:00
Robin Mueller
62c1462930 added ASCII time code module
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2022-12-05 09:48:11 +01:00
Robin Mueller
8358d5ed1c bump changelog
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2022-12-05 09:05:35 +01:00
Robin Mueller
0c77a04059 doc tweaks
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2022-12-05 09:03:40 +01:00
Robin Mueller
e8571866e8 doc fix
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2022-12-05 08:55:24 +01:00
Robin Mueller
038755e56e set minimal data len in example
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2022-12-05 01:44:53 +01:00
Robin Mueller
33d78292c6 better example 2022-12-05 01:44:28 +01:00
Robin Mueller
8cf635d2fa additional useful functions 2022-12-05 01:41:35 +01:00
Robin Mueller
3420bcbeba Merge branch 'main' of https://egit.irs.uni-stuttgart.de/rust/spacepackets
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2022-12-05 00:18:16 +01:00
Robin Mueller
6554241ed7 doc correction 2022-12-05 00:17:37 +01:00
Robin Müller
283f9ff495 Merge pull request 'Various improvements' (#1) from various_improvements into main
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Reviewed-on: #1
 2022-12-05 00:16:07 +01:00
Robin.Mueller
3a71b00198 cargo fmt
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2022-12-04 20:00:49 +01:00
Robin.Mueller
13be7ca1e7 do not push version just yet
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2022-12-04 19:58:53 +01:00
Robin.Mueller
098a534199 bump changelog
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2022-12-04 19:57:51 +01:00
Robin.Mueller
322a56335e add tests for new functionality
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2022-12-04 19:56:21 +01:00
Robin.Mueller
f7c688d8db line break
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2022-12-04 18:26:38 +01:00
Robin.Mueller
54bb4bdaaa new helper functions for CCSDS SP construction
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Robin.Mueller
1969a26f14 bump changelog
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Robin.Mueller
d28ea7d4da add docs for new feature
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2022-12-04 17:18:10 +01:00
Robin.Mueller
aeb2e806b8 move improvements
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2022-12-04 17:11:44 +01:00
Robin Mueller
938c4ba770 make serde dependency optional
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2022-12-04 12:17:36 +01:00
Robin Mueller
97c70bf03b bump changelog and cargo.toml
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2022-12-03 15:47:18 +01:00
Robin Mueller
dc6d726e61 added missing doc_cfg feature for doc_cfg attr
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2022-12-03 15:40:36 +01:00
Robin Mueller
85bfcad111 bump changelog
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2022-12-01 01:22:19 +01:00
Robin Mueller
03d112cbef update spacepackets deps
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2022-11-30 01:05:37 +01:00
Robin Mueller
1ec21c1bff use const instead of struct field
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2022-11-20 18:42:35 +01:00
Robin Mueller
c750f94fba use non-deprecated API
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2022-11-19 02:39:25 +01:00
Robin Mueller
1d6cf3a75d update changelog
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2022-11-02 11:10:41 +01:00
Robin Mueller
f8199ca87a better docs 2022-11-02 00:38:59 +01:00
Robin Mueller
4c1101f65f better naming 2022-11-02 00:36:18 +01:00
Robin Mueller
38b789ca6d cargo fmt 2022-10-31 00:23:13 +01:00
Robin Mueller
d391891991 add EcssEnumerationExt trait extension 2022-10-31 00:22:28 +01:00
Robin Mueller
65e85f20e0 doc cfg support
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Robin Mueller
a2673c9870 make ToBeBytes trait public
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Robin Mueller
603f688ac3 small clippy fix
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2022-10-15 19:56:17 +02:00
Robin Mueller
638e4cda62 bump version
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2022-09-13 10:34:31 +02:00
Robin Mueller
1cc4771a53 cross-ref docs for examples
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Robin Mueller
427b368057 cargo fmt
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2022-09-13 10:29:09 +02:00
Robin Mueller
795abc57fa better names
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2022-09-13 10:28:20 +02:00
Robin Mueller
7da7e5329c typos
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2022-09-13 10:21:52 +02:00
Robin Mueller
5631372e58 update changelog
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2022-09-13 10:18:21 +02:00
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28ba4f887d added some auto-conversion
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2022-09-13 09:52:59 +02:00
Robin Mueller
d559646d80 better naming/docs. new const for MAX_SEQ_COUNT 2022-09-13 09:41:21 +02:00
Robin Mueller
fe1a30327b work on uniform API
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2022-09-11 20:50:46 +02:00
Robin Mueller
94489da003 return usize instead of u8 for byte width
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2022-09-06 10:14:23 +02:00
Robin Mueller
c72c5ad4aa extensions
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- Add source_data getter for PusTm
- Add std time info updater for CDS short time stamp provider
 2022-09-03 20:54:37 +02:00
Robin Mueller
bb83e67e54 bump changelog
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2022-09-03 18:50:21 +02:00
Robin Mueller
a4e297f0c0 Add new features 
- Basic ECSS enumeration support for u8, u16, u32 and u64
- Better names for generic error enums
 2022-09-03 18:47:59 +02:00
Robin Mueller
96d389a651 fix test
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Robin Mueller
cc680dba46 timestamp writer should return timestamp error too 2022-09-03 16:28:11 +02:00
Robin Mueller
42d3487c19 raw accessor function
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Robin Mueller
3970061ca1 only allow tests for std envs
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15 changed files with 3260 additions and 702 deletions
Expand all files Collapse all files

30
.github/workflows/ci.yml vendored
View File

@ -20,6 +20,21 @@ jobs:
command: check
args: --release
msrv:
name: Check with MSRV
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v2
- uses: actions-rs/toolchain@v1
with:
toolchain: 1.60.0
override: true
profile: minimal
- uses: actions-rs/cargo@v1
with:
command: check
args: --release
cross-check:
name: Check Cross
runs-on: ubuntu-latest
@ -58,6 +73,21 @@ jobs:
command: fmt
args: --all -- --check
check-doc:
name: Check Documentation Build
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v2
- uses: actions-rs/toolchain@v1
with:
toolchain: nightly
override: true
profile: minimal
- uses: actions-rs/cargo@v1
with:
command: doc
args: --all-features
clippy:
name: Clippy
runs-on: ubuntu-latest

82
CHANGELOG.md
View File

@ -6,9 +6,87 @@ All notable changes to this project will be documented in this file.
The format is based on [Keep a Changelog](http://keepachangelog.com/)
and this project adheres to [Semantic Versioning](http://semver.org/).
## [unreleased]
# [unreleased]
## [v0.1.0] 16.08.2022
# [v0.4.1] 14.01.2023
## Fixed
- CDS timestamp: The conversion function from the current time were buggy
when specifying picoseconds precision, which could lead to overflow
multiplications and/or incorrect precision fields.
# [v0.4.0] 10.01.2023
## Fixed
- Remove `Default` derive on CDS time provider. This can lead to uninitialized preamble fields.
## Changed
- `serde` support is now optional and behind the `serde` feature.
- `PusTcSecondaryHeaderT` trait renamed to `GenericPusTcSecondaryHeader`.
- `PusTmSecondaryHeaderT` trait renamed to `GenericPusTmSecondaryHeader`.
- `SpHeader`: Former `tc` and `tm` methods now named `tc_unseg` and `tm_unseg`.
Former `new` method now called `new_from_single_fields`.
- `SpHeader`: Renamed `from_bytes` to `from_be_bytes`.
The function now returns the remaining slice as well.
- All CDS specific functionality was moved into the `cds` submodule of the `time`
module. `CdsShortTimeProvider` was renamed to `TimeProvider`.
PR: https://egit.irs.uni-stuttgart.de/rust/spacepackets/pulls/3
## Added
- `SpHeader` getter function `sp_header` added for `PusTc`
PR: https://egit.irs.uni-stuttgart.de/rust/spacepackets/pulls/6
- Added PFC enumerations: `ecss::UnsignedPfc` and `ecss::RealPfc`.
PR: https://egit.irs.uni-stuttgart.de/rust/spacepackets/pulls/5
- Added `std::error::Error` implementation for all error enumerations if the `std` feature
is enabled.
- CUC timestamp implementation as specified in CCSDS 301.0-B-4 section 3.2.
PR: https://egit.irs.uni-stuttgart.de/rust/spacepackets/pulls/4/files
- ACII timestamps as specified in CCSDS 301.0-B-4 section 3.5.
- Added MSRV in `Cargo.toml` with the `rust-version` field set to Rust 1.60.
- `serde` `Serialize` and `Deserialize` added to all types.
- Added `const` constructors for `PacketId`, `PacketSeqCtrl` and
`SpHeader`.
- Added `PartialEq` and `Eq` `derive`s to `TimeProvider`.
- `SpHeader`: Added serialization function into raw format `write_to_be_bytes`.
- Added 24-bit day field support for CDS short. The bit width is configured at type level
via a generic parameter type passed to the `cds::TimeProvider`
- Added submillisecond precision support for `cds::TimeProvider`
# [v0.3.1] 03.12.2022
- Small fix for faulty docs.rs build
# [v0.3.0] 01.12.2022
## Added
- `EcssEnumerationExt` trait which implements `Debug`, `Copy`, `Clone`,
`PartialEq` and `Eq` in addition to `EcssEnumeration`
## Changed
- `EcssEnumeration` trait: Rename `write_to_bytes`
to `write_to_be_bytes`
# [v0.2.0] 13.09.2022
## Added
- Basic support for ECSS enumeration types for u8, u16, u32 and u64
## Changed
- Better names for generic error enumerations: `PacketError` renamed to `ByteConversionError`
- CCSDS module: `ssc` abbreviations fully replaced by better name `seq_count`
- Time module: `CcsdsTimeProvider::date_time` now has `Option<DateTime<Utc>>` as
a returnvalue instead of `DateTime<Utc>`
- `PusTc` and `PusTm`: `new_from_raw_slice` renamed to simpler `from_bytes`
# [v0.1.0] 16.08.2022
Initial release with CCSDS Space Packet Primary Header implementation and basic PUS TC and TM
implementations.

23
Cargo.toml
View File

@ -1,7 +1,8 @@
[package]
name = "spacepackets"
version = "0.1.0"
version = "0.4.1"
edition = "2021"
rust-version = "1.60"
authors = ["Robin Mueller <muellerr@irs.uni-stuttgart.de>"]
description = "Generic implementations for various CCSDS and ECSS packet standards"
homepage = "https://egit.irs.uni-stuttgart.de/rust/spacepackets"
@ -12,17 +13,18 @@ categories = ["aerospace", "aerospace::space-protocols", "no-std", "hardware-sup
# See more keys and their definitions at https://doc.rust-lang.org/cargo/reference/manifest.html
[dependencies]
zerocopy = "0.6.1"
crc = "3.0.0"
delegate = "0.7.0"
zerocopy = "0.6"
crc = "3"
delegate = "0.8"
[dependencies.serde]
version = "1.0.142"
version = "1"
optional = true
default-features = false
features = ["derive"]
[dependencies.chrono]
version = "0.4.20"
version = "0.4"
default-features = false
[dependencies.num-traits]
@ -30,9 +32,14 @@ version = "0.2"
default-features = false
[dev-dependencies.postcard]
version = "1.0.1"
version = "1.0"
[features]
default = ["std"]
std = ["chrono/std", "chrono/clock", "alloc"]
alloc = ["postcard/alloc"]
serde = ["dep:serde", "chrono/serde"]
alloc = ["postcard/alloc", "chrono/alloc"]
[package.metadata.docs.rs]
all-features = true
rustdoc-args = ["--cfg", "doc_cfg"]

28
README.md
View File

@ -15,23 +15,33 @@ Currently, this includes the following components:
[CCSDS Blue Book 133.0-B-2](https://public.ccsds.org/Pubs/133x0b2e1.pdf)
- PUS Telecommand and PUS Telemetry implementation according to the
[ECSS-E-ST-70-41C standard](https://ecss.nl/standard/ecss-e-st-70-41c-space-engineering-telemetry-and-telecommand-packet-utilization-15-april-2016/).
- CDS Short Time Code implementation according to
[CCSDS CCSDS 301.0-B-4](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
- CUC (CCSDS Unsegmented Time Code) implementation according to
[CCSDS 301.0-B-4 3.2](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
- CDS (CCSDS Day Segmented Time Code) implementation according to
[CCSDS 301.0-B-4 3.3](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
- Some helper types to support ASCII timecodes ad specified in
[CCSDS 301.0-B-4 3.5](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
# Features
`spacepackets` supports various runtime environments and is also suitable
for suitable for `no_std` environments. It has several features which may be enabled
for disabled.
`spacepackets` supports various runtime environments and is also suitable for `no_std` environments.
It also offers support for [`serde`](https://serde.rs/). The Space Paccket, PUS TM and TC
implementations derive the `serde` `Serialize` and `Deserialize` trait. This allows serializing and
It also offers optional support for [`serde`](https://serde.rs/). This allows serializing and
deserializing them with an appropriate `serde` provider like
[`postcard`](https://github.com/jamesmunns/postcard).
Default features:
## Default features
- [`std`](https://doc.rust-lang.org/std/): Enables functionality relying on the standard library.
- [`alloc`](https://doc.rust-lang.org/alloc/): Enables features which operate on containers
like [`alloc::vec::Vec`](https://doc.rust-lang.org/beta/alloc/vec/struct.Vec.html).
Enabled by the `std` feature.
## Optional Features
- [`serde`](https://serde.rs/): Adds `serde` support for most types by adding `Serialize` and `Deserialize` `derive`s
# Examples
You can check the [documentation](https://docs.rs/spacepackets) of individual modules for various
usage examples.

4
automation/Dockerfile
View File

@ -10,6 +10,6 @@ ARG DEBIAN_FRONTEND=noninteractive
# set CROSS_CONTAINER_IN_CONTAINER to inform `cross` that it is executed from within a container
ENV CROSS_CONTAINER_IN_CONTAINER=true
# TODO: installing cross is problematic, permission issues
RUN rustup target add thumbv7em-none-eabihf armv7-unknown-linux-gnueabihf && \
RUN rustup install nightly && \
rustup target add thumbv7em-none-eabihf armv7-unknown-linux-gnueabihf && \
rustup component add rustfmt clippy

18
automation/Jenkinsfile vendored
View File

@ -13,19 +13,29 @@ pipeline {
sh 'cargo clippy'
}
}
stage('Docs') {
steps {
sh 'cargo +nightly doc --all-features'
}
}
stage('Rustfmt') {
steps {
sh 'cargo fmt'
sh 'cargo fmt --all --check'
}
}
stage('Test') {
steps {
sh 'cargo test'
sh 'cargo test --all-features'
}
}
stage('Check') {
stage('Check with all features') {
steps {
sh 'cargo check'
sh 'cargo check --all-features'
}
}
stage('Check with no features') {
steps {
sh 'cargo check --no-default-features'
}
}
stage('Check Cross Embedded Bare Metal') {

303
src/ecss.rs
View File

@ -1,9 +1,13 @@
//! Common definitions and helpers required to create PUS TMTC packets according to
//! [ECSS-E-ST-70-41C](https://ecss.nl/standard/ecss-e-st-70-41c-space-engineering-telemetry-and-telecommand-packet-utilization-15-april-2016/)
use crate::{CcsdsPacket, PacketError};
use crate::{ByteConversionError, CcsdsPacket, SizeMissmatch};
use core::fmt::{Debug, Display, Formatter};
use core::mem::size_of;
use crc::{Crc, CRC_16_IBM_3740};
#[cfg(feature = "serde")]
use serde::{Deserialize, Serialize};
#[cfg(feature = "std")]
use std::error::Error;
pub type CrcType = u16;
@ -11,8 +15,24 @@ pub type CrcType = u16;
pub const CRC_CCITT_FALSE: Crc<u16> = Crc::<u16>::new(&CRC_16_IBM_3740);
pub const CCSDS_HEADER_LEN: usize = size_of::<crate::zc::SpHeader>();
#[derive(Debug, Copy, Clone, Eq, PartialEq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum PusServiceId {
/// Service 1
Verification = 1,
/// Service 3
Housekeeping = 3,
/// Service 5
Event = 5,
/// Service 8
Action = 8,
/// Service 17
Test = 17,
}
/// All PUS versions. Only PUS C is supported by this library.
#[derive(PartialEq, Eq, Copy, Clone, Serialize, Deserialize, Debug)]
#[derive(PartialEq, Eq, Copy, Clone, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum PusVersion {
EsaPus = 0,
PusA = 1,
@ -33,7 +53,58 @@ impl TryFrom<u8> for PusVersion {
}
}
/// ECSS Packet Type Codes (PTC)s.
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum PacketTypeCodes {
Boolean = 1,
Enumerated = 2,
UnsignedInt = 3,
SignedInt = 4,
Real = 5,
BitString = 6,
OctetString = 7,
CharString = 8,
AbsoluteTime = 9,
RelativeTime = 10,
Deduced = 11,
Packet = 12,
}
pub type Ptc = PacketTypeCodes;
/// ECSS Packet Field Codes (PFC)s for the unsigned [Ptc].
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum UnsignedPfc {
OneByte = 4,
TwelveBits = 8,
TwoBytes = 12,
ThreeBytes = 13,
FourBytes = 14,
SixBytes = 15,
EightBytes = 16,
OneBit = 17,
TwoBits = 18,
ThreeBits = 19,
}
/// ECSS Packet Field Codes (PFC)s for the real (floating point) [Ptc].
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum RealPfc {
/// 4 octets simple precision format (IEEE)
Float = 1,
/// 8 octets simple precision format (IEEE)
Double = 2,
/// 4 octets simple precision format (MIL-STD)
FloatMilStd = 3,
/// 8 octets simple precision format (MIL-STD)
DoubleMilStd = 4,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum PusError {
VersionNotSupported(PusVersion),
IncorrectCrc(u16),
@ -41,9 +112,56 @@ pub enum PusError {
NoRawData,
/// CRC16 needs to be calculated first
CrcCalculationMissing,
PacketError(PacketError),
ByteConversionError(ByteConversionError),
}
impl Display for PusError {
fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result {
match self {
PusError::VersionNotSupported(v) => {
write!(f, "PUS version {:?} not supported", v)
}
PusError::IncorrectCrc(crc) => {
write!(f, "crc16 {:#04x} is incorrect", crc)
}
PusError::RawDataTooShort(size) => {
write!(
f,
"deserialization error, provided raw data with size {} too short",
size
)
}
PusError::NoRawData => {
write!(f, "no raw data provided")
}
PusError::CrcCalculationMissing => {
write!(f, "crc16 was not calculated")
}
PusError::ByteConversionError(e) => {
write!(f, "low level byte conversion error: {}", e)
}
}
}
}
#[cfg(feature = "std")]
impl Error for PusError {
fn source(&self) -> Option<&(dyn Error + 'static)> {
if let PusError::ByteConversionError(e) = self {
return Some(e);
}
None
}
}
impl From<ByteConversionError> for PusError {
fn from(e: ByteConversionError) -> Self {
PusError::ByteConversionError(e)
}
}
/// Generic trait to describe common attributes for both PUS Telecommands (TC) and PUS Telemetry
/// (TM) packets. All PUS packets are also a special type of [CcsdsPacket]s.
pub trait PusPacket: CcsdsPacket {
const PUS_VERSION: PusVersion = PusVersion::PusC;
@ -135,3 +253,182 @@ macro_rules! sp_header_impls {
pub(crate) use ccsds_impl;
pub(crate) use sp_header_impls;
/// Generic trait for ECSS enumeration which consist of a PFC field denoting their bit length
/// and an unsigned value. The trait makes no assumptions about the actual type of the unsigned
/// value and only requires implementors to implement a function which writes the enumeration into
/// a raw byte format.
pub trait EcssEnumeration {
/// Packet Format Code, which denotes the number of bits of the enumeration
fn pfc(&self) -> u8;
fn byte_width(&self) -> usize {
(self.pfc() / 8) as usize
}
fn write_to_be_bytes(&self, buf: &mut [u8]) -> Result<(), ByteConversionError>;
}
pub trait EcssEnumerationExt: EcssEnumeration + Debug + Copy + Clone + PartialEq + Eq {}
pub trait ToBeBytes {
type ByteArray: AsRef<[u8]>;
fn to_be_bytes(&self) -> Self::ByteArray;
}
impl ToBeBytes for () {
type ByteArray = [u8; 0];
fn to_be_bytes(&self) -> Self::ByteArray {
[]
}
}
impl ToBeBytes for u8 {
type ByteArray = [u8; 1];
fn to_be_bytes(&self) -> Self::ByteArray {
u8::to_be_bytes(*self)
}
}
impl ToBeBytes for u16 {
type ByteArray = [u8; 2];
fn to_be_bytes(&self) -> Self::ByteArray {
u16::to_be_bytes(*self)
}
}
impl ToBeBytes for u32 {
type ByteArray = [u8; 4];
fn to_be_bytes(&self) -> Self::ByteArray {
u32::to_be_bytes(*self)
}
}
impl ToBeBytes for u64 {
type ByteArray = [u8; 8];
fn to_be_bytes(&self) -> Self::ByteArray {
u64::to_be_bytes(*self)
}
}
#[derive(Debug, Copy, Clone, Eq, PartialEq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct GenericEcssEnumWrapper<TYPE> {
val: TYPE,
}
impl<TYPE> GenericEcssEnumWrapper<TYPE> {
pub const fn ptc() -> PacketTypeCodes {
PacketTypeCodes::Enumerated
}
pub fn new(val: TYPE) -> Self {
Self { val }
}
}
impl<TYPE: ToBeBytes> EcssEnumeration for GenericEcssEnumWrapper<TYPE> {
fn pfc(&self) -> u8 {
size_of::<TYPE>() as u8 * 8_u8
}
fn write_to_be_bytes(&self, buf: &mut [u8]) -> Result<(), ByteConversionError> {
if buf.len() < self.byte_width() {
return Err(ByteConversionError::ToSliceTooSmall(SizeMissmatch {
found: buf.len(),
expected: self.byte_width(),
}));
}
buf[0..self.byte_width()].copy_from_slice(self.val.to_be_bytes().as_ref());
Ok(())
}
}
impl<TYPE: Debug + Copy + Clone + PartialEq + Eq + ToBeBytes> EcssEnumerationExt
for GenericEcssEnumWrapper<TYPE>
{
}
pub type EcssEnumU8 = GenericEcssEnumWrapper<u8>;
pub type EcssEnumU16 = GenericEcssEnumWrapper<u16>;
pub type EcssEnumU32 = GenericEcssEnumWrapper<u32>;
pub type EcssEnumU64 = GenericEcssEnumWrapper<u64>;
#[cfg(test)]
mod tests {
use crate::ecss::{EcssEnumU16, EcssEnumU32, EcssEnumU8, EcssEnumeration};
use crate::ByteConversionError;
#[test]
fn test_enum_u8() {
let mut buf = [0, 0, 0];
let my_enum = EcssEnumU8::new(1);
my_enum
.write_to_be_bytes(&mut buf[1..2])
.expect("To byte conversion of u8 failed");
assert_eq!(buf[1], 1);
}
#[test]
fn test_enum_u16() {
let mut buf = [0, 0, 0];
let my_enum = EcssEnumU16::new(0x1f2f);
my_enum
.write_to_be_bytes(&mut buf[1..3])
.expect("To byte conversion of u8 failed");
assert_eq!(buf[1], 0x1f);
assert_eq!(buf[2], 0x2f);
}
#[test]
fn test_slice_u16_too_small() {
let mut buf = [0];
let my_enum = EcssEnumU16::new(0x1f2f);
let res = my_enum.write_to_be_bytes(&mut buf[0..1]);
assert!(res.is_err());
let error = res.unwrap_err();
match error {
ByteConversionError::ToSliceTooSmall(missmatch) => {
assert_eq!(missmatch.expected, 2);
assert_eq!(missmatch.found, 1);
}
_ => {
panic!("Unexpected error {:?}", error);
}
}
}
#[test]
fn test_enum_u32() {
let mut buf = [0, 0, 0, 0, 0];
let my_enum = EcssEnumU32::new(0x1f2f3f4f);
my_enum
.write_to_be_bytes(&mut buf[1..5])
.expect("To byte conversion of u8 failed");
assert_eq!(buf[1], 0x1f);
assert_eq!(buf[2], 0x2f);
assert_eq!(buf[3], 0x3f);
assert_eq!(buf[4], 0x4f);
}
#[test]
fn test_slice_u32_too_small() {
let mut buf = [0, 0, 0, 0, 0];
let my_enum = EcssEnumU32::new(0x1f2f3f4f);
let res = my_enum.write_to_be_bytes(&mut buf[0..3]);
assert!(res.is_err());
let error = res.unwrap_err();
match error {
ByteConversionError::ToSliceTooSmall(missmatch) => {
assert_eq!(missmatch.expected, 4);
assert_eq!(missmatch.found, 3);
}
_ => {
panic!("Unexpected error {:?}", error);
}
}
}
}

460
src/lib.rs
View File

@ -9,49 +9,63 @@
//! [CCSDS Blue Book 133.0-B-2](https://public.ccsds.org/Pubs/133x0b2e1.pdf)
//! - PUS Telecommand and PUS Telemetry implementation according to the
//! [ECSS-E-ST-70-41C standard](https://ecss.nl/standard/ecss-e-st-70-41c-space-engineering-telemetry-and-telecommand-packet-utilization-15-april-2016/).
//! - CDS Short Time Code implementation according to
//! [CCSDS CCSDS 301.0-B-4](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
//! - CUC (CCSDS Unsegmented Time Code) implementation according to
//! [CCSDS 301.0-B-4 3.2](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
//! - CDS (CCSDS Day Segmented Time Code) implementation according to
//! [CCSDS 301.0-B-4 3.3](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
//! - Some helper types to support ASCII timecodes ad specified in
//! [CCSDS 301.0-B-4 3.5](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
//!
//! ## Features
//!
//! `spacepackets` supports various runtime environments and is also suitable
//! for suitable for `no_std` environments. It has several features which may be enabled
//! for disabled.
//! `spacepackets` supports various runtime environments and is also suitable for `no_std` environments.
//!
//! It also offers support for [`serde`](https://serde.rs/). The Space Paccket, PUS TM and TC
//! implementations derive the `serde` `Serialize` and `Deserialize` trait. This allows serializing and
//! It also offers optional support for [`serde`](https://serde.rs/). This allows serializing and
//! deserializing them with an appropriate `serde` provider like
//! [`postcard`](https://github.com/jamesmunns/postcard).
//!
//! Default features:
//! ### Default features
//!
//! - [`std`](https://doc.rust-lang.org/std/): Enables functionality relying on the standard library.
//! - [`alloc`](https://doc.rust-lang.org/alloc/): Enables features which operate on containers
//! like [`alloc::vec::Vec`](https://doc.rust-lang.org/beta/alloc/vec/struct.Vec.html).
//! Enabled by the `std` feature.
//!
//! ### Optional features
//!
//! - [`serde`](https://serde.rs/): Adds `serde` support for most types by adding `Serialize` and
//! `Deserialize` `derive`s
//!
//! ## Module
//!
//! This module contains helpers and data structures to generate Space Packets according to the
//! [CCSDS 133.0-B-2](https://public.ccsds.org/Pubs/133x0b2e1.pdf). This includes the
//! [SpHeader] class to generate the Space Packet Header component common to all space packets
//! [SpHeader] class to generate the Space Packet Header component common to all space packets.
//!
//! ## Example
//!
//! ```rust
//! use spacepackets::SpHeader;
//! let sp_header = SpHeader::tc(0x42, 12, 0).expect("Error creating SP header");
//! let sp_header = SpHeader::tc_unseg(0x42, 12, 1).expect("Error creating CCSDS TC header");
//! println!("{:?}", sp_header);
//! let mut ccsds_buf: [u8; 32] = [0; 32];
//! sp_header.write_to_be_bytes(&mut ccsds_buf).expect("Writing CCSDS TC header failed");
//! println!("{:x?}", &ccsds_buf[0..6]);
//! ```
#![no_std]
#![cfg_attr(doc_cfg, feature(doc_cfg))]
#[cfg(feature = "alloc")]
extern crate alloc;
#[cfg(feature = "std")]
#[cfg(any(feature = "std", test))]
extern crate std;
use crate::ecss::CCSDS_HEADER_LEN;
use core::fmt::{Display, Formatter};
use delegate::delegate;
#[cfg(feature = "std")]
use std::error::Error;
#[cfg(feature = "serde")]
use serde::{Deserialize, Serialize};
pub mod ecss;
@ -59,23 +73,65 @@ pub mod tc;
pub mod time;
pub mod tm;
mod private {
pub trait Sealed {}
}
pub const MAX_APID: u16 = 2u16.pow(11) - 1;
pub const MAX_SEQ_COUNT: u16 = 2u16.pow(14) - 1;
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct SizeMissmatch {
pub found: usize,
pub expected: usize,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
pub enum PacketError {
/// The passed slice is too small. Returns the found and expected minimum size
ToBytesSliceTooSmall(SizeMissmatch),
/// The provider buffer it soo small. Returns the found and expected minimum size
FromBytesSliceTooSmall(SizeMissmatch),
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum ByteConversionError {
/// The passed slice is too small. Returns the passed slice length and expected minimum size
ToSliceTooSmall(SizeMissmatch),
/// The provider buffer is too small. Returns the passed slice length and expected minimum size
FromSliceTooSmall(SizeMissmatch),
/// The [zerocopy] library failed to write to bytes
ToBytesZeroCopyError,
FromBytesZeroCopyError,
ZeroCopyToError,
ZeroCopyFromError,
}
#[derive(Serialize, Deserialize, Debug, PartialEq, Eq, Copy, Clone)]
impl Display for ByteConversionError {
fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result {
match self {
ByteConversionError::ToSliceTooSmall(missmatch) => {
write!(
f,
"target slice with size {} is too small, expected size of at least {}",
missmatch.found, missmatch.expected
)
}
ByteConversionError::FromSliceTooSmall(missmatch) => {
write!(
f,
"source slice with size {} too small, expected at least {} bytes",
missmatch.found, missmatch.expected
)
}
ByteConversionError::ZeroCopyToError => {
write!(f, "zerocopy serialization error")
}
ByteConversionError::ZeroCopyFromError => {
write!(f, "zerocopy deserialization error")
}
}
}
}
#[cfg(feature = "std")]
impl Error for ByteConversionError {}
/// CCSDS packet type enumeration.
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum PacketType {
Tm = 0,
Tc = 1,
@ -97,7 +153,8 @@ pub fn packet_type_in_raw_packet_id(packet_id: u16) -> PacketType {
PacketType::try_from((packet_id >> 12) as u8 & 0b1).unwrap()
}
#[derive(Serialize, Deserialize, Debug, PartialEq, Eq, Copy, Clone)]
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum SequenceFlags {
ContinuationSegment = 0b00,
FirstSegment = 0b01,
@ -121,28 +178,66 @@ impl TryFrom<u8> for SequenceFlags {
}
}
#[derive(Serialize, Deserialize, Debug, PartialEq, Eq, Copy, Clone)]
/// Abstraction for the CCSDS Packet ID, which forms the last thirteen bits
/// of the first two bytes in the CCSDS primary header.
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct PacketId {
pub ptype: PacketType,
pub sec_header_flag: bool,
apid: u16,
}
impl PacketId {
pub fn new(ptype: PacketType, sec_header_flag: bool, apid: u16) -> Option<PacketId> {
let mut pid = PacketId {
ptype,
sec_header_flag,
impl Default for PacketId {
fn default() -> Self {
PacketId {
ptype: PacketType::Tm,
sec_header_flag: false,
apid: 0,
};
pid.set_apid(apid).then(|| pid)
}
}
}
impl PacketId {
pub const fn const_tc(sec_header: bool, apid: u16) -> Self {
Self::const_new(PacketType::Tc, sec_header, apid)
}
pub const fn const_tm(sec_header: bool, apid: u16) -> Self {
Self::const_new(PacketType::Tm, sec_header, apid)
}
pub fn tc(sec_header: bool, apid: u16) -> Option<Self> {
Self::new(PacketType::Tc, sec_header, apid)
}
pub fn tm(sec_header: bool, apid: u16) -> Option<Self> {
Self::new(PacketType::Tm, sec_header, apid)
}
pub const fn const_new(ptype: PacketType, sec_header: bool, apid: u16) -> Self {
if apid > MAX_APID {
panic!("APID too large");
}
PacketId {
ptype,
sec_header_flag: sec_header,
apid,
}
}
pub fn new(ptype: PacketType, sec_header_flag: bool, apid: u16) -> Option<PacketId> {
if apid > MAX_APID {
return None;
}
Some(PacketId::const_new(ptype, sec_header_flag, apid))
}
/// Set a new Application Process ID (APID). If the passed number is invalid, the APID will
/// not be set and false will be returned. The maximum allowed value for the 11-bit field is
/// 2047
pub fn set_apid(&mut self, apid: u16) -> bool {
if apid > 2u16.pow(11) - 1 {
if apid > MAX_APID {
return false;
}
self.apid = apid;
@ -168,35 +263,50 @@ impl From<u16> for PacketId {
}
}
#[derive(Serialize, Deserialize, Debug, PartialEq, Eq, Copy, Clone)]
/// Abstraction for the CCSDS Packet Sequence Control (PSC) field which is the
/// third and the fourth byte in the CCSDS primary header.
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct PacketSequenceCtrl {
pub seq_flags: SequenceFlags,
seq_count: u16,
}
impl PacketSequenceCtrl {
pub fn new(seq_flags: SequenceFlags, ssc: u16) -> Option<PacketSequenceCtrl> {
let mut psc = PacketSequenceCtrl {
/// const variant of [PacketSequenceCtrl::new], but panics if the sequence count exceeds
/// [MAX_SEQ_COUNT].
const fn const_new(seq_flags: SequenceFlags, seq_count: u16) -> PacketSequenceCtrl {
if seq_count > MAX_SEQ_COUNT {
panic!("Sequence count too large");
}
PacketSequenceCtrl {
seq_flags,
seq_count: 0,
};
psc.set_seq_count(ssc).then(|| psc)
seq_count,
}
}
/// Returns [None] if the passed sequence count exceeds [MAX_SEQ_COUNT].
pub fn new(seq_flags: SequenceFlags, seq_count: u16) -> Option<PacketSequenceCtrl> {
if seq_count > MAX_SEQ_COUNT {
return None;
}
Some(PacketSequenceCtrl::const_new(seq_flags, seq_count))
}
pub fn raw(&self) -> u16 {
((self.seq_flags as u16) << 14) | self.seq_count
}
/// Set a new sequence count. If the passed number is invalid, the sequence count will not be
/// set and false will be returned. The maximum allowed value for the 14-bit field is 16383
/// set and false will be returned. The maximum allowed value for the 14-bit field is 16383.
pub fn set_seq_count(&mut self, ssc: u16) -> bool {
if ssc > 2u16.pow(14) - 1 {
if ssc > MAX_SEQ_COUNT {
return false;
}
self.seq_count = ssc;
true
}
pub fn ssc(&self) -> u16 {
pub fn seq_count(&self) -> u16 {
self.seq_count
}
}
@ -228,7 +338,7 @@ macro_rules! sph_from_other {
const SSC_MASK: u16 = 0x3FFF;
const VERSION_MASK: u16 = 0xE000;
/// Generic trait to access fields of a CCSDS space packet header according to CCSDS 133.0-B-2
/// Generic trait to access fields of a CCSDS space packet header according to CCSDS 133.0-B-2.
pub trait CcsdsPacket {
fn ccsds_version(&self) -> u8;
fn packet_id(&self) -> PacketId;
@ -242,7 +352,7 @@ pub trait CcsdsPacket {
}
/// Retrieve 13 bit Packet Identification field. Can usually be retrieved with a bitwise AND
/// of the first 2 bytes with 0x1FFF
/// of the first 2 bytes with 0x1FFF.
#[inline]
fn packet_id_raw(&self) -> u16 {
self.packet_id().raw()
@ -253,8 +363,8 @@ pub trait CcsdsPacket {
self.psc().raw()
}
/// Retrieve Packet Type (TM: 0, TC: 1).
#[inline]
/// Retrieve Packet Type (TM: 0, TC: 1)
fn ptype(&self) -> PacketType {
// This call should never fail because only 0 and 1 can be passed to the try_from call
self.packet_id().ptype
@ -271,13 +381,13 @@ pub trait CcsdsPacket {
}
/// Retrieve the secondary header flag. Returns true if a secondary header is present
/// and false if it is not
/// and false if it is not.
#[inline]
fn sec_header_flag(&self) -> bool {
self.packet_id().sec_header_flag
}
/// Retrieve Application Process ID
/// Retrieve Application Process ID.
#[inline]
fn apid(&self) -> u16 {
self.packet_id().apid
@ -305,73 +415,124 @@ pub trait CcsdsPrimaryHeader {
) -> Self;
}
/// Space Packet Primary Header according to CCSDS 133.0-B-2
/// Space Packet Primary Header according to CCSDS 133.0-B-2.
///
/// # Arguments
///
/// * `version` - CCSDS version field, occupies the first 3 bits of the raw header
/// * `version` - CCSDS version field, occupies the first 3 bits of the raw header. Will generally
/// be set to 0b000 in all constructors provided by this crate.
/// * `packet_id` - Packet Identifier, which can also be used as a start marker. Occupies the last
/// 13 bits of the first two bytes of the raw header
/// * `psc` - Packet Sequence Control, occupies the third and fourth byte of the raw header
/// * `data_len` - Data length field occupies the fifth and the sixth byte of the raw header
#[derive(serde::Serialize, serde::Deserialize, Debug, PartialEq, Eq, Copy, Clone)]
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct SpHeader {
pub version: u8,
pub packet_id: PacketId,
pub psc: PacketSequenceCtrl,
pub data_len: u16,
}
impl Default for SpHeader {
/// The default function sets the sequence flag field to [SequenceFlags::Unsegmented]. The data
/// length field is set to 1, which denotes an empty space packets.
fn default() -> Self {
SpHeader {
version: 0,
packet_id: PacketId {
ptype: PacketType::Tm,
apid: 0,
sec_header_flag: false,
},
packet_id: PacketId::default(),
psc: PacketSequenceCtrl {
seq_flags: SequenceFlags::Unsegmented,
seq_count: 0,
},
data_len: 0,
data_len: 1,
}
}
}
impl SpHeader {
pub fn new(
pub const fn new(packet_id: PacketId, psc: PacketSequenceCtrl, data_len: u16) -> Self {
Self {
version: 0,
packet_id,
psc,
data_len,
}
}
/// const variant of the [SpHeader::new_fron_single_fields] function. Panics if the passed
/// APID exceeds [MAX_APID] or the passed packet sequence count exceeds [MAX_SEQ_COUNT].
const fn const_new_from_single_fields(
ptype: PacketType,
sec_header: bool,
apid: u16,
ssc: u16,
seq_flags: SequenceFlags,
seq_count: u16,
data_len: u16,
) -> Self {
if seq_count > MAX_SEQ_COUNT {
panic!("Sequence count is too large");
}
if apid > MAX_APID {
panic!("APID is too large");
}
Self {
psc: PacketSequenceCtrl::const_new(seq_flags, seq_count),
packet_id: PacketId::const_new(ptype, sec_header, apid),
data_len,
version: 0,
}
}
/// Create a new Space Packet Header instance which can be used to create generic
/// Space Packets. This will return [None] if the APID or sequence count argument
/// exceed [MAX_APID] or [MAX_SEQ_COUNT] respectively. The version field is set to 0b000.
pub fn new_from_single_fields(
ptype: PacketType,
sec_header: bool,
apid: u16,
seq_flags: SequenceFlags,
seq_count: u16,
data_len: u16,
) -> Option<Self> {
if ssc > 2u16.pow(14) - 1 || apid > 2u16.pow(11) - 1 {
if seq_count > MAX_SEQ_COUNT || apid > MAX_APID {
return None;
}
let mut header = SpHeader::default();
header.packet_id.sec_header_flag = sec_header;
header.packet_id.apid = apid;
header.packet_id.ptype = ptype;
header.psc.seq_count = ssc;
header.data_len = data_len;
Some(header)
Some(SpHeader::const_new_from_single_fields(
ptype, sec_header, apid, seq_flags, seq_count, data_len,
))
}
pub fn tm(apid: u16, seq_count: u16, data_len: u16) -> Option<Self> {
Self::new(PacketType::Tm, false, apid, seq_count, data_len)
/// Helper function for telemetry space packet headers. The packet type field will be
/// set accordingly. The secondary header flag field is set to false.
pub fn tm(apid: u16, seq_flags: SequenceFlags, seq_count: u16, data_len: u16) -> Option<Self> {
Self::new_from_single_fields(PacketType::Tm, false, apid, seq_flags, seq_count, data_len)
}
pub fn tc(apid: u16, seq_count: u16, data_len: u16) -> Option<Self> {
Self::new(PacketType::Tc, false, apid, seq_count, data_len)
/// Helper function for telemetry space packet headers. The packet type field will be
/// set accordingly. The secondary header flag field is set to false.
pub fn tc(apid: u16, seq_flags: SequenceFlags, seq_count: u16, data_len: u16) -> Option<Self> {
Self::new_from_single_fields(PacketType::Tc, false, apid, seq_flags, seq_count, data_len)
}
/// Variant of [SpHeader::tm] which sets the sequence flag field to [SequenceFlags::Unsegmented]
pub fn tm_unseg(apid: u16, seq_count: u16, data_len: u16) -> Option<Self> {
Self::tm(apid, SequenceFlags::Unsegmented, seq_count, data_len)
}
/// Variant of [SpHeader::tc] which sets the sequence flag field to [SequenceFlags::Unsegmented]
pub fn tc_unseg(apid: u16, seq_count: u16, data_len: u16) -> Option<Self> {
Self::tc(apid, SequenceFlags::Unsegmented, seq_count, data_len)
}
//noinspection RsTraitImplementation
delegate!(to self.packet_id {
/// Returns [false] and fails if the APID exceeds [MAX_APID]
pub fn set_apid(&mut self, apid: u16) -> bool;
});
delegate!(to self.psc {
/// Returns [false] and fails if the sequence count exceeds [MAX_SEQ_COUNT]
pub fn set_seq_count(&mut self, seq_count: u16) -> bool;
});
@ -391,16 +552,38 @@ impl SpHeader {
self.packet_id.ptype = packet_type;
}
pub fn from_raw_slice(buf: &[u8]) -> Result<Self, PacketError> {
if buf.len() < CCSDS_HEADER_LEN + 1 {
return Err(PacketError::FromBytesSliceTooSmall(SizeMissmatch {
/// Create a struct from a raw slice where the fields have network endianness (big).
/// This function also returns the remaining part of the passed slice starting past the read
/// CCSDS header.
pub fn from_be_bytes(buf: &[u8]) -> Result<(Self, &[u8]), ByteConversionError> {
if buf.len() < CCSDS_HEADER_LEN {
return Err(ByteConversionError::FromSliceTooSmall(SizeMissmatch {
found: buf.len(),
expected: CCSDS_HEADER_LEN + 1,
expected: CCSDS_HEADER_LEN,
}));
}
let zc_header = zc::SpHeader::from_bytes(&buf[0..CCSDS_HEADER_LEN])
.ok_or(PacketError::FromBytesZeroCopyError)?;
Ok(Self::from(zc_header))
.ok_or(ByteConversionError::ZeroCopyFromError)?;
Ok((Self::from(zc_header), &buf[CCSDS_HEADER_LEN..]))
}
/// Write the header to a raw buffer using big endian format. This function returns the
/// remaining part of the passed slice starting past the written CCSDS header.
pub fn write_to_be_bytes<'a>(
&self,
buf: &'a mut [u8],
) -> Result<&'a mut [u8], ByteConversionError> {
if buf.len() < CCSDS_HEADER_LEN {
return Err(ByteConversionError::FromSliceTooSmall(SizeMissmatch {
found: buf.len(),
expected: CCSDS_HEADER_LEN,
}));
}
let zc_header: zc::SpHeader = zc::SpHeader::from(*self);
zc_header
.to_bytes(&mut buf[0..CCSDS_HEADER_LEN])
.ok_or(ByteConversionError::ZeroCopyToError)?;
Ok(&mut buf[CCSDS_HEADER_LEN..])
}
}
@ -529,23 +712,75 @@ pub mod zc {
sph_from_other!(SpHeader, crate::SpHeader);
}
#[cfg(test)]
#[cfg(all(test, feature = "std"))]
mod tests {
#[cfg(feature = "std")]
#[cfg(feature = "serde")]
use crate::CcsdsPrimaryHeader;
use crate::SpHeader;
use crate::{
packet_type_in_raw_packet_id, zc, CcsdsPacket, PacketId, PacketSequenceCtrl, PacketType,
SequenceFlags,
};
use crate::{SequenceFlags, SpHeader};
use alloc::vec;
#[cfg(not(feature = "std"))]
use num::pow;
#[cfg(feature = "std")]
use num_traits::pow;
use postcard::from_bytes;
#[cfg(feature = "alloc")]
use postcard::to_allocvec;
#[cfg(feature = "serde")]
use postcard::{from_bytes, to_allocvec};
const CONST_SP: SpHeader = SpHeader::new(
PacketId::const_tc(true, 0x36),
PacketSequenceCtrl::const_new(SequenceFlags::ContinuationSegment, 0x88),
0x90,
);
const PACKET_ID_TM: PacketId = PacketId::const_tm(true, 0x22);
#[test]
fn verify_const_packet_id() {
assert_eq!(PACKET_ID_TM.apid(), 0x22);
assert_eq!(PACKET_ID_TM.sec_header_flag, true);
assert_eq!(PACKET_ID_TM.ptype, PacketType::Tm);
let const_tc_id = PacketId::const_tc(true, 0x23);
assert_eq!(const_tc_id.ptype, PacketType::Tc);
}
#[test]
fn test_default_packet_id() {
let id_default = PacketId::default();
assert_eq!(id_default.ptype, PacketType::Tm);
assert_eq!(id_default.apid, 0x000);
assert_eq!(id_default.sec_header_flag, false);
}
#[test]
fn test_packet_id_ctors() {
let packet_id = PacketId::new(PacketType::Tc, true, 0x1ff);
assert!(packet_id.is_some());
let packet_id = packet_id.unwrap();
assert_eq!(packet_id.apid(), 0x1ff);
assert_eq!(packet_id.ptype, PacketType::Tc);
assert_eq!(packet_id.sec_header_flag, true);
let packet_id_tc = PacketId::tc(true, 0x1ff);
assert!(packet_id_tc.is_some());
let packet_id_tc = packet_id_tc.unwrap();
assert_eq!(packet_id_tc, packet_id);
let packet_id_tm = PacketId::tm(true, 0x2ff);
assert!(packet_id_tm.is_some());
let packet_id_tm = packet_id_tm.unwrap();
assert_eq!(packet_id_tm.sec_header_flag, true);
assert_eq!(packet_id_tm.ptype, PacketType::Tm);
assert_eq!(packet_id_tm.apid, 0x2ff);
}
#[test]
fn verify_const_sp_header() {
assert_eq!(CONST_SP.sec_header_flag(), true);
assert_eq!(CONST_SP.apid(), 0x36);
assert_eq!(
CONST_SP.sequence_flags(),
SequenceFlags::ContinuationSegment
);
assert_eq!(CONST_SP.seq_count(), 0x88);
assert_eq!(CONST_SP.data_len, 0x90);
}
#[test]
fn test_seq_flag_helpers() {
@ -628,9 +863,9 @@ mod tests {
}
#[test]
#[cfg(feature = "std")]
#[cfg(feature = "serde")]
fn test_serde_sph() {
let sp_header = SpHeader::tc(0x42, 12, 0).expect("Error creating SP header");
let sp_header = SpHeader::tc_unseg(0x42, 12, 0).expect("Error creating SP header");
assert_eq!(sp_header.ccsds_version(), 0b000);
assert!(sp_header.is_tc());
assert!(!sp_header.sec_header_flag());
@ -652,7 +887,7 @@ mod tests {
assert_eq!(sp_header.ccsds_version(), 0b000);
assert_eq!(sp_header.data_len, 0);
let sp_header = SpHeader::tm(0x7, 22, 36).expect("Error creating SP header");
let sp_header = SpHeader::tm_unseg(0x7, 22, 36).expect("Error creating SP header");
assert_eq!(sp_header.ccsds_version(), 0b000);
assert!(sp_header.is_tm());
assert!(!sp_header.sec_header_flag());
@ -683,28 +918,69 @@ mod tests {
}
#[test]
fn test_sp_header_setters() {
let mut sp_header = SpHeader::tc(0x42, 12, 0).expect("Error creating SP header");
assert_eq!(sp_header.apid(), 0x42);
fn test_setters() {
let sp_header = SpHeader::tc(0x42, SequenceFlags::Unsegmented, 25, 0);
assert!(sp_header.is_some());
let mut sp_header = sp_header.unwrap();
sp_header.set_apid(0x12);
assert_eq!(sp_header.apid(), 0x12);
sp_header.set_sec_header_flag();
assert!(sp_header.sec_header_flag());
sp_header.clear_sec_header_flag();
assert!(!sp_header.sec_header_flag());
sp_header.set_seq_count(0x45);
assert_eq!(sp_header.seq_count(), 0x45);
assert_eq!(sp_header.ptype(), PacketType::Tc);
sp_header.set_packet_type(PacketType::Tm);
assert_eq!(sp_header.ptype(), PacketType::Tm);
sp_header.set_seq_count(0x45);
assert_eq!(sp_header.seq_count(), 0x45);
}
#[test]
fn test_tc_ctor() {
let sp_header = SpHeader::tc(0x42, SequenceFlags::Unsegmented, 25, 0);
assert!(sp_header.is_some());
let sp_header = sp_header.unwrap();
verify_sp_fields(PacketType::Tc, &sp_header);
}
#[test]
fn test_tc_ctor_unseg() {
let sp_header = SpHeader::tc_unseg(0x42, 25, 0);
assert!(sp_header.is_some());
let sp_header = sp_header.unwrap();
verify_sp_fields(PacketType::Tc, &sp_header);
}
#[test]
fn test_tm_ctor() {
let sp_header = SpHeader::tm(0x42, SequenceFlags::Unsegmented, 25, 0);
assert!(sp_header.is_some());
let sp_header = sp_header.unwrap();
verify_sp_fields(PacketType::Tm, &sp_header);
}
#[test]
fn test_tm_ctor_unseg() {
let sp_header = SpHeader::tm_unseg(0x42, 25, 0);
assert!(sp_header.is_some());
let sp_header = sp_header.unwrap();
verify_sp_fields(PacketType::Tm, &sp_header);
}
fn verify_sp_fields(ptype: PacketType, sp_header: &SpHeader) {
assert_eq!(sp_header.ptype(), ptype);
assert_eq!(sp_header.sequence_flags(), SequenceFlags::Unsegmented);
assert_eq!(sp_header.apid(), 0x42);
assert_eq!(sp_header.seq_count(), 25);
assert_eq!(sp_header.data_len(), 0);
}
#[test]
fn test_zc_sph() {
use zerocopy::AsBytes;
let sp_header = SpHeader::tc(0x7FF, pow(2, 14) - 1, 0).expect("Error creating SP header");
let sp_header =
SpHeader::tc_unseg(0x7FF, pow(2, 14) - 1, 0).expect("Error creating SP header");
assert_eq!(sp_header.ptype(), PacketType::Tc);
assert_eq!(sp_header.apid(), 0x7FF);
assert_eq!(sp_header.data_len(), 0);

154
src/tc.rs
View File

@ -9,7 +9,7 @@
//! use spacepackets::ecss::PusPacket;
//!
//! // Create a ping telecommand with no user application data
//! let mut sph = SpHeader::tc(0x02, 0x34, 0).unwrap();
//! let mut sph = SpHeader::tc_unseg(0x02, 0x34, 0).unwrap();
//! let tc_header = PusTcSecondaryHeader::new_simple(17, 1);
//! let pus_tc = PusTc::new(&mut sph, tc_header, None, true);
//! println!("{:?}", pus_tc);
@ -20,13 +20,13 @@
//! // Serialize TC into a raw buffer
//! let mut test_buf: [u8; 32] = [0; 32];
//! let size = pus_tc
//! .write_to(test_buf.as_mut_slice())
//! .write_to_bytes(test_buf.as_mut_slice())
//! .expect("Error writing TC to buffer");
//! assert_eq!(size, 13);
//! println!("{:?}", &test_buf[0..size]);
//!
//! // Deserialize from the raw byte representation
//! let pus_tc_deserialized = PusTc::new_from_raw_slice(&test_buf).expect("Deserialization failed");
//! let pus_tc_deserialized = PusTc::from_bytes(&test_buf).expect("Deserialization failed");
//! assert_eq!(pus_tc.service(), 17);
//! assert_eq!(pus_tc.subservice(), 1);
//! assert_eq!(pus_tc.apid(), 0x02);
@ -36,9 +36,12 @@ use crate::ecss::{
verify_crc16_from_raw, CrcType, PusError, PusPacket, PusVersion, CRC_CCITT_FALSE,
};
use crate::SpHeader;
use crate::{CcsdsPacket, PacketError, PacketType, SequenceFlags, SizeMissmatch, CCSDS_HEADER_LEN};
use crate::{
ByteConversionError, CcsdsPacket, PacketType, SequenceFlags, SizeMissmatch, CCSDS_HEADER_LEN,
};
use core::mem::size_of;
use delegate::delegate;
#[cfg(feature = "serde")]
use serde::{Deserialize, Serialize};
use zerocopy::AsBytes;
@ -64,7 +67,7 @@ pub const ACK_ALL: u8 = AckOpts::Acceptance as u8
| AckOpts::Progress as u8
| AckOpts::Completion as u8;
pub trait PusTcSecondaryHeaderT {
pub trait GenericPusTcSecondaryHeader {
fn pus_version(&self) -> PusVersion;
fn ack_flags(&self) -> u8;
fn service(&self) -> u8;
@ -74,7 +77,7 @@ pub trait PusTcSecondaryHeaderT {
pub mod zc {
use crate::ecss::{PusError, PusVersion};
use crate::tc::PusTcSecondaryHeaderT;
use crate::tc::GenericPusTcSecondaryHeader;
use zerocopy::{AsBytes, FromBytes, NetworkEndian, Unaligned, U16};
#[derive(FromBytes, AsBytes, Unaligned)]
@ -101,7 +104,7 @@ pub mod zc {
}
}
impl PusTcSecondaryHeaderT for PusTcSecondaryHeader {
impl GenericPusTcSecondaryHeader for PusTcSecondaryHeader {
fn pus_version(&self) -> PusVersion {
PusVersion::try_from(self.version_ack >> 4 & 0b1111).unwrap_or(PusVersion::Invalid)
}
@ -124,7 +127,7 @@ pub mod zc {
}
impl PusTcSecondaryHeader {
pub fn to_bytes(&self, slice: &mut [u8]) -> Option<()> {
pub fn write_to_bytes(&self, slice: &mut [u8]) -> Option<()> {
self.write_to(slice)
}
@ -134,7 +137,8 @@ pub mod zc {
}
}
#[derive(PartialEq, Eq, Copy, Clone, Serialize, Deserialize, Debug)]
#[derive(PartialEq, Eq, Copy, Clone, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct PusTcSecondaryHeader {
pub service: u8,
pub subservice: u8,
@ -143,7 +147,7 @@ pub struct PusTcSecondaryHeader {
pub version: PusVersion,
}
impl PusTcSecondaryHeaderT for PusTcSecondaryHeader {
impl GenericPusTcSecondaryHeader for PusTcSecondaryHeader {
fn pus_version(&self) -> PusVersion {
self.version
}
@ -204,25 +208,26 @@ impl PusTcSecondaryHeader {
/// This class models a PUS telecommand. It is the primary data structure to generate the raw byte
/// representation of a PUS telecommand or to deserialize from one from raw bytes.
///
/// This class also derives the [serde::Serialize] and [serde::Deserialize] trait which allows
/// to send around TC packets in a raw byte format using a serde provider like
/// [postcard](https://docs.rs/postcard/latest/postcard/).
/// This class also derives the [serde::Serialize] and [serde::Deserialize] trait if the
/// [serde] feature is used, which allows to send around TC packets in a raw byte format using a
/// serde provider like [postcard](https://docs.rs/postcard/latest/postcard/).
///
/// There is no spare bytes support yet.
#[derive(PartialEq, Eq, Copy, Clone, Serialize, Deserialize, Debug)]
pub struct PusTc<'slice> {
#[derive(PartialEq, Eq, Copy, Clone, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct PusTc<'app_data> {
sp_header: SpHeader,
pub sec_header: PusTcSecondaryHeader,
/// If this is set to false, a manual call to [PusTc::calc_own_crc16] or
/// [PusTc::update_packet_fields] is necessary for the serialized or cached CRC16 to be valid.
pub calc_crc_on_serialization: bool,
#[serde(skip)]
raw_data: Option<&'slice [u8]>,
app_data: Option<&'slice [u8]>,
#[cfg_attr(feature = "serde", serde(skip))]
raw_data: Option<&'app_data [u8]>,
app_data: Option<&'app_data [u8]>,
crc16: Option<u16>,
}
impl<'slice> PusTc<'slice> {
impl<'app_data> PusTc<'app_data> {
/// Generates a new struct instance.
///
/// # Arguments
@ -238,7 +243,7 @@ impl<'slice> PusTc<'slice> {
pub fn new(
sp_header: &mut SpHeader,
sec_header: PusTcSecondaryHeader,
app_data: Option<&'slice [u8]>,
app_data: Option<&'app_data [u8]>,
set_ccsds_len: bool,
) -> Self {
sp_header.set_packet_type(PacketType::Tc);
@ -258,12 +263,12 @@ impl<'slice> PusTc<'slice> {
}
/// Simplified version of the [PusTc::new] function which allows to only specify service and
/// subservice instead of the full PUS TC secondary header
/// subservice instead of the full PUS TC secondary header.
pub fn new_simple(
sph: &mut SpHeader,
service: u8,
subservice: u8,
app_data: Option<&'slice [u8]>,
app_data: Option<&'app_data [u8]>,
set_ccsds_len: bool,
) -> Self {
Self::new(
@ -274,6 +279,10 @@ impl<'slice> PusTc<'slice> {
)
}
pub fn sp_header(&self) -> &SpHeader {
&self.sp_header
}
pub fn len_packed(&self) -> usize {
let mut length = PUS_TC_MIN_LEN_WITHOUT_APP_DATA;
if let Some(app_data) = self.app_data {
@ -301,7 +310,7 @@ impl<'slice> PusTc<'slice> {
/// used.
/// If this was not done or the application data is set or changed after construction,
/// this function needs to be called to ensure that the data length field of the CCSDS header
/// is set correctly
/// is set correctly.
pub fn update_ccsds_data_len(&mut self) {
self.sp_header.data_len =
self.len_packed() as u16 - size_of::<crate::zc::SpHeader>() as u16 - 1;
@ -321,35 +330,30 @@ impl<'slice> PusTc<'slice> {
self.crc16 = Some(digest.finalize())
}
/// This helper function calls both [PusTc.update_ccsds_data_len] and [PusTc.calc_own_crc16]
/// This helper function calls both [PusTc::update_ccsds_data_len] and [PusTc::calc_own_crc16].
pub fn update_packet_fields(&mut self) {
self.update_ccsds_data_len();
self.calc_own_crc16();
}
/// Write the raw PUS byte representation to a provided buffer.
pub fn write_to(&self, slice: &mut [u8]) -> Result<usize, PusError> {
pub fn write_to_bytes(&self, slice: &mut [u8]) -> Result<usize, PusError> {
let mut curr_idx = 0;
let sph_zc = crate::zc::SpHeader::from(self.sp_header);
let tc_header_len = size_of::<zc::PusTcSecondaryHeader>();
let total_size = self.len_packed();
if total_size > slice.len() {
return Err(PusError::PacketError(PacketError::ToBytesSliceTooSmall(
SizeMissmatch {
found: slice.len(),
expected: total_size,
},
)));
return Err(ByteConversionError::ToSliceTooSmall(SizeMissmatch {
found: slice.len(),
expected: total_size,
})
.into());
}
sph_zc
.to_bytes(&mut slice[curr_idx..curr_idx + CCSDS_HEADER_LEN])
.ok_or(PusError::PacketError(PacketError::ToBytesZeroCopyError))?;
self.sp_header.write_to_be_bytes(slice)?;
curr_idx += CCSDS_HEADER_LEN;
let sec_header = zc::PusTcSecondaryHeader::try_from(self.sec_header).unwrap();
sec_header
.to_bytes(&mut slice[curr_idx..curr_idx + tc_header_len])
.ok_or(PusError::PacketError(PacketError::ToBytesZeroCopyError))?;
.write_to_bytes(&mut slice[curr_idx..curr_idx + tc_header_len])
.ok_or(ByteConversionError::ZeroCopyToError)?;
curr_idx += tc_header_len;
if let Some(app_data) = self.app_data {
@ -369,6 +373,7 @@ impl<'slice> PusTc<'slice> {
}
#[cfg(feature = "alloc")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
pub fn append_to_vec(&self, vec: &mut Vec<u8>) -> Result<usize, PusError> {
let sph_zc = crate::zc::SpHeader::from(self.sp_header);
let mut appended_len = PUS_TC_MIN_LEN_WITHOUT_APP_DATA;
@ -399,29 +404,27 @@ impl<'slice> PusTc<'slice> {
}
/// Create a [PusTc] instance from a raw slice. On success, it returns a tuple containing
/// the instance and the found byte length of the packet
pub fn new_from_raw_slice(slice: &'slice [u8]) -> Result<(Self, usize), PusError> {
/// the instance and the found byte length of the packet.
pub fn from_bytes(slice: &'app_data [u8]) -> Result<(Self, usize), PusError> {
let raw_data_len = slice.len();
if raw_data_len < PUS_TC_MIN_LEN_WITHOUT_APP_DATA {
return Err(PusError::RawDataTooShort(raw_data_len));
}
let mut current_idx = 0;
let sph =
crate::zc::SpHeader::from_bytes(&slice[current_idx..current_idx + CCSDS_HEADER_LEN])
.ok_or(PusError::PacketError(PacketError::FromBytesZeroCopyError))?;
let (sp_header, _) = SpHeader::from_be_bytes(&slice[0..CCSDS_HEADER_LEN])?;
current_idx += CCSDS_HEADER_LEN;
let total_len = sph.total_len();
let total_len = sp_header.total_len();
if raw_data_len < total_len || total_len < PUS_TC_MIN_LEN_WITHOUT_APP_DATA {
return Err(PusError::RawDataTooShort(raw_data_len));
}
let sec_header = crate::tc::zc::PusTcSecondaryHeader::from_bytes(
let sec_header = zc::PusTcSecondaryHeader::from_bytes(
&slice[current_idx..current_idx + PUC_TC_SECONDARY_HEADER_LEN],
)
.ok_or(PusError::PacketError(PacketError::FromBytesZeroCopyError))?;
.ok_or(ByteConversionError::ZeroCopyFromError)?;
current_idx += PUC_TC_SECONDARY_HEADER_LEN;
let raw_data = &slice[0..total_len];
let pus_tc = PusTc {
sp_header: SpHeader::from(sph),
sp_header,
sec_header: PusTcSecondaryHeader::try_from(sec_header).unwrap(),
raw_data: Some(raw_data),
app_data: user_data_from_raw(current_idx, total_len, raw_data_len, slice)?,
@ -431,6 +434,10 @@ impl<'slice> PusTc<'slice> {
verify_crc16_from_raw(raw_data, pus_tc.crc16.expect("CRC16 invalid"))?;
Ok((pus_tc, total_len))
}
pub fn raw(&self) -> Option<&'app_data [u8]> {
self.raw_data
}
}
//noinspection RsTraitImplementation
@ -456,7 +463,7 @@ impl PusPacket for PusTc<'_> {
}
//noinspection RsTraitImplementation
impl PusTcSecondaryHeaderT for PusTc<'_> {
impl GenericPusTcSecondaryHeader for PusTc<'_> {
delegate!(to self.sec_header {
fn pus_version(&self) -> PusVersion;
fn service(&self) -> u8;
@ -466,29 +473,29 @@ impl PusTcSecondaryHeaderT for PusTc<'_> {
});
}
#[cfg(test)]
#[cfg(all(test, feature = "std"))]
mod tests {
use crate::ecss::PusVersion::PusC;
use crate::ecss::{PusError, PusPacket};
use crate::tc::ACK_ALL;
use crate::tc::{PusTc, PusTcSecondaryHeader, PusTcSecondaryHeaderT};
use crate::tc::{GenericPusTcSecondaryHeader, PusTc, PusTcSecondaryHeader};
use crate::{ByteConversionError, SpHeader};
use crate::{CcsdsPacket, SequenceFlags};
use crate::{PacketError, SpHeader};
use alloc::vec::Vec;
fn base_ping_tc_full_ctor() -> PusTc<'static> {
let mut sph = SpHeader::tc(0x02, 0x34, 0).unwrap();
let mut sph = SpHeader::tc_unseg(0x02, 0x34, 0).unwrap();
let tc_header = PusTcSecondaryHeader::new_simple(17, 1);
PusTc::new(&mut sph, tc_header, None, true)
}
fn base_ping_tc_simple_ctor() -> PusTc<'static> {
let mut sph = SpHeader::tc(0x02, 0x34, 0).unwrap();
let mut sph = SpHeader::tc_unseg(0x02, 0x34, 0).unwrap();
PusTc::new_simple(&mut sph, 17, 1, None, true)
}
fn base_ping_tc_simple_ctor_with_app_data(app_data: &'static [u8]) -> PusTc<'static> {
let mut sph = SpHeader::tc(0x02, 0x34, 0).unwrap();
let mut sph = SpHeader::tc_unseg(0x02, 0x34, 0).unwrap();
PusTc::new_simple(&mut sph, 17, 1, Some(app_data), true)
}
@ -504,7 +511,7 @@ mod tests {
let pus_tc = base_ping_tc_simple_ctor();
let mut test_buf: [u8; 32] = [0; 32];
let size = pus_tc
.write_to(test_buf.as_mut_slice())
.write_to_bytes(test_buf.as_mut_slice())
.expect("Error writing TC to buffer");
assert_eq!(size, 13);
}
@ -514,11 +521,11 @@ mod tests {
let pus_tc = base_ping_tc_simple_ctor();
let mut test_buf: [u8; 32] = [0; 32];
let size = pus_tc
.write_to(test_buf.as_mut_slice())
.write_to_bytes(test_buf.as_mut_slice())
.expect("Error writing TC to buffer");
assert_eq!(size, 13);
let (tc_from_raw, size) = PusTc::new_from_raw_slice(&test_buf)
.expect("Creating PUS TC struct from raw buffer failed");
let (tc_from_raw, size) =
PusTc::from_bytes(&test_buf).expect("Creating PUS TC struct from raw buffer failed");
assert_eq!(size, 13);
verify_test_tc(&tc_from_raw, false, 13);
assert!(tc_from_raw.user_data().is_none());
@ -528,7 +535,7 @@ mod tests {
#[test]
fn test_update_func() {
let mut sph = SpHeader::tc(0x02, 0x34, 0).unwrap();
let mut sph = SpHeader::tc_unseg(0x02, 0x34, 0).unwrap();
let mut tc = PusTc::new_simple(&mut sph, 17, 1, None, false);
tc.calc_crc_on_serialization = false;
assert_eq!(tc.data_len(), 0);
@ -540,11 +547,11 @@ mod tests {
let pus_tc = base_ping_tc_simple_ctor_with_app_data(&[1, 2, 3]);
let mut test_buf: [u8; 32] = [0; 32];
let size = pus_tc
.write_to(test_buf.as_mut_slice())
.write_to_bytes(test_buf.as_mut_slice())
.expect("Error writing TC to buffer");
assert_eq!(size, 16);
let (tc_from_raw, size) = PusTc::new_from_raw_slice(&test_buf)
.expect("Creating PUS TC struct from raw buffer failed");
let (tc_from_raw, size) =
PusTc::from_bytes(&test_buf).expect("Creating PUS TC struct from raw buffer failed");
assert_eq!(size, 16);
verify_test_tc(&tc_from_raw, true, 16);
let user_data = tc_from_raw.user_data().unwrap();
@ -554,7 +561,6 @@ mod tests {
}
#[test]
#[cfg(feature = "alloc")]
fn test_vec_ser_deser() {
let pus_tc = base_ping_tc_simple_ctor();
let mut test_vec = Vec::new();
@ -571,10 +577,10 @@ mod tests {
let pus_tc = base_ping_tc_simple_ctor();
let mut test_buf: [u8; 32] = [0; 32];
pus_tc
.write_to(test_buf.as_mut_slice())
.write_to_bytes(test_buf.as_mut_slice())
.expect("Error writing TC to buffer");
test_buf[12] = 0;
let res = PusTc::new_from_raw_slice(&test_buf);
let res = PusTc::from_bytes(&test_buf);
assert!(res.is_err());
let err = res.unwrap_err();
assert!(matches!(err, PusError::IncorrectCrc { .. }));
@ -587,7 +593,7 @@ mod tests {
let mut test_buf: [u8; 32] = [0; 32];
pus_tc.calc_own_crc16();
pus_tc
.write_to(test_buf.as_mut_slice())
.write_to_bytes(test_buf.as_mut_slice())
.expect("Error writing TC to buffer");
verify_test_tc_raw(&test_buf);
verify_crc_no_app_data(&test_buf);
@ -598,7 +604,7 @@ mod tests {
let mut pus_tc = base_ping_tc_simple_ctor();
pus_tc.calc_crc_on_serialization = false;
let mut test_buf: [u8; 32] = [0; 32];
let res = pus_tc.write_to(test_buf.as_mut_slice());
let res = pus_tc.write_to_bytes(test_buf.as_mut_slice());
assert!(res.is_err());
let err = res.unwrap_err();
assert!(matches!(err, PusError::CrcCalculationMissing { .. }));
@ -619,15 +625,15 @@ mod tests {
}
#[test]
fn test_write_buf_too_msall() {
fn test_write_buf_too_small() {
let pus_tc = base_ping_tc_simple_ctor();
let mut test_buf = [0; 12];
let res = pus_tc.write_to(test_buf.as_mut_slice());
let res = pus_tc.write_to_bytes(test_buf.as_mut_slice());
assert!(res.is_err());
let err = res.unwrap_err();
match err {
PusError::PacketError(err) => match err {
PacketError::ToBytesSliceTooSmall(missmatch) => {
PusError::ByteConversionError(err) => match err {
ByteConversionError::ToSliceTooSmall(missmatch) => {
assert_eq!(missmatch.expected, pus_tc.len_packed());
assert_eq!(missmatch.found, 12);
}
@ -643,7 +649,7 @@ mod tests {
verify_test_tc(&pus_tc, true, 16);
let mut test_buf: [u8; 32] = [0; 32];
let size = pus_tc
.write_to(test_buf.as_mut_slice())
.write_to_bytes(test_buf.as_mut_slice())
.expect("Error writing TC to buffer");
assert_eq!(test_buf[11], 1);
assert_eq!(test_buf[12], 2);
@ -667,7 +673,7 @@ mod tests {
assert_eq!(pus_tc.sequence_flags(), SequenceFlags::Unsegmented);
pus_tc.calc_own_crc16();
pus_tc
.write_to(test_buf.as_mut_slice())
.write_to_bytes(test_buf.as_mut_slice())
.expect("Error writing TC to buffer");
assert_eq!(test_buf[0], 0x1f);
assert_eq!(test_buf[1], 0xff);
@ -692,7 +698,7 @@ mod tests {
assert_eq!(tc.apid(), 0x02);
assert_eq!(tc.ack_flags(), ACK_ALL);
assert_eq!(tc.len_packed(), exp_full_len);
let mut comp_header = SpHeader::tc(0x02, 0x34, exp_full_len as u16 - 7).unwrap();
let mut comp_header = SpHeader::tc_unseg(0x02, 0x34, exp_full_len as u16 - 7).unwrap();
comp_header.set_sec_header_flag();
assert_eq!(tc.sp_header, comp_header);
}

447
src/time.rs
View File

@ -1,447 +0,0 @@
//! CCSDS Time Code Formats according to [CCSDS 301.0-B-4](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
use crate::{PacketError, SizeMissmatch};
use chrono::{DateTime, TimeZone, Utc};
#[allow(unused_imports)]
#[cfg(not(feature = "std"))]
use num_traits::float::FloatCore;
use crate::time::CcsdsTimeCodes::Cds;
#[cfg(feature = "std")]
use std::time::{SystemTime, SystemTimeError};
pub const CDS_SHORT_LEN: usize = 7;
pub const DAYS_CCSDS_TO_UNIX: i32 = -4383;
pub const SECONDS_PER_DAY: u32 = 86400;
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
pub enum CcsdsTimeCodes {
None = 0,
CucCcsdsEpoch = 0b001,
CucAgencyEpoch = 0b010,
Cds = 0b100,
Ccs = 0b101,
}
impl TryFrom<u8> for CcsdsTimeCodes {
type Error = ();
fn try_from(value: u8) -> Result<Self, Self::Error> {
match value {
x if x == CcsdsTimeCodes::None as u8 => Ok(CcsdsTimeCodes::None),
x if x == CcsdsTimeCodes::CucCcsdsEpoch as u8 => Ok(CcsdsTimeCodes::CucCcsdsEpoch),
x if x == CcsdsTimeCodes::CucAgencyEpoch as u8 => Ok(CcsdsTimeCodes::CucAgencyEpoch),
x if x == CcsdsTimeCodes::Cds as u8 => Ok(CcsdsTimeCodes::Cds),
x if x == CcsdsTimeCodes::Ccs as u8 => Ok(CcsdsTimeCodes::Ccs),
_ => Err(()),
}
}
}
#[derive(Debug, PartialEq, Eq)]
pub enum TimestampError {
/// Contains tuple where first value is the expected time code and the second
/// value is the found raw value
InvalidTimeCode(CcsdsTimeCodes, u8),
OtherPacketError(PacketError),
}
#[cfg(feature = "std")]
pub fn seconds_since_epoch() -> f64 {
SystemTime::now()
.duration_since(SystemTime::UNIX_EPOCH)
.expect("System time generation failed")
.as_secs_f64()
}
/// Convert UNIX days to CCSDS days
///
/// - CCSDS epoch: 1958 January 1
/// - UNIX Epoch: 1970 January 1
pub const fn unix_to_ccsds_days(unix_days: i32) -> i32 {
unix_days - DAYS_CCSDS_TO_UNIX
}
/// Convert CCSDS days to UNIX days
///
/// - CCSDS epoch: 1958 January 1
/// - UNIX Epoch: 1970 January 1
pub const fn ccsds_to_unix_days(ccsds_days: i32) -> i32 {
ccsds_days + DAYS_CCSDS_TO_UNIX
}
pub trait TimeWriter {
fn write_to_bytes(&self, bytes: &mut [u8]) -> Result<(), PacketError>;
}
pub trait TimeReader {
fn from_bytes(buf: &[u8]) -> Result<Self, TimestampError>
where
Self: Sized;
}
/// Trait for generic CCSDS time providers
pub trait CcsdsTimeProvider {
fn len_as_bytes(&self) -> usize;
/// Returns the pfield of the time provider. The pfield can have one or two bytes depending
/// on the extension bit (first bit). The time provider should returns a tuple where the first
/// entry denotes the length of the pfield and the second entry is the value of the pfield
/// in big endian format.
fn p_field(&self) -> (usize, [u8; 2]);
fn ccdsd_time_code(&self) -> CcsdsTimeCodes;
fn unix_seconds(&self) -> i64;
fn date_time(&self) -> DateTime<Utc>;
}
#[derive(Debug, Copy, Clone)]
pub struct CdsShortTimeProvider {
pfield: u8,
ccsds_days: u16,
ms_of_day: u32,
unix_seconds: i64,
date_time: Option<DateTime<Utc>>,
}
impl CdsShortTimeProvider {
pub fn new(ccsds_days: u16, ms_of_day: u32) -> Self {
let provider = Self {
pfield: (CcsdsTimeCodes::Cds as u8) << 4,
ccsds_days,
ms_of_day,
unix_seconds: 0,
date_time: None,
};
let unix_days_seconds =
ccsds_to_unix_days(ccsds_days as i32) as i64 * SECONDS_PER_DAY as i64;
provider.setup(unix_days_seconds as i64, ms_of_day.into())
}
#[cfg(feature = "std")]
pub fn from_now() -> Result<Self, SystemTimeError> {
let now = SystemTime::now().duration_since(SystemTime::UNIX_EPOCH)?;
let epoch = now.as_secs();
let secs_of_day = epoch % SECONDS_PER_DAY as u64;
let unix_days_seconds = epoch - secs_of_day;
let ms_of_day = secs_of_day * 1000 + now.subsec_millis() as u64;
let provider = Self {
pfield: (CcsdsTimeCodes::Cds as u8) << 4,
ccsds_days: unix_to_ccsds_days((unix_days_seconds / SECONDS_PER_DAY as u64) as i32)
as u16,
ms_of_day: ms_of_day as u32,
unix_seconds: 0,
date_time: None,
};
Ok(provider.setup(unix_days_seconds as i64, ms_of_day))
}
fn setup(mut self, unix_days_seconds: i64, ms_of_day: u64) -> Self {
self.calc_unix_seconds(unix_days_seconds, ms_of_day);
self.calc_date_time((ms_of_day % 1000) as u32);
self
}
#[cfg(feature = "std")]
pub fn ms_of_day_using_sysclock() -> u32 {
Self::ms_of_day(seconds_since_epoch())
}
pub fn ms_of_day(seconds_since_epoch: f64) -> u32 {
let fraction_ms = seconds_since_epoch - seconds_since_epoch.floor();
let ms_of_day: u32 =
(((seconds_since_epoch.floor() as u32 % SECONDS_PER_DAY) * 1000) as f64 + fraction_ms)
.floor() as u32;
ms_of_day
}
fn calc_unix_seconds(&mut self, unix_days_seconds: i64, ms_of_day: u64) {
self.unix_seconds = unix_days_seconds;
let seconds_of_day = (ms_of_day / 1000) as i64;
if self.unix_seconds < 0 {
self.unix_seconds -= seconds_of_day;
} else {
self.unix_seconds += seconds_of_day;
}
}
fn calc_date_time(&mut self, ms_since_last_second: u32) {
assert!(ms_since_last_second < 1000, "Invalid MS since last second");
let ns_since_last_sec = ms_since_last_second * 1e6 as u32;
self.date_time = Some(Utc.timestamp(self.unix_seconds, ns_since_last_sec));
}
}
impl CcsdsTimeProvider for CdsShortTimeProvider {
fn len_as_bytes(&self) -> usize {
CDS_SHORT_LEN
}
fn p_field(&self) -> (usize, [u8; 2]) {
(1, [self.pfield, 0])
}
fn ccdsd_time_code(&self) -> CcsdsTimeCodes {
CcsdsTimeCodes::Cds
}
fn unix_seconds(&self) -> i64 {
self.unix_seconds
}
fn date_time(&self) -> DateTime<Utc> {
self.date_time.expect("Invalid date time")
}
}
impl TimeWriter for CdsShortTimeProvider {
fn write_to_bytes(&self, buf: &mut [u8]) -> Result<(), PacketError> {
if buf.len() < self.len_as_bytes() {
return Err(PacketError::ToBytesSliceTooSmall(SizeMissmatch {
expected: self.len_as_bytes(),
found: buf.len(),
}));
}
buf[0] = self.pfield;
buf[1..3].copy_from_slice(self.ccsds_days.to_be_bytes().as_slice());
buf[3..7].copy_from_slice(self.ms_of_day.to_be_bytes().as_slice());
Ok(())
}
}
impl TimeReader for CdsShortTimeProvider {
fn from_bytes(buf: &[u8]) -> Result<Self, TimestampError> {
if buf.len() < CDS_SHORT_LEN {
return Err(TimestampError::OtherPacketError(
PacketError::FromBytesSliceTooSmall(SizeMissmatch {
expected: CDS_SHORT_LEN,
found: buf.len(),
}),
));
}
let pfield = buf[0];
match CcsdsTimeCodes::try_from(pfield >> 4 & 0b111) {
Ok(cds_type) => match cds_type {
Cds => (),
_ => {
return Err(TimestampError::InvalidTimeCode(
CcsdsTimeCodes::Cds,
cds_type as u8,
))
}
},
_ => {
return Err(TimestampError::InvalidTimeCode(
CcsdsTimeCodes::Cds,
pfield >> 4 & 0b111,
))
}
};
let ccsds_days: u16 = u16::from_be_bytes(buf[1..3].try_into().unwrap());
let ms_of_day: u32 = u32::from_be_bytes(buf[3..7].try_into().unwrap());
Ok(Self::new(ccsds_days, ms_of_day))
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::time::TimestampError::{InvalidTimeCode, OtherPacketError};
use crate::PacketError::{FromBytesSliceTooSmall, ToBytesSliceTooSmall};
use alloc::format;
use chrono::{Datelike, Timelike};
#[test]
fn test_creation() {
assert_eq!(unix_to_ccsds_days(DAYS_CCSDS_TO_UNIX), 0);
assert_eq!(ccsds_to_unix_days(0), DAYS_CCSDS_TO_UNIX);
}
#[cfg(feature = "std")]
#[test]
fn test_get_current_time() {
let sec_floats = seconds_since_epoch();
assert!(sec_floats > 0.0);
}
#[test]
fn test_time_stamp_zero_args() {
let time_stamper = CdsShortTimeProvider::new(0, 0);
assert_eq!(
time_stamper.unix_seconds(),
(DAYS_CCSDS_TO_UNIX * SECONDS_PER_DAY as i32) as i64
);
assert_eq!(time_stamper.ccdsd_time_code(), CcsdsTimeCodes::Cds);
assert_eq!(
time_stamper.p_field(),
(1, [(CcsdsTimeCodes::Cds as u8) << 4, 0])
);
let date_time = time_stamper.date_time();
assert_eq!(date_time.year(), 1958);
assert_eq!(date_time.month(), 1);
assert_eq!(date_time.day(), 1);
assert_eq!(date_time.hour(), 0);
assert_eq!(date_time.minute(), 0);
assert_eq!(date_time.second(), 0);
}
#[test]
fn test_time_stamp_unix_epoch() {
let time_stamper = CdsShortTimeProvider::new((-DAYS_CCSDS_TO_UNIX) as u16, 0);
assert_eq!(time_stamper.unix_seconds(), 0);
let date_time = time_stamper.date_time();
assert_eq!(date_time.year(), 1970);
assert_eq!(date_time.month(), 1);
assert_eq!(date_time.day(), 1);
assert_eq!(date_time.hour(), 0);
assert_eq!(date_time.minute(), 0);
assert_eq!(date_time.second(), 0);
}
#[test]
fn test_write() {
let mut buf = [0; 16];
let time_stamper_0 = CdsShortTimeProvider::new(0, 0);
let mut res = time_stamper_0.write_to_bytes(&mut buf);
assert!(res.is_ok());
assert_eq!(buf[0], (CcsdsTimeCodes::Cds as u8) << 4);
assert_eq!(
u16::from_be_bytes(buf[1..3].try_into().expect("Byte conversion failed")),
0
);
assert_eq!(
u32::from_be_bytes(buf[3..7].try_into().expect("Byte conversion failed")),
0
);
let time_stamper_1 = CdsShortTimeProvider::new(u16::MAX - 1, u32::MAX - 1);
res = time_stamper_1.write_to_bytes(&mut buf);
assert!(res.is_ok());
assert_eq!(buf[0], (CcsdsTimeCodes::Cds as u8) << 4);
assert_eq!(
u16::from_be_bytes(buf[1..3].try_into().expect("Byte conversion failed")),
u16::MAX - 1
);
assert_eq!(
u32::from_be_bytes(buf[3..7].try_into().expect("Byte conversion failed")),
u32::MAX - 1
);
}
#[test]
fn test_faulty_write_buf_too_small() {
let mut buf = [0; 7];
let time_stamper = CdsShortTimeProvider::new(u16::MAX - 1, u32::MAX - 1);
for i in 0..6 {
let res = time_stamper.write_to_bytes(&mut buf[0..i]);
assert!(res.is_err());
match res.unwrap_err() {
ToBytesSliceTooSmall(missmatch) => {
assert_eq!(missmatch.found, i);
assert_eq!(missmatch.expected, 7);
}
_ => panic!(
"{}",
format!("Invalid error {:?} detected", res.unwrap_err())
),
}
}
}
#[test]
fn test_faulty_read_buf_too_small() {
let buf = [0; 7];
for i in 0..6 {
let res = CdsShortTimeProvider::from_bytes(&buf[0..i]);
assert!(res.is_err());
match res.unwrap_err() {
InvalidTimeCode(_, _) => {
panic!("Unexpected error");
}
OtherPacketError(e) => match e {
FromBytesSliceTooSmall(missmatch) => {
assert_eq!(missmatch.found, i);
assert_eq!(missmatch.expected, 7);
}
_ => panic!("{}", format!("Invalid error {:?} detected", e)),
},
}
}
}
#[test]
fn test_faulty_invalid_pfield() {
let mut buf = [0; 16];
let time_stamper_0 = CdsShortTimeProvider::new(0, 0);
let res = time_stamper_0.write_to_bytes(&mut buf);
assert!(res.is_ok());
buf[0] = 0;
let res = CdsShortTimeProvider::from_bytes(&buf);
assert!(res.is_err());
let err = res.unwrap_err();
match err {
InvalidTimeCode(code, raw) => {
assert_eq!(code, CcsdsTimeCodes::Cds);
assert_eq!(raw, 0);
}
OtherPacketError(_) => {}
}
}
#[test]
fn test_reading() {
let mut buf = [0; 16];
let time_stamper = CdsShortTimeProvider::new(u16::MAX - 1, u32::MAX - 1);
let res = time_stamper.write_to_bytes(&mut buf);
assert!(res.is_ok());
assert_eq!(buf[0], (CcsdsTimeCodes::Cds as u8) << 4);
assert_eq!(
u16::from_be_bytes(buf[1..3].try_into().expect("Byte conversion failed")),
u16::MAX - 1
);
assert_eq!(
u32::from_be_bytes(buf[3..7].try_into().expect("Byte conversion failed")),
u32::MAX - 1
);
let read_stamp = CdsShortTimeProvider::from_bytes(&buf).expect("Reading timestamp failed");
assert_eq!(read_stamp.ccsds_days, u16::MAX - 1);
assert_eq!(read_stamp.ms_of_day, u32::MAX - 1);
}
#[cfg(feature = "std")]
#[test]
fn test_time_now() {
let timestamp_now = CdsShortTimeProvider::from_now().unwrap();
let compare_stamp = Utc::now();
let dt = timestamp_now.date_time();
if compare_stamp.year() > dt.year() {
assert_eq!(compare_stamp.year() - dt.year(), 1);
} else {
assert_eq!(dt.year(), compare_stamp.year());
}
generic_dt_property_equality_check(dt.month(), compare_stamp.month(), 1, 12);
assert_eq!(dt.day(), compare_stamp.day());
if compare_stamp.day() < dt.day() {
assert!(dt.day() >= 28);
assert_eq!(compare_stamp.day(), 1);
} else if compare_stamp.day() > dt.day() {
assert_eq!(compare_stamp.day() - dt.day(), 1);
} else {
assert_eq!(compare_stamp.day(), dt.day());
}
generic_dt_property_equality_check(dt.hour(), compare_stamp.hour(), 0, 23);
generic_dt_property_equality_check(dt.minute(), compare_stamp.minute(), 0, 59);
}
#[cfg(feature = "std")]
fn generic_dt_property_equality_check(first: u32, second: u32, start: u32, end: u32) {
if second < first {
assert_eq!(second, start);
assert_eq!(first, end);
} else if second > first {
assert_eq!(second - first, 1);
} else {
assert_eq!(first, second);
}
}
}

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//! Module to generate the ASCII timecodes specified in
//! [CCSDS 301.0-B-4](https://public.ccsds.org/Pubs/301x0b4e1.pdf) section 3.5 .
//! See [chrono::DateTime::format] for a usage example of the generated
//! [chrono::format::DelayedFormat] structs.
#[cfg(feature = "alloc")]
use chrono::{
format::{DelayedFormat, StrftimeItems},
DateTime, Utc,
};
/// Tuple of format string and formatted size for time code A.
///
/// Format: YYYY-MM-DDThh:mm:ss.ddd
///
/// Three digits are used for the decimal fraction
pub const FMT_STR_CODE_A_WITH_SIZE: (&str, usize) = ("%FT%T%.3f", 23);
/// Tuple of format string and formatted size for time code A.
///
/// Format: YYYY-MM-DDThh:mm:ss.dddZ
///
/// Three digits are used for the decimal fraction and a terminator is added at the end.
pub const FMT_STR_CODE_A_TERMINATED_WITH_SIZE: (&str, usize) = ("%FT%T%.3fZ", 24);
/// Tuple of format string and formatted size for time code A.
///
/// Format: YYYY-DDDThh:mm:ss.ddd
///
/// Three digits are used for the decimal fraction
pub const FMT_STR_CODE_B_WITH_SIZE: (&str, usize) = ("%Y-%jT%T%.3f", 21);
/// Tuple of format string and formatted size for time code A.
///
/// Format: YYYY-DDDThh:mm:ss.dddZ
///
/// Three digits are used for the decimal fraction and a terminator is added at the end.
pub const FMT_STR_CODE_B_TERMINATED_WITH_SIZE: (&str, usize) = ("%Y-%jT%T%.3fZ", 22);
/// Generates a time code formatter using the [FMT_STR_CODE_A_WITH_SIZE] format.
#[cfg(feature = "alloc")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
pub fn generate_time_code_a(date: &DateTime<Utc>) -> DelayedFormat<StrftimeItems<'static>> {
date.format(FMT_STR_CODE_A_WITH_SIZE.0)
}
/// Generates a time code formatter using the [FMT_STR_CODE_A_TERMINATED_WITH_SIZE] format.
#[cfg(feature = "alloc")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
pub fn generate_time_code_a_terminated(
date: &DateTime<Utc>,
) -> DelayedFormat<StrftimeItems<'static>> {
date.format(FMT_STR_CODE_A_TERMINATED_WITH_SIZE.0)
}
/// Generates a time code formatter using the [FMT_STR_CODE_B_WITH_SIZE] format.
#[cfg(feature = "alloc")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
pub fn generate_time_code_b(date: &DateTime<Utc>) -> DelayedFormat<StrftimeItems<'static>> {
date.format(FMT_STR_CODE_B_WITH_SIZE.0)
}
/// Generates a time code formatter using the [FMT_STR_CODE_B_TERMINATED_WITH_SIZE] format.
#[cfg(feature = "alloc")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
pub fn generate_time_code_b_terminated(
date: &DateTime<Utc>,
) -> DelayedFormat<StrftimeItems<'static>> {
date.format(FMT_STR_CODE_B_TERMINATED_WITH_SIZE.0)
}
#[cfg(test)]
mod tests {
use super::*;
use chrono::Utc;
use std::format;
#[test]
fn test_ascii_timestamp_a_unterminated() {
let date = Utc::now();
let stamp_formatter = generate_time_code_a(&date);
let stamp = format!("{}", stamp_formatter);
let t_sep = stamp.find("T");
assert!(t_sep.is_some());
assert_eq!(t_sep.unwrap(), 10);
assert_eq!(stamp.len(), FMT_STR_CODE_A_WITH_SIZE.1);
}
#[test]
fn test_ascii_timestamp_a_terminated() {
let date = Utc::now();
let stamp_formatter = generate_time_code_a_terminated(&date);
let stamp = format!("{}", stamp_formatter);
let t_sep = stamp.find("T");
assert!(t_sep.is_some());
assert_eq!(t_sep.unwrap(), 10);
let z_terminator = stamp.find("Z");
assert!(z_terminator.is_some());
assert_eq!(
z_terminator.unwrap(),
FMT_STR_CODE_A_TERMINATED_WITH_SIZE.1 - 1
);
assert_eq!(stamp.len(), FMT_STR_CODE_A_TERMINATED_WITH_SIZE.1);
}
#[test]
fn test_ascii_timestamp_b_unterminated() {
let date = Utc::now();
let stamp_formatter = generate_time_code_b(&date);
let stamp = format!("{}", stamp_formatter);
let t_sep = stamp.find("T");
assert!(t_sep.is_some());
assert_eq!(t_sep.unwrap(), 8);
assert_eq!(stamp.len(), FMT_STR_CODE_B_WITH_SIZE.1);
}
#[test]
fn test_ascii_timestamp_b_terminated() {
let date = Utc::now();
let stamp_formatter = generate_time_code_b_terminated(&date);
let stamp = format!("{}", stamp_formatter);
let t_sep = stamp.find("T");
assert!(t_sep.is_some());
assert_eq!(t_sep.unwrap(), 8);
let z_terminator = stamp.find("Z");
assert!(z_terminator.is_some());
assert_eq!(
z_terminator.unwrap(),
FMT_STR_CODE_B_TERMINATED_WITH_SIZE.1 - 1
);
assert_eq!(stamp.len(), FMT_STR_CODE_B_TERMINATED_WITH_SIZE.1);
}
}

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//! Module to generate or read CCSDS Day Segmented (CDS) timestamps as specified in
//! [CCSDS 301.0-B-4](https://public.ccsds.org/Pubs/301x0b4e1.pdf) section 3.3 .
//!
//! The core data structure to do this is the [cds::TimeProvider] struct.
use super::*;
use crate::private::Sealed;
use core::fmt::Debug;
/// Base value for the preamble field for a time field parser to determine the time field type.
pub const P_FIELD_BASE: u8 = (CcsdsTimeCodes::Cds as u8) << 4;
pub const MIN_CDS_FIELD_LEN: usize = 7;
/// Generic trait implemented by token structs to specify the length of day field at type
/// level. This trait is only meant to be implemented in this crate and therefore sealed.
pub trait ProvidesDaysLength: Sealed {
type FieldType: Copy + Clone + TryFrom<i32>;
}
/// Type level token to be used as a generic parameter to [TimeProvider].
#[derive(Debug, PartialEq, Eq, Default)]
pub struct DaysLen16Bits {}
impl Sealed for DaysLen16Bits {}
impl ProvidesDaysLength for DaysLen16Bits {
type FieldType = u16;
}
/// Type level token to be used as a generic parameter to [TimeProvider].
#[derive(Debug, PartialEq, Eq, Default)]
pub struct DaysLen24Bits {}
impl Sealed for DaysLen24Bits {}
impl ProvidesDaysLength for DaysLen24Bits {
type FieldType = u32;
}
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum LengthOfDaySegment {
Short16Bits = 0,
Long24Bits = 1,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum SubmillisPrecision {
Absent,
Microseconds(u16),
Picoseconds(u32),
Reserved,
}
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum CdsError {
/// CCSDS days value exceeds maximum allowed size or is negative
InvalidCcsdsDays(i64),
/// There are distinct constructors depending on the days field width detected in the preamble
/// field. This error will be returned if there is a missmatch.
InvalidCtorForDaysOfLenInPreamble(LengthOfDaySegment),
}
impl Display for CdsError {
fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result {
match self {
CdsError::InvalidCcsdsDays(days) => {
write!(f, "invalid ccsds days {}", days)
}
CdsError::InvalidCtorForDaysOfLenInPreamble(length_of_day) => {
write!(
f,
"wrong constructor for length of day {:?} detected in preamble",
length_of_day
)
}
}
}
}
#[cfg(feature = "std")]
impl Error for CdsError {}
pub fn length_of_day_segment_from_pfield(pfield: u8) -> LengthOfDaySegment {
if (pfield >> 2) & 0b1 == 1 {
return LengthOfDaySegment::Long24Bits;
}
LengthOfDaySegment::Short16Bits
}
pub fn precision_from_pfield(pfield: u8) -> SubmillisPrecision {
match pfield & 0b11 {
0b01 => SubmillisPrecision::Microseconds(0),
0b10 => SubmillisPrecision::Picoseconds(0),
0b00 => SubmillisPrecision::Absent,
0b11 => SubmillisPrecision::Reserved,
_ => panic!("pfield to SubmillisPrecision failed"),
}
}
/// This object is the abstraction for the CCSDS Day Segmented Time Code (CDS).
///
/// It has the capability to generate and read timestamps as specified in the CCSDS 301.0-B-4
/// section 3.3 . The width of the days field is configured at compile time via the generic
/// [ProvidesDaysLength] trait which is implemented by [DaysLen16Bits] and [DaysLen24Bits].
///
/// Custom epochs are not supported yet.
/// Furthermore, the preamble field (p-field) is explicitly conveyed.
/// That means it will always be present when writing the time stamp to a raw buffer, and it
/// must be present when reading a CDS timestamp from a raw buffer.
///
/// # Example
///
/// ```
/// use spacepackets::time::cds::{TimeProvider, DaysLen16Bits};
/// use spacepackets::time::{TimeWriter, CcsdsTimeCodes, TimeReader, CcsdsTimeProvider};
///
/// let timestamp_now = TimeProvider::from_now_with_u16_days().unwrap();
/// let mut raw_stamp = [0; 7];
/// {
/// let written = timestamp_now.write_to_bytes(&mut raw_stamp).unwrap();
/// assert_eq!((raw_stamp[0] >> 4) & 0b111, CcsdsTimeCodes::Cds as u8);
/// assert_eq!(written, 7);
/// }
/// {
/// let read_result = TimeProvider::<DaysLen16Bits>::from_bytes(&raw_stamp);
/// assert!(read_result.is_ok());
/// let stamp_deserialized = read_result.unwrap();
/// assert_eq!(stamp_deserialized.len_as_bytes(), 7);
/// }
/// ```
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct TimeProvider<DaysLen: ProvidesDaysLength = DaysLen16Bits> {
pfield: u8,
ccsds_days: DaysLen::FieldType,
ms_of_day: u32,
submillis_precision: Option<SubmillisPrecision>,
unix_seconds: i64,
}
#[cfg(feature = "std")]
struct ConversionFromNow {
ccsds_days: i32,
ms_of_day: u64,
unix_days_seconds: u64,
submillis_prec: Option<SubmillisPrecision>,
}
#[cfg(feature = "std")]
impl ConversionFromNow {
fn new() -> Result<Self, SystemTimeError> {
Self::new_generic(None)
}
fn new_with_submillis_us_prec() -> Result<Self, SystemTimeError> {
Self::new_generic(Some(SubmillisPrecision::Microseconds(0)))
}
fn new_with_submillis_ps_prec() -> Result<Self, SystemTimeError> {
Self::new_generic(Some(SubmillisPrecision::Picoseconds(0)))
}
fn new_generic(mut prec: Option<SubmillisPrecision>) -> Result<Self, SystemTimeError> {
let now = SystemTime::now().duration_since(SystemTime::UNIX_EPOCH)?;
let epoch = now.as_secs();
let secs_of_day = epoch % SECONDS_PER_DAY as u64;
let unix_days_seconds = epoch - secs_of_day;
if let Some(submilli_prec) = prec {
match submilli_prec {
SubmillisPrecision::Microseconds(_) => {
prec = Some(SubmillisPrecision::Microseconds(
(now.subsec_micros() % 1000) as u16,
));
}
SubmillisPrecision::Picoseconds(_) => {
prec = Some(SubmillisPrecision::Picoseconds(now.subsec_nanos() * 1000));
}
_ => (),
}
}
Ok(Self {
ms_of_day: secs_of_day * 1000 + now.subsec_millis() as u64,
ccsds_days: unix_to_ccsds_days((unix_days_seconds / SECONDS_PER_DAY as u64) as i64)
as i32,
unix_days_seconds,
submillis_prec: prec,
})
}
}
impl<ProvidesDaysLen: ProvidesDaysLength> TimeProvider<ProvidesDaysLen> {
pub fn set_submillis_precision(&mut self, prec: SubmillisPrecision) {
self.pfield &= !(0b11);
if let SubmillisPrecision::Absent = prec {
self.submillis_precision = None;
return;
}
self.submillis_precision = Some(prec);
match prec {
SubmillisPrecision::Microseconds(_) => {
self.pfield |= 0b01;
}
SubmillisPrecision::Picoseconds(_) => {
self.pfield |= 0b10;
}
_ => (),
}
}
pub fn clear_submillis_precision(&mut self) {
self.pfield &= !(0b11);
self.submillis_precision = None;
}
pub fn ccsds_days(&self) -> ProvidesDaysLen::FieldType {
self.ccsds_days
}
pub fn submillis_precision(&self) -> Option<SubmillisPrecision> {
self.submillis_precision
}
pub fn ms_of_day(&self) -> u32 {
self.ms_of_day
}
fn generic_raw_read_checks(
buf: &[u8],
days_len: LengthOfDaySegment,
) -> Result<SubmillisPrecision, TimestampError> {
if buf.len() < MIN_CDS_FIELD_LEN {
return Err(TimestampError::ByteConversionError(
ByteConversionError::FromSliceTooSmall(SizeMissmatch {
expected: MIN_CDS_FIELD_LEN,
found: buf.len(),
}),
));
}
let pfield = buf[0];
match CcsdsTimeCodes::try_from(pfield >> 4 & 0b111) {
Ok(cds_type) => match cds_type {
CcsdsTimeCodes::Cds => (),
_ => {
return Err(TimestampError::InvalidTimeCode(
CcsdsTimeCodes::Cds,
cds_type as u8,
))
}
},
_ => {
return Err(TimestampError::InvalidTimeCode(
CcsdsTimeCodes::Cds,
pfield >> 4 & 0b111,
))
}
};
if ((pfield >> 3) & 0b1) == 1 {
return Err(TimestampError::CustomEpochNotSupported);
}
let days_len_from_pfield = length_of_day_segment_from_pfield(pfield);
if days_len_from_pfield != days_len {
return Err(CdsError::InvalidCtorForDaysOfLenInPreamble(days_len_from_pfield).into());
}
let stamp_len = Self::calc_stamp_len(pfield);
if buf.len() < stamp_len {
return Err(TimestampError::ByteConversionError(
ByteConversionError::FromSliceTooSmall(SizeMissmatch {
expected: stamp_len,
found: buf.len(),
}),
));
}
Ok(precision_from_pfield(pfield))
}
fn calc_stamp_len(pfield: u8) -> usize {
let mut init_len = 7;
if length_of_day_segment_from_pfield(pfield) == LengthOfDaySegment::Long24Bits {
init_len += 1
}
match pfield & 0b11 {
0b01 => {
init_len += 2;
}
0b10 => {
init_len += 4;
}
_ => (),
}
init_len
}
fn setup(&mut self, unix_days_seconds: i64, ms_of_day: u64) {
self.calc_unix_seconds(unix_days_seconds, ms_of_day);
}
fn calc_unix_seconds(&mut self, unix_days_seconds: i64, ms_of_day: u64) {
self.unix_seconds = unix_days_seconds;
let seconds_of_day = (ms_of_day / 1000) as i64;
if self.unix_seconds < 0 {
self.unix_seconds -= seconds_of_day;
} else {
self.unix_seconds += seconds_of_day;
}
}
fn calc_date_time(&self, ms_since_last_second: u32) -> Option<DateTime<Utc>> {
assert!(ms_since_last_second < 1000, "Invalid MS since last second");
let ns_since_last_sec = ms_since_last_second * 1e6 as u32;
if let LocalResult::Single(val) = Utc.timestamp_opt(self.unix_seconds, ns_since_last_sec) {
return Some(val);
}
None
}
fn length_check(&self, buf: &[u8], len_as_bytes: usize) -> Result<(), TimestampError> {
if buf.len() < len_as_bytes {
return Err(TimestampError::ByteConversionError(
ByteConversionError::ToSliceTooSmall(SizeMissmatch {
expected: len_as_bytes,
found: buf.len(),
}),
));
}
Ok(())
}
fn generic_new(
days_len: LengthOfDaySegment,
ccsds_days: ProvidesDaysLen::FieldType,
ms_of_day: u32,
) -> Result<Self, CdsError>
where
i64: From<ProvidesDaysLen::FieldType>,
{
let mut provider = Self {
pfield: Self::generate_p_field(days_len, None),
ccsds_days,
ms_of_day,
unix_seconds: 0,
submillis_precision: None,
};
let unix_days_seconds = ccsds_to_unix_days(ccsds_days.into()) * SECONDS_PER_DAY as i64;
provider.setup(unix_days_seconds, ms_of_day.into());
Ok(provider)
}
#[cfg(feature = "std")]
fn generic_from_now(
days_len: LengthOfDaySegment,
conversion_from_now: ConversionFromNow,
) -> Result<Self, StdTimestampError>
where
<ProvidesDaysLen::FieldType as TryFrom<i32>>::Error: Debug,
{
let ccsds_days: ProvidesDaysLen::FieldType =
conversion_from_now.ccsds_days.try_into().map_err(|_| {
StdTimestampError::TimestampError(
CdsError::InvalidCcsdsDays(conversion_from_now.ccsds_days.into()).into(),
)
})?;
let mut provider = Self {
pfield: Self::generate_p_field(days_len, conversion_from_now.submillis_prec),
ccsds_days,
ms_of_day: conversion_from_now.ms_of_day as u32,
unix_seconds: 0,
submillis_precision: conversion_from_now.submillis_prec,
};
provider.setup(
conversion_from_now.unix_days_seconds as i64,
conversion_from_now.ms_of_day,
);
Ok(provider)
}
#[cfg(feature = "std")]
fn generic_conversion_from_now(&self) -> Result<ConversionFromNow, SystemTimeError> {
Ok(match self.submillis_precision {
None => ConversionFromNow::new()?,
Some(prec) => match prec {
SubmillisPrecision::Microseconds(_) => {
ConversionFromNow::new_with_submillis_us_prec()?
}
SubmillisPrecision::Picoseconds(_) => {
ConversionFromNow::new_with_submillis_ps_prec()?
}
_ => ConversionFromNow::new()?,
},
})
}
fn generate_p_field(
day_seg_len: LengthOfDaySegment,
submillis_prec: Option<SubmillisPrecision>,
) -> u8 {
let mut pfield = P_FIELD_BASE | ((day_seg_len as u8) << 2);
if let Some(submillis_prec) = submillis_prec {
match submillis_prec {
SubmillisPrecision::Microseconds(_) => pfield |= 0b01,
SubmillisPrecision::Picoseconds(_) => pfield |= 0b10,
SubmillisPrecision::Reserved => pfield |= 0b11,
_ => (),
}
}
pfield
}
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn update_from_now(&mut self) -> Result<(), StdTimestampError>
where
<ProvidesDaysLen::FieldType as TryFrom<i32>>::Error: Debug,
{
let conversion_from_now = self.generic_conversion_from_now()?;
let ccsds_days: ProvidesDaysLen::FieldType =
conversion_from_now.ccsds_days.try_into().map_err(|_| {
StdTimestampError::TimestampError(
CdsError::InvalidCcsdsDays(conversion_from_now.ccsds_days as i64).into(),
)
})?;
self.ccsds_days = ccsds_days;
self.ms_of_day = conversion_from_now.ms_of_day as u32;
self.setup(
conversion_from_now.unix_days_seconds as i64,
conversion_from_now.ms_of_day,
);
Ok(())
}
}
impl TimeProvider<DaysLen24Bits> {
/// Generate a new timestamp provider with the days field width set to 24 bits
pub fn new_with_u24_days(ccsds_days: u32, ms_of_day: u32) -> Result<Self, CdsError> {
if ccsds_days > 2_u32.pow(24) {
return Err(CdsError::InvalidCcsdsDays(ccsds_days.into()));
}
Self::generic_new(LengthOfDaySegment::Long24Bits, ccsds_days, ms_of_day)
}
/// Generate a time stamp from the current time using the system clock.
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn from_now_with_u24_days() -> Result<Self, StdTimestampError> {
let conversion_from_now = ConversionFromNow::new()?;
Self::generic_from_now(LengthOfDaySegment::Long24Bits, conversion_from_now)
}
/// Like [Self::from_now_with_u24_days] but with microsecond sub-millisecond precision.
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn from_now_with_u24_days_and_us_prec() -> Result<Self, StdTimestampError> {
let conversion_from_now = ConversionFromNow::new_with_submillis_us_prec()?;
Self::generic_from_now(LengthOfDaySegment::Long24Bits, conversion_from_now)
}
/// Like [Self::from_now_with_u24_days] but with picoseconds sub-millisecond precision.
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn from_now_with_u24_days_ps_submillis_prec() -> Result<Self, StdTimestampError> {
let conversion_from_now = ConversionFromNow::new_with_submillis_ps_prec()?;
Self::generic_from_now(LengthOfDaySegment::Long24Bits, conversion_from_now)
}
fn from_bytes_24_bit_days(buf: &[u8]) -> Result<Self, TimestampError> {
let submillis_precision =
Self::generic_raw_read_checks(buf, LengthOfDaySegment::Long24Bits)?;
let mut temp_buf: [u8; 4] = [0; 4];
temp_buf[1..4].copy_from_slice(&buf[1..4]);
let cccsds_days: u32 = u32::from_be_bytes(temp_buf);
let ms_of_day: u32 = u32::from_be_bytes(buf[4..8].try_into().unwrap());
let mut provider = Self::new_with_u24_days(cccsds_days, ms_of_day)?;
match submillis_precision {
SubmillisPrecision::Microseconds(_) => {
provider.set_submillis_precision(SubmillisPrecision::Microseconds(
u16::from_be_bytes(buf[8..10].try_into().unwrap()),
))
}
SubmillisPrecision::Picoseconds(_) => provider.set_submillis_precision(
SubmillisPrecision::Picoseconds(u32::from_be_bytes(buf[8..12].try_into().unwrap())),
),
_ => (),
}
Ok(provider)
}
}
impl TimeProvider<DaysLen16Bits> {
/// Generate a new timestamp provider with the days field width set to 16 bits
pub fn new_with_u16_days(ccsds_days: u16, ms_of_day: u32) -> Self {
// This should never fail, type system ensures CCSDS can not be negative or too large
Self::generic_new(LengthOfDaySegment::Short16Bits, ccsds_days, ms_of_day).unwrap()
}
/// Generate a time stamp from the current time using the system clock.
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn from_now_with_u16_days() -> Result<Self, StdTimestampError> {
let conversion_from_now = ConversionFromNow::new()?;
Self::generic_from_now(LengthOfDaySegment::Short16Bits, conversion_from_now)
}
/// Like [Self::from_now_with_u16_days] but with microsecond sub-millisecond precision.
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn from_now_with_u16_days_and_us_prec() -> Result<Self, StdTimestampError> {
let conversion_from_now = ConversionFromNow::new_with_submillis_us_prec()?;
Self::generic_from_now(LengthOfDaySegment::Short16Bits, conversion_from_now)
}
/// Like [Self::from_now_with_u16_days] but with picosecond sub-millisecond precision.
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn from_now_with_u16_days_and_ps_prec() -> Result<Self, StdTimestampError> {
let conversion_from_now = ConversionFromNow::new_with_submillis_ps_prec()?;
Self::generic_from_now(LengthOfDaySegment::Short16Bits, conversion_from_now)
}
fn from_bytes_16_bit_days(buf: &[u8]) -> Result<Self, TimestampError> {
let submillis_precision =
Self::generic_raw_read_checks(buf, LengthOfDaySegment::Short16Bits)?;
let ccsds_days: u16 = u16::from_be_bytes(buf[1..3].try_into().unwrap());
let ms_of_day: u32 = u32::from_be_bytes(buf[3..7].try_into().unwrap());
let mut provider = Self::new_with_u16_days(ccsds_days, ms_of_day);
provider.pfield = buf[0];
match submillis_precision {
SubmillisPrecision::Microseconds(_) => provider.set_submillis_precision(
SubmillisPrecision::Microseconds(u16::from_be_bytes(buf[7..9].try_into().unwrap())),
),
SubmillisPrecision::Picoseconds(_) => provider.set_submillis_precision(
SubmillisPrecision::Picoseconds(u32::from_be_bytes(buf[7..11].try_into().unwrap())),
),
_ => (),
}
Ok(provider)
}
}
impl<ProvidesDaysLen: ProvidesDaysLength> CcsdsTimeProvider for TimeProvider<ProvidesDaysLen> {
fn len_as_bytes(&self) -> usize {
Self::calc_stamp_len(self.pfield)
}
fn p_field(&self) -> (usize, [u8; 2]) {
(1, [self.pfield, 0])
}
fn ccdsd_time_code(&self) -> CcsdsTimeCodes {
CcsdsTimeCodes::Cds
}
fn unix_seconds(&self) -> i64 {
self.unix_seconds
}
fn date_time(&self) -> Option<DateTime<Utc>> {
self.calc_date_time(self.ms_of_day % 1000)
}
}
impl TimeReader for TimeProvider<DaysLen16Bits> {
fn from_bytes(buf: &[u8]) -> Result<Self, TimestampError> {
Self::from_bytes_16_bit_days(buf)
}
}
impl TimeReader for TimeProvider<DaysLen24Bits> {
fn from_bytes(buf: &[u8]) -> Result<Self, TimestampError> {
Self::from_bytes_24_bit_days(buf)
}
}
impl TimeWriter for TimeProvider<DaysLen16Bits> {
fn write_to_bytes(&self, buf: &mut [u8]) -> Result<usize, TimestampError> {
self.length_check(buf, self.len_as_bytes())?;
buf[0] = self.pfield;
buf[1..3].copy_from_slice(self.ccsds_days.to_be_bytes().as_slice());
buf[3..7].copy_from_slice(self.ms_of_day.to_be_bytes().as_slice());
if let Some(submillis_prec) = self.submillis_precision {
match submillis_prec {
SubmillisPrecision::Microseconds(ms) => {
buf[7..9].copy_from_slice(ms.to_be_bytes().as_slice());
}
SubmillisPrecision::Picoseconds(ps) => {
buf[7..11].copy_from_slice(ps.to_be_bytes().as_slice());
}
_ => (),
}
}
Ok(self.len_as_bytes())
}
}
impl TimeWriter for TimeProvider<DaysLen24Bits> {
fn write_to_bytes(&self, buf: &mut [u8]) -> Result<usize, TimestampError> {
self.length_check(buf, self.len_as_bytes())?;
buf[0] = self.pfield;
let be_days = self.ccsds_days.to_be_bytes();
buf[1..4].copy_from_slice(&be_days[1..4]);
buf[4..8].copy_from_slice(self.ms_of_day.to_be_bytes().as_slice());
if let Some(submillis_prec) = self.submillis_precision {
match submillis_prec {
SubmillisPrecision::Microseconds(ms) => {
buf[8..10].copy_from_slice(ms.to_be_bytes().as_slice());
}
SubmillisPrecision::Picoseconds(ps) => {
buf[8..12].copy_from_slice(ps.to_be_bytes().as_slice());
}
_ => (),
}
}
Ok(self.len_as_bytes())
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::time::TimestampError::{ByteConversionError, InvalidTimeCode};
use crate::ByteConversionError::{FromSliceTooSmall, ToSliceTooSmall};
use chrono::{Datelike, Timelike};
#[cfg(feature = "serde")]
use postcard::{from_bytes, to_allocvec};
use std::format;
#[test]
fn test_time_stamp_zero_args() {
let time_stamper = TimeProvider::new_with_u16_days(0, 0);
assert_eq!(
time_stamper.unix_seconds(),
(DAYS_CCSDS_TO_UNIX * SECONDS_PER_DAY as i32) as i64
);
assert_eq!(time_stamper.submillis_precision(), None);
assert_eq!(time_stamper.ccdsd_time_code(), CcsdsTimeCodes::Cds);
assert_eq!(
time_stamper.p_field(),
(1, [(CcsdsTimeCodes::Cds as u8) << 4, 0])
);
let date_time = time_stamper.date_time().unwrap();
assert_eq!(date_time.year(), 1958);
assert_eq!(date_time.month(), 1);
assert_eq!(date_time.day(), 1);
assert_eq!(date_time.hour(), 0);
assert_eq!(date_time.minute(), 0);
assert_eq!(date_time.second(), 0);
}
#[test]
fn test_time_stamp_unix_epoch() {
let time_stamper = TimeProvider::new_with_u16_days((-DAYS_CCSDS_TO_UNIX) as u16, 0);
assert_eq!(time_stamper.unix_seconds(), 0);
assert_eq!(time_stamper.submillis_precision(), None);
let date_time = time_stamper.date_time().unwrap();
assert_eq!(date_time.year(), 1970);
assert_eq!(date_time.month(), 1);
assert_eq!(date_time.day(), 1);
assert_eq!(date_time.hour(), 0);
assert_eq!(date_time.minute(), 0);
assert_eq!(date_time.second(), 0);
}
#[test]
fn test_large_days_field_write() {
let time_stamper = TimeProvider::new_with_u24_days(0x108020, 0);
assert!(time_stamper.is_ok());
let time_stamper = time_stamper.unwrap();
assert_eq!(time_stamper.len_as_bytes(), 8);
let mut buf = [0; 16];
let written = time_stamper.write_to_bytes(&mut buf);
assert!(written.is_ok());
let written = written.unwrap();
assert_eq!(written, 8);
assert_eq!(buf[1], 0x10);
assert_eq!(buf[2], 0x80);
assert_eq!(buf[3], 0x20);
let ms = u32::from_be_bytes(buf[4..8].try_into().unwrap());
assert_eq!(ms, 0);
assert_eq!((buf[0] >> 2) & 0b1, 1);
}
#[test]
fn test_large_days_field_read() {
let time_stamper = TimeProvider::new_with_u24_days(0x108020, 0);
assert!(time_stamper.is_ok());
let time_stamper = time_stamper.unwrap();
let mut buf = [0; 16];
let written = time_stamper.write_to_bytes(&mut buf);
assert!(written.is_ok());
let provider = TimeProvider::<DaysLen24Bits>::from_bytes(&buf);
assert!(provider.is_ok());
let provider = provider.unwrap();
assert_eq!(provider.ccsds_days(), 0x108020);
assert_eq!(provider.ms_of_day(), 0);
}
#[test]
fn test_large_days_field_read_invalid_ctor() {
let time_stamper = TimeProvider::new_with_u24_days(0x108020, 0);
assert!(time_stamper.is_ok());
let time_stamper = time_stamper.unwrap();
let mut buf = [0; 16];
let written = time_stamper.write_to_bytes(&mut buf);
assert!(written.is_ok());
let faulty_ctor = TimeProvider::<DaysLen16Bits>::from_bytes(&buf);
assert!(faulty_ctor.is_err());
let error = faulty_ctor.unwrap_err();
if let TimestampError::CdsError(cds::CdsError::InvalidCtorForDaysOfLenInPreamble(
len_of_day,
)) = error
{
assert_eq!(len_of_day, LengthOfDaySegment::Long24Bits);
} else {
panic!("Wrong error type");
}
}
#[test]
fn test_write() {
let mut buf = [0; 16];
let time_stamper_0 = TimeProvider::new_with_u16_days(0, 0);
let mut res = time_stamper_0.write_to_bytes(&mut buf);
assert!(res.is_ok());
assert_eq!(buf[0], (CcsdsTimeCodes::Cds as u8) << 4);
assert_eq!(
u16::from_be_bytes(buf[1..3].try_into().expect("Byte conversion failed")),
0
);
assert_eq!(
u32::from_be_bytes(buf[3..7].try_into().expect("Byte conversion failed")),
0
);
let time_stamper_1 = TimeProvider::new_with_u16_days(u16::MAX - 1, u32::MAX - 1);
res = time_stamper_1.write_to_bytes(&mut buf);
assert!(res.is_ok());
assert_eq!(buf[0], (CcsdsTimeCodes::Cds as u8) << 4);
assert_eq!(
u16::from_be_bytes(buf[1..3].try_into().expect("Byte conversion failed")),
u16::MAX - 1
);
assert_eq!(
u32::from_be_bytes(buf[3..7].try_into().expect("Byte conversion failed")),
u32::MAX - 1
);
}
#[test]
fn test_faulty_write_buf_too_small() {
let mut buf = [0; 7];
let time_stamper = TimeProvider::new_with_u16_days(u16::MAX - 1, u32::MAX - 1);
for i in 0..6 {
let res = time_stamper.write_to_bytes(&mut buf[0..i]);
assert!(res.is_err());
match res.unwrap_err() {
ByteConversionError(ToSliceTooSmall(missmatch)) => {
assert_eq!(missmatch.found, i);
assert_eq!(missmatch.expected, 7);
}
_ => panic!(
"{}",
format!("Invalid error {:?} detected", res.unwrap_err())
),
}
}
}
#[test]
fn test_faulty_read_buf_too_small() {
let buf = [0; 7];
for i in 0..6 {
let res = TimeProvider::<DaysLen16Bits>::from_bytes(&buf[0..i]);
assert!(res.is_err());
let err = res.unwrap_err();
match err {
ByteConversionError(e) => match e {
FromSliceTooSmall(missmatch) => {
assert_eq!(missmatch.found, i);
assert_eq!(missmatch.expected, 7);
}
_ => panic!("{}", format!("Invalid error {:?} detected", e)),
},
_ => {
panic!("Unexpected error {:?}", err);
}
}
}
}
#[test]
fn test_faulty_invalid_pfield() {
let mut buf = [0; 16];
let time_stamper_0 = TimeProvider::new_with_u16_days(0, 0);
let res = time_stamper_0.write_to_bytes(&mut buf);
assert!(res.is_ok());
buf[0] = 0;
let res = TimeProvider::<DaysLen16Bits>::from_bytes(&buf);
assert!(res.is_err());
let err = res.unwrap_err();
match err {
InvalidTimeCode(code, raw) => {
assert_eq!(code, CcsdsTimeCodes::Cds);
assert_eq!(raw, 0);
}
_ => {}
}
}
#[test]
fn test_reading() {
let mut buf = [0; 16];
let time_stamper = TimeProvider::new_with_u16_days(u16::MAX - 1, u32::MAX - 1);
let res = time_stamper.write_to_bytes(&mut buf);
assert!(res.is_ok());
assert_eq!(buf[0], (CcsdsTimeCodes::Cds as u8) << 4);
assert_eq!(
u16::from_be_bytes(buf[1..3].try_into().expect("Byte conversion failed")),
u16::MAX - 1
);
assert_eq!(
u32::from_be_bytes(buf[3..7].try_into().expect("Byte conversion failed")),
u32::MAX - 1
);
let read_stamp: TimeProvider<DaysLen16Bits> =
TimeProvider::from_bytes(&buf).expect("Reading timestamp failed");
assert_eq!(read_stamp.ccsds_days(), u16::MAX - 1);
assert_eq!(read_stamp.ms_of_day(), u32::MAX - 1);
}
#[test]
fn test_time_now() {
let timestamp_now = TimeProvider::from_now_with_u16_days().unwrap();
let compare_stamp = Utc::now();
let dt = timestamp_now.date_time().unwrap();
if compare_stamp.year() > dt.year() {
assert_eq!(compare_stamp.year() - dt.year(), 1);
} else {
assert_eq!(dt.year(), compare_stamp.year());
}
generic_dt_property_equality_check(dt.month(), compare_stamp.month(), 1, 12);
assert_eq!(dt.day(), compare_stamp.day());
if compare_stamp.day() < dt.day() {
assert!(dt.day() >= 28);
assert_eq!(compare_stamp.day(), 1);
} else if compare_stamp.day() > dt.day() {
assert_eq!(compare_stamp.day() - dt.day(), 1);
} else {
assert_eq!(compare_stamp.day(), dt.day());
}
generic_dt_property_equality_check(dt.hour(), compare_stamp.hour(), 0, 23);
generic_dt_property_equality_check(dt.minute(), compare_stamp.minute(), 0, 59);
}
#[test]
fn test_submillis_precision_micros() {
let mut time_stamper = TimeProvider::new_with_u16_days(0, 0);
time_stamper.set_submillis_precision(SubmillisPrecision::Microseconds(500));
assert!(time_stamper.submillis_precision().is_some());
if let SubmillisPrecision::Microseconds(micros) =
time_stamper.submillis_precision().unwrap()
{
assert_eq!(micros, 500);
} else {
panic!("Submillis precision was not set properly");
}
let mut write_buf: [u8; 16] = [0; 16];
let written = time_stamper
.write_to_bytes(&mut write_buf)
.expect("Writing timestamp failed");
assert_eq!(written, 9);
let cross_check: u16 = 500;
assert_eq!(write_buf[7..9], cross_check.to_be_bytes());
}
#[test]
fn test_submillis_precision_picos() {
let mut time_stamper = TimeProvider::new_with_u16_days(0, 0);
time_stamper.set_submillis_precision(SubmillisPrecision::Picoseconds(5e8 as u32));
assert!(time_stamper.submillis_precision().is_some());
if let SubmillisPrecision::Picoseconds(ps) = time_stamper.submillis_precision().unwrap() {
assert_eq!(ps, 5e8 as u32);
} else {
panic!("Submillis precision was not set properly");
}
let mut write_buf: [u8; 16] = [0; 16];
let written = time_stamper
.write_to_bytes(&mut write_buf)
.expect("Writing timestamp failed");
assert_eq!(written, 11);
let cross_check: u32 = 5e8 as u32;
assert_eq!(write_buf[7..11], cross_check.to_be_bytes());
}
#[test]
fn read_stamp_with_ps_submillis_precision() {
let mut time_stamper = TimeProvider::new_with_u16_days(0, 0);
time_stamper.set_submillis_precision(SubmillisPrecision::Picoseconds(5e8 as u32));
let mut write_buf: [u8; 16] = [0; 16];
let written = time_stamper
.write_to_bytes(&mut write_buf)
.expect("Writing timestamp failed");
assert_eq!(written, 11);
let stamp_deserialized = TimeProvider::<DaysLen16Bits>::from_bytes(&write_buf);
assert!(stamp_deserialized.is_ok());
let stamp_deserialized = stamp_deserialized.unwrap();
assert_eq!(stamp_deserialized.len_as_bytes(), 11);
assert!(stamp_deserialized.submillis_precision().is_some());
let submillis_rec = stamp_deserialized.submillis_precision().unwrap();
if let SubmillisPrecision::Picoseconds(ps) = submillis_rec {
assert_eq!(ps, 5e8 as u32);
} else {
panic!("Wrong precision field detected");
}
}
#[test]
fn read_stamp_with_us_submillis_precision() {
let mut time_stamper = TimeProvider::new_with_u16_days(0, 0);
time_stamper.set_submillis_precision(SubmillisPrecision::Microseconds(500));
let mut write_buf: [u8; 16] = [0; 16];
let written = time_stamper
.write_to_bytes(&mut write_buf)
.expect("Writing timestamp failed");
assert_eq!(written, 9);
let stamp_deserialized = TimeProvider::<DaysLen16Bits>::from_bytes(&write_buf);
assert!(stamp_deserialized.is_ok());
let stamp_deserialized = stamp_deserialized.unwrap();
assert_eq!(stamp_deserialized.len_as_bytes(), 9);
assert!(stamp_deserialized.submillis_precision().is_some());
let submillis_rec = stamp_deserialized.submillis_precision().unwrap();
if let SubmillisPrecision::Microseconds(us) = submillis_rec {
assert_eq!(us, 500);
} else {
panic!("Wrong precision field detected");
}
}
#[test]
#[cfg(feature = "serde")]
fn test_serialization() {
let stamp_now = TimeProvider::from_now_with_u16_days().expect("Error retrieving time");
let val = to_allocvec(&stamp_now).expect("Serializing timestamp failed");
assert!(val.len() > 0);
let stamp_deser: TimeProvider = from_bytes(&val).expect("Stamp deserialization failed");
assert_eq!(stamp_deser, stamp_now);
}
fn generic_dt_property_equality_check(first: u32, second: u32, start: u32, end: u32) {
if second < first {
assert_eq!(second, start);
assert_eq!(first, end);
} else if second > first {
assert_eq!(second - first, 1);
} else {
assert_eq!(first, second);
}
}
}

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src/time/cuc.rs Normal file
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@ -0,0 +1,950 @@
//! Module to generate or read CCSDS Unsegmented (CUC) timestamps as specified in
//! [CCSDS 301.0-B-4](https://public.ccsds.org/Pubs/301x0b4e1.pdf) section 3.2 .
//!
//! The core data structure to do this is the [TimeProviderCcsdsEpoch] struct.
use super::*;
use core::fmt::Debug;
const MIN_CUC_LEN: usize = 2;
/// Base value for the preamble field for a time field parser to determine the time field type.
pub const P_FIELD_BASE: u8 = (CcsdsTimeCodes::CucCcsdsEpoch as u8) << 4;
/// Maximum length if the preamble field is not extended.
pub const MAX_CUC_LEN_SMALL_PREAMBLE: usize = 8;
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum FractionalResolution {
/// No fractional part, only second resolution
Seconds = 0,
/// 256 fractional parts, resulting in 1/255 ~= 4 ms fractional resolution
FourMs = 1,
/// 65535 fractional parts, resulting in 1/65535 ~= 15 us fractional resolution
FifteenUs = 2,
/// 16777215 fractional parts, resulting in 1/16777215 ~= 60 ns fractional resolution
SixtyNs = 3,
}
impl TryFrom<u8> for FractionalResolution {
type Error = ();
fn try_from(v: u8) -> Result<Self, Self::Error> {
match v {
0 => Ok(FractionalResolution::Seconds),
1 => Ok(FractionalResolution::FourMs),
2 => Ok(FractionalResolution::FifteenUs),
3 => Ok(FractionalResolution::SixtyNs),
_ => Err(()),
}
}
}
/// Please note that this function will panic if the fractional value is not smaller than
/// the maximum number of fractions allowed for the particular resolution.
/// (e.g. passing 270 when the resolution only allows 255 values).
pub fn convert_fractional_part_to_ns(fractional_part: FractionalPart) -> u64 {
let div = fractional_res_to_div(fractional_part.0);
assert!(fractional_part.1 < div);
10_u64.pow(9) * fractional_part.1 as u64 / div as u64
}
pub const fn fractional_res_to_div(res: FractionalResolution) -> u32 {
2_u32.pow(8 * res as u32) - 1
}
/// Calculate the fractional part for a given resolution and subsecond nanoseconds.
/// Please note that this function will panic if the passed nanoseconds exceeds 1 second
/// as a nanosecond (10 to the power of 9). Furthermore, it will return [None] if the
/// given resolution is [FractionalResolution::Seconds].
pub fn fractional_part_from_subsec_ns(
res: FractionalResolution,
ns: u64,
) -> Option<FractionalPart> {
if res == FractionalResolution::Seconds {
return None;
}
let sec_as_ns = 10_u64.pow(9);
if ns > sec_as_ns {
panic!("passed nanosecond value larger than 1 second");
}
let resolution = fractional_res_to_div(res) as u64;
// Use integer division because this can reduce code size of really small systems.
// First determine the nanoseconds for the smallest segment given the resolution.
// Then divide by that to find out the fractional part. For the calculation of the smallest
// fraction, we perform a ceiling division. This is because if we would use the default
// flooring division, we would divide by a smaller value, thereby allowing the calculation to
// invalid fractional parts which are too large. For the division of the nanoseconds by the
// smallest fraction, a flooring division is correct.
// The multiplication with 100000 is necessary to avoid precision loss during integer division.
// TODO: Floating point division might actually be faster option, but requires additional
// code on small embedded systems..
let fractional_part = ns * 100000 / ((sec_as_ns * 100000 + resolution) / resolution);
// Floating point division.
//let fractional_part = (ns as f64 / ((sec_as_ns as f64) / resolution as f64)).floor() as u32;
Some(FractionalPart(res, fractional_part as u32))
}
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum CucError {
InvalidCounterWidth(u8),
InvalidFractionResolution(FractionalResolution),
InvalidCounter(u8, u64),
InvalidFractions(FractionalResolution, u64),
}
impl Display for CucError {
fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result {
match self {
CucError::InvalidCounterWidth(w) => {
write!(f, "invalid cuc counter byte width {}", w)
}
CucError::InvalidFractionResolution(w) => {
write!(f, "invalid cuc fractional part byte width {:?}", w)
}
CucError::InvalidCounter(w, c) => {
write!(f, "invalid cuc counter {} for width {}", c, w)
}
CucError::InvalidFractions(w, c) => {
write!(f, "invalid cuc fractional part {} for width {:?}", c, w)
}
}
}
}
#[cfg(feature = "std")]
impl Error for CucError {}
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct WidthCounterPair(u8, u32);
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct FractionalPart(FractionalResolution, u32);
/// This object is the abstraction for the CCSDS Unsegmented Time Code (CUC) using the CCSDS epoch
/// and a small preamble field.
///
/// It has the capability to generate and read timestamps as specified in the CCSDS 301.0-B-4
/// section 3.2 . The preamble field only has one byte, which allows a time code representation
/// through the year 2094. The time is represented as a simple binary counter starting from the
/// fixed CCSDS epoch (1958-01-01 00:00:00). It is possible to provide subsecond accuracy using the
/// fractional field with various available [resolutions][FractionalResolution].
///
/// Having a preamble field of one byte limits the width of the counter
/// type (generally seconds) to 4 bytes and the width of the fractions type to 3 bytes. This limits
/// the maximum time stamp size to [MAX_CUC_LEN_SMALL_PREAMBLE] (8 bytes).
///
/// # Example
///
/// ```
/// use spacepackets::time::cuc::{FractionalResolution, TimeProviderCcsdsEpoch};
/// use spacepackets::time::{TimeWriter, CcsdsTimeCodes, TimeReader, CcsdsTimeProvider};
///
/// // Highest fractional resolution
/// let timestamp_now = TimeProviderCcsdsEpoch::from_now(FractionalResolution::SixtyNs).expect("creating cuc stamp failed");
/// let mut raw_stamp = [0; 16];
/// {
/// let written = timestamp_now.write_to_bytes(&mut raw_stamp).expect("writing timestamp failed");
/// assert_eq!((raw_stamp[0] >> 4) & 0b111, CcsdsTimeCodes::CucCcsdsEpoch as u8);
/// // 1 byte preamble + 4 byte counter + 3 byte fractional part
/// assert_eq!(written, 8);
/// }
/// {
/// let read_result = TimeProviderCcsdsEpoch::from_bytes(&raw_stamp);
/// assert!(read_result.is_ok());
/// let stamp_deserialized = read_result.unwrap();
/// assert_eq!(stamp_deserialized, timestamp_now);
/// }
/// ```
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct TimeProviderCcsdsEpoch {
pfield: u8,
counter: WidthCounterPair,
fractions: Option<FractionalPart>,
}
#[inline]
pub fn pfield_len(pfield: u8) -> usize {
if ((pfield >> 7) & 0b1) == 1 {
return 2;
}
1
}
impl TimeProviderCcsdsEpoch {
/// Create a time provider with a four byte counter and no fractional part.
pub fn new(counter: u32) -> Self {
// These values are definitely valid, so it is okay to unwrap here.
Self::new_generic(WidthCounterPair(4, counter), None).unwrap()
}
/// Like [TimeProviderCcsdsEpoch::new] but allow to supply a fractional part as well.
pub fn new_with_fractions(counter: u32, fractions: FractionalPart) -> Result<Self, CucError> {
Self::new_generic(WidthCounterPair(4, counter), Some(fractions))
}
/// Fractions with a resolution of ~ 4 ms
pub fn new_with_coarse_fractions(counter: u32, subsec_fractions: u8) -> Self {
// These values are definitely valid, so it is okay to unwrap here.
Self::new_generic(
WidthCounterPair(4, counter),
Some(FractionalPart(
FractionalResolution::FourMs,
subsec_fractions as u32,
)),
)
.unwrap()
}
/// Fractions with a resolution of ~ 16 us
pub fn new_with_medium_fractions(counter: u32, subsec_fractions: u16) -> Self {
// These values are definitely valid, so it is okay to unwrap here.
Self::new_generic(
WidthCounterPair(4, counter),
Some(FractionalPart(
FractionalResolution::FifteenUs,
subsec_fractions as u32,
)),
)
.unwrap()
}
/// Fractions with a resolution of ~ 60 ns. The fractional part value is limited by the
/// 24 bits of the fractional field, so this function will fail with
/// [CucError::InvalidFractions] if the fractional value exceeds the value.
pub fn new_with_fine_fractions(counter: u32, subsec_fractions: u32) -> Result<Self, CucError> {
Self::new_generic(
WidthCounterPair(4, counter),
Some(FractionalPart(
FractionalResolution::SixtyNs,
subsec_fractions,
)),
)
}
/// This function will return the current time as a CUC timestamp.
/// The counter width will always be set to 4 bytes because the normal CCSDS epoch will overflow
/// when using less than that.
#[cfg(feature = "std")]
pub fn from_now(fraction_resolution: FractionalResolution) -> Result<Self, StdTimestampError> {
let now = SystemTime::now().duration_since(SystemTime::UNIX_EPOCH)?;
let ccsds_epoch = unix_epoch_to_ccsds_epoch(now.as_secs());
if fraction_resolution == FractionalResolution::Seconds {
return Ok(Self::new(ccsds_epoch as u32));
}
let fractions =
fractional_part_from_subsec_ns(fraction_resolution, now.subsec_nanos() as u64);
Self::new_with_fractions(ccsds_epoch as u32, fractions.unwrap())
.map_err(|e| StdTimestampError::TimestampError(e.into()))
}
/// Updates the current time stamp from the current time. The fractional field width remains
/// the same and will be updated accordingly.
#[cfg(feature = "std")]
pub fn update_from_now(&mut self) -> Result<(), StdTimestampError> {
let now = SystemTime::now().duration_since(SystemTime::UNIX_EPOCH)?;
self.counter.1 = unix_epoch_to_ccsds_epoch(now.as_secs()) as u32;
if self.fractions.is_some() {
self.fractions = fractional_part_from_subsec_ns(
self.fractions.unwrap().0,
now.subsec_nanos() as u64,
);
}
Ok(())
}
pub fn new_u16_counter(counter: u16) -> Self {
// These values are definitely valid, so it is okay to unwrap here.
Self::new_generic(WidthCounterPair(2, counter as u32), None).unwrap()
}
pub fn width_counter_pair(&self) -> WidthCounterPair {
self.counter
}
pub fn width_fractions_pair(&self) -> Option<FractionalPart> {
self.fractions
}
pub fn set_fractions(&mut self, fractions: FractionalPart) -> Result<(), CucError> {
Self::verify_fractions_width(fractions.0)?;
Self::verify_fractions_value(fractions)?;
self.fractions = Some(fractions);
self.update_p_field_fractions();
Ok(())
}
/// Set a fractional resolution. Please note that this function will reset the fractional value
/// to 0 if the resolution changes.
pub fn set_fractional_resolution(&mut self, res: FractionalResolution) {
if res == FractionalResolution::Seconds {
self.fractions = None;
}
let mut update_fractions = true;
if let Some(existing_fractions) = self.fractions {
if existing_fractions.0 == res {
update_fractions = false;
}
};
if update_fractions {
self.fractions = Some(FractionalPart(res, 0));
}
}
pub fn new_generic(
counter: WidthCounterPair,
fractions: Option<FractionalPart>,
) -> Result<Self, CucError> {
Self::verify_counter_width(counter.0)?;
if counter.1 > (2u64.pow(counter.0 as u32 * 8) - 1) as u32 {
return Err(CucError::InvalidCounter(counter.0, counter.1 as u64));
}
if let Some(fractions) = fractions {
Self::verify_fractions_width(fractions.0)?;
Self::verify_fractions_value(fractions)?;
}
Ok(Self {
pfield: Self::build_p_field(counter.0, fractions.map(|v| v.0)),
counter,
fractions,
})
}
fn build_p_field(counter_width: u8, fractions_width: Option<FractionalResolution>) -> u8 {
let mut pfield = P_FIELD_BASE;
if !(1..=4).contains(&counter_width) {
// Okay to panic here, this function is private and all input values should
// have been sanitized
panic!("invalid counter width {} for cuc timestamp", counter_width);
}
pfield |= (counter_width - 1) << 2;
if let Some(fractions_width) = fractions_width {
if !(1..=3).contains(&(fractions_width as u8)) {
// Okay to panic here, this function is private and all input values should
// have been sanitized
panic!(
"invalid fractions width {:?} for cuc timestamp",
fractions_width
);
}
pfield |= fractions_width as u8;
}
pfield
}
fn update_p_field_fractions(&mut self) {
self.pfield &= !(0b11);
if let Some(fractions) = self.fractions {
self.pfield |= fractions.0 as u8;
}
}
#[inline]
pub fn len_cntr_from_pfield(pfield: u8) -> u8 {
((pfield >> 2) & 0b11) + 1
}
#[inline]
pub fn len_fractions_from_pfield(pfield: u8) -> u8 {
pfield & 0b11
}
/// This returns the length of the individual components of the CUC timestamp in addition
/// to the total size.
///
/// This function will return a tuple where the first value is the byte width of the
/// counter, the second value is the byte width of the fractional part, and the third
/// components is the total size.
pub fn len_components_and_total_from_pfield(pfield: u8) -> (u8, u8, usize) {
let base_len: usize = 1;
let cntr_len = Self::len_cntr_from_pfield(pfield);
let fractions_len = Self::len_fractions_from_pfield(pfield);
(
cntr_len,
fractions_len,
base_len + cntr_len as usize + fractions_len as usize,
)
}
pub fn len_packed_from_pfield(pfield: u8) -> usize {
let mut base_len: usize = 1;
base_len += Self::len_cntr_from_pfield(pfield) as usize;
base_len += Self::len_fractions_from_pfield(pfield) as usize;
base_len
}
/// Verifies the raw width parameter.
fn verify_counter_width(width: u8) -> Result<(), CucError> {
if width == 0 || width > 4 {
return Err(CucError::InvalidCounterWidth(width));
}
Ok(())
}
fn verify_fractions_width(width: FractionalResolution) -> Result<(), CucError> {
if width as u8 > 3 {
return Err(CucError::InvalidFractionResolution(width));
}
Ok(())
}
fn verify_fractions_value(val: FractionalPart) -> Result<(), CucError> {
if val.1 > 2u32.pow((val.0 as u32) * 8) - 1 {
return Err(CucError::InvalidFractions(val.0, val.1 as u64));
}
Ok(())
}
}
impl TimeReader for TimeProviderCcsdsEpoch {
fn from_bytes(buf: &[u8]) -> Result<Self, TimestampError>
where
Self: Sized,
{
if buf.len() < MIN_CUC_LEN {
return Err(TimestampError::ByteConversionError(
ByteConversionError::FromSliceTooSmall(SizeMissmatch {
expected: MIN_CUC_LEN,
found: buf.len(),
}),
));
}
match ccsds_time_code_from_p_field(buf[0]) {
Ok(code) => {
if code != CcsdsTimeCodes::CucCcsdsEpoch {
return Err(TimestampError::InvalidTimeCode(
CcsdsTimeCodes::CucCcsdsEpoch,
code as u8,
));
}
}
Err(raw) => {
return Err(TimestampError::InvalidTimeCode(
CcsdsTimeCodes::CucCcsdsEpoch,
raw,
))
}
}
let (cntr_len, fractions_len, total_len) =
Self::len_components_and_total_from_pfield(buf[0]);
if buf.len() < total_len {
return Err(TimestampError::ByteConversionError(
ByteConversionError::FromSliceTooSmall(SizeMissmatch {
expected: total_len,
found: buf.len(),
}),
));
}
let mut current_idx = 1;
let counter = match cntr_len {
1 => buf[current_idx] as u32,
2 => u16::from_be_bytes(buf[current_idx..current_idx + 2].try_into().unwrap()) as u32,
3 => {
let mut tmp_buf: [u8; 4] = [0; 4];
tmp_buf[1..4].copy_from_slice(&buf[current_idx..current_idx + 3]);
u32::from_be_bytes(tmp_buf)
}
4 => u32::from_be_bytes(buf[current_idx..current_idx + 4].try_into().unwrap()),
_ => panic!("unreachable match arm"),
};
current_idx += cntr_len as usize;
let mut fractions = None;
if fractions_len > 0 {
match fractions_len {
1 => {
fractions = Some(FractionalPart(
fractions_len.try_into().unwrap(),
buf[current_idx] as u32,
))
}
2 => {
fractions = Some(FractionalPart(
fractions_len.try_into().unwrap(),
u16::from_be_bytes(buf[current_idx..current_idx + 2].try_into().unwrap())
as u32,
))
}
3 => {
let mut tmp_buf: [u8; 4] = [0; 4];
tmp_buf[1..4].copy_from_slice(&buf[current_idx..current_idx + 3]);
fractions = Some(FractionalPart(
fractions_len.try_into().unwrap(),
u32::from_be_bytes(tmp_buf),
))
}
_ => panic!("unreachable match arm"),
}
}
let provider = Self::new_generic(WidthCounterPair(cntr_len, counter), fractions)?;
Ok(provider)
}
}
impl TimeWriter for TimeProviderCcsdsEpoch {
fn write_to_bytes(&self, bytes: &mut [u8]) -> Result<usize, TimestampError> {
// Cross check the sizes of the counters against byte widths in the ctor
if bytes.len() < self.len_as_bytes() {
return Err(TimestampError::ByteConversionError(
ByteConversionError::ToSliceTooSmall(SizeMissmatch {
found: bytes.len(),
expected: self.len_as_bytes(),
}),
));
}
bytes[0] = self.pfield;
let mut current_idx: usize = 1;
match self.counter.0 {
1 => {
bytes[current_idx] = self.counter.1 as u8;
}
2 => {
bytes[current_idx..current_idx + 2]
.copy_from_slice(&(self.counter.1 as u16).to_be_bytes());
}
3 => {
bytes[current_idx..current_idx + 3]
.copy_from_slice(&self.counter.1.to_be_bytes()[1..4]);
}
4 => {
bytes[current_idx..current_idx + 4].copy_from_slice(&self.counter.1.to_be_bytes());
}
// Should never happen
_ => panic!("invalid counter width value"),
}
current_idx += self.counter.0 as usize;
if let Some(fractions) = self.fractions {
match fractions.0 {
FractionalResolution::FourMs => bytes[current_idx] = fractions.1 as u8,
FractionalResolution::FifteenUs => bytes[current_idx..current_idx + 2]
.copy_from_slice(&(fractions.1 as u16).to_be_bytes()),
FractionalResolution::SixtyNs => bytes[current_idx..current_idx + 3]
.copy_from_slice(&fractions.1.to_be_bytes()[1..4]),
// Should also never happen
_ => panic!("invalid fractions value"),
}
current_idx += fractions.0 as usize;
}
Ok(current_idx)
}
}
impl CcsdsTimeProvider for TimeProviderCcsdsEpoch {
fn len_as_bytes(&self) -> usize {
Self::len_packed_from_pfield(self.pfield)
}
fn p_field(&self) -> (usize, [u8; 2]) {
(1, [self.pfield, 0])
}
fn ccdsd_time_code(&self) -> CcsdsTimeCodes {
CcsdsTimeCodes::CucCcsdsEpoch
}
/// Please note that this function only works as intended if the time counter resolution
/// is one second.
fn unix_seconds(&self) -> i64 {
ccsds_epoch_to_unix_epoch(self.counter.1 as u64) as i64
}
fn date_time(&self) -> Option<DateTime<Utc>> {
let unix_seconds = self.unix_seconds();
let ns = if let Some(fractional_part) = self.fractions {
convert_fractional_part_to_ns(fractional_part)
} else {
0
};
if let LocalResult::Single(res) = Utc.timestamp_opt(unix_seconds, ns as u32) {
return Some(res);
}
None
}
}
#[cfg(test)]
mod tests {
use super::*;
use chrono::{Datelike, Timelike};
#[allow(unused_imports)]
use std::println;
#[test]
fn test_basic_zero_epoch() {
let zero_cuc = TimeProviderCcsdsEpoch::new(0);
assert_eq!(zero_cuc.len_as_bytes(), 5);
assert_eq!(zero_cuc.ccdsd_time_code(), CcsdsTimeCodes::CucCcsdsEpoch);
let counter = zero_cuc.width_counter_pair();
assert_eq!(counter.0, 4);
assert_eq!(counter.1, 0);
let fractions = zero_cuc.width_fractions_pair();
assert!(fractions.is_none());
let dt = zero_cuc.date_time();
assert!(dt.is_some());
let dt = dt.unwrap();
assert_eq!(dt.year(), 1958);
assert_eq!(dt.month(), 1);
assert_eq!(dt.day(), 1);
assert_eq!(dt.hour(), 0);
assert_eq!(dt.minute(), 0);
assert_eq!(dt.second(), 0);
}
#[test]
fn test_write_no_fractions() {
let mut buf: [u8; 16] = [0; 16];
let zero_cuc = TimeProviderCcsdsEpoch::new_generic(WidthCounterPair(4, 0x20102030), None);
assert!(zero_cuc.is_ok());
let zero_cuc = zero_cuc.unwrap();
let res = zero_cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
assert_eq!(zero_cuc.len_as_bytes(), 5);
assert_eq!(pfield_len(buf[0]), 1);
let written = res.unwrap();
assert_eq!(written, 5);
assert_eq!((buf[0] >> 7) & 0b1, 0);
let time_code = ccsds_time_code_from_p_field(buf[0]);
assert!(time_code.is_ok());
assert_eq!(time_code.unwrap(), CcsdsTimeCodes::CucCcsdsEpoch);
assert_eq!((buf[0] >> 2) & 0b11, 0b11);
assert_eq!(buf[0] & 0b11, 0);
let raw_counter = u32::from_be_bytes(buf[1..5].try_into().unwrap());
assert_eq!(raw_counter, 0x20102030);
assert_eq!(buf[5], 0);
}
#[test]
fn test_datetime_now() {
let now = Utc::now();
let cuc_now = TimeProviderCcsdsEpoch::from_now(FractionalResolution::SixtyNs);
assert!(cuc_now.is_ok());
let cuc_now = cuc_now.unwrap();
let dt_opt = cuc_now.date_time();
assert!(dt_opt.is_some());
let dt = dt_opt.unwrap();
let diff = dt - now;
assert!(diff.num_milliseconds() < 1000);
println!("datetime from cuc: {}", dt);
println!("datetime now: {}", now);
}
#[test]
fn test_read_no_fractions() {
let mut buf: [u8; 16] = [0; 16];
let zero_cuc =
TimeProviderCcsdsEpoch::new_generic(WidthCounterPair(4, 0x20102030), None).unwrap();
zero_cuc.write_to_bytes(&mut buf).unwrap();
let cuc_read_back =
TimeProviderCcsdsEpoch::from_bytes(&buf).expect("reading cuc timestamp failed");
assert_eq!(cuc_read_back, zero_cuc);
assert_eq!(cuc_read_back.width_counter_pair().1, 0x20102030);
assert_eq!(cuc_read_back.width_fractions_pair(), None);
}
#[test]
fn invalid_read_len() {
let mut buf: [u8; 16] = [0; 16];
for i in 0..2 {
let res = TimeProviderCcsdsEpoch::from_bytes(&buf[0..i]);
assert!(res.is_err());
let err = res.unwrap_err();
if let TimestampError::ByteConversionError(ByteConversionError::FromSliceTooSmall(e)) =
err
{
assert_eq!(e.found, i);
assert_eq!(e.expected, 2);
}
}
let large_stamp = TimeProviderCcsdsEpoch::new_with_fine_fractions(22, 300).unwrap();
large_stamp.write_to_bytes(&mut buf).unwrap();
for i in 2..large_stamp.len_as_bytes() - 1 {
let res = TimeProviderCcsdsEpoch::from_bytes(&buf[0..i]);
assert!(res.is_err());
let err = res.unwrap_err();
if let TimestampError::ByteConversionError(ByteConversionError::FromSliceTooSmall(e)) =
err
{
assert_eq!(e.found, i);
assert_eq!(e.expected, large_stamp.len_as_bytes());
}
}
}
#[test]
fn write_and_read_tiny_stamp() {
let mut buf = [0; 2];
let cuc = TimeProviderCcsdsEpoch::new_generic(WidthCounterPair(1, 200), None);
assert!(cuc.is_ok());
let cuc = cuc.unwrap();
assert_eq!(cuc.len_as_bytes(), 2);
let res = cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
let written = res.unwrap();
assert_eq!(written, 2);
assert_eq!(buf[1], 200);
let cuc_read_back = TimeProviderCcsdsEpoch::from_bytes(&buf);
assert!(cuc_read_back.is_ok());
let cuc_read_back = cuc_read_back.unwrap();
assert_eq!(cuc_read_back, cuc);
}
#[test]
fn write_slightly_larger_stamp() {
let mut buf = [0; 4];
let cuc = TimeProviderCcsdsEpoch::new_generic(WidthCounterPair(2, 40000), None);
assert!(cuc.is_ok());
let cuc = cuc.unwrap();
assert_eq!(cuc.len_as_bytes(), 3);
let res = cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
let written = res.unwrap();
assert_eq!(written, 3);
assert_eq!(u16::from_be_bytes(buf[1..3].try_into().unwrap()), 40000);
let cuc_read_back = TimeProviderCcsdsEpoch::from_bytes(&buf);
assert!(cuc_read_back.is_ok());
let cuc_read_back = cuc_read_back.unwrap();
assert_eq!(cuc_read_back, cuc);
}
#[test]
fn invalid_buf_len_for_read() {}
#[test]
fn write_read_three_byte_cntr_stamp() {
let mut buf = [0; 4];
let cuc = TimeProviderCcsdsEpoch::new_generic(WidthCounterPair(3, 2_u32.pow(24) - 2), None);
assert!(cuc.is_ok());
let cuc = cuc.unwrap();
assert_eq!(cuc.len_as_bytes(), 4);
let res = cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
let written = res.unwrap();
assert_eq!(written, 4);
let mut temp_buf = [0; 4];
temp_buf[1..4].copy_from_slice(&buf[1..4]);
assert_eq!(u32::from_be_bytes(temp_buf), 2_u32.pow(24) - 2);
let cuc_read_back = TimeProviderCcsdsEpoch::from_bytes(&buf);
assert!(cuc_read_back.is_ok());
let cuc_read_back = cuc_read_back.unwrap();
assert_eq!(cuc_read_back, cuc);
}
#[test]
fn test_write_invalid_buf() {
let mut buf: [u8; 16] = [0; 16];
let res = TimeProviderCcsdsEpoch::new_with_fine_fractions(0, 0);
let cuc = res.unwrap();
for i in 0..cuc.len_as_bytes() - 1 {
let err = cuc.write_to_bytes(&mut buf[0..i]);
assert!(err.is_err());
let err = err.unwrap_err();
if let TimestampError::ByteConversionError(ByteConversionError::ToSliceTooSmall(e)) =
err
{
assert_eq!(e.expected, cuc.len_as_bytes());
assert_eq!(e.found, i);
} else {
panic!("unexpected error: {}", err);
}
}
}
#[test]
fn invalid_ccsds_stamp_type() {
let mut buf: [u8; 16] = [0; 16];
buf[0] |= (CcsdsTimeCodes::CucAgencyEpoch as u8) << 4;
let res = TimeProviderCcsdsEpoch::from_bytes(&buf);
assert!(res.is_err());
let err = res.unwrap_err();
if let TimestampError::InvalidTimeCode(code, raw) = err {
assert_eq!(code, CcsdsTimeCodes::CucCcsdsEpoch);
assert_eq!(raw, CcsdsTimeCodes::CucAgencyEpoch as u8);
} else {
panic!("unexpected error: {}", err);
}
}
#[test]
fn test_write_with_coarse_fractions() {
let mut buf: [u8; 16] = [0; 16];
let cuc = TimeProviderCcsdsEpoch::new_with_coarse_fractions(0x30201060, 120);
assert!(cuc.fractions.is_some());
assert_eq!(cuc.fractions.unwrap().1, 120);
assert_eq!(cuc.fractions.unwrap().0, FractionalResolution::FourMs);
let res = cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
let written = res.unwrap();
assert_eq!(written, 6);
assert_eq!(buf[5], 120);
assert_eq!(buf[6], 0);
assert_eq!(
u32::from_be_bytes(buf[1..5].try_into().unwrap()),
0x30201060
);
}
#[test]
fn test_read_with_coarse_fractions() {
let mut buf: [u8; 16] = [0; 16];
let cuc = TimeProviderCcsdsEpoch::new_with_coarse_fractions(0x30201060, 120);
let res = cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
let res = TimeProviderCcsdsEpoch::from_bytes(&buf);
assert!(res.is_ok());
let read_back = res.unwrap();
assert_eq!(read_back, cuc);
}
#[test]
fn test_write_with_medium_fractions() {
let mut buf: [u8; 16] = [0; 16];
let cuc = TimeProviderCcsdsEpoch::new_with_medium_fractions(0x30303030, 30000);
let res = cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
let written = res.unwrap();
assert_eq!(written, 7);
assert_eq!(u16::from_be_bytes(buf[5..7].try_into().unwrap()), 30000);
assert_eq!(buf[7], 0);
}
#[test]
fn test_read_with_medium_fractions() {
let mut buf: [u8; 16] = [0; 16];
let cuc = TimeProviderCcsdsEpoch::new_with_medium_fractions(0x30303030, 30000);
let res = cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
let res = TimeProviderCcsdsEpoch::from_bytes(&buf);
assert!(res.is_ok());
let cuc_read_back = res.unwrap();
assert_eq!(cuc_read_back, cuc);
}
#[test]
fn test_write_with_fine_fractions() {
let mut buf: [u8; 16] = [0; 16];
let cuc =
TimeProviderCcsdsEpoch::new_with_fine_fractions(0x30303030, u16::MAX as u32 + 60000);
assert!(cuc.is_ok());
let cuc = cuc.unwrap();
let res = cuc.write_to_bytes(&mut buf);
let written = res.unwrap();
assert_eq!(written, 8);
let mut dummy_buf: [u8; 4] = [0; 4];
dummy_buf[1..4].copy_from_slice(&buf[5..8]);
assert_eq!(u32::from_be_bytes(dummy_buf), u16::MAX as u32 + 60000);
assert_eq!(buf[8], 0);
}
#[test]
fn test_read_with_fine_fractions() {
let mut buf: [u8; 16] = [0; 16];
let cuc =
TimeProviderCcsdsEpoch::new_with_fine_fractions(0x30303030, u16::MAX as u32 + 60000);
assert!(cuc.is_ok());
let cuc = cuc.unwrap();
let res = cuc.write_to_bytes(&mut buf);
assert!(res.is_ok());
let res = TimeProviderCcsdsEpoch::from_bytes(&buf);
assert!(res.is_ok());
let cuc_read_back = res.unwrap();
assert_eq!(cuc_read_back, cuc);
}
#[test]
fn test_fractional_converter() {
let ns = convert_fractional_part_to_ns(FractionalPart(FractionalResolution::FourMs, 2));
// The formula for this is 2/255 * 10e9 = 7.843.137.
assert_eq!(ns, 7843137);
// This is the largest value we should be able to pass without this function panicking.
let ns = convert_fractional_part_to_ns(FractionalPart(
FractionalResolution::SixtyNs,
2_u32.pow(24) - 2,
));
assert_eq!(ns, 999999940);
}
#[test]
#[should_panic]
fn test_fractional_converter_invalid_input() {
convert_fractional_part_to_ns(FractionalPart(FractionalResolution::FourMs, 256));
}
#[test]
#[should_panic]
fn test_fractional_converter_invalid_input_2() {
convert_fractional_part_to_ns(FractionalPart(
FractionalResolution::SixtyNs,
2_u32.pow(32) - 1,
));
}
#[test]
fn fractional_part_formula() {
let fractional_part =
fractional_part_from_subsec_ns(FractionalResolution::FourMs, 7843138).unwrap();
assert_eq!(fractional_part.1, 2);
}
#[test]
fn fractional_part_formula_2() {
let fractional_part =
fractional_part_from_subsec_ns(FractionalResolution::FourMs, 12000000).unwrap();
assert_eq!(fractional_part.1, 3);
}
#[test]
fn fractional_part_formula_3() {
let one_fraction_with_width_two_in_ns =
10_u64.pow(9) as f64 / (2_u32.pow(8 * 2) - 1) as f64;
assert_eq!(one_fraction_with_width_two_in_ns.ceil(), 15260.0);
let hundred_fractions_and_some =
(100.0 * one_fraction_with_width_two_in_ns).floor() as u64 + 7000;
let fractional_part = fractional_part_from_subsec_ns(
FractionalResolution::FifteenUs,
hundred_fractions_and_some,
)
.unwrap();
assert_eq!(fractional_part.1, 100);
// Using exactly 101.0 can yield values which will later be rounded down to 100
let hundred_and_one_fractions =
(101.001 * one_fraction_with_width_two_in_ns).floor() as u64;
let fractional_part = fractional_part_from_subsec_ns(
FractionalResolution::FifteenUs,
hundred_and_one_fractions,
)
.unwrap();
assert_eq!(fractional_part.1, 101);
}
#[test]
fn update_fractions() {
let mut stamp = TimeProviderCcsdsEpoch::new(2000);
let res = stamp.set_fractions(FractionalPart(FractionalResolution::SixtyNs, 5000));
assert!(res.is_ok());
assert!(stamp.fractions.is_some());
let fractions = stamp.fractions.unwrap();
assert_eq!(fractions.0, FractionalResolution::SixtyNs);
assert_eq!(fractions.1, 5000);
}
#[test]
fn set_fract_resolution() {
let mut stamp = TimeProviderCcsdsEpoch::new(2000);
stamp.set_fractional_resolution(FractionalResolution::SixtyNs);
assert!(stamp.fractions.is_some());
let fractions = stamp.fractions.unwrap();
assert_eq!(fractions.0, FractionalResolution::SixtyNs);
assert_eq!(fractions.1, 0);
let res = stamp.update_from_now();
assert!(res.is_ok());
}
#[test]
fn assert_largest_fractions() {
let fractions =
fractional_part_from_subsec_ns(FractionalResolution::SixtyNs, 10u64.pow(9) - 1)
.unwrap();
// The value can not be larger than representable by 3 bytes
// Assert that the maximum resolution can be reached
assert_eq!(fractions.1, 2_u32.pow(3 * 8) - 2);
}
}

243
src/time/mod.rs Normal file
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//! CCSDS Time Code Formats according to [CCSDS 301.0-B-4](https://public.ccsds.org/Pubs/301x0b4e1.pdf)
use crate::{ByteConversionError, SizeMissmatch};
use chrono::{DateTime, LocalResult, TimeZone, Utc};
use core::fmt::{Display, Formatter};
#[allow(unused_imports)]
#[cfg(not(feature = "std"))]
use num_traits::float::FloatCore;
#[cfg(feature = "serde")]
use serde::{Deserialize, Serialize};
#[cfg(feature = "std")]
use std::error::Error;
#[cfg(feature = "std")]
use std::time::{SystemTime, SystemTimeError};
pub mod ascii;
pub mod cds;
pub mod cuc;
pub const DAYS_CCSDS_TO_UNIX: i32 = -4383;
pub const SECONDS_PER_DAY: u32 = 86400;
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum CcsdsTimeCodes {
CucCcsdsEpoch = 0b001,
CucAgencyEpoch = 0b010,
Cds = 0b100,
Ccs = 0b101,
AgencyDefined = 0b110,
}
impl TryFrom<u8> for CcsdsTimeCodes {
type Error = ();
fn try_from(value: u8) -> Result<Self, Self::Error> {
match value {
x if x == CcsdsTimeCodes::CucCcsdsEpoch as u8 => Ok(CcsdsTimeCodes::CucCcsdsEpoch),
x if x == CcsdsTimeCodes::CucAgencyEpoch as u8 => Ok(CcsdsTimeCodes::CucAgencyEpoch),
x if x == CcsdsTimeCodes::Cds as u8 => Ok(CcsdsTimeCodes::Cds),
x if x == CcsdsTimeCodes::Ccs as u8 => Ok(CcsdsTimeCodes::Ccs),
x if x == CcsdsTimeCodes::AgencyDefined as u8 => Ok(CcsdsTimeCodes::AgencyDefined),
_ => Err(()),
}
}
}
/// Retrieve the CCSDS time code from the p-field. If no valid time code identifier is found, the
/// value of the raw time code identification field is returned.
pub fn ccsds_time_code_from_p_field(pfield: u8) -> Result<CcsdsTimeCodes, u8> {
let raw_bits = (pfield >> 4) & 0b111;
CcsdsTimeCodes::try_from(raw_bits).map_err(|_| raw_bits)
}
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub enum TimestampError {
/// Contains tuple where first value is the expected time code and the second
/// value is the found raw value
InvalidTimeCode(CcsdsTimeCodes, u8),
ByteConversionError(ByteConversionError),
CdsError(cds::CdsError),
CucError(cuc::CucError),
CustomEpochNotSupported,
}
impl From<cds::CdsError> for TimestampError {
fn from(e: cds::CdsError) -> Self {
TimestampError::CdsError(e)
}
}
impl From<cuc::CucError> for TimestampError {
fn from(e: cuc::CucError) -> Self {
TimestampError::CucError(e)
}
}
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
#[derive(Debug, Clone)]
pub enum StdTimestampError {
SystemTimeError(SystemTimeError),
TimestampError(TimestampError),
}
#[cfg(feature = "std")]
impl From<TimestampError> for StdTimestampError {
fn from(v: TimestampError) -> Self {
Self::TimestampError(v)
}
}
#[cfg(feature = "std")]
impl From<SystemTimeError> for StdTimestampError {
fn from(v: SystemTimeError) -> Self {
Self::SystemTimeError(v)
}
}
impl Display for TimestampError {
fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result {
match self {
TimestampError::InvalidTimeCode(time_code, raw_val) => {
write!(
f,
"invalid raw time code value {} for time code {:?}",
raw_val, time_code
)
}
TimestampError::CdsError(e) => {
write!(f, "cds error {}", e)
}
TimestampError::CucError(e) => {
write!(f, "cuc error {}", e)
}
TimestampError::ByteConversionError(e) => {
write!(f, "byte conversion error {}", e)
}
TimestampError::CustomEpochNotSupported => {
write!(f, "custom epochs are not supported")
}
}
}
}
#[cfg(feature = "std")]
impl Error for TimestampError {
fn source(&self) -> Option<&(dyn Error + 'static)> {
match self {
TimestampError::ByteConversionError(e) => Some(e),
TimestampError::CdsError(e) => Some(e),
TimestampError::CucError(e) => Some(e),
_ => None,
}
}
}
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn seconds_since_epoch() -> f64 {
SystemTime::now()
.duration_since(SystemTime::UNIX_EPOCH)
.expect("System time generation failed")
.as_secs_f64()
}
/// Convert UNIX days to CCSDS days
///
/// - CCSDS epoch: 1958 January 1
/// - UNIX Epoch: 1970 January 1
pub const fn unix_to_ccsds_days(unix_days: i64) -> i64 {
unix_days - DAYS_CCSDS_TO_UNIX as i64
}
/// Convert CCSDS days to UNIX days
///
/// - CCSDS epoch: 1958 January 1
/// - UNIX Epoch: 1970 January 1
pub const fn ccsds_to_unix_days(ccsds_days: i64) -> i64 {
ccsds_days + DAYS_CCSDS_TO_UNIX as i64
}
/// Similar to [unix_to_ccsds_days] but converts the epoch instead, which is the number of elpased
/// seconds since the CCSDS and UNIX epoch times.
pub const fn unix_epoch_to_ccsds_epoch(unix_epoch: u64) -> u64 {
(unix_epoch as i64 - (DAYS_CCSDS_TO_UNIX as i64 * SECONDS_PER_DAY as i64)) as u64
}
pub const fn ccsds_epoch_to_unix_epoch(ccsds_epoch: u64) -> u64 {
(ccsds_epoch as i64 + (DAYS_CCSDS_TO_UNIX as i64 * SECONDS_PER_DAY as i64)) as u64
}
#[cfg(feature = "std")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "std")))]
pub fn ms_of_day_using_sysclock() -> u32 {
ms_of_day(seconds_since_epoch())
}
pub fn ms_of_day(seconds_since_epoch: f64) -> u32 {
let fraction_ms = seconds_since_epoch - seconds_since_epoch.floor();
let ms_of_day: u32 = (((seconds_since_epoch.floor() as u32 % SECONDS_PER_DAY) * 1000) as f64
+ fraction_ms)
.floor() as u32;
ms_of_day
}
pub trait TimeWriter {
/// Generic function to convert write a timestamp into a raw buffer.
/// Returns the number of written bytes on success.
fn write_to_bytes(&self, bytes: &mut [u8]) -> Result<usize, TimestampError>;
}
pub trait TimeReader {
fn from_bytes(buf: &[u8]) -> Result<Self, TimestampError>
where
Self: Sized;
}
/// Trait for generic CCSDS time providers.
pub trait CcsdsTimeProvider {
fn len_as_bytes(&self) -> usize;
/// Returns the pfield of the time provider. The pfield can have one or two bytes depending
/// on the extension bit (first bit). The time provider should returns a tuple where the first
/// entry denotes the length of the pfield and the second entry is the value of the pfield
/// in big endian format.
fn p_field(&self) -> (usize, [u8; 2]);
fn ccdsd_time_code(&self) -> CcsdsTimeCodes;
fn unix_seconds(&self) -> i64;
fn date_time(&self) -> Option<DateTime<Utc>>;
}
#[cfg(all(test, feature = "std"))]
mod tests {
use super::*;
#[test]
fn test_days_conversion() {
assert_eq!(unix_to_ccsds_days(DAYS_CCSDS_TO_UNIX.into()), 0);
assert_eq!(ccsds_to_unix_days(0), DAYS_CCSDS_TO_UNIX.into());
}
#[test]
fn test_get_current_time() {
let sec_floats = seconds_since_epoch();
assert!(sec_floats > 0.0);
}
#[test]
fn test_ccsds_epoch() {
let now = SystemTime::now()
.duration_since(SystemTime::UNIX_EPOCH)
.unwrap();
let unix_epoch = now.as_secs();
let ccsds_epoch = unix_epoch_to_ccsds_epoch(now.as_secs());
assert!(ccsds_epoch > unix_epoch);
assert_eq!((ccsds_epoch - unix_epoch) % SECONDS_PER_DAY as u64, 0);
let days_diff = (ccsds_epoch - unix_epoch) / SECONDS_PER_DAY as u64;
assert_eq!(days_diff, -DAYS_CCSDS_TO_UNIX as u64);
}
}

136
src/tm.rs
View File

@ -5,9 +5,11 @@ use crate::ecss::{
verify_crc16_from_raw, CrcType, PusError, PusPacket, PusVersion, CRC_CCITT_FALSE,
};
use crate::{
CcsdsPacket, PacketError, PacketType, SequenceFlags, SizeMissmatch, SpHeader, CCSDS_HEADER_LEN,
ByteConversionError, CcsdsPacket, PacketType, SequenceFlags, SizeMissmatch, SpHeader,
CCSDS_HEADER_LEN,
};
use core::mem::size_of;
#[cfg(feature = "serde")]
use serde::{Deserialize, Serialize};
use zerocopy::AsBytes;
@ -20,7 +22,7 @@ pub const PUC_TM_MIN_SEC_HEADER_LEN: usize = 7;
pub const PUS_TM_MIN_LEN_WITHOUT_SOURCE_DATA: usize =
CCSDS_HEADER_LEN + PUC_TM_MIN_SEC_HEADER_LEN + size_of::<CrcType>();
pub trait PusTmSecondaryHeaderT {
pub trait GenericPusTmSecondaryHeader {
fn pus_version(&self) -> PusVersion;
fn sc_time_ref_status(&self) -> u8;
fn service(&self) -> u8;
@ -30,6 +32,7 @@ pub trait PusTmSecondaryHeaderT {
}
pub mod zc {
use super::GenericPusTmSecondaryHeader;
use crate::ecss::{PusError, PusVersion};
use zerocopy::{AsBytes, FromBytes, NetworkEndian, Unaligned, U16};
@ -66,7 +69,7 @@ pub mod zc {
}
impl PusTmSecHeaderWithoutTimestamp {
pub fn to_bytes(&self, slice: &mut [u8]) -> Option<()> {
pub fn write_to_bytes(&self, slice: &mut [u8]) -> Option<()> {
self.write_to(slice)
}
@ -75,7 +78,7 @@ pub mod zc {
}
}
impl super::PusTmSecondaryHeaderT for PusTmSecHeaderWithoutTimestamp {
impl GenericPusTmSecondaryHeader for PusTmSecHeaderWithoutTimestamp {
fn pus_version(&self) -> PusVersion {
PusVersion::try_from(self.pus_version_and_sc_time_ref_status >> 4 & 0b1111)
.unwrap_or(PusVersion::Invalid)
@ -103,19 +106,20 @@ pub mod zc {
}
}
#[derive(PartialEq, Eq, Serialize, Deserialize, Copy, Clone, Debug)]
pub struct PusTmSecondaryHeader<'slice> {
#[derive(PartialEq, Eq, Copy, Clone, Debug)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct PusTmSecondaryHeader<'stamp> {
pus_version: PusVersion,
pub sc_time_ref_status: u8,
pub service: u8,
pub subservice: u8,
pub msg_counter: u16,
pub dest_id: u16,
pub time_stamp: &'slice [u8],
pub time_stamp: &'stamp [u8],
}
impl<'slice> PusTmSecondaryHeader<'slice> {
pub fn new_simple(service: u8, subservice: u8, time_stamp: &'slice [u8]) -> Self {
impl<'stamp> PusTmSecondaryHeader<'stamp> {
pub fn new_simple(service: u8, subservice: u8, time_stamp: &'stamp [u8]) -> Self {
PusTmSecondaryHeader {
pus_version: PusVersion::PusC,
sc_time_ref_status: 0,
@ -132,7 +136,7 @@ impl<'slice> PusTmSecondaryHeader<'slice> {
subservice: u8,
msg_counter: u16,
dest_id: u16,
time_stamp: &'slice [u8],
time_stamp: &'stamp [u8],
) -> Self {
PusTmSecondaryHeader {
pus_version: PusVersion::PusC,
@ -146,7 +150,7 @@ impl<'slice> PusTmSecondaryHeader<'slice> {
}
}
impl PusTmSecondaryHeaderT for PusTmSecondaryHeader<'_> {
impl GenericPusTmSecondaryHeader for PusTmSecondaryHeader<'_> {
fn pus_version(&self) -> PusVersion {
self.pus_version
}
@ -192,25 +196,31 @@ impl<'slice> TryFrom<zc::PusTmSecHeader<'slice>> for PusTmSecondaryHeader<'slice
/// structure to generate the raw byte representation of PUS telemetry or to
/// deserialize from one from raw bytes.
///
/// This class also derives the [serde::Serialize] and [serde::Deserialize] trait which allows
/// to send around TM packets in a raw byte format using a serde provider like
/// [postcard](https://docs.rs/postcard/latest/postcard/).
/// This class also derives the [serde::Serialize] and [serde::Deserialize] trait if the [serde]
/// feature is used which allows to send around TM packets in a raw byte format using a serde
/// provider like [postcard](https://docs.rs/postcard/latest/postcard/).
///
/// There is no spare bytes support yet.
#[derive(PartialEq, Eq, Serialize, Deserialize, Debug, Copy, Clone)]
pub struct PusTm<'slice> {
///
/// # Lifetimes
///
/// * `'src_data` - Life time of a buffer where the user provided time stamp and source data will
/// be serialized into.
#[derive(PartialEq, Eq, Debug, Copy, Clone)]
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
pub struct PusTm<'src_data> {
pub sp_header: SpHeader,
pub sec_header: PusTmSecondaryHeader<'slice>,
pub sec_header: PusTmSecondaryHeader<'src_data>,
/// If this is set to false, a manual call to [PusTm::calc_own_crc16] or
/// [PusTm::update_packet_fields] is necessary for the serialized or cached CRC16 to be valid.
pub calc_crc_on_serialization: bool,
#[serde(skip)]
raw_data: Option<&'slice [u8]>,
source_data: Option<&'slice [u8]>,
#[cfg_attr(feature = "serde", serde(skip))]
raw_data: Option<&'src_data [u8]>,
source_data: Option<&'src_data [u8]>,
crc16: Option<u16>,
}
impl<'slice> PusTm<'slice> {
impl<'src_data> PusTm<'src_data> {
/// Generates a new struct instance.
///
/// # Arguments
@ -225,8 +235,8 @@ impl<'slice> PusTm<'slice> {
/// the correct value to this field manually
pub fn new(
sp_header: &mut SpHeader,
sec_header: PusTmSecondaryHeader<'slice>,
source_data: Option<&'slice [u8]>,
sec_header: PusTmSecondaryHeader<'src_data>,
source_data: Option<&'src_data [u8]>,
set_ccsds_len: bool,
) -> Self {
sp_header.set_packet_type(PacketType::Tm);
@ -254,10 +264,14 @@ impl<'slice> PusTm<'slice> {
length
}
pub fn time_stamp(&self) -> &'slice [u8] {
pub fn time_stamp(&self) -> &'src_data [u8] {
self.sec_header.time_stamp
}
pub fn source_data(&self) -> Option<&'src_data [u8]> {
self.source_data
}
pub fn set_dest_id(&mut self, dest_id: u16) {
self.sec_header.dest_id = dest_id;
}
@ -304,28 +318,24 @@ impl<'slice> PusTm<'slice> {
}
/// Write the raw PUS byte representation to a provided buffer.
pub fn write_to(&self, slice: &mut [u8]) -> Result<usize, PusError> {
pub fn write_to_bytes(&self, slice: &mut [u8]) -> Result<usize, PusError> {
let mut curr_idx = 0;
let sph_zc = crate::zc::SpHeader::from(self.sp_header);
let total_size = self.len_packed();
if total_size > slice.len() {
return Err(PusError::PacketError(PacketError::ToBytesSliceTooSmall(
SizeMissmatch {
found: slice.len(),
expected: total_size,
},
)));
return Err(ByteConversionError::ToSliceTooSmall(SizeMissmatch {
found: slice.len(),
expected: total_size,
})
.into());
}
sph_zc
.to_bytes(&mut slice[curr_idx..curr_idx + CCSDS_HEADER_LEN])
.ok_or(PusError::PacketError(PacketError::ToBytesZeroCopyError))?;
self.sp_header
.write_to_be_bytes(&mut slice[0..CCSDS_HEADER_LEN])?;
curr_idx += CCSDS_HEADER_LEN;
let sec_header_len = size_of::<zc::PusTmSecHeaderWithoutTimestamp>();
let sec_header = zc::PusTmSecHeaderWithoutTimestamp::try_from(self.sec_header).unwrap();
sec_header
.to_bytes(&mut slice[curr_idx..curr_idx + sec_header_len])
.ok_or(PusError::PacketError(PacketError::ToBytesZeroCopyError))?;
.write_to_bytes(&mut slice[curr_idx..curr_idx + sec_header_len])
.ok_or(ByteConversionError::ZeroCopyToError)?;
curr_idx += sec_header_len;
let timestamp_len = self.sec_header.time_stamp.len();
slice[curr_idx..curr_idx + timestamp_len].copy_from_slice(self.sec_header.time_stamp);
@ -348,6 +358,7 @@ impl<'slice> PusTm<'slice> {
/// Append the raw PUS byte representation to a provided [alloc::vec::Vec]
#[cfg(feature = "alloc")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
pub fn append_to_vec(&self, vec: &mut Vec<u8>) -> Result<usize, PusError> {
let sph_zc = crate::zc::SpHeader::from(self.sp_header);
let mut appended_len =
@ -383,8 +394,8 @@ impl<'slice> PusTm<'slice> {
/// Create a [PusTm] instance from a raw slice. On success, it returns a tuple containing
/// the instance and the found byte length of the packet. The timestamp length needs to be
/// known beforehand.
pub fn new_from_raw_slice(
slice: &'slice [u8],
pub fn from_bytes(
slice: &'src_data [u8],
timestamp_len: usize,
) -> Result<(Self, usize), PusError> {
let raw_data_len = slice.len();
@ -392,18 +403,16 @@ impl<'slice> PusTm<'slice> {
return Err(PusError::RawDataTooShort(raw_data_len));
}
let mut current_idx = 0;
let sph =
crate::zc::SpHeader::from_bytes(&slice[current_idx..current_idx + CCSDS_HEADER_LEN])
.ok_or(PusError::PacketError(PacketError::FromBytesZeroCopyError))?;
let (sp_header, _) = SpHeader::from_be_bytes(&slice[0..CCSDS_HEADER_LEN])?;
current_idx += 6;
let total_len = sph.total_len();
let total_len = sp_header.total_len();
if raw_data_len < total_len || total_len < PUS_TM_MIN_LEN_WITHOUT_SOURCE_DATA {
return Err(PusError::RawDataTooShort(raw_data_len));
}
let sec_header_zc = zc::PusTmSecHeaderWithoutTimestamp::from_bytes(
&slice[current_idx..current_idx + PUC_TM_MIN_SEC_HEADER_LEN],
)
.ok_or(PusError::PacketError(PacketError::FromBytesZeroCopyError))?;
.ok_or(ByteConversionError::ZeroCopyFromError)?;
current_idx += PUC_TM_MIN_SEC_HEADER_LEN;
let zc_sec_header_wrapper = zc::PusTmSecHeader {
zc_header: sec_header_zc,
@ -412,7 +421,7 @@ impl<'slice> PusTm<'slice> {
current_idx += timestamp_len;
let raw_data = &slice[0..total_len];
let pus_tm = PusTm {
sp_header: SpHeader::from(sph),
sp_header,
sec_header: PusTmSecondaryHeader::try_from(zc_sec_header_wrapper).unwrap(),
raw_data: Some(&slice[0..total_len]),
source_data: user_data_from_raw(current_idx, total_len, raw_data_len, slice)?,
@ -447,7 +456,7 @@ impl PusPacket for PusTm<'_> {
}
//noinspection RsTraitImplementation
impl PusTmSecondaryHeaderT for PusTm<'_> {
impl GenericPusTmSecondaryHeader for PusTm<'_> {
delegate!(to self.sec_header {
fn pus_version(&self) -> PusVersion;
fn service(&self) -> u8;
@ -465,13 +474,13 @@ mod tests {
use crate::SpHeader;
fn base_ping_reply_full_ctor(time_stamp: &[u8]) -> PusTm {
let mut sph = SpHeader::tm(0x123, 0x234, 0).unwrap();
let mut sph = SpHeader::tm_unseg(0x123, 0x234, 0).unwrap();
let tc_header = PusTmSecondaryHeader::new_simple(17, 2, &time_stamp);
PusTm::new(&mut sph, tc_header, None, true)
}
fn base_hk_reply<'a>(time_stamp: &'a [u8], src_data: &'a [u8]) -> PusTm<'a> {
let mut sph = SpHeader::tm(0x123, 0x234, 0).unwrap();
let mut sph = SpHeader::tm_unseg(0x123, 0x234, 0).unwrap();
let tc_header = PusTmSecondaryHeader::new_simple(3, 5, &time_stamp);
PusTm::new(&mut sph, tc_header, Some(src_data), true)
}
@ -492,7 +501,9 @@ mod tests {
let time_stamp = dummy_time_stamp();
let pus_tm = base_ping_reply_full_ctor(&time_stamp);
let mut buf: [u8; 32] = [0; 32];
let ser_len = pus_tm.write_to(&mut buf).expect("Serialization failed");
let ser_len = pus_tm
.write_to_bytes(&mut buf)
.expect("Serialization failed");
assert_eq!(ser_len, 22);
verify_raw_ping_reply(&buf);
}
@ -502,7 +513,9 @@ mod tests {
let src_data = [1, 2, 3];
let hk_reply = base_hk_reply(dummy_time_stamp(), &src_data);
let mut buf: [u8; 32] = [0; 32];
let ser_len = hk_reply.write_to(&mut buf).expect("Serialization failed");
let ser_len = hk_reply
.write_to_bytes(&mut buf)
.expect("Serialization failed");
assert_eq!(ser_len, 25);
assert_eq!(buf[20], 1);
assert_eq!(buf[21], 2);
@ -528,29 +541,30 @@ mod tests {
let time_stamp = dummy_time_stamp();
let pus_tm = base_ping_reply_full_ctor(&time_stamp);
let mut buf: [u8; 32] = [0; 32];
let ser_len = pus_tm.write_to(&mut buf).expect("Serialization failed");
let ser_len = pus_tm
.write_to_bytes(&mut buf)
.expect("Serialization failed");
assert_eq!(ser_len, 22);
let (tm_deserialized, size) =
PusTm::new_from_raw_slice(&buf, 7).expect("Deserialization failed");
let (tm_deserialized, size) = PusTm::from_bytes(&buf, 7).expect("Deserialization failed");
assert_eq!(ser_len, size);
verify_ping_reply(&tm_deserialized, false, 22, dummy_time_stamp());
}
#[test]
fn test_manual_field_update() {
let mut sph = SpHeader::tm(0x123, 0x234, 0).unwrap();
let mut sph = SpHeader::tm_unseg(0x123, 0x234, 0).unwrap();
let tc_header = PusTmSecondaryHeader::new_simple(17, 2, dummy_time_stamp());
let mut tm = PusTm::new(&mut sph, tc_header, None, false);
tm.calc_crc_on_serialization = false;
assert_eq!(tm.data_len(), 0x00);
let mut buf: [u8; 32] = [0; 32];
let res = tm.write_to(&mut buf);
let res = tm.write_to_bytes(&mut buf);
assert!(res.is_err());
assert!(matches!(res.unwrap_err(), PusError::CrcCalculationMissing));
tm.update_ccsds_data_len();
assert_eq!(tm.data_len(), 15);
tm.calc_own_crc16();
let res = tm.write_to(&mut buf);
let res = tm.write_to_bytes(&mut buf);
assert!(res.is_ok());
tm.sp_header.data_len = 0;
tm.update_packet_fields();
@ -562,13 +576,13 @@ mod tests {
let time_stamp = dummy_time_stamp();
let pus_tm = base_ping_reply_full_ctor(&time_stamp);
let mut buf: [u8; 16] = [0; 16];
let res = pus_tm.write_to(&mut buf);
let res = pus_tm.write_to_bytes(&mut buf);
assert!(res.is_err());
let error = res.unwrap_err();
assert!(matches!(error, PusError::PacketError { .. }));
assert!(matches!(error, PusError::ByteConversionError { .. }));
match error {
PusError::PacketError(err) => match err {
PacketError::ToBytesSliceTooSmall(size_missmatch) => {
PusError::ByteConversionError(err) => match err {
ByteConversionError::ToSliceTooSmall(size_missmatch) => {
assert_eq!(size_missmatch.expected, 22);
assert_eq!(size_missmatch.found, 16);
}