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merge into: shimun:cache_button
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shimun:master shimun:master-old shimun:reset-timeout shimun:max_enumeration_issue shimun:hmac-secret-uv shimun:cred_dfs shimun:rgerganov-cred-meta-fix shimun:fix_version_in_build shimun:cbor_safety shimun:backup_improvements shimun:b3.1.1 shimun:aaguid_cert_update shimun:library_refactor shimun:all-contributors/add-Nitrokey shimun:bump3.0.0 shimun:all-contributors/add-ccinelli shimun:simplify_build shimun:move_certs_and_lock_to_data shimun:fido2_on_u2f shimun:redue_bootloader_size shimun:all-contributors/add-jolo1581 shimun:key-backup shimun:ctap2_issues shimun:nfc_conformance shimun:all-contributors/add-oplik0 shimun:ccid shimun:cap_button_delay shimun:all-contributors/add-kimusan shimun:fixb_build shimun:update-udev-docs shimun:nfc_fido2_fixes shimun:documentation_improvements shimun:bump_2.4.3 shimun:fix_cdc_interfaces shimun:cache_button shimun:merlokk-pps_impl shimun:all-contributors/add-szszszsz shimun:windows_hello_error_codes shimun:fix-hmac-secret shimun:fault_tolerance shimun:extapdu shimun:sanitize shimun:persistedkey shimun:fido2-conformance
shimun:8lfp9n2gyxjssac4d2c7n5pcj1ydmg6n shimun:4.0.0 shimun:3.1.3 shimun:3.1.2 shimun:3.1.1 shimun:3.1.0 shimun:3.0.1 shimun:3.0.0 shimun:2.5.3 shimun:2.5.2 shimun:2.5.1 shimun:2.5.0 shimun:2.4.3 shimun:2.4.2 shimun:2.4.1 shimun:2.4.0 shimun:2.3.0 shimun:2.2.2 shimun:2.2.1 shimun:2.2.0 shimun:2.1.0 shimun:2.0.0 shimun:1.1.1 shimun:1.1.0 shimun:1.0.2 shimun:1.0.1 shimun:basic-hacker-build shimun:fido2-cert
...
pull from: shimun:redue_bootloader_size
Branches Tags
shimun:master shimun:master-old shimun:reset-timeout shimun:max_enumeration_issue shimun:hmac-secret-uv shimun:cred_dfs shimun:rgerganov-cred-meta-fix shimun:fix_version_in_build shimun:cbor_safety shimun:backup_improvements shimun:b3.1.1 shimun:aaguid_cert_update shimun:library_refactor shimun:all-contributors/add-Nitrokey shimun:bump3.0.0 shimun:all-contributors/add-ccinelli shimun:simplify_build shimun:move_certs_and_lock_to_data shimun:fido2_on_u2f shimun:redue_bootloader_size shimun:all-contributors/add-jolo1581 shimun:key-backup shimun:ctap2_issues shimun:nfc_conformance shimun:all-contributors/add-oplik0 shimun:ccid shimun:cap_button_delay shimun:all-contributors/add-kimusan shimun:fixb_build shimun:update-udev-docs shimun:nfc_fido2_fixes shimun:documentation_improvements shimun:bump_2.4.3 shimun:fix_cdc_interfaces shimun:cache_button shimun:merlokk-pps_impl shimun:all-contributors/add-szszszsz shimun:windows_hello_error_codes shimun:fix-hmac-secret shimun:fault_tolerance shimun:extapdu shimun:sanitize shimun:persistedkey shimun:fido2-conformance
shimun:8lfp9n2gyxjssac4d2c7n5pcj1ydmg6n shimun:4.0.0 shimun:3.1.3 shimun:3.1.2 shimun:3.1.1 shimun:3.1.0 shimun:3.0.1 shimun:3.0.0 shimun:2.5.3 shimun:2.5.2 shimun:2.5.1 shimun:2.5.0 shimun:2.4.3 shimun:2.4.2 shimun:2.4.1 shimun:2.4.0 shimun:2.3.0 shimun:2.2.2 shimun:2.2.1 shimun:2.2.0 shimun:2.1.0 shimun:2.0.0 shimun:1.1.1 shimun:1.1.0 shimun:1.0.2 shimun:1.0.1 shimun:basic-hacker-build shimun:fido2-cert

151 Commits
cache_butt ... redue_boot

Author SHA1 Message Date
Conor Patrick
0f8ddbf982 fix const qualifer warnings 2019-10-08 14:32:21 -04:00
Conor Patrick
b2b9b5e0f9 remove atomic counter from bootloader to save space 2019-10-08 14:26:33 -04:00
Conor Patrick
9158453830 Merge pull request #238 from Nitrokey/bootloader-downgrade-protection 
Bootloader downgrade protection
 2019-10-08 13:53:57 -04:00
Conor Patrick
08658eb11e Merge branch 'master' into bootloader-downgrade-protection 2019-10-08 13:44:20 -04:00
Conor Patrick
49d79fa5da reduce lines/size 2019-10-08 13:42:37 -04:00
Conor Patrick
69a7191860 fix warnings 2019-10-08 13:42:37 -04:00
Conor Patrick
a2fd507f45 typo 2019-10-08 13:42:37 -04:00
Conor Patrick
a58658e35d fix pointer 2019-10-08 13:42:37 -04:00
Conor Patrick
bb2929b28f change ctap_atomic_count to increase by user-specified amount 2019-10-08 13:42:37 -04:00
Conor Patrick
8e0eda8ed4 refactor custom commands and add LOADKEY 2019-10-08 13:42:37 -04:00
Conor Patrick
0ebe0ff502 add ctap function to overwrite key bytes 2019-10-08 13:42:37 -04:00
allcontributors[bot]
7bcb7ea840 docs: update .all-contributorsrc 2019-10-08 13:42:23 -04:00
allcontributors[bot]
811a57f7ab docs: update README.md 2019-10-08 13:42:23 -04:00
Jan A
5168afa16e Code cosmetics, added missing void statement to empty parameter of 
functions
 2019-10-08 12:31:08 -04:00
Nicolas Stalder
208d26be89 Merge pull request #315 from My1/patch-1 
clone using https instead
 2019-09-26 23:01:42 +02:00
My1
45293fe998 clone using https instead 
not everyone has a github account, wants one or wants to setup ssh keys.
 2019-09-26 16:11:40 +02:00
Conor Patrick
a1a42fec5c Bump stable version to 2.5.3 2019-09-17 17:22:15 +08:00
Conor Patrick
8c256298ae default up to enabled 2019-09-17 00:13:57 +08:00
Conor Patrick
01b928c0ec allow in bootloader as well 2019-09-17 00:13:57 +08:00
Conor Patrick
018a4d394c add get_version command to hid 2019-09-17 00:13:57 +08:00
Conor Patrick
7a75fba6d3 delete old code 2019-09-17 00:13:57 +08:00
Conor Patrick
c61f15a090 allow get_assertion with disabled UP 2019-09-17 00:13:57 +08:00
Conor Patrick
f072561899 properly check the rpId in request 2019-09-17 00:13:57 +08:00
merlokk
6652feb4a2 added CID transfer and NAK-ACK sequence 2019-09-05 23:26:15 +08:00
Nicolas Stalder
fc7ea68d4a Bump STABLE_VERSION to 2.5.2 2019-09-05 00:30:59 +02:00
Nicolas Stalder
cb116efcc9 Merge pull request #303 from StoyanDimitrov/patch-3 
Typo
 2019-09-03 00:48:23 +02:00
Nicolas Stalder
80b9df3e04 Merge pull request #302 from StoyanDimitrov/patch-2 
Highlight command and few file names
 2019-09-03 00:48:08 +02:00
Nicolas Stalder
194ef5edcf Merge pull request #304 from StoyanDimitrov/patch-4 
Fix broken formating
 2019-09-03 00:47:21 +02:00
StoyanDimitrov
006117bb6b Fix broken formating 2019-09-02 20:56:55 +00:00
StoyanDimitrov
75c75fa897 Hilight file name 2019-09-02 20:41:42 +00:00
StoyanDimitrov
2969d09ffa Typo 2019-09-02 20:36:02 +00:00
StoyanDimitrov
b871e10d08 Highlight command and few file names 2019-09-02 20:34:20 +00:00
Conor Patrick
18d39a7047 Merge pull request #240 from Nitrokey/remove-pin-storage 
Replace FIDO2 PIN storage with its hash
 2019-09-02 21:50:44 +08:00
Conor Patrick
a9bbdee35b Merge branch 'master' into remove-pin-storage 2019-09-02 21:45:21 +08:00
Conor Patrick
321bbe3691 Merge pull request #293 from solokeys/ccid 
Ccid
 2019-09-02 21:42:38 +08:00
merlokk
1ce191343f add checking some rare case in iso14443-4 chaining. add NAK checking and aborting the data sending. 2019-08-31 02:12:05 +08:00
Conor Patrick
9041e5903c return SW_WRONG_LENGTH for incorrect lc 2019-08-30 16:37:17 +08:00
allcontributors[bot]
689d471688 docs: update .all-contributorsrc 2019-08-30 01:46:40 +02:00
allcontributors[bot]
8b9e44c3ed docs: update README.md 2019-08-30 01:46:40 +02:00
Conor Patrick
83dd92d9ba Update STABLE_VERSION 2019-08-29 22:05:10 +08:00
Szczepan Zalega
a5e1dc2a0c Correct linker documentation 2019-08-24 11:27:28 +02:00
Szczepan Zalega
a053bbc669 Do not verify version for the hacker edition 2019-08-24 10:26:44 +02:00
Szczepan Zalega
3621f2ed4f Add missed doc update in the linker script 2019-08-24 10:26:41 +02:00
Szczepan Zalega
3c7bf5a264 Remove obsolete debug messages 2019-08-24 10:26:38 +02:00
Conor Patrick
8bf1921263 dont reference not-enabled ccid 2019-08-24 16:20:52 +08:00
Szczepan Zalega
e3ff136196 Remove obsolete region for the app static firmware version address 2019-08-24 10:17:59 +02:00
Szczepan Zalega
74181406fe Rename last_addr->last_written_app_address 2019-08-24 10:17:55 +02:00
Szczepan Zalega
987b04523d Correct memory layout 2019-08-24 10:17:52 +02:00
Szczepan Zalega
8023347c8e Makefile: add debug info 2019-08-24 10:17:49 +02:00
Szczepan Zalega
9dae7b2e7c Makefile: fix flashboot recipe 2019-08-24 10:17:46 +02:00
Szczepan Zalega
cb13fb65de Store version in the bootloader. Debug code. 2019-08-24 10:17:43 +02:00
Szczepan Zalega
7fddd58704 Bootloader: get uploaded application version from the 4 last bytes of its firmware 2019-08-24 10:17:40 +02:00
Szczepan Zalega
3a1ea275cc Move _extra* debug linker scripts content to main 2019-08-24 10:17:37 +02:00
Szczepan Zalega
22293f82f2 Rename flash2 -> flash_cfg 2019-08-24 10:17:34 +02:00
Szczepan Zalega
40c3c13b07 Correct flash2 region. Rename _bconfig_start->bootloader_configuration. 2019-08-24 10:17:30 +02:00
Szczepan Zalega
7042b0b656 Move app version to the end of the firmware code, without specific address. Move bootloader config 8B forward. 2019-08-24 10:17:27 +02:00
Szczepan Zalega
ea803aab95 Make the flash memory structure depend on the APPLICATION_START_PAGE macro 2019-08-24 10:17:24 +02:00
Szczepan Zalega
1100b159a9 Refactor. Add debug code. Use %u for unsigned. Use volatile pointer instead of memory storage. 2019-08-24 10:17:21 +02:00
Szczepan Zalega
9ddba5dfc3 Add extra linker script changes 2019-08-24 10:17:18 +02:00
Szczepan Zalega
35e52f4968 Initial modification to move bootloader data after the application 2019-08-24 10:17:15 +02:00
Szczepan Zalega
efddd2f3a8 Use the same public bootloader key as before 2019-08-24 10:17:12 +02:00
Szczepan Zalega
17ceb7b9e8 Make the public key generic 2019-08-24 10:17:09 +02:00
Szczepan Zalega
188a34d1da Add missing Makefile entry. Rename pubkey file. 2019-08-24 10:17:05 +02:00
Szczepan Zalega
9248c6462c Add missing is_newer and pubkey 2019-08-24 10:17:02 +02:00
Szczepan Zalega
118e129152 Set firmware version in the flash 2019-08-24 10:16:59 +02:00
Szczepan Zalega
beb5a5892c Add linker scripts 2019-08-24 10:16:56 +02:00
Szczepan Zalega
d618081dd0 Add version code 2019-08-24 10:16:53 +02:00
Szczepan Zalega
e4e0a3a84e Add code responsible for firmware version verification in the bootloader 2019-08-24 10:16:50 +02:00
Conor Patrick
3ba9b671fc dont use composit for bootloader 2019-08-24 16:01:44 +08:00
Conor Patrick
69c34f9ca9 Merge branch 'master' into ccid 2019-08-24 15:54:51 +08:00
Conor Patrick
3b4c154fd1 add enable macro for CCID interface 2019-08-24 15:49:02 +08:00
Conor Patrick
ccd9a04146 add ccid log tag 2019-08-24 15:08:14 +08:00
Conor Patrick
bde4c09c21 CCID basics working 2019-08-24 15:06:16 +08:00
merlokk
5d3914bc5e remove delays 2019-08-23 22:25:22 +08:00
Conor Patrick
abe306a649 Merge branch 'master' of github.com:solokeys/solo 2019-08-23 14:53:22 +08:00
Conor Patrick
41ceb78f6c add user presence to flags 2019-08-23 14:48:21 +08:00
Conor Patrick
8e192f2363 do not delay bootloader 2019-08-23 14:41:26 +08:00
Conor Patrick
affc256ca2 add delay to cap button improve reliability 2019-08-23 14:41:26 +08:00
Conor Patrick
b3ac739a35 make touch sensor edge based to avoid approving >1 transaction 2019-08-23 13:44:06 +08:00
Conor Patrick
3b53537077 refactor fido2 user presence handling & increase timeout to 29s 2019-08-23 13:19:28 +08:00
merlokk
3fad9a7a7d add response to reset command and delete debug 2019-08-23 10:43:09 +08:00
allcontributors[bot]
8973608f59 docs: update .all-contributorsrc 2019-08-22 22:42:17 +02:00
allcontributors[bot]
8af6505f6d docs: update README.md 2019-08-22 22:42:17 +02:00
merlokk
d39d7978fd small fix 2019-08-22 21:04:01 +08:00
merlokk
c972a13034 fix reboot 2019-08-22 20:55:25 +08:00
merlokk
a95e62e2ea reset 2019-08-22 20:55:25 +08:00
merlokk
c79b7abfb6 add reset placeholder 2019-08-22 20:55:25 +08:00
merlokk
dfb124dc8b refactoring 2019-08-22 20:55:12 +08:00
merlokk
972760eb78 added APDU input chaining 2019-08-22 20:55:12 +08:00
merlokk
0d621d13f9 fix decoding apdu 2019-08-22 20:55:12 +08:00
Conor Patrick
32f920e372 compile/crash fixes 2019-08-22 19:52:21 +08:00
Conor Patrick
a5aff478dd Merge branch 'master' into ccid 2019-08-22 17:13:55 +08:00
merlokk
728acc1671 chaining not needs to go to the start 2019-08-21 12:13:16 +08:00
merlokk
62b4418dac fix pck length math 2019-08-21 12:13:16 +08:00
merlokk
8059a9765f was wrong buffer 2019-08-21 12:13:16 +08:00
merlokk
b743d5fac5 sketch 2019-08-21 12:13:16 +08:00
Conor Patrick
dccfb0d1b3 stub pc build 2019-08-21 12:06:06 +08:00
Conor Patrick
a72f0ede05 take a lazy approach to key agreement generation to not hold up boot time for nfc 2019-08-21 12:06:06 +08:00
Conor Patrick
adcbd3aeb8 speed up public key derivation slightly for nfc 2019-08-21 12:06:06 +08:00
Conor Patrick
d931954a13 remove WTX, move debug log 2019-08-21 12:06:06 +08:00
Conor Patrick
b706cc30b0 for now, always gen key agreement 2019-08-21 12:06:06 +08:00
Nicolas Stalder
57fe39704b Merge pull request #282 from solokeys/update-udev-docs 
Update udev docs
 2019-08-21 02:48:33 +02:00
Nicolas Stalder
4b6619b705 Update udev docs 2019-08-21 02:37:15 +02:00
Szczepan Zalega
a5877f518f Additional assertions and reordering 2019-08-20 12:42:46 +02:00
Szczepan Zalega
5a0cc0d02c Version used STATE data structures 2019-08-20 11:57:32 +02:00
Szczepan Zalega
b452e3dfe4 Correct doc 2019-08-20 11:47:14 +02:00
Szczepan Zalega
7f82233d17 Add missing unit for firmware compilation 2019-08-20 11:38:29 +02:00
Szczepan Zalega
8e3753e711 Add initial STATE migration code (2) 2019-08-20 11:34:51 +02:00
Szczepan Zalega
816ca21f08 Correct writing salted hash 
pinHashEnc is 16 bytes, which is too small to store sha256 result.
 2019-08-20 11:34:48 +02:00
Szczepan Zalega
6c60a37e8a Add initial STATE migration code 2019-08-20 11:34:45 +02:00
Szczepan Zalega
ee351421cb Add missing definition for the simulation to run 2019-08-20 11:34:42 +02:00
Szczepan Zalega
bac576f3a0 Make the state structure backward-compatible. Add version. 2019-08-20 11:34:39 +02:00
Szczepan Zalega
6e637299e5 Add missing declaration, and comment out wallet message 2019-08-20 11:34:35 +02:00
Szczepan Zalega
43b3e93854 Modify state struct 2019-08-20 11:34:32 +02:00
Szczepan Zalega
5a448d636c Add comments 2019-08-20 11:34:29 +02:00
Szczepan Zalega
7be0553377 Replace FIDO2 PIN storage with its hash 2019-08-20 11:34:26 +02:00
merlokk
095b08e3d9 add some stability in small responses 2019-08-19 22:33:32 +08:00
merlokk
89e021003a small fix for HID readers 2019-08-19 22:33:32 +08:00
Emanuele Cesena
4f3d4b09eb Update README.md 2019-08-16 17:22:46 -04:00
Nicolas Stalder
3f4843b03a Merge pull request #270 from solokeys/bump_2.4.3 
Update STABLE_VERSION
 2019-08-16 21:07:59 +02:00
Conor Patrick
26af0c423e Update solo-extras.md 2019-08-16 14:04:43 +08:00
Conor Patrick
19422d9daa add info for rng use 2019-08-16 14:04:43 +08:00
Conor Patrick
b7a4cf001a run through fixes 2019-08-16 14:04:43 +08:00
Conor Patrick
3927aec06d dont remove solo.hex bootloader.hex 2019-08-16 14:04:43 +08:00
Conor Patrick
f5794481ae initial draft 2019-08-16 14:04:43 +08:00
Conor Patrick
caac9d0cc1 add secure build that uses default attestation key 2019-08-16 14:04:43 +08:00
Conor Patrick
ffadab05a3 Update STABLE_VERSION 2019-08-15 19:35:54 +08:00
Conor Patrick
2423154fee fix warning 2019-08-15 18:07:40 +08:00
merlokk
cf79b7865d small fix 2019-08-15 17:50:16 +08:00
merlokk
6f0cf99c92 PPS implementation 2019-08-15 17:50:16 +08:00
Conor Patrick
7ef68fd5d3 Merge pull request #265 from solokeys/fix_cdc_interfaces 
Fix cdc interfaces
 2019-08-15 17:49:53 +08:00
Conor Patrick
3be8611fcf remove duplicate from merge 2019-08-15 17:44:09 +08:00
Conor Patrick
21489658a7 Merge branch 'master' into fix_cdc_interfaces 2019-08-15 17:38:57 +08:00
Conor Patrick
a07a3dee8d refactor user_presence handling 2019-08-15 17:36:35 +08:00
Conor Patrick
416da63a9a not for bootloader 2019-08-15 17:36:35 +08:00
Conor Patrick
027fa791a3 only 1 user presence auth per button press 2019-08-15 17:36:35 +08:00
Conor Patrick
3e52d7b42b cache button press for 2s 2019-08-15 17:36:35 +08:00
merlokk
301e18c6a2 add some int0 logic to main cycle 2019-08-14 14:32:03 +08:00
merlokk
44205141eb add one place for int0 2019-08-14 14:32:03 +08:00
merlokk
6e1110ca9b fix bug with ams_wait_for_tx 2019-08-14 14:32:03 +08:00
merlokk
9105b988e2 fix some warnings 2019-08-14 14:32:03 +08:00
Dan Drown
14c94ea8f5 minor typo 2019-08-14 14:26:45 +08:00
Conor Patrick
435b908c17 Merge pull request #241 from Wesseldr/feature/STM32L432_documentation_update 
Added OsX arm install, updated FIDO2 test site links
 2019-08-14 14:23:41 +08:00
Conor Patrick
78280e570b adjust whitespace 2019-08-12 16:18:47 +08:00
Conor Patrick
36aec9f20b separate interface into two and add "IAD" descriptor 2019-08-12 16:18:30 +08:00
Wessel de Roode
02a51454b7 Added OsX arm install, updated FIDO2 test site links 2019-08-07 18:35:41 +02:00
Conor Patrick
a51417bf61 fix epout connection 2019-05-31 15:58:13 -04:00
Conor Patrick
ba581db49c delete excess 2019-05-21 20:17:44 -04:00
Conor Patrick
3a5cd786dc enumerates correctly 2019-05-21 20:17:37 -04:00
Conor Patrick
4fad28ea47 compile new class 2019-05-18 21:47:51 -04:00
Conor Patrick
0ff9870612 add interface descriptor 2019-05-18 21:26:18 -04:00
67 changed files with 2300 additions and 1171 deletions
Expand all files Collapse all files

29
.all-contributorsrc
View File

@ -168,6 +168,35 @@
"infra",
"tool"
]
},
{
"login": "kimusan",
"name": "Kim Schulz",
"avatar_url": "https://avatars1.githubusercontent.com/u/1150049?v=4",
"profile": "http://www.schulz.dk",
"contributions": [
"business",
"ideas"
]
},
{
"login": "oplik0",
"name": "Jakub",
"avatar_url": "https://avatars2.githubusercontent.com/u/25460763?v=4",
"profile": "https://github.com/oplik0",
"contributions": [
"bug"
]
},
{
"login": "jolo1581",
"name": "Jan A.",
"avatar_url": "https://avatars1.githubusercontent.com/u/53423977?v=4",
"profile": "https://github.com/jolo1581",
"contributions": [
"code",
"doc"
]
}
],
"contributorsPerLine": 7,

2
Makefile
View File

@ -39,7 +39,7 @@ INCLUDES += -I./crypto/cifra/src
CFLAGS += $(INCLUDES)
# for crypto/tiny-AES-c
CFLAGS += -DAES256=1 -DAPP_CONFIG=\"app.h\"
CFLAGS += -DAES256=1 -DAPP_CONFIG=\"app.h\" -DSOLO_EXPERIMENTAL=1
name = main

47
README.md
View File

@ -1,24 +1,18 @@
[![License](https://img.shields.io/github/license/solokeys/solo.svg)](https://github.com/solokeys/solo/blob/master/LICENSE)
[![All Contributors](https://img.shields.io/badge/all_contributors-17-orange.svg?style=flat-square)](#contributors)
[![Build Status](https://travis-ci.com/solokeys/solo.svg?branch=master)](https://travis-ci.com/solokeys/solo)
[![Discourse Users](https://img.shields.io/discourse/https/discourse.solokeys.com/users.svg)](https://discourse.solokeys.com)
**NEW!** We launched a new tiny security key called Somu, it's live on Crowd Supply and you can [pre-order it now](https://solokeys.com/somu)!
[<img src="https://miro.medium.com/max/1400/1*PnzCPLqq_5nt1gjgSEY2LQ.png" width="600">](https://solokeys.com/somu)
Somu is the micro version of Solo. We were inspired to make a secure Tomu, so we took its tiny form factor, we added the secure microcontroller and firmware of Solo, et voilà! Here we have Somu.
[![latest release](https://img.shields.io/github/release/solokeys/solo.svg)](https://update.solokeys.com/)
[![Keybase Chat](https://img.shields.io/badge/chat-on%20keybase-brightgreen.svg)](https://keybase.io/team/solokeys.public)
[![FOSSA Status](https://app.fossa.io/api/projects/git%2Bgithub.com%2Fsolokeys%2Fsolo.svg?type=shield)](https://app.fossa.io/projects/git%2Bgithub.com%2Fsolokeys%2Fsolo?ref=badge_shield)
[![latest release](https://img.shields.io/github/release/solokeys/solo.svg)](https://github.com/solokeys/solo/releases)
[![commits since last release](https://img.shields.io/github/commits-since/solokeys/solo/latest.svg)](https://github.com/solokeys/solo/commits/master)
[![last commit](https://img.shields.io/github/last-commit/solokeys/solo.svg)](https://github.com/solokeys/solo/commits/master)
[![commit activity](https://img.shields.io/github/commit-activity/m/solokeys/solo.svg)](https://github.com/solokeys/solo/commits/master)
[![contributors](https://img.shields.io/github/contributors/solokeys/solo.svg)](https://github.com/solokeys/solo/graphs/contributors)
# Solo
[![Build Status](https://travis-ci.com/solokeys/solo.svg?style=flat-square&branch=master)](https://travis-ci.com/solokeys/solo)
Solo is an open source security key, and you can get one at [solokeys.com](https://solokeys.com).
Solo supports FIDO2 and U2F standards for strong two-factor authentication and password-less login, and it will protect you against phishing and other online attacks. With colored cases and multilingual guides we want to make secure login more personable and accessible to everyone around the globe.
[<img src="https://static.solokeys.com/images/photos/hero-on-white-cropped.png" width="600">](https://solokeys.com)
<img src="https://static.solokeys.com/images/photos/hero-on-white-cropped.png" width="600">
Solo supports FIDO2 and U2F standards for strong two-factor authentication and password-less login, and it will protect you against phishing and other online attacks. With colored cases and multilingual guides we want to make secure login more personable and accessible to everyone around the globe.
This repo contains the Solo firmware, including implementations of FIDO2 and U2F (CTAP2 and CTAP) over USB and NFC. The main implementation is for STM32L432, but it is easily portable.
@ -42,7 +36,7 @@ Solo for Hacker is a special version of Solo that let you customize its firmware
Check out [solokeys.com](https://solokeys.com), for options on where to buy Solo. Solo Hacker can be converted to a secure version, but normal Solo cannot be converted to a Hacker version.
If you have a Solo for Hacker, here's how you can load your own code on it. You can find more details, including how to permanently lock it, in our [documentation](https://docs.solokeys.io/solo/building/). We only support Python3.
If you have a Solo for Hacker, here's how you can load your own code on it. You can find more details, including how to permanently lock it, in our [documentation](https://docs.solokeys.io/solo/building/). We support Python3.
```bash
git clone --recurse-submodules https://github.com/solokeys/solo
@ -140,6 +134,9 @@ Thanks goes to these wonderful people ([emoji key](https://allcontributors.org/d
<td align="center"><a href="http://1bitsquared.com"><img src="https://avatars3.githubusercontent.com/u/17334?v=4" width="100px;" alt="Piotr Esden-Tempski"/><br /><sub><b>Piotr Esden-Tempski</b></sub></a><br /><a href="#business-esden" title="Business development">💼</a></td>
<td align="center"><a href="https://github.com/m3hm00d"><img src="https://avatars1.githubusercontent.com/u/42179593?v=4" width="100px;" alt="f.m3hm00d"/><br /><sub><b>f.m3hm00d</b></sub></a><br /><a href="https://github.com/solokeys/solo/commits?author=m3hm00d" title="Documentation">📖</a></td>
<td align="center"><a href="http://blogs.gnome.org/hughsie/"><img src="https://avatars0.githubusercontent.com/u/151380?v=4" width="100px;" alt="Richard Hughes"/><br /><sub><b>Richard Hughes</b></sub></a><br /><a href="#ideas-hughsie" title="Ideas, Planning, & Feedback">🤔</a> <a href="https://github.com/solokeys/solo/commits?author=hughsie" title="Code">💻</a> <a href="#infra-hughsie" title="Infrastructure (Hosting, Build-Tools, etc)">🚇</a> <a href="#tool-hughsie" title="Tools">🔧</a></td>
<td align="center"><a href="http://www.schulz.dk"><img src="https://avatars1.githubusercontent.com/u/1150049?v=4" width="100px;" alt="Kim Schulz"/><br /><sub><b>Kim Schulz</b></sub></a><br /><a href="#business-kimusan" title="Business development">💼</a> <a href="#ideas-kimusan" title="Ideas, Planning, & Feedback">🤔</a></td>
<td align="center"><a href="https://github.com/oplik0"><img src="https://avatars2.githubusercontent.com/u/25460763?v=4" width="100px;" alt="Jakub"/><br /><sub><b>Jakub</b></sub></a><br /><a href="https://github.com/solokeys/solo/issues?q=author%3Aoplik0" title="Bug reports">🐛</a></td>
<td align="center"><a href="https://github.com/jolo1581"><img src="https://avatars1.githubusercontent.com/u/53423977?v=4" width="100px;" alt="Jan A."/><br /><sub><b>Jan A.</b></sub></a><br /><a href="https://github.com/solokeys/solo/commits?author=jolo1581" title="Code">💻</a> <a href="https://github.com/solokeys/solo/commits?author=jolo1581" title="Documentation">📖</a></td>
</tr>
</table>
@ -168,3 +165,19 @@ You may use Solo documentation under the terms of the CC-BY-SA 4.0 license
You can buy Solo, Solo Tap, and Solo for Hackers at [solokeys.com](https://solokeys.com).
<br/>
<hr/>
<br/>
[![License](https://img.shields.io/github/license/solokeys/solo.svg)](https://github.com/solokeys/solo/blob/master/LICENSE)
[![All Contributors](https://img.shields.io/badge/all_contributors-20-orange.svg?style=flat-square)](#contributors)
[![Build Status](https://travis-ci.com/solokeys/solo.svg?branch=master)](https://travis-ci.com/solokeys/solo)
[![Discourse Users](https://img.shields.io/discourse/https/discourse.solokeys.com/users.svg)](https://discourse.solokeys.com)
[![Keybase Chat](https://img.shields.io/badge/chat-on%20keybase-brightgreen.svg)](https://keybase.io/team/solokeys.public)
[![FOSSA Status](https://app.fossa.io/api/projects/git%2Bgithub.com%2Fsolokeys%2Fsolo.svg?type=shield)](https://app.fossa.io/projects/git%2Bgithub.com%2Fsolokeys%2Fsolo?ref=badge_shield)
[![latest release](https://img.shields.io/github/release/solokeys/solo.svg)](https://github.com/solokeys/solo/releases)
[![commits since last release](https://img.shields.io/github/commits-since/solokeys/solo/latest.svg)](https://github.com/solokeys/solo/commits/master)
[![last commit](https://img.shields.io/github/last-commit/solokeys/solo.svg)](https://github.com/solokeys/solo/commits/master)
[![commit activity](https://img.shields.io/github/commit-activity/m/solokeys/solo.svg)](https://github.com/solokeys/solo/commits/master)
[![contributors](https://img.shields.io/github/contributors/solokeys/solo.svg)](https://github.com/solokeys/solo/graphs/contributors)

2
STABLE_VERSION
View File

@ -1 +1 @@
2.4.2
2.5.3

51
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@ -0,0 +1,51 @@
# Booting into bootloader mode
You can put Solo into bootloader mode by holding down the button, and plugging in Solo. After 2 seconds, bootloader mode will activate.
You'll see a yellowish flashing light and you can let go of the button.
Now Solo is ready to [accept firmware updates](/solo/signed-updates). If the Solo is a secured model, it can only accept signed updates, typically in the `firmware-*.json` format.
If Solo is running a hacker build, it can be put into bootloader mode on command. This makes it easier for development.
```bash
solo program aux enter-bootloader
```
# The boot stages of Solo
Solo has 3 boot stages.
## DFU
The first stage is the DFU (Device Firmware Update) which is in a ROM on Solo. It is baked into the chip and is not implemented by us.
This is what allows the entire firmware of Solo to be programmed. **It's not recommended to develop for Solo using the DFU because
if you program broken firmware, you could brick your device**.
On hacker devices, you can boot into the DFU by holding down the button for 5 seconds, when Solo is already in bootloader mode.
You can also run this command when Solo is in bootloader mode to put it in DFU mode.
```bash
solo program aux enter-dfu
```
Note it will stay in DFU mode until to tell it to boot again. You can boot it again by running the following.
```bash
solo program aux leave-dfu
```
*Warning*: If you change the firmware to something broken, and you tell the DFU to boot it, you could brick your device.
## Solo Bootloader
The next boot stage is the "Solo bootloader". So when we say to put your Solo into bootloader mode, it is this stage.
This bootloader is written by us and allows signed firmware updates to be written. On Solo Hackers, there is no signature checking
and will allow any firmware updates.
It is safe to develop for Solo using our Solo bootloader. If broken firmware is uploaded to the device, then the Solo
bootloader can always be booted again by holding down the button when plugging in.
## Solo application
This is what contains all the important functionality of Solo. FIDO2, U2F, etc. This is what Solo will boot to by default.

118
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@ -14,12 +14,6 @@ but be warned they might be out of date. Typically it will be called `gcc-arm-n
Install `solo-python` usually with `pip3 install solo-python`. The `solo` python application may also be used for [programming](#programming).
To program your build, you'll need one of the following programs.
- [openocd](http://openocd.org)
- [stlink](https://github.com/texane/stlink)
- [STM32CubeProg](https://www.st.com/en/development-tools/stm32cubeprog.html)
## Obtain source code and solo tool
Source code can be downloaded from:
@ -32,7 +26,7 @@ Source code can be downloaded from:
- from python programs [repository](https://pypi.org/project/solo-python/) `pip install solo-python`
- from installing prerequisites `pip3 install -r tools/requirements.txt`
- github repository: [repository](https://github.com/solokeys/solo-python)
- installation python enviroment witn command `make venv` from root directory of source code
- installation python enviroment with command `make venv` from root directory of source code
## Compilation
@ -54,7 +48,7 @@ enabled, like being able to jump to the bootloader on command. It then merges b
and solo builds into the same binary. I.e. it combines `bootloader.hex` and `solo.hex`
into `all.hex`.
If you're just planning to do development, please don't try to reprogram the bootloader,
If you're just planning to do development, **please don't try to reprogram the bootloader**,
as this can be risky if done often. Just use `solo.hex`.
### Building with debug messages
@ -86,6 +80,8 @@ solo monitor <serial-port>
### Building a Solo release
To build Solo
If you want to build a release of Solo, we recommend trying a Hacker build first
just to make sure that it's working. Otherwise it may not be as easy or possible to
fix any mistakes.
@ -96,105 +92,13 @@ If you're ready to program a full release, run this recipe to build.
make build-release-locked
```
Programming `all.hex` will cause the device to permanently lock itself.
This outputs bootloader.hex, solo.hex, and the combined all.hex.
## Programming
Programming `all.hex` will cause the device to permanently lock itself. This means debuggers cannot be used and signature checking
will be enforced on all future updates.
It's recommended to test a debug/hacker build first to make sure Solo is working as expected.
Then you can switch to a locked down build, which cannot be reprogrammed as easily (or not at all!).
Note if you program a secured `solo.hex` file onto a Solo Hacker, it will lock the flash, but the bootloader
will still accept unsigned firmware updates. So you can switch it back to being a hacker, but you will
not be able to replace the unlocked bootloader anymore, since the permanently locked flash also disables the DFU.
[Read more on Solo's boot stages](/solo/bootloader-mode).
We recommend using our `solo` tool to manage programming. It is cross platform. First you must
install the prerequisites:
```
pip3 install -r tools/requirements.txt
```
If you're on Windows, you must also install [libusb](https://sourceforge.net/projects/libusb-win32/files/libusb-win32-releases/1.2.6.0/).
### Pre-programmed Solo Hacker
If your Solo device is already programmed (it flashes green when powered), we recommend
programming it using the Solo bootloader.
```
solo program aux enter-bootloader
solo program bootloader solo.hex
```
Make sure to program `solo.hex` and not `all.hex`. Nothing bad would happen, but you'd
see errors.
If something bad happens, you can always boot the Solo bootloader by doing the following.
1. Unplug device.
2. Hold down button.
3. Plug in device while holding down button.
4. Wait about 2 seconds for flashing yellow light. Release button.
If you hold the button for an additional 5 seconds, it will boot to the ST DFU (device firmware update).
Don't use the ST DFU unless you know what you're doing.
### ST USB DFU
If your Solo has never been programmed, it will boot the ST USB DFU. The LED is turned
off and it enumerates as "STM BOOTLOADER".
You can program it by running the following.
```
solo program aux enter-bootloader
solo program aux enter-dfu
# powercycle key
solo program dfu all.hex
```
Make sure to program `all.hex`, as this contains both the bootloader and the Solo application.
If all goes well, you should see a slow-flashing green light.
### Solo Hacker vs Solo
A Solo hacker device doesn't need to be in bootloader mode to be programmed, it will automatically switch.
Solo (locked) needs the button to be held down when plugged in to boot to the bootloader.
A locked Solo will only accept signed updates.
### Signed updates
If this is not a device with a hacker build, you can only program signed updates.
```
solo program bootloader /path/to/firmware.json
```
If you've provisioned the Solo bootloader with your own secp256r1 public key, you can sign your
firmware by running the following command.
```
solo sign /path/to/signing-key.pem /path/to/solo.hex /output-path/to/firmware.json
```
If your Solo isn't locked, you can always reprogram it using a debugger connected directly
to the token.
## Permanently locking the device
If you plan to be using your Solo for real, you should lock it permanently. This prevents
someone from connecting a debugger to your token and stealing credentials.
To do this, build the locked release firmware.
```
make build-release-locked
```
Now when you program `all.hex`, the device will lock itself when it first boots. You can only update it
with signed updates.
If you'd like to also permanently disable signed updates, plug in your programmed Solo and run the following:
```
# WARNING: No more signed updates.
solo program disable-bootloader
```

141
docs/solo/customization.md Normal file
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@ -0,0 +1,141 @@
# Customization
If you are interested in customizing parts of your Solo, and you have a Solo Hacker, this page is for you.
## Custom Attestation key
The attestation key is used in the FIDO2 *makeCredential* or U2F *register* requests. It signs
newly generated credentials. The certificate associated with the attestation key is output with newly created credentials.
Platforms or services can use the attestation feature to enforce specific authenticators to be used.
This is typically a use case for organizations and isn't seen in the wild for consumer use cases.
Attestation keys are typically the same for at least 100K units of a particular authenticator model.
This is so they don't contribute a significant fingerprint that platforms could use to identify the user.
If you don't want to use the default attestation key that Solo builds with, you can create your own
and program it.
### Creating your attestation key pair
Since we are generating keys, it's important to use a good entropy source.
You can use the [True RNG on your Solo](/solo/solo-extras) to generate some good random numbers.
```
# Run for 1 second, then hit control-c
solo key rng raw > seed.bin
```
First we will create a self signed key pair that acts as the root of trust. This
won't go on the authenticator, but will sign the keypair that does.
Please change the root certification information as needed. You may change the ECC curve.
```
curve=prime256v1
country=US
state=Maine
organization=OpenSourceSecurity
unit="Root CA"
CN=example.com
email=example@example.com
# generate EC private key
openssl ecparam -genkey -name "$curve" -out root_key.pem -rand seed.bin
# generate a "signing request"
openssl req -new -key root_key.pem -out root_key.pem.csr -subj "/C=$country/ST=$state/O=$organization/OU=$unit/CN=example.com/emailAddress=$email"
# self sign the request
openssl x509 -trustout -req -days 18250 -in root_key.pem.csr -signkey root_key.pem -out root_cert.pem -sha256
# convert to smaller size format DER
openssl x509 -in root_cert.pem -outform der -out root_cert.der
# print out information and verify
openssl x509 -in root_cert.pem -text -noout
```
You need to create a extended certificate for the device certificate to work with FIDO2. You need to create this
file, `v3.ext`, and add these options to it.
```
subjectKeyIdentifier=hash
authorityKeyIdentifier=keyid,issuer
basicConstraints=CA:FALSE
keyUsage = digitalSignature, nonRepudiation, keyEncipherment, dataEncipherment
```
Now to generate & sign the attestation key pair that will go on your device, or maybe 100,000 devices :).
Note you must use a prime256v1 curve for this step, and you must leave the unit/OU as "Authenticator Attestation".
```
country=US
state=Maine
organization=OpenSourceSecurity
unit="Authenticator Attestation"
CN=example.com
email=example@example.com
# generate EC private key
openssl ecparam -genkey -name "$curve" -out device_key.pem -rand seed.bin
# generate a "signing request"
openssl req -new -key device_key.pem -out device_key.pem.csr -subj "/C=$country/ST=$state/O=$organization/OU=$unit/CN=example.com/emailAddress=$email"
# sign the request
openssl x509 -req -days 18250 -in device_key.pem.csr -extfile v3.ext -CA root_cert.pem -CAkey root_key.pem -set_serial 01 -out device_cert.pem -sha256
# convert to smaller size format DER
openssl x509 -in device_cert.pem -outform der -out device_cert.der
# Verify the device certificate details
openssl x509 -in device_cert.pem -text -noout
```
Let's verify that the attestation key and certificate are valid, and that they can be verified with the root key pair.
```
echo 'challenge $RANDOM' > chal.txt
# check that they are valid key pairs
openssl dgst -sha256 -sign device_key.pem -out sig.txt chal.txt
openssl dgst -sha256 -verify <(openssl x509 -in device_cert.pem -pubkey -noout) -signature sig.txt chal.txt
openssl dgst -sha256 -sign "root_key.pem" -out sig.txt chal.txt
openssl dgst -sha256 -verify <(openssl x509 -in root_cert.pem -pubkey -noout) -signature sig.txt chal.txt
# Check they are a chain
openssl verify -verbose -CAfile "root_cert.pem" "device_cert.pem"
```
If the checks succeed, you are ready to program the device attestation key and certificate.
### Programming an attestation key and certificate
Convert the DER format of the device attestation certificate to "C" bytes using our utility script. You may first need to
first install prerequisite python modules (`pip install -r tools/requirements.txt`).
```
python tools/gencert/cbytes.py device_cert.der
```
Copy the byte string portion into the [`attestation.c` source file of Solo](https://github.com/solokeys/solo/blob/master/targets/stm32l432/src/attestation.c). Overwrite the development or "default" certificate that is already there.
Now [build the Solo firmware](/solo/building), either a secure or hacker build. You will need to produce a `bootloader.hex` file and a `solo.hex` file.
Print your attestation key in a hex string format.
```
python tools/print_x_y.py device_key.pem
```
Merge the `bootloader.hex`, `solo.hex`, and attestion key into one firmware file.
```
solo mergehex --attestation-key <attestation-key-hex-string> bootloader.hex solo.hex all.hex
```
Now you have a newly create `all.hex` file with a custom attestation key. You can [program this `all.hex` file
with Solo in DFU mode](/solo/programming#procedure).

30
docs/solo/nucleo32-board.md
View File

@ -66,7 +66,7 @@ Environment: Fedora 29 x64, Linux 4.19.9
See <https://docs.solokeys.io/solo/building/> for the original guide. Here details not included there will be covered.
### Install ARM tools
### Install ARM tools Linux
1. Download current [ARM tools] package: [gcc-arm-none-eabi-8-2018-q4-major-linux.tar.bz2].
@ -75,17 +75,23 @@ See <https://docs.solokeys.io/solo/building/> for the original guide. Here detai
3. Add full path to the `./bin` directory as first entry to the `$PATH` variable,
as in `~/gcc-arm/gcc-arm-none-eabi-8-2018-q4-major/bin/:$PATH`.
### Install ARM tools OsX using brew package manager
```bash
brew tap ArmMbed/homebrew-formulae
brew install arm-none-eabi-gcc
```
### Install flashing software
ST provides a CLI flashing tool - `STM32_Programmer_CLI`. It can be downloaded directly from the vendor's site:
1\. Go to [download site URL](https://www.st.com/content/st_com/en/products/development-tools/software-development-tools/stm32-software-development-tools/stm32-programmers/stm32cubeprog.html),
go to bottom page and from STM32CubeProg row select Download button.
2\. Unzip contents of the archive.
3\. Run \*Linux setup
4\. In installation directory go to ./bin - there the ./STM32_Programmer_CLI is located
5\. Add symlink to the STM32 CLI binary to .local/bin. Make sure the latter it is in $PATH.
1. Go to [download site URL](https://www.st.com/content/st_com/en/products/development-tools/software-development-tools/stm32-software-development-tools/stm32-programmers/stm32cubeprog.html), go to bottom page and from STM32CubeProg row select Download button.
2. Unzip contents of the archive.
3. Run \*Linux setup
4. In installation directory go to `./bin` - there the `./STM32_Programmer_CLI` is located
5. Add symlink to the STM32 CLI binary to `.local/bin`. Make sure the latter it is in `$PATH`.
If you're on OsX and installed the STM32CubeProg, you need to add the following to your path:
If you're on MacOS X and installed the STM32CubeProg, you need to add the following to your path:
```bash
# ~/.bash_profile
@ -114,8 +120,8 @@ Do not use it, if you do not plan to do so.
```bash
# while in the main project directory
# create Python virtual environment with required packages, and activate
make env3
. env3/bin/activate
make venv
. venv/bin/activate
# Run flashing
cd ./targets/stm32l432
make flash
@ -178,8 +184,8 @@ make fido2-test
#### FIDO2 test sites
1. <https://webauthn.bin.coffee/>
2. <https://github.com/apowers313/fido2-server-demo/>
1. <https://www.passwordless.dev/overview>
2. <https://webauthn.bin.coffee/>
3. <https://webauthn.org/>
#### U2F test sites

113
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@ -0,0 +1,113 @@
# Programming
This page documents how to update or program your Solo.
## Prerequisites
To program Solo, you'll likely only need to use our Solo tool.
```python
pip3 install solo-python
```
## Updating the firmware
If you just want to update the firmware, you can run one of the following commands.
Make sure your key [is in bootloader mode](/solo/bootloader-mode#solo-bootloader) first.
```bash
solo key update <--secure | --hacker>
```
You can manually install the [latest release](https://github.com/solokeys/solo/releases), or use a build that you made.
```bash
# If it's a hacker, it will automatically boot into bootloader mode.
solo program bootloader <firmware.hex | firmware.json>
```
Note you won't be able to use `all.hex` or the `bundle-*.hex` builds, as these include the solo bootloader. You shouldn't
risk changing the Solo bootloader unless you want to make it a secure device, or [make other customizations]().
## Updating a Hacker to a Secure Solo
Updating a hacker to be a secure build overwrites the [Solo bootloader](/solo/bootloader-mode#solo-bootloader).
So it's important to not mess this up or you may brick your device.
You can use a firmware build from the [latest release](https://github.com/solokeys/solo/releases) or use
a build that you made yourself.
You need to use a firmware file that has the combined bootloader and application (or at the very least just the bootloader).
This means using the `bundle-*.hex` file or the `all.hex` from your build. If you overwrite the Solo flash with a missing bootloader,
it will be bricked.
We provide two types of bundled builds. The `bundle-hacker-*.hex` build is the hacker build. If you update with this,
you will update the bootloader and application, but nothing will be secured. The `bundle-secure-non-solokeys.hex`
is a secured build that will lock your device and it will behave just like a Secure Solo. The main difference is that
it uses a "default" attestation key in the device, rather than the SoloKeys attestation key. There is no security
concern with using our default attestation key, aside from a privacy implication that services can distinguish it from Solo Secure.
### Procedure
1. Boot into DFU mode.
# Enter Solo bootloader
solo program aux enter-bootloader
# Enter DFU
solo program aux enter-dfu
The device should be turned off.
2. Program the device
solo program dfu <bundle-secure-non-solokeys.hex | all.hex>
Double check you programmed it with bootloader + application (or just bootloader).
If you messed it up, simply don't do the next step and repeat this step correctly.
3. Boot the device
Once Solo boots a secure build, it will lock the flash permantly from debugger access. Also the bootloader
will only accept signed firmware updates.
solo program aux leave-dfu
If you are having problems with solo tool and DFU mode, you could alternatively try booting into DFU
by holding down the button while Solo is in bootloader mode. Then try another programming tool that works
with ST DFU:
* STM32CubeProg
* openocd
* stlink
Windows users need to install [libusb](https://sourceforge.net/projects/libusb-win32/files/libusb-win32-releases/1.2.6.0/)
for solo-python to work with Solo's DFU.
## Programming a Solo that hasn't been programmed
A Solo that hasn't been programmed will boot into DFU mode. You can program
it by following a bootloader, or combined bootloader + application.
```
solo program dfu <bundle-*.hex | all.hex>
```
Then boot the device. Make sure it has a bootloader to boot to.
```
solo program aux leave-dfu
```
## Disable signed firmware updates
If you'd like to also permanently disable signed updates, plug in your programmed Solo and run the following:
```bash
# WARNING: No more signed updates.
solo program disable-bootloader
```
You won't be able to update to any new releases.

19
docs/solo/solo-extras.md Normal file
View File

@ -0,0 +1,19 @@
# Solo Extras
## Random number generation
Solo contains a True Random Number Generator (TRNG). A TRNG is a hardware based mechanism
that leverages natural phenomenon to generate random numbers, which can be better than a traditional
RNG that has state and updates deterministically using cryptographic methods.
You can easily access the TRNG stream on Solo using our python tool [`solo-python`](https://github.com/solokeys/solo-python).
```
solo key rng raw > random.bin
```
Or you can seed the state of the RNG on your kernel (`/dev/random`).
```
solo key rng feedkernel
```

39
docs/solo/udev.md
View File

@ -1,30 +1,33 @@
# Summary
On Linux, by default USB dongles can't be accessed by users, for security reasons. To allow user access, so-called "udev rules" must be installed. (Under Fedora, your key may work without such a rule.)
On Linux, by default USB dongles can't be accessed by users, for security reasons. To allow user access, so-called "udev rules" must be installed.
Create a file like [`70-solokeys-access.rules`](https://github.com/solokeys/solo/blob/master/udev/70-solokeys-access.rules) in your `/etc/udev/rules.d` directory, for instance the following rule should cover normal access (it has to be on one line):
For some users, things will work automatically:
- Fedora seems to use a ["universal" udev rule for FIDO devices](https://github.com/amluto/u2f-hidraw-policy)
- Our udev rule made it into [libu2f-host](https://github.com/Yubico/libu2f-host/) v1.1.10
- Arch Linux [has this package](https://www.archlinux.org/packages/community/x86_64/libu2f-host/)
- [Debian sid](https://packages.debian.org/sid/libu2f-udev) and [Ubuntu Eon](https://packages.ubuntu.com/eoan/libu2f-udev) can use the `libu2f-udev` package
- Debian Buster and Ubuntu Disco still distribute v1.1.10, so need the manual rule
- FreeBSD has support in [u2f-devd](https://github.com/solokeys/solo/issues/144#issuecomment-500216020)
There is hope that `udev` itself will adopt the Fedora approach (which is to check for HID usage page `F1D0`, and avoids manually whitelisting each U2F/FIDO2 key): <https://github.com/systemd/systemd/issues/11996>.
Further progress is tracked in: <https://github.com/solokeys/solo/issues/144>.
If you still need to setup a rule, a simple way to do it is:
```
SUBSYSTEM=="hidraw", ATTRS{idVendor}=="0483", ATTRS{idProduct}=="a2ca", TAG+="uaccess", MODE="0660", GROUP="plugdev"
```
Additionally, run the following command after you create this file (it is not necessary to do this again in the future):
```
sudo udevadm control --reload-rules && sudo udevadm trigger
```
A simple way to setup both the udev rule and the udevadm reload is:
```
git clone git@github.com:solokeys/solo.git
git clone https://github.com/solokeys/solo.git
cd solo/udev
make setup
```
We are working on getting user access to Solo keys enabled automatically in common Linux distributions: <https://github.com/solokeys/solo/issues/144>.
Or, manually, create a file like [`70-solokeys-access.rules`](https://github.com/solokeys/solo/blob/master/udev/70-solokeys-access.rules) in your `/etc/udev/rules.d` directory.
Additionally, run the following command after you create this file (it is not necessary to do this again in the future):
```
sudo udevadm control --reload-rules && sudo udevadm trigger
```
# How do udev rules work and why are they needed

20
fido2/apdu.c
View File

@ -9,11 +9,11 @@
#include "apdu.h"
int apdu_decode(uint8_t *data, size_t len, APDU_STRUCT *apdu)
uint16_t apdu_decode(uint8_t *data, size_t len, APDU_STRUCT *apdu)
{
EXT_APDU_HEADER *hapdu = (EXT_APDU_HEADER *)data;
apdu->cla = hapdu->cla;
apdu->cla = hapdu->cla & 0xef; // mask chaining bit if any
apdu->ins = hapdu->ins;
apdu->p1 = hapdu->p1;
apdu->p2 = hapdu->p2;
@ -62,6 +62,11 @@ int apdu_decode(uint8_t *data, size_t len, APDU_STRUCT *apdu)
if (len >= 7 && b0 == 0)
{
uint16_t extlen = (hapdu->lc[1] << 8) + hapdu->lc[2];
if (len - 7 < extlen)
{
return SW_WRONG_LENGTH;
}
// case 2E (Le) - extended
if (len == 7)
@ -103,9 +108,18 @@ int apdu_decode(uint8_t *data, size_t len, APDU_STRUCT *apdu)
apdu->le = 0x10000;
}
}
else
{
if ((len > 5) && (len - 5 < hapdu->lc[0]))
{
return SW_WRONG_LENGTH;
}
}
if (!apdu->case_type)
return 1;
{
return SW_COND_USE_NOT_SATISFIED;
}
if (apdu->lc)
{

8
fido2/apdu.h
View File

@ -36,20 +36,26 @@ typedef struct
uint8_t case_type;
} __attribute__((packed)) APDU_STRUCT;
extern int apdu_decode(uint8_t *data, size_t len, APDU_STRUCT *apdu);
extern uint16_t apdu_decode(uint8_t *data, size_t len, APDU_STRUCT *apdu);
#define APDU_FIDO_U2F_REGISTER 0x01
#define APDU_FIDO_U2F_AUTHENTICATE 0x02
#define APDU_FIDO_U2F_VERSION 0x03
#define APDU_FIDO_NFCCTAP_MSG 0x10
#define APDU_FIDO_U2F_VENDOR_FIRST 0xc0 // First vendor defined command
#define APDU_FIDO_U2F_VENDOR_LAST 0xff // Last vendor defined command
#define APDU_SOLO_RESET 0xee
#define APDU_INS_SELECT 0xA4
#define APDU_INS_READ_BINARY 0xB0
#define APDU_GET_RESPONSE 0xC0
#define SW_SUCCESS 0x9000
#define SW_GET_RESPONSE 0x6100 // Command successfully executed; 'XX' bytes of data are available and can be requested using GET RESPONSE.
#define SW_WRONG_LENGTH 0x6700
#define SW_COND_USE_NOT_SATISFIED 0x6985
#define SW_FILE_NOT_FOUND 0x6a82
#define SW_INCORRECT_P1P2 0x6a86
#define SW_INS_INVALID 0x6d00 // Instruction code not supported or invalid
#define SW_CLA_INVALID 0x6e00
#define SW_INTERNAL_EXCEPTION 0x6f00

5
fido2/crypto.c
View File

@ -262,6 +262,11 @@ void crypto_ecc256_derive_public_key(uint8_t * data, int len, uint8_t * x, uint8
memmove(y,pubkey+32,32);
}
void crypto_ecc256_compute_public_key(uint8_t * privkey, uint8_t * pubkey)
{
uECC_compute_public_key(privkey, pubkey, _es256_curve);
}
void crypto_load_external_key(uint8_t * key, int len)
{
_signing_key = key;

1
fido2/crypto.h
View File

@ -26,6 +26,7 @@ void crypto_sha512_final(uint8_t * hash);
void crypto_ecc256_init();
void crypto_ecc256_derive_public_key(uint8_t * data, int len, uint8_t * x, uint8_t * y);
void crypto_ecc256_compute_public_key(uint8_t * privkey, uint8_t * pubkey);
void crypto_ecc256_load_key(uint8_t * data, int len, uint8_t * data2, int len2);
void crypto_ecc256_load_attestation_key();

189
fido2/ctap.c
View File

@ -25,11 +25,11 @@
#include "extensions.h"
#include "device.h"
#include "data_migration.h"
uint8_t PIN_TOKEN[PIN_TOKEN_SIZE];
uint8_t KEY_AGREEMENT_PUB[64];
static uint8_t KEY_AGREEMENT_PRIV[32];
static uint8_t PIN_CODE_HASH[32];
static int8_t PIN_BOOT_ATTEMPTS_LEFT = PIN_BOOT_ATTEMPTS;
AuthenticatorState STATE;
@ -256,7 +256,9 @@ static int ctap_generate_cose_key(CborEncoder * cose_key, uint8_t * hmac_input,
switch(algtype)
{
case COSE_ALG_ES256:
if (device_is_nfc() == NFC_IS_ACTIVE) device_set_clock_rate(DEVICE_LOW_POWER_FAST);
crypto_ecc256_derive_public_key(hmac_input, len, x, y);
if (device_is_nfc() == NFC_IS_ACTIVE) device_set_clock_rate(DEVICE_LOW_POWER_IDLE);
break;
default:
printf2(TAG_ERR,"Error, COSE alg %d not supported\n", algtype);
@ -435,7 +437,23 @@ static unsigned int get_credential_id_size(CTAP_credentialDescriptor * cred)
static int ctap2_user_presence_test()
{
device_set_status(CTAPHID_STATUS_UPNEEDED);
return ctap_user_presence_test(CTAP2_UP_DELAY_MS);
int ret = ctap_user_presence_test(CTAP2_UP_DELAY_MS);
if ( ret > 1 )
{
return CTAP2_ERR_PROCESSING;
}
else if ( ret > 0 )
{
return CTAP1_ERR_SUCCESS;
}
else if (ret < 0)
{
return CTAP2_ERR_KEEPALIVE_CANCEL;
}
else
{
return CTAP2_ERR_ACTION_TIMEOUT;
}
}
static int ctap_make_auth_data(struct rpId * rp, CborEncoder * map, uint8_t * auth_data_buf, uint32_t * len, CTAP_credInfo * credInfo)
@ -468,19 +486,19 @@ static int ctap_make_auth_data(struct rpId * rp, CborEncoder * map, uint8_t * au
int but;
but = ctap2_user_presence_test(CTAP2_UP_DELAY_MS);
if (!but)
if (CTAP2_ERR_PROCESSING == but)
{
return CTAP2_ERR_OPERATION_DENIED;
authData->head.flags = (0 << 0); // User presence disabled
}
else if (but < 0) // Cancel
else
{
return CTAP2_ERR_KEEPALIVE_CANCEL;
check_retr(but);
authData->head.flags = (1 << 0); // User presence
}
device_set_status(CTAPHID_STATUS_PROCESSING);
authData->head.flags = (but << 0);
authData->head.flags |= (ctap_is_pin_set() << 2);
@ -664,7 +682,16 @@ int ctap_authenticate_credential(struct rpId * rp, CTAP_credentialDescriptor * d
switch(desc->type)
{
case PUB_KEY_CRED_PUB_KEY:
make_auth_tag(desc->credential.id.rpIdHash, desc->credential.id.nonce, desc->credential.id.count, tag);
crypto_sha256_init();
crypto_sha256_update(rp->id, rp->size);
crypto_sha256_final(rpIdHash);
printf1(TAG_RED,"rpId: %s\r\n", rp->id); dump_hex1(TAG_RED,rp->id, rp->size);
if (memcmp(desc->credential.id.rpIdHash, rpIdHash, 32) != 0)
{
return 0;
}
make_auth_tag(rpIdHash, desc->credential.id.nonce, desc->credential.id.count, tag);
return (memcmp(desc->credential.id.tag, tag, CREDENTIAL_TAG_SIZE) == 0);
break;
case PUB_KEY_CRED_CTAP1:
@ -705,10 +732,7 @@ uint8_t ctap_make_credential(CborEncoder * encoder, uint8_t * request, int lengt
}
if (MC.pinAuthEmpty)
{
if (!ctap2_user_presence_test(CTAP2_UP_DELAY_MS))
{
return CTAP2_ERR_OPERATION_DENIED;
}
check_retr( ctap2_user_presence_test(CTAP2_UP_DELAY_MS) );
return ctap_is_pin_set() == 1 ? CTAP2_ERR_PIN_AUTH_INVALID : CTAP2_ERR_PIN_NOT_SET;
}
if ((MC.paramsParsed & MC_requiredMask) != MC_requiredMask)
@ -731,7 +755,7 @@ uint8_t ctap_make_credential(CborEncoder * encoder, uint8_t * request, int lengt
}
}
if (MC.up)
if (MC.up == 1 || MC.up == 0)
{
return CTAP2_ERR_INVALID_OPTION;
}
@ -1141,10 +1165,7 @@ uint8_t ctap_get_assertion(CborEncoder * encoder, uint8_t * request, int length)
if (GA.pinAuthEmpty)
{
if (!ctap2_user_presence_test(CTAP2_UP_DELAY_MS))
{
return CTAP2_ERR_OPERATION_DENIED;
}
check_retr( ctap2_user_presence_test(CTAP2_UP_DELAY_MS) );
return ctap_is_pin_set() == 1 ? CTAP2_ERR_PIN_AUTH_INVALID : CTAP2_ERR_PIN_NOT_SET;
}
if (GA.pinAuthPresent)
@ -1227,8 +1248,9 @@ uint8_t ctap_get_assertion(CborEncoder * encoder, uint8_t * request, int length)
else
#endif
{
device_disable_up(GA.up == 0);
ret = ctap_make_auth_data(&GA.rp, &map, auth_data_buf, &auth_data_buf_sz, NULL);
device_disable_up(false);
check_retr(ret);
((CTAP_authDataHeader *)auth_data_buf)->flags &= ~(1 << 2);
@ -1286,11 +1308,13 @@ uint8_t ctap_update_pin_if_verified(uint8_t * pinEnc, int len, uint8_t * platfor
uint8_t hmac[32];
int ret;
// Validate incoming data packet len
if (len < 64)
{
return CTAP1_ERR_OTHER;
}
// Validate device's state
if (ctap_is_pin_set()) // Check first, prevent SCA
{
if (ctap_device_locked())
@ -1303,6 +1327,7 @@ uint8_t ctap_update_pin_if_verified(uint8_t * pinEnc, int len, uint8_t * platfor
}
}
// calculate shared_secret
crypto_ecc256_shared_secret(platform_pubkey, KEY_AGREEMENT_PRIV, shared_secret);
crypto_sha256_init();
@ -1325,6 +1350,7 @@ uint8_t ctap_update_pin_if_verified(uint8_t * pinEnc, int len, uint8_t * platfor
return CTAP2_ERR_PIN_AUTH_INVALID;
}
// decrypt new PIN with shared secret
crypto_aes256_init(shared_secret, NULL);
while((len & 0xf) != 0) // round up to nearest AES block size multiple
@ -1334,7 +1360,7 @@ uint8_t ctap_update_pin_if_verified(uint8_t * pinEnc, int len, uint8_t * platfor
crypto_aes256_decrypt(pinEnc, len);
// validate new PIN (length)
ret = trailing_zeros(pinEnc, NEW_PIN_ENC_MIN_SIZE - 1);
ret = NEW_PIN_ENC_MIN_SIZE - ret;
@ -1350,6 +1376,8 @@ uint8_t ctap_update_pin_if_verified(uint8_t * pinEnc, int len, uint8_t * platfor
dump_hex1(TAG_CP, pinEnc, ret);
}
// validate device's state, decrypt and compare pinHashEnc (user provided current PIN hash) with stored PIN_CODE_HASH
if (ctap_is_pin_set())
{
if (ctap_device_locked())
@ -1362,7 +1390,14 @@ uint8_t ctap_update_pin_if_verified(uint8_t * pinEnc, int len, uint8_t * platfor
}
crypto_aes256_reset_iv(NULL);
crypto_aes256_decrypt(pinHashEnc, 16);
if (memcmp(pinHashEnc, PIN_CODE_HASH, 16) != 0)
uint8_t pinHashEncSalted[32];
crypto_sha256_init();
crypto_sha256_update(pinHashEnc, 16);
crypto_sha256_update(STATE.PIN_SALT, sizeof(STATE.PIN_SALT));
crypto_sha256_final(pinHashEncSalted);
if (memcmp(pinHashEncSalted, STATE.PIN_CODE_HASH, 16) != 0)
{
ctap_reset_key_agreement();
ctap_decrement_pin_attempts();
@ -1378,6 +1413,7 @@ uint8_t ctap_update_pin_if_verified(uint8_t * pinEnc, int len, uint8_t * platfor
}
}
// set new PIN (update and store PIN_CODE_HASH)
ctap_update_pin(pinEnc, ret);
return 0;
@ -1397,12 +1433,16 @@ uint8_t ctap_add_pin_if_verified(uint8_t * pinTokenEnc, uint8_t * platform_pubke
crypto_aes256_decrypt(pinHashEnc, 16);
if (memcmp(pinHashEnc, PIN_CODE_HASH, 16) != 0)
uint8_t pinHashEncSalted[32];
crypto_sha256_init();
crypto_sha256_update(pinHashEnc, 16);
crypto_sha256_update(STATE.PIN_SALT, sizeof(STATE.PIN_SALT));
crypto_sha256_final(pinHashEncSalted);
if (memcmp(pinHashEncSalted, STATE.PIN_CODE_HASH, 16) != 0)
{
printf2(TAG_ERR,"Pin does not match!\n");
printf2(TAG_ERR,"platform-pin-hash: "); dump_hex1(TAG_ERR, pinHashEnc, 16);
printf2(TAG_ERR,"authentic-pin-hash: "); dump_hex1(TAG_ERR, PIN_CODE_HASH, 16);
printf2(TAG_ERR,"authentic-pin-hash: "); dump_hex1(TAG_ERR, STATE.PIN_CODE_HASH, 16);
printf2(TAG_ERR,"shared-secret: "); dump_hex1(TAG_ERR, shared_secret, 32);
printf2(TAG_ERR,"platform-pubkey: "); dump_hex1(TAG_ERR, platform_pubkey, 64);
printf2(TAG_ERR,"device-pubkey: "); dump_hex1(TAG_ERR, KEY_AGREEMENT_PUB, 64);
@ -1479,6 +1519,11 @@ uint8_t ctap_client_pin(CborEncoder * encoder, uint8_t * request, int length)
ret = cbor_encode_int(&map, RESP_keyAgreement);
check_ret(ret);
if (device_is_nfc() == NFC_IS_ACTIVE) device_set_clock_rate(DEVICE_LOW_POWER_FAST);
crypto_ecc256_compute_public_key(KEY_AGREEMENT_PRIV, KEY_AGREEMENT_PUB);
if (device_is_nfc() == NFC_IS_ACTIVE) device_set_clock_rate(DEVICE_LOW_POWER_IDLE);
ret = ctap_add_cose_key(&map, KEY_AGREEMENT_PUB, KEY_AGREEMENT_PUB+32, PUB_KEY_CRED_PUB_KEY, COSE_ALG_ECDH_ES_HKDF_256);
check_retr(ret);
@ -1649,14 +1694,11 @@ uint8_t ctap_request(uint8_t * pkt_raw, int length, CTAP_RESPONSE * resp)
break;
case CTAP_RESET:
printf1(TAG_CTAP,"CTAP_RESET\n");
if (ctap2_user_presence_test(CTAP2_UP_DELAY_MS))
status = ctap2_user_presence_test(CTAP2_UP_DELAY_MS);
if (status == CTAP1_ERR_SUCCESS)
{
ctap_reset();
}
else
{
status = CTAP2_ERR_OPERATION_DENIED;
}
break;
case GET_NEXT_ASSERTION:
printf1(TAG_CTAP,"CTAP_NEXT_ASSERTION\n");
@ -1678,7 +1720,7 @@ uint8_t ctap_request(uint8_t * pkt_raw, int length, CTAP_RESPONSE * resp)
break;
default:
status = CTAP1_ERR_INVALID_COMMAND;
printf2(TAG_ERR,"error, invalid cmd\n");
printf2(TAG_ERR,"error, invalid cmd: 0x%02x\n", cmd);
}
done:
@ -1708,12 +1750,39 @@ static void ctap_state_init()
STATE.remaining_tries = PIN_LOCKOUT_ATTEMPTS;
STATE.is_pin_set = 0;
STATE.rk_stored = 0;
STATE.data_version = STATE_VERSION;
ctap_reset_rk();
if (ctap_generate_rng(STATE.PIN_SALT, sizeof(STATE.PIN_SALT)) != 1) {
printf2(TAG_ERR, "Error, rng failed\n");
exit(1);
}
printf1(TAG_STOR, "Generated PIN SALT: ");
dump_hex1(TAG_STOR, STATE.PIN_SALT, sizeof STATE.PIN_SALT);
}
/** Overwrite master secret from external source.
* @param keybytes an array of KEY_SPACE_BYTES length.
*
* This function should only be called from a privilege mode.
*/
void ctap_load_external_keys(uint8_t * keybytes){
memmove(STATE.key_space, keybytes, KEY_SPACE_BYTES);
authenticator_write_state(&STATE, 0);
authenticator_write_state(&STATE, 1);
crypto_load_master_secret(STATE.key_space);
}
#include "version.h"
void ctap_init()
{
printf1(TAG_ERR,"Current firmware version address: %p\r\n", &firmware_version);
printf1(TAG_ERR,"Current firmware version: %d.%d.%d.%d (%02x.%02x.%02x.%02x)\r\n",
firmware_version.major, firmware_version.minor, firmware_version.patch, firmware_version.reserved,
firmware_version.major, firmware_version.minor, firmware_version.patch, firmware_version.reserved
);
crypto_ecc256_init();
authenticator_read_state(&STATE);
@ -1742,14 +1811,12 @@ void ctap_init()
}
}
do_migration_if_required(&STATE);
crypto_load_master_secret(STATE.key_space);
if (ctap_is_pin_set())
{
printf1(TAG_STOR,"pin code: \"%s\"\n", STATE.pin_code);
crypto_sha256_init();
crypto_sha256_update(STATE.pin_code, STATE.pin_code_length);
crypto_sha256_final(PIN_CODE_HASH);
printf1(TAG_STOR, "attempts_left: %d\n", STATE.remaining_tries);
}
else
@ -1767,10 +1834,7 @@ void ctap_init()
exit(1);
}
if (device_is_nfc() != NFC_IS_ACTIVE)
{
ctap_reset_key_agreement();
}
ctap_reset_key_agreement();
#ifdef BRIDGE_TO_WALLET
wallet_init();
@ -1784,34 +1848,38 @@ uint8_t ctap_is_pin_set()
return STATE.is_pin_set == 1;
}
uint8_t ctap_pin_matches(uint8_t * pin, int len)
{
return memcmp(pin, STATE.pin_code, len) == 0;
}
/**
* Set new PIN, by updating PIN hash. Save state.
* Globals: STATE
* @param pin new PIN (raw)
* @param len pin array length
*/
void ctap_update_pin(uint8_t * pin, int len)
{
if (len > NEW_PIN_ENC_MIN_SIZE || len < 4)
if (len >= NEW_PIN_ENC_MIN_SIZE || len < 4)
{
printf2(TAG_ERR, "Update pin fail length\n");
exit(1);
}
memset(STATE.pin_code, 0, NEW_PIN_ENC_MIN_SIZE);
memmove(STATE.pin_code, pin, len);
STATE.pin_code_length = len;
STATE.pin_code[NEW_PIN_ENC_MIN_SIZE - 1] = 0;
crypto_sha256_init();
crypto_sha256_update(STATE.pin_code, len);
crypto_sha256_final(PIN_CODE_HASH);
crypto_sha256_update(pin, len);
uint8_t intermediateHash[32];
crypto_sha256_final(intermediateHash);
crypto_sha256_init();
crypto_sha256_update(intermediateHash, 16);
memset(intermediateHash, 0, sizeof(intermediateHash));
crypto_sha256_update(STATE.PIN_SALT, sizeof(STATE.PIN_SALT));
crypto_sha256_final(STATE.PIN_CODE_HASH);
STATE.is_pin_set = 1;
authenticator_write_state(&STATE, 1);
authenticator_write_state(&STATE, 0);
printf1(TAG_CTAP, "New pin set: %s\n", STATE.pin_code);
printf1(TAG_CTAP, "New pin set: %s [%d]\n", pin, len);
dump_hex1(TAG_ERR, STATE.PIN_CODE_HASH, sizeof(STATE.PIN_CODE_HASH));
}
uint8_t ctap_decrement_pin_attempts()
@ -1828,9 +1896,7 @@ uint8_t ctap_decrement_pin_attempts()
if (ctap_device_locked())
{
memset(PIN_TOKEN,0,sizeof(PIN_TOKEN));
memset(PIN_CODE_HASH,0,sizeof(PIN_CODE_HASH));
printf1(TAG_CP, "Device locked!\n");
lock_device_permanently();
}
}
else
@ -1969,7 +2035,7 @@ int8_t ctap_load_key(uint8_t index, uint8_t * key)
static void ctap_reset_key_agreement()
{
crypto_ecc256_make_key_pair(KEY_AGREEMENT_PUB, KEY_AGREEMENT_PRIV);
ctap_generate_rng(KEY_AGREEMENT_PRIV, sizeof(KEY_AGREEMENT_PRIV));
}
void ctap_reset()
@ -1986,8 +2052,17 @@ void ctap_reset()
}
ctap_reset_state();
memset(PIN_CODE_HASH,0,sizeof(PIN_CODE_HASH));
ctap_reset_key_agreement();
crypto_load_master_secret(STATE.key_space);
}
void lock_device_permanently() {
memset(PIN_TOKEN, 0, sizeof(PIN_TOKEN));
memset(STATE.PIN_CODE_HASH, 0, sizeof(STATE.PIN_CODE_HASH));
printf1(TAG_CP, "Device locked!\n");
authenticator_write_state(&STATE, 0);
authenticator_write_state(&STATE, 1);
}

5
fido2/ctap.h
View File

@ -131,7 +131,7 @@
#define PIN_LOCKOUT_ATTEMPTS 8 // Number of attempts total
#define PIN_BOOT_ATTEMPTS 3 // number of attempts per boot
#define CTAP2_UP_DELAY_MS 5000
#define CTAP2_UP_DELAY_MS 29000
typedef struct
{
@ -359,5 +359,8 @@ uint16_t ctap_key_len(uint8_t index);
extern uint8_t PIN_TOKEN[PIN_TOKEN_SIZE];
extern uint8_t KEY_AGREEMENT_PUB[64];
void lock_device_permanently();
void ctap_load_external_keys(uint8_t * keybytes);
#endif

1
fido2/ctap_errors.h
View File

@ -49,6 +49,7 @@
#define CTAP2_ERR_PIN_POLICY_VIOLATION 0x37
#define CTAP2_ERR_PIN_TOKEN_EXPIRED 0x38
#define CTAP2_ERR_REQUEST_TOO_LARGE 0x39
#define CTAP2_ERR_ACTION_TIMEOUT 0x3A
#define CTAP1_ERR_OTHER 0x7F
#define CTAP2_ERR_SPEC_LAST 0xDF
#define CTAP2_ERR_EXTENSION_FIRST 0xE0

2
fido2/ctap_parse.c
View File

@ -715,6 +715,7 @@ uint8_t ctap_parse_make_credential(CTAP_makeCredential * MC, CborEncoder * encod
CborValue it,map;
memset(MC, 0, sizeof(CTAP_makeCredential));
MC->up = 0xff;
ret = cbor_parser_init(request, length, CborValidateCanonicalFormat, &parser, &it);
check_retr(ret);
@ -1010,6 +1011,7 @@ uint8_t ctap_parse_get_assertion(CTAP_getAssertion * GA, uint8_t * request, int
memset(GA, 0, sizeof(CTAP_getAssertion));
GA->creds = getAssertionState.creds; // Save stack memory
GA->up = 0xff;
ret = cbor_parser_init(request, length, CborValidateCanonicalFormat, &parser, &it);
check_ret(ret);

341
fido2/ctaphid.c
View File

@ -16,6 +16,7 @@
#include "util.h"
#include "log.h"
#include "extensions.h"
#include "version.h"
// move custom SHA512 command out,
// and the following headers too
@ -538,11 +539,14 @@ extern void _check_ret(CborError ret, int line, const char * filename);
#define check_hardcore(r) _check_ret(r,__LINE__, __FILE__);\
if ((r) != CborNoError) exit(1);
uint8_t ctaphid_custom_command(int len, CTAP_RESPONSE * ctap_resp, CTAPHID_WRITE_BUFFER * wb);
uint8_t ctaphid_handle_packet(uint8_t * pkt_raw)
{
uint8_t cmd;
uint8_t cmd = 0;
uint32_t cid;
int len;
int len = 0;
#ifndef DISABLE_CTAPHID_CBOR
int status;
#endif
@ -552,6 +556,10 @@ uint8_t ctaphid_handle_packet(uint8_t * pkt_raw)
CTAP_RESPONSE ctap_resp;
int bufstatus = ctaphid_buffer_packet(pkt_raw, &cmd, &cid, &len);
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = cmd;
if (bufstatus == HID_IGNORE)
{
@ -587,9 +595,6 @@ uint8_t ctaphid_handle_packet(uint8_t * pkt_raw)
case CTAPHID_PING:
printf1(TAG_HID,"CTAPHID_PING\n");
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_PING;
wb.bcnt = len;
timestamp();
ctaphid_write(&wb, ctap_buffer, len);
@ -602,13 +607,9 @@ uint8_t ctaphid_handle_packet(uint8_t * pkt_raw)
case CTAPHID_WINK:
printf1(TAG_HID,"CTAPHID_WINK\n");
ctaphid_write_buffer_init(&wb);
device_wink();
wb.cid = cid;
wb.cmd = CTAPHID_WINK;
ctaphid_write(&wb,NULL,0);
break;
@ -633,9 +634,6 @@ uint8_t ctaphid_handle_packet(uint8_t * pkt_raw)
ctap_response_init(&ctap_resp);
status = ctap_request(ctap_buffer, len, &ctap_resp);
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_CBOR;
wb.bcnt = (ctap_resp.length+1);
@ -666,9 +664,6 @@ uint8_t ctaphid_handle_packet(uint8_t * pkt_raw)
ctap_response_init(&ctap_resp);
u2f_request((struct u2f_request_apdu*)ctap_buffer, &ctap_resp);
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_MSG;
wb.bcnt = (ctap_resp.length);
ctaphid_write(&wb, ctap_resp.data, ctap_resp.length);
@ -679,209 +674,14 @@ uint8_t ctaphid_handle_packet(uint8_t * pkt_raw)
printf1(TAG_HID,"CTAPHID_CANCEL\n");
is_busy = 0;
break;
#if defined(IS_BOOTLOADER)
case CTAPHID_BOOT:
printf1(TAG_HID,"CTAPHID_BOOT\n");
ctap_response_init(&ctap_resp);
u2f_set_writeback_buffer(&ctap_resp);
is_busy = bootloader_bridge(len, ctap_buffer);
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_BOOT;
wb.bcnt = (ctap_resp.length + 1);
ctaphid_write(&wb, &is_busy, 1);
ctaphid_write(&wb, ctap_resp.data, ctap_resp.length);
ctaphid_write(&wb, NULL, 0);
is_busy = 0;
break;
#endif
#if defined(SOLO_HACKER)
case CTAPHID_ENTERBOOT:
printf1(TAG_HID,"CTAPHID_ENTERBOOT\n");
boot_solo_bootloader();
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_ENTERBOOT;
wb.bcnt = 0;
ctaphid_write(&wb, NULL, 0);
is_busy = 0;
break;
case CTAPHID_ENTERSTBOOT:
printf1(TAG_HID,"CTAPHID_ENTERBOOT\n");
boot_st_bootloader();
break;
#endif
#if !defined(IS_BOOTLOADER)
case CTAPHID_GETRNG:
printf1(TAG_HID,"CTAPHID_GETRNG\n");
ctap_response_init(&ctap_resp);
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_GETRNG;
wb.bcnt = ctap_buffer[0];
if (!wb.bcnt)
wb.bcnt = 57;
memset(ctap_buffer,0,wb.bcnt);
ctap_generate_rng(ctap_buffer, wb.bcnt);
ctaphid_write(&wb, &ctap_buffer, wb.bcnt);
ctaphid_write(&wb, NULL, 0);
is_busy = 0;
break;
#endif
#if defined(SOLO_HACKER) && (DEBUG_LEVEL > 0) && (!IS_BOOTLOADER == 1)
case CTAPHID_PROBE:
/*
* Expects CBOR-serialized data of the form
* {"subcommand": "hash_type", "data": b"the_data"}
* with hash_type in SHA256, SHA512
*/
// some random logging
printf1(TAG_HID,"CTAPHID_PROBE\n");
// initialise CTAP response object
ctap_response_init(&ctap_resp);
// initialise write buffer
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_PROBE;
// prepare parsing (or halt)
int ret;
CborParser parser;
CborValue it, map;
ret = cbor_parser_init(
ctap_buffer, (size_t) buffer_len(),
// strictly speaking, CTAP is not RFC canonical...
CborValidateCanonicalFormat,
&parser, &it);
check_hardcore(ret);
CborType type = cbor_value_get_type(&it);
if (type != CborMapType) exit(1);
ret = cbor_value_enter_container(&it,&map);
check_hardcore(ret);
size_t map_length = 0;
ret = cbor_value_get_map_length(&it, &map_length);
if (map_length != 2) exit(1);
// parse subcommand (or halt)
CborValue val;
ret = cbor_value_map_find_value(&it, "subcommand", &val);
check_hardcore(ret);
if (!cbor_value_is_text_string(&val))
exit(1);
int sha_version = 0;
bool found = false;
if (!found) {
ret = cbor_value_text_string_equals(
&val, "SHA256", &found);
check_hardcore(ret);
if (found)
sha_version = 256;
}
if (!found) {
ret = cbor_value_text_string_equals(
&val, "SHA512", &found);
check_hardcore(ret);
if (found)
sha_version = 512;
}
if (sha_version == 0)
exit(1);
// parse data (or halt)
ret = cbor_value_map_find_value(&it, "data", &val);
check_hardcore(ret);
if (!cbor_value_is_byte_string(&val))
exit(1);
size_t data_length = 0;
ret = cbor_value_calculate_string_length(&val, &data_length);
check_hardcore(ret);
if (data_length > 6*1024)
exit(1);
unsigned char data[6*1024];
ret = cbor_value_copy_byte_string (
&val, &data[0], &data_length, &val);
check_hardcore(ret);
// execute subcommand
if (sha_version == 256) {
// calculate hash
crypto_sha256_init();
crypto_sha256_update(data, data_length);
crypto_sha256_final(ctap_buffer);
// write output
wb.bcnt = CF_SHA256_HASHSZ; // 32 bytes
ctaphid_write(&wb, &ctap_buffer, CF_SHA256_HASHSZ);
}
if (sha_version == 512) {
// calculate hash
crypto_sha512_init();
crypto_sha512_update(data, data_length);
crypto_sha512_final(ctap_buffer);
// write output
wb.bcnt = CF_SHA512_HASHSZ; // 64 bytes
ctaphid_write(&wb, &ctap_buffer, CF_SHA512_HASHSZ);
}
// finalize
ctaphid_write(&wb, NULL, 0);
is_busy = 0;
break;
/*
case CTAPHID_SHA256:
// some random logging
printf1(TAG_HID,"CTAPHID_SHA256\n");
// initialise CTAP response object
ctap_response_init(&ctap_resp);
// initialise write buffer
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_SHA256;
wb.bcnt = CF_SHA256_HASHSZ; // 32 bytes
// calculate hash
crypto_sha256_init();
crypto_sha256_update(ctap_buffer, buffer_len());
crypto_sha256_final(ctap_buffer);
// copy to output
ctaphid_write(&wb, &ctap_buffer, CF_SHA256_HASHSZ);
ctaphid_write(&wb, NULL, 0);
is_busy = 0;
break;
case CTAPHID_SHA512:
// some random logging
printf1(TAG_HID,"CTAPHID_SHA512\n");
// initialise CTAP response object
ctap_response_init(&ctap_resp);
// initialise write buffer
ctaphid_write_buffer_init(&wb);
wb.cid = cid;
wb.cmd = CTAPHID_SHA512;
wb.bcnt = CF_SHA512_HASHSZ; // 64 bytes
// calculate hash
crypto_sha512_init();
crypto_sha512_update(ctap_buffer, buffer_len());
crypto_sha512_final(ctap_buffer);
// copy to output
ctaphid_write(&wb, &ctap_buffer, CF_SHA512_HASHSZ);
ctaphid_write(&wb, NULL, 0);
is_busy = 0;
break;
*/
#endif
default:
printf2(TAG_ERR,"error, unimplemented HID cmd: %02x\r\n", buffer_cmd());
ctaphid_send_error(cid, CTAP1_ERR_INVALID_COMMAND);
break;
if (ctaphid_custom_command(len, &ctap_resp, &wb) != 0){
is_busy = 0;
}else{
printf2(TAG_ERR, "error, unimplemented HID cmd: %02x\r\n", buffer_cmd());
ctaphid_send_error(cid, CTAP1_ERR_INVALID_COMMAND);
}
}
cid_del(cid);
buffer_reset();
@ -891,3 +691,112 @@ uint8_t ctaphid_handle_packet(uint8_t * pkt_raw)
else return 0;
}
uint8_t ctaphid_custom_command(int len, CTAP_RESPONSE * ctap_resp, CTAPHID_WRITE_BUFFER * wb)
{
ctap_response_init(ctap_resp);
#if !defined(IS_BOOTLOADER) && (defined(SOLO_HACKER) || defined(SOLO_EXPERIMENTAL))
uint32_t param;
#endif
#if defined(IS_BOOTLOADER)
uint8_t is_busy;
#endif
switch(wb->cmd)
{
#if defined(IS_BOOTLOADER)
case CTAPHID_BOOT:
printf1(TAG_HID,"CTAPHID_BOOT\n");
u2f_set_writeback_buffer(ctap_resp);
is_busy = bootloader_bridge(len, ctap_buffer);
ctaphid_write(wb, &is_busy, 1);
ctaphid_write(wb, ctap_resp->data, ctap_resp->length);
ctaphid_write(wb, NULL, 0);
return 1;
#endif
#if defined(SOLO_HACKER)
case CTAPHID_ENTERBOOT:
printf1(TAG_HID,"CTAPHID_ENTERBOOT\n");
boot_solo_bootloader();
wb->bcnt = 0;
ctaphid_write(wb, NULL, 0);
return 1;
case CTAPHID_ENTERSTBOOT:
printf1(TAG_HID,"CTAPHID_ENTERBOOT\n");
boot_st_bootloader();
return 1;
#endif
#if !defined(IS_BOOTLOADER)
case CTAPHID_GETRNG:
printf1(TAG_HID,"CTAPHID_GETRNG\n");
wb->bcnt = ctap_buffer[0];
if (!wb->bcnt)
wb->bcnt = 57;
memset(ctap_buffer,0,wb->bcnt);
ctap_generate_rng(ctap_buffer, wb->bcnt);
ctaphid_write(wb, ctap_buffer, wb->bcnt);
ctaphid_write(wb, NULL, 0);
return 1;
break;
#endif
case CTAPHID_GETVERSION:
printf1(TAG_HID,"CTAPHID_GETVERSION\n");
wb->bcnt = 3;
ctap_buffer[0] = SOLO_VERSION_MAJ;
ctap_buffer[1] = SOLO_VERSION_MIN;
ctap_buffer[2] = SOLO_VERSION_PATCH;
ctaphid_write(wb, ctap_buffer, 3);
ctaphid_write(wb, NULL, 0);
return 1;
break;
#if !defined(IS_BOOTLOADER) && (defined(SOLO_HACKER) || defined(SOLO_EXPERIMENTAL))
case CTAPHID_LOADKEY:
/**
* Load external key. Useful for enabling backups.
* bytes: 4 96
* payload: | counter_increase (BE) | master_key |
*
* Counter should be increased by a large amount, e.g. (0x10000000)
* to outdo any previously lost/broken keys.
*/
printf1(TAG_HID,"CTAPHID_LOADKEY\n");
if (len != 100)
{
printf2(TAG_ERR,"Error, invalid length.\n");
ctaphid_send_error(wb->cid, CTAP1_ERR_INVALID_LENGTH);
return 1;
}
// Ask for THREE button presses
if (ctap_user_presence_test(8000) > 0)
if (ctap_user_presence_test(8000) > 0)
if (ctap_user_presence_test(8000) > 0)
{
ctap_load_external_keys(ctap_buffer + 4);
param = ctap_buffer[3];
param |= ctap_buffer[2] << 8;
param |= ctap_buffer[1] << 16;
param |= ctap_buffer[0] << 24;
ctap_atomic_count(param);
wb->bcnt = 0;
ctaphid_write(wb, NULL, 0);
return 1;
}
printf2(TAG_ERR, "Error, invalid length.\n");
ctaphid_send_error(wb->cid, CTAP2_ERR_OPERATION_DENIED);
return 1;
#endif
}
return 0;
}

2
fido2/ctaphid.h
View File

@ -28,6 +28,8 @@
#define CTAPHID_ENTERBOOT (TYPE_INIT | 0x51)
#define CTAPHID_ENTERSTBOOT (TYPE_INIT | 0x52)
#define CTAPHID_GETRNG (TYPE_INIT | 0x60)
#define CTAPHID_GETVERSION (TYPE_INIT | 0x61)
#define CTAPHID_LOADKEY (TYPE_INIT | 0x62)
// reserved for debug, not implemented except for HACKER and DEBUG_LEVEl > 0
#define CTAPHID_PROBE (TYPE_INIT | 0x70)

91
fido2/data_migration.c Normal file
View File

@ -0,0 +1,91 @@
// Copyright 2019 SoloKeys Developers
//
// Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
// http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
// http://opensource.org/licenses/MIT>, at your option. This file may not be
// copied, modified, or distributed except according to those terms.
#include "data_migration.h"
#include "log.h"
#include "device.h"
#include "crypto.h"
// TODO move from macro to function/assert for better readability?
#define check(x) assert(state_prev_0xff->x == state_tmp_ptr->x);
#define check_buf(x) assert(memcmp(state_prev_0xff->x, state_tmp_ptr->x, sizeof(state_tmp_ptr->x)) == 0);
bool migrate_from_FF_to_01(AuthenticatorState_0xFF* state_prev_0xff, AuthenticatorState_0x01* state_tmp_ptr){
// Calculate PIN hash, and replace PIN raw storage with it; add version to structure
// other ingredients do not change
if (state_tmp_ptr->data_version != 0xFF)
return false;
static_assert(sizeof(AuthenticatorState_0xFF) <= sizeof(AuthenticatorState_0x01), "New state structure is smaller, than current one, which is not handled");
if (ctap_generate_rng(state_tmp_ptr->PIN_SALT, sizeof(state_tmp_ptr->PIN_SALT)) != 1) {
printf2(TAG_ERR, "Error, rng failed\n");
return false;
}
if (state_prev_0xff->is_pin_set){
crypto_sha256_init();
crypto_sha256_update(state_prev_0xff->pin_code, state_prev_0xff->pin_code_length);
uint8_t intermediateHash[32];
crypto_sha256_final(intermediateHash);
crypto_sha256_init();
crypto_sha256_update(intermediateHash, 16);
memset(intermediateHash, 0, sizeof(intermediateHash));
crypto_sha256_update(state_tmp_ptr->PIN_SALT, sizeof(state_tmp_ptr->PIN_SALT));
crypto_sha256_final(state_tmp_ptr->PIN_CODE_HASH);
}
assert(state_tmp_ptr->_reserved == state_prev_0xff->pin_code_length);
state_tmp_ptr->_reserved = 0xFF;
state_tmp_ptr->data_version = 1;
check(is_initialized);
check(is_pin_set);
check(remaining_tries);
check(rk_stored);
check_buf(key_lens);
check_buf(key_space);
assert(state_tmp_ptr->data_version != 0xFF);
return true;
}
void save_migrated_state(AuthenticatorState *state_tmp_ptr) {
memmove(&STATE, state_tmp_ptr, sizeof(AuthenticatorState));
authenticator_write_state(state_tmp_ptr, 0);
authenticator_write_state(state_tmp_ptr, 1);
}
void do_migration_if_required(AuthenticatorState* state_current){
// Currently handles only state structures with the same size, or bigger
// FIXME rework to raw buffers with fixed size to allow state structure size decrease
if(!state_current->is_initialized)
return;
AuthenticatorState state_tmp;
AuthenticatorState state_previous;
authenticator_read_state(&state_previous);
authenticator_read_state(&state_tmp);
if(state_current->data_version == 0xFF){
printf2(TAG_ERR, "Running migration\n");
bool success = migrate_from_FF_to_01((AuthenticatorState_0xFF *) &state_previous, &state_tmp);
if (!success){
printf2(TAG_ERR, "Failed migration from 0xFF to 1\n");
// FIXME discuss migration failure behavior
goto return_cleanup;
}
dump_hex1(TAG_ERR, (void*)&state_tmp, sizeof(state_tmp));
dump_hex1(TAG_ERR, (void*)&state_previous, sizeof(state_previous));
save_migrated_state(&state_tmp);
}
assert(state_current->data_version == STATE_VERSION);
return_cleanup:
memset(&state_tmp, 0, sizeof(AuthenticatorState));
memset(&state_previous, 0, sizeof(AuthenticatorState));
}

15
fido2/data_migration.h Normal file
View File

@ -0,0 +1,15 @@
// Copyright 2019 SoloKeys Developers
//
// Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
// http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
// http://opensource.org/licenses/MIT>, at your option. This file may not be
// copied, modified, or distributed except according to those terms.
#ifndef FIDO2_PR_DATA_MIGRATION_H
#define FIDO2_PR_DATA_MIGRATION_H
#include "storage.h"
void do_migration_if_required(AuthenticatorState* state_current);
#endif //FIDO2_PR_DATA_MIGRATION_H

9
fido2/device.h
View File

@ -30,6 +30,7 @@ void main_loop_delay();
void heartbeat();
void device_reboot();
void authenticator_read_state(AuthenticatorState * );
@ -52,7 +53,7 @@ void device_set_status(uint32_t status);
int device_is_button_pressed();
// Test for user presence
// Return 1 for user is present, 0 user not present, -1 if cancel is requested.
// Return 2 for disabled, 1 for user is present, 0 user not present, -1 if cancel is requested.
int ctap_user_presence_test(uint32_t delay);
// Generate @num bytes of random numbers to @dest
@ -60,8 +61,8 @@ int ctap_user_presence_test(uint32_t delay);
int ctap_generate_rng(uint8_t * dst, size_t num);
// Increment atomic counter and return it.
// Must support two counters, @sel selects counter0 or counter1.
uint32_t ctap_atomic_count(int sel);
// @param amount the amount to increase the counter by.
uint32_t ctap_atomic_count(uint32_t amount);
// Verify the user
// return 1 if user is verified, 0 if not
@ -105,7 +106,7 @@ void device_set_clock_rate(DEVICE_CLOCK_RATE param);
#define NFC_IS_AVAILABLE 2
int device_is_nfc();
void request_from_nfc(bool request_active);
void device_disable_up(bool request_active);
void device_init_button();

2
fido2/extensions/wallet.c
View File

@ -95,7 +95,7 @@ int8_t wallet_pin(uint8_t subcmd, uint8_t * pinAuth, uint8_t * arg1, uint8_t * a
if (ret != 0)
return ret;
printf1(TAG_WALLET,"Success. Pin = %s\n", STATE.pin_code);
// printf1(TAG_WALLET,"Success. Pin = %s\n", STATE.pin_code);
break;
case CP_cmdChangePin:

1
fido2/log.c
View File

@ -50,6 +50,7 @@ struct logtag tagtable[] = {
{TAG_EXT,"EXT"},
{TAG_NFC,"NFC"},
{TAG_NFC_APDU, "NAPDU"},
{TAG_CCID, "CCID"},
};

1
fido2/log.h
View File

@ -44,6 +44,7 @@ typedef enum
TAG_EXT = (1 << 18),
TAG_NFC = (1 << 19),
TAG_NFC_APDU = (1 << 20),
TAG_CCID = (1 << 21),
TAG_NO_TAG = (1UL << 30),
TAG_FILENO = (1UL << 31)

1
fido2/main.c
View File

@ -46,6 +46,7 @@ int main(int argc, char *argv[])
TAG_GREEN|
TAG_RED|
TAG_EXT|
TAG_CCID|
TAG_ERR
);

29
fido2/storage.h
View File

@ -11,6 +11,9 @@
#define KEY_SPACE_BYTES 128
#define MAX_KEYS (1)
#define PIN_SALT_LEN (32)
#define STATE_VERSION (1)
#define BACKUP_MARKER 0x5A
#define INITIALIZED_MARKER 0xA5
@ -19,20 +22,40 @@
#define ERR_KEY_SPACE_TAKEN (-2)
#define ERR_KEY_SPACE_EMPTY (-2)
typedef struct
{
// Pin information
uint8_t is_initialized;
uint8_t is_pin_set;
uint8_t pin_code[NEW_PIN_ENC_MIN_SIZE];
int pin_code_length;
int8_t remaining_tries;
uint16_t rk_stored;
uint16_t key_lens[MAX_KEYS];
uint8_t key_space[KEY_SPACE_BYTES];
} AuthenticatorState_0xFF;
typedef struct
{
// Pin information
uint8_t is_initialized;
uint8_t is_pin_set;
uint8_t pin_code[NEW_PIN_ENC_MIN_SIZE];
int pin_code_length;
uint8_t PIN_CODE_HASH[32];
uint8_t PIN_SALT[PIN_SALT_LEN];
int _reserved;
int8_t remaining_tries;
uint16_t rk_stored;
uint16_t key_lens[MAX_KEYS];
uint8_t key_space[KEY_SPACE_BYTES];
} AuthenticatorState;
uint8_t data_version;
} AuthenticatorState_0x01;
typedef AuthenticatorState_0x01 AuthenticatorState;
typedef struct

4
fido2/u2f.c
View File

@ -118,9 +118,9 @@ void u2f_request_nfc(uint8_t * header, uint8_t * data, int datalen, CTAP_RESPONS
if (!header)
return;
request_from_nfc(true); // disable presence test
device_disable_up(true); // disable presence test
u2f_request_ex((APDU_HEADER *)header, data, datalen, resp);
request_from_nfc(false); // enable presence test
device_disable_up(false); // enable presence test
}
void u2f_request(struct u2f_request_apdu* req, CTAP_RESPONSE * resp)

13
fido2/version.c Normal file
View File

@ -0,0 +1,13 @@
#include "version.h"
const version_t firmware_version __attribute__ ((section (".flag"))) __attribute__ ((__used__)) = {
.major = SOLO_VERSION_MAJ,
.minor = SOLO_VERSION_MIN,
.patch = SOLO_VERSION_PATCH,
.reserved = 0
};
// from tinycbor, for a quick static_assert
#include <compilersupport_p.h>
cbor_static_assert(sizeof(version_t) == 4);

18
fido2/version.h
View File

@ -17,5 +17,23 @@
#define SOLO_VERSION __STR(SOLO_VERSION_MAJ) "." __STR(SOLO_VERSION_MIN) "." __STR(SOLO_VERSION_PATCH)
#endif
#include <stdint.h>
#include <stdbool.h>
typedef struct {
union{
uint32_t raw;
struct {
uint8_t major;
uint8_t minor;
uint8_t patch;
uint8_t reserved;
};
};
} version_t;
bool is_newer(const version_t* const newer, const version_t* const older);
const version_t firmware_version ;
#endif

4
in-docker-build.sh
View File

@ -38,6 +38,7 @@ build firmware hacker solo
build firmware hacker-debug-1 solo
build firmware hacker-debug-2 solo
build firmware secure solo
build firmware secure-non-solokeys solo
pip install -U pip
pip install -U solo-python
@ -49,3 +50,6 @@ bundle="bundle-hacker-debug-1-${version}"
/opt/conda/bin/solo mergehex bootloader-nonverifying-${version}.hex firmware-hacker-debug-1-${version}.hex ${bundle}.hex
bundle="bundle-hacker-debug-2-${version}"
/opt/conda/bin/solo mergehex bootloader-nonverifying-${version}.hex firmware-hacker-debug-2-${version}.hex ${bundle}.hex
bundle="bundle-secure-non-solokeys-${version}"
/opt/conda/bin/solo mergehex bootloader-verifying-${version}.hex firmware-secure-non-solokeys-${version}.hex ${bundle}.hex
sha256sum ${bundle}.hex > ${bundle}.sha2

4
mkdocs.yml
View File

@ -11,6 +11,10 @@ nav:
- FIDO2 Implementation: solo/fido2-impl.md
- Metadata Statements: solo/metadata-statements.md
- Build instructions: solo/building.md
- Programming instructions: solo/programming.md
- Bootloader mode: solo/bootloader-mode.md
- Customization: solo/customization.md
- Solo Extras: solo/solo-extras.md
- Running on Nucleo32 board: solo/nucleo32-board.md
- Signed update process: solo/signed-updates.md
- Code documentation: solo/code-overview.md

36
pc/device.c
View File

@ -26,6 +26,7 @@
#define RK_NUM 50
bool use_udp = true;
static bool _up_disabled = false;
struct ResidentKeyStore {
CTAP_residentKey rks[RK_NUM];
@ -43,7 +44,11 @@ void device_set_status(uint32_t status)
__device_status = status;
}
void device_reboot()
{
printf1(TAG_RED, "REBOOT command recieved!\r\n");
exit(100);
}
int udp_server()
{
@ -295,6 +300,10 @@ void ctaphid_write_block(uint8_t * data)
int ctap_user_presence_test(uint32_t d)
{
if (_up_disabled)
{
return 2;
}
return 1;
}
@ -304,20 +313,11 @@ int ctap_user_verification(uint8_t arg)
}
uint32_t ctap_atomic_count(int sel)
uint32_t ctap_atomic_count(uint32_t amount)
{
static uint32_t counter1 = 25;
/*return 713;*/
if (sel == 0)
{
printf1(TAG_RED,"counter1: %d\n", counter1);
return counter1++;
}
else
{
printf2(TAG_ERR,"counter2 not imple\n");
exit(1);
}
counter1 += amount;
return counter1;
}
int ctap_generate_rng(uint8_t * dst, size_t num)
@ -628,3 +628,13 @@ int device_is_nfc()
{
return 0;
}
void device_disable_up(bool disable)
{
_up_disabled = disable;
}
void device_set_clock_rate(DEVICE_CLOCK_RATE param)
{
}

7
targets/stm32l432/Makefile
View File

@ -21,6 +21,9 @@ firmware-hacker-debug-1:
firmware-hacker-debug-2:
$(MAKE) -f $(APPMAKE) -j8 solo.hex PREFIX=$(PREFIX) DEBUG=2 EXTRA_DEFINES='-DSOLO_HACKER -DFLASH_ROP=0'
firmware-secure-non-solokeys:
$(MAKE) -f $(APPMAKE) -j8 solo.hex PREFIX=$(PREFIX) DEBUG=0 EXTRA_DEFINES='-DFLASH_ROP=2'
firmware-secure:
$(MAKE) -f $(APPMAKE) -j8 solo.hex PREFIX=$(PREFIX) DEBUG=0 EXTRA_DEFINES='-DUSE_SOLOKEYS_CERT -DFLASH_ROP=2'
@ -59,7 +62,6 @@ boot-no-sig:
build-release-locked: cbor clean2 boot-sig-checking clean all-locked
$(VENV) $(merge_hex) solo.hex bootloader.hex all.hex
rm -f solo.hex bootloader.hex # don't program solo.hex ...
build-release: cbor clean2 boot-sig-checking clean all
$(VENV) $(merge_hex) solo.hex bootloader.hex all.hex
@ -88,8 +90,7 @@ flash_dfu: solo.hex bootloader.hex
# STM32_Programmer_CLI -c port=usb1 -halt -e all --readunprotect
STM32_Programmer_CLI -c port=usb1 -halt -rdu -d all.hex
flashboot: solo.hex bootloader.hex
$(VENV) $(merge_hex) solo.hex bootloader.hex all.hex
flashboot: bootloader.hex
STM32_Programmer_CLI -c port=SWD -halt -e all --readunprotect
STM32_Programmer_CLI -c port=SWD -halt -d bootloader.hex -rst

74
targets/stm32l432/bootloader/bootloader.c
View File

@ -19,6 +19,12 @@
#include "ctap_errors.h"
#include "log.h"
volatile version_t current_firmware_version __attribute__ ((section (".flag2"))) __attribute__ ((__used__)) = {
.major = SOLO_VERSION_MAJ,
.minor = SOLO_VERSION_MIN,
.patch = SOLO_VERSION_PATCH,
.reserved = 0
};
extern uint8_t REBOOT_FLAG;
@ -56,8 +62,6 @@ static void erase_application()
}
}
#define LAST_ADDR (APPLICATION_END_ADDR-2048 + 8)
#define LAST_PAGE (APPLICATION_END_PAGE-1)
static void disable_bootloader()
{
// Clear last 4 bytes of the last application page-1, which is 108th
@ -102,6 +106,38 @@ int is_bootloader_disabled()
uint32_t * auth = (uint32_t *)(AUTH_WORD_ADDR+4);
return *auth == 0;
}
uint8_t * last_written_app_address;
#include "version.h"
bool is_firmware_version_newer_or_equal()
{
printf1(TAG_BOOT,"Current firmware version: %u.%u.%u.%u (%02x.%02x.%02x.%02x)\r\n",
current_firmware_version.major, current_firmware_version.minor, current_firmware_version.patch, current_firmware_version.reserved,
current_firmware_version.major, current_firmware_version.minor, current_firmware_version.patch, current_firmware_version.reserved
);
volatile version_t * new_version = ((volatile version_t *) last_written_app_address);
printf1(TAG_BOOT,"Uploaded firmware version: %u.%u.%u.%u (%02x.%02x.%02x.%02x)\r\n",
new_version->major, new_version->minor, new_version->patch, new_version->reserved,
new_version->major, new_version->minor, new_version->patch, new_version->reserved
);
const bool allowed = is_newer((const version_t *)new_version, (const version_t *)&current_firmware_version) || current_firmware_version.raw == 0xFFFFFFFF;
if (allowed){
printf1(TAG_BOOT, "Update allowed, setting new firmware version as current.\r\n");
// current_firmware_version.raw = new_version.raw;
uint8_t page[PAGE_SIZE];
memmove(page, (uint8_t*)BOOT_VERSION_ADDR, PAGE_SIZE);
memmove(page, (version_t *)new_version, 4);
printf1(TAG_BOOT, "Writing\r\n");
flash_erase_page(BOOT_VERSION_PAGE);
flash_write(BOOT_VERSION_ADDR, page, PAGE_SIZE);
printf1(TAG_BOOT, "Finish\r\n");
} else {
printf1(TAG_BOOT, "Firmware older - update not allowed.\r\n");
}
return allowed;
}
/**
* Execute bootloader commands
@ -125,10 +161,7 @@ int bootloader_bridge(int klen, uint8_t * keyh)
return CTAP1_ERR_INVALID_LENGTH;
}
#ifndef SOLO_HACKER
uint8_t * pubkey = (uint8_t*)"\xd2\xa4\x2f\x8f\xb2\x31\x1c\xc1\xf7\x0c\x7e\x64\x32\xfb\xbb\xb4\xa3\xdd\x32\x20"
"\x0f\x1b\x88\x9c\xda\x62\xc2\x83\x25\x93\xdd\xb8\x75\x9d\xf9\x86\xee\x03\x6c\xce"
"\x34\x47\x71\x36\xb3\xb2\xad\x6d\x12\xb7\xbe\x49\x3e\x20\xa4\x61\xac\xc7\x71\xc7"
"\x1f\xa8\x14\xf2";
extern uint8_t *pubkey_boot;
const struct uECC_Curve_t * curve = NULL;
#endif
@ -165,12 +198,11 @@ int bootloader_bridge(int klen, uint8_t * keyh)
}
// Do the actual write
flash_write((uint32_t)ptr,req->payload, len);
last_written_app_address = (uint8_t *)ptr + len - 8 + 4;
break;
case BootDone:
// Writing to flash finished. Request code validation.
printf1(TAG_BOOT, "BootDone: ");
printf1(TAG_BOOT, "BootDone: \r\n");
#ifndef SOLO_HACKER
if (len != 64)
{
@ -185,17 +217,23 @@ int bootloader_bridge(int klen, uint8_t * keyh)
crypto_sha256_final(hash);
curve = uECC_secp256r1();
// Verify incoming signature made over the SHA256 hash
if (! uECC_verify(pubkey,
hash,
32,
req->payload,
curve))
if (
!uECC_verify(pubkey_boot, hash, 32, req->payload, curve)
)
{
printf1(TAG_BOOT, "Signature invalid\r\n");
return CTAP2_ERR_OPERATION_DENIED;
}
if (!is_firmware_version_newer_or_equal()){
printf1(TAG_BOOT, "Firmware older - update not allowed.\r\n");
printf1(TAG_BOOT, "Rebooting...\r\n");
REBOOT_FLAG = 1;
return CTAP2_ERR_OPERATION_DENIED;
}
#endif
// Set the application validated, and mark for reboot.
authorize_application();
REBOOT_FLAG = 1;
break;
case BootCheck:
@ -218,6 +256,7 @@ int bootloader_bridge(int klen, uint8_t * keyh)
break;
case BootReboot:
printf1(TAG_BOOT, "BootReboot.\r\n");
printf1(TAG_BOOT, "Application authorized: %d.\r\n", is_authorized_to_boot());
REBOOT_FLAG = 1;
break;
case BootDisable:
@ -277,3 +316,10 @@ void bootloader_heartbeat()
led_rgb(((val * g)<<8) | ((val*r) << 16) | (val*b));
}
uint32_t ctap_atomic_count(uint32_t amount)
{
static uint32_t count = 1000;
count += (amount + 1);
return count;
}

8
targets/stm32l432/bootloader/main.c
View File

@ -138,6 +138,14 @@ int main()
printf1(TAG_GEN,"recv'ing hid msg \n");
extern volatile version_t current_firmware_version;
printf1(TAG_BOOT,"Current firmware version address: %p\r\n", &current_firmware_version);
printf1(TAG_BOOT,"Current firmware version: %d.%d.%d.%d (%02x.%02x.%02x.%02x)\r\n",
current_firmware_version.major, current_firmware_version.minor, current_firmware_version.patch, current_firmware_version.reserved,
current_firmware_version.major, current_firmware_version.minor, current_firmware_version.patch, current_firmware_version.reserved
);
dump_hex1(TAG_BOOT, (uint8_t*)(&current_firmware_version) - 16, 32);
while(1)
{

6
targets/stm32l432/bootloader/pubkey_bootloader.c Normal file
View File

@ -0,0 +1,6 @@
#include "stdint.h"
uint8_t * pubkey_boot = (uint8_t*)"\xd2\xa4\x2f\x8f\xb2\x31\x1c\xc1\xf7\x0c\x7e\x64\x32\xfb\xbb\xb4\xa3\xdd\x32\x20"
"\x0f\x1b\x88\x9c\xda\x62\xc2\x83\x25\x93\xdd\xb8\x75\x9d\xf9\x86\xee\x03\x6c\xce"
"\x34\x47\x71\x36\xb3\xb2\xad\x6d\x12\xb7\xbe\x49\x3e\x20\xa4\x61\xac\xc7\x71\xc7"
"\x1f\xa8\x14\xf2";

8
targets/stm32l432/bootloader/version_check.c Normal file
View File

@ -0,0 +1,8 @@
#include "version.h"
// FIXME test version check function
bool is_newer(const version_t* const newer, const version_t* const older){
return (newer->major > older->major) ||
(newer->major == older->major && newer->minor > older->minor) ||
(newer->major == older->major && newer->minor == older->minor && newer->patch >= older->patch);
}

3
targets/stm32l432/build/application.mk
View File

@ -10,6 +10,8 @@ SRC += $(DRIVER_LIBS) $(USB_LIB)
SRC += ../../fido2/apdu.c ../../fido2/util.c ../../fido2/u2f.c ../../fido2/test_power.c
SRC += ../../fido2/stubs.c ../../fido2/log.c ../../fido2/ctaphid.c ../../fido2/ctap.c
SRC += ../../fido2/ctap_parse.c ../../fido2/main.c
SRC += ../../fido2/version.c
SRC += ../../fido2/data_migration.c
SRC += ../../fido2/extensions/extensions.c ../../fido2/extensions/solo.c
SRC += ../../fido2/extensions/wallet.c
@ -69,6 +71,7 @@ all: $(TARGET).elf
%.elf: $(OBJ)
$(CC) $^ $(HW) $(LDFLAGS) -o $@
@echo "Built version: $(VERSION_FLAGS)"
%.hex: %.elf
$(SZ) $^

2
targets/stm32l432/build/bootloader.mk
View File

@ -2,6 +2,7 @@ include build/common.mk
# ST related
SRC = bootloader/main.c bootloader/bootloader.c
SRC += bootloader/pubkey_bootloader.c bootloader/version_check.c
SRC += src/init.c src/redirect.c src/flash.c src/rng.c src/led.c src/device.c
SRC += src/fifo.c src/crypto.c src/attestation.c src/sense.c
SRC += src/startup_stm32l432xx.s src/system_stm32l4xx.c
@ -65,6 +66,7 @@ all: $(TARGET).elf
%.elf: $(OBJ)
$(CC) $^ $(HW) $(LDFLAGS) -o $@
arm-none-eabi-size $@
%.hex: %.elf
$(CP) -O ihex $^ $(TARGET).hex

3
targets/stm32l432/build/common.mk
View File

@ -10,7 +10,8 @@ DRIVER_LIBS := lib/stm32l4xx_hal_pcd.c lib/stm32l4xx_hal_pcd_ex.c lib/stm32l4xx_
USB_LIB := lib/usbd/usbd_cdc.c lib/usbd/usbd_cdc_if.c lib/usbd/usbd_composite.c \
lib/usbd/usbd_conf.c lib/usbd/usbd_core.c lib/usbd/usbd_ioreq.c \
lib/usbd/usbd_ctlreq.c lib/usbd/usbd_desc.c lib/usbd/usbd_hid.c
lib/usbd/usbd_ctlreq.c lib/usbd/usbd_desc.c lib/usbd/usbd_hid.c \
lib/usbd/usbd_ccid.c
VERSION:=$(shell git describe --abbrev=0 )
VERSION_FULL:=$(shell git describe)

319
targets/stm32l432/lib/usbd/usbd_ccid.c Normal file
View File

@ -0,0 +1,319 @@
#include <stdint.h>
#include "usbd_ccid.h"
#include "usbd_ctlreq.h"
#include "usbd_conf.h"
#include "usbd_core.h"
#include "log.h"
static uint8_t USBD_CCID_Init (USBD_HandleTypeDef *pdev,
uint8_t cfgidx);
static uint8_t USBD_CCID_DeInit (USBD_HandleTypeDef *pdev,
uint8_t cfgidx);
static uint8_t USBD_CCID_Setup (USBD_HandleTypeDef *pdev,
USBD_SetupReqTypedef *req);
static uint8_t USBD_CCID_DataIn (USBD_HandleTypeDef *pdev,
uint8_t epnum);
static uint8_t USBD_CCID_DataOut (USBD_HandleTypeDef *pdev,
uint8_t epnum);
static uint8_t USBD_CCID_EP0_RxReady (USBD_HandleTypeDef *pdev);
USBD_ClassTypeDef USBD_CCID =
{
USBD_CCID_Init,
USBD_CCID_DeInit,
USBD_CCID_Setup,
NULL, /* EP0_TxSent, */
USBD_CCID_EP0_RxReady,
USBD_CCID_DataIn,
USBD_CCID_DataOut,
NULL,
NULL,
NULL,
NULL,
NULL,
NULL,
NULL,
};
static uint8_t ccidmsg_buf[CCID_DATA_PACKET_SIZE];
static uint8_t USBD_CCID_Init (USBD_HandleTypeDef *pdev, uint8_t cfgidx)
{
uint8_t ret = 0U;
USBD_CCID_HandleTypeDef *hcdc;
//Y
USBD_LL_OpenEP(pdev, CCID_IN_EP, USBD_EP_TYPE_BULK,
CCID_DATA_PACKET_SIZE);
USBD_LL_OpenEP(pdev, CCID_OUT_EP, USBD_EP_TYPE_BULK,
CCID_DATA_PACKET_SIZE);
pdev->ep_in[CCID_IN_EP & 0xFU].is_used = 1U;
pdev->ep_out[CCID_OUT_EP & 0xFU].is_used = 1U;
USBD_LL_OpenEP(pdev, CCID_CMD_EP, USBD_EP_TYPE_INTR, CCID_DATA_PACKET_SIZE);
pdev->ep_in[CCID_CMD_EP & 0xFU].is_used = 1U;
// dump_pma_header("ccid.c");
static USBD_CCID_HandleTypeDef mem;
pdev->pClassData = &mem;
hcdc = (USBD_CCID_HandleTypeDef*) pdev->pClassData;
// init transfer states
hcdc->TxState = 0U;
hcdc->RxState = 0U;
USBD_LL_PrepareReceive(&Solo_USBD_Device, CCID_OUT_EP, ccidmsg_buf,
CCID_DATA_PACKET_SIZE);
return ret;
}
static uint8_t USBD_CCID_DeInit (USBD_HandleTypeDef *pdev, uint8_t cfgidx)
{
uint8_t ret = 0U;
//N
USBD_LL_CloseEP(pdev, CCID_IN_EP);
pdev->ep_in[CCID_IN_EP & 0xFU].is_used = 0U;
USBD_LL_CloseEP(pdev, CCID_OUT_EP);
pdev->ep_out[CCID_OUT_EP & 0xFU].is_used = 0U;
USBD_LL_CloseEP(pdev, CCID_CMD_EP);
pdev->ep_in[CCID_CMD_EP & 0xFU].is_used = 0U;
/* DeInit physical Interface components */
if(pdev->pClassData != NULL)
{
pdev->pClassData = NULL;
}
return ret;
}
/**
* @brief USBD_CDC_Setup
* Handle the CDC specific requests
* @param pdev: instance
* @param req: usb requests
* @retval status
*/
static uint8_t USBD_CCID_Setup (USBD_HandleTypeDef *pdev,
USBD_SetupReqTypedef *req)
{
USBD_CCID_HandleTypeDef *hcdc = (USBD_CCID_HandleTypeDef*) pdev->pClassData;
uint8_t ifalt = 0U;
uint16_t status_info = 0U;
uint8_t ret = USBD_OK;
//N
switch (req->bmRequest & USB_REQ_TYPE_MASK)
{
case USB_REQ_TYPE_CLASS :
if (req->wLength)
{
if (req->bmRequest & 0x80U)
{
USBD_CtlSendData (pdev, (uint8_t *)(void *)hcdc->data, req->wLength);
}
else
{
hcdc->CmdOpCode = req->bRequest;
hcdc->CmdLength = (uint8_t)req->wLength;
USBD_CtlPrepareRx (pdev, (uint8_t *)(void *)hcdc->data, req->wLength);
}
}
else
{
}
break;
case USB_REQ_TYPE_STANDARD:
switch (req->bRequest)
{
case USB_REQ_GET_STATUS:
if (pdev->dev_state == USBD_STATE_CONFIGURED)
{
USBD_CtlSendData (pdev, (uint8_t *)(void *)&status_info, 2U);
}
else
{
USBD_CtlError (pdev, req);
ret = USBD_FAIL;
}
break;
case USB_REQ_GET_INTERFACE:
if (pdev->dev_state == USBD_STATE_CONFIGURED)
{
USBD_CtlSendData (pdev, &ifalt, 1U);
}
else
{
USBD_CtlError (pdev, req);
ret = USBD_FAIL;
}
break;
case USB_REQ_SET_INTERFACE:
if (pdev->dev_state != USBD_STATE_CONFIGURED)
{
USBD_CtlError (pdev, req);
ret = USBD_FAIL;
}
break;
case USB_REQ_GET_DESCRIPTOR:
break;
default:
USBD_CtlError (pdev, req);
ret = USBD_FAIL;
break;
}
break;
default:
USBD_CtlError (pdev, req);
ret = USBD_FAIL;
break;
}
return ret;
}
/**
* @brief USBD_CDC_DataIn
* Data sent on non-control IN endpoint
* @param pdev: device instance
* @param epnum: endpoint number
* @retval status
*/
static uint8_t USBD_CCID_DataOut (USBD_HandleTypeDef *pdev, uint8_t epnum)
{
return USBD_OK;
}
static uint8_t USBD_CCID_DataIn (USBD_HandleTypeDef *pdev, uint8_t epnum)
{
USBD_CCID_HandleTypeDef *hcdc = (USBD_CCID_HandleTypeDef*)pdev->pClassData;
hcdc->TxState = 0U;
return USBD_OK;
}
uint8_t USBD_CCID_TransmitPacket(uint8_t * msg, int len)
{
/* Update the packet total length */
Solo_USBD_Device.ep_in[CCID_IN_EP & 0xFU].total_length = len;
while (PCD_GET_EP_TX_STATUS(USB, CCID_IN_EP & 0x0f) == USB_EP_TX_VALID)
;
/* Transmit next packet */
USBD_LL_Transmit(&Solo_USBD_Device, CCID_IN_EP, msg,
len);
printf1(TAG_CCID,"<< ");
dump_hex1(TAG_CCID, msg, len);
return USBD_OK;
}
void ccid_send_status(CCID_HEADER * c, uint8_t status)
{
uint8_t msg[CCID_HEADER_SIZE];
memset(msg,0,sizeof(msg));
msg[0] = CCID_SLOT_STATUS_RES;
msg[6] = c->seq;
msg[7] = status;
USBD_CCID_TransmitPacket(msg, sizeof(msg));
}
void ccid_send_data_block(CCID_HEADER * c, uint8_t status)
{
uint8_t msg[CCID_HEADER_SIZE];
memset(msg,0,sizeof(msg));
msg[0] = CCID_DATA_BLOCK_RES;
msg[6] = c->seq;
msg[7] = status;
USBD_CCID_TransmitPacket(msg, sizeof(msg));
}
void handle_ccid(uint8_t * msg, int len)
{
CCID_HEADER * h = (CCID_HEADER *) msg;
switch(h->type)
{
case CCID_SLOT_STATUS:
ccid_send_status(h, CCID_STATUS_ON);
break;
case CCID_POWER_ON:
ccid_send_data_block(h, CCID_STATUS_ON);
break;
case CCID_POWER_OFF:
ccid_send_status(h, CCID_STATUS_OFF);
break;
default:
ccid_send_status(h, CCID_STATUS_ON);
break;
}
}
/**
* @brief USBD_CDC_DataOut
* Data received on non-control Out endpoint
* @param pdev: device instance
* @param epnum: endpoint number
* @retval status
*/
uint8_t usb_ccid_recieve_callback(USBD_HandleTypeDef *pdev, uint8_t epnum)
{
USBD_CCID_HandleTypeDef *hcdc = (USBD_CCID_HandleTypeDef*) pdev->pClassData;
/* Get the received data length */
hcdc->RxLength = USBD_LL_GetRxDataSize (pdev, epnum);
printf1(TAG_CCID, ">> ");
dump_hex1(TAG_CCID, ccidmsg_buf, hcdc->RxLength);
handle_ccid(ccidmsg_buf, hcdc->RxLength);
USBD_LL_PrepareReceive(&Solo_USBD_Device, CCID_OUT_EP, ccidmsg_buf,
CCID_DATA_PACKET_SIZE);
return USBD_OK;
}
/**
* @brief USBD_CDC_EP0_RxReady
* Handle EP0 Rx Ready event
* @param pdev: device instance
* @retval status
*/
static uint8_t USBD_CCID_EP0_RxReady (USBD_HandleTypeDef *pdev)
{
return USBD_OK;
}

58
targets/stm32l432/lib/usbd/usbd_ccid.h Normal file
View File

@ -0,0 +1,58 @@
#ifndef _USBD_H_
#define _USBD_H_
#include "usbd_ioreq.h"
#define CCID_HEADER_SIZE 10
typedef struct
{
uint8_t type;
uint32_t len;
uint8_t slot;
uint8_t seq;
uint8_t rsvd;
uint16_t param;
} __attribute__((packed)) CCID_HEADER;
#define CCID_IN_EP 0x86U /* EP1 for data IN */
#define CCID_OUT_EP 0x04U /* EP1 for data OUT */
#define CCID_CMD_EP 0x85U /* EP2 for CDC commands */
#define CCID_DATA_PACKET_SIZE 64
#define CCID_SET_PARAMS 0x61
#define CCID_POWER_ON 0x62
#define CCID_POWER_OFF 0x63
#define CCID_SLOT_STATUS 0x65
#define CCID_SECURE 0x69
#define CCID_GET_PARAMS 0x6C
#define CCID_RESET_PARAMS 0x6D
#define CCID_XFR_BLOCK 0x6F
#define CCID_STATUS_ON 0x00
#define CCID_STATUS_OFF 0x02
#define CCID_DATA_BLOCK_RES 0x80
#define CCID_SLOT_STATUS_RES 0x81
#define CCID_PARAMS_RES 0x82
extern USBD_ClassTypeDef USBD_CCID;
typedef struct
{
uint32_t data[CCID_DATA_PACKET_SIZE / 4U];
uint8_t CmdOpCode;
uint8_t CmdLength;
uint8_t *RxBuffer;
uint8_t *TxBuffer;
uint32_t RxLength;
uint32_t TxLength;
__IO uint32_t TxState;
__IO uint32_t RxState;
}
USBD_CCID_HandleTypeDef;
uint8_t usb_ccid_recieve_callback(USBD_HandleTypeDef *pdev, uint8_t epnum);
#endif

345
targets/stm32l432/lib/usbd/usbd_cdc.c
View File

@ -195,302 +195,9 @@ USBD_ClassTypeDef USBD_CDC =
NULL,
NULL,
NULL,
// USBD_CDC_GetHSCfgDesc,
// USBD_CDC_GetFSCfgDesc,
// USBD_CDC_GetOtherSpeedCfgDesc,
// USBD_CDC_GetDeviceQualifierDescriptor,
};
/* USB CDC device Configuration Descriptor */
__ALIGN_BEGIN uint8_t USBD_CDC_CfgHSDesc[USB_CDC_CONFIG_DESC_SIZ] __ALIGN_END =
{
/*Configuration Descriptor*/
0x09, /* bLength: Configuration Descriptor size */
USB_DESC_TYPE_CONFIGURATION, /* bDescriptorType: Configuration */
USB_CDC_CONFIG_DESC_SIZ, /* wTotalLength:no of returned bytes */
0x00,
0x02, /* bNumInterfaces: 2 interface */
0x01, /* bConfigurationValue: Configuration value */
0x00, /* iConfiguration: Index of string descriptor describing the configuration */
0xC0, /* bmAttributes: self powered */
0x32, /* MaxPower 0 mA */
/*---------------------------------------------------------------------------*/
/*Interface Descriptor */
0x09, /* bLength: Interface Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: Interface */
/* Interface descriptor type */
0x00, /* bInterfaceNumber: Number of Interface */
0x00, /* bAlternateSetting: Alternate setting */
0x01, /* bNumEndpoints: One endpoints used */
0x02, /* bInterfaceClass: Communication Interface Class */
0x02, /* bInterfaceSubClass: Abstract Control Model */
0x01, /* bInterfaceProtocol: Common AT commands */
0x00, /* iInterface: */
/*Header Functional Descriptor*/
0x05, /* bLength: Endpoint Descriptor size */
0x24, /* bDescriptorType: CS_INTERFACE */
0x00, /* bDescriptorSubtype: Header Func Desc */
0x10, /* bcdCDC: spec release number */
0x01,
/*Call Management Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x01, /* bDescriptorSubtype: Call Management Func Desc */
0x00, /* bmCapabilities: D0+D1 */
0x01, /* bDataInterface: 1 */
/*ACM Functional Descriptor*/
0x04, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x02, /* bDescriptorSubtype: Abstract Control Management desc */
0x02, /* bmCapabilities */
/*Union Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x06, /* bDescriptorSubtype: Union func desc */
0x00, /* bMasterInterface: Communication class interface */
0x01, /* bSlaveInterface0: Data Class Interface */
/*Endpoint 2 Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_CMD_EP, /* bEndpointAddress */
0x03, /* bmAttributes: Interrupt */
LOBYTE(CDC_CMD_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_CMD_PACKET_SIZE),
CDC_HS_BINTERVAL, /* bInterval: */
/*---------------------------------------------------------------------------*/
/*Data class interface descriptor*/
0x09, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: */
0x01, /* bInterfaceNumber: Number of Interface */
0x00, /* bAlternateSetting: Alternate setting */
0x02, /* bNumEndpoints: Two endpoints used */
0x0A, /* bInterfaceClass: CDC */
0x00, /* bInterfaceSubClass: */
0x00, /* bInterfaceProtocol: */
0x00, /* iInterface: */
/*Endpoint OUT Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_OUT_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
LOBYTE(CDC_DATA_HS_MAX_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_DATA_HS_MAX_PACKET_SIZE),
0x00, /* bInterval: ignore for Bulk transfer */
/*Endpoint IN Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_IN_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
LOBYTE(CDC_DATA_HS_MAX_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_DATA_HS_MAX_PACKET_SIZE),
0x00 /* bInterval: ignore for Bulk transfer */
} ;
/* USB CDC device Configuration Descriptor */
__ALIGN_BEGIN uint8_t USBD_CDC_CfgFSDesc[USB_CDC_CONFIG_DESC_SIZ] __ALIGN_END =
{
/*Configuration Descriptor*/
0x09, /* bLength: Configuration Descriptor size */
USB_DESC_TYPE_CONFIGURATION, /* bDescriptorType: Configuration */
USB_CDC_CONFIG_DESC_SIZ, /* wTotalLength:no of returned bytes */
0x00,
0x02, /* bNumInterfaces: 2 interface */
0x01, /* bConfigurationValue: Configuration value */
0x00, /* iConfiguration: Index of string descriptor describing the configuration */
0xC0, /* bmAttributes: self powered */
0x32, /* MaxPower 0 mA */
/*---------------------------------------------------------------------------*/
/*Interface Descriptor */
0x09, /* bLength: Interface Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: Interface */
/* Interface descriptor type */
0x00, /* bInterfaceNumber: Number of Interface */
0x00, /* bAlternateSetting: Alternate setting */
0x01, /* bNumEndpoints: One endpoints used */
0x02, /* bInterfaceClass: Communication Interface Class */
0x02, /* bInterfaceSubClass: Abstract Control Model */
0x01, /* bInterfaceProtocol: Common AT commands */
0x00, /* iInterface: */
/*Header Functional Descriptor*/
0x05, /* bLength: Endpoint Descriptor size */
0x24, /* bDescriptorType: CS_INTERFACE */
0x00, /* bDescriptorSubtype: Header Func Desc */
0x10, /* bcdCDC: spec release number */
0x01,
/*Call Management Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x01, /* bDescriptorSubtype: Call Management Func Desc */
0x00, /* bmCapabilities: D0+D1 */
0x01, /* bDataInterface: 1 */
/*ACM Functional Descriptor*/
0x04, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x02, /* bDescriptorSubtype: Abstract Control Management desc */
0x02, /* bmCapabilities */
/*Union Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x06, /* bDescriptorSubtype: Union func desc */
0x00, /* bMasterInterface: Communication class interface */
0x01, /* bSlaveInterface0: Data Class Interface */
/*Endpoint 2 Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_CMD_EP, /* bEndpointAddress */
0x03, /* bmAttributes: Interrupt */
LOBYTE(CDC_CMD_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_CMD_PACKET_SIZE),
CDC_FS_BINTERVAL, /* bInterval: */
/*---------------------------------------------------------------------------*/
/*Data class interface descriptor*/
0x09, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: */
0x01, /* bInterfaceNumber: Number of Interface */
0x00, /* bAlternateSetting: Alternate setting */
0x02, /* bNumEndpoints: Two endpoints used */
0x0A, /* bInterfaceClass: CDC */
0x00, /* bInterfaceSubClass: */
0x00, /* bInterfaceProtocol: */
0x00, /* iInterface: */
/*Endpoint OUT Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_OUT_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
LOBYTE(CDC_DATA_FS_MAX_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_DATA_FS_MAX_PACKET_SIZE),
0x00, /* bInterval: ignore for Bulk transfer */
/*Endpoint IN Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_IN_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
LOBYTE(CDC_DATA_FS_MAX_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_DATA_FS_MAX_PACKET_SIZE),
0x00 /* bInterval: ignore for Bulk transfer */
} ;
__ALIGN_BEGIN uint8_t USBD_CDC_OtherSpeedCfgDesc[USB_CDC_CONFIG_DESC_SIZ] __ALIGN_END =
{
0x09, /* bLength: Configuation Descriptor size */
USB_DESC_TYPE_OTHER_SPEED_CONFIGURATION,
USB_CDC_CONFIG_DESC_SIZ,
0x00,
0x02, /* bNumInterfaces: 2 interfaces */
0x01, /* bConfigurationValue: */
0x04, /* iConfiguration: */
0xC0, /* bmAttributes: */
0x32, /* MaxPower 100 mA */
/*Interface Descriptor */
0x09, /* bLength: Interface Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: Interface */
/* Interface descriptor type */
0x00, /* bInterfaceNumber: Number of Interface */
0x00, /* bAlternateSetting: Alternate setting */
0x01, /* bNumEndpoints: One endpoints used */
0x02, /* bInterfaceClass: Communication Interface Class */
0x02, /* bInterfaceSubClass: Abstract Control Model */
0x01, /* bInterfaceProtocol: Common AT commands */
0x00, /* iInterface: */
/*Header Functional Descriptor*/
0x05, /* bLength: Endpoint Descriptor size */
0x24, /* bDescriptorType: CS_INTERFACE */
0x00, /* bDescriptorSubtype: Header Func Desc */
0x10, /* bcdCDC: spec release number */
0x01,
/*Call Management Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x01, /* bDescriptorSubtype: Call Management Func Desc */
0x00, /* bmCapabilities: D0+D1 */
0x01, /* bDataInterface: 1 */
/*ACM Functional Descriptor*/
0x04, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x02, /* bDescriptorSubtype: Abstract Control Management desc */
0x02, /* bmCapabilities */
/*Union Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x06, /* bDescriptorSubtype: Union func desc */
0x00, /* bMasterInterface: Communication class interface */
0x01, /* bSlaveInterface0: Data Class Interface */
/*Endpoint 2 Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT , /* bDescriptorType: Endpoint */
CDC_CMD_EP, /* bEndpointAddress */
0x03, /* bmAttributes: Interrupt */
LOBYTE(CDC_CMD_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_CMD_PACKET_SIZE),
CDC_FS_BINTERVAL, /* bInterval: */
/*---------------------------------------------------------------------------*/
/*Data class interface descriptor*/
0x09, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: */
0x01, /* bInterfaceNumber: Number of Interface */
0x00, /* bAlternateSetting: Alternate setting */
0x02, /* bNumEndpoints: Two endpoints used */
0x0A, /* bInterfaceClass: CDC */
0x00, /* bInterfaceSubClass: */
0x00, /* bInterfaceProtocol: */
0x00, /* iInterface: */
/*Endpoint OUT Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_OUT_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
0x40, /* wMaxPacketSize: */
0x00,
0x00, /* bInterval: ignore for Bulk transfer */
/*Endpoint IN Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_IN_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
0x40, /* wMaxPacketSize: */
0x00,
0x00 /* bInterval */
};
/**
* @}
*/
/** @defgroup USBD_CDC_Private_Functions
* @{
*/
/**
* @brief USBD_CDC_Init
@ -782,45 +489,7 @@ static uint8_t USBD_CDC_EP0_RxReady (USBD_HandleTypeDef *pdev)
return USBD_OK;
}
/**
* @brief USBD_CDC_GetFSCfgDesc
* Return configuration descriptor
* @param speed : current device speed
* @param length : pointer data length
* @retval pointer to descriptor buffer
*/
/*static uint8_t *USBD_CDC_GetFSCfgDesc (uint16_t *length)
{
*length = sizeof (USBD_CDC_CfgFSDesc);
return USBD_CDC_CfgFSDesc;
}
*/
/**
* @brief USBD_CDC_GetHSCfgDesc
* Return configuration descriptor
* @param speed : current device speed
* @param length : pointer data length
* @retval pointer to descriptor buffer
*/
/*static uint8_t *USBD_CDC_GetHSCfgDesc (uint16_t *length)
{
*length = sizeof (USBD_CDC_CfgHSDesc);
return USBD_CDC_CfgHSDesc;
}
*/
/**
* @brief USBD_CDC_GetCfgDesc
* Return configuration descriptor
* @param speed : current device speed
* @param length : pointer data length
* @retval pointer to descriptor buffer
*/
/*static uint8_t *USBD_CDC_GetOtherSpeedCfgDesc (uint16_t *length)
{
*length = sizeof (USBD_CDC_OtherSpeedCfgDesc);
return USBD_CDC_OtherSpeedCfgDesc;
}
*/
/**
* @brief DeviceQualifierDescriptor
* return Device Qualifier descriptor
@ -939,22 +608,10 @@ uint8_t USBD_CDC_ReceivePacket(USBD_HandleTypeDef *pdev)
/* Suspend or Resume USB Out process */
if(pdev->pClassData != NULL)
{
if(pdev->dev_speed == USBD_SPEED_HIGH )
{
/* Prepare Out endpoint to receive next packet */
USBD_LL_PrepareReceive(pdev,
CDC_OUT_EP,
hcdc->RxBuffer,
CDC_DATA_HS_OUT_PACKET_SIZE);
}
else
{
/* Prepare Out endpoint to receive next packet */
USBD_LL_PrepareReceive(pdev,
CDC_OUT_EP,
hcdc->RxBuffer,
CDC_DATA_FS_OUT_PACKET_SIZE);
}
return USBD_OK;
}
else

430
targets/stm32l432/lib/usbd/usbd_composite.c
View File

@ -2,7 +2,9 @@
#include "usbd_desc.h"
#include "usbd_hid.h"
#include "usbd_cdc.h"
#include "usbd_ccid.h"
#include "usbd_ctlreq.h"
#include "app.h"
static uint8_t USBD_Composite_Init (USBD_HandleTypeDef *pdev, uint8_t cfgidx);
@ -26,151 +28,265 @@ static uint8_t *USBD_Composite_GetOtherSpeedCfgDesc (uint16_t *length);
static uint8_t *USBD_Composite_GetDeviceQualifierDescriptor (uint16_t *length);
#define NUM_INTERFACES 2
#if NUM_INTERFACES>1
#define COMPOSITE_CDC_HID_DESCRIPTOR_SIZE (90)
#ifdef ENABLE_CCID
#define CCID_SIZE 84
#define CCID_NUM_INTERFACE 1
#else
#define COMPOSITE_CDC_HID_DESCRIPTOR_SIZE (41)
#define CCID_NUM_INTERFACE 0
#define CCID_SIZE 0
#endif
#define HID_INTF_NUM 0
#define CDC_INTF_NUM 1
#if DEBUG_LEVEL > 0
#define CDC_SIZE (49 + 8 + 9 + 4)
#define CDC_NUM_INTERFACE 2
#else
#define CDC_SIZE 0
#define CDC_NUM_INTERFACE 0
#endif
#define HID_SIZE 41
#define COMPOSITE_CDC_HID_DESCRIPTOR_SIZE (HID_SIZE + CDC_SIZE + CCID_SIZE)
#define NUM_INTERFACES (1 + CDC_NUM_INTERFACE + CCID_NUM_INTERFACE)
#define NUM_CLASSES 3
#define HID_INTF_NUM 0
#define CDC_MASTER_INTF_NUM 1
#define CDC_SLAVE_INTF_NUM 2
#define CCID_INTF_NUM 3
__ALIGN_BEGIN uint8_t COMPOSITE_CDC_HID_DESCRIPTOR[COMPOSITE_CDC_HID_DESCRIPTOR_SIZE] __ALIGN_END =
{
/*Configuration Descriptor*/
0x09, /* bLength: Configuration Descriptor size */
USB_DESC_TYPE_CONFIGURATION, /* bDescriptorType: Configuration */
COMPOSITE_CDC_HID_DESCRIPTOR_SIZE, /* wTotalLength:no of returned bytes */
0x00,
NUM_INTERFACES, /* bNumInterfaces: 1 interface */
0x01, /* bConfigurationValue: Configuration value */
0x00, /* iConfiguration: Index of string descriptor describing the configuration */
0x80, /* bmAttributes: self powered */
0x32, /* MaxPower 100 mA */
{
/*Configuration Descriptor*/
0x09, /* bLength: Configuration Descriptor size */
USB_DESC_TYPE_CONFIGURATION, /* bDescriptorType: Configuration */
COMPOSITE_CDC_HID_DESCRIPTOR_SIZE, /* wTotalLength:no of returned bytes */
0x00,
NUM_INTERFACES, /* bNumInterfaces */
0x01, /* bConfigurationValue: Configuration value */
0x00, /* iConfiguration: Index of string descriptor describing the configuration */
0x80, /* bmAttributes: self powered */
0x32, /* MaxPower 100 mA */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* */
/* HID */
/* */
/* */
/* HID */
/* */
/************** Descriptor of Joystick Mouse interface ****************/
0x09, /*bLength: Interface Descriptor size*/
USB_DESC_TYPE_INTERFACE,/*bDescriptorType: Interface descriptor type*/
HID_INTF_NUM, /*bInterfaceNumber: Number of Interface*/
0x00, /*bAlternateSetting: Alternate setting*/
0x02, /*bNumEndpoints*/
0x03, /*bInterfaceClass: HID*/
0x00, /*bInterfaceSubClass : 1=BOOT, 0=no boot*/
0x00, /*nInterfaceProtocol : 0=none, 1=keyboard, 2=mouse*/
2, /*iInterface: Index of string descriptor*/
/******************** Descriptor of Joystick Mouse HID ********************/
0x09, /*bLength: HID Descriptor size*/
HID_DESCRIPTOR_TYPE, /*bDescriptorType: HID*/
0x11, /*bcdHID: HID Class Spec release number*/
0x01,
0x00, /*bCountryCode: Hardware target country*/
0x01, /*bNumDescriptors: Number of HID class descriptors to follow*/
0x22, /*bDescriptorType*/
HID_FIDO_REPORT_DESC_SIZE,/*wItemLength: Total length of Report descriptor*/
0,
/******************** Descriptor of Mouse endpoint ********************/
0x07, /*bLength: Endpoint Descriptor size*/
USB_DESC_TYPE_ENDPOINT, /*bDescriptorType:*/
HID_EPIN_ADDR, /*bEndpointAddress: Endpoint Address (IN)*/
0x03, /*bmAttributes: Interrupt endpoint*/
HID_EPIN_SIZE, /*wMaxPacketSize: 4 Byte max */
0x00,
HID_BINTERVAL, /*bInterval: Polling Interval */
/************** Descriptor of Joystick Mouse interface ****************/
0x09, /*bLength: Interface Descriptor size*/
USB_DESC_TYPE_INTERFACE, /*bDescriptorType: Interface descriptor type*/
HID_INTF_NUM, /*bInterfaceNumber: Number of Interface*/
0x00, /*bAlternateSetting: Alternate setting*/
0x02, /*bNumEndpoints*/
0x03, /*bInterfaceClass: HID*/
0x00, /*bInterfaceSubClass : 1=BOOT, 0=no boot*/
0x00, /*nInterfaceProtocol : 0=none, 1=keyboard, 2=mouse*/
2, /*iInterface: Index of string descriptor*/
/******************** Descriptor of Joystick Mouse HID ********************/
0x09, /*bLength: HID Descriptor size*/
HID_DESCRIPTOR_TYPE, /*bDescriptorType: HID*/
0x11, /*bcdHID: HID Class Spec release number*/
0x01,
0x00, /*bCountryCode: Hardware target country*/
0x01, /*bNumDescriptors: Number of HID class descriptors to follow*/
0x22, /*bDescriptorType*/
HID_FIDO_REPORT_DESC_SIZE, /*wItemLength: Total length of Report descriptor*/
0,
/******************** Descriptor of Mouse endpoint ********************/
0x07, /*bLength: Endpoint Descriptor size*/
USB_DESC_TYPE_ENDPOINT, /*bDescriptorType:*/
HID_EPIN_ADDR, /*bEndpointAddress: Endpoint Address (IN)*/
0x03, /*bmAttributes: Interrupt endpoint*/
HID_EPIN_SIZE, /*wMaxPacketSize: 4 Byte max */
0x00,
HID_BINTERVAL, /*bInterval: Polling Interval */
0x07, /*bLength: Endpoint Descriptor size*/
USB_DESC_TYPE_ENDPOINT, /*bDescriptorType:*/
HID_EPOUT_ADDR, /*bEndpointAddress: Endpoint Address (IN)*/
0x03, /*bmAttributes: Interrupt endpoint*/
HID_EPOUT_SIZE, /*wMaxPacketSize: 4 Byte max */
0x00,
HID_BINTERVAL, /*bInterval: Polling Interval */
0x07, /*bLength: Endpoint Descriptor size*/
USB_DESC_TYPE_ENDPOINT, /*bDescriptorType:*/
HID_EPOUT_ADDR, /*bEndpointAddress: Endpoint Address (IN)*/
0x03, /*bmAttributes: Interrupt endpoint*/
HID_EPOUT_SIZE, /*wMaxPacketSize: 4 Byte max */
0x00,
HID_BINTERVAL, /*bInterval: Polling Interval */
#if DEBUG_LEVEL > 0
/* */
/* CDC */
/* */
// This "IAD" is needed for Windows since it ignores the standard Union Functional Descriptor
0x08, // bLength
0x0B, // IAD type
CDC_MASTER_INTF_NUM, // First interface
CDC_SLAVE_INTF_NUM, // Next interface
0x02, // bInterfaceClass of the first interface
0x02, // bInterfaceSubClass of the first interface
0x00, // bInterfaceProtocol of the first interface
0x00, // Interface string index
#if NUM_INTERFACES>1
/*Interface Descriptor */
0x09, /* bLength: Interface Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: Interface */
/* Interface descriptor type */
/*!*/ CDC_MASTER_INTF_NUM, /* bInterfaceNumber: Number of Interface */
0x00, /* bAlternateSetting: Alternate setting */
0x01, /* bNumEndpoints: 1 endpoint used */
0x02, /* bInterfaceClass: Communication Interface Class */
0x02, /* bInterfaceSubClass: Abstract Control Model */
0x00, /* bInterfaceProtocol: Common AT commands */
0x00, /* iInterface: */
/* */
/* CDC */
/* */
/*Header Functional Descriptor*/
0x05, /* bLength: Endpoint Descriptor size */
0x24, /* bDescriptorType: CS_INTERFACE */
0x00, /* bDescriptorSubtype: Header Func Desc */
0x10, /* bcdCDC: spec release number */
0x01,
/*Call Management Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x01, /* bDescriptorSubtype: Call Management Func Desc */
0x00, /* bmCapabilities: D0+D1 */
/*!*/ CDC_SLAVE_INTF_NUM, /* bDataInterface: 0 */
/*Interface Descriptor */
0x09, /* bLength: Interface Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: Interface */
/* Interface descriptor type */
/*!*/ CDC_INTF_NUM, /* bInterfaceNumber: Number of Interface */
0x00, /* bAlternateSetting: Alternate setting */
0x03, /* bNumEndpoints: 3 endpoints used */
0x02, /* bInterfaceClass: Communication Interface Class */
0x02, /* bInterfaceSubClass: Abstract Control Model */
0x00, /* bInterfaceProtocol: Common AT commands */
0x00, /* iInterface: */
/*ACM Functional Descriptor*/
0x04, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x02, /* bDescriptorSubtype: Abstract Control Management desc */
0x02, /* bmCapabilities */
/*Header Functional Descriptor*/
0x05, /* bLength: Endpoint Descriptor size */
0x24, /* bDescriptorType: CS_INTERFACE */
0x00, /* bDescriptorSubtype: Header Func Desc */
0x10, /* bcdCDC: spec release number */
0x01,
/*Union Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x06, /* bDescriptorSubtype: Union func desc */
/*!*/ CDC_MASTER_INTF_NUM, /* bMasterInterface: Communication class interface */
/*!*/ CDC_SLAVE_INTF_NUM, /* bSlaveInterface0: Data Class Interface */
/*Call Management Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x01, /* bDescriptorSubtype: Call Management Func Desc */
0x00, /* bmCapabilities: D0+D1 */
/*!*/ CDC_INTF_NUM, /* bDataInterface: 0 */
/* Control Endpoint Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_CMD_EP, /* bEndpointAddress */
0x03, /* bmAttributes: Interrupt */
LOBYTE(CDC_CMD_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_CMD_PACKET_SIZE),
0x10, /* bInterval: */
/*ACM Functional Descriptor*/
0x04, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x02, /* bDescriptorSubtype: Abstract Control Management desc */
0x02, /* bmCapabilities */
/* Interface descriptor */
0x09, /* bLength */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType */
CDC_SLAVE_INTF_NUM, /* bInterfaceNumber */
0x00, /* bAlternateSetting */
0x02, /* bNumEndpoints */
0x0A, /* bInterfaceClass: Communication class data */
0x00, /* bInterfaceSubClass */
0x00, /* bInterfaceProtocol */
0x00,
/*Union Functional Descriptor*/
0x05, /* bFunctionLength */
0x24, /* bDescriptorType: CS_INTERFACE */
0x06, /* bDescriptorSubtype: Union func desc */
/*!*/ CDC_INTF_NUM, /* bMasterInterface: Communication class interface */
/*!*/ CDC_INTF_NUM, /* bSlaveInterface0: Data Class Interface */
/*Endpoint OUT Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_OUT_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
LOBYTE(CDC_DATA_FS_MAX_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_DATA_FS_MAX_PACKET_SIZE),
0x00, /* bInterval: ignore for Bulk transfer */
/*Endpoint 2 Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_CMD_EP, /* bEndpointAddress */
0x03, /* bmAttributes: Interrupt */
LOBYTE(CDC_CMD_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_CMD_PACKET_SIZE),
0x10, /* bInterval: */
/*Endpoint IN Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_IN_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
LOBYTE(CDC_DATA_FS_MAX_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_DATA_FS_MAX_PACKET_SIZE),
0x00, /* bInterval: ignore for Bulk transfer */
/*Endpoint OUT Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_OUT_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
LOBYTE(CDC_DATA_FS_MAX_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_DATA_FS_MAX_PACKET_SIZE),
0x00, /* bInterval: ignore for Bulk transfer */
4, /* Descriptor size */
3, /* Descriptor type */
0x09,
0x04,
#endif
/*Endpoint IN Descriptor*/
0x07, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CDC_IN_EP, /* bEndpointAddress */
0x02, /* bmAttributes: Bulk */
LOBYTE(CDC_DATA_FS_MAX_PACKET_SIZE), /* wMaxPacketSize: */
HIBYTE(CDC_DATA_FS_MAX_PACKET_SIZE),
0x00, /* bInterval: ignore for Bulk transfer */
#ifdef ENABLE_CCID
/* CCID Interface Descriptor */
9, /* bLength: Interface Descriptor size */
USB_DESC_TYPE_INTERFACE, /* bDescriptorType: Interface */
CCID_INTF_NUM, /* bInterfaceNumber: CCID Interface */
0, /* Alternate setting for this interface */
3, /* bNumEndpoints: Bulk-IN, Bulk-OUT, Intr-IN */
0x0B, /* CCID class */
0x00, /* CCID subclass */
0x00, /* CCID protocol */
0, /* string index for interface */
/* ICC Descriptor */
54, /* bLength: */
0x21, /* bDescriptorType: USBDESCR_ICC */
0x10, 0x01, /* bcdCCID: revision 1.1 (of CCID) */
0, /* bMaxSlotIndex: */
1, /* bVoltageSupport: 5V-only */
0x02, 0, 0, 0, /* dwProtocols: T=1 */
0xa0, 0x0f, 0, 0, /* dwDefaultClock: 4000 */
0xa0, 0x0f, 0, 0, /* dwMaximumClock: 4000 */
0, /* bNumClockSupported: 0x00 */
0x80, 0x25, 0, 0, /* dwDataRate: 9600 */
0x80, 0x25, 0, 0, /* dwMaxDataRate: 9600 */
0, /* bNumDataRateSupported: 0x00 */
0xfe, 0, 0, 0, /* dwMaxIFSD: 254 */
0, 0, 0, 0, /* dwSynchProtocols: 0 */
0, 0, 0, 0, /* dwMechanical: 0 */
0x7a, 0x04, 0x02, 0x00, /* dwFeatures:
* Short and extended APDU level: 0x40000 ----
* Short APDU level : 0x20000 *
* (ICCD?) : 0x00800 ----
* Automatic IFSD : 0x00400 *
* NAD value other than 0x00 : 0x00200
* Can set ICC in clock stop : 0x00100
* Automatic PPS CUR : 0x00080
* Automatic PPS PROP : 0x00040 *
* Auto baud rate change : 0x00020 *
* Auto clock change : 0x00010 *
* Auto voltage selection : 0x00008 *
* Auto activaction of ICC : 0x00004
* Automatic conf. based on ATR : 0x00002 *
*/
0x0f, 0x01, 0, 0, /* dwMaxCCIDMessageLength: 271 */
0xff, /* bClassGetResponse: 0xff */
0x00, /* bClassEnvelope: 0 */
0, 0, /* wLCDLayout: 0 */
0, /* bPinSupport: No PIN pad */
1, /* bMaxCCIDBusySlots: 1 */
/*Endpoint IN1 Descriptor*/
7, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CCID_IN_EP, /* bEndpointAddress: (IN1) */
0x02, /* bmAttributes: Bulk */
CCID_DATA_PACKET_SIZE, 0x00, /* wMaxPacketSize: */
0x00, /* bInterval */
/*Endpoint OUT1 Descriptor*/
7, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CCID_OUT_EP, /* bEndpointAddress: (OUT1) */
0x02, /* bmAttributes: Bulk */
CCID_DATA_PACKET_SIZE, 0x00, /* wMaxPacketSize: */
0x00, /* bInterval */
/*Endpoint IN2 Descriptor*/
7, /* bLength: Endpoint Descriptor size */
USB_DESC_TYPE_ENDPOINT, /* bDescriptorType: Endpoint */
CCID_CMD_EP, /* bEndpointAddress: (IN2) */
0x03, /* bmAttributes: Interrupt */
CCID_DATA_PACKET_SIZE, 0x00, /* wMaxPacketSize: 4 */
0xFF, /* bInterval (255ms) */
#endif
};
};
USBD_ClassTypeDef USBD_Composite =
{
USBD_Composite_Init,
@ -189,32 +305,57 @@ USBD_ClassTypeDef USBD_Composite =
USBD_Composite_GetDeviceQualifierDescriptor,
};
static USBD_ClassTypeDef *USBD_Classes[MAX_CLASSES];
static USBD_ClassTypeDef * USBD_Classes[MAX_CLASSES];
int in_endpoint_to_class[MAX_ENDPOINTS];
int out_endpoint_to_class[MAX_ENDPOINTS];
void USBD_Composite_Set_Classes(USBD_ClassTypeDef *class0, USBD_ClassTypeDef *class1) {
USBD_Classes[0] = class0;
USBD_Classes[1] = class1;
void USBD_Composite_Set_Classes(USBD_ClassTypeDef *hid_class, USBD_ClassTypeDef *ccid_class, USBD_ClassTypeDef *cdc_class) {
memset(USBD_Classes, 0 , sizeof(USBD_Classes));
USBD_Classes[0] = hid_class;
#ifdef ENABLE_CCID
USBD_Classes[1] = ccid_class;
#endif
#if DEBUG_LEVEL > 0
USBD_Classes[2] = cdc_class;
#endif
}
static USBD_ClassTypeDef * getClass(uint8_t index)
{
switch(index)
{
case HID_INTF_NUM:
return USBD_Classes[0];
#ifdef ENABLE_CCID
case CCID_INTF_NUM:
return USBD_Classes[1];
#endif
#if DEBUG_LEVEL > 0
case CDC_MASTER_INTF_NUM:
case CDC_SLAVE_INTF_NUM:
return USBD_Classes[2];
#endif
}
return NULL;
}
static uint8_t USBD_Composite_Init (USBD_HandleTypeDef *pdev, uint8_t cfgidx) {
int i;
for(i = 0; i < NUM_INTERFACES; i++) {
if (USBD_Classes[i]->Init(pdev, cfgidx) != USBD_OK) {
for(i = 0; i < NUM_CLASSES; i++) {
if (USBD_Classes[i] != NULL && USBD_Classes[i]->Init(pdev, cfgidx) != USBD_OK) {
return USBD_FAIL;
}
}
//N
return USBD_OK;
}
static uint8_t USBD_Composite_DeInit (USBD_HandleTypeDef *pdev, uint8_t cfgidx) {
int i;
for(i = 0; i < NUM_INTERFACES; i++) {
if (USBD_Classes[i]->DeInit(pdev, cfgidx) != USBD_OK) {
for(i = 0; i < NUM_CLASSES; i++) {
if (USBD_Classes[i] != NULL && USBD_Classes[i]->DeInit(pdev, cfgidx) != USBD_OK) {
return USBD_FAIL;
}
}
@ -224,10 +365,13 @@ static uint8_t USBD_Composite_DeInit (USBD_HandleTypeDef *pdev, uint8_t cfgidx)
static uint8_t USBD_Composite_Setup (USBD_HandleTypeDef *pdev, USBD_SetupReqTypedef *req) {
int i;
USBD_ClassTypeDef * device_class;
device_class = getClass(req->wIndex);
switch (req->bmRequest & USB_REQ_TYPE_MASK) {
case USB_REQ_TYPE_CLASS :
if (req->wIndex < NUM_INTERFACES)
return USBD_Classes[req->wIndex]->Setup(pdev, req);
if (device_class != NULL)
return device_class->Setup(pdev, req);
else
return USBD_FAIL;
@ -236,8 +380,8 @@ static uint8_t USBD_Composite_Setup (USBD_HandleTypeDef *pdev, USBD_SetupReqType
switch (req->bRequest) {
case USB_REQ_GET_DESCRIPTOR :
for(i = 0; i < NUM_INTERFACES; i++) {
if (USBD_Classes[i]->Setup(pdev, req) != USBD_OK) {
for(i = 0; i < NUM_CLASSES; i++) {
if (USBD_Classes[i] != NULL && USBD_Classes[i]->Setup(pdev, req) != USBD_OK) {
return USBD_FAIL;
}
}
@ -246,8 +390,8 @@ static uint8_t USBD_Composite_Setup (USBD_HandleTypeDef *pdev, USBD_SetupReqType
case USB_REQ_GET_INTERFACE :
case USB_REQ_SET_INTERFACE :
if (req->wIndex < NUM_INTERFACES)
return USBD_Classes[req->wIndex]->Setup(pdev, req);
if (device_class != NULL)
return device_class->Setup(pdev, req);
else
return USBD_FAIL;
}
@ -260,6 +404,8 @@ static uint8_t USBD_Composite_DataIn (USBD_HandleTypeDef *pdev, uint8_t epnum) {
i = in_endpoint_to_class[epnum];
if (USBD_Classes[i] == NULL) return USBD_FAIL;
return USBD_Classes[i]->DataIn(pdev, epnum);
}
@ -268,14 +414,16 @@ static uint8_t USBD_Composite_DataOut (USBD_HandleTypeDef *pdev, uint8_t epnum)
i = out_endpoint_to_class[epnum];
if (USBD_Classes[i] == NULL) return USBD_FAIL;
return USBD_Classes[i]->DataOut(pdev, epnum);
}
static uint8_t USBD_Composite_EP0_RxReady (USBD_HandleTypeDef *pdev) {
int i;
for(i = 0; i < NUM_INTERFACES; i++) {
if (USBD_Classes[i]->EP0_RxReady != NULL) {
for(i = 0; i < NUM_CLASSES; i++) {
if (USBD_Classes[i] != NULL && USBD_Classes[i]->EP0_RxReady != NULL) {
if (USBD_Classes[i]->EP0_RxReady(pdev) != USBD_OK) {
return USBD_FAIL;
}
@ -285,16 +433,19 @@ static uint8_t USBD_Composite_EP0_RxReady (USBD_HandleTypeDef *pdev) {
}
static uint8_t *USBD_Composite_GetFSCfgDesc (uint16_t *length) {
//Y
*length = COMPOSITE_CDC_HID_DESCRIPTOR_SIZE;
return COMPOSITE_CDC_HID_DESCRIPTOR;
}
static uint8_t *USBD_Composite_GetHSCfgDesc (uint16_t *length) {
//N
*length = COMPOSITE_CDC_HID_DESCRIPTOR_SIZE;
return COMPOSITE_CDC_HID_DESCRIPTOR;
}
static uint8_t *USBD_Composite_GetOtherSpeedCfgDesc (uint16_t *length) {
*length = COMPOSITE_CDC_HID_DESCRIPTOR_SIZE;
return COMPOSITE_CDC_HID_DESCRIPTOR;
}
@ -315,6 +466,7 @@ __ALIGN_BEGIN static uint8_t USBD_Composite_DeviceQualifierDesc[USB_LEN_DEV_QUAL
};
uint8_t *USBD_Composite_GetDeviceQualifierDescriptor (uint16_t *length) {
*length = sizeof (USBD_Composite_DeviceQualifierDesc);
return USBD_Composite_DeviceQualifierDesc;
//N
*length = sizeof (USBD_Composite_DeviceQualifierDesc);
return USBD_Composite_DeviceQualifierDesc;
}

2
targets/stm32l432/lib/usbd/usbd_composite.h
View File

@ -17,7 +17,7 @@ extern int in_endpoint_to_class[MAX_ENDPOINTS];
extern int out_endpoint_to_class[MAX_ENDPOINTS];
void USBD_Composite_Set_Classes(USBD_ClassTypeDef *class0, USBD_ClassTypeDef *class1);
void USBD_Composite_Set_Classes(USBD_ClassTypeDef *class0, USBD_ClassTypeDef *class1, USBD_ClassTypeDef *class2);
#ifdef __cplusplus
}

28
targets/stm32l432/lib/usbd/usbd_conf.c
View File

@ -50,6 +50,9 @@
#include "stm32l4xx_hal.h"
#include "usbd_core.h"
#include "usbd_hid.h"
#include "usbd_cdc.h"
#include "usbd_ccid.h"
#include "log.h"
void SystemClock_Config(void);
@ -117,9 +120,14 @@ void HAL_PCD_DataOutStageCallback(PCD_HandleTypeDef *hpcd, uint8_t epnum)
USBD_LL_DataOutStage((USBD_HandleTypeDef*)hpcd->pData, epnum, hpcd->OUT_ep[epnum].xfer_buff);
switch(epnum)
{
case HID_ENDPOINT:
case HID_EPOUT_ADDR:
usb_hid_recieve_callback(epnum);
break;
#ifdef ENABLE_CCID
case CCID_OUT_EP:
usb_ccid_recieve_callback((USBD_HandleTypeDef*)hpcd->pData, epnum);
break;
#endif
}
}
@ -218,7 +226,6 @@ void HAL_PCD_DisconnectCallback(PCD_HandleTypeDef *hpcd)
{
USBD_LL_DevDisconnected((USBD_HandleTypeDef*)hpcd->pData);
}
/**
* @brief Initializes the low level portion of the device driver.
* @param pdev: Device handle
@ -252,14 +259,20 @@ USBD_StatusTypeDef USBD_LL_Init(USBD_HandleTypeDef *pdev)
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , 0x80 , PCD_SNG_BUF, 0x58);
// HID
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , 0x01 , PCD_SNG_BUF, 0x98);
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , 0x81 , PCD_SNG_BUF, 0xd8);
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , HID_EPOUT_ADDR , PCD_SNG_BUF, 0x98);
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , HID_EPIN_ADDR , PCD_SNG_BUF, 0xd8);
// CCID
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , CCID_OUT_EP , PCD_SNG_BUF, 0xd8 + 64); // data OUT
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , CCID_IN_EP , PCD_SNG_BUF, 0xd8 + 64*2); // data IN
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , CCID_CMD_EP , PCD_SNG_BUF, 0xd8 + 64*3); // commands
// CDC / uart
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , 0x02 , PCD_SNG_BUF, 0xd8 + 64); // data OUT
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , 0x82 , PCD_SNG_BUF, 0xd8 + 64*2); // data IN
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , 0x83 , PCD_SNG_BUF, 0xd8 + 64*3); // commands
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , CDC_CMD_EP , PCD_SNG_BUF, 0xd8 + 64*4); // commands
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , CDC_OUT_EP , PCD_SNG_BUF, 0xd8 + 64*5); // data OUT
HAL_PCDEx_PMAConfig((PCD_HandleTypeDef*)pdev->pData , CDC_IN_EP , PCD_SNG_BUF, 0xd8 + 64*6); // data IN
// dump_pma_header("usbd_conf");
return USBD_OK;
}
@ -310,6 +323,7 @@ USBD_StatusTypeDef USBD_LL_OpenEP(USBD_HandleTypeDef *pdev,
uint8_t ep_type,
uint16_t ep_mps)
{
// printf1(TAG_RED,"LL_Open. ep: %x, %x\r\n", ep_addr, ep_type);
HAL_PCD_EP_Open((PCD_HandleTypeDef*) pdev->pData,
ep_addr,
ep_mps,

13
targets/stm32l432/linker/bootloader_stm32l4xx.ld
View File

@ -12,9 +12,17 @@ _estack = 0x2000c000;
_MIN_STACK_SIZE = 0x400;
/*
flash_cfg is for storing bootloader data, like last used firmware version.
bootloader_configuration should be equal to (APPLICATION_END_PAGE) page address, from targets/stm32l432/src/memory_layout.h:30; and equal to flash_cfg origin
*/
bootloader_configuration = 0x08000000 + 216*1024+8;
MEMORY
{
flash (rx) : ORIGIN = 0x08000000, LENGTH = 20K
flash_cfg (rx) : ORIGIN = 0x08000000 + 216*1024+8, LENGTH = 2K-8
ram (xrw) : ORIGIN = 0x20000000, LENGTH = 48K
sram2 (rw) : ORIGIN = 0x10000000, LENGTH = 16K
}
@ -39,6 +47,11 @@ SECTIONS
_etext = .;
} >flash
.flag2 bootloader_configuration :
{
KEEP(*(.flag2)) ;
} > flash_cfg
_sidata = LOADADDR(.data);
.data :

13
targets/stm32l432/linker/bootloader_stm32l4xx_extra.ld
View File

@ -12,9 +12,17 @@ _estack = 0x2000c000;
_MIN_STACK_SIZE = 0x400;
/*
flash_cfg is for storing bootloader data, like last used firmware version.
bootloader_configuration should be equal to (APPLICATION_END_PAGE) page address, from targets/stm32l432/src/memory_layout.h:30; and equal to flash_cfg origin
*/
bootloader_configuration = 0x08000000 + 216*1024+8;
MEMORY
{
flash (rx) : ORIGIN = 0x08000000, LENGTH = 32K
flash_cfg (rx) : ORIGIN = 0x08000000 + 216*1024+8, LENGTH = 2K-8
ram (xrw) : ORIGIN = 0x20000000, LENGTH = 48K
sram2 (rw) : ORIGIN = 0x10000000, LENGTH = 16K
}
@ -39,6 +47,11 @@ SECTIONS
_etext = .;
} >flash
.flag2 bootloader_configuration :
{
KEEP(*(.flag2)) ;
} > flash_cfg
_sidata = LOADADDR(.data);
.data :

21
targets/stm32l432/linker/stm32l4xx.ld
View File

@ -13,14 +13,21 @@ _estack = 0x2000c000;
_MIN_STACK_SIZE = 0x400;
/*
Memory layout of device:
20 KB 198KB-8 38 KB
| bootloader | application | secrets/data |
len | 20 KB/10p| 196KB-8-8/98p | 2kB/1p | 38 KB/19p |
pos | 0->20 KB | 20->216KB-8-8 | 216kB -> 218 kB | 218->256 KB |
posp | 0-10 | 10-113 | 113-114 | 113-128 |
desc | bootloader | application | bootloader data | secrets/data |
Last 8 bytes in application space are occupied by bootloader flags - app
authorization and bootloader activation flag.
*/
/* Current firmware version number is concatenated to the firmware code - see .flag marker */
/* flash length is (APPLICATION_END_PAGE-20*1024), where 20K is bootloader */
MEMORY
{
flash (rx) : ORIGIN = 0x08005000, LENGTH = 198K - 8
flash (rx) : ORIGIN = 0x08000000 + 20K, LENGTH = 216K - 20K - 8
ram (xrw) : ORIGIN = 0x20000000, LENGTH = 48K
sram2 (rw) : ORIGIN = 0x10000000, LENGTH = 16K
}
@ -56,6 +63,12 @@ SECTIONS
_edata = .;
} >ram AT> flash
.flag :
{
. = ALIGN(8);
KEEP(*(.flag)) ;
} > flash
.bss :
{
. = ALIGN(4);

21
targets/stm32l432/linker/stm32l4xx_extra.ld
View File

@ -12,9 +12,22 @@ _estack = 0x2000c000;
_MIN_STACK_SIZE = 0x400;
/*
len | 32 KB/16p| 184KB-8-8/92p | 2kB/1p | 38 KB/19p |
pos | 0->32 KB | 32->216KB-8-8 | 216kB -> 218 kB | 218->256 KB |
posp | 0-16 | 16-113 | 113-114 | 113-128 |
desc | bootloader | application | bootloader data | secrets/data |
Last 8 bytes in application space are occupied by bootloader flags - app
authorization and bootloader activation flag.
*/
/* Current firmware version number is concatenated to the firmware code - see .flag marker */
/* flash length is (APPLICATION_END_PAGE-20*1024), where 20K is bootloader */
MEMORY
{
flash (rx) : ORIGIN = 0x08008000, LENGTH = 186K - 8
flash (rx) : ORIGIN = 0x08000000 + 20K + 12K, LENGTH = 216K - 20K - 12K - 8
ram (xrw) : ORIGIN = 0x20000000, LENGTH = 48K
sram2 (rw) : ORIGIN = 0x10000000, LENGTH = 16K
}
@ -50,6 +63,12 @@ SECTIONS
_edata = .;
} >ram AT> flash
.flag :
{
. = ALIGN(8);
KEEP(*(.flag)) ;
} > flash
.bss :
{
. = ALIGN(4);

14
targets/stm32l432/src/ams.c
View File

@ -8,21 +8,25 @@
#include "device.h"
#include "nfc.h"
static void flush_rx()
static void flush_rx(void)
{
while(LL_SPI_IsActiveFlag_RXNE(SPI1) != 0)
{
LL_SPI_ReceiveData8(SPI1);
}
}
static void wait_for_tx()
static void wait_for_tx(void)
{
// while (LL_SPI_IsActiveFlag_BSY(SPI1) == 1)
// ;
while(LL_SPI_GetTxFIFOLevel(SPI1) != LL_SPI_TX_FIFO_EMPTY)
;
}
static void wait_for_rx()
static void wait_for_rx(void)
{
while(LL_SPI_IsActiveFlag_RXNE(SPI1) == 0)
;
@ -270,7 +274,7 @@ void ams_print_int1(uint8_t int0)
#endif
}
int ams_init()
int ams_init(void)
{
LL_GPIO_SetPinMode(SOLO_AMS_CS_PORT,SOLO_AMS_CS_PIN,LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetOutputPin(SOLO_AMS_CS_PORT,SOLO_AMS_CS_PIN);
@ -292,7 +296,7 @@ int ams_init()
return 0;
}
void ams_configure()
void ams_configure(void)
{
// Should not be used during passive operation.
uint8_t block[4];

4
targets/stm32l432/src/ams.h
View File

@ -39,8 +39,8 @@ typedef union
#define SELECT() LL_GPIO_ResetOutputPin(SOLO_AMS_CS_PORT,SOLO_AMS_CS_PIN)
#define UNSELECT() LL_GPIO_SetOutputPin(SOLO_AMS_CS_PORT,SOLO_AMS_CS_PIN)
int ams_init();
void ams_configure();
int ams_init(void);
void ams_configure(void);
void ams_read_buffer(uint8_t * data, int len);
void ams_write_buffer(uint8_t * data, int len);

4
targets/stm32l432/src/app.h
View File

@ -12,9 +12,13 @@
#define DEBUG_UART USART1
#ifndef DEBUG_LEVEL
// Enable the CDC ACM USB interface & debug logs (DEBUG_LEVEL > 0)
#define DEBUG_LEVEL 0
#endif
// Enable the CCID USB interface
// #define ENABLE_CCID
#define NON_BLOCK_PRINTING 0

19
targets/stm32l432/src/crypto.c
View File

@ -61,12 +61,13 @@ static uint8_t master_secret[64];
static uint8_t transport_secret[32];
void crypto_sha256_init()
void crypto_sha256_init(void)
{
sha256_init(&sha256_ctx);
}
void crypto_sha512_init() {
void crypto_sha512_init(void)
{
cf_sha512_init(&sha512_ctx);
}
@ -79,7 +80,7 @@ void crypto_load_master_secret(uint8_t * key)
memmove(transport_secret, key+64, 32);
}
void crypto_reset_master_secret()
void crypto_reset_master_secret(void)
{
memset(master_secret, 0, 64);
memset(transport_secret, 0, 32);
@ -107,7 +108,8 @@ void crypto_sha256_final(uint8_t * hash)
sha256_final(&sha256_ctx, hash);
}
void crypto_sha512_final(uint8_t * hash) {
void crypto_sha512_final(uint8_t * hash)
{
// NB: there is also cf_sha512_digest
cf_sha512_digest_final(&sha512_ctx, hash);
}
@ -183,14 +185,14 @@ void crypto_sha256_hmac_final(uint8_t * key, uint32_t klen, uint8_t * hmac)
}
void crypto_ecc256_init()
void crypto_ecc256_init(void)
{
uECC_set_rng((uECC_RNG_Function)ctap_generate_rng);
_es256_curve = uECC_secp256r1();
}
void crypto_ecc256_load_attestation_key()
void crypto_ecc256_load_attestation_key(void)
{
static uint8_t _key [32];
memmove(_key, (uint8_t*)ATTESTATION_KEY_ADDR, 32);
@ -282,6 +284,11 @@ void crypto_ecc256_derive_public_key(uint8_t * data, int len, uint8_t * x, uint8
memmove(x,pubkey,32);
memmove(y,pubkey+32,32);
}
void crypto_ecc256_compute_public_key(uint8_t * privkey, uint8_t * pubkey)
{
uECC_compute_public_key(privkey, pubkey, _es256_curve);
}
void crypto_load_external_key(uint8_t * key, int len)
{

228
targets/stm32l432/src/device.c
View File

@ -34,37 +34,71 @@
#define LOW_FREQUENCY 1
#define HIGH_FREQUENCY 0
void wait_for_usb_tether();
void wait_for_usb_tether(void);
uint32_t __90_ms = 0;
uint32_t __last_button_press_time = 0;
uint32_t __last_button_bounce_time = 0;
uint32_t __device_status = 0;
uint32_t __last_update = 0;
extern PCD_HandleTypeDef hpcd;
static int _NFC_status = 0;
static bool isLowFreq = 0;
static bool _RequestComeFromNFC = false;
static bool _up_disabled = false;
// #define IS_BUTTON_PRESSED() (0 == (LL_GPIO_ReadInputPort(SOLO_BUTTON_PORT) & SOLO_BUTTON_PIN))
static int is_physical_button_pressed()
static int is_physical_button_pressed(void)
{
return (0 == (LL_GPIO_ReadInputPort(SOLO_BUTTON_PORT) & SOLO_BUTTON_PIN));
}
static int is_touch_button_pressed()
static int is_touch_button_pressed(void)
{
return tsc_read_button(0) || tsc_read_button(1);
int is_pressed = (tsc_read_button(0) || tsc_read_button(1));
#ifndef IS_BOOTLOADER
if (is_pressed)
{
// delay for debounce, and longer than polling timer period.
delay(95);
return (tsc_read_button(0) || tsc_read_button(1));
}
#endif
return is_pressed;
}
int (*IS_BUTTON_PRESSED)() = is_physical_button_pressed;
void request_from_nfc(bool request_active) {
_RequestComeFromNFC = request_active;
static void edge_detect_touch_button(void)
{
static uint8_t last_touch = 0;
uint8_t current_touch = 0;
if (is_touch_button_pressed == IS_BUTTON_PRESSED)
{
current_touch = (tsc_read_button(0) || tsc_read_button(1));
// 1 sample per 25 ms
if ((millis() - __last_button_bounce_time) > 25)
{
// Detect "touch / rising edge"
if (!last_touch && current_touch)
{
__last_button_press_time = millis();
}
__last_button_bounce_time = millis();
last_touch = current_touch;
}
}
}
void device_disable_up(bool disable)
{
_up_disabled = disable;
}
// Timer6 overflow handler. happens every ~90ms.
void TIM6_DAC_IRQHandler()
void TIM6_DAC_IRQHandler(void)
{
// timer is only 16 bits, so roll it over here
TIM6->SR = 0;
@ -76,6 +110,9 @@ void TIM6_DAC_IRQHandler()
ctaphid_update_status(__device_status);
}
}
edge_detect_touch_button();
#ifndef IS_BOOTLOADER
// NFC sending WTX if needs
if (device_is_nfc() == NFC_IS_ACTIVE)
@ -84,10 +121,20 @@ void TIM6_DAC_IRQHandler()
}
#endif
}
// Interrupt on rising edge of button (button released)
void EXTI0_IRQHandler(void)
{
EXTI->PR1 = EXTI->PR1;
__last_button_press_time = millis();
if (is_physical_button_pressed == IS_BUTTON_PRESSED)
{
// Only allow 1 press per 25 ms.
if ((millis() - __last_button_bounce_time) > 25)
{
__last_button_press_time = millis();
}
__last_button_bounce_time = millis();
}
}
// Global USB interrupt handler
@ -96,7 +143,7 @@ void USB_IRQHandler(void)
HAL_PCD_IRQHandler(&hpcd);
}
uint32_t millis()
uint32_t millis(void)
{
return (((uint32_t)TIM6->CNT) + (__90_ms * 90));
}
@ -114,9 +161,8 @@ void device_set_status(uint32_t status)
__device_status = status;
}
int device_is_button_pressed()
int device_is_button_pressed(void)
{
return IS_BUTTON_PRESSED();
}
@ -126,12 +172,13 @@ void delay(uint32_t ms)
while ((millis() - time) < ms)
;
}
void device_reboot()
void device_reboot(void)
{
NVIC_SystemReset();
}
void device_init_button()
void device_init_button(void)
{
if (tsc_sensor_exists())
{
@ -181,12 +228,12 @@ void device_init(int argc, char *argv[])
}
int device_is_nfc()
int device_is_nfc(void)
{
return _NFC_status;
}
void wait_for_usb_tether()
void wait_for_usb_tether(void)
{
while (USBD_OK != CDC_Transmit_FS((uint8_t*)"tethered\r\n", 10) )
;
@ -197,7 +244,7 @@ void wait_for_usb_tether()
;
}
void usbhid_init()
void usbhid_init(void)
{
if (!isLowFreq)
{
@ -247,12 +294,12 @@ void ctaphid_write_block(uint8_t * data)
}
void usbhid_close()
void usbhid_close(void)
{
}
void main_loop_delay()
void main_loop_delay(void)
{
}
@ -262,13 +309,14 @@ static uint32_t winkt1 = 0;
#ifdef LED_WINK_VALUE
static uint32_t winkt2 = 0;
#endif
void device_wink()
void device_wink(void)
{
wink_time = 10;
winkt1 = 0;
}
void heartbeat()
void heartbeat(void)
{
static int state = 0;
static uint32_t val = (LED_MAX_SCALER - LED_MIN_SCALER)/2;
@ -337,7 +385,7 @@ void authenticator_read_backup_state(AuthenticatorState * a)
}
// Return 1 yes backup is init'd, else 0
int authenticator_is_backup_initialized()
int authenticator_is_backup_initialized(void)
{
uint8_t header[16];
uint32_t * ptr = (uint32_t *)flash_addr(STATE2_PAGE);
@ -362,7 +410,8 @@ void authenticator_write_state(AuthenticatorState * a, int backup)
}
}
uint32_t ctap_atomic_count(int sel)
#if !defined(IS_BOOTLOADER)
uint32_t ctap_atomic_count(uint32_t amount)
{
int offset = 0;
uint32_t * ptr = (uint32_t *)flash_addr(COUNTER1_PAGE);
@ -377,10 +426,12 @@ uint32_t ctap_atomic_count(int sel)
uint32_t lastc = 0;
if (sel != 0)
if (amount == 0)
{
printf2(TAG_ERR,"counter2 not imple\n");
exit(1);
// Use a random count [1-16].
uint8_t rng[1];
ctap_generate_rng(rng, 1);
amount = (rng[0] & 0x0f) + 1;
}
for (offset = 0; offset < PAGE_SIZE/4; offset += 2) // wear-level the flash
@ -413,7 +464,7 @@ uint32_t ctap_atomic_count(int sel)
return lastc;
}
lastc++;
lastc += amount;
if (lastc/256 > erases)
{
@ -451,10 +502,10 @@ uint32_t ctap_atomic_count(int sel)
return lastc;
}
#endif
void device_manage()
void device_manage(void)
{
#if NON_BLOCK_PRINTING
int i = 10;
@ -480,7 +531,7 @@ void device_manage()
#endif
}
static int handle_packets()
static int handle_packets(void)
{
static uint8_t hidmsg[HID_PACKET_SIZE];
memset(hidmsg,0, sizeof(hidmsg));
@ -499,19 +550,56 @@ static int handle_packets()
return 0;
}
static int wait_for_button_activate(uint32_t wait)
{
int ret;
uint32_t start = millis();
do
{
if ((start + wait) < millis())
{
return 0;
}
delay(1);
ret = handle_packets();
if (ret)
return ret;
} while (!IS_BUTTON_PRESSED());
return 0;
}
static int wait_for_button_release(uint32_t wait)
{
int ret;
uint32_t start = millis();
do
{
if ((start + wait) < millis())
{
return 0;
}
delay(1);
ret = handle_packets();
if (ret)
return ret;
} while (IS_BUTTON_PRESSED());
return 0;
}
int ctap_user_presence_test(uint32_t up_delay)
{
int ret;
if (device_is_nfc() == NFC_IS_ACTIVE || _RequestComeFromNFC)
if (device_is_nfc() == NFC_IS_ACTIVE)
{
return 1;
}
// "cache" button presses for 2 seconds.
if (millis() - __last_button_press_time < 2000)
if (_up_disabled)
{
__last_button_press_time = 0;
return 1;
return 2;
}
#if SKIP_BUTTON_CHECK_WITH_DELAY
int i=500;
while(i--)
@ -524,53 +612,41 @@ int ctap_user_presence_test(uint32_t up_delay)
#elif SKIP_BUTTON_CHECK_FAST
delay(2);
ret = handle_packets();
if (ret) return ret;
if (ret)
return ret;
goto done;
#endif
uint32_t t1 = millis();
// If button was pressed within last [2] seconds, succeed.
if (__last_button_press_time && (millis() - __last_button_press_time < 2000))
{
goto done;
}
// Set LED status and wait.
led_rgb(0xff3520);
if (IS_BUTTON_PRESSED == is_touch_button_pressed)
{
// Wait for user to release touch button if it's already pressed
while (IS_BUTTON_PRESSED())
{
if (t1 + up_delay < millis())
{
printf1(TAG_GEN,"Button not pressed\n");
goto fail;
}
ret = handle_packets();
if (ret) return ret;
}
}
t1 = millis();
do
{
if (t1 + up_delay < millis())
{
goto fail;
}
delay(1);
ret = handle_packets();
// Block and wait for some time.
ret = wait_for_button_activate(up_delay);
if (ret) return ret;
ret = wait_for_button_release(up_delay);
if (ret) return ret;
}
while (! IS_BUTTON_PRESSED());
led_rgb(0x001040);
delay(50);
// If button was pressed within last [2] seconds, succeed.
if (__last_button_press_time && (millis() - __last_button_press_time < 2000))
{
goto done;
}
return 0;
#if SKIP_BUTTON_CHECK_WITH_DELAY || SKIP_BUTTON_CHECK_FAST
done:
#endif
return 1;
ret = wait_for_button_release(up_delay);
__last_button_press_time = 0;
return 1;
fail:
return 0;
}
int ctap_generate_rng(uint8_t * dst, size_t num)
@ -585,7 +661,7 @@ int ctap_user_verification(uint8_t arg)
return 1;
}
void ctap_reset_rk()
void ctap_reset_rk(void)
{
int i;
printf1(TAG_GREEN, "resetting RK \r\n");
@ -595,7 +671,7 @@ void ctap_reset_rk()
}
}
uint32_t ctap_rk_size()
uint32_t ctap_rk_size(void)
{
return RK_NUM_PAGES * (PAGE_SIZE / sizeof(CTAP_residentKey));
}
@ -657,7 +733,7 @@ void ctap_overwrite_rk(int index,CTAP_residentKey * rk)
}
}
void boot_st_bootloader()
void boot_st_bootloader(void)
{
__disable_irq();
@ -669,7 +745,7 @@ void boot_st_bootloader()
;
}
void boot_solo_bootloader()
void boot_solo_bootloader(void)
{
LL_IWDG_Enable(IWDG);

4
targets/stm32l432/src/flash.c
View File

@ -14,12 +14,12 @@
#include "log.h"
#include "device.h"
static void flash_lock()
static void flash_lock(void)
{
FLASH->CR |= (1U<<31);
}
static void flash_unlock()
static void flash_unlock(void)
{
if (FLASH->CR & FLASH_CR_LOCK)
{

21
targets/stm32l432/src/init.c
View File

@ -28,6 +28,7 @@
#include "usbd_desc.h"
#include "usbd_hid.h"
#include "usbd_cdc.h"
#include "usbd_ccid.h"
#include "usbd_composite.h"
#include "usbd_cdc_if.h"
#include "device.h"
@ -698,33 +699,33 @@ void SystemClock_Config_LF20(void)
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_PWREN);
}
void init_usb()
void init_usb(void)
{
// enable USB power
SET_BIT(PWR->CR2, PWR_CR2_USV);
// Enable USB Clock
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USBFSEN);
#if DEBUG_LEVEL > 0
USBD_Composite_Set_Classes(&USBD_HID, &USBD_CDC);
#ifndef IS_BOOTLOADER
USBD_Composite_Set_Classes(&USBD_HID, &USBD_CCID, &USBD_CDC);
in_endpoint_to_class[HID_EPIN_ADDR & 0x7F] = 0;
out_endpoint_to_class[HID_EPOUT_ADDR & 0x7F] = 0;
in_endpoint_to_class[CDC_IN_EP & 0x7F] = 1;
out_endpoint_to_class[CDC_OUT_EP & 0x7F] = 1;
in_endpoint_to_class[CCID_IN_EP & 0x7F] = 1;
out_endpoint_to_class[CCID_OUT_EP & 0x7F] = 1;
in_endpoint_to_class[CDC_IN_EP & 0x7F] = 2;
out_endpoint_to_class[CDC_OUT_EP & 0x7F] = 2;
USBD_Init(&Solo_USBD_Device, &Solo_Desc, 0);
USBD_RegisterClass(&Solo_USBD_Device, &USBD_Composite);
// USBD_RegisterClass(&Solo_USBD_Device, &USBD_HID);
//
// USBD_RegisterClass(&Solo_USBD_Device, &USBD_CDC);
#if DEBUG_LEVEL > 0
USBD_CDC_RegisterInterface(&Solo_USBD_Device, &USBD_Interface_fops_FS);
#endif
#else
USBD_Init(&Solo_USBD_Device, &Solo_Desc, 0);
USBD_RegisterClass(&Solo_USBD_Device, &USBD_HID);
#endif
USBD_Start(&Solo_USBD_Device);
}

2
targets/stm32l432/src/init.h
View File

@ -22,7 +22,7 @@
#ifndef _INIT_H_
#define _INIT_H_
void init_usb();
void init_usb(void);
void init_gpio(void);
void init_debug_uart(void);
void init_pwm(void);

3
targets/stm32l432/src/main.c
View File

@ -57,10 +57,11 @@ void TIM6_DAC_IRQHandler()
__90_ms += 1;
}
uint32_t millis()
uint32_t millis(void)
{
return (((uint32_t)TIM6->CNT) + (__90_ms * 90));
}
void _Error_Handler(char *file, int line)
{
while(1)

25
targets/stm32l432/src/memory_layout.h
View File

@ -37,10 +37,33 @@
// End of application code. Leave some extra room for future data storage.
// NOT included in application
#define APPLICATION_END_PAGE ((PAGES - 19))
#define APPLICATION_END_PAGE ((PAGES - 20))
#define APPLICATION_END_ADDR ((0x08000000 + ((APPLICATION_END_PAGE)*PAGE_SIZE))-8)
// Bootloader state.
#define AUTH_WORD_ADDR (APPLICATION_END_ADDR)
#define LAST_ADDR (APPLICATION_END_ADDR-2048 + 8)
#define BOOT_VERSION_PAGE (APPLICATION_END_PAGE)
#define BOOT_VERSION_ADDR (0x08000000 + BOOT_VERSION_PAGE*FLASH_PAGE_SIZE + 8)
#define LAST_PAGE (APPLICATION_END_PAGE-1)
struct flash_memory_st{
uint8_t bootloader[APPLICATION_START_PAGE*2*1024];
uint8_t application[(APPLICATION_END_PAGE-APPLICATION_START_PAGE)*2*1024-8];
uint8_t auth_word[4];
uint8_t bootloader_disabled[4];
// place for more user data
uint8_t _reserved_application_end_mark[8];
uint8_t bootloader_data[2*1024-8];
uint8_t user_data[38*1024];
} __attribute__((packed));
typedef struct flash_memory_st flash_memory_st;
#include <assert.h>
static_assert(sizeof(flash_memory_st) == 256*1024, "Data structure doesn't match flash size");
#endif

369
targets/stm32l432/src/nfc.c
View File

@ -14,6 +14,23 @@
#define IS_IRQ_ACTIVE() (1 == (LL_GPIO_ReadInputPort(SOLO_AMS_IRQ_PORT) & SOLO_AMS_IRQ_PIN))
// chain buffer for 61XX responses
static uint8_t chain_buffer[2048] = {0};
static size_t chain_buffer_len = 0;
static bool chain_buffer_tx = false;
static uint8_t current_cid = 0;
// forward declarations
void rblock_acknowledge(uint8_t req0, bool ack);
uint8_t p14443_have_cid(uint8_t pcb) {
// CID
if (pcb & 0x08)
return true;
else
return false;
}
uint8_t p14443_block_offset(uint8_t pcb) {
uint8_t offset = 1;
// NAD following
@ -92,19 +109,27 @@ int nfc_init()
return NFC_IS_NA;
}
static uint8_t gl_int0 = 0;
void process_int0(uint8_t int0)
{
gl_int0 = int0;
}
bool ams_wait_for_tx(uint32_t timeout_ms)
{
if (gl_int0 & AMS_INT_TXE) {
uint8_t int0 = ams_read_reg(AMS_REG_INT0);
process_int0(int0);
return true;
}
uint32_t tstart = millis();
while (tstart + timeout_ms > millis())
{
uint8_t int0 = ams_read_reg(AMS_REG_INT0);
if (int0) process_int0(int0);
if (int0 & AMS_INT_TXE)
process_int0(int0);
if (int0 & AMS_INT_TXE || int0 & AMS_INT_RXE)
return true;
delay(1);
@ -121,8 +146,13 @@ bool ams_receive_with_timeout(uint32_t timeout_ms, uint8_t * data, int maxlen, i
uint32_t tstart = millis();
while (tstart + timeout_ms > millis())
{
uint8_t int0 = ams_read_reg(AMS_REG_INT0);
if (int0) process_int0(int0);
uint8_t int0 = 0;
if (gl_int0 & AMS_INT_RXE) {
int0 = gl_int0;
} else {
int0 = ams_read_reg(AMS_REG_INT0);
process_int0(int0);
}
uint8_t buffer_status2 = ams_read_reg(AMS_REG_BUF2);
if (buffer_status2 && (int0 & AMS_INT_RXE))
@ -173,7 +203,7 @@ bool nfc_write_response_ex(uint8_t req0, uint8_t * data, uint8_t len, uint16_t r
return false;
res[0] = NFC_CMD_IBLOCK | (req0 & 0x0f);
res[1] = 0;
res[1] = current_cid;
res[2] = 0;
uint8_t block_offset = p14443_block_offset(req0);
@ -183,7 +213,14 @@ bool nfc_write_response_ex(uint8_t req0, uint8_t * data, uint8_t len, uint16_t r
res[len + block_offset + 0] = resp >> 8;
res[len + block_offset + 1] = resp & 0xff;
nfc_write_frame(res, block_offset + len + 2);
if (!ams_wait_for_tx(1))
{
printf1(TAG_NFC, "TX resp timeout. len: %d \r\n", len);
return false;
}
return true;
}
@ -193,10 +230,9 @@ bool nfc_write_response(uint8_t req0, uint16_t resp)
return nfc_write_response_ex(req0, NULL, 0, resp);
}
void nfc_write_response_chaining(uint8_t req0, uint8_t * data, int len)
void nfc_write_response_chaining_plain(uint8_t req0, uint8_t * data, int len)
{
uint8_t res[32 + 2];
int sendlen = 0;
uint8_t iBlock = NFC_CMD_IBLOCK | (req0 & 0x0f);
uint8_t block_offset = p14443_block_offset(req0);
@ -204,15 +240,18 @@ void nfc_write_response_chaining(uint8_t req0, uint8_t * data, int len)
{
uint8_t res[32] = {0};
res[0] = iBlock;
res[1] = current_cid;
res[2] = 0;
if (len && data)
memcpy(&res[block_offset], data, len);
nfc_write_frame(res, len + block_offset);
} else {
int sendlen = 0;
do {
// transmit I block
int vlen = MIN(32 - block_offset, len - sendlen);
res[0] = iBlock;
res[1] = 0;
res[1] = current_cid;
res[2] = 0;
memcpy(&res[block_offset], &data[sendlen], vlen);
@ -227,11 +266,11 @@ void nfc_write_response_chaining(uint8_t req0, uint8_t * data, int len)
sendlen += vlen;
// wait for transmit (32 bytes aprox 2,5ms)
// if (!ams_wait_for_tx(10))
// {
// printf1(TAG_NFC, "TX timeout. slen: %d \r\n", sendlen);
// break;
// }
if (!ams_wait_for_tx(5))
{
printf1(TAG_NFC, "TX timeout. slen: %d \r\n", sendlen);
break;
}
// if needs to receive R block (not a last block)
if (res[0] & 0x10)
@ -243,6 +282,20 @@ void nfc_write_response_chaining(uint8_t req0, uint8_t * data, int len)
printf1(TAG_NFC, "R block RX timeout %d/%d.\r\n",sendlen,len);
break;
}
if (!IS_RBLOCK(recbuf[0]))
{
printf1(TAG_NFC, "R block RX error. Not a R block(0x%02x) %d/%d.\r\n", recbuf[0], sendlen, len);
break;
}
// NAK check
if (recbuf[0] & NFC_CMD_RBLOCK_ACK)
{
rblock_acknowledge(recbuf[0], true);
printf1(TAG_NFC, "R block RX error. NAK received. %d/%d.\r\n", recbuf[0], sendlen, len);
break;
}
uint8_t rblock_offset = p14443_block_offset(recbuf[0]);
if (reclen != rblock_offset)
@ -264,6 +317,38 @@ void nfc_write_response_chaining(uint8_t req0, uint8_t * data, int len)
}
}
void append_get_response(uint8_t *data, size_t rest_len)
{
data[0] = 0x61;
data[1] = 0x00;
if (rest_len <= 0xff)
data[1] = rest_len & 0xff;
}
void nfc_write_response_chaining(uint8_t req0, uint8_t * data, int len, bool extapdu)
{
chain_buffer_len = 0;
chain_buffer_tx = true;
// if we dont need to break data to parts that need to exchange via GET RESPONSE command (ISO 7816-4 7.1.3)
if (len <= 255 || extapdu)
{
nfc_write_response_chaining_plain(req0, data, len);
} else {
size_t pcklen = MIN(253, len);
chain_buffer_len = len - pcklen;
printf1(TAG_NFC, "61XX chaining %d/%d.\r\n", pcklen, chain_buffer_len);
memmove(chain_buffer, data, pcklen);
append_get_response(&chain_buffer[pcklen], chain_buffer_len);
nfc_write_response_chaining_plain(req0, chain_buffer, pcklen + 2); // 2 for 61XX
// put the rest data into chain buffer
memmove(chain_buffer, &data[pcklen], chain_buffer_len);
}
}
// WTX on/off:
// sends/receives WTX frame to reader every `WTX_time` time in ms
// works via timer interrupts
@ -274,7 +359,7 @@ static uint32_t WTX_timer;
bool WTX_process(int read_timeout);
void WTX_clear()
void WTX_clear(void)
{
WTX_sent = false;
WTX_fail = false;
@ -289,7 +374,7 @@ bool WTX_on(int WTX_time)
return true;
}
bool WTX_off()
bool WTX_off(void)
{
WTX_timer = 0;
@ -313,10 +398,10 @@ bool WTX_off()
return true;
}
void WTX_timer_exec()
void WTX_timer_exec(void)
{
// condition: (timer on) or (not expired[300ms])
if ((WTX_timer <= 0) || WTX_timer + 300 > millis())
if ((WTX_timer == 0) || WTX_timer + 300 > millis())
return;
WTX_process(10);
@ -327,12 +412,12 @@ void WTX_timer_exec()
// read timeout must be 10 ms to call from interrupt
bool WTX_process(int read_timeout)
{
uint8_t wtx[] = {0xf2, 0x01};
if (WTX_fail)
return false;
if (!WTX_sent)
{
uint8_t wtx[] = {0xf2, 0x01};
nfc_write_frame(wtx, sizeof(wtx));
WTX_sent = true;
return true;
@ -409,7 +494,9 @@ void rblock_acknowledge(uint8_t req0, bool ack)
NFC_STATE.block_num = !NFC_STATE.block_num;
buf[0] = NFC_CMD_RBLOCK | (req0 & 0x0f);
if (ack)
buf[1] = current_cid;
// iso14443-4:2001 page 16. ACK, if bit is set to 0, NAK, if bit is set to 1
if (!ack)
buf[0] |= NFC_CMD_RBLOCK_ACK;
nfc_write_frame(buf, block_offset);
@ -463,37 +550,70 @@ int select_applet(uint8_t * aid, int len)
return APP_NOTHING;
}
void nfc_process_iblock(uint8_t * buf, int len)
void apdu_process(uint8_t buf0, uint8_t *apduptr, APDU_STRUCT *apdu)
{
int selected;
CTAP_RESPONSE ctap_resp;
int status;
uint16_t reslen;
printf1(TAG_NFC,"Iblock: ");
dump_hex1(TAG_NFC, buf, len);
uint8_t block_offset = p14443_block_offset(buf[0]);
APDU_STRUCT apdu;
if (apdu_decode(buf + block_offset, len - block_offset, &apdu)) {
printf1(TAG_NFC,"apdu decode error\r\n");
nfc_write_response(buf[0], SW_COND_USE_NOT_SATISFIED);
return;
}
printf1(TAG_NFC,"apdu ok. %scase=%02x cla=%02x ins=%02x p1=%02x p2=%02x lc=%d le=%d\r\n",
apdu.extended_apdu ? "[e]":"", apdu.case_type, apdu.cla, apdu.ins, apdu.p1, apdu.p2, apdu.lc, apdu.le);
// check CLA
if (apdu.cla != 0x00 && apdu.cla != 0x80) {
printf1(TAG_NFC, "Unknown CLA %02x\r\n", apdu.cla);
nfc_write_response(buf[0], SW_CLA_INVALID);
if (apdu->cla != 0x00 && apdu->cla != 0x80) {
printf1(TAG_NFC, "Unknown CLA %02x\r\n", apdu->cla);
nfc_write_response(buf0, SW_CLA_INVALID);
return;
}
// TODO this needs to be organized better
switch(apdu.ins)
switch(apdu->ins)
{
// ISO 7816. 7.1 GET RESPONSE command
case APDU_GET_RESPONSE:
if (apdu->p1 != 0x00 || apdu->p2 != 0x00)
{
nfc_write_response(buf0, SW_INCORRECT_P1P2);
printf1(TAG_NFC, "P1 or P2 error\r\n");
return;
}
// too many bytes needs. 0x00 and 0x100 - any length
if (apdu->le != 0 && apdu->le != 0x100 && apdu->le > chain_buffer_len)
{
uint16_t wlresp = SW_WRONG_LENGTH; // here can be 6700, 6C00, 6FXX. but the most standard way - 67XX or 6700
if (chain_buffer_len <= 0xff)
wlresp += chain_buffer_len & 0xff;
nfc_write_response(buf0, wlresp);
printf1(TAG_NFC, "buffer length less than requesteds\r\n");
return;
}
// create temporary packet
uint8_t pck[255] = {0};
size_t pcklen = 253;
if (apdu->le)
pcklen = apdu->le;
if (pcklen > chain_buffer_len)
pcklen = chain_buffer_len;
printf1(TAG_NFC, "GET RESPONSE. pck len: %d buffer len: %d\r\n", pcklen, chain_buffer_len);
// create packet and add 61XX there if we have another portion(s) of data
memmove(pck, chain_buffer, pcklen);
size_t dlen = 0;
if (chain_buffer_len - pcklen)
{
append_get_response(&pck[pcklen], chain_buffer_len - pcklen);
dlen = 2;
}
// send
nfc_write_response_chaining_plain(buf0, pck, pcklen + dlen); // dlen for 61XX
// shift the buffer
chain_buffer_len -= pcklen;
memmove(chain_buffer, &chain_buffer[pcklen], chain_buffer_len);
break;
case APDU_INS_SELECT:
// if (apdu->p1 == 0 && apdu->p2 == 0x0c)
// {
@ -509,49 +629,49 @@ void nfc_process_iblock(uint8_t * buf, int len)
// }
// else
{
selected = select_applet(apdu.data, apdu.lc);
selected = select_applet(apdu->data, apdu->lc);
if (selected == APP_FIDO)
{
nfc_write_response_ex(buf[0], (uint8_t *)"U2F_V2", 6, SW_SUCCESS);
nfc_write_response_ex(buf0, (uint8_t *)"U2F_V2", 6, SW_SUCCESS);
printf1(TAG_NFC, "FIDO applet selected.\r\n");
}
else if (selected != APP_NOTHING)
{
nfc_write_response(buf[0], SW_SUCCESS);
nfc_write_response(buf0, SW_SUCCESS);
printf1(TAG_NFC, "SELECTED %d\r\n", selected);
}
else
{
nfc_write_response(buf[0], SW_FILE_NOT_FOUND);
printf1(TAG_NFC, "NOT selected "); dump_hex1(TAG_NFC, apdu.data, apdu.lc);
nfc_write_response(buf0, SW_FILE_NOT_FOUND);
printf1(TAG_NFC, "NOT selected "); dump_hex1(TAG_NFC, apdu->data, apdu->lc);
}
}
break;
case APDU_FIDO_U2F_VERSION:
if (NFC_STATE.selected_applet != APP_FIDO) {
nfc_write_response(buf[0], SW_INS_INVALID);
nfc_write_response(buf0, SW_INS_INVALID);
break;
}
printf1(TAG_NFC, "U2F GetVersion command.\r\n");
u2f_request_nfc(&buf[block_offset], apdu.data, apdu.lc, &ctap_resp);
nfc_write_response_chaining(buf[0], ctap_resp.data, ctap_resp.length);
u2f_request_nfc(apduptr, apdu->data, apdu->lc, &ctap_resp);
nfc_write_response_chaining(buf0, ctap_resp.data, ctap_resp.length, apdu->extended_apdu);
break;
case APDU_FIDO_U2F_REGISTER:
if (NFC_STATE.selected_applet != APP_FIDO) {
nfc_write_response(buf[0], SW_INS_INVALID);
nfc_write_response(buf0, SW_INS_INVALID);
break;
}
printf1(TAG_NFC, "U2F Register command.\r\n");
if (apdu.lc != 64)
if (apdu->lc != 64)
{
printf1(TAG_NFC, "U2F Register request length error. len=%d.\r\n", apdu.lc);
nfc_write_response(buf[0], SW_WRONG_LENGTH);
printf1(TAG_NFC, "U2F Register request length error. len=%d.\r\n", apdu->lc);
nfc_write_response(buf0, SW_WRONG_LENGTH);
return;
}
@ -562,63 +682,63 @@ void nfc_process_iblock(uint8_t * buf, int len)
// SystemClock_Config_LF32();
// delay(300);
if (device_is_nfc() == NFC_IS_ACTIVE) device_set_clock_rate(DEVICE_LOW_POWER_FAST);
u2f_request_nfc(&buf[block_offset], apdu.data, apdu.lc, &ctap_resp);
u2f_request_nfc(apduptr, apdu->data, apdu->lc, &ctap_resp);
if (device_is_nfc() == NFC_IS_ACTIVE) device_set_clock_rate(DEVICE_LOW_POWER_IDLE);
// if (!WTX_off())
// return;
printf1(TAG_NFC, "U2F resp len: %d\r\n", ctap_resp.length);
printf1(TAG_NFC,"U2F Register P2 took %d\r\n", timestamp());
nfc_write_response_chaining(buf[0], ctap_resp.data, ctap_resp.length);
nfc_write_response_chaining(buf0, ctap_resp.data, ctap_resp.length, apdu->extended_apdu);
printf1(TAG_NFC,"U2F Register answered %d (took %d)\r\n", millis(), timestamp());
break;
case APDU_FIDO_U2F_AUTHENTICATE:
if (NFC_STATE.selected_applet != APP_FIDO) {
nfc_write_response(buf[0], SW_INS_INVALID);
nfc_write_response(buf0, SW_INS_INVALID);
break;
}
printf1(TAG_NFC, "U2F Authenticate command.\r\n");
if (apdu.lc != 64 + 1 + apdu.data[64])
if (apdu->lc != 64 + 1 + apdu->data[64])
{
delay(5);
printf1(TAG_NFC, "U2F Authenticate request length error. len=%d keyhlen=%d.\r\n", apdu.lc, apdu.data[64]);
nfc_write_response(buf[0], SW_WRONG_LENGTH);
printf1(TAG_NFC, "U2F Authenticate request length error. len=%d keyhlen=%d.\r\n", apdu->lc, apdu->data[64]);
nfc_write_response(buf0, SW_WRONG_LENGTH);
return;
}
timestamp();
// WTX_on(WTX_TIME_DEFAULT);
u2f_request_nfc(&buf[block_offset], apdu.data, apdu.lc, &ctap_resp);
u2f_request_nfc(apduptr, apdu->data, apdu->lc, &ctap_resp);
// if (!WTX_off())
// return;
printf1(TAG_NFC, "U2F resp len: %d\r\n", ctap_resp.length);
printf1(TAG_NFC,"U2F Authenticate processing %d (took %d)\r\n", millis(), timestamp());
nfc_write_response_chaining(buf[0], ctap_resp.data, ctap_resp.length);
nfc_write_response_chaining(buf0, ctap_resp.data, ctap_resp.length, apdu->extended_apdu);
printf1(TAG_NFC,"U2F Authenticate answered %d (took %d)\r\n", millis(), timestamp);
break;
case APDU_FIDO_NFCCTAP_MSG:
if (NFC_STATE.selected_applet != APP_FIDO) {
nfc_write_response(buf[0], SW_INS_INVALID);
nfc_write_response(buf0, SW_INS_INVALID);
return;
}
printf1(TAG_NFC, "FIDO2 CTAP message. %d\r\n", timestamp());
WTX_on(WTX_TIME_DEFAULT);
request_from_nfc(true);
// WTX_on(WTX_TIME_DEFAULT);
device_disable_up(true);
ctap_response_init(&ctap_resp);
status = ctap_request(apdu.data, apdu.lc, &ctap_resp);
request_from_nfc(false);
if (!WTX_off())
return;
status = ctap_request(apdu->data, apdu->lc, &ctap_resp);
device_disable_up(false);
// if (!WTX_off())
// return;
printf1(TAG_NFC, "CTAP resp: 0x%02<EFBFBD> len: %d\r\n", status, ctap_resp.length);
printf1(TAG_NFC, "CTAP resp: 0x%02x len: %d\r\n", status, ctap_resp.length);
if (status == CTAP1_ERR_SUCCESS)
{
@ -632,48 +752,111 @@ void nfc_process_iblock(uint8_t * buf, int len)
ctap_resp.data[ctap_resp.length - 1] = SW_SUCCESS & 0xff;
printf1(TAG_NFC,"CTAP processing %d (took %d)\r\n", millis(), timestamp());
nfc_write_response_chaining(buf[0], ctap_resp.data, ctap_resp.length);
nfc_write_response_chaining(buf0, ctap_resp.data, ctap_resp.length, apdu->extended_apdu);
printf1(TAG_NFC,"CTAP answered %d (took %d)\r\n", millis(), timestamp());
break;
case APDU_INS_READ_BINARY:
// response length
reslen = apdu.le & 0xffff;
reslen = apdu->le & 0xffff;
switch(NFC_STATE.selected_applet)
{
case APP_CAPABILITY_CONTAINER:
printf1(TAG_NFC,"APP_CAPABILITY_CONTAINER\r\n");
if (reslen == 0 || reslen > sizeof(NFC_CC))
reslen = sizeof(NFC_CC);
nfc_write_response_ex(buf[0], (uint8_t *)&NFC_CC, reslen, SW_SUCCESS);
nfc_write_response_ex(buf0, (uint8_t *)&NFC_CC, reslen, SW_SUCCESS);
ams_wait_for_tx(10);
break;
case APP_NDEF_TAG:
printf1(TAG_NFC,"APP_NDEF_TAG\r\n");
if (reslen == 0 || reslen > sizeof(NDEF_SAMPLE) - 1)
reslen = sizeof(NDEF_SAMPLE) - 1;
nfc_write_response_ex(buf[0], NDEF_SAMPLE, reslen, SW_SUCCESS);
nfc_write_response_ex(buf0, NDEF_SAMPLE, reslen, SW_SUCCESS);
ams_wait_for_tx(10);
break;
default:
nfc_write_response(buf[0], SW_FILE_NOT_FOUND);
nfc_write_response(buf0, SW_FILE_NOT_FOUND);
printf1(TAG_ERR, "No binary applet selected!\r\n");
return;
break;
}
break;
case APDU_SOLO_RESET:
if (apdu->lc == 4 && !memcmp(apdu->data, "\x12\x56\xab\xf0", 4)) {
printf1(TAG_NFC, "Reset...\r\n");
nfc_write_response(buf0, SW_SUCCESS);
delay(20);
device_reboot();
while(1);
} else {
printf1(TAG_NFC, "Reset FAIL\r\n");
nfc_write_response(buf0, SW_INS_INVALID);
}
break;
default:
printf1(TAG_NFC, "Unknown INS %02x\r\n", apdu.ins);
nfc_write_response(buf[0], SW_INS_INVALID);
printf1(TAG_NFC, "Unknown INS %02x\r\n", apdu->ins);
nfc_write_response(buf0, SW_INS_INVALID);
break;
}
}
void nfc_process_iblock(uint8_t * buf, int len)
{
uint8_t block_offset = p14443_block_offset(buf[0]);
// clear tx chain buffer if we have some other command than GET RESPONSE
if (chain_buffer_tx && buf[block_offset + 1] != APDU_GET_RESPONSE) {
chain_buffer_len = 0;
chain_buffer_tx = false;
}
APDU_STRUCT apdu;
uint16_t ret = apdu_decode(buf + block_offset, len - block_offset, &apdu);
if (ret != 0) {
printf1(TAG_NFC,"apdu decode error\r\n");
nfc_write_response(buf[0], ret);
return;
}
printf1(TAG_NFC,"apdu ok. %scase=%02x cla=%02x ins=%02x p1=%02x p2=%02x lc=%d le=%d\r\n",
apdu.extended_apdu ? "[e]":"", apdu.case_type, apdu.cla, apdu.ins, apdu.p1, apdu.p2, apdu.lc, apdu.le);
// APDU level chaining. ISO7816-4, 5.1.1. class byte
if (!chain_buffer_tx && buf[block_offset] & 0x10) {
if (chain_buffer_len + len > sizeof(chain_buffer)) {
nfc_write_response(buf[0], SW_WRONG_LENGTH);
return;
}
memmove(&chain_buffer[chain_buffer_len], apdu.data, apdu.lc);
chain_buffer_len += apdu.lc;
nfc_write_response(buf[0], SW_SUCCESS);
printf1(TAG_NFC, "APDU chaining ok. %d/%d\r\n", apdu.lc, chain_buffer_len);
return;
}
// if we have ISO 7816 APDU chain - move there all the data
if (!chain_buffer_tx && chain_buffer_len > 0) {
memmove(&apdu.data[chain_buffer_len], apdu.data, apdu.lc);
memmove(apdu.data, chain_buffer, chain_buffer_len);
apdu.lc += chain_buffer_len; // here apdu struct does not match with memory!
printf1(TAG_NFC, "APDU chaining merge. %d/%d\r\n", chain_buffer_len, apdu.lc);
}
apdu_process(buf[0], &buf[block_offset], &apdu);
printf1(TAG_NFC,"prev.Iblock: ");
dump_hex1(TAG_NFC, buf, len);
}
static uint8_t ibuf[1024];
static int ibuflen = 0;
void clear_ibuf()
void clear_ibuf(void)
{
ibuflen = 0;
memset(ibuf, 0, sizeof(ibuf));
@ -687,14 +870,23 @@ void nfc_process_block(uint8_t * buf, unsigned int len)
if (IS_PPSS_CMD(buf[0]))
{
printf1(TAG_NFC, "NFC_CMD_PPSS\r\n");
printf1(TAG_NFC, "NFC_CMD_PPSS [%d] 0x%02x\r\n", len, (len > 2) ? buf[2] : 0);
if (buf[1] == 0x11 && (buf[2] & 0x0f) == 0x00) {
nfc_write_frame(buf, 1); // ack with correct start byte
} else {
printf1(TAG_NFC, "NFC_CMD_PPSS ERROR!!!\r\n");
nfc_write_frame((uint8_t*)"\x00", 1); // this should not happend. but iso14443-4 dont have NACK here, so just 0x00
}
}
else if (IS_IBLOCK(buf[0]))
{
uint8_t block_offset = p14443_block_offset(buf[0]);
if (p14443_have_cid(buf[0]))
current_cid = buf[1];
if (buf[0] & 0x10)
{
printf1(TAG_NFC_APDU, "NFC_CMD_IBLOCK chaining blen=%d len=%d\r\n", ibuflen, len);
printf1(TAG_NFC_APDU, "NFC_CMD_IBLOCK chaining blen=%d len=%d offs=%d\r\n", ibuflen, len, block_offset);
if (ibuflen + len > sizeof(ibuf))
{
printf1(TAG_NFC, "I block memory error! must have %d but have only %d\r\n", ibuflen + len, sizeof(ibuf));
@ -727,21 +919,24 @@ void nfc_process_block(uint8_t * buf, unsigned int len)
memmove(ibuf, buf, block_offset);
ibuflen += block_offset;
printf1(TAG_NFC_APDU, "NFC_CMD_IBLOCK chaining last block. blen=%d len=%d\r\n", ibuflen, len);
printf1(TAG_NFC_APDU, "NFC_CMD_IBLOCK chaining last block. blen=%d len=%d offset=%d\r\n", ibuflen, len, block_offset);
printf1(TAG_NFC_APDU,"i> ");
dump_hex1(TAG_NFC_APDU, buf, len);
nfc_process_iblock(ibuf, ibuflen);
} else {
nfc_process_iblock(buf, len);
memcpy(ibuf, buf, len); // because buf only 32b
nfc_process_iblock(ibuf, len);
}
clear_ibuf();
}
}
else if (IS_RBLOCK(buf[0]))
{
rblock_acknowledge(buf[0], false);
if (p14443_have_cid(buf[0]))
current_cid = buf[1];
rblock_acknowledge(buf[0], true);
printf1(TAG_NFC, "NFC_CMD_RBLOCK\r\n");
}
else if (IS_SBLOCK(buf[0]))
@ -750,7 +945,10 @@ void nfc_process_block(uint8_t * buf, unsigned int len)
if ((buf[0] & NFC_SBLOCK_DESELECT) == 0)
{
printf1(TAG_NFC, "NFC_CMD_SBLOCK, DESELECTED\r\n");
nfc_write_frame(buf, 1);
uint8_t block_offset = p14443_block_offset(buf[0]);
if (p14443_have_cid(buf[0]))
current_cid = buf[1];
nfc_write_frame(buf, block_offset);
ams_wait_for_tx(2);
ams_write_command(AMS_CMD_SLEEP);
nfc_state_init();
@ -771,7 +969,7 @@ void nfc_process_block(uint8_t * buf, unsigned int len)
}
}
int nfc_loop()
int nfc_loop(void)
{
uint8_t buf[32];
AMS_DEVICE ams;
@ -779,6 +977,8 @@ int nfc_loop()
read_reg_block(&ams);
uint8_t old_int0 = gl_int0;
process_int0(ams.regs.int0);
uint8_t state = AMS_STATE_MASK & ams.regs.rfid_status;
if (state != AMS_STATE_SELECTED && state != AMS_STATE_SELECTEDX)
@ -792,7 +992,7 @@ int nfc_loop()
// if (state != AMS_STATE_SENSE)
// printf1(TAG_NFC," %s x%02x\r\n", ams_get_state_string(ams.regs.rfid_status), state);
}
if (ams.regs.int0 & AMS_INT_INIT)
if (ams.regs.int0 & AMS_INT_INIT || old_int0 & AMS_INT_INIT)
{
nfc_state_init();
}
@ -801,7 +1001,7 @@ int nfc_loop()
// ams_print_int1(ams.regs.int1);
}
if ((ams.regs.int0 & AMS_INT_RXE))
if (ams.regs.int0 & AMS_INT_RXE || old_int0 & AMS_INT_RXE)
{
if (ams.regs.buffer_status2)
{
@ -830,6 +1030,7 @@ int nfc_loop()
printf1(TAG_NFC, "NFC_CMD_WUPA\r\n");
break;
case NFC_CMD_HLTA:
ams_write_command(AMS_CMD_SLEEP);
printf1(TAG_NFC, "HLTA/Halt\r\n");
break;
case NFC_CMD_RATS:

12
targets/stm32l432/src/nfc.h
View File

@ -6,9 +6,9 @@
#include "apdu.h"
// Return number of bytes read if any.
int nfc_loop();
int nfc_loop(void);
int nfc_init();
int nfc_init(void);
typedef struct
{
@ -34,9 +34,9 @@ typedef struct
#define IS_PPSS_CMD(x) (((x) & 0xf0) == NFC_CMD_PPSS)
#define NFC_CMD_IBLOCK 0x00
#define IS_IBLOCK(x) ( (((x) & 0xc0) == NFC_CMD_IBLOCK) && (((x) & 0x02) == 0x02) )
#define NFC_CMD_RBLOCK 0x80
#define NFC_CMD_RBLOCK_ACK 0x20
#define IS_RBLOCK(x) ( (((x) & 0xc0) == NFC_CMD_RBLOCK) && (((x) & 0x02) == 0x02) )
#define NFC_CMD_RBLOCK 0xa0
#define NFC_CMD_RBLOCK_ACK 0x10
#define IS_RBLOCK(x) ( (((x) & 0xe0) == NFC_CMD_RBLOCK) && (((x) & 0x02) == 0x02) )
#define NFC_CMD_SBLOCK 0xc0
#define IS_SBLOCK(x) ( (((x) & 0xc0) == NFC_CMD_SBLOCK) && (((x) & 0x02) == 0x02) )
@ -61,6 +61,6 @@ typedef enum
APP_FIDO,
} APPLETS;
void WTX_timer_exec();
void WTX_timer_exec(void);
#endif

8
targets/stm32l432/src/sense.c
View File

@ -8,7 +8,7 @@
#define ELECTRODE_0 TSC_GROUP2_IO1
#define ELECTRODE_1 TSC_GROUP2_IO2
void tsc_init()
void tsc_init(void)
{
LL_GPIO_InitTypeDef GPIO_InitStruct;
// Enable TSC clock
@ -74,7 +74,7 @@ void tsc_set_electrode(uint32_t channel_ids)
TSC->IOCCR = (channel_ids);
}
void tsc_start_acq()
void tsc_start_acq(void)
{
TSC->CR &= ~(TSC_CR_START);
@ -86,7 +86,7 @@ void tsc_start_acq()
TSC->CR |= TSC_CR_START;
}
void tsc_wait_on_acq()
void tsc_wait_on_acq(void)
{
while ( ! (TSC->ISR & TSC_FLAG_EOA) )
;
@ -117,7 +117,7 @@ uint32_t tsc_read_button(uint32_t index)
return tsc_read(1) < 45;
}
int tsc_sensor_exists()
int tsc_sensor_exists(void)
{
static uint8_t does = 0;
if (does) return 1;

4
targets/stm32l432/src/sense.h
View File

@ -3,9 +3,9 @@
#include <stdint.h>
void tsc_init();
void tsc_init(void);
int tsc_sensor_exists();
int tsc_sensor_exists(void);
// Read button0 or button1
// Returns 1 if pressed, 0 if not.