| /linux/include/trace/events/ |
| H A D | 9p.h | 11 EM( P9_TLERROR, "P9_TLERROR" ) \
12 EM( P9_RLERROR, "P9_RLERROR" ) \
13 EM( P9_TSTATFS, "P9_TSTATFS" ) \
14 EM( P9_RSTATFS, "P9_RSTATFS" ) \
15 EM( P9_TLOPEN, "P9_TLOPEN" ) \
16 EM( P9_RLOPEN, "P9_RLOPEN" ) \
17 EM( P9_TLCREATE, "P9_TLCREATE" ) \
18 EM( P9_RLCREATE, "P9_RLCREATE" ) \
19 EM( P9_TSYMLINK, "P9_TSYMLINK" ) \
20 EM( P9_RSYMLINK, "P9_RSYMLINK" ) \
[all …]
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| H A D | netfs.h | 19 EM(netfs_read_trace_dio_read, "DIO-READ ") \
20 EM(netfs_read_trace_expanded, "EXPANDED ") \
21 EM(netfs_read_trace_readahead, "READAHEAD") \
22 EM(netfs_read_trace_readpage, "READPAGE ") \
23 EM(netfs_read_trace_read_gaps, "READ-GAPS") \
24 EM(netfs_read_trace_read_single, "READ-SNGL") \
25 EM(netfs_read_trace_prefetch_for_write, "PREFETCHW") \
29 EM(netfs_write_trace_copy_to_cache, "COPY2CACH") \
30 EM(netfs_write_trace_dio_write, "DIO-WRITE") \
31 EM(netfs_write_trace_unbuffered_write, "UNB-WRITE") \
[all …]
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| H A D | afs.h | 123 EM(afs_call_trace_alloc, "ALLOC") \
124 EM(afs_call_trace_async_abort, "ASYAB") \
125 EM(afs_call_trace_async_kill, "ASYKL") \
126 EM(afs_call_trace_free, "FREE ") \
127 EM(afs_call_trace_get, "GET ") \
128 EM(afs_call_trace_put, "PUT ") \
129 EM(afs_call_trace_wake, "WAKE ") \
133 EM(afs_server_trace_callback, "CALLBACK ") \
134 EM(afs_server_trace_destroy, "DESTROY ") \
135 EM(afs_server_trace_free, "FREE ") \
[all …]
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| H A D | rxrpc.h | 21 EM(afs_abort_general_error, "afs-error") \
22 EM(afs_abort_interrupted, "afs-intr") \
23 EM(afs_abort_oom, "afs-oom") \
24 EM(afs_abort_op_not_supported, "afs-op-notsupp") \
25 EM(afs_abort_probeuuid_negative, "afs-probeuuid-neg") \
26 EM(afs_abort_send_data_error, "afs-send-data") \
27 EM(afs_abort_unmarshal_error, "afs-unmarshal") \
28 EM(afs_abort_unsupported_sec_class, "afs-unsup-sec-class") \
30 EM(rxperf_abort_general_error, "rxperf-error") \
31 EM(rxperf_abort_oom, "rxperf-oom") \
[all …]
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| H A D | memory-failure.h | 21 EM ( MF_IGNORED, "Ignored" ) \
22 EM ( MF_FAILED, "Failed" ) \
23 EM ( MF_DELAYED, "Delayed" ) \
27 EM ( MF_MSG_KERNEL, "reserved kernel page" ) \
28 EM ( MF_MSG_KERNEL_HIGH_ORDER, "high-order kernel page" ) \
29 EM ( MF_MSG_HUGE, "huge page" ) \
30 EM ( MF_MSG_FREE_HUGE, "free huge page" ) \
31 EM ( MF_MSG_GET_HWPOISON, "get hwpoison page" ) \
32 EM ( MF_MSG_UNMAP_FAILED, "unmapping failed page" ) \
33 EM ( MF_MSG_DIRTY_SWAPCACHE, "dirty swapcache page" ) \
[all …]
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| H A D | fscache.h | 111 EM(fscache_cache_collision, "*COLLIDE*") \
112 EM(fscache_cache_get_acquire, "GET acq ") \
113 EM(fscache_cache_new_acquire, "NEW acq ") \
114 EM(fscache_cache_put_alloc_volume, "PUT alvol") \
115 EM(fscache_cache_put_cache, "PUT cache") \
116 EM(fscache_cache_put_prep_failed, "PUT pfail") \
117 EM(fscache_cache_put_relinquish, "PUT relnq") \
121 EM(fscache_volume_collision, "*COLLIDE*") \
122 EM(fscache_volume_get_cookie, "GET cook ") \
123 EM(fscache_volume_get_create_work, "GET creat") \
[all …]
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| H A D | huge_memory.h | 11 EM( SCAN_FAIL, "failed") \
12 EM( SCAN_SUCCEED, "succeeded") \
13 EM( SCAN_NO_PTE_TABLE, "no_pte_table") \
14 EM( SCAN_PMD_MAPPED, "page_pmd_mapped") \
15 EM( SCAN_EXCEED_NONE_PTE, "exceed_none_pte") \
16 EM( SCAN_EXCEED_SWAP_PTE, "exceed_swap_pte") \
17 EM( SCAN_EXCEED_SHARED_PTE, "exceed_shared_pte") \
18 EM( SCAN_PTE_NON_PRESENT, "pte_non_present") \
19 EM( SCAN_PTE_UFFD_WP, "pte_uffd_wp") \
20 EM( SCAN_PTE_MAPPED_HUGEPAG
44 #define EM( global() macro
51 #define EM( global() macro
[all...] |
| H A D | cachefiles.h | 112 EM(FSCACHE_OBJECT_IS_STALE, "stale") \
113 EM(FSCACHE_OBJECT_IS_WEIRD, "weird") \
114 EM(FSCACHE_OBJECT_INVALIDATED, "inval") \
115 EM(FSCACHE_OBJECT_NO_SPACE, "no_space") \
116 EM(FSCACHE_OBJECT_WAS_RETIRED, "was_retired") \
117 EM(FSCACHE_OBJECT_WAS_CULLED, "was_culled") \
121 EM(cachefiles_obj_get_ioreq, "GET ioreq") \
122 EM(cachefiles_obj_new, "NEW obj") \
123 EM(cachefiles_obj_put_alloc_fail, "PUT alloc_fail") \
124 EM(cachefiles_obj_put_detach, "PUT detach") \
[all …]
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| H A D | mmflags.h | 246 EM( COMPACT_SKIPPED, "skipped") \
247 EM( COMPACT_DEFERRED, "deferred") \
248 EM( COMPACT_CONTINUE, "continue") \
249 EM( COMPACT_SUCCESS, "success") \
250 EM( COMPACT_PARTIAL_SKIPPED, "partial_skipped") \
251 EM( COMPACT_COMPLETE, "complete") \
252 EM( COMPACT_NO_SUITABLE_PAGE, "no_suitable_page") \
253 EM( COMPACT_NOT_SUITABLE_ZONE, "not_suitable_zone") \
269 EM(COMPACTION_FAILED, "failed") \
270 EM(COMPACTION_WITHDRAWN, "withdrawn") \
[all …]
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| H A D | v4l2.h | 12 #undef EM
14 #define EM(a, b) TRACE_DEFINE_ENUM(a); macro
21 EM( V4L2_BUF_TYPE_VIDEO_CAPTURE, "VIDEO_CAPTURE" ) \
22 EM( V4L2_BUF_TYPE_VIDEO_OUTPUT, "VIDEO_OUTPUT" ) \
23 EM( V4L2_BUF_TYPE_VIDEO_OVERLAY, "VIDEO_OVERLAY" ) \
24 EM( V4L2_BUF_TYPE_VBI_CAPTURE, "VBI_CAPTURE" ) \
25 EM( V4L2_BUF_TYPE_VBI_OUTPUT, "VBI_OUTPUT" ) \
26 EM( V4L2_BUF_TYPE_SLICED_VBI_CAPTURE, "SLICED_VBI_CAPTURE" ) \
27 EM( V4L2_BUF_TYPE_SLICED_VBI_OUTPUT, "SLICED_VBI_OUTPUT" ) \
28 EM( V4L2_BUF_TYPE_VIDEO_OUTPUT_OVERLAY, "VIDEO_OUTPUT_OVERLAY" ) \
[all …]
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| H A D | migrate.h | 11 EM( MIGRATE_ASYNC, "MIGRATE_ASYNC") \
12 EM( MIGRATE_SYNC_LIGHT, "MIGRATE_SYNC_LIGHT") \
17 EM( MR_COMPACTION, "compaction") \
18 EM( MR_MEMORY_FAILURE, "memory_failure") \
19 EM( MR_MEMORY_HOTPLUG, "memory_hotplug") \
20 EM( MR_SYSCALL, "syscall_or_cpuset") \
21 EM( MR_MEMPOLICY_MBIND, "mempolicy_mbind") \
22 EM( MR_NUMA_MISPLACED, "numa_misplaced") \
23 EM( MR_CONTIG_RANGE, "contig_range") \
24 EM( MR_LONGTERM_PIN, "longterm_pin") \
[all …]
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| H A D | tlb.h | 12 EM( TLB_FLUSH_ON_TASK_SWITCH, "flush on task switch" ) \
13 EM( TLB_REMOTE_SHOOTDOWN, "remote shootdown" ) \
14 EM( TLB_LOCAL_SHOOTDOWN, "local shootdown" ) \
15 EM( TLB_LOCAL_MM_SHOOTDOWN, "local MM shootdown" ) \
16 EM( TLB_REMOTE_SEND_IPI, "remote IPI send" ) \
23 #undef EM
25 #define EM(a,b) TRACE_DEFINE_ENUM(a); macro
34 #undef EM
36 #define EM(a,b) { a, b }, macro
|
| H A D | sock.h | 16 EM(AF_INET) \
21 EM(IPPROTO_TCP) \
22 EM(IPPROTO_SCTP) \
26 EM(TCP_ESTABLISHED) \
27 EM(TCP_SYN_SENT) \
28 EM(TCP_SYN_RECV) \
29 EM(TCP_FIN_WAIT1) \
30 EM(TCP_FIN_WAIT2) \
31 EM(TCP_TIME_WAIT) \
32 EM(TCP_CLOS
47 #define EM( global() macro
57 #define EM( global() macro
[all...] |
| H A D | error_report.h | 27 EM(ERROR_DETECTOR_KFENCE, "kfence") \
28 EM(ERROR_DETECTOR_KASAN, "kasan") \
32 #undef EM
35 #define EM(a, b) TRACE_DEFINE_ENUM(a); macro
40 #undef EM
43 #define EM(a, b) { a, b }, macro
|
| H A D | rpm.h | 105 EM(RPM_INVALID, "RPM_INVALID") \
106 EM(RPM_ACTIVE, "RPM_ACTIVE") \
107 EM(RPM_RESUMING, "RPM_RESUMING") \
108 EM(RPM_SUSPENDED, "RPM_SUSPENDED") \
112 #undef EM
114 #define EM(a, b) TRACE_DEFINE_ENUM(a); macro
120 * Now redefine the EM() and EMe() macros to map the enums to the strings that
123 #undef EM
125 #define EM(a, b) { a, b }, macro
|
| H A D | ceph.h | 16 EM(ceph_mdsc_suspend_reason_no_mdsmap, "no-mdsmap") \
17 EM(ceph_mdsc_suspend_reason_no_active_mds, "no-active-mds") \
18 EM(ceph_mdsc_suspend_reason_rejected, "rejected") \
24 #undef EM
26 #define EM(a, b) a, macro
36 #undef EM
38 #define EM(a, b) TRACE_DEFINE_ENUM(a); macro
47 #undef EM
49 #define EM(a, b) { a, b }, macro
229 #undef EM
|
| H A D | kmem.h | 408 EM(MM_FILEPAGES) \
409 EM(MM_ANONPAGES) \
410 EM(MM_SWAPENTS) \
413 #undef EM
416 #define EM(a) TRACE_DEFINE_ENUM(a); macro
421 #undef EM
424 #define EM(a) { a, #a }, macro
|
| H A D | sched.h | 725 EM( NUMAB_SKIP_UNSUITABLE, "unsuitable" ) \
726 EM( NUMAB_SKIP_SHARED_RO, "shared_ro" ) \
727 EM( NUMAB_SKIP_INACCESSIBLE, "inaccessible" ) \
728 EM( NUMAB_SKIP_SCAN_DELAY, "scan_delay" ) \
729 EM( NUMAB_SKIP_PID_INACTIVE, "pid_inactive" ) \
730 EM( NUMAB_SKIP_IGNORE_PID, "ignore_pid_inactive" ) \
734 #undef EM
736 #define EM(a, b) TRACE_DEFINE_ENUM(a); macro
742 #undef EM
744 #define EM(a, b) { a, b }, macro
|
| H A D | btrfs.h | 65 EM( BTRFS_RESERVE_NO_FLUSH, "BTRFS_RESERVE_NO_FLUSH") \
66 EM( BTRFS_RESERVE_FLUSH_LIMIT, "BTRFS_RESERVE_FLUSH_LIMIT") \
67 EM( BTRFS_RESERVE_FLUSH_ALL, "BTRFS_RESERVE_FLUSH_ALL") \
71 EM( BTRFS_FILE_EXTENT_INLINE, "INLINE") \
72 EM( BTRFS_FILE_EXTENT_REG, "REG") \
76 EM( BTRFS_QGROUP_RSV_DATA, "DATA") \
77 EM( BTRFS_QGROUP_RSV_META_PERTRANS, "META_PERTRANS") \
81 EM( IO_TREE_FS_PINNED_EXTENTS, "PINNED_EXTENTS") \
82 EM( IO_TREE_FS_EXCLUDED_EXTENTS, "EXCLUDED_EXTENTS") \
83 EM( IO_TREE_BTREE_INODE_IO, "BTREE_INODE_IO") \
[all …]
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| /linux/fs/fuse/ |
| H A D | fuse_trace.h | 11 EM( FUSE_LOOKUP, "FUSE_LOOKUP") \
12 EM( FUSE_FORGET, "FUSE_FORGET") \
13 EM( FUSE_GETATTR, "FUSE_GETATTR") \
14 EM( FUSE_SETATTR, "FUSE_SETATTR") \
15 EM( FUSE_READLINK, "FUSE_READLINK") \
16 EM( FUSE_SYMLINK, "FUSE_SYMLINK") \
17 EM( FUSE_MKNOD, "FUSE_MKNOD") \
18 EM( FUSE_MKDIR, "FUSE_MKDIR") \
19 EM( FUSE_UNLINK, "FUSE_UNLINK") \
20 EM( FUSE_RMDIR, "FUSE_RMDIR") \
[all …]
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| /linux/Documentation/translations/zh_CN/power/ |
| H A D | energy-model.rst | 17 能量模型(EM)框架是一种驱动程序与内核子系统之间的接口。其中驱动程序了解不同
23 实现支持,EM框架作为一个抽象层介入,它在内核中对功率成本表的格式进行标准化,
26 功率值可以用微瓦或“抽象刻度”表示。多个子系统可能使用EM,由系统集成商来检查
33 内核子系统可能(基于EM内部标志位)实现了对EM注册设备是否具有不一致刻度的自动
38 向EM框架提供了功率成本,感兴趣的客户端可从中读取数据::
65 对于CPU设备,EM框架管理着系统中每个“性能域”的功率成本表。一个性能域是一组
76 必须使能CONFIG_ENERGY_MODEL才能使用EM框架。
82 “高级”EM的注册
85 “高级”EM因它允许驱动提供更精确的功率模型而得名。它并不受限于框架中的一些已
86 实现的数学公式(就像“简单”EM那样)。它可以更好地反映每个性能状态的实际功率
[all …]
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| /linux/fs/smb/client/ |
| H A D | trace.h | 24 EM(smb_eio_trace_compress_copy, "compress_copy") \
25 EM(smb_eio_trace_copychunk_inv_rsp, "copychunk_inv_rsp") \
26 EM(smb_eio_trace_copychunk_overcopy_b, "copychunk_overcopy_b") \
27 EM(smb_eio_trace_copychunk_overcopy_c, "copychunk_overcopy_c") \
28 EM(smb_eio_trace_create_rsp_too_small, "create_rsp_too_small") \
29 EM(smb_eio_trace_dfsref_no_rsp, "dfsref_no_rsp") \
30 EM(smb_eio_trace_ea_overrun, "ea_overrun") \
31 EM(smb_eio_trace_extract_will_pin, "extract_will_pin") \
32 EM(smb_eio_trace_forced_shutdown, "forced_shutdown") \
33 EM(smb_eio_trace_getacl_bcc_too_small, "getacl_bcc_too_small") \
[all …]
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| /linux/Documentation/translations/zh_CN/scheduler/ |
| H A D | sched-energy.rst | 18 一个能量模型(EM)来为每个任务选择一个节能的CPU,同时最小化对吞吐率的影响。
29 EAS实际使用的EM不是由调度器维护的,而是一个专门的框架。关于这个框架的细节和
55 引入EM的想法是为了让调度器评估其决策的影响,而不是盲目地应用可能仅在部分
56 平台有正面效果的节能技术。同时,EM必须尽可能的简单,以最小化调度器的时延
60 运行时(在唤醒期间),EM被用来在不损害系统吞吐率的情况下,从几个较好的候选
75 EAS使用的其余平台信息是直接从能量模型(EM)框架中读取的。一个平台的EM是一张
79 当调度域被建立或重新建立时,调度器管理对拓扑代码中EM对象的引用。对于每个根域
81 节点都包含一个指向EM框架所提供的结构体em_perf_domain的指针。
102 两个节点持有指向同一个EM框架的共享数据结构的指针。
114 EAS覆盖了CFS的任务唤醒平衡代码。在唤醒平衡时,它使用平台的EM和PELT信号来选择节能
[all …]
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| /linux/drivers/ufs/core/ |
| H A D | ufs_trace.h | 26 EM(UIC_LINK_OFF_STATE, "UIC_LINK_OFF_STATE") \
27 EM(UIC_LINK_ACTIVE_STATE, "UIC_LINK_ACTIVE_STATE") \
31 EM(UFS_ACTIVE_PWR_MODE, "UFS_ACTIVE_PWR_MODE") \
32 EM(UFS_SLEEP_PWR_MODE, "UFS_SLEEP_PWR_MODE") \
33 EM(UFS_POWERDOWN_PWR_MODE, "UFS_POWERDOWN_PWR_MODE") \
37 EM(CLKS_OFF, "CLKS_OFF") \
38 EM(CLKS_ON, "CLKS_ON") \
39 EM(REQ_CLKS_OFF, "REQ_CLKS_OFF") \
43 EM(UFS_CMD_SEND, "send_req") \
44 EM(UFS_CMD_COMP, "complete_rsp") \
[all …]
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| /linux/Documentation/translations/zh_CN/infiniband/ |
| H A D | opa_vnic.rst | 31 实际上是一个独立的以太网网络。该配置由以太网管理器(EM)执行,它是可信的结
125 管理器(EM)和VNIC netdev交换管理信息。VNIC netdev部分分配和释放OPA_VNIC
128 对于每个VNIC接口,封装所需的信息是由EM通过VEMA MAD接口配置的。它还通过调用
|