| /linux-6.1.9/include/trace/events/ ! |
| 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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| D | afs.h | 326 EM(afs_call_trace_alloc, "ALLOC") \
327 EM(afs_call_trace_free, "FREE ") \
328 EM(afs_call_trace_get, "GET ") \
329 EM(afs_call_trace_put, "PUT ") \
330 EM(afs_call_trace_wake, "WAKE ") \
334 EM(afs_server_trace_alloc, "ALLOC ") \
335 EM(afs_server_trace_callback, "CALLBACK ") \
336 EM(afs_server_trace_destroy, "DESTROY ") \
337 EM(afs_server_trace_free, "FREE ") \
338 EM(afs_server_trace_gc, "GC ") \
[all …]
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| D | fscache.h | 109 EM(fscache_cache_collision, "*COLLIDE*") \
110 EM(fscache_cache_get_acquire, "GET acq ") \
111 EM(fscache_cache_new_acquire, "NEW acq ") \
112 EM(fscache_cache_put_alloc_volume, "PUT alvol") \
113 EM(fscache_cache_put_cache, "PUT cache") \
114 EM(fscache_cache_put_prep_failed, "PUT pfail") \
115 EM(fscache_cache_put_relinquish, "PUT relnq") \
119 EM(fscache_volume_collision, "*COLLIDE*") \
120 EM(fscache_volume_get_cookie, "GET cook ") \
121 EM(fscache_volume_get_create_work, "GET creat") \
[all …]
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| D | netfs.h | 19 EM(netfs_read_trace_expanded, "EXPANDED ") \
20 EM(netfs_read_trace_readahead, "READAHEAD") \
21 EM(netfs_read_trace_readpage, "READPAGE ") \
25 EM(NETFS_READAHEAD, "RA") \
26 EM(NETFS_READPAGE, "RP") \
30 EM(netfs_rreq_trace_assess, "ASSESS ") \
31 EM(netfs_rreq_trace_copy, "COPY ") \
32 EM(netfs_rreq_trace_done, "DONE ") \
33 EM(netfs_rreq_trace_free, "FREE ") \
34 EM(netfs_rreq_trace_resubmit, "RESUBMT") \
[all …]
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| D | rxrpc.h | 20 EM(rxrpc_skb_cleaned, "CLN") \
21 EM(rxrpc_skb_freed, "FRE") \
22 EM(rxrpc_skb_got, "GOT") \
23 EM(rxrpc_skb_lost, "*L*") \
24 EM(rxrpc_skb_new, "NEW") \
25 EM(rxrpc_skb_purged, "PUR") \
26 EM(rxrpc_skb_received, "RCV") \
27 EM(rxrpc_skb_rotated, "ROT") \
28 EM(rxrpc_skb_seen, "SEE") \
29 EM(rxrpc_skb_unshared, "UNS") \
[all …]
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| D | huge_memory.h | 11 EM( SCAN_FAIL, "failed") \
12 EM( SCAN_SUCCEED, "succeeded") \
13 EM( SCAN_PMD_NULL, "pmd_null") \
14 EM( SCAN_PMD_NONE, "pmd_none") \
15 EM( SCAN_PMD_MAPPED, "page_pmd_mapped") \
16 EM( SCAN_EXCEED_NONE_PTE, "exceed_none_pte") \
17 EM( SCAN_EXCEED_SWAP_PTE, "exceed_swap_pte") \
18 EM( SCAN_EXCEED_SHARED_PTE, "exceed_shared_pte") \
19 EM( SCAN_PTE_NON_PRESENT, "pte_non_present") \
20 EM( SCAN_PTE_UFFD_WP, "pte_uffd_wp") \
[all …]
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| D | mmflags.h | 206 EM( COMPACT_SKIPPED, "skipped") \
207 EM( COMPACT_DEFERRED, "deferred") \
208 EM( COMPACT_CONTINUE, "continue") \
209 EM( COMPACT_SUCCESS, "success") \
210 EM( COMPACT_PARTIAL_SKIPPED, "partial_skipped") \
211 EM( COMPACT_COMPLETE, "complete") \
212 EM( COMPACT_NO_SUITABLE_PAGE, "no_suitable_page") \
213 EM( COMPACT_NOT_SUITABLE_ZONE, "not_suitable_zone") \
229 EM(COMPACTION_FAILED, "failed") \
230 EM(COMPACTION_WITHDRAWN, "withdrawn") \
[all …]
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| D | cachefiles.h | 110 EM(FSCACHE_OBJECT_IS_STALE, "stale") \
111 EM(FSCACHE_OBJECT_IS_WEIRD, "weird") \
112 EM(FSCACHE_OBJECT_INVALIDATED, "inval") \
113 EM(FSCACHE_OBJECT_NO_SPACE, "no_space") \
114 EM(FSCACHE_OBJECT_WAS_RETIRED, "was_retired") \
115 EM(FSCACHE_OBJECT_WAS_CULLED, "was_culled") \
119 EM(cachefiles_obj_get_ioreq, "GET ioreq") \
120 EM(cachefiles_obj_new, "NEW obj") \
121 EM(cachefiles_obj_put_alloc_fail, "PUT alloc_fail") \
122 EM(cachefiles_obj_put_detach, "PUT detach") \
[all …]
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| 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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| 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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| D | sock.h | 15 EM(AF_INET) \
20 EM(IPPROTO_TCP) \
21 EM(IPPROTO_DCCP) \
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) \
[all …]
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| 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" ) \
22 #undef EM
24 #define EM(a,b) TRACE_DEFINE_ENUM(a); macro
33 #undef EM
35 #define EM(a,b) { a, b }, macro
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| D | ufs.h | 24 EM(UIC_LINK_OFF_STATE, "UIC_LINK_OFF_STATE") \
25 EM(UIC_LINK_ACTIVE_STATE, "UIC_LINK_ACTIVE_STATE") \
29 EM(UFS_ACTIVE_PWR_MODE, "UFS_ACTIVE_PWR_MODE") \
30 EM(UFS_SLEEP_PWR_MODE, "UFS_SLEEP_PWR_MODE") \
31 EM(UFS_POWERDOWN_PWR_MODE, "UFS_POWERDOWN_PWR_MODE") \
35 EM(CLKS_OFF, "CLKS_OFF") \
36 EM(CLKS_ON, "CLKS_ON") \
37 EM(REQ_CLKS_OFF, "REQ_CLKS_OFF") \
41 EM(UFS_CMD_SEND, "send_req") \
42 EM(UFS_CMD_COMP, "complete_rsp") \
[all …]
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| 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
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| D | kmem.h | 327 EM(MM_FILEPAGES) \
328 EM(MM_ANONPAGES) \
329 EM(MM_SWAPENTS) \
332 #undef EM
335 #define EM(a) TRACE_DEFINE_ENUM(a); macro
340 #undef EM
343 #define EM(a) { a, #a }, macro
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| D | writeback.h | 27 #undef EM
29 #define EM(a,b) TRACE_DEFINE_ENUM(a); macro
33 EM( WB_REASON_BACKGROUND, "background") \
34 EM( WB_REASON_VMSCAN, "vmscan") \
35 EM( WB_REASON_SYNC, "sync") \
36 EM( WB_REASON_PERIODIC, "periodic") \
37 EM( WB_REASON_LAPTOP_TIMER, "laptop_timer") \
38 EM( WB_REASON_FS_FREE_SPACE, "fs_free_space") \
39 EM( WB_REASON_FORKER_THREAD, "forker_thread") \
48 #undef EM
[all …]
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| D | btrfs.h | 67 EM( BTRFS_RESERVE_NO_FLUSH, "BTRFS_RESERVE_NO_FLUSH") \
68 EM( BTRFS_RESERVE_FLUSH_LIMIT, "BTRFS_RESERVE_FLUSH_LIMIT") \
69 EM( BTRFS_RESERVE_FLUSH_ALL, "BTRFS_RESERVE_FLUSH_ALL") \
73 EM( BTRFS_FILE_EXTENT_INLINE, "INLINE") \
74 EM( BTRFS_FILE_EXTENT_REG, "REG") \
78 EM( BTRFS_QGROUP_RSV_DATA, "DATA") \
79 EM( BTRFS_QGROUP_RSV_META_PERTRANS, "META_PERTRANS") \
83 EM( IO_TREE_FS_PINNED_EXTENTS, "PINNED_EXTENTS") \
84 EM( IO_TREE_FS_EXCLUDED_EXTENTS, "EXCLUDED_EXTENTS") \
85 EM( IO_TREE_BTREE_INODE_IO, "BTREE_INODE_IO") \
[all …]
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| D | sunrpc.h | 761 #undef EM
763 #define EM(a, b) TRACE_DEFINE_ENUM(a); macro
767 EM( SS_FREE, "FREE" ) \
768 EM( SS_UNCONNECTED, "UNCONNECTED" ) \
769 EM( SS_CONNECTING, "CONNECTING" ) \
770 EM( SS_CONNECTED, "CONNECTED" ) \
779 EM( TCP_ESTABLISHED, "ESTABLISHED" ) \
780 EM( TCP_SYN_SENT, "SYN_SENT" ) \
781 EM( TCP_SYN_RECV, "SYN_RECV" ) \
782 EM( TCP_FIN_WAIT1, "FIN_WAIT1" ) \
[all …]
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| /linux-6.1.9/Documentation/translations/zh_CN/power/ ! |
| 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 功率值可以用毫瓦或“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-6.1.9/Documentation/translations/zh_CN/scheduler/ ! |
| 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-6.1.9/include/ras/ ! |
| D | ras_event.h | 351 EM ( MF_IGNORED, "Ignored" ) \
352 EM ( MF_FAILED, "Failed" ) \
353 EM ( MF_DELAYED, "Delayed" ) \
357 EM ( MF_MSG_KERNEL, "reserved kernel page" ) \
358 EM ( MF_MSG_KERNEL_HIGH_ORDER, "high-order kernel page" ) \
359 EM ( MF_MSG_SLAB, "kernel slab page" ) \
360 EM ( MF_MSG_DIFFERENT_COMPOUND, "different compound page after locking" ) \
361 EM ( MF_MSG_HUGE, "huge page" ) \
362 EM ( MF_MSG_FREE_HUGE, "free huge page" ) \
363 EM ( MF_MSG_UNMAP_FAILED, "unmapping failed page" ) \
[all …]
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| /linux-6.1.9/Documentation/power/ ! |
| D | energy-model.rst | 10 The Energy Model (EM) framework serves as an interface between drivers knowing
19 possible source of information on its own, the EM framework intervenes as an
24 Multiple subsystems might use the EM and it is up to the system integrator to
33 Kernel subsystems might implement automatic detection to check whether EM
34 registered devices have inconsistent scale (based on EM internal flag).
39 approach is applicable to any architecture) providing power costs to the EM
67 In case of CPU devices the EM framework manages power cost tables per
81 CONFIG_ENERGY_MODEL must be enabled to use the EM framework.
87 Registration of 'advanced' EM
90 The 'advanced' EM gets it's name due to the fact that the driver is allowed
[all …]
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| /linux-6.1.9/Documentation/translations/zh_CN/infiniband/ ! |
| 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
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| /linux-6.1.9/Documentation/scheduler/ ! |
| D | sched-energy.rst | 10 Energy Model (EM) of the CPUs to select an energy efficient CPU for each task,
23 The actual EM used by EAS is _not_ maintained by the scheduler, but by a
53 The idea behind introducing an EM is to allow the scheduler to evaluate the
56 time, the EM must be as simple as possible to minimize the scheduler latency
60 for the scheduler to decide where a task should run (during wake-up), the EM
83 Model (EM) framework. The EM of a platform is composed of a power cost table
87 The scheduler manages references to the EM objects in the topology code when the
91 em_perf_domain as provided by the EM framework.
117 shared data structure of the EM framework.
131 EAS overrides the CFS task wake-up balancing code. It uses the EM of the
[all …]
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| /linux-6.1.9/Documentation/ABI/testing/ ! |
| D | sysfs-class-scsi_host | 104 (RW) Allows access to AHCI EM (enclosure management) buffer
105 directly if the host supports EM.
107 For eg. the AHCI driver supports SGPIO EM messages but the
108 SATA/AHCI specs do not define the SGPIO message format of the EM
|