| /linux/drivers/comedi/drivers/ni_routing/ni_route_values/ |
| A D | ni_mseries.c | 71 [B(PXI_Star)] = I(26),
86 [B(NI_PFI_DO)] = I(16),
103 [B(PXI_Star)] = I(26),
118 [B(NI_PFI_DO)] = I(16),
135 [B(PXI_Star)] = I(26),
150 [B(NI_PFI_DO)] = I(16),
167 [B(PXI_Star)] = I(26),
199 [B(PXI_Star)] = I(26),
231 [B(PXI_Star)] = I(26),
263 [B(PXI_Star)] = I(26),
[all …]
|
| A D | ni_eseries.c | 95 [B(NI_RGOUT0)] = I(7),
109 [B(NI_RGOUT0)] = I(7),
123 [B(NI_RGOUT0)] = I(7),
137 [B(NI_RGOUT0)] = I(7),
151 [B(NI_RGOUT0)] = I(7),
165 [B(NI_RGOUT0)] = I(7),
192 [B(PXI_Star)] = I(6),
203 [B(PXI_Star)] = I(6),
214 [B(PXI_Star)] = I(6),
225 [B(PXI_Star)] = I(6),
[all …]
|
| A D | ni_660x.c | 52 [B(NI_CtrGate(7))] = I(1),
305 [B(NI_PFI(10))] = I(9),
306 [B(NI_PFI(14))] = I(8),
307 [B(NI_PFI(18))] = I(7),
308 [B(NI_PFI(22))] = I(6),
473 [B(NI_PFI(9))] = I(9),
495 [B(NI_PFI(9))] = I(9),
517 [B(NI_PFI(9))] = I(9),
539 [B(NI_PFI(9))] = I(9),
561 [B(NI_PFI(9))] = I(9),
[all …]
|
| /linux/Documentation/translations/zh_CN/virt/acrn/ |
| A D | io-request.rst | 16 I/O请求处理
19 客户虚拟机的I/O请求由超级管理器构建,由ACRN超级管理器服务模块分发到与I/O请求的地址范
20 围相对应的I/O客户端。I/O请求处理的细节将在以下章节描述。
22 1. I/O请求
26 I/O请求通信。一个I/O请求是一个256字节的结构体缓冲区,它是 "acrn_io_request" 结构
27 体,当客户虚拟机中发生被困的I/O访问时,由超级管理器的I/O处理器填充。服务虚拟机中的
29 台。缓冲区被用作16个I/O请求槽的数组,每个I/O请求槽为256字节。这个数组是按vCPU ID
32 2. I/O客户端
35 一个I/O客户端负责处理客户虚拟机的I/O请求,其访问的GPA在一定范围内。每个客户虚拟机
39 下面的图示显示了I/O请求共享缓冲区、I/O请求和I/O客户端之间的关系。
[all …]
|
| /linux/Documentation/virt/acrn/ |
| A D | io-request.rst | 3 I/O request handling
8 corresponding to the address range of the I/O request. Details of I/O request
11 1. I/O request
17 an I/O handler of the hypervisor when a trapped I/O access happens in a User
20 used as an array of 16 I/O request slots with each I/O request slot being 256
23 2. I/O clients
26 An I/O client is responsible for handling User VM I/O requests whose accessed
34 I/O requests and I/O clients.
67 3. I/O request state transition
84 4. Processing flow of I/O requests
[all …]
|
| /linux/arch/powerpc/perf/ |
| A D | hv-gpci-requests.h | 51 #include I(REQUEST_BEGIN)
67 #include I(REQUEST_END)
72 #include I(REQUEST_BEGIN)
80 #include I(REQUEST_END)
94 #include I(REQUEST_END)
104 #include I(REQUEST_END)
118 #include I(REQUEST_END)
133 #include I(REQUEST_END)
162 #include I(REQUEST_END)
179 #include I(REQUEST_END)
[all …]
|
| /linux/drivers/net/ethernet/qlogic/netxen/ |
| A D | netxen_nic_hdr.h | 632 #define NETXEN_NIU_AP_MAC_CONFIG_0(I) (NETXEN_CRB_NIU+0xa0000+(I)*0x10000) argument
633 #define NETXEN_NIU_AP_MAC_CONFIG_1(I) (NETXEN_CRB_NIU+0xa0004+(I)*0x10000) argument
634 #define NETXEN_NIU_AP_MAC_IPG_IFG(I) (NETXEN_CRB_NIU+0xa0008+(I)*0x10000) argument
635 #define NETXEN_NIU_AP_HALF_DUPLEX_CTRL(I) (NETXEN_CRB_NIU+0xa000c+(I)*0x10000) argument
636 #define NETXEN_NIU_AP_MAX_FRAME_SIZE(I) (NETXEN_CRB_NIU+0xa0010+(I)*0x10000) argument
637 #define NETXEN_NIU_AP_TEST_REG(I) (NETXEN_CRB_NIU+0xa001c+(I)*0x10000) argument
638 #define NETXEN_NIU_AP_MII_MGMT_CONFIG(I) (NETXEN_CRB_NIU+0xa0020+(I)*0x10000) argument
639 #define NETXEN_NIU_AP_MII_MGMT_COMMAND(I) (NETXEN_CRB_NIU+0xa0024+(I)*0x10000) argument
640 #define NETXEN_NIU_AP_MII_MGMT_ADDR(I) (NETXEN_CRB_NIU+0xa0028+(I)*0x10000) argument
641 #define NETXEN_NIU_AP_MII_MGMT_CTRL(I) (NETXEN_CRB_NIU+0xa002c+(I)*0x10000) argument
[all …]
|
| /linux/arch/xtensa/variants/test_kc705_hifi/include/variant/ |
| A D | tie-asm.h | 222 AE_S64.I aed0, \ptr, .Lxchal_ofs_+24
223 AE_S64.I aed1, \ptr, .Lxchal_ofs_+32
224 AE_S64.I aed2, \ptr, .Lxchal_ofs_+40
225 AE_S64.I aed3, \ptr, .Lxchal_ofs_+48
226 AE_S64.I aed4, \ptr, .Lxchal_ofs_+56
228 AE_S64.I aed5, \ptr, .Lxchal_ofs_+0
229 AE_S64.I aed6, \ptr, .Lxchal_ofs_+8
230 AE_S64.I aed7, \ptr, .Lxchal_ofs_+16
231 AE_S64.I aed8, \ptr, .Lxchal_ofs_+24
285 AE_L64.I aed5, \ptr, .Lxchal_ofs_+0
[all …]
|
| /linux/security/apparmor/include/ |
| A D | label.h | 155 for ((I).i = 0; ((P) = (L)->vec[(I).i]); ++((I).i))
159 for (++((I).i); ((P) = (L)->vec[(I).i]); ++((I).i))
163 (I).j++; \
165 (I).i++; \
173 for ((I).i = (I).j = 0; \
174 ((P1) = (L1)->vec[(I).i]) && ((P2) = (L2)->vec[(I).j]); \
175 (I) = next_comb(I, L1, L2))
191 (I).i = aa_label_next_confined((L), (I).i + 1))
194 for ((I).i = (I).j = 0; \
199 for ((I).i = (I).j = 0; \
[all …]
|
| /linux/Documentation/block/ |
| A D | stat.rst | 29 read I/Os requests number of read I/Os processed
30 read merges requests number of read I/Os merged with in-queue I/O
33 write I/Os requests number of write I/Os processed
34 write merges requests number of write I/Os merged with in-queue I/O
40 discard I/Os requests number of discard I/Os processed
41 discard merges requests number of discard I/Os merged with in-queue I/O
44 flush I/Os requests number of flush I/Os processed
48 read I/Os, write I/Os, discard I/0s
53 flush I/Os
65 already-queued I/O request.
[all …]
|
| /linux/arch/xtensa/variants/test_mmuhifi_c3/include/variant/ |
| A D | tie-asm.h | 116 AE_SP24X2S.I aep6, \ptr, 0
117 AE_SP24X2S.I aep7, \ptr, 8
118 AE_SQ56S.I aeq0, \ptr, 16
119 AE_SQ56S.I aeq1, \ptr, 24
120 AE_SQ56S.I aeq2, \ptr, 32
121 AE_SQ56S.I aeq3, \ptr, 40
146 AE_LQ56.I aeq0, \ptr, 0
147 AE_LQ56.I aeq1, \ptr, 8
148 AE_LQ56.I aeq2, \ptr, 16
149 AE_LQ56.I aeq3, \ptr, 24
[all …]
|
| /linux/arch/riscv/include/asm/ |
| A D | atomic.h | 61 : "r" (I) \
66 #define ATOMIC_OPS(op, asm_op, I) \ argument
67 ATOMIC_OP (op, asm_op, I, w, int, )
69 #define ATOMIC_OPS(op, asm_op, I) \ argument
71 ATOMIC_OP (op, asm_op, I, d, s64, 64)
97 : "r" (I) \ in ATOMIC_OPS()
108 : "r" (I) \
127 #define ATOMIC_OPS(op, asm_op, c_op, I) \ argument
131 #define ATOMIC_OPS(op, asm_op, c_op, I) \
166 #define ATOMIC_OPS(op, asm_op, I) \ argument
[all …]
|
| /linux/crypto/ |
| A D | cast6_generic.c | 27 #define F1(D, r, m) ((I = ((m) + (D))), (I = rol32(I, (r))), \
28 (((s1[I >> 24] ^ s2[(I>>16)&0xff]) - s3[(I>>8)&0xff]) + s4[I&0xff]))
29 #define F2(D, r, m) ((I = ((m) ^ (D))), (I = rol32(I, (r))), \
30 (((s1[I >> 24] - s2[(I>>16)&0xff]) + s3[(I>>8)&0xff]) ^ s4[I&0xff]))
31 #define F3(D, r, m) ((I = ((m) - (D))), (I = rol32(I, (r))), \
32 (((s1[I >> 24] + s2[(I>>16)&0xff]) ^ s3[(I>>8)&0xff]) - s4[I&0xff]))
95 u32 I; in W() local
155 u32 I; in Q() local
165 u32 I; in QBAR() local
|
| A D | cast5_generic.c | 295 #define F1(D, m, r) ((I = ((m) + (D))), (I = rol32(I, (r))), \
296 (((s1[I >> 24] ^ s2[(I>>16)&0xff]) - s3[(I>>8)&0xff]) + s4[I&0xff]))
297 #define F2(D, m, r) ((I = ((m) ^ (D))), (I = rol32(I, (r))), \
298 (((s1[I >> 24] - s2[(I>>16)&0xff]) + s3[(I>>8)&0xff]) ^ s4[I&0xff]))
299 #define F3(D, m, r) ((I = ((m) - (D))), (I = rol32(I, (r))), \
300 (((s1[I >> 24] + s2[(I>>16)&0xff]) ^ s3[(I>>8)&0xff]) - s4[I&0xff]))
306 u32 I; /* used by the Fx macros */ in __cast5_encrypt() local
361 u32 I; in __cast5_decrypt() local
|
| /linux/include/linux/platform_data/ |
| A D | adp8870.h | 85 #define ADP8870_BL_CUR_mA(I) ((I * 127) / 30) argument
90 #define ADP8870_L2_COMP_CURR_uA(I) ((I * 255) / 1106) argument
95 #define ADP8870_L3_COMP_CURR_uA(I) ((I * 255) / 551) argument
100 #define ADP8870_L4_COMP_CURR_uA(I) ((I * 255) / 275) argument
105 #define ADP8870_L5_COMP_CURR_uA(I) ((I * 255) / 138) argument
|
| /linux/drivers/gpu/drm/nouveau/nvkm/engine/ce/fuc/ |
| A D | com.fuc | 150 iowr I[$r1] $r2
156 iowr I[$r1] $r2
201 iowrs I[$r15] $r5
220 iowrs I[$r15] $r14
245 iord $r3 I[$r2]
345 iowr I[$r0] $r2
355 iowr I[$r2] $r3
389 iowr I[$r2] $r3
412 iowr I[$r4] $r3
835 iowr I[$r5] $r4
[all …]
|
| /linux/Documentation/hwmon/ |
| A D | it87.rst | 10 Addresses scanned: from Super I/O config space (8 I/O ports)
18 Addresses scanned: from Super I/O config space (8 I/O ports)
24 Addresses scanned: from Super I/O config space (8 I/O ports)
32 Addresses scanned: from Super I/O config space (8 I/O ports)
40 Addresses scanned: from Super I/O config space (8 I/O ports)
48 Addresses scanned: from Super I/O config space (8 I/O ports)
56 Addresses scanned: from Super I/O config space (8 I/O ports)
64 Addresses scanned: from Super I/O config space (8 I/O ports)
72 Addresses scanned: from Super I/O config space (8 I/O ports)
80 Addresses scanned: from Super I/O config space (8 I/O ports)
[all …]
|
| /linux/Documentation/s390/ |
| A D | cds.rst | 6 Device Driver I/O Support Routines
67 initiate an I/O request.
120 they are presenting I/O completion a unified way : I/O interruptions. Every
193 ccw_device_start() - Initiate I/O Request
232 cdev ccw_device the I/O is destined for
237 particular I/O request.
306 interrupt will be presented to indicate I/O completion as the I/O request was
381 next it can reduce I/O processing overhead by chaining a NoOp I/O command
448 ccw_device_halt() - Halt I/O Request Processing
466 the I/O request is returned
[all …]
|
| A D | vfio-ccw.rst | 8 Here we describe the vfio support for I/O subchannel devices for
13 I/O access method, which is so called Channel I/O. It has its own access
26 to perform I/O instructions.
31 - A good start to know Channel I/O in general:
72 way: I/O interruptions.
92 and starts the I/O with issuing a privileged Channel I/O instruction
95 - I/O completion will be signaled to the host with I/O interruptions.
190 vfio-ccw I/O region
213 irb_area stores the I/O result.
366 Get I/O region info during initialization.
[all …]
|
| /linux/Documentation/admin-guide/device-mapper/ |
| A D | dm-io.rst | 5 Dm-io provides synchronous and asynchronous I/O services. There are three
6 types of I/O services available, and each type has a sync and an async
10 of the I/O. Each io_region indicates a block-device along with the starting
22 The first I/O service type takes a list of memory pages as the data buffer for
23 the I/O, along with an offset into the first page::
37 The second I/O service type takes an array of bio vectors as the data buffer
38 for the I/O. This service can be handy if the caller has a pre-assembled bio,
49 data buffer for the I/O. This service can be handy if the caller needs to do
59 callback routine and a pointer to some context data for the I/O::
65 In the case of an write-I/O to multiple regions, this bitset allows dm-io to
[all …]
|
| /linux/drivers/media/tuners/ |
| A D | mt2060.c | 136 int I,J; in mt2060_spurcalc() local
139 for (I = 1; I < 10; I++) { in mt2060_spurcalc()
156 int I,J; in mt2060_spurcheck() local
157 I=0; in mt2060_spurcheck()
165 I=1000; in mt2060_spurcheck()
166 Sp1 = mt2060_spurcalc(lo1+I,lo2+I,if2); in mt2060_spurcheck()
167 Sp2 = mt2060_spurcalc(lo1-I,lo2-I,if2); in mt2060_spurcheck()
170 J=-J; I=-I; Spur=Sp2; in mt2060_spurcheck()
175 I += J; in mt2060_spurcheck()
176 Spur = mt2060_spurcalc(lo1+I,lo2+I,if2); in mt2060_spurcheck()
[all …]
|
| /linux/drivers/pinctrl/sunxi/ |
| A D | pinctrl-sun50i-h616.c | 383 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 0),
391 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 1),
399 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 2),
407 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 3),
415 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 4),
423 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 5),
431 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 6),
439 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 7),
447 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 8),
455 SUNXI_PIN(SUNXI_PINCTRL_PIN(I, 9),
[all …]
|
| /linux/Documentation/driver-api/ |
| A D | s390-drivers.rst | 11 drive s390 based channel attached I/O devices. This includes interfaces
14 I/O layer.
17 with the s390 channel I/O architecture. For a description of this
21 While most I/O devices on a s390 system are typically driven through the
22 channel I/O mechanism described here, there are various other methods
25 The s390 common I/O layer also provides access to some devices that are
26 not strictly considered I/O devices. They are considered here as well,
38 * Standard I/O subchannels, for use by the system. They have a child
40 * I/O subchannels bound to the vfio-ccw driver. See
53 so-called channel attached devices. They are addressed via I/O
[all …]
|
| /linux/Documentation/userspace-api/media/v4l/ |
| A D | pixfmt-sdr-pcu20be.rst | 15 number consist of two parts called In-phase and Quadrature (IQ). Both I
18 padded with 0. I value starts first and Q value starts at an offset
36 - I'\ :sub:`0[19:12]`
37 - I'\ :sub:`0[11:4]`
38 - I'\ :sub:`0[3:0]; B2[3:0]=pad`
41 - I'\ :sub:`1[19:12]`
42 - I'\ :sub:`1[11:4]`
43 - I'\ :sub:`1[3:0]; B2[3:0]=pad`
|
| A D | pixfmt-sdr-pcu18be.rst | 15 number consist of two parts called In-phase and Quadrature (IQ). Both I
18 padded with 0. I value starts first and Q value starts at an offset
36 - I'\ :sub:`0[17:10]`
37 - I'\ :sub:`0[9:2]`
38 - I'\ :sub:`0[1:0]; B2[5:0]=pad`
41 - I'\ :sub:`1[17:10]`
42 - I'\ :sub:`1[9:2]`
43 - I'\ :sub:`1[1:0]; B2[5:0]=pad`
|