| /linux/arch/arm/probes/kprobes/ |
| A D | test-arm.c | 1176 #define COPROCESSOR_INSTRUCTIONS_ST_LD(two,cc) \ in kprobe_arm_test_cases() argument
1177 TEST_COPROCESSOR("stc"two" p0, cr0, [r13, #4]") \ in kprobe_arm_test_cases()
1178 TEST_COPROCESSOR("stc"two" p0, cr0, [r13, #-4]") \ in kprobe_arm_test_cases()
1179 TEST_COPROCESSOR("stc"two" p0, cr0, [r13, #4]!") \ in kprobe_arm_test_cases()
1181 TEST_COPROCESSOR("stc"two" p0, cr0, [r13], #4") \ in kprobe_arm_test_cases()
1182 TEST_COPROCESSOR("stc"two" p0, cr0, [r13], #-4") \ in kprobe_arm_test_cases()
1183 TEST_COPROCESSOR("stc"two" p0, cr0, [r13], {1}") \ in kprobe_arm_test_cases()
1191 TEST_COPROCESSOR("ldc"two" p0, cr0, [r13, #4]") \ in kprobe_arm_test_cases()
1195 TEST_COPROCESSOR("ldc"two" p0, cr0, [r13], #4") \ in kprobe_arm_test_cases()
1233 TEST_COPROCESSOR( "ldc"two"l p0, cr0, [r15], {1}") in kprobe_arm_test_cases()
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|
| /linux/tools/testing/selftests/seccomp/ |
| A D | seccomp_benchmark.c | 86 double two = i_two, two_bump = two * 0.1; in approx() local
89 two_bump = two + MAX(two_bump, 2.0); in approx()
92 if (one == two || in approx()
93 (one > two && one <= two_bump) || in approx()
94 (two > one && two <= one_bump)) in approx()
107 unsigned long long one, bool (*eval)(int, int), unsigned long long two, in compare() argument
119 (long long)one, name_eval, (long long)two); in compare()
125 if (two > INT_MAX) { in compare()
126 ksft_print_msg("Miscalculation! Measurement went negative: %lld\n", (long long)two); in compare()
131 good = eval(one, two); in compare()
|
| /linux/Documentation/devicetree/bindings/iommu/ |
| A D | mediatek,iommu.yaml | 74 - mediatek,mt2712-m4u # generation two
75 - mediatek,mt6779-m4u # generation two
76 - mediatek,mt6795-m4u # generation two
77 - mediatek,mt8167-m4u # generation two
78 - mediatek,mt8173-m4u # generation two
79 - mediatek,mt8183-m4u # generation two
80 - mediatek,mt8186-iommu-mm # generation two
81 - mediatek,mt8188-iommu-vdo # generation two
82 - mediatek,mt8188-iommu-vpp # generation two
84 - mediatek,mt8192-m4u # generation two
[all …]
|
| /linux/lib/ |
| A D | stackinit_kunit.c | 91 zero.two = 0; \
108 .two = 0, \
112 #define __dynamic_partial { .two = arg->two, }
114 .two = arg->two, \
118 #define __runtime_partial var.two = 0
120 var.two = 0; \
257 unsigned long two; member
265 char two; member
274 u8 two; member
282 char *two; member
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| /linux/Documentation/devicetree/bindings/sound/ |
| A D | fsl,audmix.yaml | 14 The Audio Mixer is a on-chip functional module that allows mixing of two
15 audio streams into a single audio stream. Audio Mixer has two input serial
16 audio interfaces. These are driven by two Synchronous Audio interface
19 from two interfaces into a single sample. Before mixing, audio samples of
20 two inputs can be attenuated based on configuration. The output of the
31 Mixing operation is independent of audio sample rate but the two audio
|
| A D | mvebu-audio.txt | 13 With "marvell,armada-380-audio" two other regions are required:
20 with "marvell,dove-audio", a list of two interrupts, the first for
23 - clocks: one or two phandles.
|
| A D | mt6359.yaml | 23 Indicates how many data pins are used to transmit two channels of PDM
24 signal. 0 means two wires, 1 means one wire. Default value is 0.
27 - 1 # two wires
|
| /linux/Documentation/devicetree/bindings/phy/ |
| A D | fsl,imx8qm-lvds-phy.yaml | 14 It converts two groups of four 7/10 bits of CMOS data into two
19 through the two groups of LVDS data streams. Together with the
20 transmit clocks, the two groups of LVDS data streams form two
|
| /linux/arch/sh/boards/mach-r2d/ |
| A D | Kconfig | 11 R2D-PLUS is the smaller of the two R2D board versions, equipped
19 R2D-1 is the larger of the two R2D board versions, equipped
20 with two PCI slots.
|
| /linux/tools/testing/selftests/bpf/progs/ |
| A D | test_sockmap_kern.h | 98 int *f, two = 2; in bpf_prog1() local
100 f = bpf_map_lookup_elem(&sock_skb_opts, &two); in bpf_prog1()
236 int *bytes, zero = 0, one = 1, two = 2, three = 3, four = 4, five = 5; in bpf_prog4() local
249 start_push = bpf_map_lookup_elem(&sock_bytes, &two); in bpf_prog4()
266 int zero = 0, one = 1, two = 2, three = 3, four = 4, five = 5, key = 0; in bpf_prog6() local
283 start_push = bpf_map_lookup_elem(&sock_bytes, &two); in bpf_prog6()
352 int zero = 0, one = 1, two = 2, three = 3, four = 4, five = 5, err = 0; in bpf_prog10() local
364 start_push = bpf_map_lookup_elem(&sock_bytes, &two); in bpf_prog10()
|
| A D | test_mmap.c | 30 int zero = 0, one = 1, two = 2, far = 1500; in test_mmap() local
36 bpf_map_update_elem(&data_map, &two, (const void *)&in_val, 0); in test_mmap()
|
| /linux/tools/testing/selftests/splice/ |
| A D | short_splice_read.sh | 100 two=$(echo "$full" | grep -m1 . | cut -c-2)
110 if ! do_splice "$filename" 2 "$two" "'$two'" ; then
|
| /linux/tools/testing/selftests/bpf/prog_tests/ |
| A D | subprogs.c | 15 char two = '2'; in toggle_jit_harden() local
20 write(ctx->fd, &two, sizeof(two)); in toggle_jit_harden()
|
| /linux/Documentation/devicetree/bindings/leds/backlight/ |
| A D | ti,lm3509.yaml | 13 The LM3509 current mode boost converter offers two separate outputs.
49 The control register that is used to program the two current sinks.
50 The LM3509 has two registers (BMAIN and BSUB) and are represented
51 as 0 or 1 in this property. The two current sinks can be controlled
|
| A D | lm3630a-backlight.yaml | 16 controls the current in up to two strings of 10 LEDs per string.
51 The control bank that is used to program the two current sinks. The
52 LM3630A has two control banks (A and B) and are represented as 0 or 1
53 in this property. The two current sinks can be controlled
|
| /linux/Documentation/admin-guide/device-mapper/ |
| A D | unstriped.rst | 85 Intel NVMe drives contain two cores on the physical device.
88 in a 256k stripe across the two cores::
97 neighbor environments. When two partitions are created on the
100 are striped across the two cores. When we unstripe this hardware RAID 0
101 and make partitions on each new exposed device the two partitions are now
121 There will now be two devices that expose Intel NVMe core 0 and 1
|
| /linux/Documentation/devicetree/bindings/soc/fsl/cpm_qe/qe/ |
| A D | usb.txt | 5 - reg : the first two cells should contain usb registers location and
6 length, the next two two cells should contain PRAM location and
|
| /linux/arch/sh/lib/ |
| A D | checksum.S | 54 add #-2, r5 ! Alignment uses up two bytes.
56 bt/s 1f ! Jump if we had at least two bytes.
178 add #-2,r6 ! Alignment uses up two bytes.
179 cmp/pz r6 ! Jump if we had at least two bytes.
224 ! src and dest equally aligned, but to a two byte boundary.
225 ! Handle first two bytes as a special case
|
| /linux/drivers/misc/lkdtm/ |
| A D | usercopy.c | 137 unsigned char *one, *two; in do_usercopy_slab_size() local
143 two = kmalloc(size, GFP_KERNEL); in do_usercopy_slab_size()
144 if (!one || !two) { in do_usercopy_slab_size()
158 memset(two, 'B', size); in do_usercopy_slab_size()
195 kfree(two); in do_usercopy_slab_size()
|
| /linux/Documentation/devicetree/bindings/display/bridge/ |
| A D | fsl,imx8qxp-ldb.yaml | 13 The Freescale i.MX8qm/qxp LVDS Display Bridge(LDB) has two channels.
20 format and can map the input to VESA or JEIDA standards. The two channels
22 them to use. Two LDB channels from two LDB instances can work together in
28 input color format. The two channels can be used simultaneously, either
29 in dual mode or split mode. In dual mode, the two channels output identical
|
| /linux/Documentation/devicetree/bindings/memory-controllers/fsl/ |
| A D | fsl,ifc.yaml | 29 Should be either two or three. The first cell is the chipselect
35 Either one or two, depending on how large each chipselect can be.
44 IFC may have one or two interrupts. If two interrupt specifiers are
|
| /linux/arch/arm/boot/dts/microchip/ |
| A D | at91-kizbox2-2.dts | 4 * two head board
15 model = "Overkiz Kizbox 2 with two heads";
|
| /linux/tools/perf/Documentation/ |
| A D | intel-hybrid.txt | 10 Kernel exports two new cpu pmus via sysfs:
49 Create two events for one hardware event automatically
52 two events are created automatically. One is for atom, the other is for
84 perf stat -e cycles -a (use system-wide in this example), two events
118 For perf-stat result, it displays two events:
137 As previous, two events are created.
173 it creates two default 'cycles' and adds them to event list. One
|
| /linux/Documentation/gpu/ |
| A D | komeda-kms.rst | 66 introduces Layer Split, which splits the whole image to two half parts and feeds
67 them to two Layers A and B, and does the scaling independently. After scaling
68 the result need to be fed to merger to merge two part images together, and then
74 compiz result to two parts and then feed them to two scalers.
80 adjusted to fit different usages. And D71 has two pipelines, which support two
84 Two pipelines work independently and separately to drive two display outputs.
306 capabilities, and a specific component includes two parts:
328 achieve this, split the komeda device into two layers: CORE and CHIP.
384 Layer_Split is quite complicated feature, which splits a big image into two
385 parts and handles it by two layers and two scalers individually. But it
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| /linux/Documentation/maintainer/ |
| A D | messy-diffstat.rst | 25 If one wants to see what has changed between two points, a command like
30 Here, there are two clear points in the history; Git will essentially
43 the mainline branch (let's call it "linus") and cN, there are still two
55 two were then subsequently merged into c2. Now a pull request generated
59 What is happening here is that there are no longer two clear end points for
61 started in two different places; to generate the diffstat, ``git diff``
|