| /linux/Documentation/devicetree/ |
| H A D | of_unittest.rst | 97 Figure 1, describes a generic structure of machine's un-flattened device tree
126 Figure 1: Generic structure of un-flattened device tree
144 in Figure 2 is attached to the live tree described in Figure 1::
155 Figure 2: Example test data tree to be attached to live tree.
164 data node is attached to the live tree above (Figure 1), the final structure is
165 as shown in Figure 3::
200 Figure 3: Live device tree structure after attaching the testcase-data.
204 sibling compared to the earlier structure (Figure 2). After attaching first
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| /linux/Documentation/translations/zh_CN/devicetree/ |
| H A D | of_unittest.rst | 101 Figure 1: 未扁平化的设备树的通用结构
127 Figure 2: 将测试数据树附在实时树上的例子。
169 Figure 3: 附加测试案例数据后的实时设备树结构。
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| /linux/Documentation/sphinx/ |
| H A D | kfigure.py | 64 Figure = images.Figure variable
478 class KernelFigure(Figure):
493 result = Figure.run(self)
554 class KernelRender(Figure):
572 option_spec = Figure.option_spec.copy()
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| /linux/Documentation/firmware-guide/acpi/ |
| H A D | namespace.rst | 72 Figure 1. ACPI Definition Blocks
189 Figure 2. Example ACPI Namespace
325 example ACPI namespace illustrated in Figure 2 with the addition of
388 Figure 3. Example Linux ACPI Device Tree
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| /linux/Documentation/userspace-api/ |
| H A D | perf_ring_buffer.rst | 70 Figure 1. Ring buffer
100 Figure 2. Perf ring buffer
193 Figure 3. Ring buffer for default mode
248 Figure 4. Ring buffer for per-thread mode
314 Figure 5. Ring buffer for per-CPU mode
380 Figure 6. Ring buffer for system wide mode
421 Figure 7. Writing and reading the ring buffer
717 Figure 8. AUX ring buffer for system wide mode
830 Figure 9. Snapshot with system wide mode
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| /linux/arch/arm64/boot/dts/qcom/ |
| H A D | msm8998-mtp.dts | 128 /* FIXME: Figure out why clock late_initcall crashes the board with this enabled. */
132 /* FIXME: Figure out why clock late_initcall crashes the board with this enabled. */
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| H A D | msm8998-fxtec-pro1.dts | 313 /* FIXME: Figure out why clock late_initcall crashes the board with this enabled. */
317 /* FIXME: Figure out why clock late_initcall crashes the board with this enabled. */
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| /linux/Documentation/timers/ |
| H A D | highres.rst | 14 changes in the time(r) related Linux subsystems. Figure #1 (p. 2) shows the
66 Figure #3 (OLS slides p.18) illustrates the transformation.
139 Figure #4 (OLS slides p.20) illustrates the transformation.
205 Figure #5 (OLS slides p.22) illustrates the transformation.
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| /linux/Documentation/netlabel/ |
| H A D | draft-ietf-cipso-ipsecurity-01.txt | 99 Figure 1. CIPSO Format
177 Figure 2: Standard Tag Format
218 Figure 3. Tag Type 1 Format
253 by the least significant bit of the second byte. Figure 4 graphically
276 Figure 4. Ordering of Bits in Tag 1 Bit Map
304 Figure 5. Tag Type 2 Format
367 Figure 6. Tag Type 5 Format
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| /linux/Documentation/arch/powerpc/ |
| H A D | pci_iov_resource_on_powernv.rst | 235 total_VFs is less than 256, we have the situation in Figure 1.0, where
253 Figure 1.0 Direct map VF(n) BAR space
256 space doesn't need that much, as shown in Figure 1.1::
272 Figure 1.1 Map VF(n) BAR space + extra
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| /linux/Documentation/userspace-api/media/v4l/ |
| H A D | dev-raw-vbi.rst | 224 **Figure 4.1. Line synchronization**
232 **Figure 4.2. ITU-R 525 line numbering (M/NTSC and M/PAL)**
240 **Figure 4.3. ITU-R 625 line numbering**
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| H A D | vidioc-g-sliced-vbi-cap.rst | 151 - Byte number 3 to 15 according to Figure 9 of ETS 300 231, lsb
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| H A D | dev-sliced-vbi.rst | 242 - Byte number 3 to 15 according to Figure 9 of ETS 300 231, lsb
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| /linux/drivers/leds/ |
| H A D | TODO | 32 * Figure out what to do with RGB leds
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| /linux/Documentation/driver-api/acpi/ |
| H A D | linuxized-acpica.rst | 78 Figure 1. Linux ACPI Software Components
169 Figure 2. ACPICA -> Linux Upstream Process
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| /linux/Documentation/translations/zh_CN/core-api/ |
| H A D | rbtree.rst | 114 /* Figure out where to put new node */
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| /linux/Documentation/filesystems/ |
| H A D | ubifs-authentication.rst | 73 Figure 1: Linux kernel subsystems for dealing with raw flash
181 Figure 2: UBIFS flash layout of log area with commit start nodes
311 Figure 3: Coverage areas of index node hash and master node HMAC
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| /linux/arch/arm64/boot/dts/ti/ |
| H A D | k3-am625-beagleplay.dts | 89 /* Internal power on time(Figure 8-3) * 2 */
91 /* Re-enable time(Figure 8-2) + 20uS */
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| H A D | k3-am65-main.dtsi | 1018 * DIV1. See "Figure 12-3365. DSS Integration"
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| /linux/tools/perf/Documentation/ |
| H A D | perf-list.txt | 114 layout of IA32_PERFEVTSELx MSRs (see [Intel® 64 and IA-32 Architectures Software Developer's Manual Volume 3B: System Programming Guide] Figure 30-1 Layout
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| /linux/Documentation/core-api/ |
| H A D | rbtree.rst | 122 /* Figure out where to put new node */
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| /linux/Documentation/translations/it_IT/doc-guide/ |
| H A D | sphinx.rst | 409 Figure ed immagini
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| /linux/Documentation/networking/ |
| H A D | switchdev.rst | 18 Figure 1 is a block diagram showing the components of the switchdev model for
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| /linux/arch/arm/mm/ |
| H A D | Kconfig | 446 # Figure out what processor architecture version we should be using.
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| /linux/tools/memory-model/Documentation/ |
| H A D | explanation.txt | 245 impossible. (Exercise: Figure out the reasoning.) But TSO allows
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