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Searched refs:IRQ (Results 1 – 25 of 334) sorted by relevance

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/linux/Documentation/translations/zh_CN/core-api/irq/
H A D	irq-domain.rst	16 目前Linux内核的设计使用了一个巨大的数字空间，每个独立的IRQ源都被分配了一个不 19 个中断控制器都能得到非重复的Linux IRQ号（数字）分配。 23 避免了重新实现与IRQ核心系统相同的回调机制。 25 在这里，中断号与硬件中断号离散了所有种类的对应关系：而在过去，IRQ号可以选择， 26 使它们与硬件IRQ线进入根中断控制器（即实际向CPU发射中断线的组件）相匹配，现 29 出于这个原因，我们需要一种机制将控制器本地中断号（即硬件irq编号）与Linux IRQ 33 提供任何对控制器本地IRQ(hwirq)号到Linux IRQ号空间的反向映射的支持。 35 irq_domain 库在 irq_alloc_desc*() API 的基础上增加了 hwirq 和 IRQ 号码 40 Device Tree和ACPI GSI），并且可以很容易地扩展以支持其它IRQ拓扑数据源。 50 在大多数情况下，irq_domain在开始时是空的，没有任何hwirq和IRQ号之间的映射。 [all …]
H A D	concepts.rst	12 什么是IRQ？ 15 IRQ (Interrupt ReQuest) 指来自设备的中断请求。 17 多个设备可以连接到同一个引脚，从而共享一个IRQ。 19 IRQ编号是用来描述硬件中断源的内核标识符。通常它是一个到全局irq_desc数组的索引， 22 IRQ编号是对机器上可能的中断源的枚举。通常枚举的是系统中所有中断控制器的输入引脚 25 体系结构可以给IRQ号赋予额外的含义，在涉及到硬件手动配置的情况下，我们鼓励这样做。 26 ISA IRQ是赋予这种额外含义的一个典型例子。
H A D	irq-affinity.rst	12 SMP IRQ 亲和性 20 /proc/irq/IRQ#/smp_affinity和/proc/irq/IRQ#/smp_affinity_list指定了哪些CPU能 21 够关联到一个给定的IRQ源，这两个文件包含了这些指定cpu的cpu位掩码(smp_affinity)和cpu列 22 表(smp_affinity_list)。它不允许关闭所有CPU，同时如果IRQ控制器不支持中断请求亲和 23 (IRQ affinity)，那么所有cpu的默认值将保持不变(即关联到所有CPU). 25 /proc/irq/default_smp_affinity指明了适用于所有非激活IRQ的默认亲和性掩码。一旦IRQ被 50 现在让我们把这个IRQ限制在CPU(4-7)。
/linux/Documentation/translations/zh_CN/core-api/
H A D	genericirq.rst	18 Linux通用IRQ处理 32 本文档提供给那些希望在通用IRQ处理层的帮助下实现基于其架构的中断子系统的开发 58 这种高层IRQ处理程序的拆分实现使我们能够为每个特定的中断类型优化中断处理的流 61 最初的通用IRQ实现使用hw_interrupt_type结构体及其 ``->ack`` ``->end`` 等回 64 这两个IRQ类型共享许多低级的细节，但有不同的流处理。 68 分析一些架构的IRQ子系统的实现可以发现，他们中的大多数可以使用一套通用的“irq 69 流”方法，只需要添加芯片级的特定代码。这种分离对于那些需要IRQ流本身而不需要芯 70 片细节的特定（子）架构也很有价值——以提供了一个更透明的IRQ子系统设计。 77 的IRQ流实现“电平触发型”中断，并添加一个（子）架构特定的“边沿型”实现。 81 被使用，因为它能使IRQ子系统更小更干净。它已经被废弃三年了，即将被删除。 [all …]
/linux/Documentation/arch/arm/
H A D	interrupts.rst	`16 Secondly, the IRQ subsystem. 39 SA1111 IRQ handler, SA1111 IRQs can hold off SMC9196 IRQs indefinitely. 48 We also bring the idea of an IRQ "chip" (mainly to reduce the size of 57 * Acknowledge the IRQ. 58 * If this is a level-based IRQ, then it is expected to mask the IRQ 63 * Mask the IRQ in hardware. 67 * Unmask the IRQ in hardware. 71 * Re-run the IRQ 75 * Set the type of the IRQ. 90 the hardware IRQ if possible. If not, may call the handler [all …]`
/linux/Documentation/translations/zh_TW/
H A D	IRQ.txt	26 何爲 IRQ? 28 一個 IRQ 是來自某個設備的一個中斷請求。目前，它們可以來自一個硬體引腳， 29 或來自一個數據包。多個設備可能連接到同個硬體引腳，從而共享一個 IRQ。 31 一個 IRQ 編號是用於告知硬體中斷源的內核標識。通常情況下，這是一個 35 一個 IRQ 編號是設備上某個可能的中斷源的枚舉。通常情況下，枚舉的編號是 39 架構可以對 IRQ 編號指定額外的含義，在硬體涉及任何手工配置的情況下， 40 是被提倡的。ISA 的 IRQ 是一個分配這類額外含義的典型例子。
/linux/Documentation/misc-devices/
H A D	pci-endpoint-test.rst	`16 #) raise legacy IRQ 17 #) raise MSI IRQ 18 #) raise MSI-X IRQ 34 Tests legacy IRQ 42 Changes driver IRQ type configuration. The IRQ type 45 Gets driver IRQ type configuration.`
/linux/Documentation/driver-api/hte/
H A D	tegra-hte.rst	10 (Legacy Interrupt Controller) IRQ GTE. Both GTE instances get the timestamp 34 LIC (Legacy Interrupt Controller) IRQ GTE 37 This GTE instance timestamps LIC IRQ lines in real time. The hte devicetree 39 provides an example of how a consumer can request an IRQ line. Since it is a 40 one-to-one mapping with IRQ GTE provider, consumers can simply specify the IRQ 44 The provider source code of both IRQ and GPIO GTE instances is located at 46 ``drivers/hte/hte-tegra194-test.c`` demonstrates HTE API usage for both IRQ
/linux/Documentation/core-api/irq/
H A D	concepts.rst	`2 What is an IRQ? 5 An IRQ is an interrupt request from a device. Currently, they can come 7 the same pin thus sharing an IRQ. Such as on legacy PCI bus: All devices 11 An IRQ number is a kernel identifier used to talk about a hardware 16 An IRQ number is an enumeration of the possible interrupt sources on a 22 Architectures can assign additional meaning to the IRQ numbers, and`
/linux/Documentation/translations/zh_TW/arch/loongarch/
H A D	irq-chip-model.rst	`9 LoongArch的IRQ芯片模型（層級關係） 13 中的中斷控制器（即IRQ芯片）包括CPUINTC（CPU Core Interrupt Controller）、LIOINTC（ 20 斷控制器（在配套芯片組裏面）。這些中斷控制器（或者說IRQ芯片）以一種層次樹的組織形式 21 級聯在一起，一共有兩種層級關係模型（傳統IRQ模型和擴展IRQ模型）。 23 傳統IRQ模型 59 擴展IRQ模型`
/linux/Documentation/core-api/
H A D	genericirq.rst	4 Linux generic IRQ handling 23 generic IRQ handling layer. 51 This split implementation of high-level IRQ handlers allows us to 56 The original general IRQ implementation used hw_interrupt_type 61 ``ioapic_edge_irq`` IRQ-type which share many of the low-level details but 67 Analysing a couple of architecture's IRQ subsystem implementations 71 IRQ flow itself but not in the chip details - and thus provides a more 72 transparent IRQ subsystem design. 82 IRQ-flow implementation for 'level type' interrupts and add a 89 enables smaller and cleaner IRQ subsystems. It's deprecated for three [all …]
/linux/drivers/pinctrl/renesas/
H A D	pfc-r8a73a4.c	236 #define IRQ(a) IRQ##a##_MARK macro 238 F1(LCDD0), F3(PDM2_CLK_0), F7(DU0_DR0), IRQ(0), /* Port0 */ enumerator 239 F1(LCDD1), F3(PDM2_DATA_1), F7(DU0_DR19), IRQ(1), enumerator 240 F1(LCDD2), F3(PDM3_CLK_2), F7(DU0_DR2), IRQ(2), enumerator 241 F1(LCDD3), F3(PDM3_DATA_3), F7(DU0_DR3), IRQ(3), enumerator 242 F1(LCDD4), F3(PDM4_CLK_4), F7(DU0_DR4), IRQ(4), enumerator 243 F1(LCDD5), F3(PDM4_DATA_5), F7(DU0_DR5), IRQ(5), enumerator 244 F1(LCDD6), F3(PDM0_OUTCLK_6), F7(DU0_DR6), IRQ(6), enumerator 245 F1(LCDD7), F3(PDM0_OUTDATA_7), F7(DU0_DR7), IRQ(7), enumerator 246 F1(LCDD8), F3(PDM1_OUTCLK_8), F7(DU0_DG0), IRQ(8), enumerator [all …]
/linux/Documentation/power/
H A D	suspend-and-interrupts.rst	43 The IRQF_NO_SUSPEND flag is used to indicate that to the IRQ subsystem when 45 leave the corresponding IRQ enabled so as to allow the interrupt to work as 50 Note that the IRQF_NO_SUSPEND flag affects the entire IRQ and not just one 51 user of it. Thus, if the IRQ is shared, all of the interrupt handlers installed 54 the IRQ's users. For this reason, using IRQF_NO_SUSPEND and IRQF_SHARED at the 75 The IRQ subsystem provides two helper functions to be used by device drivers for 77 handling the given IRQ as a system wakeup interrupt line and disable_irq_wake() 80 Calling enable_irq_wake() causes suspend_device_irqs() to treat the given IRQ 81 in a special way. Namely, the IRQ remains enabled, but on the first interrupt 105 IRQ subsystem to trigger a system wakeup. [all …]
/linux/Documentation/virt/kvm/devices/
H A D	mpic.rst	`34 IRQ input line for each standard openpic source. 0 is inactive and 1 41 "attr" is the IRQ number. IRQ numbers for standard sources are the 44 IRQ Routing: 46 The MPIC emulation supports IRQ routing. Only a single MPIC device can 58 Access to non-SRC interrupts is not implemented through IRQ routing mechanisms.`
/linux/Documentation/tools/rtla/
H A D	rtla-timerlat-hist.rst	`49 …Index IRQ-000 Thr-000 IRQ-001 Thr-001 IRQ-002 Thr-002 IRQ-003 Thr-003 IRQ-004 …`
H A D	rtla-timerlat-top.rst	`53 0 00:00:12 \| IRQ Timer Latency (us) \| Thread Timer Latency (us) 80 IRQ handler delay: 27.49 us (65.52 %) 81 IRQ latency: 28.13 us 82 Timerlat IRQ duration: 9.59 us (22.85 %) 109 Max timerlat IRQ latency from idle: 17.48 us in cpu 4 112 In this case, the major factor was the delay suffered by the IRQ handler`
/linux/arch/arc/kernel/
H A D	entry-compact.S	118 ;##################### Scratch Mem for IRQ stack switching ############# 152 ; if L2 IRQ interrupted a L1 ISR, disable preemption 155 ; -L1 IRQ taken 157 ; -preemption off IRQ, user task in syscall picked to run 170 bbit0 r9, STATUS_A1_BIT, 1f ; L1 not active when L2 IRQ, so normal 306 ; Restore the saved sys context (common exit-path for EXCPN/IRQ/Trap) 307 ; IRQ shd definitely not happen between now and rtie 320 ; use the same priority as rtie: EXCPN, L2 IRQ, L1 IRQ, None 343 ; if L2 IRQ interrupted an L1 ISR, we'd disabled preemption earlier 350 bbit0 r9, STATUS_A1_BIT, 149f ; L1 not active when L2 IRQ, so normal
/linux/Documentation/arch/x86/i386/
H A D	IO-APIC.rst	17 distribute IRQ load further. 40 none of those IRQ sources is performance-critical. 44 you can use the pirq= boot parameter to 'hand-construct' IRQ entries. This 52 connected to the PCI chipset IRQ routing facility (the incoming PIRQ1-4 65 Every PCI card emits a PCI IRQ, which can be INTA, INTB, INTC or INTD:: 79 a card in slot4, issuing INTA IRQ, it will end up as a signal on PIRQ4 of 81 between the PIRQ lines. (distributing IRQ sources properly is not a 103 [value '0' is a generic 'placeholder', reserved for empty (or non-IRQ emitting) 107 permute all IRQ numbers properly ... it will take some time though. An
/linux/Documentation/scsi/
H A D	g_NCR5380.rst	`22 for the correct IRQ line automatically. If the irq parameter is 0 or 255 23 then no IRQ will be used. 71 E.g. a port mapped NCR5380 board, driver to probe for IRQ:: 79 E.g. a memory mapped NCR53C400 board with no IRQ:: 87 E.g. two cards, DTC3181 (in non-PnP mode) at 0x240 with no IRQ 88 and HP C2502 at 0x300 with IRQ 7::`
/linux/Documentation/devicetree/bindings/iio/accel/
H A D	lis302.txt	`36 - st,irq{1,2}-disable: disable IRQ 1/2 37 - st,irq{1,2}-ff-wu-1: raise IRQ 1/2 on FF_WU_1 condition 38 - st,irq{1,2}-ff-wu-2: raise IRQ 1/2 on FF_WU_2 condition 39 - st,irq{1,2}-data-ready: raise IRQ 1/2 on data ready condition 40 - st,irq{1,2}-click: raise IRQ 1/2 on click condition 41 - st,irq-open-drain: consider IRQ lines open-drain 42 - st,irq-active-low: make IRQ lines active low`
/linux/Documentation/PCI/endpoint/
H A D	pci-test-function.rst	`44 Bit 0 raise legacy IRQ 45 Bit 1 raise MSI IRQ 46 Bit 2 raise MSI-X IRQ 65 Bit 6 IRQ raised 83 for the READ/WRITE/COPY and raise IRQ (Legacy/MSI) commands.`
/linux/Documentation/trace/
H A D	timerlat-tracer.rst	77 - print_stack: save the stack of the IRQ occurrence. The stack is printed 78 after the thread context event, or at the IRQ handler if stop_tracing_us 99 single cause but to multiple ones. Firstly, the timer IRQ was delayed 100 for 13 us, which may point to a long IRQ disabled section (see IRQ 102 thread took 7597 ns, and the qxl:21 device IRQ took 7139 ns. Finally, 110 by the IRQ execution (which indeed accounted for 12736 ns). But 137 IRQ stacktrace 172 the timerlat IRQ handler, points to a function named 205 When the timer IRQ fires, the timerlat IRQ will execute, report the 206 IRQ latency and wake up the thread waiting in the read. The thread will be
/linux/Documentation/devicetree/bindings/bus/
H A D	brcm,bus-axi.txt	`11 Automatic detection of the IRQ number is not working on 12 BCM47xx/BCM53xx ARM SoCs. To assign IRQ numbers to the cores, provide 14 IRQ used by the devices on the bus. The first address is just an index, 19 detected (e.g. IRQ numbers). Also some of the cores may be responsible`
/linux/kernel/irq/
H A D	Kconfig	`2 menu "IRQ subsystem" 75 # Generic IRQ IPI support 81 # Generic IRQ IPI Mux support 141 bool "KUnit tests for IRQ management APIs" if !KUNIT_ALL_TESTS 148 This option enables KUnit tests for the IRQ subsystem API. These are 158 Allow to specify the low level IRQ handler at run time.`
/linux/scripts/coccinelle/misc/
H A D	irqf_oneshot.cocci	`106 msg = "WARNING: Threaded IRQ with no primary handler requested without IRQF_ONESHOT (unless it is n… 112 msg = "WARNING: Threaded IRQ with no primary handler requested without IRQF_ONESHOT (unless it is n…`

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