| =============================================== |
| The irq_domain interrupt number mapping library |
| =============================================== |
| |
| The current design of the Linux kernel uses a single large number |
| space where each separate IRQ source is assigned a different number. |
| This is simple when there is only one interrupt controller, but in |
| systems with multiple interrupt controllers the kernel must ensure |
| that each one gets assigned non-overlapping allocations of Linux |
| IRQ numbers. |
| |
| The number of interrupt controllers registered as unique irqchips |
| show a rising tendency: for example subdrivers of different kinds |
| such as GPIO controllers avoid reimplementing identical callback |
| mechanisms as the IRQ core system by modelling their interrupt |
| handlers as irqchips, i.e. in effect cascading interrupt controllers. |
| |
| Here the interrupt number loose all kind of correspondence to |
| hardware interrupt numbers: whereas in the past, IRQ numbers could |
| be chosen so they matched the hardware IRQ line into the root |
| interrupt controller (i.e. the component actually fireing the |
| interrupt line to the CPU) nowadays this number is just a number. |
| |
| For this reason we need a mechanism to separate controller-local |
| interrupt numbers, called hardware irq's, from Linux IRQ numbers. |
| |
| The irq_alloc_desc*() and irq_free_desc*() APIs provide allocation of |
| irq numbers, but they don't provide any support for reverse mapping of |
| the controller-local IRQ (hwirq) number into the Linux IRQ number |
| space. |
| |
| The irq_domain library adds mapping between hwirq and IRQ numbers on |
| top of the irq_alloc_desc*() API. An irq_domain to manage mapping is |
| preferred over interrupt controller drivers open coding their own |
| reverse mapping scheme. |
| |
| irq_domain also implements translation from an abstract irq_fwspec |
| structure to hwirq numbers (Device Tree and ACPI GSI so far), and can |
| be easily extended to support other IRQ topology data sources. |
| |
| irq_domain usage |
| ================ |
| |
| An interrupt controller driver creates and registers an irq_domain by |
| calling one of the irq_domain_add_*() functions (each mapping method |
| has a different allocator function, more on that later). The function |
| will return a pointer to the irq_domain on success. The caller must |
| provide the allocator function with an irq_domain_ops structure. |
| |
| In most cases, the irq_domain will begin empty without any mappings |
| between hwirq and IRQ numbers. Mappings are added to the irq_domain |
| by calling irq_create_mapping() which accepts the irq_domain and a |
| hwirq number as arguments. If a mapping for the hwirq doesn't already |
| exist then it will allocate a new Linux irq_desc, associate it with |
| the hwirq, and call the .map() callback so the driver can perform any |
| required hardware setup. |
| |
| When an interrupt is received, irq_find_mapping() function should |
| be used to find the Linux IRQ number from the hwirq number. |
| |
| The irq_create_mapping() function must be called *atleast once* |
| before any call to irq_find_mapping(), lest the descriptor will not |
| be allocated. |
| |
| If the driver has the Linux IRQ number or the irq_data pointer, and |
| needs to know the associated hwirq number (such as in the irq_chip |
| callbacks) then it can be directly obtained from irq_data->hwirq. |
| |
| Types of irq_domain mappings |
| ============================ |
| |
| There are several mechanisms available for reverse mapping from hwirq |
| to Linux irq, and each mechanism uses a different allocation function. |
| Which reverse map type should be used depends on the use case. Each |
| of the reverse map types are described below: |
| |
| Linear |
| ------ |
| |
| :: |
| |
| irq_domain_add_linear() |
| irq_domain_create_linear() |
| |
| The linear reverse map maintains a fixed size table indexed by the |
| hwirq number. When a hwirq is mapped, an irq_desc is allocated for |
| the hwirq, and the IRQ number is stored in the table. |
| |
| The Linear map is a good choice when the maximum number of hwirqs is |
| fixed and a relatively small number (~ < 256). The advantages of this |
| map are fixed time lookup for IRQ numbers, and irq_descs are only |
| allocated for in-use IRQs. The disadvantage is that the table must be |
| as large as the largest possible hwirq number. |
| |
| irq_domain_add_linear() and irq_domain_create_linear() are functionally |
| equivalent, except for the first argument is different - the former |
| accepts an Open Firmware specific 'struct device_node', while the latter |
| accepts a more general abstraction 'struct fwnode_handle'. |
| |
| The majority of drivers should use the linear map. |
| |
| Tree |
| ---- |
| |
| :: |
| |
| irq_domain_add_tree() |
| irq_domain_create_tree() |
| |
| The irq_domain maintains a radix tree map from hwirq numbers to Linux |
| IRQs. When an hwirq is mapped, an irq_desc is allocated and the |
| hwirq is used as the lookup key for the radix tree. |
| |
| The tree map is a good choice if the hwirq number can be very large |
| since it doesn't need to allocate a table as large as the largest |
| hwirq number. The disadvantage is that hwirq to IRQ number lookup is |
| dependent on how many entries are in the table. |
| |
| irq_domain_add_tree() and irq_domain_create_tree() are functionally |
| equivalent, except for the first argument is different - the former |
| accepts an Open Firmware specific 'struct device_node', while the latter |
| accepts a more general abstraction 'struct fwnode_handle'. |
| |
| Very few drivers should need this mapping. |
| |
| No Map |
| ------ |
| |
| :: |
| |
| irq_domain_add_nomap() |
| |
| The No Map mapping is to be used when the hwirq number is |
| programmable in the hardware. In this case it is best to program the |
| Linux IRQ number into the hardware itself so that no mapping is |
| required. Calling irq_create_direct_mapping() will allocate a Linux |
| IRQ number and call the .map() callback so that driver can program the |
| Linux IRQ number into the hardware. |
| |
| Most drivers cannot use this mapping. |
| |
| Legacy |
| ------ |
| |
| :: |
| |
| irq_domain_add_simple() |
| irq_domain_add_legacy() |
| irq_domain_add_legacy_isa() |
| |
| The Legacy mapping is a special case for drivers that already have a |
| range of irq_descs allocated for the hwirqs. It is used when the |
| driver cannot be immediately converted to use the linear mapping. For |
| example, many embedded system board support files use a set of #defines |
| for IRQ numbers that are passed to struct device registrations. In that |
| case the Linux IRQ numbers cannot be dynamically assigned and the legacy |
| mapping should be used. |
| |
| The legacy map assumes a contiguous range of IRQ numbers has already |
| been allocated for the controller and that the IRQ number can be |
| calculated by adding a fixed offset to the hwirq number, and |
| visa-versa. The disadvantage is that it requires the interrupt |
| controller to manage IRQ allocations and it requires an irq_desc to be |
| allocated for every hwirq, even if it is unused. |
| |
| The legacy map should only be used if fixed IRQ mappings must be |
| supported. For example, ISA controllers would use the legacy map for |
| mapping Linux IRQs 0-15 so that existing ISA drivers get the correct IRQ |
| numbers. |
| |
| Most users of legacy mappings should use irq_domain_add_simple() which |
| will use a legacy domain only if an IRQ range is supplied by the |
| system and will otherwise use a linear domain mapping. The semantics |
| of this call are such that if an IRQ range is specified then |
| descriptors will be allocated on-the-fly for it, and if no range is |
| specified it will fall through to irq_domain_add_linear() which means |
| *no* irq descriptors will be allocated. |
| |
| A typical use case for simple domains is where an irqchip provider |
| is supporting both dynamic and static IRQ assignments. |
| |
| In order to avoid ending up in a situation where a linear domain is |
| used and no descriptor gets allocated it is very important to make sure |
| that the driver using the simple domain call irq_create_mapping() |
| before any irq_find_mapping() since the latter will actually work |
| for the static IRQ assignment case. |
| |
| Hierarchy IRQ domain |
| -------------------- |
| |
| On some architectures, there may be multiple interrupt controllers |
| involved in delivering an interrupt from the device to the target CPU. |
| Let's look at a typical interrupt delivering path on x86 platforms:: |
| |
| Device --> IOAPIC -> Interrupt remapping Controller -> Local APIC -> CPU |
| |
| There are three interrupt controllers involved: |
| |
| 1) IOAPIC controller |
| 2) Interrupt remapping controller |
| 3) Local APIC controller |
| |
| To support such a hardware topology and make software architecture match |
| hardware architecture, an irq_domain data structure is built for each |
| interrupt controller and those irq_domains are organized into hierarchy. |
| When building irq_domain hierarchy, the irq_domain near to the device is |
| child and the irq_domain near to CPU is parent. So a hierarchy structure |
| as below will be built for the example above:: |
| |
| CPU Vector irq_domain (root irq_domain to manage CPU vectors) |
| ^ |
| | |
| Interrupt Remapping irq_domain (manage irq_remapping entries) |
| ^ |
| | |
| IOAPIC irq_domain (manage IOAPIC delivery entries/pins) |
| |
| There are four major interfaces to use hierarchy irq_domain: |
| |
| 1) irq_domain_alloc_irqs(): allocate IRQ descriptors and interrupt |
| controller related resources to deliver these interrupts. |
| 2) irq_domain_free_irqs(): free IRQ descriptors and interrupt controller |
| related resources associated with these interrupts. |
| 3) irq_domain_activate_irq(): activate interrupt controller hardware to |
| deliver the interrupt. |
| 4) irq_domain_deactivate_irq(): deactivate interrupt controller hardware |
| to stop delivering the interrupt. |
| |
| Following changes are needed to support hierarchy irq_domain: |
| |
| 1) a new field 'parent' is added to struct irq_domain; it's used to |
| maintain irq_domain hierarchy information. |
| 2) a new field 'parent_data' is added to struct irq_data; it's used to |
| build hierarchy irq_data to match hierarchy irq_domains. The irq_data |
| is used to store irq_domain pointer and hardware irq number. |
| 3) new callbacks are added to struct irq_domain_ops to support hierarchy |
| irq_domain operations. |
| |
| With support of hierarchy irq_domain and hierarchy irq_data ready, an |
| irq_domain structure is built for each interrupt controller, and an |
| irq_data structure is allocated for each irq_domain associated with an |
| IRQ. Now we could go one step further to support stacked(hierarchy) |
| irq_chip. That is, an irq_chip is associated with each irq_data along |
| the hierarchy. A child irq_chip may implement a required action by |
| itself or by cooperating with its parent irq_chip. |
| |
| With stacked irq_chip, interrupt controller driver only needs to deal |
| with the hardware managed by itself and may ask for services from its |
| parent irq_chip when needed. So we could achieve a much cleaner |
| software architecture. |
| |
| For an interrupt controller driver to support hierarchy irq_domain, it |
| needs to: |
| |
| 1) Implement irq_domain_ops.alloc and irq_domain_ops.free |
| 2) Optionally implement irq_domain_ops.activate and |
| irq_domain_ops.deactivate. |
| 3) Optionally implement an irq_chip to manage the interrupt controller |
| hardware. |
| 4) No need to implement irq_domain_ops.map and irq_domain_ops.unmap, |
| they are unused with hierarchy irq_domain. |
| |
| Hierarchy irq_domain is in no way x86 specific, and is heavily used to |
| support other architectures, such as ARM, ARM64 etc. |
| |
| === Debugging === |
| |
| Most of the internals of the IRQ subsystem are exposed in debugfs by |
| turning CONFIG_GENERIC_IRQ_DEBUGFS on. |