1 =============================================== 2 The irq_domain interrupt number mapping library 3 =============================================== 4 5 The current design of the Linux kernel uses a single large number 6 space where each separate IRQ source is assigned a different number. 7 This is simple when there is only one interrupt controller, but in 8 systems with multiple interrupt controllers the kernel must ensure 9 that each one gets assigned non-overlapping allocations of Linux 10 IRQ numbers. 11 12 The number of interrupt controllers registered as unique irqchips 13 show a rising tendency: for example subdrivers of different kinds 14 such as GPIO controllers avoid reimplementing identical callback 15 mechanisms as the IRQ core system by modelling their interrupt 16 handlers as irqchips, i.e. in effect cascading interrupt controllers. 17 18 Here the interrupt number loose all kind of correspondence to 19 hardware interrupt numbers: whereas in the past, IRQ numbers could 20 be chosen so they matched the hardware IRQ line into the root 21 interrupt controller (i.e. the component actually fireing the 22 interrupt line to the CPU) nowadays this number is just a number. 23 24 For this reason we need a mechanism to separate controller-local 25 interrupt numbers, called hardware irq's, from Linux IRQ numbers. 26 27 The irq_alloc_desc*() and irq_free_desc*() APIs provide allocation of 28 irq numbers, but they don't provide any support for reverse mapping of 29 the controller-local IRQ (hwirq) number into the Linux IRQ number 30 space. 31 32 The irq_domain library adds mapping between hwirq and IRQ numbers on 33 top of the irq_alloc_desc*() API. An irq_domain to manage mapping is 34 preferred over interrupt controller drivers open coding their own 35 reverse mapping scheme. 36 37 irq_domain also implements translation from an abstract irq_fwspec 38 structure to hwirq numbers (Device Tree and ACPI GSI so far), and can 39 be easily extended to support other IRQ topology data sources. 40 41 irq_domain usage 42 ================ 43 44 An interrupt controller driver creates and registers an irq_domain by 45 calling one of the irq_domain_add_*() or irq_domain_create_*() functions 46 (each mapping method has a different allocator function, more on that later). 47 The function will return a pointer to the irq_domain on success. The caller 48 must provide the allocator function with an irq_domain_ops structure. 49 50 In most cases, the irq_domain will begin empty without any mappings 51 between hwirq and IRQ numbers. Mappings are added to the irq_domain 52 by calling irq_create_mapping() which accepts the irq_domain and a 53 hwirq number as arguments. If a mapping for the hwirq doesn't already 54 exist then it will allocate a new Linux irq_desc, associate it with 55 the hwirq, and call the .map() callback so the driver can perform any 56 required hardware setup. 57 58 Once a mapping has been established, it can be retrieved or used via a 59 variety of methods: 60 61 - irq_resolve_mapping() returns a pointer to the irq_desc structure 62 for a given domain and hwirq number, and NULL if there was no 63 mapping. 64 - irq_find_mapping() returns a Linux IRQ number for a given domain and 65 hwirq number, and 0 if there was no mapping 66 - irq_linear_revmap() is now identical to irq_find_mapping(), and is 67 deprecated 68 - generic_handle_domain_irq() handles an interrupt described by a 69 domain and a hwirq number 70 71 Note that irq domain lookups must happen in contexts that are 72 compatible with a RCU read-side critical section. 73 74 The irq_create_mapping() function must be called *at least once* 75 before any call to irq_find_mapping(), lest the descriptor will not 76 be allocated. 77 78 If the driver has the Linux IRQ number or the irq_data pointer, and 79 needs to know the associated hwirq number (such as in the irq_chip 80 callbacks) then it can be directly obtained from irq_data->hwirq. 81 82 Types of irq_domain mappings 83 ============================ 84 85 There are several mechanisms available for reverse mapping from hwirq 86 to Linux irq, and each mechanism uses a different allocation function. 87 Which reverse map type should be used depends on the use case. Each 88 of the reverse map types are described below: 89 90 Linear 91 ------ 92 93 :: 94 95 irq_domain_add_linear() 96 irq_domain_create_linear() 97 98 The linear reverse map maintains a fixed size table indexed by the 99 hwirq number. When a hwirq is mapped, an irq_desc is allocated for 100 the hwirq, and the IRQ number is stored in the table. 101 102 The Linear map is a good choice when the maximum number of hwirqs is 103 fixed and a relatively small number (~ < 256). The advantages of this 104 map are fixed time lookup for IRQ numbers, and irq_descs are only 105 allocated for in-use IRQs. The disadvantage is that the table must be 106 as large as the largest possible hwirq number. 107 108 irq_domain_add_linear() and irq_domain_create_linear() are functionally 109 equivalent, except for the first argument is different - the former 110 accepts an Open Firmware specific 'struct device_node', while the latter 111 accepts a more general abstraction 'struct fwnode_handle'. 112 113 The majority of drivers should use the linear map. 114 115 Tree 116 ---- 117 118 :: 119 120 irq_domain_add_tree() 121 irq_domain_create_tree() 122 123 The irq_domain maintains a radix tree map from hwirq numbers to Linux 124 IRQs. When an hwirq is mapped, an irq_desc is allocated and the 125 hwirq is used as the lookup key for the radix tree. 126 127 The tree map is a good choice if the hwirq number can be very large 128 since it doesn't need to allocate a table as large as the largest 129 hwirq number. The disadvantage is that hwirq to IRQ number lookup is 130 dependent on how many entries are in the table. 131 132 irq_domain_add_tree() and irq_domain_create_tree() are functionally 133 equivalent, except for the first argument is different - the former 134 accepts an Open Firmware specific 'struct device_node', while the latter 135 accepts a more general abstraction 'struct fwnode_handle'. 136 137 Very few drivers should need this mapping. 138 139 No Map 140 ------ 141 142 :: 143 144 irq_domain_add_nomap() 145 146 The No Map mapping is to be used when the hwirq number is 147 programmable in the hardware. In this case it is best to program the 148 Linux IRQ number into the hardware itself so that no mapping is 149 required. Calling irq_create_direct_mapping() will allocate a Linux 150 IRQ number and call the .map() callback so that driver can program the 151 Linux IRQ number into the hardware. 152 153 Most drivers cannot use this mapping, and it is now gated on the 154 CONFIG_IRQ_DOMAIN_NOMAP option. Please refrain from introducing new 155 users of this API. 156 157 Legacy 158 ------ 159 160 :: 161 162 irq_domain_add_simple() 163 irq_domain_add_legacy() 164 irq_domain_create_simple() 165 irq_domain_create_legacy() 166 167 The Legacy mapping is a special case for drivers that already have a 168 range of irq_descs allocated for the hwirqs. It is used when the 169 driver cannot be immediately converted to use the linear mapping. For 170 example, many embedded system board support files use a set of #defines 171 for IRQ numbers that are passed to struct device registrations. In that 172 case the Linux IRQ numbers cannot be dynamically assigned and the legacy 173 mapping should be used. 174 175 As the name implies, the \*_legacy() functions are deprecated and only 176 exist to ease the support of ancient platforms. No new users should be 177 added. Same goes for the \*_simple() functions when their use results 178 in the legacy behaviour. 179 180 The legacy map assumes a contiguous range of IRQ numbers has already 181 been allocated for the controller and that the IRQ number can be 182 calculated by adding a fixed offset to the hwirq number, and 183 visa-versa. The disadvantage is that it requires the interrupt 184 controller to manage IRQ allocations and it requires an irq_desc to be 185 allocated for every hwirq, even if it is unused. 186 187 The legacy map should only be used if fixed IRQ mappings must be 188 supported. For example, ISA controllers would use the legacy map for 189 mapping Linux IRQs 0-15 so that existing ISA drivers get the correct IRQ 190 numbers. 191 192 Most users of legacy mappings should use irq_domain_add_simple() or 193 irq_domain_create_simple() which will use a legacy domain only if an IRQ range 194 is supplied by the system and will otherwise use a linear domain mapping. 195 The semantics of this call are such that if an IRQ range is specified then 196 descriptors will be allocated on-the-fly for it, and if no range is 197 specified it will fall through to irq_domain_add_linear() or 198 irq_domain_create_linear() which means *no* irq descriptors will be allocated. 199 200 A typical use case for simple domains is where an irqchip provider 201 is supporting both dynamic and static IRQ assignments. 202 203 In order to avoid ending up in a situation where a linear domain is 204 used and no descriptor gets allocated it is very important to make sure 205 that the driver using the simple domain call irq_create_mapping() 206 before any irq_find_mapping() since the latter will actually work 207 for the static IRQ assignment case. 208 209 irq_domain_add_simple() and irq_domain_create_simple() as well as 210 irq_domain_add_legacy() and irq_domain_create_legacy() are functionally 211 equivalent, except for the first argument is different - the former 212 accepts an Open Firmware specific 'struct device_node', while the latter 213 accepts a more general abstraction 'struct fwnode_handle'. 214 215 Hierarchy IRQ domain 216 -------------------- 217 218 On some architectures, there may be multiple interrupt controllers 219 involved in delivering an interrupt from the device to the target CPU. 220 Let's look at a typical interrupt delivering path on x86 platforms:: 221 222 Device --> IOAPIC -> Interrupt remapping Controller -> Local APIC -> CPU 223 224 There are three interrupt controllers involved: 225 226 1) IOAPIC controller 227 2) Interrupt remapping controller 228 3) Local APIC controller 229 230 To support such a hardware topology and make software architecture match 231 hardware architecture, an irq_domain data structure is built for each 232 interrupt controller and those irq_domains are organized into hierarchy. 233 When building irq_domain hierarchy, the irq_domain near to the device is 234 child and the irq_domain near to CPU is parent. So a hierarchy structure 235 as below will be built for the example above:: 236 237 CPU Vector irq_domain (root irq_domain to manage CPU vectors) 238 ^ 239 | 240 Interrupt Remapping irq_domain (manage irq_remapping entries) 241 ^ 242 | 243 IOAPIC irq_domain (manage IOAPIC delivery entries/pins) 244 245 There are four major interfaces to use hierarchy irq_domain: 246 247 1) irq_domain_alloc_irqs(): allocate IRQ descriptors and interrupt 248 controller related resources to deliver these interrupts. 249 2) irq_domain_free_irqs(): free IRQ descriptors and interrupt controller 250 related resources associated with these interrupts. 251 3) irq_domain_activate_irq(): activate interrupt controller hardware to 252 deliver the interrupt. 253 4) irq_domain_deactivate_irq(): deactivate interrupt controller hardware 254 to stop delivering the interrupt. 255 256 Following changes are needed to support hierarchy irq_domain: 257 258 1) a new field 'parent' is added to struct irq_domain; it's used to 259 maintain irq_domain hierarchy information. 260 2) a new field 'parent_data' is added to struct irq_data; it's used to 261 build hierarchy irq_data to match hierarchy irq_domains. The irq_data 262 is used to store irq_domain pointer and hardware irq number. 263 3) new callbacks are added to struct irq_domain_ops to support hierarchy 264 irq_domain operations. 265 266 With support of hierarchy irq_domain and hierarchy irq_data ready, an 267 irq_domain structure is built for each interrupt controller, and an 268 irq_data structure is allocated for each irq_domain associated with an 269 IRQ. Now we could go one step further to support stacked(hierarchy) 270 irq_chip. That is, an irq_chip is associated with each irq_data along 271 the hierarchy. A child irq_chip may implement a required action by 272 itself or by cooperating with its parent irq_chip. 273 274 With stacked irq_chip, interrupt controller driver only needs to deal 275 with the hardware managed by itself and may ask for services from its 276 parent irq_chip when needed. So we could achieve a much cleaner 277 software architecture. 278 279 For an interrupt controller driver to support hierarchy irq_domain, it 280 needs to: 281 282 1) Implement irq_domain_ops.alloc and irq_domain_ops.free 283 2) Optionally implement irq_domain_ops.activate and 284 irq_domain_ops.deactivate. 285 3) Optionally implement an irq_chip to manage the interrupt controller 286 hardware. 287 4) No need to implement irq_domain_ops.map and irq_domain_ops.unmap, 288 they are unused with hierarchy irq_domain. 289 290 Hierarchy irq_domain is in no way x86 specific, and is heavily used to 291 support other architectures, such as ARM, ARM64 etc. 292 293 Debugging 294 ========= 295 296 Most of the internals of the IRQ subsystem are exposed in debugfs by 297 turning CONFIG_GENERIC_IRQ_DEBUGFS on.
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