/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #define MIN_SHARED_IRQ 16 #define MAX_SHARED_IRQ 23 #define TOTAL_SHARED_IRQ (MAX_SHARED_IRQ - MIN_SHARED_IRQ + 1) #define MAX_IRQS 120 #define IDX2PIN(i) (enum pci_pin)((i) + PCI_INT_A) #define PIN2IDX(p) (size_t)((p) - PCI_INT_A) struct pin_info { enum pin_state { FREE_PIN, SHARED_IRQ_PIN, UNIQUE_IRQ_PIN, } pin_state; unsigned int usage_count; unsigned int irq; }; static unsigned int irq_share_count[TOTAL_SHARED_IRQ]; /* * Assign PCI IRQs & pins according to controller rules. * * This information is provided to the FSP in order for it to do the * programming; this is required because the FSP is also responsible for * enabling some PCI devices so they will show up on their respective PCI * buses. The FSP & PCH BIOS Specification contain rules for how certain IPs * require their interrupt pin and interrupt line to be programmed. * * IOAPIC IRQs are used for PCI devices & GPIOs. The GPIO IRQs are fixed in * hardware (the IRQ field is RO), and often start at 24, which means * conflicts with PCI devices (if using the default FSP configuration) are very * possible. * * These are the rules: * 1) One entry per slot/function * 2) Functions using PIRQs must use IOxAPIC IRQs 16-23 * 3) Single-function devices must use INTA * 4) Each slot must have consistent INTx<->PIRQy mappings * 5) Some functions have special interrupt pin requirements (FIXED_INT_ANY_PIRQ) * 6) PCI Express RPs must be assigned in a special way (FIXED_INT_PIRQ) * 7) Some functions require a unique IRQ number (mostly LPSS devices, DIRECT_IRQ) * 8) PCI functions must avoid sharing an IRQ with a GPIO pad which routes its * IRQ through IO-APIC. */ static int find_free_unique_irq(void) { static unsigned int next_irq = MAX_SHARED_IRQ + 1; while (next_irq < MAX_IRQS && gpio_routes_ioapic_irq(next_irq)) ++next_irq; if (next_irq == MAX_IRQS) return INVALID_IRQ; return next_irq++; } static enum pci_pin find_free_pin(const struct pin_info pin_info[PCI_INT_MAX]) { for (size_t pin_idx = 0; pin_idx < PCI_INT_MAX; pin_idx++) { if (pin_info[pin_idx].pin_state == FREE_PIN) return IDX2PIN(pin_idx); } return PCI_INT_NONE; } static enum pci_pin find_shareable_pin(const struct pin_info pin_info[PCI_INT_MAX]) { unsigned int least_shared = 255; int least_index = -1; for (size_t pin_idx = 0; pin_idx < PCI_INT_MAX; pin_idx++) { if (pin_info[pin_idx].pin_state == SHARED_IRQ_PIN && pin_info[pin_idx].usage_count < least_shared) { least_shared = pin_info[pin_idx].usage_count; least_index = pin_idx; } } if (least_index < 0) return PCI_INT_NONE; return IDX2PIN(least_index); } static enum pirq find_global_least_used_pirq(void) { unsigned int least_shared = 255; int least_index = -1; for (size_t i = 0; i < TOTAL_SHARED_IRQ; i++) { if (irq_share_count[i] < least_shared) { least_shared = irq_share_count[i]; least_index = i; } } if (least_index >= 0) return (enum pirq)least_index + PIRQ_A; return PIRQ_INVALID; } static int pirq_to_irq(enum pirq pirq) { return pirq_idx(pirq) + MIN_SHARED_IRQ; } static bool assign_pirq(struct pin_info pin_info[PCI_INT_MAX], enum pci_pin pin, enum pirq pirq) { if (pirq < PIRQ_A || pirq > PIRQ_H) { printk(BIOS_ERR, "Invalid pirq constraint %u\n", pirq); return false; } const int irq = pirq_to_irq(pirq); pin_info[PIN2IDX(pin)].irq = irq; irq_share_count[pirq_idx(pirq)]++; return true; } static bool assign_pin(enum pci_pin pin, unsigned int fn, enum pin_state state, struct pin_info *pin_info, enum pci_pin fn_pin_map[MAX_FNS]) { if (pin < PCI_INT_A || pin > PCI_INT_D) { printk(BIOS_ERR, "Invalid pin constraint %u\n", pin); return false; } const size_t pin_idx = PIN2IDX(pin); pin_info[pin_idx].pin_state = state; pin_info[pin_idx].usage_count++; fn_pin_map[fn] = pin; return true; } static bool assign_fixed_pins(const struct slot_irq_constraints *constraints, struct pin_info *pin_info, enum pci_pin fn_pin_map[MAX_FNS]) { for (size_t i = 0; i < MAX_FNS; i++) { const enum pci_pin fixed_int_pin = constraints->fns[i].fixed_int_pin; if (fixed_int_pin == PCI_INT_NONE) continue; if (!assign_pin(fixed_int_pin, i, SHARED_IRQ_PIN, pin_info, fn_pin_map)) return false; } return true; } static bool assign_fixed_pirqs(const struct slot_irq_constraints *constraints, struct pin_info *pin_info, enum pci_pin fn_pin_map[MAX_FNS]) { for (size_t i = 0; i < MAX_FNS; i++) { const enum pirq fixed_pirq = constraints->fns[i].fixed_pirq; if (fixed_pirq == PIRQ_INVALID) continue; /* A constraint with a fixed pirq is assumed to also have a fixed pin */ const enum pci_pin pin = fn_pin_map[i]; if (pin == PCI_INT_NONE) { printk(BIOS_ERR, "Slot %u, pirq %u, no pin for function %zu\n", constraints->slot, fixed_pirq, i); return false; } if (!assign_pirq(pin_info, pin, fixed_pirq)) return false; } return true; } static bool assign_direct_irqs(const struct slot_irq_constraints *constraints, struct pin_info *pin_info, enum pci_pin fn_pin_map[MAX_FNS]) { for (size_t i = 0; i < MAX_FNS; i++) { if (constraints->fns[i].irq_route != IRQ_DIRECT) continue; enum pci_pin pin = find_free_pin(pin_info); if (pin == PCI_INT_NONE) return false; if (!assign_pin(pin, i, UNIQUE_IRQ_PIN, pin_info, fn_pin_map)) return false; const int irq = find_free_unique_irq(); if (irq == INVALID_IRQ) { printk(BIOS_ERR, "No free unique IRQs found\n"); return false; } const size_t pin_idx = PIN2IDX(pin); pin_info[pin_idx].irq = irq; } return true; } static bool assign_shareable_pins(const struct slot_irq_constraints *constraints, struct pin_info *pin_info, enum pci_pin fn_pin_map[MAX_FNS]) { for (size_t i = 0; i < MAX_FNS; i++) { if (constraints->fns[i].irq_route != IRQ_PIRQ) continue; if (fn_pin_map[i] == PCI_INT_NONE) { enum pci_pin pin = find_free_pin(pin_info); if (pin == PCI_INT_NONE) { pin = find_shareable_pin(pin_info); if (pin == PCI_INT_NONE) { printk(BIOS_ERR, "No shareable pins found\n"); return false; } } if (!assign_pin(pin, i, SHARED_IRQ_PIN, pin_info, fn_pin_map)) return false; } } return true; } static bool assign_pirqs(struct pin_info pin_info[PCI_INT_MAX]) { for (size_t pin_idx = 0; pin_idx < PCI_INT_MAX; pin_idx++) { if (pin_info[pin_idx].pin_state != SHARED_IRQ_PIN || pin_info[pin_idx].irq != 0) continue; enum pirq pirq = find_global_least_used_pirq(); if (pirq == PIRQ_INVALID) return false; if (!assign_pirq(pin_info, IDX2PIN(pin_idx), pirq)) return false; } return true; } static void add_entry(struct pci_irq_entry **head, pci_devfn_t devfn, enum pci_pin pin, unsigned int irq) { struct pci_irq_entry *entry = malloc(sizeof(*entry)); struct pci_irq_entry **tmp = head; entry->devfn = devfn; entry->pin = pin; entry->irq = irq; entry->next = NULL; while (*tmp) tmp = &(*tmp)->next; *tmp = entry; } static void add_slot_entries(struct pci_irq_entry **head, unsigned int slot, struct pin_info pin_info[PCI_INT_MAX], const enum pci_pin fn_pin_map[MAX_FNS]) { for (size_t fn = 0; fn < MAX_FNS; fn++) { if (fn_pin_map[fn] == PCI_INT_NONE) continue; const size_t pin_idx = PIN2IDX(fn_pin_map[fn]); add_entry(head, PCI_DEVFN(slot, fn), fn_pin_map[fn], pin_info[pin_idx].irq); } } static bool assign_slot(struct pci_irq_entry **head, const struct slot_irq_constraints *constraints) { struct pin_info pin_info[PCI_INT_MAX] = {0}; enum pci_pin fn_pin_map[MAX_FNS] = {0}; /* The order in which pins are assigned is important in that strict constraints must * be resolved first. This means fixed_int_pin -> fixed_pirq -> direct route -> * shared pins -> shared pirqs */ if (!assign_fixed_pins(constraints, pin_info, fn_pin_map)) return false; if (!assign_fixed_pirqs(constraints, pin_info, fn_pin_map)) return false; if (!assign_direct_irqs(constraints, pin_info, fn_pin_map)) return false; if (!assign_shareable_pins(constraints, pin_info, fn_pin_map)) return false; if (!assign_pirqs(pin_info)) return false; add_slot_entries(head, constraints->slot, pin_info, fn_pin_map); return true; } static struct pci_irq_entry *cached_entries; bool assign_pci_irqs(const struct slot_irq_constraints *constraints, size_t num_slots) { for (size_t i = 0; i < num_slots; i++) { if (!assign_slot(&cached_entries, &constraints[i])) return false; } const struct pci_irq_entry *entry = cached_entries; while (entry) { printk(BIOS_INFO, "PCI %2X.%X, %s, using IRQ #%d\n", PCI_SLOT(entry->devfn), PCI_FUNC(entry->devfn), pin_to_str(entry->pin), entry->irq); entry = entry->next; } return true; } const struct pci_irq_entry *get_cached_pci_irqs(void) { return cached_entries; } static enum pirq irq_to_pirq(unsigned int irq) { if (irq >= MIN_SHARED_IRQ && irq <= MAX_SHARED_IRQ) return (enum pirq)(irq - MIN_SHARED_IRQ + PIRQ_A); else /* * Unknown if devices that require unique IRQs will * even work in legacy PIC mode, given they cannot map * to a PIRQ, therefore skip adding an entry. */ return PIRQ_INVALID; } bool generate_pin_irq_map(void) { struct slot_pin_irq_map *pin_irq_map; const uint8_t *legacy_pirq_routing; struct pic_pirq_map pirq_map = {0}; size_t map_count = 0; size_t pirq_routes; size_t i; if (!cached_entries) return false; pin_irq_map = calloc(MAX_SLOTS * PCI_INT_MAX, sizeof(struct slot_pin_irq_map)); pirq_map.type = PIRQ_GSI; legacy_pirq_routing = lpc_get_pic_pirq_routing(&pirq_routes); for (i = 0; i < PIRQ_COUNT && i < pirq_routes; i++) pirq_map.gsi[i] = legacy_pirq_routing[i]; const struct pci_irq_entry *entry = cached_entries; while (entry) { const unsigned int slot = PCI_SLOT(entry->devfn); if (is_slot_pin_assigned(pin_irq_map, map_count, slot, entry->pin)) { entry = entry->next; continue; } pin_irq_map[map_count].slot = slot; pin_irq_map[map_count].pin = entry->pin; pin_irq_map[map_count].apic_gsi = entry->irq; pin_irq_map[map_count].pic_pirq = irq_to_pirq(entry->irq); map_count++; entry = entry->next; } intel_write_pci_PRT("\\_SB.PCI0", pin_irq_map, map_count, &pirq_map); free(pin_irq_map); return true; } bool __weak is_pch_slot(unsigned int devfn) { if (PCI_SLOT(devfn) >= MIN_PCH_SLOT) return true; return false; } bool irq_program_non_pch(void) { const struct pci_irq_entry *entry = cached_entries; if (!entry) return false; while (entry) { if (is_pch_slot(entry->devfn)) { entry = entry->next; continue; } if (entry->irq) { pci_devfn_t dev = PCI_DEV(0, PCI_SLOT(entry->devfn), PCI_FUNC(entry->devfn)); pci_s_write_config8(dev, PCI_INTERRUPT_LINE, entry->irq); pci_s_write_config8(dev, PCI_INTERRUPT_PIN, (uint8_t)entry->pin); } entry = entry->next; } return true; } int get_pci_devfn_irq(unsigned int devfn) { const struct pci_irq_entry *entry = cached_entries; while (entry) { if (entry->devfn == devfn) return entry->irq; entry = entry->next; } return INVALID_IRQ; }