#include "kvm/pci.h" #include "kvm/ioport.h" #include "kvm/util.h" #include "kvm/kvm.h" #include #define PCI_MAX_DEVICES 256 #define PCI_BAR_OFFSET(b) (offsetof(struct pci_device_header, bar[b])) static struct pci_device_header *pci_devices[PCI_MAX_DEVICES]; static struct pci_config_address pci_config_address; /* This is within our PCI gap - in an unused area */ static u32 io_space_blocks = KVM_32BIT_GAP_START + 0x1000000; u32 pci_get_io_space_block(u32 size) { u32 block = io_space_blocks; io_space_blocks += size; return block; } static void *pci_config_address_ptr(u16 port) { unsigned long offset; void *base; offset = port - PCI_CONFIG_ADDRESS; base = &pci_config_address; return base + offset; } static bool pci_config_address_out(struct ioport *ioport, struct kvm *kvm, u16 port, void *data, int size) { void *p = pci_config_address_ptr(port); memcpy(p, data, size); return true; } static bool pci_config_address_in(struct ioport *ioport, struct kvm *kvm, u16 port, void *data, int size) { void *p = pci_config_address_ptr(port); memcpy(data, p, size); return true; } static struct ioport_operations pci_config_address_ops = { .io_in = pci_config_address_in, .io_out = pci_config_address_out, }; static bool pci_device_exists(u8 bus_number, u8 device_number, u8 function_number) { struct pci_device_header *dev; if (pci_config_address.bus_number != bus_number) return false; if (pci_config_address.function_number != function_number) return false; if (device_number >= PCI_MAX_DEVICES) return false; dev = pci_devices[device_number]; return dev != NULL; } static bool pci_config_data_out(struct ioport *ioport, struct kvm *kvm, u16 port, void *data, int size) { unsigned long start; u8 dev_num; /* * If someone accesses PCI configuration space offsets that are not * aligned to 4 bytes, it uses ioports to signify that. */ start = port - PCI_CONFIG_DATA; dev_num = pci_config_address.device_number; if (pci_device_exists(0, dev_num, 0)) { unsigned long offset; offset = start + (pci_config_address.register_number << 2); if (offset < sizeof(struct pci_device_header)) { void *p = pci_devices[dev_num]; u8 bar = (offset - PCI_BAR_OFFSET(0)) / (sizeof(u32)); u32 sz = PCI_IO_SIZE; if (bar < 6 && pci_devices[dev_num]->bar_size[bar]) sz = pci_devices[dev_num]->bar_size[bar]; /* * If the kernel masks the BAR it would expect to find the * size of the BAR there next time it reads from it. * When the kernel got the size it would write the address * back. */ if (ioport__read32(p + offset)) { /* See if kernel tries to mask one of the BARs */ if ((offset >= PCI_BAR_OFFSET(0)) && (offset <= PCI_BAR_OFFSET(6)) && (ioport__read32(data) == 0xFFFFFFFF)) memcpy(p + offset, &sz, sizeof(sz)); else memcpy(p + offset, data, size); } } } return true; } static bool pci_config_data_in(struct ioport *ioport, struct kvm *kvm, u16 port, void *data, int size) { unsigned long start; u8 dev_num; /* * If someone accesses PCI configuration space offsets that are not * aligned to 4 bytes, it uses ioports to signify that. */ start = port - PCI_CONFIG_DATA; dev_num = pci_config_address.device_number; if (pci_device_exists(0, dev_num, 0)) { unsigned long offset; offset = start + (pci_config_address.register_number << 2); if (offset < sizeof(struct pci_device_header)) { void *p = pci_devices[dev_num]; memcpy(data, p + offset, size); } else memset(data, 0x00, size); } else memset(data, 0xff, size); return true; } static struct ioport_operations pci_config_data_ops = { .io_in = pci_config_data_in, .io_out = pci_config_data_out, }; void pci__register(struct pci_device_header *dev, u8 dev_num) { assert(dev_num < PCI_MAX_DEVICES); pci_devices[dev_num] = dev; } void pci__init(void) { ioport__register(PCI_CONFIG_DATA + 0, &pci_config_data_ops, 4, NULL); ioport__register(PCI_CONFIG_ADDRESS + 0, &pci_config_address_ops, 4, NULL); }