Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Liu Shuo | 970 | 99.49% | 13 | 92.86% |
Andy Shevchenko | 5 | 0.51% | 1 | 7.14% |
Total | 975 | 14 |
/* SPDX-License-Identifier: GPL-2.0 WITH Linux-syscall-note */ /* * Userspace interface for /dev/acrn_hsm - ACRN Hypervisor Service Module * * This file can be used by applications that need to communicate with the HSM * via the ioctl interface. * * Copyright (C) 2021 Intel Corporation. All rights reserved. */ #ifndef _UAPI_ACRN_H #define _UAPI_ACRN_H #include <linux/types.h> #define ACRN_IO_REQUEST_MAX 16 #define ACRN_IOREQ_STATE_PENDING 0 #define ACRN_IOREQ_STATE_COMPLETE 1 #define ACRN_IOREQ_STATE_PROCESSING 2 #define ACRN_IOREQ_STATE_FREE 3 #define ACRN_IOREQ_TYPE_PORTIO 0 #define ACRN_IOREQ_TYPE_MMIO 1 #define ACRN_IOREQ_TYPE_PCICFG 2 #define ACRN_IOREQ_DIR_READ 0 #define ACRN_IOREQ_DIR_WRITE 1 /** * struct acrn_mmio_request - Info of a MMIO I/O request * @direction: Access direction of this request (ACRN_IOREQ_DIR_*) * @reserved: Reserved for alignment and should be 0 * @address: Access address of this MMIO I/O request * @size: Access size of this MMIO I/O request * @value: Read/write value of this MMIO I/O request */ struct acrn_mmio_request { __u32 direction; __u32 reserved; __u64 address; __u64 size; __u64 value; }; /** * struct acrn_pio_request - Info of a PIO I/O request * @direction: Access direction of this request (ACRN_IOREQ_DIR_*) * @reserved: Reserved for alignment and should be 0 * @address: Access address of this PIO I/O request * @size: Access size of this PIO I/O request * @value: Read/write value of this PIO I/O request */ struct acrn_pio_request { __u32 direction; __u32 reserved; __u64 address; __u64 size; __u32 value; }; /** * struct acrn_pci_request - Info of a PCI I/O request * @direction: Access direction of this request (ACRN_IOREQ_DIR_*) * @reserved: Reserved for alignment and should be 0 * @size: Access size of this PCI I/O request * @value: Read/write value of this PIO I/O request * @bus: PCI bus value of this PCI I/O request * @dev: PCI device value of this PCI I/O request * @func: PCI function value of this PCI I/O request * @reg: PCI config space offset of this PCI I/O request * * Need keep same header layout with &struct acrn_pio_request. */ struct acrn_pci_request { __u32 direction; __u32 reserved[3]; __u64 size; __u32 value; __u32 bus; __u32 dev; __u32 func; __u32 reg; }; /** * struct acrn_io_request - 256-byte ACRN I/O request * @type: Type of this request (ACRN_IOREQ_TYPE_*). * @completion_polling: Polling flag. Hypervisor will poll completion of the * I/O request if this flag set. * @reserved0: Reserved fields. * @reqs: Union of different types of request. Byte offset: 64. * @reqs.pio_request: PIO request data of the I/O request. * @reqs.pci_request: PCI configuration space request data of the I/O request. * @reqs.mmio_request: MMIO request data of the I/O request. * @reqs.data: Raw data of the I/O request. * @reserved1: Reserved fields. * @kernel_handled: Flag indicates this request need be handled in kernel. * @processed: The status of this request (ACRN_IOREQ_STATE_*). * * The state transitions of ACRN I/O request: * * FREE -> PENDING -> PROCESSING -> COMPLETE -> FREE -> ... * * An I/O request in COMPLETE or FREE state is owned by the hypervisor. HSM and * ACRN userspace are in charge of processing the others. * * On basis of the states illustrated above, a typical lifecycle of ACRN IO * request would look like: * * Flow (assume the initial state is FREE) * | * | Service VM vCPU 0 Service VM vCPU x User vCPU y * | * | hypervisor: * | fills in type, addr, etc. * | pauses the User VM vCPU y * | sets the state to PENDING (a) * | fires an upcall to Service VM * | * | HSM: * | scans for PENDING requests * | sets the states to PROCESSING (b) * | assigns the requests to clients (c) * V * | client: * | scans for the assigned requests * | handles the requests (d) * | HSM: * | sets states to COMPLETE * | notifies the hypervisor * | * | hypervisor: * | resumes User VM vCPU y (e) * | * | hypervisor: * | post handling (f) * V sets states to FREE * * Note that the procedures (a) to (f) in the illustration above require to be * strictly processed in the order. One vCPU cannot trigger another request of * I/O emulation before completing the previous one. * * Atomic and barriers are required when HSM and hypervisor accessing the state * of &struct acrn_io_request. * */ struct acrn_io_request { __u32 type; __u32 completion_polling; __u32 reserved0[14]; union { struct acrn_pio_request pio_request; struct acrn_pci_request pci_request; struct acrn_mmio_request mmio_request; __u64 data[8]; } reqs; __u32 reserved1; __u32 kernel_handled; __u32 processed; } __attribute__((aligned(256))); struct acrn_io_request_buffer { union { struct acrn_io_request req_slot[ACRN_IO_REQUEST_MAX]; __u8 reserved[4096]; }; }; /** * struct acrn_ioreq_notify - The structure of ioreq completion notification * @vmid: User VM ID * @reserved: Reserved and should be 0 * @vcpu: vCPU ID */ struct acrn_ioreq_notify { __u16 vmid; __u16 reserved; __u32 vcpu; }; /** * struct acrn_vm_creation - Info to create a User VM * @vmid: User VM ID returned from the hypervisor * @reserved0: Reserved and must be 0 * @vcpu_num: Number of vCPU in the VM. Return from hypervisor. * @reserved1: Reserved and must be 0 * @uuid: Empty space never to be used again (used to be UUID of the VM) * @vm_flag: Flag of the VM creating. Pass to hypervisor directly. * @ioreq_buf: Service VM GPA of I/O request buffer. Pass to * hypervisor directly. * @cpu_affinity: CPU affinity of the VM. Pass to hypervisor directly. * It's a bitmap which indicates CPUs used by the VM. */ struct acrn_vm_creation { __u16 vmid; __u16 reserved0; __u16 vcpu_num; __u16 reserved1; __u8 uuid[16]; __u64 vm_flag; __u64 ioreq_buf; __u64 cpu_affinity; }; /** * struct acrn_gp_regs - General registers of a User VM * @rax: Value of register RAX * @rcx: Value of register RCX * @rdx: Value of register RDX * @rbx: Value of register RBX * @rsp: Value of register RSP * @rbp: Value of register RBP * @rsi: Value of register RSI * @rdi: Value of register RDI * @r8: Value of register R8 * @r9: Value of register R9 * @r10: Value of register R10 * @r11: Value of register R11 * @r12: Value of register R12 * @r13: Value of register R13 * @r14: Value of register R14 * @r15: Value of register R15 */ struct acrn_gp_regs { __le64 rax; __le64 rcx; __le64 rdx; __le64 rbx; __le64 rsp; __le64 rbp; __le64 rsi; __le64 rdi; __le64 r8; __le64 r9; __le64 r10; __le64 r11; __le64 r12; __le64 r13; __le64 r14; __le64 r15; }; /** * struct acrn_descriptor_ptr - Segment descriptor table of a User VM. * @limit: Limit field. * @base: Base field. * @reserved: Reserved and must be 0. */ struct acrn_descriptor_ptr { __le16 limit; __le64 base; __le16 reserved[3]; } __attribute__ ((__packed__)); /** * struct acrn_regs - Registers structure of a User VM * @gprs: General registers * @gdt: Global Descriptor Table * @idt: Interrupt Descriptor Table * @rip: Value of register RIP * @cs_base: Base of code segment selector * @cr0: Value of register CR0 * @cr4: Value of register CR4 * @cr3: Value of register CR3 * @ia32_efer: Value of IA32_EFER MSR * @rflags: Value of regsiter RFLAGS * @reserved_64: Reserved and must be 0 * @cs_ar: Attribute field of code segment selector * @cs_limit: Limit field of code segment selector * @reserved_32: Reserved and must be 0 * @cs_sel: Value of code segment selector * @ss_sel: Value of stack segment selector * @ds_sel: Value of data segment selector * @es_sel: Value of extra segment selector * @fs_sel: Value of FS selector * @gs_sel: Value of GS selector * @ldt_sel: Value of LDT descriptor selector * @tr_sel: Value of TSS descriptor selector */ struct acrn_regs { struct acrn_gp_regs gprs; struct acrn_descriptor_ptr gdt; struct acrn_descriptor_ptr idt; __le64 rip; __le64 cs_base; __le64 cr0; __le64 cr4; __le64 cr3; __le64 ia32_efer; __le64 rflags; __le64 reserved_64[4]; __le32 cs_ar; __le32 cs_limit; __le32 reserved_32[3]; __le16 cs_sel; __le16 ss_sel; __le16 ds_sel; __le16 es_sel; __le16 fs_sel; __le16 gs_sel; __le16 ldt_sel; __le16 tr_sel; }; /** * struct acrn_vcpu_regs - Info of vCPU registers state * @vcpu_id: vCPU ID * @reserved: Reserved and must be 0 * @vcpu_regs: vCPU registers state * * This structure will be passed to hypervisor directly. */ struct acrn_vcpu_regs { __u16 vcpu_id; __u16 reserved[3]; struct acrn_regs vcpu_regs; }; #define ACRN_MEM_ACCESS_RIGHT_MASK 0x00000007U #define ACRN_MEM_ACCESS_READ 0x00000001U #define ACRN_MEM_ACCESS_WRITE 0x00000002U #define ACRN_MEM_ACCESS_EXEC 0x00000004U #define ACRN_MEM_ACCESS_RWX (ACRN_MEM_ACCESS_READ | \ ACRN_MEM_ACCESS_WRITE | \ ACRN_MEM_ACCESS_EXEC) #define ACRN_MEM_TYPE_MASK 0x000007C0U #define ACRN_MEM_TYPE_WB 0x00000040U #define ACRN_MEM_TYPE_WT 0x00000080U #define ACRN_MEM_TYPE_UC 0x00000100U #define ACRN_MEM_TYPE_WC 0x00000200U #define ACRN_MEM_TYPE_WP 0x00000400U /* Memory mapping types */ #define ACRN_MEMMAP_RAM 0 #define ACRN_MEMMAP_MMIO 1 /** * struct acrn_vm_memmap - A EPT memory mapping info for a User VM. * @type: Type of the memory mapping (ACRM_MEMMAP_*). * Pass to hypervisor directly. * @attr: Attribute of the memory mapping. * Pass to hypervisor directly. * @user_vm_pa: Physical address of User VM. * Pass to hypervisor directly. * @service_vm_pa: Physical address of Service VM. * Pass to hypervisor directly. * @vma_base: VMA address of Service VM. Pass to hypervisor directly. * @len: Length of the memory mapping. * Pass to hypervisor directly. */ struct acrn_vm_memmap { __u32 type; __u32 attr; __u64 user_vm_pa; union { __u64 service_vm_pa; __u64 vma_base; }; __u64 len; }; /* Type of interrupt of a passthrough device */ #define ACRN_PTDEV_IRQ_INTX 0 #define ACRN_PTDEV_IRQ_MSI 1 #define ACRN_PTDEV_IRQ_MSIX 2 /** * struct acrn_ptdev_irq - Interrupt data of a passthrough device. * @type: Type (ACRN_PTDEV_IRQ_*) * @virt_bdf: Virtual Bus/Device/Function * @phys_bdf: Physical Bus/Device/Function * @intx: Info of interrupt * @intx.virt_pin: Virtual IOAPIC pin * @intx.phys_pin: Physical IOAPIC pin * @intx.is_pic_pin: Is PIC pin or not * * This structure will be passed to hypervisor directly. */ struct acrn_ptdev_irq { __u32 type; __u16 virt_bdf; __u16 phys_bdf; struct { __u32 virt_pin; __u32 phys_pin; __u32 is_pic_pin; } intx; }; /* Type of PCI device assignment */ #define ACRN_PTDEV_QUIRK_ASSIGN (1U << 0) #define ACRN_MMIODEV_RES_NUM 3 #define ACRN_PCI_NUM_BARS 6 /** * struct acrn_pcidev - Info for assigning or de-assigning a PCI device * @type: Type of the assignment * @virt_bdf: Virtual Bus/Device/Function * @phys_bdf: Physical Bus/Device/Function * @intr_line: PCI interrupt line * @intr_pin: PCI interrupt pin * @bar: PCI BARs. * * This structure will be passed to hypervisor directly. */ struct acrn_pcidev { __u32 type; __u16 virt_bdf; __u16 phys_bdf; __u8 intr_line; __u8 intr_pin; __u32 bar[ACRN_PCI_NUM_BARS]; }; /** * struct acrn_mmiodev - Info for assigning or de-assigning a MMIO device * @name: Name of the MMIO device. * @res[].user_vm_pa: Physical address of User VM of the MMIO region * for the MMIO device. * @res[].service_vm_pa: Physical address of Service VM of the MMIO * region for the MMIO device. * @res[].size: Size of the MMIO region for the MMIO device. * @res[].mem_type: Memory type of the MMIO region for the MMIO * device. * * This structure will be passed to hypervisor directly. */ struct acrn_mmiodev { __u8 name[8]; struct { __u64 user_vm_pa; __u64 service_vm_pa; __u64 size; __u64 mem_type; } res[ACRN_MMIODEV_RES_NUM]; }; /** * struct acrn_vdev - Info for creating or destroying a virtual device * @id: Union of identifier of the virtual device * @id.value: Raw data of the identifier * @id.fields.vendor: Vendor id of the virtual PCI device * @id.fields.device: Device id of the virtual PCI device * @id.fields.legacy_id: ID of the virtual device if not a PCI device * @slot: Virtual Bus/Device/Function of the virtual * device * @io_base: IO resource base address of the virtual device * @io_size: IO resource size of the virtual device * @args: Arguments for the virtual device creation * * The created virtual device can be a PCI device or a legacy device (e.g. * a virtual UART controller) and it is emulated by the hypervisor. This * structure will be passed to hypervisor directly. */ struct acrn_vdev { /* * the identifier of the device, the low 32 bits represent the vendor * id and device id of PCI device and the high 32 bits represent the * device number of the legacy device */ union { __u64 value; struct { __le16 vendor; __le16 device; __le32 legacy_id; } fields; } id; __u64 slot; __u32 io_addr[ACRN_PCI_NUM_BARS]; __u32 io_size[ACRN_PCI_NUM_BARS]; __u8 args[128]; }; /** * struct acrn_msi_entry - Info for injecting a MSI interrupt to a VM * @msi_addr: MSI addr[19:12] with dest vCPU ID * @msi_data: MSI data[7:0] with vector */ struct acrn_msi_entry { __u64 msi_addr; __u64 msi_data; }; struct acrn_acpi_generic_address { __u8 space_id; __u8 bit_width; __u8 bit_offset; __u8 access_size; __u64 address; } __attribute__ ((__packed__)); /** * struct acrn_cstate_data - A C state package defined in ACPI * @cx_reg: Register of the C state object * @type: Type of the C state object * @latency: The worst-case latency to enter and exit this C state * @power: The average power consumption when in this C state */ struct acrn_cstate_data { struct acrn_acpi_generic_address cx_reg; __u8 type; __u32 latency; __u64 power; }; /** * struct acrn_pstate_data - A P state package defined in ACPI * @core_frequency: CPU frequency (in MHz). * @power: Power dissipation (in milliwatts). * @transition_latency: The worst-case latency in microseconds that CPU is * unavailable during a transition from any P state to * this P state. * @bus_master_latency: The worst-case latency in microseconds that Bus Masters * are prevented from accessing memory during a transition * from any P state to this P state. * @control: The value to be written to Performance Control Register * @status: Transition status. */ struct acrn_pstate_data { __u64 core_frequency; __u64 power; __u64 transition_latency; __u64 bus_master_latency; __u64 control; __u64 status; }; #define PMCMD_TYPE_MASK 0x000000ff enum acrn_pm_cmd_type { ACRN_PMCMD_GET_PX_CNT, ACRN_PMCMD_GET_PX_DATA, ACRN_PMCMD_GET_CX_CNT, ACRN_PMCMD_GET_CX_DATA, }; #define ACRN_IOEVENTFD_FLAG_PIO 0x01 #define ACRN_IOEVENTFD_FLAG_DATAMATCH 0x02 #define ACRN_IOEVENTFD_FLAG_DEASSIGN 0x04 /** * struct acrn_ioeventfd - Data to operate a &struct hsm_ioeventfd * @fd: The fd of eventfd associated with a hsm_ioeventfd * @flags: Logical-OR of ACRN_IOEVENTFD_FLAG_* * @addr: The start address of IO range of ioeventfd * @len: The length of IO range of ioeventfd * @reserved: Reserved and should be 0 * @data: Data for data matching * * Without flag ACRN_IOEVENTFD_FLAG_DEASSIGN, ioctl ACRN_IOCTL_IOEVENTFD * creates a &struct hsm_ioeventfd with properties originated from &struct * acrn_ioeventfd. With flag ACRN_IOEVENTFD_FLAG_DEASSIGN, ioctl * ACRN_IOCTL_IOEVENTFD destroys the &struct hsm_ioeventfd matching the fd. */ struct acrn_ioeventfd { __u32 fd; __u32 flags; __u64 addr; __u32 len; __u32 reserved; __u64 data; }; #define ACRN_IRQFD_FLAG_DEASSIGN 0x01 /** * struct acrn_irqfd - Data to operate a &struct hsm_irqfd * @fd: The fd of eventfd associated with a hsm_irqfd * @flags: Logical-OR of ACRN_IRQFD_FLAG_* * @msi: Info of MSI associated with the irqfd */ struct acrn_irqfd { __s32 fd; __u32 flags; struct acrn_msi_entry msi; }; /* The ioctl type, documented in ioctl-number.rst */ #define ACRN_IOCTL_TYPE 0xA2 /* * Common IOCTL IDs definition for ACRN userspace */ #define ACRN_IOCTL_CREATE_VM \ _IOWR(ACRN_IOCTL_TYPE, 0x10, struct acrn_vm_creation) #define ACRN_IOCTL_DESTROY_VM \ _IO(ACRN_IOCTL_TYPE, 0x11) #define ACRN_IOCTL_START_VM \ _IO(ACRN_IOCTL_TYPE, 0x12) #define ACRN_IOCTL_PAUSE_VM \ _IO(ACRN_IOCTL_TYPE, 0x13) #define ACRN_IOCTL_RESET_VM \ _IO(ACRN_IOCTL_TYPE, 0x15) #define ACRN_IOCTL_SET_VCPU_REGS \ _IOW(ACRN_IOCTL_TYPE, 0x16, struct acrn_vcpu_regs) #define ACRN_IOCTL_INJECT_MSI \ _IOW(ACRN_IOCTL_TYPE, 0x23, struct acrn_msi_entry) #define ACRN_IOCTL_VM_INTR_MONITOR \ _IOW(ACRN_IOCTL_TYPE, 0x24, unsigned long) #define ACRN_IOCTL_SET_IRQLINE \ _IOW(ACRN_IOCTL_TYPE, 0x25, __u64) #define ACRN_IOCTL_NOTIFY_REQUEST_FINISH \ _IOW(ACRN_IOCTL_TYPE, 0x31, struct acrn_ioreq_notify) #define ACRN_IOCTL_CREATE_IOREQ_CLIENT \ _IO(ACRN_IOCTL_TYPE, 0x32) #define ACRN_IOCTL_ATTACH_IOREQ_CLIENT \ _IO(ACRN_IOCTL_TYPE, 0x33) #define ACRN_IOCTL_DESTROY_IOREQ_CLIENT \ _IO(ACRN_IOCTL_TYPE, 0x34) #define ACRN_IOCTL_CLEAR_VM_IOREQ \ _IO(ACRN_IOCTL_TYPE, 0x35) #define ACRN_IOCTL_SET_MEMSEG \ _IOW(ACRN_IOCTL_TYPE, 0x41, struct acrn_vm_memmap) #define ACRN_IOCTL_UNSET_MEMSEG \ _IOW(ACRN_IOCTL_TYPE, 0x42, struct acrn_vm_memmap) #define ACRN_IOCTL_SET_PTDEV_INTR \ _IOW(ACRN_IOCTL_TYPE, 0x53, struct acrn_ptdev_irq) #define ACRN_IOCTL_RESET_PTDEV_INTR \ _IOW(ACRN_IOCTL_TYPE, 0x54, struct acrn_ptdev_irq) #define ACRN_IOCTL_ASSIGN_PCIDEV \ _IOW(ACRN_IOCTL_TYPE, 0x55, struct acrn_pcidev) #define ACRN_IOCTL_DEASSIGN_PCIDEV \ _IOW(ACRN_IOCTL_TYPE, 0x56, struct acrn_pcidev) #define ACRN_IOCTL_ASSIGN_MMIODEV \ _IOW(ACRN_IOCTL_TYPE, 0x57, struct acrn_mmiodev) #define ACRN_IOCTL_DEASSIGN_MMIODEV \ _IOW(ACRN_IOCTL_TYPE, 0x58, struct acrn_mmiodev) #define ACRN_IOCTL_CREATE_VDEV \ _IOW(ACRN_IOCTL_TYPE, 0x59, struct acrn_vdev) #define ACRN_IOCTL_DESTROY_VDEV \ _IOW(ACRN_IOCTL_TYPE, 0x5A, struct acrn_vdev) #define ACRN_IOCTL_PM_GET_CPU_STATE \ _IOWR(ACRN_IOCTL_TYPE, 0x60, __u64) #define ACRN_IOCTL_IOEVENTFD \ _IOW(ACRN_IOCTL_TYPE, 0x70, struct acrn_ioeventfd) #define ACRN_IOCTL_IRQFD \ _IOW(ACRN_IOCTL_TYPE, 0x71, struct acrn_irqfd) #endif /* _UAPI_ACRN_H */
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