net: set initial device refcount to 1

[platform/kernel/linux-starfive.git] / include / asm-generic / hyperv-tlfs.h

/* SPDX-License-Identifier: GPL-2.0 */

/*
 * This file contains definitions from Hyper-V Hypervisor Top-Level Functional
 * Specification (TLFS):
 * https://docs.microsoft.com/en-us/virtualization/hyper-v-on-windows/reference/tlfs
 */

#ifndef _ASM_GENERIC_HYPERV_TLFS_H
#define _ASM_GENERIC_HYPERV_TLFS_H

#include <linux/types.h>
#include <linux/bits.h>
#include <linux/time64.h>

/*
 * While not explicitly listed in the TLFS, Hyper-V always runs with a page size
 * of 4096. These definitions are used when communicating with Hyper-V using
 * guest physical pages and guest physical page addresses, since the guest page
 * size may not be 4096 on all architectures.
 */
#define HV_HYP_PAGE_SHIFT      12
#define HV_HYP_PAGE_SIZE       BIT(HV_HYP_PAGE_SHIFT)
#define HV_HYP_PAGE_MASK       (~(HV_HYP_PAGE_SIZE - 1))

/*
 * Hyper-V provides two categories of flags relevant to guest VMs.  The
 * "Features" category indicates specific functionality that is available
 * to guests on this particular instance of Hyper-V. The "Features"
 * are presented in four groups, each of which is 32 bits. The group A
 * and B definitions are common across architectures and are listed here.
 * However, not all flags are relevant on all architectures.
 *
 * Groups C and D vary across architectures and are listed in the
 * architecture specific portion of hyperv-tlfs.h. Some of these flags exist
 * on multiple architectures, but the bit positions are different so they
 * cannot appear in the generic portion of hyperv-tlfs.h.
 *
 * The "Enlightenments" category provides recommendations on whether to use
 * specific enlightenments that are available. The Enlighenments are a single
 * group of 32 bits, but they vary across architectures and are listed in
 * the architecture specific portion of hyperv-tlfs.h.
 */

/*
 * Group A Features.
 */

/* VP Runtime register available */
#define HV_MSR_VP_RUNTIME_AVAILABLE             BIT(0)
/* Partition Reference Counter available*/
#define HV_MSR_TIME_REF_COUNT_AVAILABLE         BIT(1)
/* Basic SynIC register available */
#define HV_MSR_SYNIC_AVAILABLE                  BIT(2)
/* Synthetic Timer registers available */
#define HV_MSR_SYNTIMER_AVAILABLE               BIT(3)
/* Virtual APIC assist and VP assist page registers available */
#define HV_MSR_APIC_ACCESS_AVAILABLE            BIT(4)
/* Hypercall and Guest OS ID registers available*/
#define HV_MSR_HYPERCALL_AVAILABLE              BIT(5)
/* Access virtual processor index register available*/
#define HV_MSR_VP_INDEX_AVAILABLE               BIT(6)
/* Virtual system reset register available*/
#define HV_MSR_RESET_AVAILABLE                  BIT(7)
/* Access statistics page registers available */
#define HV_MSR_STAT_PAGES_AVAILABLE             BIT(8)
/* Partition reference TSC register is available */
#define HV_MSR_REFERENCE_TSC_AVAILABLE          BIT(9)
/* Partition Guest IDLE register is available */
#define HV_MSR_GUEST_IDLE_AVAILABLE             BIT(10)
/* Partition local APIC and TSC frequency registers available */
#define HV_ACCESS_FREQUENCY_MSRS                BIT(11)
/* AccessReenlightenmentControls privilege */
#define HV_ACCESS_REENLIGHTENMENT               BIT(13)
/* AccessTscInvariantControls privilege */
#define HV_ACCESS_TSC_INVARIANT                 BIT(15)

/*
 * Group B features.
 */
#define HV_CREATE_PARTITIONS                    BIT(0)
#define HV_ACCESS_PARTITION_ID                  BIT(1)
#define HV_ACCESS_MEMORY_POOL                   BIT(2)
#define HV_ADJUST_MESSAGE_BUFFERS               BIT(3)
#define HV_POST_MESSAGES                        BIT(4)
#define HV_SIGNAL_EVENTS                        BIT(5)
#define HV_CREATE_PORT                          BIT(6)
#define HV_CONNECT_PORT                         BIT(7)
#define HV_ACCESS_STATS                         BIT(8)
#define HV_DEBUGGING                            BIT(11)
#define HV_CPU_MANAGEMENT                       BIT(12)
#define HV_ISOLATION                            BIT(22)


/*
 * TSC page layout.
 */
struct ms_hyperv_tsc_page {
        volatile u32 tsc_sequence;
        u32 reserved1;
        volatile u64 tsc_scale;
        volatile s64 tsc_offset;
} __packed;

/*
 * The guest OS needs to register the guest ID with the hypervisor.
 * The guest ID is a 64 bit entity and the structure of this ID is
 * specified in the Hyper-V specification:
 *
 * msdn.microsoft.com/en-us/library/windows/hardware/ff542653%28v=vs.85%29.aspx
 *
 * While the current guideline does not specify how Linux guest ID(s)
 * need to be generated, our plan is to publish the guidelines for
 * Linux and other guest operating systems that currently are hosted
 * on Hyper-V. The implementation here conforms to this yet
 * unpublished guidelines.
 *
 *
 * Bit(s)
 * 63 - Indicates if the OS is Open Source or not; 1 is Open Source
 * 62:56 - Os Type; Linux is 0x100
 * 55:48 - Distro specific identification
 * 47:16 - Linux kernel version number
 * 15:0  - Distro specific identification
 *
 *
 */

#define HV_LINUX_VENDOR_ID              0x8100

/*
 * Crash notification flags.
 */
#define HV_CRASH_CTL_CRASH_NOTIFY_MSG           BIT_ULL(62)
#define HV_CRASH_CTL_CRASH_NOTIFY               BIT_ULL(63)

/* Declare the various hypercall operations. */
#define HVCALL_FLUSH_VIRTUAL_ADDRESS_SPACE      0x0002
#define HVCALL_FLUSH_VIRTUAL_ADDRESS_LIST       0x0003
#define HVCALL_NOTIFY_LONG_SPIN_WAIT            0x0008
#define HVCALL_SEND_IPI                         0x000b
#define HVCALL_FLUSH_VIRTUAL_ADDRESS_SPACE_EX   0x0013
#define HVCALL_FLUSH_VIRTUAL_ADDRESS_LIST_EX    0x0014
#define HVCALL_SEND_IPI_EX                      0x0015
#define HVCALL_GET_PARTITION_ID                 0x0046
#define HVCALL_DEPOSIT_MEMORY                   0x0048
#define HVCALL_CREATE_VP                        0x004e
#define HVCALL_GET_VP_REGISTERS                 0x0050
#define HVCALL_SET_VP_REGISTERS                 0x0051
#define HVCALL_POST_MESSAGE                     0x005c
#define HVCALL_SIGNAL_EVENT                     0x005d
#define HVCALL_POST_DEBUG_DATA                  0x0069
#define HVCALL_RETRIEVE_DEBUG_DATA              0x006a
#define HVCALL_RESET_DEBUG_SESSION              0x006b
#define HVCALL_ADD_LOGICAL_PROCESSOR            0x0076
#define HVCALL_MAP_DEVICE_INTERRUPT             0x007c
#define HVCALL_UNMAP_DEVICE_INTERRUPT           0x007d
#define HVCALL_RETARGET_INTERRUPT               0x007e
#define HVCALL_FLUSH_GUEST_PHYSICAL_ADDRESS_SPACE 0x00af
#define HVCALL_FLUSH_GUEST_PHYSICAL_ADDRESS_LIST 0x00b0

#define HV_FLUSH_ALL_PROCESSORS                 BIT(0)
#define HV_FLUSH_ALL_VIRTUAL_ADDRESS_SPACES     BIT(1)
#define HV_FLUSH_NON_GLOBAL_MAPPINGS_ONLY       BIT(2)
#define HV_FLUSH_USE_EXTENDED_RANGE_FORMAT      BIT(3)

enum HV_GENERIC_SET_FORMAT {
        HV_GENERIC_SET_SPARSE_4K,
        HV_GENERIC_SET_ALL,
};

#define HV_PARTITION_ID_SELF            ((u64)-1)
#define HV_VP_INDEX_SELF                ((u32)-2)

#define HV_HYPERCALL_RESULT_MASK        GENMASK_ULL(15, 0)
#define HV_HYPERCALL_FAST_BIT           BIT(16)
#define HV_HYPERCALL_VARHEAD_OFFSET     17
#define HV_HYPERCALL_REP_COMP_OFFSET    32
#define HV_HYPERCALL_REP_COMP_1         BIT_ULL(32)
#define HV_HYPERCALL_REP_COMP_MASK      GENMASK_ULL(43, 32)
#define HV_HYPERCALL_REP_START_OFFSET   48
#define HV_HYPERCALL_REP_START_MASK     GENMASK_ULL(59, 48)

/* hypercall status code */
#define HV_STATUS_SUCCESS                       0
#define HV_STATUS_INVALID_HYPERCALL_CODE        2
#define HV_STATUS_INVALID_HYPERCALL_INPUT       3
#define HV_STATUS_INVALID_ALIGNMENT             4
#define HV_STATUS_INVALID_PARAMETER             5
#define HV_STATUS_OPERATION_DENIED              8
#define HV_STATUS_INSUFFICIENT_MEMORY           11
#define HV_STATUS_INVALID_PORT_ID               17
#define HV_STATUS_INVALID_CONNECTION_ID         18
#define HV_STATUS_INSUFFICIENT_BUFFERS          19

/*
 * The Hyper-V TimeRefCount register and the TSC
 * page provide a guest VM clock with 100ns tick rate
 */
#define HV_CLOCK_HZ (NSEC_PER_SEC/100)

/* Define the number of synthetic interrupt sources. */
#define HV_SYNIC_SINT_COUNT             (16)
/* Define the expected SynIC version. */
#define HV_SYNIC_VERSION_1              (0x1)
/* Valid SynIC vectors are 16-255. */
#define HV_SYNIC_FIRST_VALID_VECTOR     (16)

#define HV_SYNIC_CONTROL_ENABLE         (1ULL << 0)
#define HV_SYNIC_SIMP_ENABLE            (1ULL << 0)
#define HV_SYNIC_SIEFP_ENABLE           (1ULL << 0)
#define HV_SYNIC_SINT_MASKED            (1ULL << 16)
#define HV_SYNIC_SINT_AUTO_EOI          (1ULL << 17)
#define HV_SYNIC_SINT_VECTOR_MASK       (0xFF)

#define HV_SYNIC_STIMER_COUNT           (4)

/* Define synthetic interrupt controller message constants. */
#define HV_MESSAGE_SIZE                 (256)
#define HV_MESSAGE_PAYLOAD_BYTE_COUNT   (240)
#define HV_MESSAGE_PAYLOAD_QWORD_COUNT  (30)

/* Define synthetic interrupt controller message flags. */
union hv_message_flags {
        __u8 asu8;
        struct {
                __u8 msg_pending:1;
                __u8 reserved:7;
        } __packed;
};

/* Define port identifier type. */
union hv_port_id {
        __u32 asu32;
        struct {
                __u32 id:24;
                __u32 reserved:8;
        } __packed u;
};

/* Define synthetic interrupt controller message header. */
struct hv_message_header {
        __u32 message_type;
        __u8 payload_size;
        union hv_message_flags message_flags;
        __u8 reserved[2];
        union {
                __u64 sender;
                union hv_port_id port;
        };
} __packed;

/* Define synthetic interrupt controller message format. */
struct hv_message {
        struct hv_message_header header;
        union {
                __u64 payload[HV_MESSAGE_PAYLOAD_QWORD_COUNT];
        } u;
} __packed;

/* Define the synthetic interrupt message page layout. */
struct hv_message_page {
        struct hv_message sint_message[HV_SYNIC_SINT_COUNT];
} __packed;

/* Define timer message payload structure. */
struct hv_timer_message_payload {
        __u32 timer_index;
        __u32 reserved;
        __u64 expiration_time;  /* When the timer expired */
        __u64 delivery_time;    /* When the message was delivered */
} __packed;


/* Define synthetic interrupt controller flag constants. */
#define HV_EVENT_FLAGS_COUNT            (256 * 8)
#define HV_EVENT_FLAGS_LONG_COUNT       (256 / sizeof(unsigned long))

/*
 * Synthetic timer configuration.
 */
union hv_stimer_config {
        u64 as_uint64;
        struct {
                u64 enable:1;
                u64 periodic:1;
                u64 lazy:1;
                u64 auto_enable:1;
                u64 apic_vector:8;
                u64 direct_mode:1;
                u64 reserved_z0:3;
                u64 sintx:4;
                u64 reserved_z1:44;
        } __packed;
};


/* Define the synthetic interrupt controller event flags format. */
union hv_synic_event_flags {
        unsigned long flags[HV_EVENT_FLAGS_LONG_COUNT];
};

/* Define SynIC control register. */
union hv_synic_scontrol {
        u64 as_uint64;
        struct {
                u64 enable:1;
                u64 reserved:63;
        } __packed;
};

/* Define synthetic interrupt source. */
union hv_synic_sint {
        u64 as_uint64;
        struct {
                u64 vector:8;
                u64 reserved1:8;
                u64 masked:1;
                u64 auto_eoi:1;
                u64 polling:1;
                u64 reserved2:45;
        } __packed;
};

/* Define the format of the SIMP register */
union hv_synic_simp {
        u64 as_uint64;
        struct {
                u64 simp_enabled:1;
                u64 preserved:11;
                u64 base_simp_gpa:52;
        } __packed;
};

/* Define the format of the SIEFP register */
union hv_synic_siefp {
        u64 as_uint64;
        struct {
                u64 siefp_enabled:1;
                u64 preserved:11;
                u64 base_siefp_gpa:52;
        } __packed;
};

struct hv_vpset {
        u64 format;
        u64 valid_bank_mask;
        u64 bank_contents[];
} __packed;

/* HvCallSendSyntheticClusterIpi hypercall */
struct hv_send_ipi {
        u32 vector;
        u32 reserved;
        u64 cpu_mask;
} __packed;

/* HvCallSendSyntheticClusterIpiEx hypercall */
struct hv_send_ipi_ex {
        u32 vector;
        u32 reserved;
        struct hv_vpset vp_set;
} __packed;

/* HvFlushGuestPhysicalAddressSpace hypercalls */
struct hv_guest_mapping_flush {
        u64 address_space;
        u64 flags;
} __packed;

/*
 *  HV_MAX_FLUSH_PAGES = "additional_pages" + 1. It's limited
 *  by the bitwidth of "additional_pages" in union hv_gpa_page_range.
 */
#define HV_MAX_FLUSH_PAGES (2048)

/* HvFlushGuestPhysicalAddressList hypercall */
union hv_gpa_page_range {
        u64 address_space;
        struct {
                u64 additional_pages:11;
                u64 largepage:1;
                u64 basepfn:52;
        } page;
};

/*
 * All input flush parameters should be in single page. The max flush
 * count is equal with how many entries of union hv_gpa_page_range can
 * be populated into the input parameter page.
 */
#define HV_MAX_FLUSH_REP_COUNT ((HV_HYP_PAGE_SIZE - 2 * sizeof(u64)) /  \
                                sizeof(union hv_gpa_page_range))

struct hv_guest_mapping_flush_list {
        u64 address_space;
        u64 flags;
        union hv_gpa_page_range gpa_list[HV_MAX_FLUSH_REP_COUNT];
};

/* HvFlushVirtualAddressSpace, HvFlushVirtualAddressList hypercalls */
struct hv_tlb_flush {
        u64 address_space;
        u64 flags;
        u64 processor_mask;
        u64 gva_list[];
} __packed;

/* HvFlushVirtualAddressSpaceEx, HvFlushVirtualAddressListEx hypercalls */
struct hv_tlb_flush_ex {
        u64 address_space;
        u64 flags;
        struct hv_vpset hv_vp_set;
        u64 gva_list[];
} __packed;

/* HvGetPartitionId hypercall (output only) */
struct hv_get_partition_id {
        u64 partition_id;
} __packed;

/* HvDepositMemory hypercall */
struct hv_deposit_memory {
        u64 partition_id;
        u64 gpa_page_list[];
} __packed;

struct hv_proximity_domain_flags {
        u32 proximity_preferred : 1;
        u32 reserved : 30;
        u32 proximity_info_valid : 1;
} __packed;

/* Not a union in windows but useful for zeroing */
union hv_proximity_domain_info {
        struct {
                u32 domain_id;
                struct hv_proximity_domain_flags flags;
        };
        u64 as_uint64;
} __packed;

struct hv_lp_startup_status {
        u64 hv_status;
        u64 substatus1;
        u64 substatus2;
        u64 substatus3;
        u64 substatus4;
        u64 substatus5;
        u64 substatus6;
} __packed;

/* HvAddLogicalProcessor hypercall */
struct hv_add_logical_processor_in {
        u32 lp_index;
        u32 apic_id;
        union hv_proximity_domain_info proximity_domain_info;
        u64 flags;
} __packed;

struct hv_add_logical_processor_out {
        struct hv_lp_startup_status startup_status;
} __packed;

enum HV_SUBNODE_TYPE
{
    HvSubnodeAny = 0,
    HvSubnodeSocket = 1,
    HvSubnodeAmdNode = 2,
    HvSubnodeL3 = 3,
    HvSubnodeCount = 4,
    HvSubnodeInvalid = -1
};

/* HvCreateVp hypercall */
struct hv_create_vp {
        u64 partition_id;
        u32 vp_index;
        u8 padding[3];
        u8 subnode_type;
        u64 subnode_id;
        union hv_proximity_domain_info proximity_domain_info;
        u64 flags;
} __packed;

enum hv_interrupt_source {
        HV_INTERRUPT_SOURCE_MSI = 1, /* MSI and MSI-X */
        HV_INTERRUPT_SOURCE_IOAPIC,
};

union hv_msi_address_register {
        u32 as_uint32;
        struct {
                u32 reserved1:2;
                u32 destination_mode:1;
                u32 redirection_hint:1;
                u32 reserved2:8;
                u32 destination_id:8;
                u32 msi_base:12;
        };
} __packed;

union hv_msi_data_register {
        u32 as_uint32;
        struct {
                u32 vector:8;
                u32 delivery_mode:3;
                u32 reserved1:3;
                u32 level_assert:1;
                u32 trigger_mode:1;
                u32 reserved2:16;
        };
} __packed;

/* HvRetargetDeviceInterrupt hypercall */
union hv_msi_entry {
        u64 as_uint64;
        struct {
                union hv_msi_address_register address;
                union hv_msi_data_register data;
        } __packed;
};

union hv_ioapic_rte {
        u64 as_uint64;

        struct {
                u32 vector:8;
                u32 delivery_mode:3;
                u32 destination_mode:1;
                u32 delivery_status:1;
                u32 interrupt_polarity:1;
                u32 remote_irr:1;
                u32 trigger_mode:1;
                u32 interrupt_mask:1;
                u32 reserved1:15;

                u32 reserved2:24;
                u32 destination_id:8;
        };

        struct {
                u32 low_uint32;
                u32 high_uint32;
        };
} __packed;

struct hv_interrupt_entry {
        u32 source;
        u32 reserved1;
        union {
                union hv_msi_entry msi_entry;
                union hv_ioapic_rte ioapic_rte;
        };
} __packed;

/*
 * flags for hv_device_interrupt_target.flags
 */
#define HV_DEVICE_INTERRUPT_TARGET_MULTICAST            1
#define HV_DEVICE_INTERRUPT_TARGET_PROCESSOR_SET        2

struct hv_device_interrupt_target {
        u32 vector;
        u32 flags;
        union {
                u64 vp_mask;
                struct hv_vpset vp_set;
        };
} __packed;

struct hv_retarget_device_interrupt {
        u64 partition_id;               /* use "self" */
        u64 device_id;
        struct hv_interrupt_entry int_entry;
        u64 reserved2;
        struct hv_device_interrupt_target int_target;
} __packed __aligned(8);


/* HvGetVpRegisters hypercall input with variable size reg name list*/
struct hv_get_vp_registers_input {
        struct {
                u64 partitionid;
                u32 vpindex;
                u8  inputvtl;
                u8  padding[3];
        } header;
        struct input {
                u32 name0;
                u32 name1;
        } element[];
} __packed;


/* HvGetVpRegisters returns an array of these output elements */
struct hv_get_vp_registers_output {
        union {
                struct {
                        u32 a;
                        u32 b;
                        u32 c;
                        u32 d;
                } as32 __packed;
                struct {
                        u64 low;
                        u64 high;
                } as64 __packed;
        };
};

/* HvSetVpRegisters hypercall with variable size reg name/value list*/
struct hv_set_vp_registers_input {
        struct {
                u64 partitionid;
                u32 vpindex;
                u8  inputvtl;
                u8  padding[3];
        } header;
        struct {
                u32 name;
                u32 padding1;
                u64 padding2;
                u64 valuelow;
                u64 valuehigh;
        } element[];
} __packed;

enum hv_device_type {
        HV_DEVICE_TYPE_LOGICAL = 0,
        HV_DEVICE_TYPE_PCI = 1,
        HV_DEVICE_TYPE_IOAPIC = 2,
        HV_DEVICE_TYPE_ACPI = 3,
};

typedef u16 hv_pci_rid;
typedef u16 hv_pci_segment;
typedef u64 hv_logical_device_id;
union hv_pci_bdf {
        u16 as_uint16;

        struct {
                u8 function:3;
                u8 device:5;
                u8 bus;
        };
} __packed;

union hv_pci_bus_range {
        u16 as_uint16;

        struct {
                u8 subordinate_bus;
                u8 secondary_bus;
        };
} __packed;

union hv_device_id {
        u64 as_uint64;

        struct {
                u64 reserved0:62;
                u64 device_type:2;
        };

        /* HV_DEVICE_TYPE_LOGICAL */
        struct {
                u64 id:62;
                u64 device_type:2;
        } logical;

        /* HV_DEVICE_TYPE_PCI */
        struct {
                union {
                        hv_pci_rid rid;
                        union hv_pci_bdf bdf;
                };

                hv_pci_segment segment;
                union hv_pci_bus_range shadow_bus_range;

                u16 phantom_function_bits:2;
                u16 source_shadow:1;

                u16 rsvdz0:11;
                u16 device_type:2;
        } pci;

        /* HV_DEVICE_TYPE_IOAPIC */
        struct {
                u8 ioapic_id;
                u8 rsvdz0;
                u16 rsvdz1;
                u16 rsvdz2;

                u16 rsvdz3:14;
                u16 device_type:2;
        } ioapic;

        /* HV_DEVICE_TYPE_ACPI */
        struct {
                u32 input_mapping_base;
                u32 input_mapping_count:30;
                u32 device_type:2;
        } acpi;
} __packed;

enum hv_interrupt_trigger_mode {
        HV_INTERRUPT_TRIGGER_MODE_EDGE = 0,
        HV_INTERRUPT_TRIGGER_MODE_LEVEL = 1,
};

struct hv_device_interrupt_descriptor {
        u32 interrupt_type;
        u32 trigger_mode;
        u32 vector_count;
        u32 reserved;
        struct hv_device_interrupt_target target;
} __packed;

struct hv_input_map_device_interrupt {
        u64 partition_id;
        u64 device_id;
        u64 flags;
        struct hv_interrupt_entry logical_interrupt_entry;
        struct hv_device_interrupt_descriptor interrupt_descriptor;
} __packed;

struct hv_output_map_device_interrupt {
        struct hv_interrupt_entry interrupt_entry;
} __packed;

struct hv_input_unmap_device_interrupt {
        u64 partition_id;
        u64 device_id;
        struct hv_interrupt_entry interrupt_entry;
} __packed;

#define HV_SOURCE_SHADOW_NONE               0x0
#define HV_SOURCE_SHADOW_BRIDGE_BUS_RANGE   0x1

#endif