WSL2-Linux-Kernel/drivers/misc/habanalabs/habanalabs.h

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/* SPDX-License-Identifier: GPL-2.0
*
* Copyright 2016-2019 HabanaLabs, Ltd.
* All Rights Reserved.
*
*/
#ifndef HABANALABSP_H_
#define HABANALABSP_H_
#include "include/armcp_if.h"
#include "include/qman_if.h"
#include <linux/cdev.h>
#include <linux/iopoll.h>
#include <linux/irqreturn.h>
#include <linux/dma-fence.h>
#include <linux/dma-direction.h>
#include <linux/scatterlist.h>
#include <linux/hashtable.h>
#define HL_NAME "habanalabs"
#define HL_MMAP_CB_MASK (0x8000000000000000ull >> PAGE_SHIFT)
#define HL_PENDING_RESET_PER_SEC 5
#define HL_DEVICE_TIMEOUT_USEC 1000000 /* 1 s */
#define HL_HEARTBEAT_PER_USEC 5000000 /* 5 s */
#define HL_PLL_LOW_JOB_FREQ_USEC 5000000 /* 5 s */
#define HL_ARMCP_INFO_TIMEOUT_USEC 10000000 /* 10s */
#define HL_ARMCP_EEPROM_TIMEOUT_USEC 10000000 /* 10s */
#define HL_PCI_ELBI_TIMEOUT_MSEC 10 /* 10ms */
#define HL_SIM_MAX_TIMEOUT_US 10000000 /* 10s */
#define HL_MAX_QUEUES 128
/* MUST BE POWER OF 2 and larger than 1 */
#define HL_MAX_PENDING_CS 64
#define HL_IDLE_BUSY_TS_ARR_SIZE 4096
/* Memory */
#define MEM_HASH_TABLE_BITS 7 /* 1 << 7 buckets */
/* MMU */
#define MMU_HASH_TABLE_BITS 7 /* 1 << 7 buckets */
/**
* struct pgt_info - MMU hop page info.
* @node: hash linked-list node for the pgts shadow hash of pgts.
* @phys_addr: physical address of the pgt.
* @shadow_addr: shadow hop in the host.
* @ctx: pointer to the owner ctx.
* @num_of_ptes: indicates how many ptes are used in the pgt.
*
* The MMU page tables hierarchy is placed on the DRAM. When a new level (hop)
* is needed during mapping, a new page is allocated and this structure holds
* its essential information. During unmapping, if no valid PTEs remained in the
* page, it is freed with its pgt_info structure.
*/
struct pgt_info {
struct hlist_node node;
u64 phys_addr;
u64 shadow_addr;
struct hl_ctx *ctx;
int num_of_ptes;
};
struct hl_device;
struct hl_fpriv;
/**
* enum hl_queue_type - Supported QUEUE types.
* @QUEUE_TYPE_NA: queue is not available.
* @QUEUE_TYPE_EXT: external queue which is a DMA channel that may access the
* host.
* @QUEUE_TYPE_INT: internal queue that performs DMA inside the device's
* memories and/or operates the compute engines.
* @QUEUE_TYPE_CPU: S/W queue for communication with the device's CPU.
* @QUEUE_TYPE_HW: queue of DMA and compute engines jobs, for which completion
* notifications are sent by H/W.
*/
enum hl_queue_type {
QUEUE_TYPE_NA,
QUEUE_TYPE_EXT,
QUEUE_TYPE_INT,
QUEUE_TYPE_CPU,
QUEUE_TYPE_HW
};
/**
* struct hw_queue_properties - queue information.
* @type: queue type.
* @driver_only: true if only the driver is allowed to send a job to this queue,
* false otherwise.
* @requires_kernel_cb: true if a CB handle must be provided for jobs on this
* queue, false otherwise (a CB address must be provided).
*/
struct hw_queue_properties {
enum hl_queue_type type;
u8 driver_only;
u8 requires_kernel_cb;
};
/**
* enum vm_type_t - virtual memory mapping request information.
* @VM_TYPE_USERPTR: mapping of user memory to device virtual address.
* @VM_TYPE_PHYS_PACK: mapping of DRAM memory to device virtual address.
*/
enum vm_type_t {
VM_TYPE_USERPTR = 0x1,
VM_TYPE_PHYS_PACK = 0x2
};
/**
* enum hl_device_hw_state - H/W device state. use this to understand whether
* to do reset before hw_init or not
* @HL_DEVICE_HW_STATE_CLEAN: H/W state is clean. i.e. after hard reset
* @HL_DEVICE_HW_STATE_DIRTY: H/W state is dirty. i.e. we started to execute
* hw_init
*/
enum hl_device_hw_state {
HL_DEVICE_HW_STATE_CLEAN = 0,
HL_DEVICE_HW_STATE_DIRTY
};
/**
* struct hl_mmu_properties - ASIC specific MMU address translation properties.
* @hop0_shift: shift of hop 0 mask.
* @hop1_shift: shift of hop 1 mask.
* @hop2_shift: shift of hop 2 mask.
* @hop3_shift: shift of hop 3 mask.
* @hop4_shift: shift of hop 4 mask.
* @hop0_mask: mask to get the PTE address in hop 0.
* @hop1_mask: mask to get the PTE address in hop 1.
* @hop2_mask: mask to get the PTE address in hop 2.
* @hop3_mask: mask to get the PTE address in hop 3.
* @hop4_mask: mask to get the PTE address in hop 4.
* @page_size: default page size used to allocate memory.
* @huge_page_size: page size used to allocate memory with huge pages.
*/
struct hl_mmu_properties {
u64 hop0_shift;
u64 hop1_shift;
u64 hop2_shift;
u64 hop3_shift;
u64 hop4_shift;
u64 hop0_mask;
u64 hop1_mask;
u64 hop2_mask;
u64 hop3_mask;
u64 hop4_mask;
u32 page_size;
u32 huge_page_size;
};
/**
* struct asic_fixed_properties - ASIC specific immutable properties.
* @hw_queues_props: H/W queues properties.
* @armcp_info: received various information from ArmCP regarding the H/W, e.g.
* available sensors.
* @uboot_ver: F/W U-boot version.
* @preboot_ver: F/W Preboot version.
* @dmmu: DRAM MMU address translation properties.
* @pmmu: PCI (host) MMU address translation properties.
* @sram_base_address: SRAM physical start address.
* @sram_end_address: SRAM physical end address.
* @sram_user_base_address - SRAM physical start address for user access.
* @dram_base_address: DRAM physical start address.
* @dram_end_address: DRAM physical end address.
* @dram_user_base_address: DRAM physical start address for user access.
* @dram_size: DRAM total size.
* @dram_pci_bar_size: size of PCI bar towards DRAM.
* @max_power_default: max power of the device after reset
* @va_space_host_start_address: base address of virtual memory range for
* mapping host memory.
* @va_space_host_end_address: end address of virtual memory range for
* mapping host memory.
* @va_space_dram_start_address: base address of virtual memory range for
* mapping DRAM memory.
* @va_space_dram_end_address: end address of virtual memory range for
* mapping DRAM memory.
* @dram_size_for_default_page_mapping: DRAM size needed to map to avoid page
* fault.
* @pcie_dbi_base_address: Base address of the PCIE_DBI block.
* @pcie_aux_dbi_reg_addr: Address of the PCIE_AUX DBI register.
* @mmu_pgt_addr: base physical address in DRAM of MMU page tables.
* @mmu_dram_default_page_addr: DRAM default page physical address.
* @mmu_pgt_size: MMU page tables total size.
* @mmu_pte_size: PTE size in MMU page tables.
* @mmu_hop_table_size: MMU hop table size.
* @mmu_hop0_tables_total_size: total size of MMU hop0 tables.
* @dram_page_size: page size for MMU DRAM allocation.
* @cfg_size: configuration space size on SRAM.
* @sram_size: total size of SRAM.
* @max_asid: maximum number of open contexts (ASIDs).
* @num_of_events: number of possible internal H/W IRQs.
* @psoc_pci_pll_nr: PCI PLL NR value.
* @psoc_pci_pll_nf: PCI PLL NF value.
* @psoc_pci_pll_od: PCI PLL OD value.
* @psoc_pci_pll_div_factor: PCI PLL DIV FACTOR 1 value.
* @high_pll: high PLL frequency used by the device.
* @cb_pool_cb_cnt: number of CBs in the CB pool.
* @cb_pool_cb_size: size of each CB in the CB pool.
* @tpc_enabled_mask: which TPCs are enabled.
* @completion_queues_count: number of completion queues.
*/
struct asic_fixed_properties {
struct hw_queue_properties hw_queues_props[HL_MAX_QUEUES];
struct armcp_info armcp_info;
char uboot_ver[VERSION_MAX_LEN];
char preboot_ver[VERSION_MAX_LEN];
struct hl_mmu_properties dmmu;
struct hl_mmu_properties pmmu;
u64 sram_base_address;
u64 sram_end_address;
u64 sram_user_base_address;
u64 dram_base_address;
u64 dram_end_address;
u64 dram_user_base_address;
u64 dram_size;
u64 dram_pci_bar_size;
u64 max_power_default;
u64 va_space_host_start_address;
u64 va_space_host_end_address;
u64 va_space_dram_start_address;
u64 va_space_dram_end_address;
u64 dram_size_for_default_page_mapping;
u64 pcie_dbi_base_address;
u64 pcie_aux_dbi_reg_addr;
u64 mmu_pgt_addr;
u64 mmu_dram_default_page_addr;
u32 mmu_pgt_size;
u32 mmu_pte_size;
u32 mmu_hop_table_size;
u32 mmu_hop0_tables_total_size;
u32 dram_page_size;
u32 cfg_size;
u32 sram_size;
u32 max_asid;
u32 num_of_events;
u32 psoc_pci_pll_nr;
u32 psoc_pci_pll_nf;
u32 psoc_pci_pll_od;
u32 psoc_pci_pll_div_factor;
u32 high_pll;
u32 cb_pool_cb_cnt;
u32 cb_pool_cb_size;
u8 tpc_enabled_mask;
u8 completion_queues_count;
};
/**
* struct hl_dma_fence - wrapper for fence object used by command submissions.
* @base_fence: kernel fence object.
* @lock: spinlock to protect fence.
* @hdev: habanalabs device structure.
* @cs_seq: command submission sequence number.
*/
struct hl_dma_fence {
struct dma_fence base_fence;
spinlock_t lock;
struct hl_device *hdev;
u64 cs_seq;
};
/*
* Command Buffers
*/
/**
* struct hl_cb_mgr - describes a Command Buffer Manager.
* @cb_lock: protects cb_handles.
* @cb_handles: an idr to hold all command buffer handles.
*/
struct hl_cb_mgr {
spinlock_t cb_lock;
struct idr cb_handles; /* protected by cb_lock */
};
/**
* struct hl_cb - describes a Command Buffer.
* @refcount: reference counter for usage of the CB.
* @hdev: pointer to device this CB belongs to.
* @lock: spinlock to protect mmap/cs flows.
* @debugfs_list: node in debugfs list of command buffers.
* @pool_list: node in pool list of command buffers.
* @kernel_address: Holds the CB's kernel virtual address.
* @bus_address: Holds the CB's DMA address.
* @mmap_size: Holds the CB's size that was mmaped.
* @size: holds the CB's size.
* @id: the CB's ID.
* @cs_cnt: holds number of CS that this CB participates in.
* @ctx_id: holds the ID of the owner's context.
* @mmap: true if the CB is currently mmaped to user.
* @is_pool: true if CB was acquired from the pool, false otherwise.
*/
struct hl_cb {
struct kref refcount;
struct hl_device *hdev;
spinlock_t lock;
struct list_head debugfs_list;
struct list_head pool_list;
u64 kernel_address;
dma_addr_t bus_address;
u32 mmap_size;
u32 size;
u32 id;
u32 cs_cnt;
u32 ctx_id;
u8 mmap;
u8 is_pool;
};
/*
* QUEUES
*/
struct hl_cs_job;
/*
* Currently, there are two limitations on the maximum length of a queue:
*
* 1. The memory footprint of the queue. The current allocated space for the
* queue is PAGE_SIZE. Because each entry in the queue is HL_BD_SIZE,
* the maximum length of the queue can be PAGE_SIZE / HL_BD_SIZE,
* which currently is 4096/16 = 256 entries.
*
* To increase that, we need either to decrease the size of the
* BD (difficult), or allocate more than a single page (easier).
*
* 2. Because the size of the JOB handle field in the BD CTL / completion queue
* is 10-bit, we can have up to 1024 open jobs per hardware queue.
* Therefore, each queue can hold up to 1024 entries.
*
* HL_QUEUE_LENGTH is in units of struct hl_bd.
* HL_QUEUE_LENGTH * sizeof(struct hl_bd) should be <= HL_PAGE_SIZE
*/
#define HL_PAGE_SIZE 4096 /* minimum page size */
/* Must be power of 2 (HL_PAGE_SIZE / HL_BD_SIZE) */
#define HL_QUEUE_LENGTH 256
#define HL_QUEUE_SIZE_IN_BYTES (HL_QUEUE_LENGTH * HL_BD_SIZE)
/*
* HL_CQ_LENGTH is in units of struct hl_cq_entry.
* HL_CQ_LENGTH should be <= HL_PAGE_SIZE
*/
#define HL_CQ_LENGTH HL_QUEUE_LENGTH
#define HL_CQ_SIZE_IN_BYTES (HL_CQ_LENGTH * HL_CQ_ENTRY_SIZE)
/* Must be power of 2 (HL_PAGE_SIZE / HL_EQ_ENTRY_SIZE) */
#define HL_EQ_LENGTH 64
#define HL_EQ_SIZE_IN_BYTES (HL_EQ_LENGTH * HL_EQ_ENTRY_SIZE)
/* Host <-> ArmCP shared memory size */
#define HL_CPU_ACCESSIBLE_MEM_SIZE SZ_2M
/**
* struct hl_hw_queue - describes a H/W transport queue.
* @shadow_queue: pointer to a shadow queue that holds pointers to jobs.
* @queue_type: type of queue.
* @kernel_address: holds the queue's kernel virtual address.
* @bus_address: holds the queue's DMA address.
* @pi: holds the queue's pi value.
* @ci: holds the queue's ci value, AS CALCULATED BY THE DRIVER (not real ci).
* @hw_queue_id: the id of the H/W queue.
* @int_queue_len: length of internal queue (number of entries).
* @valid: is the queue valid (we have array of 32 queues, not all of them
* exists).
*/
struct hl_hw_queue {
struct hl_cs_job **shadow_queue;
enum hl_queue_type queue_type;
u64 kernel_address;
dma_addr_t bus_address;
u32 pi;
u32 ci;
u32 hw_queue_id;
u16 int_queue_len;
u8 valid;
};
/**
* struct hl_cq - describes a completion queue
* @hdev: pointer to the device structure
* @kernel_address: holds the queue's kernel virtual address
* @bus_address: holds the queue's DMA address
* @hw_queue_id: the id of the matching H/W queue
* @ci: ci inside the queue
* @pi: pi inside the queue
* @free_slots_cnt: counter of free slots in queue
*/
struct hl_cq {
struct hl_device *hdev;
u64 kernel_address;
dma_addr_t bus_address;
u32 hw_queue_id;
u32 ci;
u32 pi;
atomic_t free_slots_cnt;
};
/**
* struct hl_eq - describes the event queue (single one per device)
* @hdev: pointer to the device structure
* @kernel_address: holds the queue's kernel virtual address
* @bus_address: holds the queue's DMA address
* @ci: ci inside the queue
*/
struct hl_eq {
struct hl_device *hdev;
u64 kernel_address;
dma_addr_t bus_address;
u32 ci;
};
/*
* ASICs
*/
/**
* enum hl_asic_type - supported ASIC types.
* @ASIC_INVALID: Invalid ASIC type.
* @ASIC_GOYA: Goya device.
*/
enum hl_asic_type {
ASIC_INVALID,
ASIC_GOYA
};
struct hl_cs_parser;
/**
* enum hl_pm_mng_profile - power management profile.
* @PM_AUTO: internal clock is set by the Linux driver.
* @PM_MANUAL: internal clock is set by the user.
* @PM_LAST: last power management type.
*/
enum hl_pm_mng_profile {
PM_AUTO = 1,
PM_MANUAL,
PM_LAST
};
/**
* enum hl_pll_frequency - PLL frequency.
* @PLL_HIGH: high frequency.
* @PLL_LOW: low frequency.
* @PLL_LAST: last frequency values that were configured by the user.
*/
enum hl_pll_frequency {
PLL_HIGH = 1,
PLL_LOW,
PLL_LAST
};
/**
* struct hl_asic_funcs - ASIC specific functions that are can be called from
* common code.
* @early_init: sets up early driver state (pre sw_init), doesn't configure H/W.
* @early_fini: tears down what was done in early_init.
* @late_init: sets up late driver/hw state (post hw_init) - Optional.
* @late_fini: tears down what was done in late_init (pre hw_fini) - Optional.
* @sw_init: sets up driver state, does not configure H/W.
* @sw_fini: tears down driver state, does not configure H/W.
* @hw_init: sets up the H/W state.
* @hw_fini: tears down the H/W state.
* @halt_engines: halt engines, needed for reset sequence. This also disables
* interrupts from the device. Should be called before
* hw_fini and before CS rollback.
* @suspend: handles IP specific H/W or SW changes for suspend.
* @resume: handles IP specific H/W or SW changes for resume.
* @cb_mmap: maps a CB.
* @ring_doorbell: increment PI on a given QMAN.
* @pqe_write: Write the PQ entry to the PQ. This is ASIC-specific
* function because the PQs are located in different memory areas
* per ASIC (SRAM, DRAM, Host memory) and therefore, the method of
* writing the PQE must match the destination memory area
* properties.
* @asic_dma_alloc_coherent: Allocate coherent DMA memory by calling
* dma_alloc_coherent(). This is ASIC function because
* its implementation is not trivial when the driver
* is loaded in simulation mode (not upstreamed).
* @asic_dma_free_coherent: Free coherent DMA memory by calling
* dma_free_coherent(). This is ASIC function because
* its implementation is not trivial when the driver
* is loaded in simulation mode (not upstreamed).
* @get_int_queue_base: get the internal queue base address.
* @test_queues: run simple test on all queues for sanity check.
* @asic_dma_pool_zalloc: small DMA allocation of coherent memory from DMA pool.
* size of allocation is HL_DMA_POOL_BLK_SIZE.
* @asic_dma_pool_free: free small DMA allocation from pool.
* @cpu_accessible_dma_pool_alloc: allocate CPU PQ packet from DMA pool.
* @cpu_accessible_dma_pool_free: free CPU PQ packet from DMA pool.
* @hl_dma_unmap_sg: DMA unmap scatter-gather list.
* @cs_parser: parse Command Submission.
* @asic_dma_map_sg: DMA map scatter-gather list.
* @get_dma_desc_list_size: get number of LIN_DMA packets required for CB.
* @add_end_of_cb_packets: Add packets to the end of CB, if device requires it.
* @update_eq_ci: update event queue CI.
* @context_switch: called upon ASID context switch.
* @restore_phase_topology: clear all SOBs amd MONs.
* @debugfs_read32: debug interface for reading u32 from DRAM/SRAM.
* @debugfs_write32: debug interface for writing u32 to DRAM/SRAM.
* @add_device_attr: add ASIC specific device attributes.
* @handle_eqe: handle event queue entry (IRQ) from ArmCP.
* @set_pll_profile: change PLL profile (manual/automatic).
* @get_events_stat: retrieve event queue entries histogram.
* @read_pte: read MMU page table entry from DRAM.
* @write_pte: write MMU page table entry to DRAM.
* @mmu_invalidate_cache: flush MMU STLB host/DRAM cache, either with soft
* (L1 only) or hard (L0 & L1) flush.
* @mmu_invalidate_cache_range: flush specific MMU STLB cache lines with
* ASID-VA-size mask.
* @send_heartbeat: send is-alive packet to ArmCP and verify response.
habanalabs: add new IOCTL for debug, tracing and profiling Habanalabs ASICs use the ARM coresight infrastructure to support debug, tracing and profiling of neural networks topologies. Because the coresight is configured using register writes and reads, and some of the registers hold sensitive information (e.g. the address in the device's DRAM where the trace data is written to), the user must go through the kernel driver to configure this mechanism. This patch implements the common code of the IOCTL and calls the ASIC-specific function for the actual H/W configuration. The IOCTL supports configuration of seven coresight components: ETR, ETF, STM, FUNNEL, BMON, SPMU and TIMESTAMP The user specifies which component he wishes to configure and provides a pointer to a structure (located in its process space) that contains the relevant configuration. The common code copies the relevant data from the user-space to kernel space and then calls the ASIC-specific function to do the H/W configuration. After the configuration is done, which is usually composed of several IOCTL calls depending on what the user wanted to trace, the user can start executing the topology. The trace data will be written to the user's area in the device's DRAM. After the tracing operation is complete, and user will call the IOCTL again to disable the tracing operation. The user also need to read values from registers for some of the components (e.g. the size of the trace data in the device's DRAM). In that case, the user will provide a pointer to an "output" structure in user-space, which the IOCTL code will fill according the to selected component. Signed-off-by: Omer Shpigelman <oshpigelman@habana.ai> Signed-off-by: Oded Gabbay <oded.gabbay@gmail.com>
2019-04-01 22:31:22 +03:00
* @debug_coresight: perform certain actions on Coresight for debugging.
* @is_device_idle: return true if device is idle, false otherwise.
* @soft_reset_late_init: perform certain actions needed after soft reset.
* @hw_queues_lock: acquire H/W queues lock.
* @hw_queues_unlock: release H/W queues lock.
* @get_pci_id: retrieve PCI ID.
* @get_eeprom_data: retrieve EEPROM data from F/W.
* @send_cpu_message: send buffer to ArmCP.
* @get_hw_state: retrieve the H/W state
* @pci_bars_map: Map PCI BARs.
* @set_dram_bar_base: Set DRAM BAR to map specific device address. Returns
* old address the bar pointed to or U64_MAX for failure
* @init_iatu: Initialize the iATU unit inside the PCI controller.
* @rreg: Read a register. Needed for simulator support.
* @wreg: Write a register. Needed for simulator support.
* @halt_coresight: stop the ETF and ETR traces.
* @get_clk_rate: Retrieve the ASIC current and maximum clock rate in MHz
*/
struct hl_asic_funcs {
int (*early_init)(struct hl_device *hdev);
int (*early_fini)(struct hl_device *hdev);
int (*late_init)(struct hl_device *hdev);
void (*late_fini)(struct hl_device *hdev);
int (*sw_init)(struct hl_device *hdev);
int (*sw_fini)(struct hl_device *hdev);
int (*hw_init)(struct hl_device *hdev);
void (*hw_fini)(struct hl_device *hdev, bool hard_reset);
void (*halt_engines)(struct hl_device *hdev, bool hard_reset);
int (*suspend)(struct hl_device *hdev);
int (*resume)(struct hl_device *hdev);
int (*cb_mmap)(struct hl_device *hdev, struct vm_area_struct *vma,
u64 kaddress, phys_addr_t paddress, u32 size);
void (*ring_doorbell)(struct hl_device *hdev, u32 hw_queue_id, u32 pi);
void (*pqe_write)(struct hl_device *hdev, __le64 *pqe,
struct hl_bd *bd);
void* (*asic_dma_alloc_coherent)(struct hl_device *hdev, size_t size,
dma_addr_t *dma_handle, gfp_t flag);
void (*asic_dma_free_coherent)(struct hl_device *hdev, size_t size,
void *cpu_addr, dma_addr_t dma_handle);
void* (*get_int_queue_base)(struct hl_device *hdev, u32 queue_id,
dma_addr_t *dma_handle, u16 *queue_len);
int (*test_queues)(struct hl_device *hdev);
void* (*asic_dma_pool_zalloc)(struct hl_device *hdev, size_t size,
gfp_t mem_flags, dma_addr_t *dma_handle);
void (*asic_dma_pool_free)(struct hl_device *hdev, void *vaddr,
dma_addr_t dma_addr);
void* (*cpu_accessible_dma_pool_alloc)(struct hl_device *hdev,
size_t size, dma_addr_t *dma_handle);
void (*cpu_accessible_dma_pool_free)(struct hl_device *hdev,
size_t size, void *vaddr);
void (*hl_dma_unmap_sg)(struct hl_device *hdev,
struct scatterlist *sgl, int nents,
enum dma_data_direction dir);
int (*cs_parser)(struct hl_device *hdev, struct hl_cs_parser *parser);
int (*asic_dma_map_sg)(struct hl_device *hdev,
struct scatterlist *sgl, int nents,
enum dma_data_direction dir);
u32 (*get_dma_desc_list_size)(struct hl_device *hdev,
struct sg_table *sgt);
void (*add_end_of_cb_packets)(struct hl_device *hdev,
u64 kernel_address, u32 len,
u64 cq_addr, u32 cq_val, u32 msix_num);
void (*update_eq_ci)(struct hl_device *hdev, u32 val);
int (*context_switch)(struct hl_device *hdev, u32 asid);
void (*restore_phase_topology)(struct hl_device *hdev);
int (*debugfs_read32)(struct hl_device *hdev, u64 addr, u32 *val);
int (*debugfs_write32)(struct hl_device *hdev, u64 addr, u32 val);
void (*add_device_attr)(struct hl_device *hdev,
struct attribute_group *dev_attr_grp);
void (*handle_eqe)(struct hl_device *hdev,
struct hl_eq_entry *eq_entry);
void (*set_pll_profile)(struct hl_device *hdev,
enum hl_pll_frequency freq);
void* (*get_events_stat)(struct hl_device *hdev, bool aggregate,
u32 *size);
u64 (*read_pte)(struct hl_device *hdev, u64 addr);
void (*write_pte)(struct hl_device *hdev, u64 addr, u64 val);
void (*mmu_invalidate_cache)(struct hl_device *hdev, bool is_hard,
u32 flags);
void (*mmu_invalidate_cache_range)(struct hl_device *hdev, bool is_hard,
u32 asid, u64 va, u64 size);
int (*send_heartbeat)(struct hl_device *hdev);
habanalabs: add new IOCTL for debug, tracing and profiling Habanalabs ASICs use the ARM coresight infrastructure to support debug, tracing and profiling of neural networks topologies. Because the coresight is configured using register writes and reads, and some of the registers hold sensitive information (e.g. the address in the device's DRAM where the trace data is written to), the user must go through the kernel driver to configure this mechanism. This patch implements the common code of the IOCTL and calls the ASIC-specific function for the actual H/W configuration. The IOCTL supports configuration of seven coresight components: ETR, ETF, STM, FUNNEL, BMON, SPMU and TIMESTAMP The user specifies which component he wishes to configure and provides a pointer to a structure (located in its process space) that contains the relevant configuration. The common code copies the relevant data from the user-space to kernel space and then calls the ASIC-specific function to do the H/W configuration. After the configuration is done, which is usually composed of several IOCTL calls depending on what the user wanted to trace, the user can start executing the topology. The trace data will be written to the user's area in the device's DRAM. After the tracing operation is complete, and user will call the IOCTL again to disable the tracing operation. The user also need to read values from registers for some of the components (e.g. the size of the trace data in the device's DRAM). In that case, the user will provide a pointer to an "output" structure in user-space, which the IOCTL code will fill according the to selected component. Signed-off-by: Omer Shpigelman <oshpigelman@habana.ai> Signed-off-by: Oded Gabbay <oded.gabbay@gmail.com>
2019-04-01 22:31:22 +03:00
int (*debug_coresight)(struct hl_device *hdev, void *data);
bool (*is_device_idle)(struct hl_device *hdev, u32 *mask,
struct seq_file *s);
int (*soft_reset_late_init)(struct hl_device *hdev);
void (*hw_queues_lock)(struct hl_device *hdev);
void (*hw_queues_unlock)(struct hl_device *hdev);
u32 (*get_pci_id)(struct hl_device *hdev);
int (*get_eeprom_data)(struct hl_device *hdev, void *data,
size_t max_size);
int (*send_cpu_message)(struct hl_device *hdev, u32 *msg,
u16 len, u32 timeout, long *result);
enum hl_device_hw_state (*get_hw_state)(struct hl_device *hdev);
int (*pci_bars_map)(struct hl_device *hdev);
u64 (*set_dram_bar_base)(struct hl_device *hdev, u64 addr);
int (*init_iatu)(struct hl_device *hdev);
u32 (*rreg)(struct hl_device *hdev, u32 reg);
void (*wreg)(struct hl_device *hdev, u32 reg, u32 val);
void (*halt_coresight)(struct hl_device *hdev);
int (*get_clk_rate)(struct hl_device *hdev, u32 *cur_clk, u32 *max_clk);
};
/*
* CONTEXTS
*/
#define HL_KERNEL_ASID_ID 0
/**
* struct hl_va_range - virtual addresses range.
* @lock: protects the virtual addresses list.
* @list: list of virtual addresses blocks available for mappings.
* @start_addr: range start address.
* @end_addr: range end address.
*/
struct hl_va_range {
struct mutex lock;
struct list_head list;
u64 start_addr;
u64 end_addr;
};
/**
* struct hl_ctx - user/kernel context.
* @mem_hash: holds mapping from virtual address to virtual memory area
* descriptor (hl_vm_phys_pg_list or hl_userptr).
* @mmu_phys_hash: holds a mapping from physical address to pgt_info structure.
* @mmu_shadow_hash: holds a mapping from shadow address to pgt_info structure.
* @hpriv: pointer to the private (Kernel Driver) data of the process (fd).
* @hdev: pointer to the device structure.
* @refcount: reference counter for the context. Context is released only when
* this hits 0l. It is incremented on CS and CS_WAIT.
* @cs_pending: array of DMA fence objects representing pending CS.
* @host_va_range: holds available virtual addresses for host mappings.
* @dram_va_range: holds available virtual addresses for DRAM mappings.
* @mem_hash_lock: protects the mem_hash.
* @mmu_lock: protects the MMU page tables. Any change to the PGT, modifing the
* MMU hash or walking the PGT requires talking this lock
* @debugfs_list: node in debugfs list of contexts.
* @cs_sequence: sequence number for CS. Value is assigned to a CS and passed
* to user so user could inquire about CS. It is used as
* index to cs_pending array.
* @dram_default_hops: array that holds all hops addresses needed for default
* DRAM mapping.
* @cs_lock: spinlock to protect cs_sequence.
* @dram_phys_mem: amount of used physical DRAM memory by this context.
* @thread_ctx_switch_token: token to prevent multiple threads of the same
* context from running the context switch phase.
* Only a single thread should run it.
* @thread_ctx_switch_wait_token: token to prevent the threads that didn't run
* the context switch phase from moving to their
* execution phase before the context switch phase
* has finished.
* @asid: context's unique address space ID in the device's MMU.
* @handle: context's opaque handle for user
*/
struct hl_ctx {
DECLARE_HASHTABLE(mem_hash, MEM_HASH_TABLE_BITS);
DECLARE_HASHTABLE(mmu_phys_hash, MMU_HASH_TABLE_BITS);
DECLARE_HASHTABLE(mmu_shadow_hash, MMU_HASH_TABLE_BITS);
struct hl_fpriv *hpriv;
struct hl_device *hdev;
struct kref refcount;
struct dma_fence *cs_pending[HL_MAX_PENDING_CS];
struct hl_va_range host_va_range;
struct hl_va_range dram_va_range;
struct mutex mem_hash_lock;
struct mutex mmu_lock;
struct list_head debugfs_list;
u64 cs_sequence;
u64 *dram_default_hops;
spinlock_t cs_lock;
atomic64_t dram_phys_mem;
atomic_t thread_ctx_switch_token;
u32 thread_ctx_switch_wait_token;
u32 asid;
u32 handle;
};
/**
* struct hl_ctx_mgr - for handling multiple contexts.
* @ctx_lock: protects ctx_handles.
* @ctx_handles: idr to hold all ctx handles.
*/
struct hl_ctx_mgr {
struct mutex ctx_lock;
struct idr ctx_handles;
};
/*
* COMMAND SUBMISSIONS
*/
/**
* struct hl_userptr - memory mapping chunk information
* @vm_type: type of the VM.
* @job_node: linked-list node for hanging the object on the Job's list.
* @vec: pointer to the frame vector.
* @sgt: pointer to the scatter-gather table that holds the pages.
* @dir: for DMA unmapping, the direction must be supplied, so save it.
* @debugfs_list: node in debugfs list of command submissions.
* @addr: user-space virtual address of the start of the memory area.
* @size: size of the memory area to pin & map.
* @dma_mapped: true if the SG was mapped to DMA addresses, false otherwise.
*/
struct hl_userptr {
enum vm_type_t vm_type; /* must be first */
struct list_head job_node;
struct frame_vector *vec;
struct sg_table *sgt;
enum dma_data_direction dir;
struct list_head debugfs_list;
u64 addr;
u32 size;
u8 dma_mapped;
};
/**
* struct hl_cs - command submission.
* @jobs_in_queue_cnt: per each queue, maintain counter of submitted jobs.
* @ctx: the context this CS belongs to.
* @job_list: list of the CS's jobs in the various queues.
* @job_lock: spinlock for the CS's jobs list. Needed for free_job.
* @refcount: reference counter for usage of the CS.
* @fence: pointer to the fence object of this CS.
* @work_tdr: delayed work node for TDR.
* @mirror_node : node in device mirror list of command submissions.
* @debugfs_list: node in debugfs list of command submissions.
* @sequence: the sequence number of this CS.
* @submitted: true if CS was submitted to H/W.
* @completed: true if CS was completed by device.
* @timedout : true if CS was timedout.
* @tdr_active: true if TDR was activated for this CS (to prevent
* double TDR activation).
* @aborted: true if CS was aborted due to some device error.
*/
struct hl_cs {
u8 jobs_in_queue_cnt[HL_MAX_QUEUES];
struct hl_ctx *ctx;
struct list_head job_list;
spinlock_t job_lock;
struct kref refcount;
struct dma_fence *fence;
struct delayed_work work_tdr;
struct list_head mirror_node;
struct list_head debugfs_list;
u64 sequence;
u8 submitted;
u8 completed;
u8 timedout;
u8 tdr_active;
u8 aborted;
};
/**
* struct hl_cs_job - command submission job.
* @cs_node: the node to hang on the CS jobs list.
* @cs: the CS this job belongs to.
* @user_cb: the CB we got from the user.
* @patched_cb: in case of patching, this is internal CB which is submitted on
* the queue instead of the CB we got from the IOCTL.
* @finish_work: workqueue object to run when job is completed.
* @userptr_list: linked-list of userptr mappings that belong to this job and
* wait for completion.
* @debugfs_list: node in debugfs list of command submission jobs.
* @queue_type: the type of the H/W queue this job is submitted to.
* @id: the id of this job inside a CS.
* @hw_queue_id: the id of the H/W queue this job is submitted to.
* @user_cb_size: the actual size of the CB we got from the user.
* @job_cb_size: the actual size of the CB that we put on the queue.
* @is_kernel_allocated_cb: true if the CB handle we got from the user holds a
* handle to a kernel-allocated CB object, false
* otherwise (SRAM/DRAM/host address).
*/
struct hl_cs_job {
struct list_head cs_node;
struct hl_cs *cs;
struct hl_cb *user_cb;
struct hl_cb *patched_cb;
struct work_struct finish_work;
struct list_head userptr_list;
struct list_head debugfs_list;
enum hl_queue_type queue_type;
u32 id;
u32 hw_queue_id;
u32 user_cb_size;
u32 job_cb_size;
u8 is_kernel_allocated_cb;
};
/**
* struct hl_cs_parser - command submission parser properties.
* @user_cb: the CB we got from the user.
* @patched_cb: in case of patching, this is internal CB which is submitted on
* the queue instead of the CB we got from the IOCTL.
* @job_userptr_list: linked-list of userptr mappings that belong to the related
* job and wait for completion.
* @cs_sequence: the sequence number of the related CS.
* @queue_type: the type of the H/W queue this job is submitted to.
* @ctx_id: the ID of the context the related CS belongs to.
* @hw_queue_id: the id of the H/W queue this job is submitted to.
* @user_cb_size: the actual size of the CB we got from the user.
* @patched_cb_size: the size of the CB after parsing.
* @job_id: the id of the related job inside the related CS.
* @is_kernel_allocated_cb: true if the CB handle we got from the user holds a
* handle to a kernel-allocated CB object, false
* otherwise (SRAM/DRAM/host address).
*/
struct hl_cs_parser {
struct hl_cb *user_cb;
struct hl_cb *patched_cb;
struct list_head *job_userptr_list;
u64 cs_sequence;
enum hl_queue_type queue_type;
u32 ctx_id;
u32 hw_queue_id;
u32 user_cb_size;
u32 patched_cb_size;
u8 job_id;
u8 is_kernel_allocated_cb;
};
/*
* MEMORY STRUCTURE
*/
/**
* struct hl_vm_hash_node - hash element from virtual address to virtual
* memory area descriptor (hl_vm_phys_pg_list or
* hl_userptr).
* @node: node to hang on the hash table in context object.
* @vaddr: key virtual address.
* @ptr: value pointer (hl_vm_phys_pg_list or hl_userptr).
*/
struct hl_vm_hash_node {
struct hlist_node node;
u64 vaddr;
void *ptr;
};
/**
* struct hl_vm_phys_pg_pack - physical page pack.
* @vm_type: describes the type of the virtual area descriptor.
* @pages: the physical page array.
* @npages: num physical pages in the pack.
* @total_size: total size of all the pages in this list.
* @mapping_cnt: number of shared mappings.
* @asid: the context related to this list.
* @page_size: size of each page in the pack.
* @flags: HL_MEM_* flags related to this list.
* @handle: the provided handle related to this list.
* @offset: offset from the first page.
* @contiguous: is contiguous physical memory.
* @created_from_userptr: is product of host virtual address.
*/
struct hl_vm_phys_pg_pack {
enum vm_type_t vm_type; /* must be first */
u64 *pages;
u64 npages;
u64 total_size;
atomic_t mapping_cnt;
u32 asid;
u32 page_size;
u32 flags;
u32 handle;
u32 offset;
u8 contiguous;
u8 created_from_userptr;
};
/**
* struct hl_vm_va_block - virtual range block information.
* @node: node to hang on the virtual range list in context object.
* @start: virtual range start address.
* @end: virtual range end address.
* @size: virtual range size.
*/
struct hl_vm_va_block {
struct list_head node;
u64 start;
u64 end;
u64 size;
};
/**
* struct hl_vm - virtual memory manager for MMU.
* @dram_pg_pool: pool for DRAM physical pages of 2MB.
* @dram_pg_pool_refcount: reference counter for the pool usage.
* @idr_lock: protects the phys_pg_list_handles.
* @phys_pg_pack_handles: idr to hold all device allocations handles.
* @init_done: whether initialization was done. We need this because VM
* initialization might be skipped during device initialization.
*/
struct hl_vm {
struct gen_pool *dram_pg_pool;
struct kref dram_pg_pool_refcount;
spinlock_t idr_lock;
struct idr phys_pg_pack_handles;
u8 init_done;
};
habanalabs: add new IOCTL for debug, tracing and profiling Habanalabs ASICs use the ARM coresight infrastructure to support debug, tracing and profiling of neural networks topologies. Because the coresight is configured using register writes and reads, and some of the registers hold sensitive information (e.g. the address in the device's DRAM where the trace data is written to), the user must go through the kernel driver to configure this mechanism. This patch implements the common code of the IOCTL and calls the ASIC-specific function for the actual H/W configuration. The IOCTL supports configuration of seven coresight components: ETR, ETF, STM, FUNNEL, BMON, SPMU and TIMESTAMP The user specifies which component he wishes to configure and provides a pointer to a structure (located in its process space) that contains the relevant configuration. The common code copies the relevant data from the user-space to kernel space and then calls the ASIC-specific function to do the H/W configuration. After the configuration is done, which is usually composed of several IOCTL calls depending on what the user wanted to trace, the user can start executing the topology. The trace data will be written to the user's area in the device's DRAM. After the tracing operation is complete, and user will call the IOCTL again to disable the tracing operation. The user also need to read values from registers for some of the components (e.g. the size of the trace data in the device's DRAM). In that case, the user will provide a pointer to an "output" structure in user-space, which the IOCTL code will fill according the to selected component. Signed-off-by: Omer Shpigelman <oshpigelman@habana.ai> Signed-off-by: Oded Gabbay <oded.gabbay@gmail.com>
2019-04-01 22:31:22 +03:00
/*
* DEBUG, PROFILING STRUCTURE
*/
/**
* struct hl_debug_params - Coresight debug parameters.
* @input: pointer to component specific input parameters.
* @output: pointer to component specific output parameters.
* @output_size: size of output buffer.
* @reg_idx: relevant register ID.
* @op: component operation to execute.
* @enable: true if to enable component debugging, false otherwise.
*/
struct hl_debug_params {
void *input;
void *output;
u32 output_size;
u32 reg_idx;
u32 op;
bool enable;
};
/*
* FILE PRIVATE STRUCTURE
*/
/**
* struct hl_fpriv - process information stored in FD private data.
* @hdev: habanalabs device structure.
* @filp: pointer to the given file structure.
* @taskpid: current process ID.
* @ctx: current executing context. TODO: remove for multiple ctx per process
* @ctx_mgr: context manager to handle multiple context for this FD.
* @cb_mgr: command buffer manager to handle multiple buffers for this FD.
* @debugfs_list: list of relevant ASIC debugfs.
* @dev_node: node in the device list of file private data
* @refcount: number of related contexts.
* @restore_phase_mutex: lock for context switch and restore phase.
* @is_control: true for control device, false otherwise
*/
struct hl_fpriv {
struct hl_device *hdev;
struct file *filp;
struct pid *taskpid;
struct hl_ctx *ctx;
struct hl_ctx_mgr ctx_mgr;
struct hl_cb_mgr cb_mgr;
struct list_head debugfs_list;
struct list_head dev_node;
struct kref refcount;
struct mutex restore_phase_mutex;
u8 is_control;
};
/*
* DebugFS
*/
/**
* struct hl_info_list - debugfs file ops.
* @name: file name.
* @show: function to output information.
* @write: function to write to the file.
*/
struct hl_info_list {
const char *name;
int (*show)(struct seq_file *s, void *data);
ssize_t (*write)(struct file *file, const char __user *buf,
size_t count, loff_t *f_pos);
};
/**
* struct hl_debugfs_entry - debugfs dentry wrapper.
* @dent: base debugfs entry structure.
* @info_ent: dentry realted ops.
* @dev_entry: ASIC specific debugfs manager.
*/
struct hl_debugfs_entry {
struct dentry *dent;
const struct hl_info_list *info_ent;
struct hl_dbg_device_entry *dev_entry;
};
/**
* struct hl_dbg_device_entry - ASIC specific debugfs manager.
* @root: root dentry.
* @hdev: habanalabs device structure.
* @entry_arr: array of available hl_debugfs_entry.
* @file_list: list of available debugfs files.
* @file_mutex: protects file_list.
* @cb_list: list of available CBs.
* @cb_spinlock: protects cb_list.
* @cs_list: list of available CSs.
* @cs_spinlock: protects cs_list.
* @cs_job_list: list of available CB jobs.
* @cs_job_spinlock: protects cs_job_list.
* @userptr_list: list of available userptrs (virtual memory chunk descriptor).
* @userptr_spinlock: protects userptr_list.
* @ctx_mem_hash_list: list of available contexts with MMU mappings.
* @ctx_mem_hash_spinlock: protects cb_list.
* @addr: next address to read/write from/to in read/write32.
* @mmu_addr: next virtual address to translate to physical address in mmu_show.
* @mmu_asid: ASID to use while translating in mmu_show.
* @i2c_bus: generic u8 debugfs file for bus value to use in i2c_data_read.
* @i2c_bus: generic u8 debugfs file for address value to use in i2c_data_read.
* @i2c_bus: generic u8 debugfs file for register value to use in i2c_data_read.
*/
struct hl_dbg_device_entry {
struct dentry *root;
struct hl_device *hdev;
struct hl_debugfs_entry *entry_arr;
struct list_head file_list;
struct mutex file_mutex;
struct list_head cb_list;
spinlock_t cb_spinlock;
struct list_head cs_list;
spinlock_t cs_spinlock;
struct list_head cs_job_list;
spinlock_t cs_job_spinlock;
struct list_head userptr_list;
spinlock_t userptr_spinlock;
struct list_head ctx_mem_hash_list;
spinlock_t ctx_mem_hash_spinlock;
u64 addr;
u64 mmu_addr;
u32 mmu_asid;
u8 i2c_bus;
u8 i2c_addr;
u8 i2c_reg;
};
/*
* DEVICES
*/
/* Theoretical limit only. A single host can only contain up to 4 or 8 PCIe
* x16 cards. In extreme cases, there are hosts that can accommodate 16 cards.
*/
#define HL_MAX_MINORS 256
/*
* Registers read & write functions.
*/
u32 hl_rreg(struct hl_device *hdev, u32 reg);
void hl_wreg(struct hl_device *hdev, u32 reg, u32 val);
#define RREG32(reg) hdev->asic_funcs->rreg(hdev, (reg))
#define WREG32(reg, v) hdev->asic_funcs->wreg(hdev, (reg), (v))
#define DREG32(reg) pr_info("REGISTER: " #reg " : 0x%08X\n", \
hdev->asic_funcs->rreg(hdev, (reg)))
#define WREG32_P(reg, val, mask) \
do { \
u32 tmp_ = RREG32(reg); \
tmp_ &= (mask); \
tmp_ |= ((val) & ~(mask)); \
WREG32(reg, tmp_); \
} while (0)
#define WREG32_AND(reg, and) WREG32_P(reg, 0, and)
#define WREG32_OR(reg, or) WREG32_P(reg, or, ~(or))
#define REG_FIELD_SHIFT(reg, field) reg##_##field##_SHIFT
#define REG_FIELD_MASK(reg, field) reg##_##field##_MASK
#define WREG32_FIELD(reg, offset, field, val) \
WREG32(mm##reg + offset, (RREG32(mm##reg + offset) & \
~REG_FIELD_MASK(reg, field)) | \
(val) << REG_FIELD_SHIFT(reg, field))
/* Timeout should be longer when working with simulator but cap the
* increased timeout to some maximum
*/
#define hl_poll_timeout(hdev, addr, val, cond, sleep_us, timeout_us) \
({ \
ktime_t __timeout; \
if (hdev->pdev) \
__timeout = ktime_add_us(ktime_get(), timeout_us); \
else \
__timeout = ktime_add_us(ktime_get(),\
min((u64)(timeout_us * 10), \
(u64) HL_SIM_MAX_TIMEOUT_US)); \
might_sleep_if(sleep_us); \
for (;;) { \
(val) = RREG32(addr); \
if (cond) \
break; \
if (timeout_us && ktime_compare(ktime_get(), __timeout) > 0) { \
(val) = RREG32(addr); \
break; \
} \
if (sleep_us) \
usleep_range((sleep_us >> 2) + 1, sleep_us); \
} \
(cond) ? 0 : -ETIMEDOUT; \
})
/*
* address in this macro points always to a memory location in the
* host's (server's) memory. That location is updated asynchronously
* either by the direct access of the device or by another core.
*
* To work both in LE and BE architectures, we need to distinguish between the
* two states (device or another core updates the memory location). Therefore,
* if mem_written_by_device is true, the host memory being polled will be
* updated directly by the device. If false, the host memory being polled will
* be updated by host CPU. Required so host knows whether or not the memory
* might need to be byte-swapped before returning value to caller.
*/
#define hl_poll_timeout_memory(hdev, addr, val, cond, sleep_us, timeout_us, \
mem_written_by_device) \
({ \
ktime_t __timeout; \
if (hdev->pdev) \
__timeout = ktime_add_us(ktime_get(), timeout_us); \
else \
__timeout = ktime_add_us(ktime_get(),\
min((u64)(timeout_us * 10), \
(u64) HL_SIM_MAX_TIMEOUT_US)); \
might_sleep_if(sleep_us); \
for (;;) { \
/* Verify we read updates done by other cores or by device */ \
mb(); \
(val) = *((u32 *) (uintptr_t) (addr)); \
if (mem_written_by_device) \
(val) = le32_to_cpu(*(__le32 *) &(val)); \
if (cond) \
break; \
if (timeout_us && ktime_compare(ktime_get(), __timeout) > 0) { \
(val) = *((u32 *) (uintptr_t) (addr)); \
if (mem_written_by_device) \
(val) = le32_to_cpu(*(__le32 *) &(val)); \
break; \
} \
if (sleep_us) \
usleep_range((sleep_us >> 2) + 1, sleep_us); \
} \
(cond) ? 0 : -ETIMEDOUT; \
})
#define hl_poll_timeout_device_memory(hdev, addr, val, cond, sleep_us, \
timeout_us) \
({ \
ktime_t __timeout; \
if (hdev->pdev) \
__timeout = ktime_add_us(ktime_get(), timeout_us); \
else \
__timeout = ktime_add_us(ktime_get(),\
min((u64)(timeout_us * 10), \
(u64) HL_SIM_MAX_TIMEOUT_US)); \
might_sleep_if(sleep_us); \
for (;;) { \
(val) = readl(addr); \
if (cond) \
break; \
if (timeout_us && ktime_compare(ktime_get(), __timeout) > 0) { \
(val) = readl(addr); \
break; \
} \
if (sleep_us) \
usleep_range((sleep_us >> 2) + 1, sleep_us); \
} \
(cond) ? 0 : -ETIMEDOUT; \
})
struct hwmon_chip_info;
/**
* struct hl_device_reset_work - reset workqueue task wrapper.
* @reset_work: reset work to be done.
* @hdev: habanalabs device structure.
*/
struct hl_device_reset_work {
struct work_struct reset_work;
struct hl_device *hdev;
};
/**
* struct hl_device_idle_busy_ts - used for calculating device utilization rate.
* @idle_to_busy_ts: timestamp where device changed from idle to busy.
* @busy_to_idle_ts: timestamp where device changed from busy to idle.
*/
struct hl_device_idle_busy_ts {
ktime_t idle_to_busy_ts;
ktime_t busy_to_idle_ts;
};
/**
* struct hl_device - habanalabs device structure.
* @pdev: pointer to PCI device, can be NULL in case of simulator device.
* @pcie_bar: array of available PCIe bars.
* @rmmio: configuration area address on SRAM.
* @cdev: related char device.
* @cdev_ctrl: char device for control operations only (INFO IOCTL)
* @dev: related kernel basic device structure.
* @dev_ctrl: related kernel device structure for the control device
* @work_freq: delayed work to lower device frequency if possible.
* @work_heartbeat: delayed work for ArmCP is-alive check.
* @asic_name: ASIC specific nmae.
* @asic_type: ASIC specific type.
* @completion_queue: array of hl_cq.
* @cq_wq: work queue of completion queues for executing work in process context
* @eq_wq: work queue of event queue for executing work in process context.
* @kernel_ctx: Kernel driver context structure.
* @kernel_queues: array of hl_hw_queue.
* @hw_queues_mirror_list: CS mirror list for TDR.
* @hw_queues_mirror_lock: protects hw_queues_mirror_list.
* @kernel_cb_mgr: command buffer manager for creating/destroying/handling CGs.
* @event_queue: event queue for IRQ from ArmCP.
* @dma_pool: DMA pool for small allocations.
* @cpu_accessible_dma_mem: Host <-> ArmCP shared memory CPU address.
* @cpu_accessible_dma_address: Host <-> ArmCP shared memory DMA address.
* @cpu_accessible_dma_pool: Host <-> ArmCP shared memory pool.
* @asid_bitmap: holds used/available ASIDs.
* @asid_mutex: protects asid_bitmap.
* @send_cpu_message_lock: enforces only one message in Host <-> ArmCP queue.
* @debug_lock: protects critical section of setting debug mode for device
* @asic_prop: ASIC specific immutable properties.
* @asic_funcs: ASIC specific functions.
* @asic_specific: ASIC specific information to use only from ASIC files.
* @mmu_pgt_pool: pool of available MMU hops.
* @vm: virtual memory manager for MMU.
* @mmu_cache_lock: protects MMU cache invalidation as it can serve one context.
* @mmu_shadow_hop0: shadow mapping of the MMU hop 0 zone.
* @hwmon_dev: H/W monitor device.
* @pm_mng_profile: current power management profile.
* @hl_chip_info: ASIC's sensors information.
* @hl_debugfs: device's debugfs manager.
* @cb_pool: list of preallocated CBs.
* @cb_pool_lock: protects the CB pool.
* @fpriv_list: list of file private data structures. Each structure is created
* when a user opens the device
* @fpriv_list_lock: protects the fpriv_list
* @compute_ctx: current compute context executing.
* @idle_busy_ts_arr: array to hold time stamps of transitions from idle to busy
* and vice-versa
* @dram_used_mem: current DRAM memory consumption.
* @timeout_jiffies: device CS timeout value.
* @max_power: the max power of the device, as configured by the sysadmin. This
* value is saved so in case of hard-reset, the driver will restore
* this value and update the F/W after the re-initialization
* @in_reset: is device in reset flow.
* @curr_pll_profile: current PLL profile.
* @cs_active_cnt: number of active command submissions on this device (active
* means already in H/W queues)
* @major: habanalabs kernel driver major.
* @high_pll: high PLL profile frequency.
* @soft_reset_cnt: number of soft reset since the driver was loaded.
* @hard_reset_cnt: number of hard reset since the driver was loaded.
* @idle_busy_ts_idx: index of current entry in idle_busy_ts_arr
* @id: device minor.
* @id_control: minor of the control device
* @disabled: is device disabled.
* @late_init_done: is late init stage was done during initialization.
* @hwmon_initialized: is H/W monitor sensors was initialized.
* @hard_reset_pending: is there a hard reset work pending.
* @heartbeat: is heartbeat sanity check towards ArmCP enabled.
* @reset_on_lockup: true if a reset should be done in case of stuck CS, false
* otherwise.
* @dram_supports_virtual_memory: is MMU enabled towards DRAM.
* @dram_default_page_mapping: is DRAM default page mapping enabled.
* @init_done: is the initialization of the device done.
* @mmu_enable: is MMU enabled.
* @device_cpu_disabled: is the device CPU disabled (due to timeouts)
* @dma_mask: the dma mask that was set for this device
* @in_debug: is device under debug. This, together with fpriv_list, enforces
* that only a single user is configuring the debug infrastructure.
* @cdev_sysfs_created: were char devices and sysfs nodes created.
*/
struct hl_device {
struct pci_dev *pdev;
void __iomem *pcie_bar[6];
void __iomem *rmmio;
struct cdev cdev;
struct cdev cdev_ctrl;
struct device *dev;
struct device *dev_ctrl;
struct delayed_work work_freq;
struct delayed_work work_heartbeat;
char asic_name[16];
enum hl_asic_type asic_type;
struct hl_cq *completion_queue;
struct workqueue_struct *cq_wq;
struct workqueue_struct *eq_wq;
struct hl_ctx *kernel_ctx;
struct hl_hw_queue *kernel_queues;
struct list_head hw_queues_mirror_list;
spinlock_t hw_queues_mirror_lock;
struct hl_cb_mgr kernel_cb_mgr;
struct hl_eq event_queue;
struct dma_pool *dma_pool;
void *cpu_accessible_dma_mem;
dma_addr_t cpu_accessible_dma_address;
struct gen_pool *cpu_accessible_dma_pool;
unsigned long *asid_bitmap;
struct mutex asid_mutex;
struct mutex send_cpu_message_lock;
struct mutex debug_lock;
struct asic_fixed_properties asic_prop;
const struct hl_asic_funcs *asic_funcs;
void *asic_specific;
struct gen_pool *mmu_pgt_pool;
struct hl_vm vm;
struct mutex mmu_cache_lock;
void *mmu_shadow_hop0;
struct device *hwmon_dev;
enum hl_pm_mng_profile pm_mng_profile;
struct hwmon_chip_info *hl_chip_info;
struct hl_dbg_device_entry hl_debugfs;
struct list_head cb_pool;
spinlock_t cb_pool_lock;
struct list_head fpriv_list;
struct mutex fpriv_list_lock;
struct hl_ctx *compute_ctx;
struct hl_device_idle_busy_ts *idle_busy_ts_arr;
atomic64_t dram_used_mem;
u64 timeout_jiffies;
u64 max_power;
atomic_t in_reset;
enum hl_pll_frequency curr_pll_profile;
int cs_active_cnt;
u32 major;
u32 high_pll;
u32 soft_reset_cnt;
u32 hard_reset_cnt;
u32 idle_busy_ts_idx;
u16 id;
u16 id_control;
u8 disabled;
u8 late_init_done;
u8 hwmon_initialized;
u8 hard_reset_pending;
u8 heartbeat;
u8 reset_on_lockup;
u8 dram_supports_virtual_memory;
u8 dram_default_page_mapping;
u8 init_done;
u8 device_cpu_disabled;
u8 dma_mask;
u8 in_debug;
u8 cdev_sysfs_created;
/* Parameters for bring-up */
u8 mmu_enable;
u8 cpu_enable;
u8 reset_pcilink;
u8 cpu_queues_enable;
u8 fw_loading;
u8 pldm;
};
/*
* IOCTLs
*/
/**
* typedef hl_ioctl_t - typedef for ioctl function in the driver
* @hpriv: pointer to the FD's private data, which contains state of
* user process
* @data: pointer to the input/output arguments structure of the IOCTL
*
* Return: 0 for success, negative value for error
*/
typedef int hl_ioctl_t(struct hl_fpriv *hpriv, void *data);
/**
* struct hl_ioctl_desc - describes an IOCTL entry of the driver.
* @cmd: the IOCTL code as created by the kernel macros.
* @func: pointer to the driver's function that should be called for this IOCTL.
*/
struct hl_ioctl_desc {
unsigned int cmd;
hl_ioctl_t *func;
};
/*
* Kernel module functions that can be accessed by entire module
*/
/**
* hl_mem_area_inside_range() - Checks whether address+size are inside a range.
* @address: The start address of the area we want to validate.
* @size: The size in bytes of the area we want to validate.
* @range_start_address: The start address of the valid range.
* @range_end_address: The end address of the valid range.
*
* Return: true if the area is inside the valid range, false otherwise.
*/
static inline bool hl_mem_area_inside_range(u64 address, u32 size,
u64 range_start_address, u64 range_end_address)
{
u64 end_address = address + size;
if ((address >= range_start_address) &&
(end_address <= range_end_address) &&
(end_address > address))
return true;
return false;
}
/**
* hl_mem_area_crosses_range() - Checks whether address+size crossing a range.
* @address: The start address of the area we want to validate.
* @size: The size in bytes of the area we want to validate.
* @range_start_address: The start address of the valid range.
* @range_end_address: The end address of the valid range.
*
* Return: true if the area overlaps part or all of the valid range,
* false otherwise.
*/
static inline bool hl_mem_area_crosses_range(u64 address, u32 size,
u64 range_start_address, u64 range_end_address)
{
u64 end_address = address + size;
if ((address >= range_start_address) &&
(address < range_end_address))
return true;
if ((end_address >= range_start_address) &&
(end_address < range_end_address))
return true;
if ((address < range_start_address) &&
(end_address >= range_end_address))
return true;
return false;
}
int hl_device_open(struct inode *inode, struct file *filp);
int hl_device_open_ctrl(struct inode *inode, struct file *filp);
bool hl_device_disabled_or_in_reset(struct hl_device *hdev);
enum hl_device_status hl_device_status(struct hl_device *hdev);
int hl_device_set_debug_mode(struct hl_device *hdev, bool enable);
int create_hdev(struct hl_device **dev, struct pci_dev *pdev,
enum hl_asic_type asic_type, int minor);
void destroy_hdev(struct hl_device *hdev);
int hl_hw_queues_create(struct hl_device *hdev);
void hl_hw_queues_destroy(struct hl_device *hdev);
int hl_hw_queue_send_cb_no_cmpl(struct hl_device *hdev, u32 hw_queue_id,
u32 cb_size, u64 cb_ptr);
int hl_hw_queue_schedule_cs(struct hl_cs *cs);
u32 hl_hw_queue_add_ptr(u32 ptr, u16 val);
void hl_hw_queue_inc_ci_kernel(struct hl_device *hdev, u32 hw_queue_id);
void hl_int_hw_queue_update_ci(struct hl_cs *cs);
void hl_hw_queue_reset(struct hl_device *hdev, bool hard_reset);
#define hl_queue_inc_ptr(p) hl_hw_queue_add_ptr(p, 1)
#define hl_pi_2_offset(pi) ((pi) & (HL_QUEUE_LENGTH - 1))
int hl_cq_init(struct hl_device *hdev, struct hl_cq *q, u32 hw_queue_id);
void hl_cq_fini(struct hl_device *hdev, struct hl_cq *q);
int hl_eq_init(struct hl_device *hdev, struct hl_eq *q);
void hl_eq_fini(struct hl_device *hdev, struct hl_eq *q);
void hl_cq_reset(struct hl_device *hdev, struct hl_cq *q);
void hl_eq_reset(struct hl_device *hdev, struct hl_eq *q);
irqreturn_t hl_irq_handler_cq(int irq, void *arg);
irqreturn_t hl_irq_handler_eq(int irq, void *arg);
u32 hl_cq_inc_ptr(u32 ptr);
int hl_asid_init(struct hl_device *hdev);
void hl_asid_fini(struct hl_device *hdev);
unsigned long hl_asid_alloc(struct hl_device *hdev);
void hl_asid_free(struct hl_device *hdev, unsigned long asid);
int hl_ctx_create(struct hl_device *hdev, struct hl_fpriv *hpriv);
void hl_ctx_free(struct hl_device *hdev, struct hl_ctx *ctx);
int hl_ctx_init(struct hl_device *hdev, struct hl_ctx *ctx, bool is_kernel_ctx);
void hl_ctx_do_release(struct kref *ref);
void hl_ctx_get(struct hl_device *hdev, struct hl_ctx *ctx);
int hl_ctx_put(struct hl_ctx *ctx);
struct dma_fence *hl_ctx_get_fence(struct hl_ctx *ctx, u64 seq);
void hl_ctx_mgr_init(struct hl_ctx_mgr *mgr);
void hl_ctx_mgr_fini(struct hl_device *hdev, struct hl_ctx_mgr *mgr);
int hl_device_init(struct hl_device *hdev, struct class *hclass);
void hl_device_fini(struct hl_device *hdev);
int hl_device_suspend(struct hl_device *hdev);
int hl_device_resume(struct hl_device *hdev);
int hl_device_reset(struct hl_device *hdev, bool hard_reset,
bool from_hard_reset_thread);
void hl_hpriv_get(struct hl_fpriv *hpriv);
void hl_hpriv_put(struct hl_fpriv *hpriv);
int hl_device_set_frequency(struct hl_device *hdev, enum hl_pll_frequency freq);
uint32_t hl_device_utilization(struct hl_device *hdev, uint32_t period_ms);
int hl_build_hwmon_channel_info(struct hl_device *hdev,
struct armcp_sensor *sensors_arr);
int hl_sysfs_init(struct hl_device *hdev);
void hl_sysfs_fini(struct hl_device *hdev);
int hl_hwmon_init(struct hl_device *hdev);
void hl_hwmon_fini(struct hl_device *hdev);
int hl_cb_create(struct hl_device *hdev, struct hl_cb_mgr *mgr, u32 cb_size,
u64 *handle, int ctx_id);
int hl_cb_destroy(struct hl_device *hdev, struct hl_cb_mgr *mgr, u64 cb_handle);
int hl_cb_mmap(struct hl_fpriv *hpriv, struct vm_area_struct *vma);
struct hl_cb *hl_cb_get(struct hl_device *hdev, struct hl_cb_mgr *mgr,
u32 handle);
void hl_cb_put(struct hl_cb *cb);
void hl_cb_mgr_init(struct hl_cb_mgr *mgr);
void hl_cb_mgr_fini(struct hl_device *hdev, struct hl_cb_mgr *mgr);
struct hl_cb *hl_cb_kernel_create(struct hl_device *hdev, u32 cb_size);
int hl_cb_pool_init(struct hl_device *hdev);
int hl_cb_pool_fini(struct hl_device *hdev);
void hl_cs_rollback_all(struct hl_device *hdev);
struct hl_cs_job *hl_cs_allocate_job(struct hl_device *hdev,
enum hl_queue_type queue_type, bool is_kernel_allocated_cb);
void goya_set_asic_funcs(struct hl_device *hdev);
int hl_vm_ctx_init(struct hl_ctx *ctx);
void hl_vm_ctx_fini(struct hl_ctx *ctx);
int hl_vm_init(struct hl_device *hdev);
void hl_vm_fini(struct hl_device *hdev);
int hl_pin_host_memory(struct hl_device *hdev, u64 addr, u64 size,
struct hl_userptr *userptr);
void hl_unpin_host_memory(struct hl_device *hdev, struct hl_userptr *userptr);
void hl_userptr_delete_list(struct hl_device *hdev,
struct list_head *userptr_list);
bool hl_userptr_is_pinned(struct hl_device *hdev, u64 addr, u32 size,
struct list_head *userptr_list,
struct hl_userptr **userptr);
int hl_mmu_init(struct hl_device *hdev);
void hl_mmu_fini(struct hl_device *hdev);
int hl_mmu_ctx_init(struct hl_ctx *ctx);
void hl_mmu_ctx_fini(struct hl_ctx *ctx);
int hl_mmu_map(struct hl_ctx *ctx, u64 virt_addr, u64 phys_addr, u32 page_size);
int hl_mmu_unmap(struct hl_ctx *ctx, u64 virt_addr, u32 page_size);
void hl_mmu_swap_out(struct hl_ctx *ctx);
void hl_mmu_swap_in(struct hl_ctx *ctx);
int hl_fw_push_fw_to_device(struct hl_device *hdev, const char *fw_name,
void __iomem *dst);
int hl_fw_send_pci_access_msg(struct hl_device *hdev, u32 opcode);
int hl_fw_send_cpu_message(struct hl_device *hdev, u32 hw_queue_id, u32 *msg,
u16 len, u32 timeout, long *result);
int hl_fw_test_cpu_queue(struct hl_device *hdev);
void *hl_fw_cpu_accessible_dma_pool_alloc(struct hl_device *hdev, size_t size,
dma_addr_t *dma_handle);
void hl_fw_cpu_accessible_dma_pool_free(struct hl_device *hdev, size_t size,
void *vaddr);
int hl_fw_send_heartbeat(struct hl_device *hdev);
int hl_fw_armcp_info_get(struct hl_device *hdev);
int hl_fw_get_eeprom_data(struct hl_device *hdev, void *data, size_t max_size);
int hl_pci_bars_map(struct hl_device *hdev, const char * const name[3],
bool is_wc[3]);
int hl_pci_iatu_write(struct hl_device *hdev, u32 addr, u32 data);
int hl_pci_set_dram_bar_base(struct hl_device *hdev, u8 inbound_region, u8 bar,
u64 addr);
int hl_pci_init_iatu(struct hl_device *hdev, u64 sram_base_address,
u64 dram_base_address, u64 host_phys_base_address,
u64 host_phys_size);
int hl_pci_init(struct hl_device *hdev, u8 dma_mask);
void hl_pci_fini(struct hl_device *hdev);
int hl_pci_set_dma_mask(struct hl_device *hdev, u8 dma_mask);
long hl_get_frequency(struct hl_device *hdev, u32 pll_index, bool curr);
void hl_set_frequency(struct hl_device *hdev, u32 pll_index, u64 freq);
long hl_get_temperature(struct hl_device *hdev, int sensor_index, u32 attr);
long hl_get_voltage(struct hl_device *hdev, int sensor_index, u32 attr);
long hl_get_current(struct hl_device *hdev, int sensor_index, u32 attr);
long hl_get_fan_speed(struct hl_device *hdev, int sensor_index, u32 attr);
long hl_get_pwm_info(struct hl_device *hdev, int sensor_index, u32 attr);
void hl_set_pwm_info(struct hl_device *hdev, int sensor_index, u32 attr,
long value);
u64 hl_get_max_power(struct hl_device *hdev);
void hl_set_max_power(struct hl_device *hdev, u64 value);
#ifdef CONFIG_DEBUG_FS
void hl_debugfs_init(void);
void hl_debugfs_fini(void);
void hl_debugfs_add_device(struct hl_device *hdev);
void hl_debugfs_remove_device(struct hl_device *hdev);
void hl_debugfs_add_file(struct hl_fpriv *hpriv);
void hl_debugfs_remove_file(struct hl_fpriv *hpriv);
void hl_debugfs_add_cb(struct hl_cb *cb);
void hl_debugfs_remove_cb(struct hl_cb *cb);
void hl_debugfs_add_cs(struct hl_cs *cs);
void hl_debugfs_remove_cs(struct hl_cs *cs);
void hl_debugfs_add_job(struct hl_device *hdev, struct hl_cs_job *job);
void hl_debugfs_remove_job(struct hl_device *hdev, struct hl_cs_job *job);
void hl_debugfs_add_userptr(struct hl_device *hdev, struct hl_userptr *userptr);
void hl_debugfs_remove_userptr(struct hl_device *hdev,
struct hl_userptr *userptr);
void hl_debugfs_add_ctx_mem_hash(struct hl_device *hdev, struct hl_ctx *ctx);
void hl_debugfs_remove_ctx_mem_hash(struct hl_device *hdev, struct hl_ctx *ctx);
#else
static inline void __init hl_debugfs_init(void)
{
}
static inline void hl_debugfs_fini(void)
{
}
static inline void hl_debugfs_add_device(struct hl_device *hdev)
{
}
static inline void hl_debugfs_remove_device(struct hl_device *hdev)
{
}
static inline void hl_debugfs_add_file(struct hl_fpriv *hpriv)
{
}
static inline void hl_debugfs_remove_file(struct hl_fpriv *hpriv)
{
}
static inline void hl_debugfs_add_cb(struct hl_cb *cb)
{
}
static inline void hl_debugfs_remove_cb(struct hl_cb *cb)
{
}
static inline void hl_debugfs_add_cs(struct hl_cs *cs)
{
}
static inline void hl_debugfs_remove_cs(struct hl_cs *cs)
{
}
static inline void hl_debugfs_add_job(struct hl_device *hdev,
struct hl_cs_job *job)
{
}
static inline void hl_debugfs_remove_job(struct hl_device *hdev,
struct hl_cs_job *job)
{
}
static inline void hl_debugfs_add_userptr(struct hl_device *hdev,
struct hl_userptr *userptr)
{
}
static inline void hl_debugfs_remove_userptr(struct hl_device *hdev,
struct hl_userptr *userptr)
{
}
static inline void hl_debugfs_add_ctx_mem_hash(struct hl_device *hdev,
struct hl_ctx *ctx)
{
}
static inline void hl_debugfs_remove_ctx_mem_hash(struct hl_device *hdev,
struct hl_ctx *ctx)
{
}
#endif
/* IOCTLs */
long hl_ioctl(struct file *filep, unsigned int cmd, unsigned long arg);
long hl_ioctl_control(struct file *filep, unsigned int cmd, unsigned long arg);
int hl_cb_ioctl(struct hl_fpriv *hpriv, void *data);
int hl_cs_ioctl(struct hl_fpriv *hpriv, void *data);
int hl_cs_wait_ioctl(struct hl_fpriv *hpriv, void *data);
int hl_mem_ioctl(struct hl_fpriv *hpriv, void *data);
#endif /* HABANALABSP_H_ */