/*
* GK20A Graphics
*
* Copyright (c) 2011-2016, NVIDIA CORPORATION. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef GK20A_H
#define GK20A_H
struct gk20a;
struct fifo_gk20a;
struct channel_gk20a;
struct gr_gk20a;
struct sim_gk20a;
struct gk20a_ctxsw_ucode_segments;
struct gk20a_fecs_trace;
struct gk20a_ctxsw_trace;
struct acr_desc;
#include <linux/sched.h>
#include <linux/spinlock.h>
#include <linux/nvgpu.h>
#include <linux/irqreturn.h>
#include <linux/tegra-soc.h>
#include <linux/version.h>
#include "../../../arch/arm/mach-tegra/iomap.h"
#include "as_gk20a.h"
#include "clk_gk20a.h"
#include "ce2_gk20a.h"
#include "fifo_gk20a.h"
#include "tsg_gk20a.h"
#include "gr_gk20a.h"
#include "sim_gk20a.h"
#include "pmu_gk20a.h"
#include "priv_ring_gk20a.h"
#include "therm_gk20a.h"
#include "platform_gk20a.h"
#include "gm20b/acr_gm20b.h"
#include "acr.h"
#include "cde_gk20a.h"
#include "debug_gk20a.h"
#include "sched_gk20a.h"
/* PTIMER_REF_FREQ_HZ corresponds to a period of 32 nanoseconds.
32 ns is the resolution of ptimer. */
#define PTIMER_REF_FREQ_HZ 31250000
struct cooling_device_gk20a {
struct thermal_cooling_device *gk20a_cooling_dev;
unsigned int gk20a_freq_state;
unsigned int gk20a_freq_table_size;
struct gk20a *g;
};
#ifdef CONFIG_DEBUG_FS
struct railgate_stats {
unsigned long last_rail_gate_start;
unsigned long last_rail_gate_complete;
unsigned long last_rail_ungate_start;
unsigned long last_rail_ungate_complete;
unsigned long total_rail_gate_time_ms;
unsigned long total_rail_ungate_time_ms;
unsigned long railgating_cycle_count;
};
#endif
enum gk20a_cbc_op {
gk20a_cbc_op_clear,
gk20a_cbc_op_clean,
gk20a_cbc_op_invalidate,
};
#define MC_INTR_UNIT_DISABLE false
#define MC_INTR_UNIT_ENABLE true
enum nvgpu_litter_value {
GPU_LIT_NUM_GPCS,
GPU_LIT_NUM_PES_PER_GPC,
GPU_LIT_NUM_ZCULL_BANKS,
GPU_LIT_NUM_TPC_PER_GPC,
GPU_LIT_NUM_FBPS,
GPU_LIT_GPC_BASE,
GPU_LIT_GPC_STRIDE,
GPU_LIT_GPC_SHARED_BASE,
GPU_LIT_TPC_IN_GPC_BASE,
GPU_LIT_TPC_IN_GPC_STRIDE,
GPU_LIT_TPC_IN_GPC_SHARED_BASE,
GPU_LIT_PPC_IN_GPC_BASE,
GPU_LIT_PPC_IN_GPC_STRIDE,
GPU_LIT_ROP_BASE,
GPU_LIT_ROP_STRIDE,
GPU_LIT_ROP_SHARED_BASE,
GPU_LIT_HOST_NUM_ENGINES,
GPU_LIT_HOST_NUM_PBDMA,
GPU_LIT_LTC_STRIDE,
GPU_LIT_LTS_STRIDE,
GPU_LIT_NUM_FBPAS,
GPU_LIT_FBPA_STRIDE,
};
#define nvgpu_get_litter_value(g, v) (g)->ops.get_litter_value((g), v)
struct gpu_ops {
struct {
int (*determine_L2_size_bytes)(struct gk20a *gk20a);
int (*init_comptags)(struct gk20a *g, struct gr_gk20a *gr);
int (*cbc_ctrl)(struct gk20a *g, enum gk20a_cbc_op op,
u32 min, u32 max);
void (*set_zbc_color_entry)(struct gk20a *g,
struct zbc_entry *color_val,
u32 index);
void (*set_zbc_depth_entry)(struct gk20a *g,
struct zbc_entry *depth_val,
u32 index);
void (*init_cbc)(struct gk20a *g, struct gr_gk20a *gr);
void (*sync_debugfs)(struct gk20a *g);
void (*init_fs_state)(struct gk20a *g);
void (*elpg_flush)(struct gk20a *g);
void (*isr)(struct gk20a *g);
u32 (*cbc_fix_config)(struct gk20a *g, int base);
void (*flush)(struct gk20a *g);
} ltc;
struct {
void (*isr_stall)(struct gk20a *g, u32 inst_id, u32 pri_base);
void (*isr_nonstall)(struct gk20a *g, u32 inst_id, u32 pri_base);
} ce2;
struct {
int (*init_fs_state)(struct gk20a *g);
int (*init_preemption_state)(struct gk20a *g);
void (*access_smpc_reg)(struct gk20a *g, u32 quad, u32 offset);
void (*bundle_cb_defaults)(struct gk20a *g);
void (*cb_size_default)(struct gk20a *g);
int (*calc_global_ctx_buffer_size)(struct gk20a *g);
void (*commit_global_attrib_cb)(struct gk20a *g,
struct channel_ctx_gk20a *ch_ctx,
u64 addr, bool patch);
void (*commit_global_bundle_cb)(struct gk20a *g,
struct channel_ctx_gk20a *ch_ctx,
u64 addr, u64 size, bool patch);
int (*commit_global_cb_manager)(struct gk20a *g,
struct channel_gk20a *ch,
bool patch);
void (*commit_global_pagepool)(struct gk20a *g,
struct channel_ctx_gk20a *ch_ctx,
u64 addr, u32 size, bool patch);
void (*init_gpc_mmu)(struct gk20a *g);
int (*handle_sw_method)(struct gk20a *g, u32 addr,
u32 class_num, u32 offset, u32 data);
void (*set_alpha_circular_buffer_size)(struct gk20a *g,
u32 data);
void (*set_circular_buffer_size)(struct gk20a *g, u32 data);
void (*enable_hww_exceptions)(struct gk20a *g);
bool (*is_valid_class)(struct gk20a *g, u32 class_num);
void (*get_sm_dsm_perf_regs)(struct gk20a *g,
u32 *num_sm_dsm_perf_regs,
u32 **sm_dsm_perf_regs,
u32 *perf_register_stride);
void (*get_sm_dsm_perf_ctrl_regs)(struct gk20a *g,
u32 *num_sm_dsm_perf_regs,
u32 **sm_dsm_perf_regs,
u32 *perf_register_stride);
void (*set_hww_esr_report_mask)(struct gk20a *g);
int (*setup_alpha_beta_tables)(struct gk20a *g,
struct gr_gk20a *gr);
int (*falcon_load_ucode)(struct gk20a *g,
u64 addr_base,
struct gk20a_ctxsw_ucode_segments *segments,
u32 reg_offset);
int (*load_ctxsw_ucode)(struct gk20a *g);
u32 (*get_gpc_tpc_mask)(struct gk20a *g, u32 gpc_index);
void (*set_gpc_tpc_mask)(struct gk20a *g, u32 gpc_index);
void (*free_channel_ctx)(struct channel_gk20a *c);
int (*alloc_obj_ctx)(struct channel_gk20a *c,
struct nvgpu_alloc_obj_ctx_args *args);
int (*free_obj_ctx)(struct channel_gk20a *c,
struct nvgpu_free_obj_ctx_args *args);
int (*bind_ctxsw_zcull)(struct gk20a *g, struct gr_gk20a *gr,
struct channel_gk20a *c, u64 zcull_va,
u32 mode);
int (*get_zcull_info)(struct gk20a *g, struct gr_gk20a *gr,
struct gr_zcull_info *zcull_params);
bool (*is_tpc_addr)(struct gk20a *g, u32 addr);
u32 (*get_tpc_num)(struct gk20a *g, u32 addr);
bool (*is_ltcs_ltss_addr)(struct gk20a *g, u32 addr);
bool (*is_ltcn_ltss_addr)(struct gk20a *g, u32 addr);
bool (*get_lts_in_ltc_shared_base)(void);
void (*split_lts_broadcast_addr)(struct gk20a *g, u32 addr,
u32 *priv_addr_table,
u32 *priv_addr_table_index);
void (*split_ltc_broadcast_addr)(struct gk20a *g, u32 addr,
u32 *priv_addr_table,
u32 *priv_addr_table_index);
void (*detect_sm_arch)(struct gk20a *g);
int (*add_zbc_color)(struct gk20a *g, struct gr_gk20a *gr,
struct zbc_entry *color_val, u32 index);
int (*add_zbc_depth)(struct gk20a *g, struct gr_gk20a *gr,
struct zbc_entry *depth_val, u32 index);
int (*zbc_set_table)(struct gk20a *g, struct gr_gk20a *gr,
struct zbc_entry *zbc_val);
int (*zbc_query_table)(struct gk20a *g, struct gr_gk20a *gr,
struct zbc_query_params *query_params);
void (*pmu_save_zbc)(struct gk20a *g, u32 entries);
int (*add_zbc)(struct gk20a *g, struct gr_gk20a *gr,
struct zbc_entry *zbc_val);
u32 (*pagepool_default_size)(struct gk20a *g);
int (*init_ctx_state)(struct gk20a *g);
int (*alloc_gr_ctx)(struct gk20a *g,
struct gr_ctx_desc **__gr_ctx, struct vm_gk20a *vm,
u32 class, u32 padding);
void (*free_gr_ctx)(struct gk20a *g,
struct vm_gk20a *vm,
struct gr_ctx_desc *gr_ctx);
void (*update_ctxsw_preemption_mode)(struct gk20a *g,
struct channel_ctx_gk20a *ch_ctx,
struct mem_desc *mem);
int (*update_smpc_ctxsw_mode)(struct gk20a *g,
struct channel_gk20a *c,
bool enable);
int (*update_hwpm_ctxsw_mode)(struct gk20a *g,
struct channel_gk20a *c,
bool enable);
int (*dump_gr_regs)(struct gk20a *g,
struct gk20a_debug_output *o);
int (*update_pc_sampling)(struct channel_gk20a *ch,
bool enable);
u32 (*get_max_fbps_count)(struct gk20a *g);
u32 (*get_fbp_en_mask)(struct gk20a *g);
u32 (*get_max_ltc_per_fbp)(struct gk20a *g);
u32 (*get_max_lts_per_ltc)(struct gk20a *g);
u32* (*get_rop_l2_en_mask)(struct gk20a *g);
void (*init_sm_dsm_reg_info)(void);
int (*wait_empty)(struct gk20a *g, unsigned long end_jiffies,
u32 expect_delay);
void (*init_cyclestats)(struct gk20a *g);
void (*enable_cde_in_fecs)(struct gk20a *g,
struct mem_desc *mem);
int (*set_sm_debug_mode)(struct gk20a *g, struct channel_gk20a *ch,
u64 sms, bool enable);
void (*bpt_reg_info)(struct gk20a *g,
struct warpstate *w_state);
void (*get_access_map)(struct gk20a *g,
u32 **whitelist, int *num_entries);
int (*handle_fecs_error)(struct gk20a *g,
struct channel_gk20a *ch,
struct gr_gk20a_isr_data *isr_data);
int (*pre_process_sm_exception)(struct gk20a *g,
u32 gpc, u32 tpc, u32 global_esr, u32 warp_esr,
bool sm_debugger_attached,
struct channel_gk20a *fault_ch,
bool *early_exit, bool *ignore_debugger);
u32 (*mask_hww_warp_esr)(u32 hww_warp_esr);
int (*handle_sm_exception)(struct gk20a *g, u32 gpc, u32 tpc,
bool *post_event, struct channel_gk20a *fault_ch);
int (*handle_tex_exception)(struct gk20a *g, u32 gpc, u32 tpc,
bool *post_event);
void (*create_gr_sysfs)(struct device *dev);
u32 (*get_lrf_tex_ltc_dram_override)(struct gk20a *g);
int (*record_sm_error_state)(struct gk20a *g,
u32 gpc, u32 tpc);
int (*update_sm_error_state)(struct gk20a *g,
struct channel_gk20a *ch, u32 sm_id,
struct nvgpu_dbg_gpu_sm_error_state_record *
sm_error_state);
int (*clear_sm_error_state)(struct gk20a *g,
struct channel_gk20a *ch, u32 sm_id);
int (*suspend_contexts)(struct gk20a *g,
struct dbg_session_gk20a *dbg_s,
int *ctx_resident_ch_fd);
int (*set_preemption_mode)(struct channel_gk20a *ch,
u32 graphics_preempt_mode,
u32 compute_preempt_mode);
int (*get_preemption_mode_flags)(struct gk20a *g,
struct nvgpu_preemption_modes_rec *preemption_modes_rec);
int (*fuse_override)(struct gk20a *g);
int (*load_smid_config)(struct gk20a *g);
void (*program_sm_id_numbering)(struct gk20a *g,
u32 gpc, u32 tpc, u32 smid);
void (*program_active_tpc_counts)(struct gk20a *g, u32 gpc);
} gr;
const char *name;
struct {
void (*init_fs_state)(struct gk20a *g);
void (*reset)(struct gk20a *g);
void (*init_uncompressed_kind_map)(struct gk20a *g);
void (*init_kind_attr)(struct gk20a *g);
void (*set_mmu_page_size)(struct gk20a *g);
bool (*set_use_full_comp_tag_line)(struct gk20a *g);
int (*compression_page_size)(struct gk20a *g);
int (*compressible_page_size)(struct gk20a *g);
void (*dump_vpr_wpr_info)(struct gk20a *g);
} fb;
struct {
void (*slcg_bus_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_ce2_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_chiplet_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_ctxsw_firmware_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_fb_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_fifo_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_gr_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_ltc_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_perf_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_priring_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_pmu_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_therm_load_gating_prod)(struct gk20a *g, bool prod);
void (*slcg_xbar_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_bus_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_ce_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_ctxsw_firmware_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_fb_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_fifo_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_gr_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_ltc_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_pwr_csb_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_pmu_load_gating_prod)(struct gk20a *g, bool prod);
void (*blcg_xbar_load_gating_prod)(struct gk20a *g, bool prod);
void (*pg_gr_load_gating_prod)(struct gk20a *g, bool prod);
} clock_gating;
struct {
void (*bind_channel)(struct channel_gk20a *ch_gk20a);
void (*unbind_channel)(struct channel_gk20a *ch_gk20a);
void (*disable_channel)(struct channel_gk20a *ch);
void (*enable_channel)(struct channel_gk20a *ch);
int (*alloc_inst)(struct gk20a *g, struct channel_gk20a *ch);
void (*free_inst)(struct gk20a *g, struct channel_gk20a *ch);
int (*setup_ramfc)(struct channel_gk20a *c, u64 gpfifo_base,
u32 gpfifo_entries, u32 flags);
int (*resetup_ramfc)(struct channel_gk20a *c);
int (*preempt_channel)(struct gk20a *g, u32 hw_chid);
int (*preempt_tsg)(struct gk20a *g, u32 tsgid);
int (*update_runlist)(struct gk20a *g, u32 runlist_id,
u32 hw_chid, bool add,
bool wait_for_finish);
void (*trigger_mmu_fault)(struct gk20a *g,
unsigned long engine_ids);
void (*apply_pb_timeout)(struct gk20a *g);
int (*wait_engine_idle)(struct gk20a *g);
u32 (*get_num_fifos)(struct gk20a *g);
u32 (*get_pbdma_signature)(struct gk20a *g);
int (*channel_set_priority)(struct channel_gk20a *ch, u32 priority);
int (*set_runlist_interleave)(struct gk20a *g, u32 id,
bool is_tsg, u32 runlist_id,
u32 new_level);
int (*channel_set_timeslice)(struct channel_gk20a *ch,
u32 timeslice);
int (*tsg_set_timeslice)(struct tsg_gk20a *tsg, u32 timeslice);
int (*force_reset_ch)(struct channel_gk20a *ch, bool verbose);
int (*engine_enum_from_type)(struct gk20a *g, u32 engine_type,
u32 *inst_id);
void (*device_info_data_parse)(struct gk20a *g,
u32 table_entry, u32 *inst_id,
u32 *pri_base, u32 *fault_id);
int (*tsg_bind_channel)(struct tsg_gk20a *tsg,
struct channel_gk20a *ch);
int (*tsg_unbind_channel)(struct channel_gk20a *ch);
u32 (*eng_runlist_base_size)(void);
int (*init_engine_info)(struct fifo_gk20a *f);
} fifo;
struct pmu_v {
/*used for change of enum zbc update cmd id from ver 0 to ver1*/
u32 cmd_id_zbc_table_update;
u32 (*get_pmu_cmdline_args_size)(struct pmu_gk20a *pmu);
void (*set_pmu_cmdline_args_cpu_freq)(struct pmu_gk20a *pmu,
u32 freq);
void (*set_pmu_cmdline_args_trace_size)(struct pmu_gk20a *pmu,
u32 size);
void (*set_pmu_cmdline_args_trace_dma_base)(
struct pmu_gk20a *pmu);
void (*set_pmu_cmdline_args_trace_dma_idx)(
struct pmu_gk20a *pmu, u32 idx);
void * (*get_pmu_cmdline_args_ptr)(struct pmu_gk20a *pmu);
u32 (*get_pmu_allocation_struct_size)(struct pmu_gk20a *pmu);
void (*set_pmu_allocation_ptr)(struct pmu_gk20a *pmu,
void **pmu_alloc_ptr, void *assign_ptr);
void (*pmu_allocation_set_dmem_size)(struct pmu_gk20a *pmu,
void *pmu_alloc_ptr, u16 size);
u16 (*pmu_allocation_get_dmem_size)(struct pmu_gk20a *pmu,
void *pmu_alloc_ptr);
u32 (*pmu_allocation_get_dmem_offset)(struct pmu_gk20a *pmu,
void *pmu_alloc_ptr);
u32 * (*pmu_allocation_get_dmem_offset_addr)(
struct pmu_gk20a *pmu, void *pmu_alloc_ptr);
void (*pmu_allocation_set_dmem_offset)(struct pmu_gk20a *pmu,
void *pmu_alloc_ptr, u32 offset);
void (*get_pmu_init_msg_pmu_queue_params)(
struct pmu_queue *queue, u32 id,
void *pmu_init_msg);
void *(*get_pmu_msg_pmu_init_msg_ptr)(
struct pmu_init_msg *init);
u16 (*get_pmu_init_msg_pmu_sw_mg_off)(
union pmu_init_msg_pmu *init_msg);
u16 (*get_pmu_init_msg_pmu_sw_mg_size)(
union pmu_init_msg_pmu *init_msg);
u32 (*get_pmu_perfmon_cmd_start_size)(void);
int (*get_perfmon_cmd_start_offsetofvar)(
enum pmu_perfmon_cmd_start_fields field);
void (*perfmon_start_set_cmd_type)(struct pmu_perfmon_cmd *pc,
u8 value);
void (*perfmon_start_set_group_id)(struct pmu_perfmon_cmd *pc,
u8 value);
void (*perfmon_start_set_state_id)(struct pmu_perfmon_cmd *pc,
u8 value);
void (*perfmon_start_set_flags)(struct pmu_perfmon_cmd *pc,
u8 value);
u8 (*perfmon_start_get_flags)(struct pmu_perfmon_cmd *pc);
u32 (*get_pmu_perfmon_cmd_init_size)(void);
int (*get_perfmon_cmd_init_offsetofvar)(
enum pmu_perfmon_cmd_start_fields field);
void (*perfmon_cmd_init_set_sample_buffer)(
struct pmu_perfmon_cmd *pc, u16 value);
void (*perfmon_cmd_init_set_dec_cnt)(
struct pmu_perfmon_cmd *pc, u8 value);
void (*perfmon_cmd_init_set_base_cnt_id)(
struct pmu_perfmon_cmd *pc, u8 value);
void (*perfmon_cmd_init_set_samp_period_us)(
struct pmu_perfmon_cmd *pc, u32 value);
void (*perfmon_cmd_init_set_num_cnt)(struct pmu_perfmon_cmd *pc,
u8 value);
void (*perfmon_cmd_init_set_mov_avg)(struct pmu_perfmon_cmd *pc,
u8 value);
void *(*get_pmu_seq_in_a_ptr)(
struct pmu_sequence *seq);
void *(*get_pmu_seq_out_a_ptr)(
struct pmu_sequence *seq);
void (*set_pmu_cmdline_args_secure_mode)(struct pmu_gk20a *pmu,
u32 val);
u32 (*get_perfmon_cntr_sz)(struct pmu_gk20a *pmu);
void * (*get_perfmon_cntr_ptr)(struct pmu_gk20a *pmu);
void (*set_perfmon_cntr_ut)(struct pmu_gk20a *pmu, u16 ut);
void (*set_perfmon_cntr_lt)(struct pmu_gk20a *pmu, u16 lt);
void (*set_perfmon_cntr_valid)(struct pmu_gk20a *pmu, u8 val);
void (*set_perfmon_cntr_index)(struct pmu_gk20a *pmu, u8 val);
void (*set_perfmon_cntr_group_id)(struct pmu_gk20a *pmu,
u8 gid);
u8 (*pg_cmd_eng_buf_load_size)(struct pmu_pg_cmd *pg);
void (*pg_cmd_eng_buf_load_set_cmd_type)(struct pmu_pg_cmd *pg,
u8 value);
void (*pg_cmd_eng_buf_load_set_engine_id)(struct pmu_pg_cmd *pg,
u8 value);
void (*pg_cmd_eng_buf_load_set_buf_idx)(struct pmu_pg_cmd *pg,
u8 value);
void (*pg_cmd_eng_buf_load_set_pad)(struct pmu_pg_cmd *pg,
u8 value);
void (*pg_cmd_eng_buf_load_set_buf_size)(struct pmu_pg_cmd *pg,
u16 value);
void (*pg_cmd_eng_buf_load_set_dma_base)(struct pmu_pg_cmd *pg,
u32 value);
void (*pg_cmd_eng_buf_load_set_dma_offset)(struct pmu_pg_cmd *pg,
u8 value);
void (*pg_cmd_eng_buf_load_set_dma_idx)(struct pmu_pg_cmd *pg,
u8 value);
} pmu_ver;
struct {
int (*get_netlist_name)(struct gk20a *g, int index, char *name);
bool (*is_fw_defined)(void);
bool use_dma_for_fw_bootstrap;
} gr_ctx;
struct {
int (*init)(struct gk20a *g);
int (*max_entries)(struct gk20a *,
struct nvgpu_ctxsw_trace_filter *);
int (*flush)(struct gk20a *g);
int (*poll)(struct gk20a *g);
int (*enable)(struct gk20a *g);
int (*disable)(struct gk20a *g);
int (*reset)(struct gk20a *g);
int (*bind_channel)(struct gk20a *, struct channel_gk20a *);
int (*unbind_channel)(struct gk20a *, struct channel_gk20a *);
int (*deinit)(struct gk20a *g);
int (*alloc_user_buffer)(struct gk20a *g,
void **buf, size_t *size);
int (*free_user_buffer)(struct gk20a *g);
int (*mmap_user_buffer)(struct gk20a *g,
struct vm_area_struct *vma);
int (*set_filter)(struct gk20a *g,
struct nvgpu_ctxsw_trace_filter *filter);
} fecs_trace;
struct {
bool (*support_sparse)(struct gk20a *g);
bool (*is_debug_mode_enabled)(struct gk20a *g);
void (*set_debug_mode)(struct gk20a *g, bool enable);
u64 (*gmmu_map)(struct vm_gk20a *vm,
u64 map_offset,
struct sg_table *sgt,
u64 buffer_offset,
u64 size,
int pgsz_idx,
u8 kind_v,
u32 ctag_offset,
u32 flags,
int rw_flag,
bool clear_ctags,
bool sparse,
bool priv,
struct vm_gk20a_mapping_batch *batch,
enum gk20a_aperture aperture);
void (*gmmu_unmap)(struct vm_gk20a *vm,
u64 vaddr,
u64 size,
int pgsz_idx,
bool va_allocated,
int rw_flag,
bool sparse,
struct vm_gk20a_mapping_batch *batch);
void (*vm_remove)(struct vm_gk20a *vm);
int (*vm_alloc_share)(struct gk20a_as_share *as_share,
u32 big_page_size, u32 flags);
int (*vm_bind_channel)(struct gk20a_as_share *as_share,
struct channel_gk20a *ch);
int (*fb_flush)(struct gk20a *g);
void (*l2_invalidate)(struct gk20a *g);
void (*l2_flush)(struct gk20a *g, bool invalidate);
void (*cbc_clean)(struct gk20a *g);
void (*tlb_invalidate)(struct vm_gk20a *vm);
void (*set_big_page_size)(struct gk20a *g,
struct mem_desc *mem, int size);
u32 (*get_big_page_sizes)(void);
u32 (*get_physical_addr_bits)(struct gk20a *g);
int (*init_mm_setup_hw)(struct gk20a *g);
int (*init_bar2_vm)(struct gk20a *g);
int (*init_bar2_mm_hw_setup)(struct gk20a *g);
void (*remove_bar2_vm)(struct gk20a *g);
const struct gk20a_mmu_level *
(*get_mmu_levels)(struct gk20a *g, u32 big_page_size);
void (*init_pdb)(struct gk20a *g, struct mem_desc *inst_block,
struct vm_gk20a *vm);
u64 (*get_iova_addr)(struct gk20a *g, struct scatterlist *sgl,
u32 flags);
int (*bar1_bind)(struct gk20a *g, struct mem_desc *bar1_inst);
size_t (*get_vidmem_size)(struct gk20a *g);
} mm;
struct {
int (*init_therm_setup_hw)(struct gk20a *g);
int (*update_therm_gate_ctrl)(struct gk20a *g);
} therm;
struct {
int (*prepare_ucode)(struct gk20a *g);
int (*pmu_setup_hw_and_bootstrap)(struct gk20a *g);
int (*pmu_nsbootstrap)(struct pmu_gk20a *pmu);
int (*pmu_setup_elpg)(struct gk20a *g);
int (*init_wpr_region)(struct gk20a *g);
int (*load_lsfalcon_ucode)(struct gk20a *g, u32 falconidmask);
void (*write_dmatrfbase)(struct gk20a *g, u32 addr);
void (*pmu_elpg_statistics)(struct gk20a *g,
u32 *ingating_time, u32 *ungating_time,
u32 *gating_cnt);
int (*pmu_pg_grinit_param)(struct gk20a *g,
u8 grfeaturemask);
int (*send_lrf_tex_ltc_dram_overide_en_dis_cmd)
(struct gk20a *g, u32 mask);
void (*dump_secure_fuses)(struct gk20a *g);
int (*reset)(struct gk20a *g);
int (*falcon_wait_for_halt)(struct gk20a *g,
unsigned int timeout);
int (*falcon_clear_halt_interrupt_status)(struct gk20a *g,
unsigned int timeout);
int (*init_falcon_setup_hw)(struct gk20a *g,
void *desc, u32 bl_sz);
bool (*is_lazy_bootstrap)(u32 falcon_id);
bool (*is_priv_load)(u32 falcon_id);
void (*get_wpr)(struct gk20a *g, struct wpr_carveout_info *inf);
int (*alloc_blob_space)(struct gk20a *g,
size_t size, struct mem_desc *mem);
int (*pmu_populate_loader_cfg)(struct gk20a *g,
void *lsfm, u32 *p_bl_gen_desc_size);
int (*flcn_populate_bl_dmem_desc)(struct gk20a *g,
void *lsfm, u32 *p_bl_gen_desc_size, u32 falconid);
u32 lspmuwprinitdone;
u32 lsfloadedfalconid;
bool fecsbootstrapdone;
} pmu;
struct {
void (*disable_slowboot)(struct gk20a *g);
int (*init_clk_support)(struct gk20a *g);
int (*suspend_clk_support)(struct gk20a *g);
} clk;
bool privsecurity;
bool securegpccs;
struct {
const struct regop_offset_range* (
*get_global_whitelist_ranges)(void);
int (*get_global_whitelist_ranges_count)(void);
const struct regop_offset_range* (
*get_context_whitelist_ranges)(void);
int (*get_context_whitelist_ranges_count)(void);
const u32* (*get_runcontrol_whitelist)(void);
int (*get_runcontrol_whitelist_count)(void);
const struct regop_offset_range* (
*get_runcontrol_whitelist_ranges)(void);
int (*get_runcontrol_whitelist_ranges_count)(void);
const u32* (*get_qctl_whitelist)(void);
int (*get_qctl_whitelist_count)(void);
const struct regop_offset_range* (
*get_qctl_whitelist_ranges)(void);
int (*get_qctl_whitelist_ranges_count)(void);
int (*apply_smpc_war)(struct dbg_session_gk20a *dbg_s);
} regops;
struct {
void (*intr_enable)(struct gk20a *g);
void (*intr_unit_config)(struct gk20a *g,
bool enable, bool is_stalling, u32 unit);
irqreturn_t (*isr_stall)(struct gk20a *g);
irqreturn_t (*isr_nonstall)(struct gk20a *g);
irqreturn_t (*isr_thread_stall)(struct gk20a *g);
irqreturn_t (*isr_thread_nonstall)(struct gk20a *g);
u32 intr_mask_restore[4];
} mc;
struct {
void (*show_dump)(struct gk20a *g,
struct gk20a_debug_output *o);
} debug;
struct {
void (*get_program_numbers)(struct gk20a *g,
u32 block_height_log2,
int *hprog, int *vprog);
bool (*need_scatter_buffer)(struct gk20a *g);
int (*populate_scatter_buffer)(struct gk20a *g,
struct sg_table *sgt,
size_t surface_size,
void *scatter_buffer_ptr,
size_t scatter_buffer_size);
} cde;
int (*get_litter_value)(struct gk20a *g, enum nvgpu_litter_value value);
int (*chip_init_gpu_characteristics)(struct gk20a *g);
int (*read_ptimer)(struct gk20a *g, u64 *value);
struct {
int (*init)(struct gk20a *g);
} bios;
};
struct nvgpu_bios_ucode {
u8 *bootloader;
u32 bootloader_phys_base;
u32 bootloader_size;
u8 *ucode;
u32 phys_base;
u32 size;
u8 *dmem;
u32 dmem_phys_base;
u32 dmem_size;
u32 code_entry_point;
};
struct nvgpu_bios {
u8 *data;
struct nvgpu_bios_ucode devinit;
struct nvgpu_bios_ucode preos;
u8 *devinit_tables;
u32 devinit_tables_size;
u8 *bootscripts;
u32 bootscripts_size;
u32 devinit_tables_phys_base;
u32 devinit_script_phys_base;
u32 expansion_rom_offset;
};
struct gk20a {
struct device *dev;
struct platform_device *host1x_dev;
struct resource *reg_mem;
void __iomem *regs;
void __iomem *regs_saved;
struct resource *bar1_mem;
void __iomem *bar1;
void __iomem *bar1_saved;
bool power_on;
bool suspended;
struct rw_semaphore busy_lock;
struct clk_gk20a clk;
struct fifo_gk20a fifo;
struct gr_gk20a gr;
struct sim_gk20a sim;
struct mm_gk20a mm;
struct pmu_gk20a pmu;
struct acr_desc acr;
struct cooling_device_gk20a gk20a_cdev;
#ifdef CONFIG_DEBUG_FS
struct railgate_stats pstats;
#endif
/* Save pmu fw here so that it lives cross suspend/resume.
pmu suspend destroys all pmu sw/hw states. Loading pmu
fw in resume crashes when the resume is from sys_exit. */
const struct firmware *pmu_fw;
u32 gr_idle_timeout_default;
#if LINUX_VERSION_CODE < KERNEL_VERSION(4,4,0)
u32 timeouts_enabled;
#else
bool timeouts_enabled;
#endif
struct mutex ch_wdt_lock;
struct mutex poweroff_lock;
/* Channel priorities */
u32 timeslice_low_priority_us;
u32 timeslice_medium_priority_us;
u32 timeslice_high_priority_us;
#if LINUX_VERSION_CODE < KERNEL_VERSION(4,4,0)
u32 runlist_interleave;
#else
bool runlist_interleave;
#endif
bool slcg_enabled;
bool blcg_enabled;
bool elcg_enabled;
bool elpg_enabled;
bool aelpg_enabled;
bool forced_idle;
bool forced_reset;
bool allow_all;
u32 emc3d_ratio;
#ifdef CONFIG_DEBUG_FS
spinlock_t debugfs_lock;
struct dentry *debugfs_ltc_enabled;
struct dentry *debugfs_timeouts_enabled;
struct dentry *debugfs_gr_idle_timeout_default;
struct dentry *debugfs_bypass_smmu;
struct dentry *debugfs_disable_bigpage;
struct dentry *debugfs_gr_default_attrib_cb_size;
struct dentry *debugfs_timeslice_low_priority_us;
struct dentry *debugfs_timeslice_medium_priority_us;
struct dentry *debugfs_timeslice_high_priority_us;
struct dentry *debugfs_runlist_interleave;
#endif
struct gk20a_ctxsw_ucode_info ctxsw_ucode_info;
/*
* A group of semaphore pools. One for each channel.
*/
struct gk20a_semaphore_sea *sema_sea;
/* held while manipulating # of debug/profiler sessions present */
/* also prevents debug sessions from attaching until released */
struct mutex dbg_sessions_lock;
int dbg_powergating_disabled_refcount; /*refcount for pg disable */
int dbg_timeout_disabled_refcount; /*refcount for timeout disable */
/*
* When set subsequent VMAs will separate fixed and non-fixed
* allocations. This avoids conflicts with fixed and non-fixed allocs
* for some tests. The value in separate_fixed_allocs is used to
* determine the split boundary.
*/
u64 separate_fixed_allocs;
void (*remove_support)(struct device *);
u64 pg_ingating_time_us;
u64 pg_ungating_time_us;
u32 pg_gating_cnt;
spinlock_t mc_enable_lock;
struct nvgpu_gpu_characteristics gpu_characteristics;
struct {
struct cdev cdev;
struct device *node;
} channel;
struct gk20a_as as;
struct {
struct cdev cdev;
struct device *node;
} ctrl;
struct {
struct cdev cdev;
struct device *node;
} dbg;
struct {
struct cdev cdev;
struct device *node;
} prof;
struct {
struct cdev cdev;
struct device *node;
} tsg;
struct {
struct cdev cdev;
struct device *node;
} ctxsw;
struct {
struct cdev cdev;
struct device *node;
} sched;
struct mutex client_lock;
int client_refcount; /* open channels and ctrl nodes */
dev_t cdev_region;
struct gpu_ops ops;
int irq_stall; /* can be same as irq_nonstall in case of PCI */
int irq_nonstall;
u32 max_ltc_count;
u32 ltc_count;
atomic_t hw_irq_stall_count;
atomic_t hw_irq_nonstall_count;
atomic_t sw_irq_stall_last_handled;
wait_queue_head_t sw_irq_stall_last_handled_wq;
atomic_t sw_irq_nonstall_last_handled;
wait_queue_head_t sw_irq_nonstall_last_handled_wq;
struct devfreq *devfreq;
u32 devfreq_max_freq;
u32 devfreq_min_freq;
struct gk20a_scale_profile *scale_profile;
struct gk20a_ctxsw_trace *ctxsw_trace;
struct gk20a_fecs_trace *fecs_trace;
struct gk20a_sched_ctrl sched_ctrl;
struct device_dma_parameters dma_parms;
struct gk20a_cde_app cde_app;
bool mmu_debug_ctrl;
u32 tpc_fs_mask_user;
struct nvgpu_bios bios;
struct debugfs_blob_wrapper bios_blob;
};
static inline unsigned long gk20a_get_gr_idle_timeout(struct gk20a *g)
{
return g->timeouts_enabled ?
g->gr_idle_timeout_default : MAX_SCHEDULE_TIMEOUT;
}
static inline struct gk20a *get_gk20a(struct device *dev)
{
return gk20a_get_platform(dev)->g;
}
enum BAR0_DEBUG_OPERATION {
BARO_ZERO_NOP = 0,
OP_END = 'DONE',
BAR0_READ32 = '0R32',
BAR0_WRITE32 = '0W32',
};
struct share_buffer_head {
enum BAR0_DEBUG_OPERATION operation;
/* size of the operation item */
u32 size;
u32 completed;
u32 failed;
u64 context;
u64 completion_callback;
};
struct gk20a_cyclestate_buffer_elem {
struct share_buffer_head head;
/* in */
u64 p_data;
u64 p_done;
u32 offset_bar0;
u16 first_bit;
u16 last_bit;
/* out */
/* keep 64 bits to be consistent */
u64 data;
};
/* debug accessories */
#ifdef CONFIG_DEBUG_FS
/* debug info, default is compiled-in but effectively disabled (0 mask) */
#define GK20A_DEBUG
/*e.g: echo 1 > /d/gk20a.0/dbg_mask */
#define GK20A_DEFAULT_DBG_MASK 0
#else
/* manually enable and turn it on the mask */
/*#define NVGPU_DEBUG*/
#define GK20A_DEFAULT_DBG_MASK (dbg_info)
#endif
enum gk20a_dbg_categories {
gpu_dbg_info = BIT(0), /* lightly verbose info */
gpu_dbg_fn = BIT(2), /* fn name tracing */
gpu_dbg_reg = BIT(3), /* register accesses, very verbose */
gpu_dbg_pte = BIT(4), /* gmmu ptes */
gpu_dbg_intr = BIT(5), /* interrupts */
gpu_dbg_pmu = BIT(6), /* gk20a pmu */
gpu_dbg_clk = BIT(7), /* gk20a clk */
gpu_dbg_map = BIT(8), /* mem mappings */
gpu_dbg_gpu_dbg = BIT(9), /* gpu debugger/profiler */
gpu_dbg_cde = BIT(10), /* cde info messages */
gpu_dbg_cde_ctx = BIT(11), /* cde context usage messages */
gpu_dbg_ctxsw = BIT(12), /* ctxsw tracing */
gpu_dbg_sched = BIT(13), /* sched control tracing */
gpu_dbg_mem = BIT(31), /* memory accesses, very verbose */
};
#if defined(GK20A_DEBUG)
extern u32 gk20a_dbg_mask;
extern u32 gk20a_dbg_ftrace;
#define gk20a_dbg(dbg_mask, format, arg...) \
do { \
if (unlikely((dbg_mask) & gk20a_dbg_mask)) { \
if (gk20a_dbg_ftrace) \
trace_printk(format "\n", ##arg); \
else \
pr_info("gk20a %s: " format "\n", \
__func__, ##arg); \
} \
} while (0)
#else /* GK20A_DEBUG */
#define gk20a_dbg(dbg_mask, format, arg...) \
do { \
if (0) \
pr_info("gk20a %s: " format "\n", __func__, ##arg);\
} while (0)
#endif
#define gk20a_err(d, fmt, arg...) \
dev_err(d, "%s: " fmt "\n", __func__, ##arg)
#define gk20a_warn(d, fmt, arg...) \
dev_warn(d, "%s: " fmt "\n", __func__, ##arg)
#define gk20a_dbg_fn(fmt, arg...) \
gk20a_dbg(gpu_dbg_fn, fmt, ##arg)
#define gk20a_dbg_info(fmt, arg...) \
gk20a_dbg(gpu_dbg_info, fmt, ##arg)
void gk20a_init_clk_ops(struct gpu_ops *gops);
/* register accessors */
int gk20a_lockout_registers(struct gk20a *g);
int gk20a_restore_registers(struct gk20a *g);
static inline void gk20a_writel(struct gk20a *g, u32 r, u32 v)
{
gk20a_dbg(gpu_dbg_reg, " r=0x%x v=0x%x", r, v);
wmb();
writel_relaxed(v, g->regs + r);
}
static inline u32 gk20a_readl(struct gk20a *g, u32 r)
{
u32 v = readl(g->regs + r);
gk20a_dbg(gpu_dbg_reg, " r=0x%x v=0x%x", r, v);
return v;
}
static inline void gk20a_writel_check(struct gk20a *g, u32 r, u32 v)
{
gk20a_dbg(gpu_dbg_reg, " r=0x%x v=0x%x", r, v);
wmb();
do {
writel_relaxed(v, g->regs + r);
} while (readl(g->regs + r) != v);
}
static inline void gk20a_bar1_writel(struct gk20a *g, u32 b, u32 v)
{
gk20a_dbg(gpu_dbg_reg, " b=0x%x v=0x%x", b, v);
wmb();
writel_relaxed(v, g->bar1 + b);
}
static inline u32 gk20a_bar1_readl(struct gk20a *g, u32 b)
{
u32 v = readl(g->bar1 + b);
gk20a_dbg(gpu_dbg_reg, " b=0x%x v=0x%x", b, v);
return v;
}
/* convenience */
static inline struct device *dev_from_gk20a(struct gk20a *g)
{
return g->dev;
}
static inline struct gk20a *gk20a_from_dev(struct device *dev)
{
return ((struct gk20a_platform *)dev_get_drvdata(dev))->g;
}
static inline struct gk20a *gk20a_from_as(struct gk20a_as *as)
{
return container_of(as, struct gk20a, as);
}
static inline struct gk20a *gk20a_from_pmu(struct pmu_gk20a *pmu)
{
return container_of(pmu, struct gk20a, pmu);
}
static inline u32 u64_hi32(u64 n)
{
return (u32)((n >> 32) & ~(u32)0);
}
static inline u32 u64_lo32(u64 n)
{
return (u32)(n & ~(u32)0);
}
static inline u32 set_field(u32 val, u32 mask, u32 field)
{
return ((val & ~mask) | field);
}
/* invalidate channel lookup tlb */
static inline void gk20a_gr_flush_channel_tlb(struct gr_gk20a *gr)
{
spin_lock(&gr->ch_tlb_lock);
memset(gr->chid_tlb, 0,
sizeof(struct gr_channel_map_tlb_entry) *
GR_CHANNEL_MAP_TLB_SIZE);
spin_unlock(&gr->ch_tlb_lock);
}
/* classes that the device supports */
/* TBD: get these from an open-sourced SDK? */
enum {
KEPLER_C = 0xA297,
FERMI_TWOD_A = 0x902D,
KEPLER_COMPUTE_A = 0xA0C0,
KEPLER_INLINE_TO_MEMORY_A = 0xA040,
KEPLER_DMA_COPY_A = 0xA0B5,
KEPLER_CHANNEL_GPFIFO_C = 0xA26F,
};
static inline bool gk20a_gpu_is_virtual(struct device *dev)
{
struct gk20a_platform *platform = dev_get_drvdata(dev);
return platform->virtual_dev;
}
static inline int support_gk20a_pmu(struct device *dev)
{
if (IS_ENABLED(CONFIG_GK20A_PMU)) {
/* gPMU is not supported for vgpu */
return !gk20a_gpu_is_virtual(dev);
}
return 0;
}
void gk20a_create_sysfs(struct device *dev);
void gk20a_remove_sysfs(struct device *dev);
#define GK20A_BAR0_IORESOURCE_MEM 0
#define GK20A_BAR1_IORESOURCE_MEM 1
#define GK20A_SIM_IORESOURCE_MEM 2
void gk20a_busy_noresume(struct device *dev);
int __must_check gk20a_busy(struct device *dev);
void gk20a_idle(struct device *dev);
void gk20a_disable(struct gk20a *g, u32 units);
void gk20a_enable(struct gk20a *g, u32 units);
void gk20a_reset(struct gk20a *g, u32 units);
int gk20a_do_idle(void);
int gk20a_do_unidle(void);
int __gk20a_do_idle(struct device *dev, bool force_reset);
int __gk20a_do_unidle(struct device *dev);
const struct firmware *
gk20a_request_firmware(struct gk20a *g, const char *fw_name);
#define NVGPU_GPU_ARCHITECTURE_SHIFT 4
/* constructs unique and compact GPUID from nvgpu_gpu_characteristics
* arch/impl fields */
#define GK20A_GPUID(arch, impl) ((u32) ((arch) | (impl)))
#define GK20A_GPUID_GK20A \
GK20A_GPUID(NVGPU_GPU_ARCH_GK100, NVGPU_GPU_IMPL_GK20A)
#define GK20A_GPUID_GM20B \
GK20A_GPUID(NVGPU_GPU_ARCH_GM200, NVGPU_GPU_IMPL_GM20B)
#define GK20A_GPUID_GM204 \
GK20A_GPUID(NVGPU_GPU_ARCH_GM200, NVGPU_GPU_IMPL_GM204)
#define GK20A_GPUID_GM206 \
GK20A_GPUID(NVGPU_GPU_ARCH_GM200, NVGPU_GPU_IMPL_GM206)
int gk20a_init_gpu_characteristics(struct gk20a *g);
void gk20a_pbus_isr(struct gk20a *g);
int gk20a_user_init(struct device *dev, const char *interface_name,
struct class *class);
void gk20a_user_deinit(struct device *dev, struct class *class);
static inline u32 ptimer_scalingfactor10x(u32 ptimer_src_freq)
{
return (u32)(((u64)(PTIMER_REF_FREQ_HZ * 10)) / ptimer_src_freq);
}
static inline u32 scale_ptimer(u32 timeout , u32 scale10x)
{
if (((timeout*10) % scale10x) >= (scale10x/2))
return ((timeout * 10) / scale10x) + 1;
else
return (timeout * 10) / scale10x;
}
int gk20a_read_ptimer(struct gk20a *g, u64 *value);
extern struct class nvgpu_class;
#define INTERFACE_NAME "nvhost%s-gpu"
int gk20a_pm_init(struct device *dev);
int gk20a_pm_finalize_poweron(struct device *dev);
void gk20a_remove_support(struct device *dev);
static inline struct tsg_gk20a *tsg_gk20a_from_ch(struct channel_gk20a *ch)
{
struct tsg_gk20a *tsg = NULL;
if (gk20a_is_channel_marked_as_tsg(ch))
{
struct gk20a *g = ch->g;
struct fifo_gk20a *f = &g->fifo;
tsg = &f->tsg[ch->tsgid];
}
return tsg;
}
static inline void gk20a_channel_trace_sched_param(
void (*trace)(int chid, int tsgid, pid_t pid, u32 timeslice,
u32 timeout, const char *interleave,
const char *graphics_preempt_mode,
const char *compute_preempt_mode),
struct channel_gk20a *ch)
{
(trace)(ch->hw_chid, ch->tsgid, ch->pid,
gk20a_is_channel_marked_as_tsg(ch) ?
tsg_gk20a_from_ch(ch)->timeslice_us : ch->timeslice_us,
ch->timeout_ms_max,
gk20a_fifo_interleave_level_name(ch->interleave_level),
gr_gk20a_graphics_preempt_mode_name(ch->ch_ctx.gr_ctx ?
ch->ch_ctx.gr_ctx->graphics_preempt_mode : 0),
gr_gk20a_compute_preempt_mode_name(ch->ch_ctx.gr_ctx ?
ch->ch_ctx.gr_ctx->compute_preempt_mode : 0));
}
#endif /* GK20A_H */