Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Ben Goz | 1239 | 43.31% | 1 | 4.35% |
Felix Kuhling | 1020 | 35.65% | 6 | 26.09% |
Philip Cox | 279 | 9.75% | 1 | 4.35% |
Yong Zhao | 171 | 5.98% | 5 | 21.74% |
Moses Reuben | 54 | 1.89% | 1 | 4.35% |
Andres Rodriguez | 44 | 1.54% | 3 | 13.04% |
Oak Zeng | 26 | 0.91% | 1 | 4.35% |
Shaoyun Liu | 14 | 0.49% | 2 | 8.70% |
Edward O'Callaghan | 8 | 0.28% | 1 | 4.35% |
Kees Cook | 4 | 0.14% | 1 | 4.35% |
Harish Kasiviswanathan | 2 | 0.07% | 1 | 4.35% |
Total | 2861 | 23 |
/* * Copyright 2014 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. */ #include <linux/mmu_context.h> #include "amdgpu.h" #include "amdgpu_amdkfd.h" #include "gfx_v8_0.h" #include "gca/gfx_8_0_sh_mask.h" #include "gca/gfx_8_0_d.h" #include "gca/gfx_8_0_enum.h" #include "oss/oss_3_0_sh_mask.h" #include "oss/oss_3_0_d.h" #include "gmc/gmc_8_1_sh_mask.h" #include "gmc/gmc_8_1_d.h" #include "vi_structs.h" #include "vid.h" enum hqd_dequeue_request_type { NO_ACTION = 0, DRAIN_PIPE, RESET_WAVES }; static inline struct amdgpu_device *get_amdgpu_device(struct kgd_dev *kgd) { return (struct amdgpu_device *)kgd; } static void lock_srbm(struct kgd_dev *kgd, uint32_t mec, uint32_t pipe, uint32_t queue, uint32_t vmid) { struct amdgpu_device *adev = get_amdgpu_device(kgd); uint32_t value = PIPEID(pipe) | MEID(mec) | VMID(vmid) | QUEUEID(queue); mutex_lock(&adev->srbm_mutex); WREG32(mmSRBM_GFX_CNTL, value); } static void unlock_srbm(struct kgd_dev *kgd) { struct amdgpu_device *adev = get_amdgpu_device(kgd); WREG32(mmSRBM_GFX_CNTL, 0); mutex_unlock(&adev->srbm_mutex); } static void acquire_queue(struct kgd_dev *kgd, uint32_t pipe_id, uint32_t queue_id) { struct amdgpu_device *adev = get_amdgpu_device(kgd); uint32_t mec = (pipe_id / adev->gfx.mec.num_pipe_per_mec) + 1; uint32_t pipe = (pipe_id % adev->gfx.mec.num_pipe_per_mec); lock_srbm(kgd, mec, pipe, queue_id, 0); } static void release_queue(struct kgd_dev *kgd) { unlock_srbm(kgd); } static void kgd_program_sh_mem_settings(struct kgd_dev *kgd, uint32_t vmid, uint32_t sh_mem_config, uint32_t sh_mem_ape1_base, uint32_t sh_mem_ape1_limit, uint32_t sh_mem_bases) { struct amdgpu_device *adev = get_amdgpu_device(kgd); lock_srbm(kgd, 0, 0, 0, vmid); WREG32(mmSH_MEM_CONFIG, sh_mem_config); WREG32(mmSH_MEM_APE1_BASE, sh_mem_ape1_base); WREG32(mmSH_MEM_APE1_LIMIT, sh_mem_ape1_limit); WREG32(mmSH_MEM_BASES, sh_mem_bases); unlock_srbm(kgd); } static int kgd_set_pasid_vmid_mapping(struct kgd_dev *kgd, unsigned int pasid, unsigned int vmid) { struct amdgpu_device *adev = get_amdgpu_device(kgd); /* * We have to assume that there is no outstanding mapping. * The ATC_VMID_PASID_MAPPING_UPDATE_STATUS bit could be 0 because * a mapping is in progress or because a mapping finished * and the SW cleared it. * So the protocol is to always wait & clear. */ uint32_t pasid_mapping = (pasid == 0) ? 0 : (uint32_t)pasid | ATC_VMID0_PASID_MAPPING__VALID_MASK; WREG32(mmATC_VMID0_PASID_MAPPING + vmid, pasid_mapping); while (!(RREG32(mmATC_VMID_PASID_MAPPING_UPDATE_STATUS) & (1U << vmid))) cpu_relax(); WREG32(mmATC_VMID_PASID_MAPPING_UPDATE_STATUS, 1U << vmid); /* Mapping vmid to pasid also for IH block */ WREG32(mmIH_VMID_0_LUT + vmid, pasid_mapping); return 0; } static int kgd_init_interrupts(struct kgd_dev *kgd, uint32_t pipe_id) { struct amdgpu_device *adev = get_amdgpu_device(kgd); uint32_t mec; uint32_t pipe; mec = (pipe_id / adev->gfx.mec.num_pipe_per_mec) + 1; pipe = (pipe_id % adev->gfx.mec.num_pipe_per_mec); lock_srbm(kgd, mec, pipe, 0, 0); WREG32(mmCPC_INT_CNTL, CP_INT_CNTL_RING0__TIME_STAMP_INT_ENABLE_MASK | CP_INT_CNTL_RING0__OPCODE_ERROR_INT_ENABLE_MASK); unlock_srbm(kgd); return 0; } static inline uint32_t get_sdma_rlc_reg_offset(struct vi_sdma_mqd *m) { uint32_t retval; retval = m->sdma_engine_id * SDMA1_REGISTER_OFFSET + m->sdma_queue_id * KFD_VI_SDMA_QUEUE_OFFSET; pr_debug("RLC register offset for SDMA%d RLC%d: 0x%x\n", m->sdma_engine_id, m->sdma_queue_id, retval); return retval; } static inline struct vi_mqd *get_mqd(void *mqd) { return (struct vi_mqd *)mqd; } static inline struct vi_sdma_mqd *get_sdma_mqd(void *mqd) { return (struct vi_sdma_mqd *)mqd; } static int kgd_hqd_load(struct kgd_dev *kgd, void *mqd, uint32_t pipe_id, uint32_t queue_id, uint32_t __user *wptr, uint32_t wptr_shift, uint32_t wptr_mask, struct mm_struct *mm) { struct amdgpu_device *adev = get_amdgpu_device(kgd); struct vi_mqd *m; uint32_t *mqd_hqd; uint32_t reg, wptr_val, data; bool valid_wptr = false; m = get_mqd(mqd); acquire_queue(kgd, pipe_id, queue_id); /* HIQ is set during driver init period with vmid set to 0*/ if (m->cp_hqd_vmid == 0) { uint32_t value, mec, pipe; mec = (pipe_id / adev->gfx.mec.num_pipe_per_mec) + 1; pipe = (pipe_id % adev->gfx.mec.num_pipe_per_mec); pr_debug("kfd: set HIQ, mec:%d, pipe:%d, queue:%d.\n", mec, pipe, queue_id); value = RREG32(mmRLC_CP_SCHEDULERS); value = REG_SET_FIELD(value, RLC_CP_SCHEDULERS, scheduler1, ((mec << 5) | (pipe << 3) | queue_id | 0x80)); WREG32(mmRLC_CP_SCHEDULERS, value); } /* HQD registers extend from CP_MQD_BASE_ADDR to CP_HQD_EOP_WPTR_MEM. */ mqd_hqd = &m->cp_mqd_base_addr_lo; for (reg = mmCP_MQD_BASE_ADDR; reg <= mmCP_HQD_EOP_CONTROL; reg++) WREG32(reg, mqd_hqd[reg - mmCP_MQD_BASE_ADDR]); /* Tonga errata: EOP RPTR/WPTR should be left unmodified. * This is safe since EOP RPTR==WPTR for any inactive HQD * on ASICs that do not support context-save. * EOP writes/reads can start anywhere in the ring. */ if (get_amdgpu_device(kgd)->asic_type != CHIP_TONGA) { WREG32(mmCP_HQD_EOP_RPTR, m->cp_hqd_eop_rptr); WREG32(mmCP_HQD_EOP_WPTR, m->cp_hqd_eop_wptr); WREG32(mmCP_HQD_EOP_WPTR_MEM, m->cp_hqd_eop_wptr_mem); } for (reg = mmCP_HQD_EOP_EVENTS; reg <= mmCP_HQD_ERROR; reg++) WREG32(reg, mqd_hqd[reg - mmCP_MQD_BASE_ADDR]); /* Copy userspace write pointer value to register. * Activate doorbell logic to monitor subsequent changes. */ data = REG_SET_FIELD(m->cp_hqd_pq_doorbell_control, CP_HQD_PQ_DOORBELL_CONTROL, DOORBELL_EN, 1); WREG32(mmCP_HQD_PQ_DOORBELL_CONTROL, data); /* read_user_ptr may take the mm->mmap_sem. * release srbm_mutex to avoid circular dependency between * srbm_mutex->mm_sem->reservation_ww_class_mutex->srbm_mutex. */ release_queue(kgd); valid_wptr = read_user_wptr(mm, wptr, wptr_val); acquire_queue(kgd, pipe_id, queue_id); if (valid_wptr) WREG32(mmCP_HQD_PQ_WPTR, (wptr_val << wptr_shift) & wptr_mask); data = REG_SET_FIELD(m->cp_hqd_active, CP_HQD_ACTIVE, ACTIVE, 1); WREG32(mmCP_HQD_ACTIVE, data); release_queue(kgd); return 0; } static int kgd_hqd_dump(struct kgd_dev *kgd, uint32_t pipe_id, uint32_t queue_id, uint32_t (**dump)[2], uint32_t *n_regs) { struct amdgpu_device *adev = get_amdgpu_device(kgd); uint32_t i = 0, reg; #define HQD_N_REGS (54+4) #define DUMP_REG(addr) do { \ if (WARN_ON_ONCE(i >= HQD_N_REGS)) \ break; \ (*dump)[i][0] = (addr) << 2; \ (*dump)[i++][1] = RREG32(addr); \ } while (0) *dump = kmalloc_array(HQD_N_REGS * 2, sizeof(uint32_t), GFP_KERNEL); if (*dump == NULL) return -ENOMEM; acquire_queue(kgd, pipe_id, queue_id); DUMP_REG(mmCOMPUTE_STATIC_THREAD_MGMT_SE0); DUMP_REG(mmCOMPUTE_STATIC_THREAD_MGMT_SE1); DUMP_REG(mmCOMPUTE_STATIC_THREAD_MGMT_SE2); DUMP_REG(mmCOMPUTE_STATIC_THREAD_MGMT_SE3); for (reg = mmCP_MQD_BASE_ADDR; reg <= mmCP_HQD_EOP_DONES; reg++) DUMP_REG(reg); release_queue(kgd); WARN_ON_ONCE(i != HQD_N_REGS); *n_regs = i; return 0; } static int kgd_hqd_sdma_load(struct kgd_dev *kgd, void *mqd, uint32_t __user *wptr, struct mm_struct *mm) { struct amdgpu_device *adev = get_amdgpu_device(kgd); struct vi_sdma_mqd *m; unsigned long end_jiffies; uint32_t sdma_rlc_reg_offset; uint32_t data; m = get_sdma_mqd(mqd); sdma_rlc_reg_offset = get_sdma_rlc_reg_offset(m); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_CNTL, m->sdmax_rlcx_rb_cntl & (~SDMA0_RLC0_RB_CNTL__RB_ENABLE_MASK)); end_jiffies = msecs_to_jiffies(2000) + jiffies; while (true) { data = RREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_CONTEXT_STATUS); if (data & SDMA0_RLC0_CONTEXT_STATUS__IDLE_MASK) break; if (time_after(jiffies, end_jiffies)) { pr_err("SDMA RLC not idle in %s\n", __func__); return -ETIME; } usleep_range(500, 1000); } data = REG_SET_FIELD(m->sdmax_rlcx_doorbell, SDMA0_RLC0_DOORBELL, ENABLE, 1); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_DOORBELL, data); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_RPTR, m->sdmax_rlcx_rb_rptr); if (read_user_wptr(mm, wptr, data)) WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_WPTR, data); else WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_WPTR, m->sdmax_rlcx_rb_rptr); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_VIRTUAL_ADDR, m->sdmax_rlcx_virtual_addr); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_BASE, m->sdmax_rlcx_rb_base); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_BASE_HI, m->sdmax_rlcx_rb_base_hi); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_RPTR_ADDR_LO, m->sdmax_rlcx_rb_rptr_addr_lo); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_RPTR_ADDR_HI, m->sdmax_rlcx_rb_rptr_addr_hi); data = REG_SET_FIELD(m->sdmax_rlcx_rb_cntl, SDMA0_RLC0_RB_CNTL, RB_ENABLE, 1); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_CNTL, data); return 0; } static int kgd_hqd_sdma_dump(struct kgd_dev *kgd, uint32_t engine_id, uint32_t queue_id, uint32_t (**dump)[2], uint32_t *n_regs) { struct amdgpu_device *adev = get_amdgpu_device(kgd); uint32_t sdma_offset = engine_id * SDMA1_REGISTER_OFFSET + queue_id * KFD_VI_SDMA_QUEUE_OFFSET; uint32_t i = 0, reg; #undef HQD_N_REGS #define HQD_N_REGS (19+4+2+3+7) *dump = kmalloc_array(HQD_N_REGS * 2, sizeof(uint32_t), GFP_KERNEL); if (*dump == NULL) return -ENOMEM; for (reg = mmSDMA0_RLC0_RB_CNTL; reg <= mmSDMA0_RLC0_DOORBELL; reg++) DUMP_REG(sdma_offset + reg); for (reg = mmSDMA0_RLC0_VIRTUAL_ADDR; reg <= mmSDMA0_RLC0_WATERMARK; reg++) DUMP_REG(sdma_offset + reg); for (reg = mmSDMA0_RLC0_CSA_ADDR_LO; reg <= mmSDMA0_RLC0_CSA_ADDR_HI; reg++) DUMP_REG(sdma_offset + reg); for (reg = mmSDMA0_RLC0_IB_SUB_REMAIN; reg <= mmSDMA0_RLC0_DUMMY_REG; reg++) DUMP_REG(sdma_offset + reg); for (reg = mmSDMA0_RLC0_MIDCMD_DATA0; reg <= mmSDMA0_RLC0_MIDCMD_CNTL; reg++) DUMP_REG(sdma_offset + reg); WARN_ON_ONCE(i != HQD_N_REGS); *n_regs = i; return 0; } static bool kgd_hqd_is_occupied(struct kgd_dev *kgd, uint64_t queue_address, uint32_t pipe_id, uint32_t queue_id) { struct amdgpu_device *adev = get_amdgpu_device(kgd); uint32_t act; bool retval = false; uint32_t low, high; acquire_queue(kgd, pipe_id, queue_id); act = RREG32(mmCP_HQD_ACTIVE); if (act) { low = lower_32_bits(queue_address >> 8); high = upper_32_bits(queue_address >> 8); if (low == RREG32(mmCP_HQD_PQ_BASE) && high == RREG32(mmCP_HQD_PQ_BASE_HI)) retval = true; } release_queue(kgd); return retval; } static bool kgd_hqd_sdma_is_occupied(struct kgd_dev *kgd, void *mqd) { struct amdgpu_device *adev = get_amdgpu_device(kgd); struct vi_sdma_mqd *m; uint32_t sdma_rlc_reg_offset; uint32_t sdma_rlc_rb_cntl; m = get_sdma_mqd(mqd); sdma_rlc_reg_offset = get_sdma_rlc_reg_offset(m); sdma_rlc_rb_cntl = RREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_CNTL); if (sdma_rlc_rb_cntl & SDMA0_RLC0_RB_CNTL__RB_ENABLE_MASK) return true; return false; } static int kgd_hqd_destroy(struct kgd_dev *kgd, void *mqd, enum kfd_preempt_type reset_type, unsigned int utimeout, uint32_t pipe_id, uint32_t queue_id) { struct amdgpu_device *adev = get_amdgpu_device(kgd); uint32_t temp; enum hqd_dequeue_request_type type; unsigned long flags, end_jiffies; int retry; struct vi_mqd *m = get_mqd(mqd); if (adev->in_gpu_reset) return -EIO; acquire_queue(kgd, pipe_id, queue_id); if (m->cp_hqd_vmid == 0) WREG32_FIELD(RLC_CP_SCHEDULERS, scheduler1, 0); switch (reset_type) { case KFD_PREEMPT_TYPE_WAVEFRONT_DRAIN: type = DRAIN_PIPE; break; case KFD_PREEMPT_TYPE_WAVEFRONT_RESET: type = RESET_WAVES; break; default: type = DRAIN_PIPE; break; } /* Workaround: If IQ timer is active and the wait time is close to or * equal to 0, dequeueing is not safe. Wait until either the wait time * is larger or timer is cleared. Also, ensure that IQ_REQ_PEND is * cleared before continuing. Also, ensure wait times are set to at * least 0x3. */ local_irq_save(flags); preempt_disable(); retry = 5000; /* wait for 500 usecs at maximum */ while (true) { temp = RREG32(mmCP_HQD_IQ_TIMER); if (REG_GET_FIELD(temp, CP_HQD_IQ_TIMER, PROCESSING_IQ)) { pr_debug("HW is processing IQ\n"); goto loop; } if (REG_GET_FIELD(temp, CP_HQD_IQ_TIMER, ACTIVE)) { if (REG_GET_FIELD(temp, CP_HQD_IQ_TIMER, RETRY_TYPE) == 3) /* SEM-rearm is safe */ break; /* Wait time 3 is safe for CP, but our MMIO read/write * time is close to 1 microsecond, so check for 10 to * leave more buffer room */ if (REG_GET_FIELD(temp, CP_HQD_IQ_TIMER, WAIT_TIME) >= 10) break; pr_debug("IQ timer is active\n"); } else break; loop: if (!retry) { pr_err("CP HQD IQ timer status time out\n"); break; } ndelay(100); --retry; } retry = 1000; while (true) { temp = RREG32(mmCP_HQD_DEQUEUE_REQUEST); if (!(temp & CP_HQD_DEQUEUE_REQUEST__IQ_REQ_PEND_MASK)) break; pr_debug("Dequeue request is pending\n"); if (!retry) { pr_err("CP HQD dequeue request time out\n"); break; } ndelay(100); --retry; } local_irq_restore(flags); preempt_enable(); WREG32(mmCP_HQD_DEQUEUE_REQUEST, type); end_jiffies = (utimeout * HZ / 1000) + jiffies; while (true) { temp = RREG32(mmCP_HQD_ACTIVE); if (!(temp & CP_HQD_ACTIVE__ACTIVE_MASK)) break; if (time_after(jiffies, end_jiffies)) { pr_err("cp queue preemption time out.\n"); release_queue(kgd); return -ETIME; } usleep_range(500, 1000); } release_queue(kgd); return 0; } static int kgd_hqd_sdma_destroy(struct kgd_dev *kgd, void *mqd, unsigned int utimeout) { struct amdgpu_device *adev = get_amdgpu_device(kgd); struct vi_sdma_mqd *m; uint32_t sdma_rlc_reg_offset; uint32_t temp; unsigned long end_jiffies = (utimeout * HZ / 1000) + jiffies; m = get_sdma_mqd(mqd); sdma_rlc_reg_offset = get_sdma_rlc_reg_offset(m); temp = RREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_CNTL); temp = temp & ~SDMA0_RLC0_RB_CNTL__RB_ENABLE_MASK; WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_CNTL, temp); while (true) { temp = RREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_CONTEXT_STATUS); if (temp & SDMA0_RLC0_CONTEXT_STATUS__IDLE_MASK) break; if (time_after(jiffies, end_jiffies)) { pr_err("SDMA RLC not idle in %s\n", __func__); return -ETIME; } usleep_range(500, 1000); } WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_DOORBELL, 0); WREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_CNTL, RREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_CNTL) | SDMA0_RLC0_RB_CNTL__RB_ENABLE_MASK); m->sdmax_rlcx_rb_rptr = RREG32(sdma_rlc_reg_offset + mmSDMA0_RLC0_RB_RPTR); return 0; } static bool get_atc_vmid_pasid_mapping_info(struct kgd_dev *kgd, uint8_t vmid, uint16_t *p_pasid) { uint32_t value; struct amdgpu_device *adev = (struct amdgpu_device *) kgd; value = RREG32(mmATC_VMID0_PASID_MAPPING + vmid); *p_pasid = value & ATC_VMID0_PASID_MAPPING__PASID_MASK; return !!(value & ATC_VMID0_PASID_MAPPING__VALID_MASK); } static int kgd_address_watch_disable(struct kgd_dev *kgd) { return 0; } static int kgd_address_watch_execute(struct kgd_dev *kgd, unsigned int watch_point_id, uint32_t cntl_val, uint32_t addr_hi, uint32_t addr_lo) { return 0; } static int kgd_wave_control_execute(struct kgd_dev *kgd, uint32_t gfx_index_val, uint32_t sq_cmd) { struct amdgpu_device *adev = get_amdgpu_device(kgd); uint32_t data = 0; mutex_lock(&adev->grbm_idx_mutex); WREG32(mmGRBM_GFX_INDEX, gfx_index_val); WREG32(mmSQ_CMD, sq_cmd); data = REG_SET_FIELD(data, GRBM_GFX_INDEX, INSTANCE_BROADCAST_WRITES, 1); data = REG_SET_FIELD(data, GRBM_GFX_INDEX, SH_BROADCAST_WRITES, 1); data = REG_SET_FIELD(data, GRBM_GFX_INDEX, SE_BROADCAST_WRITES, 1); WREG32(mmGRBM_GFX_INDEX, data); mutex_unlock(&adev->grbm_idx_mutex); return 0; } static uint32_t kgd_address_watch_get_offset(struct kgd_dev *kgd, unsigned int watch_point_id, unsigned int reg_offset) { return 0; } static void set_scratch_backing_va(struct kgd_dev *kgd, uint64_t va, uint32_t vmid) { struct amdgpu_device *adev = (struct amdgpu_device *) kgd; lock_srbm(kgd, 0, 0, 0, vmid); WREG32(mmSH_HIDDEN_PRIVATE_BASE_VMID, va); unlock_srbm(kgd); } static void set_vm_context_page_table_base(struct kgd_dev *kgd, uint32_t vmid, uint64_t page_table_base) { struct amdgpu_device *adev = get_amdgpu_device(kgd); if (!amdgpu_amdkfd_is_kfd_vmid(adev, vmid)) { pr_err("trying to set page table base for wrong VMID\n"); return; } WREG32(mmVM_CONTEXT8_PAGE_TABLE_BASE_ADDR + vmid - 8, lower_32_bits(page_table_base)); } const struct kfd2kgd_calls gfx_v8_kfd2kgd = { .program_sh_mem_settings = kgd_program_sh_mem_settings, .set_pasid_vmid_mapping = kgd_set_pasid_vmid_mapping, .init_interrupts = kgd_init_interrupts, .hqd_load = kgd_hqd_load, .hqd_sdma_load = kgd_hqd_sdma_load, .hqd_dump = kgd_hqd_dump, .hqd_sdma_dump = kgd_hqd_sdma_dump, .hqd_is_occupied = kgd_hqd_is_occupied, .hqd_sdma_is_occupied = kgd_hqd_sdma_is_occupied, .hqd_destroy = kgd_hqd_destroy, .hqd_sdma_destroy = kgd_hqd_sdma_destroy, .address_watch_disable = kgd_address_watch_disable, .address_watch_execute = kgd_address_watch_execute, .wave_control_execute = kgd_wave_control_execute, .address_watch_get_offset = kgd_address_watch_get_offset, .get_atc_vmid_pasid_mapping_info = get_atc_vmid_pasid_mapping_info, .set_scratch_backing_va = set_scratch_backing_va, .set_vm_context_page_table_base = set_vm_context_page_table_base, };
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