from __future__ import annotations from typing import Any, cast, ClassVar import os, ctypes, ctypes.util, struct, hashlib, functools, importlib, mmap, errno, array, contextlib, sys, select assert sys.platform != 'win32' from dataclasses import dataclass from tinygrad.runtime.support.hcq import HCQCompiled, HCQAllocator, HCQBuffer, HWQueue, CLikeArgsState, HCQSignal, HCQProgram, FileIOInterface from tinygrad.runtime.support.hcq import MMIOInterface from tinygrad.ops import sint from tinygrad.device import Compiled, ProfileEvent, BufferSpec, CPUProgram, PROFILE from tinygrad.helpers import getenv, to_mv, round_up, data64_le, all_same, flatten, DEBUG, OSX from tinygrad.renderer.cstyle import AMDRenderer from tinygrad.renderer.llvmir import AMDLLVMRenderer from tinygrad.runtime.autogen import kfd, hsa, libc, pci, vfio, sqtt from tinygrad.runtime.autogen.am import am from tinygrad.runtime.support.compiler_amd import HIPCompiler, AMDLLVMCompiler from tinygrad.runtime.support.elf import elf_loader from tinygrad.runtime.support.am.amdev import AMDev, AMMapping from tinygrad.runtime.support.amd import AMDRegBase, collect_registers, import_module, setup_pci_bars from tinygrad.runtime.support.usb import ASM24Controller, USBMMIOInterface if getenv("IOCTL"): import extra.hip_gpu_driver.hip_ioctl # noqa: F401 # pylint: disable=unused-import EVENT_INDEX_PARTIAL_FLUSH = 4 # based on a comment in nvd.h WAIT_REG_MEM_FUNCTION_EQ = 3 # == WAIT_REG_MEM_FUNCTION_NEQ = 4 # != WAIT_REG_MEM_FUNCTION_GEQ = 5 # >= class AMDSignal(HCQSignal): def __init__(self, base_buf:HCQBuffer|None=None, **kwargs): super().__init__(base_buf, **kwargs, timestamp_divider=100, dev_t=AMDDevice) def _sleep(self, time_spent_waiting_ms:int): # Resonable to sleep for long workloads (which take more than 2s) and only timeline signals. if time_spent_waiting_ms > 2000 and self.timeline_for_device is not None: self.timeline_for_device.dev_iface.sleep(200) class AMDComputeQueue(HWQueue): def __init__(self, dev:AMDDevice): self.dev, self.soc, self.pm4, self.gc, self.nbio = dev, dev.soc, dev.pm4, dev.gc, dev.nbio super().__init__() def __del__(self): if self.binded_device is not None: self.binded_device.allocator.free(self.hw_page, self.hw_page.size, BufferSpec(cpu_access=True, nolru=True, uncached=True)) def pkt3(self, cmd, *vals): self.q(self.pm4.PACKET3(cmd, len(vals) - 1), *vals) def wreg(self, reg:AMDReg, *args:sint, **kwargs:int): if bool(args) == bool(kwargs): raise RuntimeError('One (and only one) of *args or **kwargs must be specified') if self.pm4.PACKET3_SET_SH_REG_START <= reg.addr < self.pm4.PACKET3_SET_SH_REG_END: set_packet, set_packet_start = self.pm4.PACKET3_SET_SH_REG, self.pm4.PACKET3_SET_SH_REG_START elif self.pm4.PACKET3_SET_UCONFIG_REG_START <= reg.addr < self.pm4.PACKET3_SET_UCONFIG_REG_START + 2**16-1: set_packet, set_packet_start = self.pm4.PACKET3_SET_UCONFIG_REG, self.pm4.PACKET3_SET_UCONFIG_REG_START else: raise RuntimeError(f'Cannot set {reg.name} ({reg.addr}) via pm4 packet') self.pkt3(set_packet, reg.addr - set_packet_start, *(args or (reg.encode(**kwargs),))) @contextlib.contextmanager def pred_exec(self, xcc_mask:int): if self.dev.xccs > 1: self.pkt3(self.pm4.PACKET3_PRED_EXEC, xcc_mask << 24) prev_len = len(self._q) yield if self.dev.xccs > 1: self._q[prev_len-1] |= (len(self._q) - prev_len) def wait_reg_mem(self, value, mask=0xffffffff, mem=None, reg_req=None, reg_done=None): wrm_info_dw = self.pm4.WAIT_REG_MEM_MEM_SPACE(int(mem is not None)) | self.pm4.WAIT_REG_MEM_OPERATION(int(mem is None)) \ | self.pm4.WAIT_REG_MEM_FUNCTION(WAIT_REG_MEM_FUNCTION_GEQ) | self.pm4.WAIT_REG_MEM_ENGINE(0) self.pkt3(self.pm4.PACKET3_WAIT_REG_MEM, wrm_info_dw, *(data64_le(mem) if mem is not None else (reg_req, reg_done)), value, mask, 4) def acquire_mem(self, addr=0x0, sz=(1 << 64)-1, gli=1, glm=1, glk=1, glv=1, gl1=1, gl2=1): if self.dev.target >= (10,0,0): cache_flags_dw = self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GLI_INV(gli) \ | self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GLM_INV(glm) | self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GLM_WB(glm) \ | self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GLK_INV(glk) | self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GLK_WB(glk) \ | self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GLV_INV(glv) | self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GL1_INV(gl1) \ | self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GL2_INV(gl2) | self.pm4.PACKET3_ACQUIRE_MEM_GCR_CNTL_GL2_WB(gl2) self.pkt3(self.pm4.PACKET3_ACQUIRE_MEM, 0, *data64_le(sz), *data64_le(addr), 0, cache_flags_dw) else: cp_coher_cntl = self.pm4.PACKET3_ACQUIRE_MEM_CP_COHER_CNTL_SH_ICACHE_ACTION_ENA(gli) | \ self.pm4.PACKET3_ACQUIRE_MEM_CP_COHER_CNTL_SH_KCACHE_ACTION_ENA(glk) | \ self.pm4.PACKET3_ACQUIRE_MEM_CP_COHER_CNTL_TC_ACTION_ENA(gl2) | \ self.pm4.PACKET3_ACQUIRE_MEM_CP_COHER_CNTL_TCL1_ACTION_ENA(gl1) | \ self.pm4.PACKET3_ACQUIRE_MEM_CP_COHER_CNTL_TC_WB_ACTION_ENA(gl2) self.pkt3(self.pm4.PACKET3_ACQUIRE_MEM, cp_coher_cntl, *data64_le(sz), *data64_le(addr), 0x0000000A) def release_mem(self, address=0x0, value=0, data_sel=0, int_sel=2, ctxid=0, cache_flush=False): if self.dev.target >= (10,0,0): cache_flags_dw = 0 if not cache_flush else (self.pm4.PACKET3_RELEASE_MEM_GCR_GLV_INV | self.pm4.PACKET3_RELEASE_MEM_GCR_GL1_INV \ | self.pm4.PACKET3_RELEASE_MEM_GCR_GL2_INV | self.pm4.PACKET3_RELEASE_MEM_GCR_GLM_WB \ | self.pm4.PACKET3_RELEASE_MEM_GCR_GLM_INV | self.pm4.PACKET3_RELEASE_MEM_GCR_GL2_WB | self.pm4.PACKET3_RELEASE_MEM_GCR_SEQ) event_dw = self.pm4.PACKET3_RELEASE_MEM_EVENT_TYPE(self.pm4.CACHE_FLUSH_AND_INV_TS_EVENT) \ | self.pm4.PACKET3_RELEASE_MEM_EVENT_INDEX(self.pm4.event_index__mec_release_mem__end_of_pipe) memsel_dw = self.pm4.PACKET3_RELEASE_MEM_DATA_SEL(data_sel) | self.pm4.PACKET3_RELEASE_MEM_INT_SEL(int_sel) \ | self.pm4.PACKET3_RELEASE_MEM_DST_SEL(0) else: cache_flags_dw = 0 if not cache_flush else (self.pm4.EOP_TC_WB_ACTION_EN | self.pm4.EOP_TC_NC_ACTION_EN) event_dw = self.pm4.EVENT_TYPE(self.pm4.CACHE_FLUSH_AND_INV_TS_EVENT) | self.pm4.EVENT_INDEX(self.pm4.event_index__mec_release_mem__end_of_pipe) memsel_dw = self.pm4.DATA_SEL(data_sel) | self.pm4.INT_SEL(int_sel) ctxid = 0 self.pkt3(self.pm4.PACKET3_RELEASE_MEM, event_dw | cache_flags_dw, memsel_dw, *data64_le(address), *data64_le(value), ctxid) def xcc_barrier(self): if self.dev.xcc_sync is None: return self assert self.dev.xccs == 8, 'only 8 XCCs supported' a, b = self.dev.xcc_sync mem_eq = self.pm4.WAIT_REG_MEM_FUNCTION(WAIT_REG_MEM_FUNCTION_EQ) | self.pm4.WAIT_REG_MEM_MEM_SPACE(1) self.pkt3(self.pm4.PACKET3_ATOMIC_MEM, self.soc.TC_OP_ATOMIC_ADD_RTN_32, *data64_le(a.value_addr), *data64_le(1), *data64_le(0), 0x10) # a += 1 self.pkt3(self.pm4.PACKET3_WAIT_REG_MEM, mem_eq, *data64_le(a.value_addr), 0, 0b111, 0x80) # a == 0 (mod 8) via bitmask self.pkt3(self.pm4.PACKET3_ATOMIC_MEM, self.soc.TC_OP_ATOMIC_ADD_RTN_32, *data64_le(b.value_addr), *data64_le(1), *data64_le(0), 0x10) # b += 1 self.pkt3(self.pm4.PACKET3_WAIT_REG_MEM, mem_eq, *data64_le(b.value_addr), 0, 0b111, 0x80) # b == 0 (mod 8) via bitmask return self def memory_barrier(self): pf = '' if self.nbio.version[0] == 2 else '0' if self.nbio.version[:2] != (7, 11) else '1' self.wait_reg_mem(reg_req=getattr(self.nbio, f'regBIF_BX_PF{pf}_GPU_HDP_FLUSH_REQ').addr, reg_done=getattr(self.nbio, f'regBIF_BX_PF{pf}_GPU_HDP_FLUSH_DONE').addr, value=0xffffffff) self.acquire_mem() return self def xcc_config(self): self.wreg(self.gc.regCOMPUTE_TG_CHUNK_SIZE, 1) for xcc_id in range(self.dev.xccs): with self.pred_exec(xcc_mask=1 << xcc_id): self.wreg(self.gc.regCOMPUTE_CURRENT_LOGIC_XCC_ID, xcc_id) return self def spi_config(self, tracing:bool): self.wreg(self.gc.regSPI_CONFIG_CNTL, ps_pkr_priority_cntl=3, exp_priority_order=3, gpr_write_priority=0x2c688, enable_sqg_bop_events=int(tracing), enable_sqg_top_events=int(tracing)) ### SQTT ### def sqtt_userdata(self, data, *extra_dwords): data_ints = [x[0] for x in struct.iter_unpack('>12) self.wreg(self.gc.regSQ_THREAD_TRACE_BUF0_SIZE, base_hi=buf0_hi, size=buf0s[se].size>>12) self.wreg(self.gc.regSQ_THREAD_TRACE_BUF0_BASE, base_lo=buf0_lo) # NOTE: SQTT can only trace instructions on one simd per se, this selects first simd in first wgp in first sa. # For RGP to display instruction trace it has to see it on first SE. Howerver ACE/MEC/whatever does the dispatching starting with second se, # and on amdgpu/non-AM it also does weird things with dispatch order inside se: around 7 times out of 10 it starts from the last cu, but # sometimes not, especially if the kernel has more than one wavefront which means that kernels with small global size might get unlucky and # be dispatched on something else and not be seen in instruction tracing tab. You can force the wavefronts of a kernel to be dispatched on the # CUs you want to by disabling other CUs via bits in regCOMPUTE_STATIC_THREAD_MGMT_SE and trace even kernels that only have one wavefront. self.wreg(self.gc.regSQ_THREAD_TRACE_MASK, wtype_include=self.soc.SQ_TT_WTYPE_INCLUDE_CS_BIT, simd_sel=0, wgp_sel=0, sa_sel=0) REG_INCLUDE = self.soc.SQ_TT_TOKEN_MASK_SQDEC_BIT | self.soc.SQ_TT_TOKEN_MASK_SHDEC_BIT | self.soc.SQ_TT_TOKEN_MASK_GFXUDEC_BIT | \ self.soc.SQ_TT_TOKEN_MASK_COMP_BIT | self.soc.SQ_TT_TOKEN_MASK_CONTEXT_BIT | self.soc.SQ_TT_TOKEN_MASK_CONTEXT_BIT TOKEN_EXCLUDE = 1 << self.soc.SQ_TT_TOKEN_EXCLUDE_PERF_SHIFT if not (se_mask >> se) & 0b1: TOKEN_EXCLUDE |= 1 << self.soc.SQ_TT_TOKEN_EXCLUDE_VMEMEXEC_SHIFT | 1 << self.soc.SQ_TT_TOKEN_EXCLUDE_ALUEXEC_SHIFT | \ 1 << self.soc.SQ_TT_TOKEN_EXCLUDE_VALUINST_SHIFT | 1 << self.soc.SQ_TT_TOKEN_EXCLUDE_IMMEDIATE_SHIFT | \ 1 << self.soc.SQ_TT_TOKEN_EXCLUDE_INST_SHIFT self.wreg(self.gc.regSQ_THREAD_TRACE_TOKEN_MASK, reg_include=REG_INCLUDE, token_exclude=TOKEN_EXCLUDE, bop_events_token_include=1) # Enable SQTT self.sqtt_config(tracing=True) # Restore global broadcasting self.wreg(self.gc.regGRBM_GFX_INDEX, se_broadcast_writes=1, sa_broadcast_writes=1, instance_broadcast_writes=1) self.wreg(self.gc.regCOMPUTE_THREAD_TRACE_ENABLE, 1) self.memory_barrier() return self # Magic values from src/amd/common/ac_sqtt.c:ac_sqtt_emit_stop and src/amd/common/ac_sqtt.c:ac_sqtt_emit_wait def sqtt_stop(self, ses: int, wptrs: HCQBuffer): self.memory_barrier() # Start shutting everything down self.wreg(self.gc.regCOMPUTE_THREAD_TRACE_ENABLE, 0) self.pkt3(self.pm4.PACKET3_EVENT_WRITE, self.pm4.EVENT_TYPE(self.soc.THREAD_TRACE_FINISH) | self.pm4.EVENT_INDEX(0)) # For each SE wait for finish to complete and copy regSQ_THREAD_TRACE_WPTR to know where in the buffer trace data ends for se in range(ses): self.wreg(self.gc.regGRBM_GFX_INDEX, se_index=se, instance_broadcast_writes=1) # Wait for FINISH_PENDING==0 self.pkt3(self.pm4.PACKET3_WAIT_REG_MEM, self.pm4.WAIT_REG_MEM_FUNCTION(WAIT_REG_MEM_FUNCTION_EQ), self.gc.regSQ_THREAD_TRACE_STATUS.addr, 0, 0, self.gc.SQ_THREAD_TRACE_STATUS__FINISH_PENDING_MASK, 4) # Wait for FINISH_DONE!=0 self.pkt3(self.pm4.PACKET3_WAIT_REG_MEM, self.pm4.WAIT_REG_MEM_FUNCTION(WAIT_REG_MEM_FUNCTION_NEQ), self.gc.regSQ_THREAD_TRACE_STATUS.addr, 0, 0, self.gc.SQ_THREAD_TRACE_STATUS__FINISH_DONE_MASK, 4) # Disable SQTT self.sqtt_config(tracing=False) # Wait for BUSY==0 self.pkt3(self.pm4.PACKET3_WAIT_REG_MEM, self.pm4.WAIT_REG_MEM_FUNCTION(WAIT_REG_MEM_FUNCTION_EQ), self.gc.regSQ_THREAD_TRACE_STATUS.addr, 0, 0, self.gc.SQ_THREAD_TRACE_STATUS__BUSY_MASK, 4) # Copy WPTR to memory (src_sel = perf, dst_sel = tc_l2, wr_confirm = True) self.pkt3(self.pm4.PACKET3_COPY_DATA, 1 << 20 | 2 << 8 | 4, self.gc.regSQ_THREAD_TRACE_WPTR.addr, 0, *data64_le(wptrs.va_addr+(se*4))) # Restore global broadcasting self.wreg(self.gc.regGRBM_GFX_INDEX, se_broadcast_writes=1, sa_broadcast_writes=1, instance_broadcast_writes=1) self.spi_config(tracing=False) self.memory_barrier() return self def sqtt_prg_marker(self, prg:AMDProgram, global_size:tuple[sint, ...]): BIND_POINT_COMPUTE = 1 self.sqtt_userdata(sqtt.struct_rgp_sqtt_marker_pipeline_bind( _0=sqtt.union_rgp_sqtt_marker_pipeline_bind_0(_0=sqtt.struct_rgp_sqtt_marker_pipeline_bind_0_0( identifier=sqtt.RGP_SQTT_MARKER_IDENTIFIER_BIND_PIPELINE, bind_point=BIND_POINT_COMPUTE)), _1=sqtt.union_rgp_sqtt_marker_pipeline_bind_1(api_pso_hash=data64_le(prg.libhash[0])))) self.sqtt_userdata(sqtt.struct_rgp_sqtt_marker_event( _0=sqtt.union_rgp_sqtt_marker_event_0(_0=sqtt.struct_rgp_sqtt_marker_event_0_0(has_thread_dims=1)), _2=sqtt.union_rgp_sqtt_marker_event_2(cmd_id=prg.dev.cmd_id)), *global_size) prg.dev.cmd_id += 1 def exec(self, prg:AMDProgram, args_state:CLikeArgsState, global_size:tuple[sint, ...], local_size:tuple[sint, ...]): self.bind_args_state(args_state) self.acquire_mem(gli=0, gl2=0) user_regs = [] if prg.enable_private_segment_sgpr: assert self.dev.xccs == 1, "Only architected flat scratch is suppored on multi-xcc" scratch_hilo = data64_le(prg.dev.scratch.va_addr) # sgpr word1 bit31 enables swizzle # sgpr word3 = 0x14 << 12 | 2 << 28 | 2 << 21 | 1 << 23 user_regs = [scratch_hilo[0], scratch_hilo[1] | 1 << 31, 0xffffffff, 0x20c14000] if prg.enable_dispatch_ptr: dp = (dp_t:=hsa.hsa_kernel_dispatch_packet_t).from_address(cast(int, (disp_buf:=args_state.buf.offset(prg.kernargs_segment_size)).va_addr)) self.bind_sints(*local_size, mem=disp_buf.cpu_view(), struct_t=dp_t, start_field='workgroup_size_x', fmt='H') self.bind_sints(*[g*l for g,l in zip(global_size, local_size)], mem=disp_buf.cpu_view(), struct_t=dp_t, start_field='grid_size_x', fmt='I') dp.group_segment_size, dp.private_segment_size, dp.kernarg_address = prg.group_segment_size, prg.private_segment_size, args_state.buf.va_addr user_regs += [*data64_le(disp_buf.va_addr)] user_regs += [*data64_le(args_state.buf.va_addr)] if prg.dev.sqtt_enabled: self.sqtt_prg_marker(prg, global_size) self.wreg(self.gc.regCOMPUTE_PGM_LO, *data64_le(prg.prog_addr >> 8)) self.wreg(self.gc.regCOMPUTE_PGM_RSRC1, prg.rsrc1, prg.rsrc2) self.wreg(self.gc.regCOMPUTE_PGM_RSRC3, prg.rsrc3) self.wreg(self.gc.regCOMPUTE_TMPRING_SIZE, prg.dev.tmpring_size) if prg.dev.has_scratch_base_registers: for xcc_id in range(self.dev.xccs): with self.pred_exec(xcc_mask=1<> 8)) if (10,0,0) <= prg.dev.target < (11,0,0): self.wreg(self.gc.mmCP_COHER_START_DELAY, 0x20) self.wreg(self.gc.regCOMPUTE_RESTART_X, 0, 0, 0) self.wreg(self.gc.regCOMPUTE_STATIC_THREAD_MGMT_SE0, 0xFFFFFFFF, 0xFFFFFFFF) self.wreg(self.gc.regCOMPUTE_STATIC_THREAD_MGMT_SE2, 0xFFFFFFFF, 0xFFFFFFFF) if prg.dev.target >= (11,0,0): self.wreg(self.gc.regCOMPUTE_STATIC_THREAD_MGMT_SE4, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF) self.wreg(self.gc.regCOMPUTE_USER_DATA_0, *user_regs) self.wreg(self.gc.regCOMPUTE_RESOURCE_LIMITS, 0) self.wreg(self.gc.regCOMPUTE_START_X, 0, 0, 0, *local_size, 0, 0) gfx10p = {'cs_w32_en': int(prg.wave32)} if prg.dev.target >= (10,0,0) else {} DISPATCH_INITIATOR = self.gc.regCOMPUTE_DISPATCH_INITIATOR.encode(**gfx10p, force_start_at_000=1, compute_shader_en=1) self.pkt3(self.pm4.PACKET3_DISPATCH_DIRECT, *global_size, DISPATCH_INITIATOR) if prg.dev.sqtt_enabled: self.pkt3(self.pm4.PACKET3_EVENT_WRITE, self.pm4.EVENT_TYPE(self.soc.THREAD_TRACE_MARKER) | self.pm4.EVENT_INDEX(0)) self.pkt3(self.pm4.PACKET3_EVENT_WRITE, self.pm4.EVENT_TYPE(self.soc.CS_PARTIAL_FLUSH) | self.pm4.EVENT_INDEX(EVENT_INDEX_PARTIAL_FLUSH)) if self.dev.xccs > 1: self.release_mem(cache_flush=True) self.acquire_mem(gli=0) self.xcc_barrier() return self def wait(self, signal:AMDSignal, value:sint=0): self.wait_reg_mem(mem=signal.value_addr, value=value, mask=0xffffffff) if self.dev.xccs > 1: self.xcc_barrier() return self def timestamp(self, signal:AMDSignal): with self.pred_exec(xcc_mask=0b1): self.release_mem(signal.timestamp_addr, 0, self.pm4.data_sel__mec_release_mem__send_gpu_clock_counter, self.pm4.int_sel__mec_release_mem__none) return self def signal(self, signal:AMDSignal, value:sint=0): with self.pred_exec(xcc_mask=0b1): # NOTE: this needs an EOP buffer on the queue or it will NULL pointer self.release_mem(signal.value_addr, value, self.pm4.data_sel__mec_release_mem__send_32_bit_low, self.pm4.int_sel__mec_release_mem__send_interrupt_after_write_confirm, cache_flush=True) if (dev:=signal.timeline_for_device) is not None and not dev.is_am(): self.release_mem(dev.queue_event_mailbox_ptr, dev.queue_event.event_id, self.pm4.data_sel__mec_release_mem__send_32_bit_low, self.pm4.int_sel__mec_release_mem__send_interrupt_after_write_confirm, ctxid=dev.queue_event.event_id) return self def bind(self, dev:AMDDevice): self.binded_device = dev self.hw_page = dev.allocator.alloc(len(self._q) * 4, BufferSpec(cpu_access=True, nolru=True, uncached=True)) hw_view = self.hw_page.cpu_view().view(fmt='I') for i, value in enumerate(self._q): hw_view[i] = value self.indirect_cmd = [self.pm4.PACKET3(self.pm4.PACKET3_INDIRECT_BUFFER, 2), *data64_le(self.hw_page.va_addr), len(self._q) | self.pm4.INDIRECT_BUFFER_VALID] self._q = hw_view return self def _submit(self, dev:AMDDevice): cmds = self.indirect_cmd if dev == self.binded_device else self._q # WORKAROUND: PACKET3_PRED_EXEC doesn't work in rings, only in IBs, create a fake IB inside a ring to work around that if self.dev.xccs > 1 and dev != self.binded_device: ib_end = ((dev.compute_queue.put_value + 5) % len(dev.compute_queue.ring)) + len(cmds) ib_pad = len(dev.compute_queue.ring) - (ib_end - len(cmds)) if ib_end > len(dev.compute_queue.ring) else 0 ib_ptr = dev.compute_queue.ring.addr + ((dev.compute_queue.put_value + 5 + ib_pad) % len(dev.compute_queue.ring)) * 4 cmds = [self.pm4.PACKET3(self.pm4.PACKET3_INDIRECT_BUFFER, 2), *data64_le(ib_ptr), len(cmds) | self.pm4.INDIRECT_BUFFER_VALID, self.pm4.PACKET3(self.pm4.PACKET3_NOP, ib_pad + len(cmds) - 1), *((0,) * ib_pad), *cmds] for i, value in enumerate(cmds): dev.compute_queue.ring[(dev.compute_queue.put_value + i) % len(dev.compute_queue.ring)] = value dev.compute_queue.put_value += len(cmds) dev.compute_queue.signal_doorbell(dev) class AMDCopyQueue(HWQueue): def __init__(self, dev, max_copy_size=0x40000000): self.dev, self.sdma, self.internal_cmd_sizes, self.max_copy_size = dev, dev.sdma, [], max_copy_size super().__init__() def q(self, *arr): super().q(*arr) self.internal_cmd_sizes.append(len(arr)) def copy(self, dest:sint, src:sint, copy_size:int): copied, copy_commands = 0, (copy_size + self.max_copy_size - 1) // self.max_copy_size for _ in range(copy_commands): step_copy_size = min(copy_size - copied, self.max_copy_size) self.q(self.sdma.SDMA_OP_COPY | self.sdma.SDMA_PKT_COPY_LINEAR_HEADER_SUB_OP(self.sdma.SDMA_SUBOP_COPY_LINEAR), self.sdma.SDMA_PKT_COPY_LINEAR_COUNT_COUNT(step_copy_size - 1), 0, *data64_le(src + copied), *data64_le(dest + copied)) copied += step_copy_size return self def signal(self, signal:AMDSignal, value:sint=0): fence_flags = self.sdma.SDMA_PKT_FENCE_HEADER_MTYPE(3) if self.dev.target >= (10,0,0) else 0 self.q(self.sdma.SDMA_OP_FENCE | fence_flags, *data64_le(signal.value_addr), value) if (dev:=signal.timeline_for_device) is not None and not dev.is_am(): self.q(self.sdma.SDMA_OP_FENCE | fence_flags, *data64_le(dev.queue_event_mailbox_ptr), dev.queue_event.event_id) self.q(self.sdma.SDMA_OP_TRAP, self.sdma.SDMA_PKT_TRAP_INT_CONTEXT_INT_CONTEXT(dev.queue_event.event_id)) elif dev is not None and dev.is_am(): self.q(self.sdma.SDMA_OP_TRAP, self.sdma.SDMA_PKT_TRAP_INT_CONTEXT_INT_CONTEXT(0)) return self def wait(self, signal:AMDSignal, value:sint=0): self.q(self.sdma.SDMA_OP_POLL_REGMEM | self.sdma.SDMA_PKT_POLL_REGMEM_HEADER_FUNC(WAIT_REG_MEM_FUNCTION_GEQ) | \ self.sdma.SDMA_PKT_POLL_REGMEM_HEADER_MEM_POLL(1), *data64_le(signal.value_addr), value, 0xffffffff, self.sdma.SDMA_PKT_POLL_REGMEM_DW5_INTERVAL(0x04) | self.sdma.SDMA_PKT_POLL_REGMEM_DW5_RETRY_COUNT(0xfff)) return self def timestamp(self, signal:AMDSignal): self.q(self.sdma.SDMA_OP_TIMESTAMP | self.sdma.SDMA_PKT_TIMESTAMP_GET_HEADER_SUB_OP(self.sdma.SDMA_SUBOP_TIMESTAMP_GET_GLOBAL), *data64_le(signal.timestamp_addr)) return self def bind(self, dev:AMDDevice): if not getenv("AMD_SDMA_BIND", 0) or not dev.is_am(): return self.binded_device = dev self.hw_page = dev.allocator.alloc((qsz:=round_up(len(self._q), 8)) * 4, BufferSpec(cpu_access=True, nolru=True, uncached=True)) hw_view = self.hw_page.cpu_view().view(fmt='I') for i in range(qsz): hw_view[i] = self._q[i] if i < len(self._q) else 0 self.indirect_cmd = [self.sdma.SDMA_OP_INDIRECT | self.sdma.SDMA_PKT_INDIRECT_HEADER_VMID(0), *data64_le(self.hw_page.va_addr), qsz, *data64_le(0)] self._q, self.cmd_sizes = hw_view, [len(self.indirect_cmd)] def _submit(self, dev:AMDDevice): # usb devices run in single-step mode, so they can't overrun the queue. if not dev.is_usb() and dev.sdma_queue.put_value - dev.sdma_queue.read_ptr > dev.sdma_queue.ring.nbytes: raise RuntimeError("SDMA queue overrun") if self.binded_device == dev: # An IB packet must end on a 8 DW boundary. add = (8 - (((dev.sdma_queue.put_value % 32) // 4) + len(self.indirect_cmd) % 8)) % 8 cmds, cmd_sizes = ([0] * add) + self.indirect_cmd, [len(self.indirect_cmd) + add] if len(cmds) * 4 >= (dev.sdma_queue.ring.nbytes - dev.sdma_queue.put_value % dev.sdma_queue.ring.nbytes): cmds, cmd_sizes = [0, 0] + self.indirect_cmd, [8] else: cmds, cmd_sizes = self._q, self.internal_cmd_sizes tail_blit_dword = 0 for cmdsz in cmd_sizes: if (tail_blit_dword + cmdsz) * 4 >= dev.sdma_queue.ring.nbytes - dev.sdma_queue.put_value % dev.sdma_queue.ring.nbytes: break tail_blit_dword += cmdsz # Force align of submits to hit our usb layer write cache. if dev.is_usb() and (rem_packet_cnt := len(cmds) - tail_blit_dword) > 0: tail_blit_dword = 0 start_idx = (dev.sdma_queue.put_value % dev.sdma_queue.ring.nbytes) // 4 dev.sdma_queue.ring[start_idx : start_idx + tail_blit_dword] = array.array('I', cmds[:tail_blit_dword]) dev.sdma_queue.put_value += tail_blit_dword * 4 if (rem_packet_cnt := len(cmds) - tail_blit_dword) > 0: zero_fill = dev.sdma_queue.ring.nbytes - dev.sdma_queue.put_value % dev.sdma_queue.ring.nbytes dev.sdma_queue.ring.view(dev.sdma_queue.put_value % dev.sdma_queue.ring.nbytes, zero_fill, fmt='B')[:] = bytes(zero_fill) dev.sdma_queue.put_value += zero_fill dev.sdma_queue.ring[0:rem_packet_cnt] = array.array('I', cmds[tail_blit_dword:]) dev.sdma_queue.put_value += rem_packet_cnt * 4 dev.sdma_queue.signal_doorbell(dev) class AMDProgram(HCQProgram): def __init__(self, dev:AMDDevice, name:str, lib:bytes): # TODO; this API needs the type signature of the function and global_size/local_size self.dev, self.name, self.lib = dev, name, lib image, sections, _ = elf_loader(self.lib) self.lib_gpu = self.dev.allocator.alloc(round_up(image.nbytes, 0x1000), BufferSpec(cpu_access=True, nolru=True)) self.dev.allocator._copyin(self.lib_gpu, image) self.dev.synchronize() rodata_entry = next((sh.header.sh_addr for sh in sections if sh.name == ".rodata"), -1) text_entry = next((sh.header.sh_addr for sh in sections if sh.name == ".text"), -1) assert rodata_entry >= 0 and text_entry >= 0, ".text or .rodata section not found" self.group_segment_size = image[rodata_entry:rodata_entry+4].cast("I")[0] self.private_segment_size = image[rodata_entry+4:rodata_entry+8].cast("I")[0] self.kernargs_segment_size = image[rodata_entry+8:rodata_entry+12].cast("I")[0] lds_size = ((self.group_segment_size + 511) // 512) & 0x1FF if lds_size > (self.dev.dev_iface.props['lds_size_in_kb'] * 1024) // 512: raise RuntimeError("Too many resources requested: group_segment_size") # Ensure scratch size self.dev._ensure_has_local_memory(self.private_segment_size) # NOTE: this is wrong, it's not this object. pad it, since it might be smaller than the struct code = hsa.amd_kernel_code_t.from_buffer_copy(bytes(image[rodata_entry:rodata_entry+256]) + b'\x00'*256) self.wave32: bool = code.kernel_code_properties & 0x400 == 0x400 # Set rsrc1.priv=1 on gfx11 to workaround cwsr. self.rsrc1: int = code.compute_pgm_rsrc1 | ((1 << 20) if (11,0,0) <= self.dev.target < (12,0,0) else 0) self.rsrc2: int = code.compute_pgm_rsrc2 | (lds_size << 15) self.rsrc3: int = image[rodata_entry+44:rodata_entry+48].cast("I")[0] # NOTE: kernel descriptor, not in amd_kernel_code_t struct self.prog_addr: int = self.lib_gpu.va_addr + rodata_entry + code.kernel_code_entry_byte_offset if code.kernel_code_entry_byte_offset == 0: self.prog_addr = self.lib_gpu.va_addr + text_entry # Some programs use hsa_kernel_dispatch_packet_t to read workgroup sizes during execution. # The packet is represented as a pointer and set up in SGPRs. Space for the packet is allocated as part of the kernel arguments. self.enable_dispatch_ptr: int = code.kernel_code_properties & hsa.AMD_KERNEL_CODE_PROPERTIES_ENABLE_SGPR_DISPATCH_PTR self.enable_private_segment_sgpr: int = code.kernel_code_properties & hsa.AMD_KERNEL_CODE_PROPERTIES_ENABLE_SGPR_PRIVATE_SEGMENT_BUFFER additional_alloc_sz = ctypes.sizeof(hsa.hsa_kernel_dispatch_packet_t) if self.enable_dispatch_ptr else 0 if dev.sqtt_enabled: self.libhash: tuple[int, int] = struct.unpack(' HCQBuffer: return self.dev.dev_iface.alloc(size, host=options.host, uncached=options.uncached, cpu_access=options.cpu_access) def _free(self, opaque, options:BufferSpec): self.dev.synchronize() self.dev.dev_iface.free(opaque) def map(self, buf:HCQBuffer): self.dev.dev_iface.map(buf._base if buf._base is not None else buf) MAP_FIXED, MAP_NORESERVE, MAP_LOCKED = 0x10, 0x400, 0 if OSX else 0x2000 @dataclass(frozen=True) class ProfileSQTTEvent(ProfileEvent): device:str; se:int; blob:bytes; itrace:bool # noqa: E702 @dataclass class AMDQueueDesc: ring: MMIOInterface read_ptrs: list[MMIOInterface] write_ptrs: list[MMIOInterface] doorbells: list[MMIOInterface] put_value: int = 0 @property def read_ptr(self): return min(p[0] for p in self.read_ptrs) @classmethod def multi(cls, *queues: AMDQueueDesc): assert all_same([(q.ring.addr, q.put_value) for q in queues]), f"All queues must have the same ring and put_value: {queues}" return cls(ring=queues[0].ring, put_value=queues[0].put_value, doorbells=flatten(q.doorbells for q in queues), read_ptrs=flatten(q.read_ptrs for q in queues), write_ptrs=flatten(q.write_ptrs for q in queues)) def signal_doorbell(self, dev): for write_ptr in self.write_ptrs: write_ptr[0] = self.put_value # Ensure all prior writes are visible to the GPU. if CPUProgram.atomic_lib is not None: CPUProgram.atomic_lib.atomic_thread_fence(__ATOMIC_SEQ_CST:=5) # Flush hdp if queue is in dev mem. if dev.is_am() and not dev.is_usb() and getenv("AMD_ALLOC_QUEUE_DEV_MEM", 1): dev.dev_iface.adev.gmc.flush_hdp() for doorbell in self.doorbells: doorbell[0] = self.put_value @dataclass(frozen=True) class AMDReg(AMDRegBase): ip: AMDIP @property def addr(self): return self.ip.bases[self.segment] + self.offset @dataclass(frozen=True) class AMDIP: name: str version: tuple[int, ...] bases: tuple[int, ...] @functools.cached_property def module(self): return import_module(self.name, self.version) @functools.cached_property def regs(self): return collect_registers(self.module, cls=functools.partial(AMDReg, ip=self)) def __getattr__(self, name:str): if name in self.regs: return self.regs[name] # NOTE: gfx10 gc registers always start with mm, no reg prefix if (mmname:=name.replace('reg', 'mm')) in self.regs: return self.regs[mmname] return getattr(self.module, name) class KFDIface: kfd:FileIOInterface|None = None event_page:HCQBuffer|None = None gpus:list[FileIOInterface] = [] def _is_usable_gpu(self, gpu_id): with contextlib.suppress(OSError): return int(gpu_id.read()) != 0 return False def __init__(self, dev, device_id): self.dev = dev kfd_topo_path = "/sys/devices/virtual/kfd/kfd/topology/nodes" # Initialize KFD interface during first run if KFDIface.kfd is None: KFDIface.kfd = FileIOInterface("/dev/kfd", os.O_RDWR) gpus = [g for g in FileIOInterface(kfd_topo_path).listdir() if self._is_usable_gpu(FileIOInterface(f"{kfd_topo_path}/{g}/gpu_id"))] gpus = sorted(gpus, key=lambda x: int(x.split('/')[-1])) visible_devices = [int(x) for x in (getenv('VISIBLE_DEVICES', getenv('HIP_VISIBLE_DEVICES', ''))).split(',') if x.strip()] KFDIface.gpus = [gpus[x] for x in visible_devices] if visible_devices else gpus if device_id >= len(KFDIface.gpus): raise RuntimeError(f"No device found for {device_id}. Requesting more devices than the system has?") self.gpu_id = int(FileIOInterface(f"{kfd_topo_path}/{KFDIface.gpus[device_id]}/gpu_id").read()) self.props = {(p:=l.split())[0]: int(p[1]) for l in FileIOInterface(f"{kfd_topo_path}/{KFDIface.gpus[device_id]}/properties").read().splitlines()} ip_base = f"/sys/class/drm/renderD{self.props['drm_render_minor']}/device/ip_discovery/die/0" id2ip = {am.GC_HWID: am.GC_HWIP, am.SDMA0_HWID: am.SDMA0_HWIP, am.NBIF_HWID: am.NBIF_HWIP} self.ip_versions = {id2ip[int(hwid)]:tuple(int(FileIOInterface(f'{ip_base}/{hwid}/0/{part}').read()) for part in ['major', 'minor', 'revision']) for hwid in FileIOInterface(ip_base).listdir() if hwid.isnumeric() and int(hwid) in id2ip} self.ip_offsets = {id2ip[int(hwid)]:tuple(int(x, 16) for x in FileIOInterface(f'{ip_base}/{hwid}/0/base_addr').read().splitlines()) for hwid in FileIOInterface(ip_base).listdir() if hwid.isnumeric() and int(hwid) in id2ip} self.drm_fd = FileIOInterface(f"/dev/dri/renderD{self.props['drm_render_minor']}", os.O_RDWR) kfd.AMDKFD_IOC_ACQUIRE_VM(KFDIface.kfd, drm_fd=self.drm_fd.fd, gpu_id=self.gpu_id) # Set these for our device. if KFDIface.event_page is None: KFDIface.event_page = self.alloc(0x8000, uncached=True) kfd.AMDKFD_IOC_CREATE_EVENT(KFDIface.kfd, event_page_offset=KFDIface.event_page.meta.handle) else: self.map(KFDIface.event_page) # Event to wait for queues completion self.dev.queue_event = kfd.AMDKFD_IOC_CREATE_EVENT(KFDIface.kfd, event_type=kfd.KFD_IOC_EVENT_SIGNAL, auto_reset=1) self.dev.queue_event_mailbox_ptr = KFDIface.event_page.va_addr + self.dev.queue_event.event_slot_index * 8 self.queue_event_arr = (kfd.struct_kfd_event_data)(event_id=self.dev.queue_event.event_id) self.queue_event_arr_ptr = ctypes.addressof(self.queue_event_arr) # OS events to collect memory and hardware faults self.mem_fault_event = kfd.AMDKFD_IOC_CREATE_EVENT(KFDIface.kfd, event_type=kfd.KFD_IOC_EVENT_MEMORY) self.hw_fault_event = kfd.AMDKFD_IOC_CREATE_EVENT(KFDIface.kfd, event_type=kfd.KFD_IOC_EVENT_HW_EXCEPTION) def alloc(self, size:int, host=False, uncached=False, cpu_access=False) -> HCQBuffer: flags = kfd.KFD_IOC_ALLOC_MEM_FLAGS_WRITABLE | kfd.KFD_IOC_ALLOC_MEM_FLAGS_EXECUTABLE | kfd.KFD_IOC_ALLOC_MEM_FLAGS_NO_SUBSTITUTE if uncached: flags |= kfd.KFD_IOC_ALLOC_MEM_FLAGS_COHERENT | kfd.KFD_IOC_ALLOC_MEM_FLAGS_UNCACHED | kfd.KFD_IOC_ALLOC_MEM_FLAGS_GTT else: flags |= (kfd.KFD_IOC_ALLOC_MEM_FLAGS_USERPTR if host else kfd.KFD_IOC_ALLOC_MEM_FLAGS_VRAM) if cpu_access or host: flags |= kfd.KFD_IOC_ALLOC_MEM_FLAGS_PUBLIC if flags & kfd.KFD_IOC_ALLOC_MEM_FLAGS_USERPTR: buf = addr = FileIOInterface.anon_mmap(0, size, mmap.PROT_READ | mmap.PROT_WRITE, mmap.MAP_SHARED | mmap.MAP_ANONYMOUS, 0) else: buf, addr = 0, FileIOInterface.anon_mmap(0, size, 0, mmap.MAP_PRIVATE | mmap.MAP_ANONYMOUS | MAP_NORESERVE, 0) assert addr != 0xffffffffffffffff try: mem = kfd.AMDKFD_IOC_ALLOC_MEMORY_OF_GPU(self.kfd, va_addr=addr, size=size, base=addr, length=size, gpu_id=self.gpu_id, flags=flags, mmap_offset=buf) except OSError as e: if e.errno == errno.EINVAL and (flags & kfd.KFD_IOC_ALLOC_MEM_FLAGS_VRAM) and cpu_access: raise MemoryError("Cannot allocate host-visible VRAM. Ensure the resizable BAR option is enabled on your system.") from e if e.errno == errno.ENOMEM: raise MemoryError("Cannot allocate memory: no memory is available.") from e raise if not (flags & kfd.KFD_IOC_ALLOC_MEM_FLAGS_USERPTR): buf = self.drm_fd.mmap(mem.va_addr, mem.size, mmap.PROT_READ | mmap.PROT_WRITE, mmap.MAP_SHARED | MAP_FIXED, mem.mmap_offset) assert addr == buf == mem.va_addr self.map(hcqbuf:=HCQBuffer(mem.va_addr, mem.size, meta=mem, view=MMIOInterface(mem.va_addr, mem.size, fmt='B') if cpu_access or host else None)) return hcqbuf def free(self, mem): if len(gpus:=getattr(mem.meta, "mapped_gpu_ids", [])): c_gpus = (ctypes.c_int32 * len(gpus))(*gpus) stm = kfd.AMDKFD_IOC_UNMAP_MEMORY_FROM_GPU(self.kfd, handle=mem.meta.handle, device_ids_array_ptr=ctypes.addressof(c_gpus), n_devices=len(gpus)) assert stm.n_success == len(gpus) if mem.va_addr: FileIOInterface.munmap(mem.va_addr, mem.size) kfd.AMDKFD_IOC_FREE_MEMORY_OF_GPU(self.kfd, handle=mem.meta.handle) def map(self, mem): if self.gpu_id in getattr(mem.meta, "mapped_gpu_ids", []): return mem.meta.__setattr__("mapped_gpu_ids", getattr(mem.meta, "mapped_gpu_ids", []) + [self.gpu_id]) c_gpus = (ctypes.c_int32 * len(mem.meta.mapped_gpu_ids))(*mem.meta.mapped_gpu_ids) stm = kfd.AMDKFD_IOC_MAP_MEMORY_TO_GPU(self.kfd, handle=mem.meta.handle, device_ids_array_ptr=ctypes.addressof(c_gpus), n_devices=len(mem.meta.mapped_gpu_ids)) assert stm.n_success == len(mem.meta.mapped_gpu_ids) def create_queue(self, queue_type, ring, gart, eop_buffer=None, cwsr_buffer=None, ctl_stack_size=0, ctx_save_restore_size=0, xcc_id=0): queue = kfd.AMDKFD_IOC_CREATE_QUEUE(KFDIface.kfd, ring_base_address=ring.va_addr, ring_size=ring.size, gpu_id=self.gpu_id, queue_type=queue_type, queue_percentage=kfd.KFD_MAX_QUEUE_PERCENTAGE|(xcc_id<<8), queue_priority=kfd.KFD_MAX_QUEUE_PRIORITY, eop_buffer_address=eop_buffer.va_addr if eop_buffer else 0, eop_buffer_size=eop_buffer.size if eop_buffer else 0, ctl_stack_size=ctl_stack_size, ctx_save_restore_address=cwsr_buffer.va_addr if cwsr_buffer else 0, ctx_save_restore_size=ctx_save_restore_size, write_pointer_address=gart.va_addr, read_pointer_address=gart.va_addr + 8 * (xcc_id + 1)) if not hasattr(self, 'doorbells'): self.doorbells_base = queue.doorbell_offset & (~0x1fff) # doorbell is two pages self.doorbells = cast(FileIOInterface, KFDIface.kfd).mmap(0, 0x2000, mmap.PROT_READ|mmap.PROT_WRITE, mmap.MAP_SHARED, self.doorbells_base) return AMDQueueDesc(ring=MMIOInterface(ring.va_addr, ring.size, fmt='I'), read_ptrs=[MMIOInterface(queue.read_pointer_address, 8, fmt='Q')], write_ptrs=[MMIOInterface(queue.write_pointer_address, 8, fmt='Q')], doorbells=[MMIOInterface(self.doorbells + queue.doorbell_offset - self.doorbells_base, 8, fmt='Q')]) def sleep(self, tm:int): kfd.AMDKFD_IOC_WAIT_EVENTS(KFDIface.kfd, events_ptr=self.queue_event_arr_ptr, num_events=1, wait_for_all=1, timeout=tm) def on_device_hang(self): def _collect_str(st): return ' '.join(f'{k[0]}={getattr(st, k[0])}' for k in st._fields_) report = [] for evnt in [self.mem_fault_event, self.hw_fault_event]: ev = (kfd.struct_kfd_event_data)(event_id=evnt.event_id) kfd.AMDKFD_IOC_WAIT_EVENTS(KFDIface.kfd, events_ptr=ctypes.addressof(ev), num_events=1, wait_for_all=1) if evnt == self.mem_fault_event and ev.memory_exception_data.gpu_id: report += [f"MMU fault: 0x{ev.memory_exception_data.va:X} | {_collect_str(ev.memory_exception_data.failure)}"] if evnt == self.hw_fault_event and ev.hw_exception_data.gpu_id: report += [f"HW fault: {_collect_str(ev.hw_exception_data)}"] raise RuntimeError("\n".join(report)) @dataclass class AMAllocationMeta: owner:AMDDevice; mapped_devs:list[AMDDevice]; mapping:AMMapping; has_cpu_mapping:bool # noqa: E702 class PCIIface: supported_devs:list[int] = [0x744c, 0x7480, 0x7550] vfio:bool = getenv("VFIO", 1) and FileIOInterface.exists("/dev/vfio/vfio") vfio_fd:FileIOInterface gpus:list[Any] = [] def __init__(self, dev, dev_id): self.dev = dev if first_dev:=len(PCIIface.gpus) == 0: for pcibus in FileIOInterface("/sys/bus/pci/devices").listdir(): vendor = int(FileIOInterface(f"/sys/bus/pci/devices/{pcibus}/vendor").read(), 16) device = int(FileIOInterface(f"/sys/bus/pci/devices/{pcibus}/device").read(), 16) if vendor == 0x1002 and device in PCIIface.supported_devs: PCIIface.gpus.append(pcibus) PCIIface.gpus = sorted(PCIIface.gpus) # TODO: visible_devices should be handled layer above this? visible_devices = [int(x) for x in (getenv('VISIBLE_DEVICES', getenv('HIP_VISIBLE_DEVICES', ''))).split(',') if x.strip()] PCIIface.gpus = [PCIIface.gpus[x] for x in visible_devices] if visible_devices else PCIIface.gpus self.pcibus = PCIIface.gpus[dev_id] # Unbind the device from the kernel driver if FileIOInterface.exists(f"/sys/bus/pci/devices/{self.pcibus}/driver"): FileIOInterface(f"/sys/bus/pci/devices/{self.pcibus}/driver/unbind", os.O_WRONLY).write(self.pcibus) supported_sizes = int(FileIOInterface(f"/sys/bus/pci/devices/{self.pcibus}/resource0_resize", os.O_RDONLY).read(), 16) try: FileIOInterface(f"/sys/bus/pci/devices/{self.pcibus}/resource0_resize", os.O_RDWR).write(str(supported_sizes.bit_length() - 1)) except OSError as e: raise RuntimeError(f"Cannot resize BAR: {e}. Ensure the resizable BAR option is enabled on your system.") from e # Try to init vfio. Use it if success. if PCIIface.vfio: try: if first_dev: FileIOInterface("/sys/module/vfio/parameters/enable_unsafe_noiommu_mode", os.O_RDWR).write("1") PCIIface.vfio_fd = FileIOInterface("/dev/vfio/vfio", os.O_RDWR) vfio.VFIO_CHECK_EXTENSION(PCIIface.vfio_fd, vfio.VFIO_NOIOMMU_IOMMU) FileIOInterface(f"/sys/bus/pci/devices/{self.pcibus}/driver_override", os.O_WRONLY).write("vfio-pci") FileIOInterface("/sys/bus/pci/drivers_probe", os.O_WRONLY).write(self.pcibus) iommu_group = FileIOInterface.readlink(f"/sys/bus/pci/devices/{self.pcibus}/iommu_group").split('/')[-1] except OSError: if DEBUG >= 1: print(f"am {self.pcibus}: failed to init vfio-pci module (run `sudo modprobe vfio-pci`).") PCIIface.vfio = False # Init vfio for the device if PCIIface.vfio: self.vfio_group = FileIOInterface(f"/dev/vfio/noiommu-{iommu_group}", os.O_RDWR) vfio.VFIO_GROUP_SET_CONTAINER(self.vfio_group, ctypes.c_int(PCIIface.vfio_fd.fd)) if first_dev: vfio.VFIO_SET_IOMMU(PCIIface.vfio_fd, vfio.VFIO_NOIOMMU_IOMMU) self.vfio_dev = FileIOInterface(fd=vfio.VFIO_GROUP_GET_DEVICE_FD(self.vfio_group, ctypes.create_string_buffer(self.pcibus.encode()))) self.irq_fd = FileIOInterface.eventfd(0, 0) self.irq_poller = select.poll() self.irq_poller.register(self.irq_fd.fd, select.POLLIN) irqs = vfio.struct_vfio_irq_set(index=vfio.VFIO_PCI_MSI_IRQ_INDEX, flags=vfio.VFIO_IRQ_SET_DATA_EVENTFD|vfio.VFIO_IRQ_SET_ACTION_TRIGGER, argsz=ctypes.sizeof(vfio.struct_vfio_irq_set), count=1, data=(ctypes.c_int * 1)(self.irq_fd.fd)) vfio.VFIO_DEVICE_SET_IRQS(self.vfio_dev, irqs) else: FileIOInterface(f"/sys/bus/pci/devices/{self.pcibus}/enable", os.O_RDWR).write("1") self.pagemap = FileIOInterface("/proc/self/pagemap", os.O_RDONLY) self.cfg_fd = FileIOInterface(f"/sys/bus/pci/devices/{self.pcibus}/config", os.O_RDWR | os.O_SYNC | os.O_CLOEXEC) self.bar_fds = {b: FileIOInterface(f"/sys/bus/pci/devices/{self.pcibus}/resource{b}", os.O_RDWR | os.O_SYNC | os.O_CLOEXEC) for b in [0, 2, 5]} bar_info = FileIOInterface(f"/sys/bus/pci/devices/{self.pcibus}/resource", os.O_RDONLY).read().splitlines() self.bar_info = {j:(int(start,16), int(end,16), int(flgs,16)) for j,(start,end,flgs) in enumerate(l.split() for l in bar_info)} self._setup_adev(self.pcibus, self._map_pci_range(0), dbell:=self._map_pci_range(2, fmt='Q'), self._map_pci_range(5, fmt='I')) self.doorbell_cpu_addr = dbell.addr pci_cmd = int.from_bytes(self.cfg_fd.read(2, binary=True, offset=pci.PCI_COMMAND), byteorder='little') | pci.PCI_COMMAND_MASTER self.cfg_fd.write(pci_cmd.to_bytes(2, byteorder='little'), binary=True, offset=pci.PCI_COMMAND) def _setup_adev(self, name, vram:MMIOInterface, doorbell:MMIOInterface, mmio:MMIOInterface): self.adev = AMDev(name, vram, doorbell, mmio) self.ip_versions = self.adev.ip_ver self.ip_offsets = {hwip: tuple(instances[0]) for hwip,instances in self.adev.regs_offset.items()} gfxver = int(f"{self.adev.ip_ver[am.GC_HWIP][0]:02d}{self.adev.ip_ver[am.GC_HWIP][1]:02d}{self.adev.ip_ver[am.GC_HWIP][2]:02d}") array_count = self.adev.gc_info.gc_num_sa_per_se * self.adev.gc_info.gc_num_se simd_count = 2 * array_count * (self.adev.gc_info.gc_num_wgp0_per_sa + self.adev.gc_info.gc_num_wgp1_per_sa) self.props = {'simd_count': 2 * simd_count, 'simd_per_cu': 2, 'array_count': array_count, 'gfx_target_version': gfxver, 'max_slots_scratch_cu': self.adev.gc_info.gc_max_scratch_slots_per_cu, 'max_waves_per_simd': self.adev.gc_info.gc_max_waves_per_simd, 'simd_arrays_per_engine': self.adev.gc_info.gc_num_sa_per_se, 'lds_size_in_kb': self.adev.gc_info.gc_lds_size} def _map_pci_range(self, bar, off=0, addr=0, size=None, fmt='B'): fd, sz = self.bar_fds[bar], size or (self.bar_info[bar][1] - self.bar_info[bar][0] + 1) libc.madvise(loc:=fd.mmap(addr, sz, mmap.PROT_READ | mmap.PROT_WRITE, mmap.MAP_SHARED | (MAP_FIXED if addr else 0), off), sz, libc.MADV_DONTFORK) assert loc != 0xffffffffffffffff, f"Failed to mmap {size} bytes at {hex(addr)}" return MMIOInterface(loc, sz, fmt=fmt) def alloc(self, size:int, host=False, uncached=False, cpu_access=False): if host or (not getenv("AMD_ALLOC_QUEUE_DEV_MEM", 1) and uncached and cpu_access): # host or gtt-like memory. vaddr = self.adev.mm.alloc_vaddr(size:=round_up(size, mmap.PAGESIZE), align=mmap.PAGESIZE) va = FileIOInterface.anon_mmap(vaddr, size, mmap.PROT_READ | mmap.PROT_WRITE, mmap.MAP_SHARED | mmap.MAP_ANONYMOUS | MAP_LOCKED | MAP_FIXED, 0) assert va != 0xffffffffffffffff, f"Failed to mmap {size} bytes at {hex(vaddr)}" # Read pagemap to get the physical address of each page. The pages are locked. self.pagemap.seek(va // mmap.PAGESIZE * 8) paddrs = [((x & ((1<<55) - 1)) * mmap.PAGESIZE, mmap.PAGESIZE) for x in array.array('Q', self.pagemap.read(size//mmap.PAGESIZE*8, binary=True))] am_mapping = self.adev.mm.map_range(vaddr, size, paddrs, system=True, snooped=True, uncached=True) return HCQBuffer(vaddr, size, meta=AMAllocationMeta(self.dev, [self.dev], am_mapping, has_cpu_mapping=cpu_access), view=MMIOInterface(am_mapping.va_addr, size, fmt='B')) am_mapping = self.adev.mm.valloc(size:=round_up(size, 4 << 10), uncached=uncached, contigous=cpu_access) if cpu_access: self._map_pci_range(bar=0, off=am_mapping.paddrs[0][0], addr=am_mapping.va_addr, size=am_mapping.size) return HCQBuffer(am_mapping.va_addr, size, meta=AMAllocationMeta(self.dev, [self.dev], am_mapping, has_cpu_mapping=cpu_access), view=MMIOInterface(am_mapping.va_addr, size, fmt='B') if cpu_access else None) def free(self, mem): for dev in mem.meta.mapped_devs[1:]: dev.dev_iface.adev.mm.unmap_range(mem.va_addr, mem.size) if not mem.meta.mapping.system: self.adev.mm.vfree(mem.meta.mapping) if mem.meta.owner == self.dev and mem.meta.has_cpu_mapping: FileIOInterface.munmap(mem.va_addr, mem.size) def map(self, mem): # Check if the memory is already mapped on this device if self.dev in mem.meta.mapped_devs: return mem.meta.mapped_devs.append(self.dev) paddrs = [(paddr if mem.meta.mapping.system else (paddr+mem.meta.owner.dev_iface.bar_info[0][0]), size) for paddr,size in mem.meta.mapping.paddrs] self.adev.mm.map_range(mem.va_addr, mem.size, paddrs, system=True, snooped=mem.meta.mapping.snooped, uncached=mem.meta.mapping.uncached) def create_queue(self, queue_type, ring, gart, eop_buffer=None, cwsr_buffer=None, ctl_stack_size=0, ctx_save_restore_size=0, xcc_id=0): assert cwsr_buffer is None, "no cwsr buffer for am" if queue_type == kfd.KFD_IOC_QUEUE_TYPE_SDMA: self.adev.sdma.setup_ring(ring_addr=ring.va_addr, ring_size=ring.size, rptr_addr=gart.va_addr, wptr_addr=gart.va_addr+0x10, doorbell=(doorbell_index:=am.AMDGPU_NAVI10_DOORBELL_sDMA_ENGINE0), pipe=0, queue=0) else: self.adev.gfx.setup_ring(ring_addr=ring.va_addr, ring_size=ring.size, rptr_addr=gart.va_addr, wptr_addr=gart.va_addr+0x10, eop_addr=eop_buffer.va_addr, eop_size=eop_buffer.size, doorbell=(doorbell_index:=am.AMDGPU_NAVI10_DOORBELL_MEC_RING0), pipe=0, queue=0) return AMDQueueDesc(ring=MMIOInterface(ring.va_addr, ring.size, fmt='I'), read_ptrs=[MMIOInterface(gart.va_addr, 8, fmt='Q')], write_ptrs=[MMIOInterface(gart.va_addr+0x10, 8, fmt='Q')], doorbells=[MMIOInterface(self.doorbell_cpu_addr + doorbell_index * 8, 8, fmt='Q')]) def sleep(self, timeout): if PCIIface.vfio and (events_cnt:=len(self.irq_poller.poll(timeout))): self.irq_fd.read(8 * events_cnt) self.adev.ih.interrupt_handler() def on_device_hang(self): for d in self.dev.devices: d.dev_iface.adev.gmc.on_interrupt() raise RuntimeError("Device hang detected") def device_fini(self): self.adev.fini() class USBIface(PCIIface): def __init__(self, dev, dev_id): self.dev = dev self.usb = ASM24Controller() self.bars = setup_pci_bars(self.usb, gpu_bus=4, mem_base=0x10000000, pref_mem_base=(32 << 30)) self._setup_adev(f"usb:{dev_id}", USBMMIOInterface(self.usb, *self.bars[0], fmt='B'), USBMMIOInterface(self.usb, *self.bars[2], fmt='Q'), USBMMIOInterface(self.usb, *self.bars[5], fmt='I')) self.usb._pci_cacheable += [self.bars[2]] # doorbell region is cacheable # special regions self.copy_bufs = [self._new_dma_region(ctrl_addr=0xf000, sys_addr=0x200000, size=0x80000)] self.sys_buf, self.sys_next_off = self._new_dma_region(ctrl_addr=0xa000, sys_addr=0x820000, size=0x1000), 0x800 def _new_dma_region(self, ctrl_addr, sys_addr, size): region = self.adev.mm.map_range(vaddr:=self.adev.mm.alloc_vaddr(size=size), size, [(sys_addr, size)], system=True, snooped=False, uncached=True) return HCQBuffer(vaddr, size, meta=AMAllocationMeta(self.dev, [self.dev], region, has_cpu_mapping=False), view=USBMMIOInterface(self.usb, ctrl_addr, size, fmt='B', pcimem=False)) def alloc(self, size:int, host=False, uncached=False, cpu_access=False): if (host or (uncached and cpu_access)) and self.sys_next_off + size < self.sys_buf.size: self.sys_next_off += size return self.sys_buf.offset(self.sys_next_off - size, size) am_mapping = self.adev.mm.valloc(size:=round_up(size, 4 << 10), uncached=uncached, contigous=cpu_access) return HCQBuffer(am_mapping.va_addr, size, meta=AMAllocationMeta(self.dev, [self.dev], am_mapping, has_cpu_mapping=False), view=USBMMIOInterface(self.usb, self.bars[0][0] + am_mapping.paddrs[0][0], size, fmt='B') if cpu_access else None) def create_queue(self, queue_type, ring, gart, eop_buffer=None, cwsr_buffer=None, ctl_stack_size=0, ctx_save_restore_size=0, xcc_id=0): if queue_type == kfd.KFD_IOC_QUEUE_TYPE_SDMA: self.adev.sdma.setup_ring(ring_addr=ring.va_addr, ring_size=ring.size, rptr_addr=gart.va_addr, wptr_addr=gart.va_addr+0x10, doorbell=(doorbell_index:=am.AMDGPU_NAVI10_DOORBELL_sDMA_ENGINE0), pipe=0, queue=0) else: self.adev.gfx.setup_ring(ring_addr=ring.va_addr, ring_size=ring.size, rptr_addr=gart.va_addr, wptr_addr=gart.va_addr+0x10, eop_addr=eop_buffer.va_addr, eop_size=eop_buffer.size, doorbell=(doorbell_index:=am.AMDGPU_NAVI10_DOORBELL_MEC_RING0), pipe=0, queue=0) return AMDQueueDesc(ring=ring.cpu_view().view(fmt='I'), doorbells=[self.adev.doorbell64.view(doorbell_index * 8, 8, fmt='Q')], read_ptrs=[gart.cpu_view().view(size=8, fmt='Q')], write_ptrs=[gart.cpu_view().view(offset=0x10, size=8, fmt='Q')]) class AMDDevice(HCQCompiled): devices: ClassVar[list[HCQCompiled]] = [] signal_pages: ClassVar[list[HCQBuffer]] = [] signal_pool: ClassVar[list[HCQBuffer]] = [] def is_am(self) -> bool: return isinstance(self.dev_iface, (PCIIface, USBIface)) def is_usb(self) -> bool: return isinstance(self.dev_iface, USBIface) def _select_iface(self): if len(nm:=getenv("AMD_IFACE", "")) > 0: return getattr(sys.modules[__name__], f"{nm.upper()}Iface")(self, self.device_id) errs:str = "" for iface_t in (KFDIface, PCIIface, USBIface): try: return iface_t(self, self.device_id) except Exception as e: errs += f"\n{iface_t.__name__}: {type(e).__name__}: {e}" raise RuntimeError(f"Cannot find a usable interface for AMD:{self.device_id}:{errs}") def __init__(self, device:str=""): self.device_id = int(device.split(":")[1]) if ":" in device else 0 self.dev_iface = self._select_iface() self.target:tuple[int, ...] = ((trgt:=self.dev_iface.props['gfx_target_version']) // 10000, (trgt // 100) % 100, trgt % 100) self.arch = "gfx%d%x%x" % self.target if self.target < (9,4,2) or self.target >= (13,0,0): raise RuntimeError(f"Unsupported arch: {self.arch}") if DEBUG >= 1: print(f"AMDDevice: opening {self.device_id} with target {self.target} arch {self.arch}") self.max_cu_id = self.dev_iface.props['simd_count'] // self.dev_iface.props['simd_per_cu'] // self.dev_iface.props.get('num_xcc', 1) - 1 self.max_wave_id = (self.dev_iface.props['max_waves_per_simd'] * self.dev_iface.props['simd_per_cu'] - 1) if self.target >= (10,1,0) else \ (min((self.max_cu_id+1)*40, self.dev_iface.props['array_count'] // self.dev_iface.props['simd_arrays_per_engine'] * 512) - 1) self.xccs = self.dev_iface.props.get('num_xcc', 1) if getenv("XCCS", 1) else 1 self.has_scratch_base_registers = self.target >= (11,0,0) or self.target == (9,4,2) # this is what llvm refers to as "architected flat scratch" # https://gitlab.freedesktop.org/agd5f/linux/-/blob/a1fc9f584c4aaf8bc1ebfa459fc57a3f26a290d8/drivers/gpu/drm/amd/amdkfd/kfd_queue.c#L391 sgrp_size_per_cu, lds_size_per_cu, hwreg_size_per_cu = 0x4000, 0x10000, 0x1000 vgpr_size_per_cu = 0x60000 if self.target in {(11,0,0), (11,0,1), (12,0,0), (12,0,1)} else \ 0x80000 if (self.target[:2]) == (9,4) or self.target in {(9,0,8), (9,0,10)} else 0x40000 wg_data_size = round_up((vgpr_size_per_cu + sgrp_size_per_cu + lds_size_per_cu + hwreg_size_per_cu) * (self.max_cu_id + 1), mmap.PAGESIZE) ctl_stack_size = round_up(12 * (self.max_cu_id + 1) * (self.max_wave_id + 1) + 8 + 40, mmap.PAGESIZE) if self.target >= (10,1,0) else \ round_up((self.max_wave_id + 1) * 8 + 8 + 40, mmap.PAGESIZE) debug_memory_size = round_up((self.max_cu_id + 1 if self.target >= (10,1,0) else 1) * (self.max_wave_id + 1) * 32, 64) if self.target[0] == 10: ctl_stack_size = min(ctl_stack_size, 0x7000) self.soc = importlib.import_module(f"tinygrad.runtime.autogen.am.{({9: 'vega10', 10: 'navi10', 11: 'soc21', 12: 'soc24'}[self.target[0]])}") self.pm4 = importlib.import_module(f"tinygrad.runtime.autogen.am.pm4_{'nv' if self.target[0] >= 10 else 'soc15'}") self.sdma = import_module('sdma', min(self.dev_iface.ip_versions[am.SDMA0_HWIP], (6, 0, 0))) self.gc = AMDIP('gc', self.dev_iface.ip_versions[am.GC_HWIP], self.dev_iface.ip_offsets[am.GC_HWIP]) nbio_ver = self.dev_iface.ip_versions[am.NBIF_HWIP] if nbio_ver[:2] == (3, 3): nbio_ver = (2, 3, 0) nbio_pad = (0,) if self.target[0] == 9 else () self.nbio = AMDIP('nbio' if self.target[0]<12 else 'nbif', nbio_ver, nbio_pad+self.dev_iface.ip_offsets[am.NBIF_HWIP]) self.compute_queue = self.create_queue(kfd.KFD_IOC_QUEUE_TYPE_COMPUTE, 0x8000 if self.is_usb() else 0x800000, eop_buffer_size=0x1000, ctx_save_restore_size=0 if self.is_am() else wg_data_size + ctl_stack_size, ctl_stack_size=ctl_stack_size, debug_memory_size=debug_memory_size) max_copy_size = 0x40000000 if self.dev_iface.ip_versions[am.SDMA0_HWIP][0] >= 5 else 0x400000 self.sdma_queue = self.create_queue(kfd.KFD_IOC_QUEUE_TYPE_SDMA, 0x200 if self.is_usb() else 0x800000) super().__init__(device, AMDAllocator(self), AMDLLVMRenderer(self.arch) if getenv("AMD_LLVM", 0) else AMDRenderer(self.arch), AMDLLVMCompiler(self.arch) if getenv("AMD_LLVM", 0) else HIPCompiler(self.arch), functools.partial(AMDProgram, self), AMDSignal, functools.partial(AMDComputeQueue, self), functools.partial(AMDCopyQueue, self, max_copy_size=max_copy_size), kernargs_size=(8 << 10) if self.is_usb() else (16 << 20), sigalloc_size=0x100 if self.is_usb() else 0x1000) # Scratch setup self.max_private_segment_size = 0 self._ensure_has_local_memory(128) # set default scratch size to 128 bytes per thread # XCC setup self.xcc_sync: tuple[AMDSignal, AMDSignal]|None = None if self.xccs > 1: self.xcc_sync_area = self.allocator.alloc(0x1000, BufferSpec(nolru=True, cpu_access=True)) self.xcc_sync = (AMDSignal(base_buf=self.xcc_sync_area), AMDSignal(base_buf=self.xcc_sync_area.offset(256))) AMDComputeQueue(self).xcc_config().submit(self) # SQTT is disabled by default because of runtime overhead and big file sizes (~200mb to Tensor.full() two 4096x4096 tensors and matmul them) self.sqtt_enabled = PROFILE and bool(getenv("SQTT", 0)) if self.sqtt_enabled: if self.arch != 'gfx1100': raise RuntimeError('SQ Thread Tracing is only supported on 7900XTX') if not self.is_am() and (ppfeaturemask:=int(FileIOInterface('/sys/module/amdgpu/parameters/ppfeaturemask', os.O_RDONLY).read(), 16))&0x8000: raise RuntimeError("SQTT can't be enabled because of hardware bug, to workaround either use AMD_IFACE=PCI or add " f"ppfeaturemask={(ppfeaturemask&~0x8000):#x} (current {ppfeaturemask=:#x} & ~PP_GFXOFF_MASK) to amdgpu module parameters\n" "For more information read https://github.com/tinygrad/tinygrad/blob/master/extra/sqtt/README.md") SQTT_BUFFER_SIZE = getenv("SQTT_BUFFER_SIZE", 256) # in mb, per shader engine SQTT_NUM = self.dev_iface.props['array_count'] // self.dev_iface.props['simd_arrays_per_engine'] self.sqtt_buffers = [self.allocator.alloc(SQTT_BUFFER_SIZE*1024*1024, BufferSpec(cpu_access=True, nolru=True)) for _ in range(SQTT_NUM)] self.sqtt_itrace_se_mask = getenv("SQTT_ITRACE_SE_MASK", 2) # -1 enable all, 0 disable all, >0 bitmask for where to enable instruction tracing self.cmd_id = 0 AMDComputeQueue(self).sqtt_start(self.sqtt_buffers, self.sqtt_itrace_se_mask).submit(self) def create_queue(self, queue_type, ring_size, ctx_save_restore_size=0, eop_buffer_size=0, ctl_stack_size=0, debug_memory_size=0): ring = self.dev_iface.alloc(ring_size, uncached=True, cpu_access=True) gart = self.dev_iface.alloc(0x100, uncached=True, cpu_access=True) cwsr_buffer_size = round_up((ctx_save_restore_size + debug_memory_size) * self.dev_iface.props.get('num_xcc', 1), mmap.PAGESIZE) cwsr_buffer = self.dev_iface.alloc(cwsr_buffer_size) if ctx_save_restore_size else None eop_buffer = self.dev_iface.alloc(eop_buffer_size) if eop_buffer_size else None return AMDQueueDesc.multi(*(self.dev_iface.create_queue(queue_type, ring, gart, eop_buffer=eop_buffer, cwsr_buffer=cwsr_buffer, xcc_id=xcc_id, ctx_save_restore_size=ctx_save_restore_size, ctl_stack_size=ctl_stack_size) for xcc_id in range(self.xccs if queue_type == kfd.KFD_IOC_QUEUE_TYPE_COMPUTE else 1))) def _ensure_has_local_memory(self, required): if self.max_private_segment_size >= required: return # =gfx11 requires 256 wave_scratch_len = round_up(((self.max_wave_id + 1) * required), 256 if self.target >= (11,0,0) else 1024) scratch_size = (self.max_cu_id+1)*self.dev_iface.props['max_slots_scratch_cu']*wave_scratch_len # per xcc self.scratch, ok = self._realloc(getattr(self, 'scratch', None), scratch_size*self.xccs) if ok: engines = self.dev_iface.props['array_count'] // self.dev_iface.props['simd_arrays_per_engine'] waves = wave_scratch_len // (256 if self.target >= (11,0,0) else 1024) # >=gfx11 wavesize is per SE wavesize = scratch_size // ((wave_scratch_len * engines) if self.target >= (11,0,0) else wave_scratch_len) self.tmpring_size = waves << 12 | wavesize self.max_private_segment_size = required def invalidate_caches(self): AMDComputeQueue(self).memory_barrier().signal(self.timeline_signal, self.next_timeline()).submit(self) self.synchronize() def on_device_hang(self): self.dev_iface.on_device_hang() def _at_profile_finalize(self): if self.sqtt_enabled: wptrs_buf = self.allocator.alloc(round_up(len(self.sqtt_buffers), 0x1000), BufferSpec(cpu_access=True, nolru=True)) wptrs = to_mv(wptrs_buf.va_addr, wptrs_buf.size) AMDComputeQueue(self).sqtt_stop(len(self.sqtt_buffers), wptrs_buf).signal(self.timeline_signal, self.next_timeline()).submit(self) self.synchronize() if DEBUG>=2: print('Saving SQTT in profile...') for i,buf0 in enumerate(self.sqtt_buffers): wptr = ((struct.unpack('=2: print(f'Se {i} blob size {wptr:#x}') assert wptr >= 0 and wptr <= buf0.size, f"{wptr} > {buf0.size}, should never happen" # When sqtt buffer overflows, wptr stops at the last dword if wptr >= buf0.size-32: print(f"WARNING: SQTT BUFFER IS FULL (SE {i})! INCREASE SQTT BUFFER SIZE WITH SQTT_BUFFER_SIZE=X (in MB)") self.allocator._copyout(sqtt_buf:=memoryview(bytearray(wptr)), buf0) Compiled.profile_events += [ProfileSQTTEvent(self.device, i, bytes(sqtt_buf), bool((self.sqtt_itrace_se_mask >> i) & 0b1))] super()._at_profile_finalize() def finalize(self): try: self.synchronize() # Try to finalize device in any case. except RuntimeError as e: print(f"{self.device} synchronization failed before finalizing: {e}") if hasattr(self.dev_iface, 'device_fini'): self.dev_iface.device_fini()