/* * Copyright (C) 2021 Intel Corporation. All rights reserved. * SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception */ #include "jit_utils.h" #include "jit_compiler.h" #if BH_DEBUG != 0 #define VREG_DEF_SANITIZER #endif /** * A uint16 stack for storing distances of occurrences of virtual * registers. */ typedef struct UintStack { /* Capacity of the stack. */ uint32 capacity; /* Top index of the stack. */ uint32 top; /* Elements of the vector. */ uint32 elem[1]; } UintStack; static bool uint_stack_push(UintStack **stack, unsigned val) { unsigned capacity = *stack ? (*stack)->capacity : 0; unsigned top = *stack ? (*stack)->top : 0; bh_assert(top <= capacity); if (top == capacity) { const unsigned elem_size = sizeof((*stack)->elem[0]); unsigned new_capacity = capacity ? capacity + capacity / 2 : 4; UintStack *new_stack = jit_malloc(offsetof(UintStack, elem) + elem_size * new_capacity); if (!new_stack) return false; new_stack->capacity = new_capacity; new_stack->top = top; if (*stack) memcpy(new_stack->elem, (*stack)->elem, elem_size * top); jit_free(*stack); *stack = new_stack; } (*stack)->elem[(*stack)->top++] = val; return true; } static int uint_stack_top(UintStack *stack) { return stack->elem[stack->top - 1]; } static void uint_stack_delete(UintStack **stack) { jit_free(*stack); *stack = NULL; } static void uint_stack_pop(UintStack **stack) { bh_assert((*stack)->top > 0); /** * TODO: the fact of empty distances stack means there is no instruction * using current JitReg anymore. so shall we release the HardReg and clean * VirtualReg information? */ if (--(*stack)->top == 0) uint_stack_delete(stack); } /** * Information of a virtual register. */ typedef struct VirtualReg { /* The hard register allocated to this virtual register. */ JitReg hreg; /* The spill slot allocated to this virtual register. */ JitReg slot; /* The hard register allocated to global virtual registers. It is 0 for local registers, whose lifetime is within one basic block. */ JitReg global_hreg; /* Distances from the beginning of basic block of all occurrences of the virtual register in the basic block. */ UintStack *distances; } VirtualReg; /** * Information of a hard register. */ typedef struct HardReg { /* The virtual register this hard register is allocated to. */ JitReg vreg; } HardReg; /** * Information of a spill slot. */ typedef struct SpillSlot { /* The virtual register this spill slot is allocated to. */ JitReg vreg; } SpillSlot; typedef struct RegallocContext { /* The compiler context. */ JitCompContext *cc; /* Information of virtual registers. The register allocation must not increase the virtual register number during the allocation process. */ VirtualReg *vregs[JIT_REG_KIND_L32]; /* Information of hard registers. */ HardReg *hregs[JIT_REG_KIND_L32]; /* Number of elements in the spill_slots array. */ uint32 spill_slot_num; /* Information of spill slots. */ SpillSlot *spill_slots; /* The last define-released hard register. */ JitReg last_def_released_hreg; } RegallocContext; /** * Get the VirtualReg structure of the given virtual register. * * @param rc the regalloc context * @param vreg the virtual register * * @return the VirtualReg structure of the given virtual register */ static VirtualReg * rc_get_vr(RegallocContext *rc, JitReg vreg) { unsigned kind = jit_reg_kind(vreg); unsigned no = jit_reg_no(vreg); bh_assert(jit_reg_is_variable(vreg)); return &rc->vregs[kind][no]; } /** * Get the HardReg structure of the given hard register. * * @param rc the regalloc context * @param hreg the hard register * * @return the HardReg structure of the given hard register */ static HardReg * rc_get_hr(RegallocContext *rc, JitReg hreg) { unsigned kind = jit_reg_kind(hreg); unsigned no = jit_reg_no(hreg); bh_assert(jit_reg_is_variable(hreg) && jit_cc_is_hreg(rc->cc, hreg)); return &rc->hregs[kind][no]; } /** * Get the SpillSlot structure of the given slot. * * @param rc the regalloc context * @param slot the constant register representing the slot index * * @return the SpillSlot of the given slot */ static SpillSlot * rc_get_spill_slot(RegallocContext *rc, JitReg slot) { unsigned index = jit_cc_get_const_I32(rc->cc, slot); bh_assert(index < rc->spill_slot_num); return &rc->spill_slots[index]; } /** * Get the stride in the spill slots of the register. * * @param reg a virtual register * * @return stride in the spill slots */ static unsigned get_reg_stride(JitReg reg) { static const uint8 strides[] = { 0, 1, 2, 1, 2, 2, 4, 8, 0 }; return strides[jit_reg_kind(reg)]; } /** * Allocate a spill slot for the given virtual register. * * @param rc the regalloc context * @param vreg the virtual register * * @return the spill slot encoded in a consant register */ static JitReg rc_alloc_spill_slot(RegallocContext *rc, JitReg vreg) { const unsigned stride = get_reg_stride(vreg); unsigned mask, new_num, i, j; SpillSlot *slots; bh_assert(stride > 0); for (i = 0; i < rc->spill_slot_num; i += stride) for (j = i;; j++) { if (j == i + stride) /* Found a free slot for vreg. */ goto found; if (rc->spill_slots[j].vreg) break; } /* No free slot, increase the slot number. */ mask = stride - 1; /* Align the slot index. */ i = (rc->spill_slot_num + mask) & ~mask; new_num = i == 0 ? 32 : i + i / 2; if (!(slots = jit_calloc(sizeof(*slots) * new_num))) return 0; if (rc->spill_slots) memcpy(slots, rc->spill_slots, sizeof(*slots) * rc->spill_slot_num); jit_free(rc->spill_slots); rc->spill_slots = slots; rc->spill_slot_num = new_num; found: /* Now, i is the first slot for vreg. */ if ((i + stride) * 4 > rc->cc->spill_cache_size) /* No frame space for the spill area. */ return 0; /* Allocate the slot(s) to vreg. */ for (j = i; j < i + stride; j++) rc->spill_slots[j].vreg = vreg; return jit_cc_new_const_I32(rc->cc, i); } /** * Free a spill slot. * * @param rc the regalloc context * @param slot_reg the constant register representing the slot index */ static void rc_free_spill_slot(RegallocContext *rc, JitReg slot_reg) { if (slot_reg) { SpillSlot *slot = rc_get_spill_slot(rc, slot_reg); const JitReg vreg = slot->vreg; const unsigned stride = get_reg_stride(vreg); unsigned i; for (i = 0; i < stride; i++) slot[i].vreg = 0; } } static void rc_destroy(RegallocContext *rc) { unsigned i, j; for (i = JIT_REG_KIND_VOID; i < JIT_REG_KIND_L32; i++) { const unsigned vreg_num = jit_cc_reg_num(rc->cc, i); if (rc->vregs[i]) for (j = 0; j < vreg_num; j++) uint_stack_delete(&rc->vregs[i][j].distances); jit_free(rc->vregs[i]); jit_free(rc->hregs[i]); } jit_free(rc->spill_slots); } static bool rc_init(RegallocContext *rc, JitCompContext *cc) { unsigned i, j; memset(rc, 0, sizeof(*rc)); rc->cc = cc; for (i = JIT_REG_KIND_VOID; i < JIT_REG_KIND_L32; i++) { const unsigned vreg_num = jit_cc_reg_num(cc, i); const unsigned hreg_num = jit_cc_hreg_num(cc, i); if (vreg_num > 0 && !(rc->vregs[i] = jit_calloc(sizeof(VirtualReg) * vreg_num))) goto fail; if (hreg_num > 0 && !(rc->hregs[i] = jit_calloc(sizeof(HardReg) * hreg_num))) goto fail; /* Hard registers can only be allocated to themselves. */ for (j = 0; j < hreg_num; j++) rc->vregs[i][j].global_hreg = jit_reg_new(i, j); } return true; fail: rc_destroy(rc); return false; } /** * Check whether the given register is an allocation candidate, which * must be a variable register that is not fixed hard register. * * @param cc the compilation context * @param reg the register * * @return true if the register is an allocation candidate */ static bool is_alloc_candidate(JitCompContext *cc, JitReg reg) { return (jit_reg_is_variable(reg) && (!jit_cc_is_hreg(cc, reg) || !jit_cc_is_hreg_fixed(cc, reg))); } #ifdef VREG_DEF_SANITIZER static void check_vreg_definition(RegallocContext *rc, JitInsn *insn) { JitRegVec regvec = jit_insn_opnd_regs(insn); JitReg *regp, reg_defined = 0; unsigned i, first_use = jit_insn_opnd_first_use(insn); /* check if there is the definition of an vr before its references */ JIT_REG_VEC_FOREACH(regvec, i, regp) { VirtualReg *vr = NULL; if (!is_alloc_candidate(rc->cc, *regp)) continue; /* a strong assumption that there is only one defined reg */ if (i < first_use) { reg_defined = *regp; continue; } /** * both definition and references are in one instruction, * like MOV i3, i3 */ if (reg_defined == *regp) continue; vr = rc_get_vr(rc, *regp); bh_assert(vr->distances); } } #endif /** * Collect distances from the beginning of basic block of all occurrences of * each virtual register. * * @param rc the regalloc context * @param basic_block the basic block * * @return distance of the end instruction if succeeds, -1 otherwise */ static int collect_distances(RegallocContext *rc, JitBasicBlock *basic_block) { JitInsn *insn; int distance = 1; JIT_FOREACH_INSN(basic_block, insn) { JitRegVec regvec = jit_insn_opnd_regs(insn); unsigned i; JitReg *regp; #ifdef VREG_DEF_SANITIZER check_vreg_definition(rc, insn); #endif /* NOTE: the distance may be pushed more than once if the virtual register occurs multiple times in the instruction. */ JIT_REG_VEC_FOREACH(regvec, i, regp) if (is_alloc_candidate(rc->cc, *regp)) if (!uint_stack_push(&(rc_get_vr(rc, *regp))->distances, distance)) return -1; /* Integer overflow check, normally it won't happen, but we had better add the check here */ if (distance >= INT32_MAX) return -1; distance++; } return distance; } static JitReg offset_of_spill_slot(JitCompContext *cc, JitReg slot) { return jit_cc_new_const_I32(cc, cc->spill_cache_offset + jit_cc_get_const_I32(cc, slot) * 4); } /** * Reload the virtual register from memory. Reload instruction will * be inserted after the given instruction. * * @param rc the regalloc context * @param vreg the virtual register to be reloaded * @param cur_insn the current instruction after which the reload * insertion will be inserted * * @return the reload instruction if succeeds, NULL otherwise */ static JitInsn * reload_vreg(RegallocContext *rc, JitReg vreg, JitInsn *cur_insn) { VirtualReg *vr = rc_get_vr(rc, vreg); HardReg *hr = rc_get_hr(rc, vr->hreg); JitInsn *insn = NULL; if (vreg == rc->cc->exec_env_reg) /* Reload exec_env_reg with LDEXECENV. */ insn = jit_cc_new_insn(rc->cc, LDEXECENV, vr->hreg); else /* Allocate spill slot if not yet and reload from there. */ { JitReg fp_reg = rc->cc->fp_reg, offset; if (!vr->slot && !(vr->slot = rc_alloc_spill_slot(rc, vreg))) /* Cannot allocte spill slot (due to OOM or frame size limit). */ return NULL; offset = offset_of_spill_slot(rc->cc, vr->slot); switch (jit_reg_kind(vreg)) { case JIT_REG_KIND_I32: insn = jit_cc_new_insn(rc->cc, LDI32, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_I64: insn = jit_cc_new_insn(rc->cc, LDI64, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_F32: insn = jit_cc_new_insn(rc->cc, LDF32, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_F64: insn = jit_cc_new_insn(rc->cc, LDF64, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_V64: insn = jit_cc_new_insn(rc->cc, LDV64, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_V128: insn = jit_cc_new_insn(rc->cc, LDV128, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_V256: insn = jit_cc_new_insn(rc->cc, LDV256, vr->hreg, fp_reg, offset); break; default: bh_assert(0); } } if (insn) jit_insn_insert_after(cur_insn, insn); bh_assert(hr->vreg == vreg); hr->vreg = vr->hreg = 0; return insn; } /** * Spill the virtual register (which cannot be exec_env_reg) to memory. * Spill instruction will be inserted after the given instruction. * * @param rc the regalloc context * @param vreg the virtual register to be reloaded * @param cur_insn the current instruction after which the reload * insertion will be inserted * * @return the spill instruction if succeeds, NULL otherwise */ static JitInsn * spill_vreg(RegallocContext *rc, JitReg vreg, JitInsn *cur_insn) { VirtualReg *vr = rc_get_vr(rc, vreg); JitReg fp_reg = rc->cc->fp_reg, offset; JitInsn *insn; /* There is no chance to spill exec_env_reg. */ bh_assert(vreg != rc->cc->exec_env_reg); bh_assert(vr->hreg && vr->slot); offset = offset_of_spill_slot(rc->cc, vr->slot); switch (jit_reg_kind(vreg)) { case JIT_REG_KIND_I32: insn = jit_cc_new_insn(rc->cc, STI32, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_I64: insn = jit_cc_new_insn(rc->cc, STI64, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_F32: insn = jit_cc_new_insn(rc->cc, STF32, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_F64: insn = jit_cc_new_insn(rc->cc, STF64, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_V64: insn = jit_cc_new_insn(rc->cc, STV64, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_V128: insn = jit_cc_new_insn(rc->cc, STV128, vr->hreg, fp_reg, offset); break; case JIT_REG_KIND_V256: insn = jit_cc_new_insn(rc->cc, STV256, vr->hreg, fp_reg, offset); break; default: bh_assert(0); return NULL; } if (insn) jit_insn_insert_after(cur_insn, insn); return insn; } /** * Allocate a hard register for the virtual register. Necessary * reloade instruction will be inserted after the given instruction. * * @param rc the regalloc context * @param vreg the virtual register * @param insn the instruction after which the reload insertion will * be inserted * @param distance the distance of the current instruction * * @return the hard register allocated if succeeds, 0 otherwise */ static JitReg allocate_hreg(RegallocContext *rc, JitReg vreg, JitInsn *insn, int distance) { const int kind = jit_reg_kind(vreg); const HardReg *hregs = rc->hregs[kind]; const unsigned hreg_num = jit_cc_hreg_num(rc->cc, kind); JitReg hreg, vreg_to_reload = 0; int min_distance = distance, vr_distance; VirtualReg *vr = rc_get_vr(rc, vreg); unsigned i; if (hreg_num == 0) /* Unsupported hard register kind. */ { jit_set_last_error(rc->cc, "unsupported hard register kind"); return 0; } if (vr->global_hreg) /* It has globally allocated register, we can only use it. */ { if ((vreg_to_reload = (rc_get_hr(rc, vr->global_hreg))->vreg)) if (!reload_vreg(rc, vreg_to_reload, insn)) return 0; return vr->global_hreg; } /* Use the last define-released register if its kind is correct and it's free so as to optimize for two-operand instructions. */ if (jit_reg_kind(rc->last_def_released_hreg) == kind && (rc_get_hr(rc, rc->last_def_released_hreg))->vreg == 0) return rc->last_def_released_hreg; /* No hint given, just try to pick any free register. */ for (i = 0; i < hreg_num; i++) { hreg = jit_reg_new(kind, i); if (jit_cc_is_hreg_fixed(rc->cc, hreg)) continue; if (hregs[i].vreg == 0) /* Found a free one, return it. */ return hreg; } /* No free registers, need to spill and reload one. */ for (i = 0; i < hreg_num; i++) { if (jit_cc_is_hreg_fixed(rc->cc, jit_reg_new(kind, i))) continue; vr = rc_get_vr(rc, hregs[i].vreg); /* TODO: since the hregs[i] is in use, its distances should be valid */ vr_distance = vr->distances ? uint_stack_top(vr->distances) : 0; if (vr_distance < min_distance) { min_distance = vr_distance; vreg_to_reload = hregs[i].vreg; hreg = jit_reg_new(kind, i); } } bh_assert(min_distance < distance); if (!reload_vreg(rc, vreg_to_reload, insn)) return 0; return hreg; } /** * Allocate a hard register for the virtual register if not allocated * yet. Necessary spill and reloade instructions will be inserted * before/after and after the given instruction. This operation will * convert the virtual register's state from 1 or 3 to 2. * * @param rc the regalloc context * @param vreg the virtual register * @param insn the instruction after which the spill and reload * insertions will be inserted * @param distance the distance of the current instruction * * @return the hard register allocated to the virtual register if * succeeds, 0 otherwise */ static JitReg allocate_for_vreg(RegallocContext *rc, JitReg vreg, JitInsn *insn, int distance) { VirtualReg *vr = rc_get_vr(rc, vreg); if (vr->hreg) /* It has had a hard register, reuse it. */ return vr->hreg; /* Not allocated yet. */ if ((vr->hreg = allocate_hreg(rc, vreg, insn, distance))) (rc_get_hr(rc, vr->hreg))->vreg = vreg; return vr->hreg; } /** * Clobber live registers. * * @param rc the regalloc context * @param is_native whether it's native ABI or JITed ABI * @param insn the instruction after which the reload insertion will * be inserted * * @return true if succeeds, false otherwise */ static bool clobber_live_regs(RegallocContext *rc, bool is_native, JitInsn *insn) { unsigned i, j; for (i = JIT_REG_KIND_VOID; i < JIT_REG_KIND_L32; i++) { const unsigned hreg_num = jit_cc_hreg_num(rc->cc, i); for (j = 0; j < hreg_num; j++) { JitReg hreg = jit_reg_new(i, j); bool caller_saved = (is_native ? jit_cc_is_hreg_caller_saved_native(rc->cc, hreg) : jit_cc_is_hreg_caller_saved_jitted(rc->cc, hreg)); if (caller_saved && rc->hregs[i][j].vreg) if (!reload_vreg(rc, rc->hregs[i][j].vreg, insn)) return false; } } return true; } /** * Do local register allocation for the given basic block * * @param rc the regalloc context * @param basic_block the basic block * @param distance the distance of the last instruction of the basic block * * @return true if succeeds, false otherwise */ static bool allocate_for_basic_block(RegallocContext *rc, JitBasicBlock *basic_block, int distance) { JitInsn *insn; JIT_FOREACH_INSN_REVERSE(basic_block, insn) { JitRegVec regvec = jit_insn_opnd_regs(insn); unsigned first_use = jit_insn_opnd_first_use(insn); unsigned i; JitReg *regp; distance--; JIT_REG_VEC_FOREACH_DEF(regvec, i, regp, first_use) if (is_alloc_candidate(rc->cc, *regp)) { const JitReg vreg = *regp; VirtualReg *vr = rc_get_vr(rc, vreg); if (!(*regp = allocate_for_vreg(rc, vreg, insn, distance))) return false; /* Spill the register if required. */ if (vr->slot && !spill_vreg(rc, vreg, insn)) return false; bh_assert(uint_stack_top(vr->distances) == distance); uint_stack_pop(&vr->distances); /* Record the define-released hard register. */ rc->last_def_released_hreg = vr->hreg; /* Release the hreg and spill slot. */ rc_free_spill_slot(rc, vr->slot); (rc_get_hr(rc, vr->hreg))->vreg = 0; vr->hreg = vr->slot = 0; } if (insn->opcode == JIT_OP_CALLBC) { if (!clobber_live_regs(rc, false, insn)) return false; /* The exec_env_reg is implicitly used by the callee. */ if (!allocate_for_vreg(rc, rc->cc->exec_env_reg, insn, distance)) return false; } else if (insn->opcode == JIT_OP_CALLNATIVE) { if (!clobber_live_regs(rc, true, insn)) return false; } JIT_REG_VEC_FOREACH_USE(regvec, i, regp, first_use) if (is_alloc_candidate(rc->cc, *regp)) { if (!allocate_for_vreg(rc, *regp, insn, distance)) return false; } JIT_REG_VEC_FOREACH_USE(regvec, i, regp, first_use) if (is_alloc_candidate(rc->cc, *regp)) { VirtualReg *vr = rc_get_vr(rc, *regp); bh_assert(uint_stack_top(vr->distances) == distance); uint_stack_pop(&vr->distances); /* be sure that the hreg exists and hasn't been spilled out */ bh_assert(vr->hreg != 0); *regp = vr->hreg; } } return true; } bool jit_pass_regalloc(JitCompContext *cc) { RegallocContext rc = { 0 }; unsigned label_index, end_label_index; JitBasicBlock *basic_block; VirtualReg *self_vr; bool retval = false; if (!rc_init(&rc, cc)) return false; /* NOTE: don't allocate new virtual registers during allocation because the rc->vregs array is fixed size. */ /* TODO: allocate hard registers for global virtual registers here. Currently, exec_env_reg is the only global virtual register. */ self_vr = rc_get_vr(&rc, cc->exec_env_reg); JIT_FOREACH_BLOCK_ENTRY_EXIT(cc, label_index, end_label_index, basic_block) { int distance; /* TODO: initialize hreg for live-out registers. */ self_vr->hreg = self_vr->global_hreg; (rc_get_hr(&rc, cc->exec_env_reg))->vreg = cc->exec_env_reg; /** * TODO: the allocation of a basic block keeps using vregs[] * and hregs[] from previous basic block */ if ((distance = collect_distances(&rc, basic_block)) < 0) goto cleanup_and_return; if (!allocate_for_basic_block(&rc, basic_block, distance)) goto cleanup_and_return; /* TODO: generate necessary spills for live-in registers. */ } retval = true; cleanup_and_return: rc_destroy(&rc); return retval; }