#include "yjit_asm.h" #include "yjit_utils.h" #include "yjit_iface.h" #include "yjit_core.h" #include "yjit_codegen.h" #include "vm_sync.h" #include "builtin.h" // Maximum number of versions per block #define MAX_VERSIONS 4 // Maximum number of branch instructions we can track #define MAX_BRANCHES 100000 // Registered branch entries branch_t branch_entries[MAX_BRANCHES]; uint32_t num_branches = 0; /* Get an operand for the adjusted stack pointer address */ x86opnd_t ctx_sp_opnd(ctx_t* ctx, int32_t offset_bytes) { int32_t offset = (ctx->sp_offset * sizeof(VALUE)) + offset_bytes; return mem_opnd(64, REG_SP, offset); } /* Push one new value on the temp stack Return a pointer to the new stack top */ x86opnd_t ctx_stack_push(ctx_t* ctx, int type) { // Keep track of the type of the value RUBY_ASSERT(type <= RUBY_T_MASK); if (ctx->stack_size < MAX_TEMP_TYPES) ctx->temp_types[ctx->stack_size] = type; ctx->stack_size += 1; ctx->sp_offset += 1; // SP points just above the topmost value int32_t offset = (ctx->sp_offset - 1) * sizeof(VALUE); return mem_opnd(64, REG_SP, offset); } /* Pop N values off the stack Return a pointer to the stack top before the pop operation */ x86opnd_t ctx_stack_pop(ctx_t* ctx, size_t n) { RUBY_ASSERT(n <= ctx->stack_size); // SP points just above the topmost value int32_t offset = (ctx->sp_offset - 1) * sizeof(VALUE); x86opnd_t top = mem_opnd(64, REG_SP, offset); // Clear the types of the popped values for (size_t i = 0; i < n; ++i) { size_t idx = ctx->stack_size - i - 1; if (idx < MAX_TEMP_TYPES) ctx->temp_types[idx] = T_NONE; } ctx->stack_size -= n; ctx->sp_offset -= n; return top; } /** Get an operand pointing to a slot on the temp stack */ x86opnd_t ctx_stack_opnd(ctx_t* ctx, int32_t idx) { // SP points just above the topmost value int32_t offset = (ctx->sp_offset - 1 - idx) * sizeof(VALUE); x86opnd_t opnd = mem_opnd(64, REG_SP, offset); return opnd; } /** Get the type of the topmost value on the temp stack Returns T_NONE if unknown */ int ctx_get_top_type(ctx_t* ctx) { RUBY_ASSERT(ctx->stack_size > 0); if (ctx->stack_size > MAX_TEMP_TYPES) return T_NONE; return ctx->temp_types[ctx->stack_size - 1]; } /** Compute a difference score for two context objects Returns 0 if the two contexts are the same Returns > 0 if different but compatible Returns INT_MAX if incompatible */ int ctx_diff(const ctx_t* src, const ctx_t* dst) { // Can only lookup the first version in the chain if (dst->chain_depth != 0) return INT_MAX; // Blocks with depth > 0 always produce new versions // Sidechains cannot overlap if (src->chain_depth != 0) return INT_MAX; if (dst->stack_size != src->stack_size) return INT_MAX; if (dst->sp_offset != src->sp_offset) return INT_MAX; if (dst->self_is_object != src->self_is_object) return INT_MAX; // Difference sum int diff = 0; // For each temporary variable for (size_t i = 0; i < MAX_TEMP_TYPES; ++i) { int t_src = src->temp_types[i]; int t_dst = dst->temp_types[i]; if (t_dst != t_src) { // It's OK to lose some type information if (t_dst == T_NONE) diff += 1; else return INT_MAX; } } return diff; } // Get all blocks for a particular place in an iseq. static rb_yjit_block_array_t get_version_array(const rb_iseq_t *iseq, unsigned idx) { struct rb_iseq_constant_body *body = iseq->body; if (rb_darray_size(body->yjit_blocks) == 0) { return NULL; } RUBY_ASSERT((unsigned)rb_darray_size(body->yjit_blocks) == body->iseq_size); return rb_darray_get(body->yjit_blocks, idx); } // Count the number of block versions matching a given blockid static size_t get_num_versions(blockid_t blockid) { return rb_darray_size(get_version_array(blockid.iseq, blockid.idx)); } // Keep track of a block version. Block should be fully constructed. static void add_block_version(blockid_t blockid, block_t* block) { // Function entry blocks must have stack size 0 RUBY_ASSERT(!(block->blockid.idx == 0 && block->ctx.stack_size > 0)); const rb_iseq_t *iseq = block->blockid.iseq; struct rb_iseq_constant_body *body = iseq->body; // Ensure yjit_blocks is initialized for this iseq if (rb_darray_size(body->yjit_blocks) == 0) { // Initialize yjit_blocks to be as wide as body->iseq_encoded int32_t casted = (int32_t)body->iseq_size; if ((unsigned)casted != body->iseq_size) { rb_bug("iseq too large"); } if (!rb_darray_make(&body->yjit_blocks, casted)) { rb_bug("allocation failed"); } #if RUBY_DEBUG // First block compiled for this iseq rb_compiled_iseq_count++; #endif } RUBY_ASSERT((int32_t)blockid.idx < rb_darray_size(body->yjit_blocks)); rb_yjit_block_array_t *block_array_ref = rb_darray_ref(body->yjit_blocks, blockid.idx); // Add the new block if (!rb_darray_append(block_array_ref, block)) { rb_bug("allocation failed"); } { // By writing the new block to the iseq, the iseq now // contains new references to Ruby objects. Run write barriers. RB_OBJ_WRITTEN(iseq, Qundef, block->dependencies.cc); RB_OBJ_WRITTEN(iseq, Qundef, block->dependencies.cme); // Run write barriers for all objects in generated code. uint32_t *offset_element; rb_darray_foreach(block->gc_object_offsets, offset_idx, offset_element) { uint32_t offset_to_value = *offset_element; uint8_t *value_address = cb_get_ptr(cb, offset_to_value); VALUE object; memcpy(&object, value_address, SIZEOF_VALUE); RB_OBJ_WRITTEN(iseq, Qundef, object); } } } // Retrieve a basic block version for an (iseq, idx) tuple block_t* find_block_version(blockid_t blockid, const ctx_t* ctx) { rb_yjit_block_array_t versions = get_version_array(blockid.iseq, blockid.idx); // Best match found block_t* best_version = NULL; int best_diff = INT_MAX; // For each version matching the blockid rb_darray_for(versions, idx) { block_t *version = rb_darray_get(versions, idx); int diff = ctx_diff(ctx, &version->ctx); // Note that we always prefer the first matching // version because of inline-cache chains if (diff < best_diff) { best_version = version; best_diff = diff; } } return best_version; } void yjit_branches_update_references(void) { for (uint32_t i = 0; i < num_branches; i++) { branch_entries[i].targets[0].iseq = (const void *)rb_gc_location((VALUE)branch_entries[i].targets[0].iseq); branch_entries[i].targets[1].iseq = (const void *)rb_gc_location((VALUE)branch_entries[i].targets[1].iseq); } } // Compile a new block version immediately block_t* gen_block_version(blockid_t blockid, const ctx_t* start_ctx, rb_execution_context_t* ec) { // Copy the context to avoid mutating it ctx_t ctx_copy = *start_ctx; ctx_t* ctx = &ctx_copy; // Allocate a new block version object block_t* first_block = calloc(1, sizeof(block_t)); first_block->blockid = blockid; memcpy(&first_block->ctx, ctx, sizeof(ctx_t)); // Block that is currently being compiled block_t* block = first_block; // Generate code for the first block yjit_gen_block(ctx, block, ec); // Keep track of the new block version add_block_version(block->blockid, block); // For each successor block to compile for (;;) { // If no branches were generated, stop if (num_branches == 0) { break; } // Get the last branch entry uint32_t branch_idx = num_branches - 1; branch_t* last_branch = &branch_entries[num_branches - 1]; // If there is no next block to compile, stop if (last_branch->dst_addrs[0] || last_branch->dst_addrs[1]) { break; } if (last_branch->targets[0].iseq == NULL) { rb_bug("invalid target for last branch"); } // Use the context from the branch *ctx = last_branch->target_ctxs[0]; // Allocate a new block version object block = calloc(1, sizeof(block_t)); block->blockid = last_branch->targets[0]; memcpy(&block->ctx, ctx, sizeof(ctx_t)); // Generate code for the current block yjit_gen_block(ctx, block, ec); // Keep track of the new block version add_block_version(block->blockid, block); // Patch the last branch address last_branch->dst_addrs[0] = cb_get_ptr(cb, block->start_pos); rb_darray_append(&block->incoming, branch_idx); RUBY_ASSERT(block->start_pos == last_branch->end_pos); } return first_block; } // Generate a block version that is an entry point inserted into an iseq uint8_t* gen_entry_point(const rb_iseq_t *iseq, uint32_t insn_idx, rb_execution_context_t *ec) { // The entry context makes no assumptions about types blockid_t blockid = { iseq, insn_idx }; // Write the interpreter entry prologue uint8_t* code_ptr = yjit_entry_prologue(); // Try to generate code for the entry block block_t* block = gen_block_version(blockid, &DEFAULT_CTX, ec); // If we couldn't generate any code if (block->end_idx == insn_idx) { return NULL; } return code_ptr; } // Called by the generated code when a branch stub is executed // Triggers compilation of branches and code patching static uint8_t * branch_stub_hit(uint32_t branch_idx, uint32_t target_idx, rb_execution_context_t* ec) { uint8_t* dst_addr; RB_VM_LOCK_ENTER(); RUBY_ASSERT(branch_idx < num_branches); RUBY_ASSERT(target_idx < 2); branch_t *branch = &branch_entries[branch_idx]; blockid_t target = branch->targets[target_idx]; const ctx_t* target_ctx = &branch->target_ctxs[target_idx]; //fprintf(stderr, "\nstub hit, branch idx: %d, target idx: %d\n", branch_idx, target_idx); //fprintf(stderr, "blockid.iseq=%p, blockid.idx=%d\n", target.iseq, target.idx); //fprintf(stderr, "chain_depth=%d\n", target_ctx->chain_depth); // Update the PC in the current CFP, because it // may be out of sync in JITted code ec->cfp->pc = iseq_pc_at_idx(target.iseq, target.idx); // If either of the target blocks will be placed next if (cb->write_pos == branch->end_pos) { //fprintf(stderr, "target idx %d will be placed next\n", target_idx); branch->shape = (uint8_t)target_idx; // Rewrite the branch with the new, potentially more compact shape cb_set_pos(cb, branch->start_pos); branch->gen_fn(cb, branch->dst_addrs[0], branch->dst_addrs[1], branch->shape); RUBY_ASSERT(cb->write_pos <= branch->end_pos); } // Limit the number of block versions ctx_t generic_ctx = DEFAULT_CTX; generic_ctx.stack_size = target_ctx->stack_size; generic_ctx.sp_offset = target_ctx->sp_offset; if (target_ctx->chain_depth == 0) { // guard chains implement limits individually if (get_num_versions(target) >= MAX_VERSIONS - 1) { //fprintf(stderr, "version limit hit in branch_stub_hit\n"); target_ctx = &generic_ctx; } } // Try to find a compiled version of this block block_t* p_block = find_block_version(target, target_ctx); // If this block hasn't yet been compiled if (!p_block) { p_block = gen_block_version(target, target_ctx, ec); } // Add this branch to the list of incoming branches for the target rb_darray_append(&p_block->incoming, branch_idx); // Update the branch target address dst_addr = cb_get_ptr(cb, p_block->start_pos); branch->dst_addrs[target_idx] = dst_addr; // Rewrite the branch with the new jump target address RUBY_ASSERT(branch->dst_addrs[0] != NULL); uint32_t cur_pos = cb->write_pos; cb_set_pos(cb, branch->start_pos); branch->gen_fn(cb, branch->dst_addrs[0], branch->dst_addrs[1], branch->shape); RUBY_ASSERT(cb->write_pos <= branch->end_pos); branch->end_pos = cb->write_pos; cb_set_pos(cb, cur_pos); RB_VM_LOCK_LEAVE(); // Return a pointer to the compiled block version return dst_addr; } // Get a version or stub corresponding to a branch target uint8_t* get_branch_target( blockid_t target, const ctx_t* ctx, uint32_t branch_idx, uint32_t target_idx ) { //fprintf(stderr, "get_branch_target, block (%p, %d)\n", target.iseq, target.idx); block_t* p_block = find_block_version(target, ctx); if (p_block) { // Add an incoming branch for this version rb_darray_append(&p_block->incoming, branch_idx); // Return a pointer to the compiled code return cb_get_ptr(cb, p_block->start_pos); } // Generate an outlined stub that will call // branch_stub_hit(uint32_t branch_idx, uint32_t target_idx) uint8_t* stub_addr = cb_get_ptr(ocb, ocb->write_pos); // Save the yjit registers push(ocb, REG_CFP); push(ocb, REG_EC); push(ocb, REG_SP); push(ocb, REG_SP); // Call branch_stub_hit(branch_idx, target_idx, ec) mov(ocb, C_ARG_REGS[2], REG_EC); mov(ocb, C_ARG_REGS[1], imm_opnd(target_idx)); mov(ocb, C_ARG_REGS[0], imm_opnd(branch_idx)); call_ptr(ocb, REG0, (void *)&branch_stub_hit); // Restore the yjit registers pop(ocb, REG_SP); pop(ocb, REG_SP); pop(ocb, REG_EC); pop(ocb, REG_CFP); // Jump to the address returned by the // branch_stub_hit call jmp_rm(ocb, RAX); return stub_addr; } void gen_branch( const ctx_t* src_ctx, blockid_t target0, const ctx_t* ctx0, blockid_t target1, const ctx_t* ctx1, branchgen_fn gen_fn ) { RUBY_ASSERT(target0.iseq != NULL); //RUBY_ASSERT(target1.iseq != NULL); RUBY_ASSERT(num_branches < MAX_BRANCHES); uint32_t branch_idx = num_branches++; // Get the branch targets or stubs uint8_t* dst_addr0 = get_branch_target(target0, ctx0, branch_idx, 0); uint8_t* dst_addr1 = ctx1? get_branch_target(target1, ctx1, branch_idx, 1):NULL; // Call the branch generation function uint32_t start_pos = cb->write_pos; gen_fn(cb, dst_addr0, dst_addr1, SHAPE_DEFAULT); uint32_t end_pos = cb->write_pos; // Register this branch entry branch_t branch_entry = { start_pos, end_pos, *src_ctx, { target0, target1 }, { *ctx0, ctx1? *ctx1:DEFAULT_CTX }, { dst_addr0, dst_addr1 }, gen_fn, SHAPE_DEFAULT }; branch_entries[branch_idx] = branch_entry; } void gen_jump_branch(codeblock_t* cb, uint8_t* target0, uint8_t* target1, uint8_t shape) { switch (shape) { case SHAPE_NEXT0: break; case SHAPE_NEXT1: RUBY_ASSERT(false); break; case SHAPE_DEFAULT: jmp_ptr(cb, target0); break; } } void gen_direct_jump( const ctx_t* ctx, blockid_t target0 ) { RUBY_ASSERT(target0.iseq != NULL); RUBY_ASSERT(num_branches < MAX_BRANCHES); uint32_t branch_idx = num_branches++; // Branch targets or stub adddress uint8_t* dst_addr0; // Shape of the branch uint8_t branch_shape; // Branch start and end positions uint32_t start_pos; uint32_t end_pos; // Limit the number of block versions ctx_t generic_ctx = DEFAULT_CTX; generic_ctx.stack_size = ctx->stack_size; generic_ctx.sp_offset = ctx->sp_offset; if (get_num_versions(target0) >= MAX_VERSIONS - 1) { //fprintf(stderr, "version limit hit in gen_direct_jump\n"); ctx = &generic_ctx; } block_t* p_block = find_block_version(target0, ctx); // If the version already exists if (p_block) { rb_darray_append(&p_block->incoming, branch_idx); dst_addr0 = cb_get_ptr(cb, p_block->start_pos); branch_shape = SHAPE_DEFAULT; // Call the branch generation function start_pos = cb->write_pos; gen_jump_branch(cb, dst_addr0, NULL, branch_shape); end_pos = cb->write_pos; } else { // The target block will follow next // It will be compiled in gen_block_version() dst_addr0 = NULL; branch_shape = SHAPE_NEXT0; start_pos = cb->write_pos; end_pos = cb->write_pos; } // Register this branch entry branch_t branch_entry = { start_pos, end_pos, *ctx, { target0, BLOCKID_NULL }, { *ctx, *ctx }, { dst_addr0, NULL }, gen_jump_branch, branch_shape }; branch_entries[branch_idx] = branch_entry; } // Create a stub to force the code up to this point to be executed void defer_compilation( block_t* block, uint32_t insn_idx, ctx_t* cur_ctx ) { //fprintf(stderr, "defer compilation at (%p, %d) depth=%d\n", block->blockid.iseq, insn_idx, cur_ctx->chain_depth); if (cur_ctx->chain_depth != 0) { rb_backtrace(); exit(1); } ctx_t next_ctx = *cur_ctx; if (next_ctx.chain_depth >= UINT8_MAX) { rb_bug("max block version chain depth reached"); } next_ctx.chain_depth += 1; RUBY_ASSERT(num_branches < MAX_BRANCHES); uint32_t branch_idx = num_branches++; // Get the branch targets or stubs blockid_t target0 = (blockid_t){ block->blockid.iseq, insn_idx }; uint8_t* dst_addr0 = get_branch_target(target0, &next_ctx, branch_idx, 0); // Call the branch generation function uint32_t start_pos = cb->write_pos; gen_jump_branch(cb, dst_addr0, NULL, SHAPE_DEFAULT); uint32_t end_pos = cb->write_pos; // Register this branch entry branch_t branch_entry = { start_pos, end_pos, *cur_ctx, { target0, BLOCKID_NULL }, { next_ctx, next_ctx }, { dst_addr0, NULL }, gen_jump_branch, SHAPE_DEFAULT }; branch_entries[branch_idx] = branch_entry; } // Remove all references to a block then free it. void yjit_free_block(block_t *block) { yjit_unlink_method_lookup_dependency(block); yjit_block_assumptions_free(block); rb_darray_free(block->incoming); rb_darray_free(block->gc_object_offsets); free(block); } // Remove a block version without reordering the version array static bool block_array_remove(rb_yjit_block_array_t block_array, block_t *block) { bool after_target = false; block_t **element; rb_darray_foreach(block_array, idx, element) { if (after_target) { rb_darray_set(block_array, idx - 1, *element); } else if (*element == block) { after_target = true; } } if (after_target) rb_darray_pop_back(block_array); return after_target; } // Invalidate one specific block version void invalidate_block_version(block_t* block) { const rb_iseq_t *iseq = block->blockid.iseq; // fprintf(stderr, "invalidating block (%p, %d)\n", block->blockid.iseq, block->blockid.idx); // fprintf(stderr, "block=%p\n", block); // Remove this block from the version array rb_yjit_block_array_t versions = get_version_array(iseq, block->blockid.idx); RB_UNUSED_VAR(bool removed); removed = block_array_remove(versions, block); RUBY_ASSERT(removed); // Get a pointer to the generated code for this block uint8_t* code_ptr = cb_get_ptr(cb, block->start_pos); // For each incoming branch uint32_t* branch_idx; rb_darray_foreach(block->incoming, i, branch_idx) { //uint32_t branch_idx = block->incoming[i]; branch_t* branch = &branch_entries[*branch_idx]; uint32_t target_idx = (branch->dst_addrs[0] == code_ptr)? 0:1; //fprintf(stderr, "branch_idx=%d, target_idx=%d\n", branch_idx, target_idx); //fprintf(stderr, "blockid.iseq=%p, blockid.idx=%d\n", block->blockid.iseq, block->blockid.idx); // Create a stub for this branch target branch->dst_addrs[target_idx] = get_branch_target( block->blockid, &block->ctx, *branch_idx, target_idx ); // Check if the invalidated block immediately follows bool target_next = block->start_pos == branch->end_pos; if (target_next) { // The new block will no longer be adjacent branch->shape = SHAPE_DEFAULT; } // Rewrite the branch with the new jump target address RUBY_ASSERT(branch->dst_addrs[0] != NULL); uint32_t cur_pos = cb->write_pos; cb_set_pos(cb, branch->start_pos); branch->gen_fn(cb, branch->dst_addrs[0], branch->dst_addrs[1], branch->shape); branch->end_pos = cb->write_pos; cb_set_pos(cb, cur_pos); if (target_next && branch->end_pos > block->end_pos) { rb_bug("yjit invalidate rewrote branch past block end"); } } uint32_t idx = block->blockid.idx; // FIXME: the following says "if", but it's unconditional. // If the block is an entry point, it needs to be unmapped from its iseq VALUE* entry_pc = iseq_pc_at_idx(iseq, idx); int entry_opcode = opcode_at_pc(iseq, entry_pc); // TODO: unmap_addr2insn in yjit_iface.c? Maybe we can write a function to encompass this logic? // Should check how it's used in exit and side-exit const void * const *handler_table = rb_vm_get_insns_address_table(); void* handler_addr = (void*)handler_table[entry_opcode]; iseq->body->iseq_encoded[idx] = (VALUE)handler_addr; // TODO: // May want to recompile a new entry point (for interpreter entry blocks) // This isn't necessary for correctness // FIXME: // Call continuation addresses on the stack can also be atomically replaced by jumps going to the stub. yjit_free_block(block); // fprintf(stderr, "invalidation done\n"); } void yjit_init_core(void) { // Nothing yet }