return code [0] == 0xe8;
}
+#ifdef __native_client_codegen__
+
+/* Keep track of instruction "depth", that is, the level of sub-instruction */
+/* for any given instruction. For instance, amd64_call_reg resolves to */
+/* amd64_call_reg_internal, which uses amd64_alu_* macros, etc. */
+/* We only want to force bundle alignment for the top level instruction, */
+/* so NaCl pseudo-instructions can be implemented with sub instructions. */
+static guint32 nacl_instruction_depth;
+
+static guint32 nacl_rex_tag;
+static guint32 nacl_legacy_prefix_tag;
+
+void
+amd64_nacl_clear_legacy_prefix_tag ()
+{
+ TlsSetValue (nacl_legacy_prefix_tag, NULL);
+}
+
+void
+amd64_nacl_tag_legacy_prefix (guint8* code)
+{
+ if (TlsGetValue (nacl_legacy_prefix_tag) == NULL)
+ TlsSetValue (nacl_legacy_prefix_tag, code);
+}
+
+void
+amd64_nacl_tag_rex (guint8* code)
+{
+ TlsSetValue (nacl_rex_tag, code);
+}
+
+guint8*
+amd64_nacl_get_legacy_prefix_tag ()
+{
+ return (guint8*)TlsGetValue (nacl_legacy_prefix_tag);
+}
+
+guint8*
+amd64_nacl_get_rex_tag ()
+{
+ return (guint8*)TlsGetValue (nacl_rex_tag);
+}
+
+/* Increment the instruction "depth" described above */
+void
+amd64_nacl_instruction_pre ()
+{
+ intptr_t depth = (intptr_t) TlsGetValue (nacl_instruction_depth);
+ depth++;
+ TlsSetValue (nacl_instruction_depth, (gpointer)depth);
+}
+
+/* amd64_nacl_instruction_post: Decrement instruction "depth", force bundle */
+/* alignment if depth == 0 (top level instruction) */
+/* IN: start, end pointers to instruction beginning and end */
+/* OUT: start, end pointers to beginning and end after possible alignment */
+/* GLOBALS: nacl_instruction_depth defined above */
+void
+amd64_nacl_instruction_post (guint8 **start, guint8 **end)
+{
+ intptr_t depth = (intptr_t) TlsGetValue(nacl_instruction_depth);
+ depth--;
+ TlsSetValue (nacl_instruction_depth, (void*)depth);
+
+ g_assert ( depth >= 0 );
+ if (depth == 0) {
+ uintptr_t space_in_block;
+ uintptr_t instlen;
+ guint8 *prefix = amd64_nacl_get_legacy_prefix_tag ();
+ /* if legacy prefix is present, and if it was emitted before */
+ /* the start of the instruction sequence, adjust the start */
+ if (prefix != NULL && prefix < *start) {
+ g_assert (*start - prefix <= 3);/* only 3 are allowed */
+ *start = prefix;
+ }
+ space_in_block = kNaClAlignment - ((uintptr_t)(*start) & kNaClAlignmentMask);
+ instlen = (uintptr_t)(*end - *start);
+ /* Only check for instructions which are less than */
+ /* kNaClAlignment. The only instructions that should ever */
+ /* be that long are call sequences, which are already */
+ /* padded out to align the return to the next bundle. */
+ if (instlen > space_in_block && instlen < kNaClAlignment) {
+ const size_t MAX_NACL_INST_LENGTH = kNaClAlignment;
+ guint8 copy_of_instruction[MAX_NACL_INST_LENGTH];
+ const size_t length = (size_t)((*end)-(*start));
+ g_assert (length < MAX_NACL_INST_LENGTH);
+
+ memcpy (copy_of_instruction, *start, length);
+ *start = mono_arch_nacl_pad (*start, space_in_block);
+ memcpy (*start, copy_of_instruction, length);
+ *end = *start + length;
+ }
+ amd64_nacl_clear_legacy_prefix_tag ();
+ amd64_nacl_tag_rex (NULL);
+ }
+}
+
+/* amd64_nacl_membase_handler: ensure all access to memory of the form */
+/* OFFSET(%rXX) is sandboxed. For allowable base registers %rip, %rbp, */
+/* %rsp, and %r15, emit the membase as usual. For all other registers, */
+/* make sure the upper 32-bits are cleared, and use that register in the */
+/* index field of a new address of this form: OFFSET(%r15,%eXX,1) */
+/* IN: code */
+/* pointer to current instruction stream (in the */
+/* middle of an instruction, after opcode is emitted) */
+/* basereg/offset/dreg */
+/* operands of normal membase address */
+/* OUT: code */
+/* pointer to the end of the membase/memindex emit */
+/* GLOBALS: nacl_rex_tag */
+/* position in instruction stream that rex prefix was emitted */
+/* nacl_legacy_prefix_tag */
+/* (possibly NULL) position in instruction of legacy x86 prefix */
+void
+amd64_nacl_membase_handler (guint8** code, gint8 basereg, gint32 offset, gint8 dreg)
+{
+ gint8 true_basereg = basereg;
+
+ /* Cache these values, they might change */
+ /* as new instructions are emitted below. */
+ guint8* rex_tag = amd64_nacl_get_rex_tag ();
+ guint8* legacy_prefix_tag = amd64_nacl_get_legacy_prefix_tag ();
+
+ /* 'basereg' is given masked to 0x7 at this point, so check */
+ /* the rex prefix to see if this is an extended register. */
+ if ((rex_tag != NULL) && IS_REX(*rex_tag) && (*rex_tag & AMD64_REX_B)) {
+ true_basereg |= 0x8;
+ }
+
+#define X86_LEA_OPCODE (0x8D)
+
+ if (!amd64_is_valid_nacl_base (true_basereg) && (*(*code-1) != X86_LEA_OPCODE)) {
+ guint8* old_instruction_start;
+
+ /* This will hold the 'mov %eXX, %eXX' that clears the upper */
+ /* 32-bits of the old base register (new index register) */
+ guint8 buf[32];
+ guint8* buf_ptr = buf;
+ size_t insert_len;
+
+ g_assert (rex_tag != NULL);
+
+ if (IS_REX(*rex_tag)) {
+ /* The old rex.B should be the new rex.X */
+ if (*rex_tag & AMD64_REX_B) {
+ *rex_tag |= AMD64_REX_X;
+ }
+ /* Since our new base is %r15 set rex.B */
+ *rex_tag |= AMD64_REX_B;
+ } else {
+ /* Shift the instruction by one byte */
+ /* so we can insert a rex prefix */
+ memmove (rex_tag + 1, rex_tag, (size_t)(*code - rex_tag));
+ *code += 1;
+ /* New rex prefix only needs rex.B for %r15 base */
+ *rex_tag = AMD64_REX(AMD64_REX_B);
+ }
+
+ if (legacy_prefix_tag) {
+ old_instruction_start = legacy_prefix_tag;
+ } else {
+ old_instruction_start = rex_tag;
+ }
+
+ /* Clears the upper 32-bits of the previous base register */
+ amd64_mov_reg_reg_size (buf_ptr, true_basereg, true_basereg, 4);
+ insert_len = buf_ptr - buf;
+
+ /* Move the old instruction forward to make */
+ /* room for 'mov' stored in 'buf_ptr' */
+ memmove (old_instruction_start + insert_len, old_instruction_start, (size_t)(*code - old_instruction_start));
+ *code += insert_len;
+ memcpy (old_instruction_start, buf, insert_len);
+
+ /* Sandboxed replacement for the normal membase_emit */
+ x86_memindex_emit (*code, dreg, AMD64_R15, offset, basereg, 0);
+
+ } else {
+ /* Normal default behavior, emit membase memory location */
+ x86_membase_emit_body (*code, dreg, basereg, offset);
+ }
+}
+
+
+static inline unsigned char*
+amd64_skip_nops (unsigned char* code)
+{
+ guint8 in_nop;
+ do {
+ in_nop = 0;
+ if ( code[0] == 0x90) {
+ in_nop = 1;
+ code += 1;
+ }
+ if ( code[0] == 0x66 && code[1] == 0x90) {
+ in_nop = 1;
+ code += 2;
+ }
+ if (code[0] == 0x0f && code[1] == 0x1f
+ && code[2] == 0x00) {
+ in_nop = 1;
+ code += 3;
+ }
+ if (code[0] == 0x0f && code[1] == 0x1f
+ && code[2] == 0x40 && code[3] == 0x00) {
+ in_nop = 1;
+ code += 4;
+ }
+ if (code[0] == 0x0f && code[1] == 0x1f
+ && code[2] == 0x44 && code[3] == 0x00
+ && code[4] == 0x00) {
+ in_nop = 1;
+ code += 5;
+ }
+ if (code[0] == 0x66 && code[1] == 0x0f
+ && code[2] == 0x1f && code[3] == 0x44
+ && code[4] == 0x00 && code[5] == 0x00) {
+ in_nop = 1;
+ code += 6;
+ }
+ if (code[0] == 0x0f && code[1] == 0x1f
+ && code[2] == 0x80 && code[3] == 0x00
+ && code[4] == 0x00 && code[5] == 0x00
+ && code[6] == 0x00) {
+ in_nop = 1;
+ code += 7;
+ }
+ if (code[0] == 0x0f && code[1] == 0x1f
+ && code[2] == 0x84 && code[3] == 0x00
+ && code[4] == 0x00 && code[5] == 0x00
+ && code[6] == 0x00 && code[7] == 0x00) {
+ in_nop = 1;
+ code += 8;
+ }
+ } while ( in_nop );
+ return code;
+}
+
+guint8*
+mono_arch_nacl_skip_nops (guint8* code)
+{
+ return amd64_skip_nops(code);
+}
+
+#endif /*__native_client_codegen__*/
+
static inline void
amd64_patch (unsigned char* code, gpointer target)
{
guint8 rex = 0;
+#ifdef __native_client_codegen__
+ code = amd64_skip_nops (code);
+#endif
+#if defined(__native_client_codegen__) && defined(__native_client__)
+ if (nacl_is_code_address (code)) {
+ /* For tail calls, code is patched after being installed */
+ /* but not through the normal "patch callsite" method. */
+ unsigned char buf[kNaClAlignment];
+ unsigned char *aligned_code = (uintptr_t)code & ~kNaClAlignmentMask;
+ int ret;
+ memcpy (buf, aligned_code, kNaClAlignment);
+ /* Patch a temp buffer of bundle size, */
+ /* then install to actual location. */
+ amd64_patch (buf + ((uintptr_t)code - (uintptr_t)aligned_code), target);
+ ret = nacl_dyncode_modify (aligned_code, buf, kNaClAlignment);
+ g_assert (ret == 0);
+ return;
+ }
+ target = nacl_modify_patch_target (target);
+#endif
+
/* Skip REX */
if ((code [0] >= 0x40) && (code [0] <= 0x4f)) {
rex = code [0];
if (*gr >= PARAM_REGS) {
ainfo->storage = ArgOnStack;
- (*stack_size) += sizeof (gpointer);
+ /* Since the same stack slot size is used for all arg */
+ /* types, it needs to be big enough to hold them all */
+ (*stack_size) += sizeof(mgreg_t);
}
else {
ainfo->storage = ArgInIReg;
if (*gr >= FLOAT_PARAM_REGS) {
ainfo->storage = ArgOnStack;
- (*stack_size) += sizeof (gpointer);
+ /* Since the same stack slot size is used for both float */
+ /* types, it needs to be big enough to hold them both */
+ (*stack_size) += sizeof(mgreg_t);
}
else {
/* A double register */
return class1;
}
+#ifdef __native_client_codegen__
+const guint kNaClAlignment = kNaClAlignmentAMD64;
+const guint kNaClAlignmentMask = kNaClAlignmentMaskAMD64;
+
+/* Default alignment for Native Client is 32-byte. */
+gint8 nacl_align_byte = -32; /* signed version of 0xe0 */
+
+/* mono_arch_nacl_pad: Add pad bytes of alignment instructions at code, */
+/* Check that alignment doesn't cross an alignment boundary. */
+guint8*
+mono_arch_nacl_pad(guint8 *code, int pad)
+{
+ const int kMaxPadding = 8; /* see amd64-codegen.h:amd64_padding_size() */
+
+ if (pad == 0) return code;
+ /* assertion: alignment cannot cross a block boundary */
+ g_assert (((uintptr_t)code & (~kNaClAlignmentMask)) ==
+ (((uintptr_t)code + pad - 1) & (~kNaClAlignmentMask)));
+ while (pad >= kMaxPadding) {
+ amd64_padding (code, kMaxPadding);
+ pad -= kMaxPadding;
+ }
+ if (pad != 0) amd64_padding (code, pad);
+ return code;
+}
+#endif
static void
add_valuetype (MonoGenericSharingContext *gsctx, MonoMethodSignature *sig, ArgInfo *ainfo, MonoType *type,
guint32 *gr, guint32 *fr, guint32 *stack_size)
{
guint32 size, quad, nquads, i;
+ /* Keep track of the size used in each quad so we can */
+ /* use the right size when copying args/return vars. */
+ guint32 quadsize [2] = {8, 8};
ArgumentClass args [2];
MonoMarshalType *info = NULL;
MonoClass *klass;
}
#endif
+ /* If this struct can't be split up naturally into 8-byte */
+ /* chunks (registers), pass it on the stack. */
+ if (sig->pinvoke && !pass_on_stack) {
+ info = mono_marshal_load_type_info (klass);
+ g_assert(info);
+ guint32 align;
+ guint32 field_size;
+ for (i = 0; i < info->num_fields; ++i) {
+ field_size = mono_marshal_type_size (info->fields [i].field->type,
+ info->fields [i].mspec,
+ &align, TRUE, klass->unicode);
+ if ((info->fields [i].offset < 8) && (info->fields [i].offset + field_size) > 8) {
+ pass_on_stack = TRUE;
+ break;
+ }
+ }
+ }
+
if (pass_on_stack) {
/* Allways pass in memory */
ainfo->offset = *stack_size;
if ((quad == 1) && (info->fields [i].offset < 8))
continue;
+ /* How far into this quad this data extends.*/
+ /* (8 is size of quad) */
+ quadsize [quad] = info->fields [i].offset + size - (quad * 8);
+
class1 = merge_argument_class_from_type (info->fields [i].field->type, class1);
}
g_assert (class1 != ARG_CLASS_NO_CLASS);
if (*fr >= FLOAT_PARAM_REGS)
args [quad] = ARG_CLASS_MEMORY;
else {
- ainfo->pair_storage [quad] = ArgInDoubleSSEReg;
+ if (quadsize[quad] <= 4)
+ ainfo->pair_storage [quad] = ArgInFloatSSEReg;
+ else ainfo->pair_storage [quad] = ArgInDoubleSSEReg;
ainfo->pair_regs [quad] = *fr;
(*fr) ++;
}
if (sig->pinvoke)
*stack_size += ALIGN_TO (info->native_size, 8);
else
- *stack_size += nquads * sizeof (gpointer);
+ *stack_size += nquads * sizeof(mgreg_t);
ainfo->storage = ArgOnStack;
}
}
static int
cpuid (int id, int* p_eax, int* p_ebx, int* p_ecx, int* p_edx)
{
+#if defined(MONO_CROSS_COMPILE)
+ return 0;
+#else
#ifndef _MSC_VER
__asm__ __volatile__ ("cpuid"
: "=a" (*p_eax), "=b" (*p_ebx), "=c" (*p_ecx), "=d" (*p_edx)
*p_edx = info[3];
#endif
return 1;
+#endif
}
/*
int flags;
InitializeCriticalSection (&mini_arch_mutex);
+#if defined(__native_client_codegen__)
+ nacl_instruction_depth = TlsAlloc ();
+ TlsSetValue (nacl_instruction_depth, (gpointer)0);
+ nacl_rex_tag = TlsAlloc ();
+ nacl_legacy_prefix_tag = TlsAlloc ();
+#endif
#ifdef MONO_ARCH_NOMAP32BIT
flags = MONO_MMAP_READ;
mono_arch_cleanup (void)
{
DeleteCriticalSection (&mini_arch_mutex);
+#if defined(__native_client_codegen__)
+ TlsFree (nacl_instruction_depth);
+ TlsFree (nacl_rex_tag);
+ TlsFree (nacl_legacy_prefix_tag);
+#endif
}
/*
cfg->arch.omit_fp = TRUE;
cfg->arch.omit_fp_computed = TRUE;
+#ifdef __native_client_codegen__
+ /* NaCl modules may not change the value of RBP, so it cannot be */
+ /* used as a normal register, but it can be used as a frame pointer*/
+ cfg->disable_omit_fp = TRUE;
+ cfg->arch.omit_fp = FALSE;
+#endif
+
if (cfg->disable_omit_fp)
cfg->arch.omit_fp = FALSE;
regs = g_list_prepend (regs, (gpointer)AMD64_R12);
regs = g_list_prepend (regs, (gpointer)AMD64_R13);
regs = g_list_prepend (regs, (gpointer)AMD64_R14);
+#ifndef __native_client_codegen__
regs = g_list_prepend (regs, (gpointer)AMD64_R15);
+#endif
regs = g_list_prepend (regs, (gpointer)AMD64_R10);
regs = g_list_prepend (regs, (gpointer)AMD64_R9);
regs = g_list_prepend (regs, (gpointer)AMD64_R12);
regs = g_list_prepend (regs, (gpointer)AMD64_R13);
regs = g_list_prepend (regs, (gpointer)AMD64_R14);
+#ifndef __native_client_codegen__
regs = g_list_prepend (regs, (gpointer)AMD64_R15);
+#endif
#ifdef HOST_WIN32
regs = g_list_prepend (regs, (gpointer)AMD64_RDI);
regs = g_list_prepend (regs, (gpointer)AMD64_RSI);
regs = g_list_prepend (regs, (gpointer)AMD64_R12);
regs = g_list_prepend (regs, (gpointer)AMD64_R13);
regs = g_list_prepend (regs, (gpointer)AMD64_R14);
+#ifndef __native_client_codegen__
regs = g_list_prepend (regs, (gpointer)AMD64_R15);
+#endif
regs = g_list_prepend (regs, (gpointer)AMD64_R10);
regs = g_list_prepend (regs, (gpointer)AMD64_R9);
/* Reserve space for caller saved registers */
for (i = 0; i < AMD64_NREG; ++i)
if (AMD64_IS_CALLEE_SAVED_REG (i) && (cfg->used_int_regs & (1 << i))) {
- offset += sizeof (gpointer);
+ offset += sizeof(mgreg_t);
}
}
ins->opcode = OP_REGOFFSET;
ins->inst_basereg = cfg->frame_reg;
/* These arguments are saved to the stack in the prolog */
- offset = ALIGN_TO (offset, sizeof (gpointer));
+ offset = ALIGN_TO (offset, sizeof(mgreg_t));
if (cfg->arch.omit_fp) {
ins->inst_offset = offset;
- offset += (ainfo->storage == ArgValuetypeInReg) ? ainfo->nregs * sizeof (gpointer) : sizeof (gpointer);
+ offset += (ainfo->storage == ArgValuetypeInReg) ? ainfo->nregs * sizeof (mgreg_t) : sizeof (mgreg_t);
} else {
- offset += (ainfo->storage == ArgValuetypeInReg) ? ainfo->nregs * sizeof (gpointer) : sizeof (gpointer);
+ offset += (ainfo->storage == ArgValuetypeInReg) ? ainfo->nregs * sizeof (mgreg_t) : sizeof (mgreg_t);
ins->inst_offset = - offset;
}
break;
ins->opcode = OP_REGOFFSET;
ins->inst_basereg = cfg->frame_reg;
/* These arguments are saved to the stack in the prolog */
- offset = ALIGN_TO (offset, sizeof (gpointer));
+ offset = ALIGN_TO (offset, sizeof(mgreg_t));
if (cfg->arch.omit_fp) {
ins->inst_offset = offset;
- offset += (ainfo->storage == ArgValuetypeInReg) ? ainfo->nregs * sizeof (gpointer) : sizeof (gpointer);
+ offset += (ainfo->storage == ArgValuetypeInReg) ? ainfo->nregs * sizeof (mgreg_t) : sizeof (mgreg_t);
// Arguments are yet supported by the stack map creation code
//cfg->locals_max_stack_offset = MAX (cfg->locals_max_stack_offset, offset);
} else {
- offset += (ainfo->storage == ArgValuetypeInReg) ? ainfo->nregs * sizeof (gpointer) : sizeof (gpointer);
+ offset += (ainfo->storage == ArgValuetypeInReg) ? ainfo->nregs * sizeof (mgreg_t) : sizeof (mgreg_t);
ins->inst_offset = - offset;
//cfg->locals_min_stack_offset = MIN (cfg->locals_min_stack_offset, offset);
}
{
switch (storage) {
case ArgInIReg:
+#if defined(__mono_ilp32__)
+ return OP_LOADI8_MEMBASE;
+#else
return OP_LOAD_MEMBASE;
+#endif
case ArgInDoubleSSEReg:
return OP_LOADR8_MEMBASE;
case ArgInFloatSSEReg:
MONO_INST_NEW (cfg, load, arg_storage_to_load_membase (ainfo->pair_storage [part]));
load->inst_basereg = src->dreg;
- load->inst_offset = part * sizeof (gpointer);
+ load->inst_offset = part * sizeof(mgreg_t);
switch (ainfo->pair_storage [part]) {
case ArgInIReg:
g_free (ainfo);
}
+#if !defined(__native_client__)
+#define PTR_TO_GREG(ptr) (mgreg_t)(ptr)
+#define GREG_TO_PTR(greg) (gpointer)(greg)
+#else
+/* Correctly handle casts to/from 32-bit pointers without compiler warnings */
+#define PTR_TO_GREG(ptr) (mgreg_t)(uintptr_t)(ptr)
+#define GREG_TO_PTR(greg) (gpointer)(guint32)(greg)
+#endif
+
/*
* mono_arch_get_start_dyn_call:
*
pindex = 0;
if (sig->hasthis || dinfo->cinfo->vret_arg_index == 1) {
- p->regs [greg ++] = (mgreg_t)*(args [arg_index ++]);
+ p->regs [greg ++] = PTR_TO_GREG(*(args [arg_index ++]));
if (!sig->hasthis)
pindex = 1;
}
if (dinfo->cinfo->vtype_retaddr)
- p->regs [greg ++] = (mgreg_t)ret;
+ p->regs [greg ++] = PTR_TO_GREG(ret);
for (i = pindex; i < sig->param_count; i++) {
MonoType *t = mono_type_get_underlying_type (sig->params [i]);
gpointer *arg = args [arg_index ++];
if (t->byref) {
- p->regs [greg ++] = (mgreg_t)*(arg);
+ p->regs [greg ++] = PTR_TO_GREG(*(arg));
continue;
}
case MONO_TYPE_PTR:
case MONO_TYPE_I:
case MONO_TYPE_U:
+#if !defined(__mono_ilp32__)
case MONO_TYPE_I8:
case MONO_TYPE_U8:
+#endif
g_assert (dinfo->cinfo->args [i + sig->hasthis].reg == param_regs [greg]);
- p->regs [greg ++] = (mgreg_t)*(arg);
+ p->regs [greg ++] = PTR_TO_GREG(*(arg));
break;
+#if defined(__mono_ilp32__)
+ case MONO_TYPE_I8:
+ case MONO_TYPE_U8:
+ g_assert (dinfo->cinfo->args [i + sig->hasthis].reg == param_regs [greg]);
+ p->regs [greg ++] = *(guint64*)(arg);
+ break;
+#endif
case MONO_TYPE_BOOLEAN:
case MONO_TYPE_U1:
p->regs [greg ++] = *(guint8*)(arg);
break;
case MONO_TYPE_GENERICINST:
if (MONO_TYPE_IS_REFERENCE (t)) {
- p->regs [greg ++] = (mgreg_t)*(arg);
+ p->regs [greg ++] = PTR_TO_GREG(*(arg));
break;
} else {
/* Fall through */
case MONO_TYPE_I:
case MONO_TYPE_U:
case MONO_TYPE_PTR:
- *(gpointer*)ret = (gpointer)res;
+ *(gpointer*)ret = GREG_TO_PTR(res);
break;
case MONO_TYPE_I1:
*(gint8*)ret = res;
break;
case MONO_TYPE_GENERICINST:
if (MONO_TYPE_IS_REFERENCE (sig->ret)) {
- *(gpointer*)ret = (gpointer)res;
+ *(gpointer*)ret = GREG_TO_PTR(res);
break;
} else {
/* Fall through */
* not span cache lines. This is required for code patching to work on SMP
* systems.
*/
- if (!no_patch && ((guint32)(code + 1 - cfg->native_code) % 4) != 0)
- amd64_padding (code, 4 - ((guint32)(code + 1 - cfg->native_code) % 4));
+ if (!no_patch && ((guint32)(code + 1 - cfg->native_code) % 4) != 0) {
+ guint32 pad_size = 4 - ((guint32)(code + 1 - cfg->native_code) % 4);
+ amd64_padding (code, pad_size);
+ }
mono_add_patch_info (cfg, code - cfg->native_code, patch_type, data);
amd64_call_code (code, 0);
}
ins->sreg2 = temp->dreg;
}
break;
+#ifndef __mono_ilp32__
case OP_LOAD_MEMBASE:
+#endif
case OP_LOADI8_MEMBASE:
+#ifndef __native_client_codegen__
+ /* Don't generate memindex opcodes (to simplify */
+ /* read sandboxing) */
if (!amd64_is_imm32 (ins->inst_offset)) {
NEW_INS (cfg, ins, temp, OP_I8CONST);
temp->inst_c0 = ins->inst_offset;
ins->opcode = OP_AMD64_LOADI8_MEMINDEX;
ins->inst_indexreg = temp->dreg;
}
+#endif
break;
+#ifndef __mono_ilp32__
case OP_STORE_MEMBASE_IMM:
+#endif
case OP_STOREI8_MEMBASE_IMM:
if (!amd64_is_imm32 (ins->inst_imm)) {
NEW_INS (cfg, ins, temp, OP_I8CONST);
if (cfg->param_area && cfg->arch.no_pushes)
amd64_alu_reg_imm (code, X86_ADD, AMD64_RDI, cfg->param_area);
amd64_cld (code);
+#if defined(__default_codegen__)
+ amd64_prefix (code, X86_REP_PREFIX);
+ amd64_stosl (code);
+#elif defined(__native_client_codegen__)
+ /* NaCl stos pseudo-instruction */
+ amd64_codegen_pre(code);
+ /* First, clear the upper 32 bits of RDI (mov %edi, %edi) */
+ amd64_mov_reg_reg (code, AMD64_RDI, AMD64_RDI, 4);
+ /* Add %r15 to %rdi using lea, condition flags unaffected. */
+ amd64_lea_memindex_size (code, AMD64_RDI, AMD64_R15, 0, AMD64_RDI, 0, 8);
amd64_prefix (code, X86_REP_PREFIX);
amd64_stosl (code);
+ amd64_codegen_post(code);
+#endif /* __native_client_codegen__ */
if (tree->dreg != AMD64_RDI && sreg != AMD64_RDI)
amd64_pop_reg (code, AMD64_RDI);
/* Load the destination address */
g_assert (loc->opcode == OP_REGOFFSET);
- amd64_mov_reg_membase (code, AMD64_RCX, loc->inst_basereg, loc->inst_offset, 8);
+ amd64_mov_reg_membase (code, AMD64_RCX, loc->inst_basereg, loc->inst_offset, sizeof(gpointer));
for (quad = 0; quad < 2; quad ++) {
switch (cinfo->ret.pair_storage [quad]) {
case ArgInIReg:
- amd64_mov_membase_reg (code, AMD64_RCX, (quad * 8), cinfo->ret.pair_regs [quad], 8);
+ amd64_mov_membase_reg (code, AMD64_RCX, (quad * sizeof(mgreg_t)), cinfo->ret.pair_regs [quad], sizeof(mgreg_t));
break;
case ArgInFloatSSEReg:
amd64_movss_membase_reg (code, AMD64_RCX, (quad * 8), cinfo->ret.pair_regs [quad]);
#ifndef DISABLE_JIT
+#if defined(__native_client__) || defined(__native_client_codegen__)
+void mono_nacl_gc()
+{
+#ifdef __native_client_gc__
+ __nacl_suspend_thread_if_needed();
+#endif
+}
+#endif
+
void
mono_arch_output_basic_block (MonoCompile *cfg, MonoBasicBlock *bb)
{
}
}
+#if defined(__native_client_codegen__)
+ /* For Native Client, all indirect call/jump targets must be */
+ /* 32-byte aligned. Exception handler blocks are jumped to */
+ /* indirectly as well. */
+ gboolean bb_needs_alignment = (bb->flags & BB_INDIRECT_JUMP_TARGET) ||
+ (bb->flags & BB_EXCEPTION_HANDLER);
+
+ if ( bb_needs_alignment && ((cfg->code_len & kNaClAlignmentMask) != 0)) {
+ int pad = kNaClAlignment - (cfg->code_len & kNaClAlignmentMask);
+ if (pad != kNaClAlignment) code = mono_arch_nacl_pad(code, pad);
+ cfg->code_len += pad;
+ bb->native_offset = cfg->code_len;
+ }
+#endif /*__native_client_codegen__*/
+
if (cfg->verbose_level > 2)
g_print ("Basic block %d starting at offset 0x%x\n", bb->block_num, bb->native_offset);
max_len = ((guint8 *)ins_get_spec (ins->opcode))[MONO_INST_LEN];
- if (G_UNLIKELY (offset > (cfg->code_size - max_len - 16))) {
+#define EXTRA_CODE_SPACE (NACL_SIZE (16, 16 + kNaClAlignment))
+
+ if (G_UNLIKELY (offset > (cfg->code_size - max_len - EXTRA_CODE_SPACE))) {
cfg->code_size *= 2;
- cfg->native_code = g_realloc (cfg->native_code, cfg->code_size);
+ cfg->native_code = mono_realloc_native_code(cfg);
code = cfg->native_code + offset;
mono_jit_stats.code_reallocs++;
}
case OP_STOREI2_MEMBASE_REG:
amd64_mov_membase_reg (code, ins->inst_destbasereg, ins->inst_offset, ins->sreg1, 2);
break;
+ /* In AMD64 NaCl, pointers are 4 bytes, */
+ /* so STORE_* != STOREI8_*. Likewise below. */
case OP_STORE_MEMBASE_REG:
+ amd64_mov_membase_reg (code, ins->inst_destbasereg, ins->inst_offset, ins->sreg1, sizeof(gpointer));
+ break;
case OP_STOREI8_MEMBASE_REG:
amd64_mov_membase_reg (code, ins->inst_destbasereg, ins->inst_offset, ins->sreg1, 8);
break;
amd64_mov_membase_reg (code, ins->inst_destbasereg, ins->inst_offset, ins->sreg1, 4);
break;
case OP_STORE_MEMBASE_IMM:
+#ifndef __native_client_codegen__
+ /* In NaCl, this could be a PCONST type, which could */
+ /* mean a pointer type was copied directly into the */
+ /* lower 32-bits of inst_imm, so for InvalidPtr==-1 */
+ /* the value would be 0x00000000FFFFFFFF which is */
+ /* not proper for an imm32 unless you cast it. */
+ g_assert (amd64_is_imm32 (ins->inst_imm));
+#endif
+ amd64_mov_membase_imm (code, ins->inst_destbasereg, ins->inst_offset, (gint32)ins->inst_imm, sizeof(gpointer));
+ break;
case OP_STOREI8_MEMBASE_IMM:
g_assert (amd64_is_imm32 (ins->inst_imm));
amd64_mov_membase_imm (code, ins->inst_destbasereg, ins->inst_offset, ins->inst_imm, 8);
break;
case OP_LOAD_MEM:
+#ifdef __mono_ilp32__
+ /* In ILP32, pointers are 4 bytes, so separate these */
+ /* cases, use literal 8 below where we really want 8 */
+ amd64_mov_reg_imm (code, ins->dreg, ins->inst_imm);
+ amd64_mov_reg_membase (code, ins->dreg, ins->dreg, 0, sizeof(gpointer));
+ break;
+#endif
case OP_LOADI8_MEM:
// FIXME: Decompose this earlier
if (amd64_is_imm32 (ins->inst_imm))
- amd64_mov_reg_mem (code, ins->dreg, ins->inst_imm, sizeof (gpointer));
+ amd64_mov_reg_mem (code, ins->dreg, ins->inst_imm, 8);
else {
amd64_mov_reg_imm (code, ins->dreg, ins->inst_imm);
amd64_mov_reg_membase (code, ins->dreg, ins->dreg, 0, 8);
amd64_widen_membase (code, ins->dreg, ins->dreg, 0, FALSE, FALSE);
break;
case OP_LOADU2_MEM:
+ /* For NaCl, pointers are 4 bytes, so separate these */
+ /* cases, use literal 8 below where we really want 8 */
amd64_mov_reg_imm (code, ins->dreg, ins->inst_imm);
amd64_widen_membase (code, ins->dreg, ins->dreg, 0, FALSE, TRUE);
break;
case OP_LOAD_MEMBASE:
+ g_assert (amd64_is_imm32 (ins->inst_offset));
+ amd64_mov_reg_membase (code, ins->dreg, ins->inst_basereg, ins->inst_offset, sizeof(gpointer));
+ break;
case OP_LOADI8_MEMBASE:
+ /* Use literal 8 instead of sizeof pointer or */
+ /* register, we really want 8 for this opcode */
g_assert (amd64_is_imm32 (ins->inst_offset));
- amd64_mov_reg_membase (code, ins->dreg, ins->inst_basereg, ins->inst_offset, sizeof (gpointer));
+ amd64_mov_reg_membase (code, ins->dreg, ins->inst_basereg, ins->inst_offset, 8);
break;
case OP_LOADI4_MEMBASE:
amd64_movsxd_reg_membase (code, ins->dreg, ins->inst_basereg, ins->inst_offset);
break;
case OP_AOTCONST:
mono_add_patch_info (cfg, offset, (MonoJumpInfoType)ins->inst_i1, ins->inst_p0);
- amd64_mov_reg_membase (code, ins->dreg, AMD64_RIP, 0, 8);
+ amd64_mov_reg_membase (code, ins->dreg, AMD64_RIP, 0, sizeof(gpointer));
break;
case OP_JUMP_TABLE:
mono_add_patch_info (cfg, offset, (MonoJumpInfoType)ins->inst_i1, ins->inst_p0);
amd64_mov_reg_imm_size (code, ins->dreg, 0, 8);
break;
case OP_MOVE:
- amd64_mov_reg_reg (code, ins->dreg, ins->sreg1, sizeof (gpointer));
+ amd64_mov_reg_reg (code, ins->dreg, ins->sreg1, sizeof(mgreg_t));
break;
case OP_AMD64_SET_XMMREG_R4: {
amd64_sse_cvtsd2ss_reg_reg (code, ins->dreg, ins->sreg1);
else {
for (i = 0; i < AMD64_NREG; ++i)
if (AMD64_IS_CALLEE_SAVED_REG (i) && (cfg->used_int_regs & (1 << i)))
- pos -= sizeof (gpointer);
+ pos -= sizeof(mgreg_t);
/* Restore callee-saved registers */
for (i = AMD64_NREG - 1; i > 0; --i) {
if (AMD64_IS_CALLEE_SAVED_REG (i) && (cfg->used_int_regs & (1 << i))) {
- amd64_mov_reg_membase (code, i, AMD64_RBP, pos, 8);
- pos += 8;
+ amd64_mov_reg_membase (code, i, AMD64_RBP, pos, sizeof(mgreg_t));
+ pos += sizeof(mgreg_t);
}
}
/* Copy arguments on the stack to our argument area */
- for (i = 0; i < call->stack_usage; i += 8) {
- amd64_mov_reg_membase (code, AMD64_RAX, AMD64_RSP, i, 8);
- amd64_mov_membase_reg (code, AMD64_RBP, 16 + i, AMD64_RAX, 8);
+ for (i = 0; i < call->stack_usage; i += sizeof(mgreg_t)) {
+ amd64_mov_reg_membase (code, AMD64_RAX, AMD64_RSP, i, sizeof(mgreg_t));
+ amd64_mov_membase_reg (code, AMD64_RBP, 16 + i, AMD64_RAX, sizeof(mgreg_t));
}
if (pos)
break;
case OP_ARGLIST: {
amd64_lea_membase (code, AMD64_R11, cfg->frame_reg, cfg->sig_cookie);
- amd64_mov_membase_reg (code, ins->sreg1, 0, AMD64_R11, 8);
+ amd64_mov_membase_reg (code, ins->sreg1, 0, AMD64_R11, sizeof(gpointer));
break;
}
case OP_CALL:
/* Set argument registers */
for (i = 0; i < PARAM_REGS; ++i)
- amd64_mov_reg_membase (code, param_regs [i], AMD64_R11, i * sizeof (gpointer), 8);
+ amd64_mov_reg_membase (code, param_regs [i], AMD64_R11, i * sizeof(mgreg_t), sizeof(mgreg_t));
/* Make the call */
amd64_call_reg (code, AMD64_R10);
amd64_alu_reg_imm (code, X86_ADD, AMD64_RSP, 8);
break;
case OP_START_HANDLER: {
+ /* Even though we're saving RSP, use sizeof */
+ /* gpointer because spvar is of type IntPtr */
+ /* see: mono_create_spvar_for_region */
MonoInst *spvar = mono_find_spvar_for_region (cfg, bb->region);
- amd64_mov_membase_reg (code, spvar->inst_basereg, spvar->inst_offset, AMD64_RSP, 8);
+ amd64_mov_membase_reg (code, spvar->inst_basereg, spvar->inst_offset, AMD64_RSP, sizeof(gpointer));
if ((MONO_BBLOCK_IS_IN_REGION (bb, MONO_REGION_FINALLY) ||
MONO_BBLOCK_IS_IN_REGION (bb, MONO_REGION_FINALLY)) &&
}
case OP_ENDFINALLY: {
MonoInst *spvar = mono_find_spvar_for_region (cfg, bb->region);
- amd64_mov_reg_membase (code, AMD64_RSP, spvar->inst_basereg, spvar->inst_offset, 8);
+ amd64_mov_reg_membase (code, AMD64_RSP, spvar->inst_basereg, spvar->inst_offset, sizeof(gpointer));
amd64_ret (code);
break;
}
case OP_ENDFILTER: {
MonoInst *spvar = mono_find_spvar_for_region (cfg, bb->region);
- amd64_mov_reg_membase (code, AMD64_RSP, spvar->inst_basereg, spvar->inst_offset, 8);
+ amd64_mov_reg_membase (code, AMD64_RSP, spvar->inst_basereg, spvar->inst_offset, sizeof(gpointer));
/* The local allocator will put the result into RAX */
amd64_ret (code);
break;
MONO_VARINFO (cfg, ins->inst_c0)->live_range_end = code - cfg->native_code;
break;
}
+ case OP_NACL_GC_SAFE_POINT: {
+#if defined(__native_client_codegen__)
+ code = emit_call (cfg, code, MONO_PATCH_INFO_ABS, (gpointer)mono_nacl_gc, TRUE);
+#endif
+ break;
+ }
case OP_GC_LIVENESS_DEF:
case OP_GC_LIVENESS_USE:
case OP_GC_PARAM_SLOT_LIVENESS_DEF:
}
if ((code - cfg->native_code - offset) > max_len) {
+#if !defined(__native_client_codegen__)
g_warning ("wrong maximal instruction length of instruction %s (expected %d, got %ld)",
mono_inst_name (ins->opcode), max_len, code - cfg->native_code - offset);
g_assert_not_reached ();
+#endif
}
last_ins = ins;
gint32 lmf_offset = cfg->arch.lmf_offset;
gboolean args_clobbered = FALSE;
gboolean trace = FALSE;
+#ifdef __native_client_codegen__
+ guint alignment_check;
+#endif
cfg->code_size = MAX (cfg->header->code_size * 4, 10240);
+#if defined(__default_codegen__)
code = cfg->native_code = g_malloc (cfg->code_size);
+#elif defined(__native_client_codegen__)
+ /* native_code_alloc is not 32-byte aligned, native_code is. */
+ cfg->native_code_alloc = g_malloc (cfg->code_size + kNaClAlignment);
+
+ /* Align native_code to next nearest kNaclAlignment byte. */
+ cfg->native_code = (uintptr_t)cfg->native_code_alloc + kNaClAlignment;
+ cfg->native_code = (uintptr_t)cfg->native_code & ~kNaClAlignmentMask;
+
+ code = cfg->native_code;
+
+ alignment_check = (guint)cfg->native_code & kNaClAlignmentMask;
+ g_assert (alignment_check == 0);
+#endif
if (mono_jit_trace_calls != NULL && mono_trace_eval (method))
trace = TRUE;
/* These are handled automatically by the stack marking code */
mini_gc_set_slot_type_from_cfa (cfg, -cfa_offset, SLOT_NOREF);
- amd64_mov_reg_reg (code, AMD64_RBP, AMD64_RSP, sizeof (gpointer));
+ amd64_mov_reg_reg (code, AMD64_RBP, AMD64_RSP, sizeof(mgreg_t));
mono_emit_unwind_op_def_cfa_reg (cfg, code, AMD64_RBP);
async_exc_point (code);
#ifdef HOST_WIN32
for (i = 0; i < AMD64_NREG; ++i)
if (AMD64_IS_CALLEE_SAVED_REG (i) && (cfg->used_int_regs & (1 << i))) {
amd64_push_reg (code, i);
- pos += sizeof (gpointer);
+ pos += 8; /* AMD64 push inst is always 8 bytes, no way to change it */
offset += 8;
mono_emit_unwind_op_offset (cfg, code, i, - offset);
async_exc_point (code);
if (cfg->arch.omit_fp)
// FIXME:
g_assert_not_reached ();
- cfg->stack_offset += ALIGN_TO (cfg->param_area, sizeof (gpointer));
+ cfg->stack_offset += ALIGN_TO (cfg->param_area, sizeof(mgreg_t));
}
if (cfg->arch.omit_fp) {
if (G_UNLIKELY (required_code_size >= (cfg->code_size - offset))) {
while (required_code_size >= (cfg->code_size - offset))
cfg->code_size *= 2;
- cfg->native_code = g_realloc (cfg->native_code, cfg->code_size);
+ cfg->native_code = mono_realloc_native_code (cfg);
code = cfg->native_code + offset;
mono_jit_stats.code_reallocs++;
}
amd64_mov_reg_reg (code, AMD64_RDI, AMD64_RSP, 8);
amd64_cld (code);
+#if defined(__default_codegen__)
+ amd64_prefix (code, X86_REP_PREFIX);
+ amd64_stosl (code);
+#elif defined(__native_client_codegen__)
+ /* NaCl stos pseudo-instruction */
+ amd64_codegen_pre (code);
+ /* First, clear the upper 32 bits of RDI (mov %edi, %edi) */
+ amd64_mov_reg_reg (code, AMD64_RDI, AMD64_RDI, 4);
+ /* Add %r15 to %rdi using lea, condition flags unaffected. */
+ amd64_lea_memindex_size (code, AMD64_RDI, AMD64_R15, 0, AMD64_RDI, 0, 8);
amd64_prefix (code, X86_REP_PREFIX);
amd64_stosl (code);
+ amd64_codegen_post (code);
+#endif /* __native_client_codegen__ */
amd64_mov_reg_membase (code, AMD64_RDI, AMD64_RSP, -8, 8);
amd64_mov_reg_membase (code, AMD64_RCX, AMD64_RSP, -16, 8);
case AMD64_R12: offset = G_STRUCT_OFFSET (MonoLMF, r12); break;
case AMD64_R13: offset = G_STRUCT_OFFSET (MonoLMF, r13); break;
case AMD64_R14: offset = G_STRUCT_OFFSET (MonoLMF, r14); break;
+#ifndef __native_client_codegen__
case AMD64_R15: offset = G_STRUCT_OFFSET (MonoLMF, r15); break;
+#endif
#ifdef HOST_WIN32
case AMD64_RDI: offset = G_STRUCT_OFFSET (MonoLMF, rdi); break;
case AMD64_RSI: offset = G_STRUCT_OFFSET (MonoLMF, rsi); break;
g_assert (cfg->rgctx_var->opcode == OP_REGOFFSET &&
(cfg->rgctx_var->inst_basereg == AMD64_RBP || cfg->rgctx_var->inst_basereg == AMD64_RSP));
- amd64_mov_membase_reg (code, cfg->rgctx_var->inst_basereg, cfg->rgctx_var->inst_offset, MONO_ARCH_RGCTX_REG, 8);
+ amd64_mov_membase_reg (code, cfg->rgctx_var->inst_basereg, cfg->rgctx_var->inst_offset, MONO_ARCH_RGCTX_REG, sizeof(gpointer));
}
/* compute max_length in order to use short forward jumps */
/* max alignment for loops */
if ((cfg->opt & MONO_OPT_LOOP) && bb_is_loop_start (bb))
max_length += LOOP_ALIGNMENT;
+#ifdef __native_client_codegen__
+ /* max alignment for native client */
+ max_length += kNaClAlignment;
+#endif
MONO_BB_FOR_EACH_INS (bb, ins) {
+#ifdef __native_client_codegen__
+ {
+ int space_in_block = kNaClAlignment -
+ ((max_length + cfg->code_len) & kNaClAlignmentMask);
+ int max_len = ((guint8 *)ins_get_spec (ins->opcode))[MONO_INST_LEN];
+ if (space_in_block < max_len && max_len < kNaClAlignment) {
+ max_length += space_in_block;
+ }
+ }
+#endif /*__native_client_codegen__*/
max_length += ((guint8 *)ins_get_spec (ins->opcode))[MONO_INST_LEN];
}
for (quad = 0; quad < 2; quad ++) {
switch (ainfo->pair_storage [quad]) {
case ArgInIReg:
- amd64_mov_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof (gpointer)), ainfo->pair_regs [quad], sizeof (gpointer));
+ amd64_mov_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof(mgreg_t)), ainfo->pair_regs [quad], sizeof(mgreg_t));
break;
case ArgInFloatSSEReg:
- amd64_movss_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof (gpointer)), ainfo->pair_regs [quad]);
+ amd64_movss_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof(mgreg_t)), ainfo->pair_regs [quad]);
break;
case ArgInDoubleSSEReg:
- amd64_movsd_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof (gpointer)), ainfo->pair_regs [quad]);
+ amd64_movsd_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof(mgreg_t)), ainfo->pair_regs [quad]);
break;
case ArgNone:
break;
for (quad = 0; quad < 2; quad ++) {
switch (ainfo->pair_storage [quad]) {
case ArgInIReg:
- amd64_mov_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof (gpointer)), ainfo->pair_regs [quad], sizeof (gpointer));
+ amd64_mov_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof(mgreg_t)), ainfo->pair_regs [quad], sizeof(mgreg_t));
break;
case ArgInFloatSSEReg:
- amd64_movss_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof (gpointer)), ainfo->pair_regs [quad]);
+ amd64_movss_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof(mgreg_t)), ainfo->pair_regs [quad]);
break;
case ArgInDoubleSSEReg:
- amd64_movsd_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof (gpointer)), ainfo->pair_regs [quad]);
+ amd64_movsd_membase_reg (code, ins->inst_basereg, ins->inst_offset + (quad * sizeof(mgreg_t)), ainfo->pair_regs [quad]);
break;
case ArgNone:
break;
}
/* Save lmf_addr */
- amd64_mov_membase_reg (code, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, lmf_addr), AMD64_RAX, 8);
+ amd64_mov_membase_reg (code, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, lmf_addr), AMD64_RAX, sizeof(gpointer));
/* Save previous_lmf */
- amd64_mov_reg_membase (code, AMD64_R11, AMD64_RAX, 0, 8);
- amd64_mov_membase_reg (code, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, previous_lmf), AMD64_R11, 8);
+ amd64_mov_reg_membase (code, AMD64_R11, AMD64_RAX, 0, sizeof(gpointer));
+ amd64_mov_membase_reg (code, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, previous_lmf), AMD64_R11, sizeof(gpointer));
/* Set new lmf */
amd64_lea_membase (code, AMD64_R11, cfg->frame_reg, lmf_offset);
- amd64_mov_membase_reg (code, AMD64_RAX, 0, AMD64_R11, 8);
+ amd64_mov_membase_reg (code, AMD64_RAX, 0, AMD64_R11, sizeof(gpointer));
}
}
while (cfg->code_len + max_epilog_size > (cfg->code_size - 16)) {
cfg->code_size *= 2;
- cfg->native_code = g_realloc (cfg->native_code, cfg->code_size);
+ cfg->native_code = mono_realloc_native_code (cfg);
mono_jit_stats.code_reallocs++;
}
* through the mono_lmf_addr TLS variable.
*/
/* reg = previous_lmf */
- amd64_mov_reg_membase (code, AMD64_R11, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, previous_lmf), 8);
+ amd64_mov_reg_membase (code, AMD64_R11, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, previous_lmf), sizeof(gpointer));
x86_prefix (code, X86_FS_PREFIX);
amd64_mov_mem_reg (code, lmf_tls_offset, AMD64_R11, 8);
} else {
/* Restore previous lmf */
- amd64_mov_reg_membase (code, AMD64_RCX, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, previous_lmf), 8);
- amd64_mov_reg_membase (code, AMD64_R11, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, lmf_addr), 8);
- amd64_mov_membase_reg (code, AMD64_R11, 0, AMD64_RCX, 8);
+ amd64_mov_reg_membase (code, AMD64_RCX, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, previous_lmf), sizeof(gpointer));
+ amd64_mov_reg_membase (code, AMD64_R11, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, lmf_addr), sizeof(gpointer));
+ amd64_mov_membase_reg (code, AMD64_R11, 0, AMD64_RCX, sizeof(gpointer));
}
/* Restore caller saved regs */
amd64_mov_reg_membase (code, AMD64_R14, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, r14), 8);
}
if (cfg->used_int_regs & (1 << AMD64_R15)) {
+#if defined(__default_codegen__)
amd64_mov_reg_membase (code, AMD64_R15, cfg->frame_reg, lmf_offset + G_STRUCT_OFFSET (MonoLMF, r15), 8);
+#elif defined(__native_client_codegen__)
+ g_assert_not_reached();
+#endif
}
#ifdef HOST_WIN32
if (cfg->used_int_regs & (1 << AMD64_RDI)) {
else {
for (i = 0; i < AMD64_NREG; ++i)
if (AMD64_IS_CALLEE_SAVED_REG (i) && (cfg->used_int_regs & (1 << i)))
- pos -= sizeof (gpointer);
+ pos -= sizeof(mgreg_t);
if (pos) {
- if (pos == - sizeof (gpointer)) {
+ if (pos == - sizeof(mgreg_t)) {
/* Only one register, so avoid lea */
for (i = AMD64_NREG - 1; i > 0; --i)
if (AMD64_IS_CALLEE_SAVED_REG (i) && (cfg->used_int_regs & (1 << i))) {
for (quad = 0; quad < 2; quad ++) {
switch (ainfo->pair_storage [quad]) {
case ArgInIReg:
- amd64_mov_reg_membase (code, ainfo->pair_regs [quad], inst->inst_basereg, inst->inst_offset + (quad * sizeof (gpointer)), sizeof (gpointer));
+ amd64_mov_reg_membase (code, ainfo->pair_regs [quad], inst->inst_basereg, inst->inst_offset + (quad * sizeof(mgreg_t)), sizeof(mgreg_t));
break;
case ArgInFloatSSEReg:
- amd64_movss_reg_membase (code, ainfo->pair_regs [quad], inst->inst_basereg, inst->inst_offset + (quad * sizeof (gpointer)));
+ amd64_movss_reg_membase (code, ainfo->pair_regs [quad], inst->inst_basereg, inst->inst_offset + (quad * sizeof(mgreg_t)));
break;
case ArgInDoubleSSEReg:
- amd64_movsd_reg_membase (code, ainfo->pair_regs [quad], inst->inst_basereg, inst->inst_offset + (quad * sizeof (gpointer)));
+ amd64_movsd_reg_membase (code, ainfo->pair_regs [quad], inst->inst_basereg, inst->inst_offset + (quad * sizeof(mgreg_t)));
break;
case ArgNone:
break;
code_size += 8 + 7; /*sizeof (void*) + alignment */
}
+#ifdef __native_client_codegen__
+ /* Give us extra room on Native Client. This could be */
+ /* more carefully calculated, but bundle alignment makes */
+ /* it much trickier, so *2 like other places is good. */
+ code_size *= 2;
+#endif
+
while (cfg->code_len + code_size > (cfg->code_size - 16)) {
cfg->code_size *= 2;
- cfg->native_code = g_realloc (cfg->native_code, cfg->code_size);
+ cfg->native_code = mono_realloc_native_code (cfg);
mono_jit_stats.code_reallocs++;
}
/* do nothing */
break;
}
+ g_assert(code < cfg->native_code + cfg->code_size);
}
/* Handle relocations with RIP relative addressing */
switch (patch_info->type) {
case MONO_PATCH_INFO_R8:
case MONO_PATCH_INFO_R4: {
- guint8 *pos;
+ guint8 *pos, *patch_pos, *target_pos;
/* The SSE opcodes require a 16 byte alignment */
+#if defined(__default_codegen__)
code = (guint8*)ALIGN_TO (code, 16);
- memset (orig_code, 0, code - orig_code);
+#elif defined(__native_client_codegen__)
+ {
+ /* Pad this out with HLT instructions */
+ /* or we can get garbage bytes emitted */
+ /* which will fail validation */
+ guint8 *aligned_code;
+ /* extra align to make room for */
+ /* mov/push below */
+ int extra_align = patch_info->type == MONO_PATCH_INFO_R8 ? 2 : 1;
+ aligned_code = (guint8*)ALIGN_TO (code + extra_align, 16);
+ /* The technique of hiding data in an */
+ /* instruction has a problem here: we */
+ /* need the data aligned to a 16-byte */
+ /* boundary but the instruction cannot */
+ /* cross the bundle boundary. so only */
+ /* odd multiples of 16 can be used */
+ if ((intptr_t)aligned_code % kNaClAlignment == 0) {
+ aligned_code += 16;
+ }
+ while (code < aligned_code) {
+ *(code++) = 0xf4; /* hlt */
+ }
+ }
+#endif
pos = cfg->native_code + patch_info->ip.i;
-
- if (IS_REX (pos [1]))
- *(guint32*)(pos + 5) = (guint8*)code - pos - 9;
- else
- *(guint32*)(pos + 4) = (guint8*)code - pos - 8;
+ if (IS_REX (pos [1])) {
+ patch_pos = pos + 5;
+ target_pos = code - pos - 9;
+ }
+ else {
+ patch_pos = pos + 4;
+ target_pos = code - pos - 8;
+ }
if (patch_info->type == MONO_PATCH_INFO_R8) {
+#ifdef __native_client_codegen__
+ /* Hide 64-bit data in a */
+ /* "mov imm64, r11" instruction. */
+ /* write it before the start of */
+ /* the data*/
+ *(code-2) = 0x49; /* prefix */
+ *(code-1) = 0xbb; /* mov X, %r11 */
+#endif
*(double*)code = *(double*)patch_info->data.target;
code += sizeof (double);
} else {
+#ifdef __native_client_codegen__
+ /* Hide 32-bit data in a */
+ /* "push imm32" instruction. */
+ *(code-1) = 0x68; /* push */
+#endif
*(float*)code = *(float*)patch_info->data.target;
code += sizeof (float);
}
+ *(guint32*)(patch_pos) = target_pos;
+
remove = TRUE;
break;
}
tmp->next = patch_info->next;
}
}
+ g_assert (code < cfg->native_code + cfg->code_size);
}
cfg->code_len = code - cfg->native_code;
return can_write;
}
+#if defined(__native_client_codegen__)
+/* For membase calls, we want the base register. for Native Client, */
+/* all indirect calls have the following sequence with the given sizes: */
+/* mov %eXX,%eXX [2-3] */
+/* mov disp(%r15,%rXX,scale),%r11d [4-8] */
+/* and $0xffffffffffffffe0,%r11d [4] */
+/* add %r15,%r11 [3] */
+/* callq *%r11 [3] */
+
+
+/* Determine if code points to a NaCl call-through-register sequence, */
+/* (i.e., the last 3 instructions listed above) */
+int
+is_nacl_call_reg_sequence(guint8* code)
+{
+ const char *sequence = "\x41\x83\xe3\xe0" /* and */
+ "\x4d\x03\xdf" /* add */
+ "\x41\xff\xd3"; /* call */
+ return memcmp(code, sequence, 10) == 0;
+}
+
+/* Determine if code points to the first opcode of the mov membase component */
+/* of an indirect call sequence (i.e. the first 2 instructions listed above) */
+/* (there could be a REX prefix before the opcode but it is ignored) */
+static int
+is_nacl_indirect_call_membase_sequence(guint8* code)
+{
+ /* Check for mov opcode, reg-reg addressing mode (mod = 3), */
+ return code[0] == 0x8b && amd64_modrm_mod(code[1]) == 3 &&
+ /* and that src reg = dest reg */
+ amd64_modrm_reg(code[1]) == amd64_modrm_rm(code[1]) &&
+ /* Check that next inst is mov, uses SIB byte (rm = 4), */
+ IS_REX(code[2]) &&
+ code[3] == 0x8b && amd64_modrm_rm(code[4]) == 4 &&
+ /* and has dst of r11 and base of r15 */
+ (amd64_modrm_reg(code[4]) + amd64_rex_r(code[2])) == AMD64_R11 &&
+ (amd64_sib_base(code[5]) + amd64_rex_b(code[2])) == AMD64_R15;
+}
+#endif /* __native_client_codegen__ */
+
int
mono_arch_get_this_arg_reg (guint8 *code)
{
g_assert ((code - start) < 64);
}
+ nacl_global_codeman_validate(&start, 64, &code);
+
mono_debug_add_delegate_trampoline (start, code - start);
if (code_len)
#ifdef MONO_ARCH_HAVE_IMT
+#if defined(__default_codegen__)
#define CMP_SIZE (6 + 1)
#define CMP_REG_REG_SIZE (4 + 1)
#define BR_SMALL_SIZE 2
#define MOV_REG_IMM_SIZE 10
#define MOV_REG_IMM_32BIT_SIZE 6
#define JUMP_REG_SIZE (2 + 1)
+#elif defined(__native_client_codegen__)
+/* NaCl N-byte instructions can be padded up to N-1 bytes */
+#define CMP_SIZE ((6 + 1) * 2 - 1)
+#define CMP_REG_REG_SIZE ((4 + 1) * 2 - 1)
+#define BR_SMALL_SIZE (2 * 2 - 1)
+#define BR_LARGE_SIZE (6 * 2 - 1)
+#define MOV_REG_IMM_SIZE (10 * 2 - 1)
+#define MOV_REG_IMM_32BIT_SIZE (6 * 2 - 1)
+/* Jump reg for NaCl adds a mask (+4) and add (+3) */
+#define JUMP_REG_SIZE ((2 + 1 + 4 + 3) * 2 - 1)
+/* Jump membase's size is large and unpredictable */
+/* in native client, just pad it out a whole bundle. */
+#define JUMP_MEMBASE_SIZE (kNaClAlignment)
+#endif
static int
imt_branch_distance (MonoIMTCheckItem **imt_entries, int start, int target)
item->chunk_size += MOV_REG_IMM_32BIT_SIZE;
else
item->chunk_size += MOV_REG_IMM_SIZE;
+#ifdef __native_client_codegen__
+ item->chunk_size += JUMP_MEMBASE_SIZE;
+#endif
}
item->chunk_size += BR_SMALL_SIZE + JUMP_REG_SIZE;
} else {
/* with assert below:
* item->chunk_size += CMP_SIZE + BR_SMALL_SIZE + 1;
*/
+#ifdef __native_client_codegen__
+ item->chunk_size += JUMP_MEMBASE_SIZE;
+#endif
}
}
} else {
}
size += item->chunk_size;
}
+#if defined(__native_client__) && defined(__native_client_codegen__)
+ /* In Native Client, we don't re-use thunks, allocate from the */
+ /* normal code manager paths. */
+ code = mono_domain_code_reserve (domain, size);
+#else
if (fail_tramp)
code = mono_method_alloc_generic_virtual_thunk (domain, size);
else
code = mono_domain_code_reserve (domain, size);
+#endif
start = code;
for (i = 0; i < count; ++i) {
MonoIMTCheckItem *item = imt_entries [i];
if (amd64_is_imm32 (item->key))
amd64_alu_reg_imm (code, X86_CMP, MONO_ARCH_IMT_REG, (guint32)(gssize)item->key);
else {
- amd64_mov_reg_imm (code, AMD64_R11, item->key);
- amd64_alu_reg_reg (code, X86_CMP, MONO_ARCH_IMT_REG, AMD64_R11);
+ amd64_mov_reg_imm (code, MONO_ARCH_IMT_SCRATCH_REG, item->key);
+ amd64_alu_reg_reg (code, X86_CMP, MONO_ARCH_IMT_REG, MONO_ARCH_IMT_SCRATCH_REG);
}
}
item->jmp_code = code;
amd64_branch8 (code, X86_CC_NE, 0, FALSE);
if (item->has_target_code) {
- amd64_mov_reg_imm (code, AMD64_R11, item->value.target_code);
- amd64_jump_reg (code, AMD64_R11);
+ amd64_mov_reg_imm (code, MONO_ARCH_IMT_SCRATCH_REG, item->value.target_code);
+ amd64_jump_reg (code, MONO_ARCH_IMT_SCRATCH_REG);
} else {
- amd64_mov_reg_imm (code, AMD64_R11, & (vtable->vtable [item->value.vtable_slot]));
- amd64_jump_membase (code, AMD64_R11, 0);
+ amd64_mov_reg_imm (code, MONO_ARCH_IMT_SCRATCH_REG, & (vtable->vtable [item->value.vtable_slot]));
+ amd64_jump_membase (code, MONO_ARCH_IMT_SCRATCH_REG, 0);
}
if (fail_case) {
amd64_patch (item->jmp_code, code);
- amd64_mov_reg_imm (code, AMD64_R11, fail_tramp);
- amd64_jump_reg (code, AMD64_R11);
+ amd64_mov_reg_imm (code, MONO_ARCH_IMT_SCRATCH_REG, fail_tramp);
+ amd64_jump_reg (code, MONO_ARCH_IMT_SCRATCH_REG);
item->jmp_code = NULL;
}
} else {
if (amd64_is_imm32 (item->key))
amd64_alu_reg_imm (code, X86_CMP, MONO_ARCH_IMT_REG, (guint32)(gssize)item->key);
else {
- amd64_mov_reg_imm (code, AMD64_R11, item->key);
- amd64_alu_reg_reg (code, X86_CMP, MONO_ARCH_IMT_REG, AMD64_R11);
+ amd64_mov_reg_imm (code, MONO_ARCH_IMT_SCRATCH_REG, item->key);
+ amd64_alu_reg_reg (code, X86_CMP, MONO_ARCH_IMT_REG, MONO_ARCH_IMT_SCRATCH_REG);
}
item->jmp_code = code;
amd64_branch8 (code, X86_CC_NE, 0, FALSE);
- amd64_mov_reg_imm (code, AMD64_R11, & (vtable->vtable [item->value.vtable_slot]));
- amd64_jump_membase (code, AMD64_R11, 0);
+ /* See the comment below about R10 */
+ amd64_mov_reg_imm (code, MONO_ARCH_IMT_SCRATCH_REG, & (vtable->vtable [item->value.vtable_slot]));
+ amd64_jump_membase (code, MONO_ARCH_IMT_SCRATCH_REG, 0);
amd64_patch (item->jmp_code, code);
amd64_breakpoint (code);
item->jmp_code = NULL;
#else
- amd64_mov_reg_imm (code, AMD64_R11, & (vtable->vtable [item->value.vtable_slot]));
- amd64_jump_membase (code, AMD64_R11, 0);
+ /* We're using R10 (MONO_ARCH_IMT_SCRATCH_REG) here because R11 (MONO_ARCH_IMT_REG)
+ needs to be preserved. R10 needs
+ to be preserved for calls which
+ require a runtime generic context,
+ but interface calls don't. */
+ amd64_mov_reg_imm (code, MONO_ARCH_IMT_SCRATCH_REG, & (vtable->vtable [item->value.vtable_slot]));
+ amd64_jump_membase (code, MONO_ARCH_IMT_SCRATCH_REG, 0);
#endif
}
} else {
if (amd64_is_imm32 (item->key))
amd64_alu_reg_imm (code, X86_CMP, MONO_ARCH_IMT_REG, (guint32)(gssize)item->key);
else {
- amd64_mov_reg_imm (code, AMD64_R11, item->key);
- amd64_alu_reg_reg (code, X86_CMP, MONO_ARCH_IMT_REG, AMD64_R11);
+ amd64_mov_reg_imm (code, MONO_ARCH_IMT_SCRATCH_REG, item->key);
+ amd64_alu_reg_reg (code, X86_CMP, MONO_ARCH_IMT_REG, MONO_ARCH_IMT_SCRATCH_REG);
}
item->jmp_code = code;
if (x86_is_imm8 (imt_branch_distance (imt_entries, i, item->check_target_idx)))
mono_stats.imt_thunks_size += code - start;
g_assert (code - start <= size);
+ nacl_domain_code_validate(domain, &start, size, &code);
+
return start;
}