Flush (work in progress)

[mono.git] / mono / mini / aot-runtime.c

/*
 * aot-runtime.c: mono Ahead of Time compiler
 *
 * Author:
 *   Dietmar Maurer (dietmar@ximian.com)
 *   Zoltan Varga (vargaz@gmail.com)
 *
 * (C) 2002 Ximian, Inc.
 */

#include "config.h"
#include <sys/types.h>
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#include <fcntl.h>
#include <string.h>
#ifdef HAVE_SYS_MMAN_H
#include <sys/mman.h>
#endif

#if HOST_WIN32
#include <winsock2.h>
#include <windows.h>
#endif

#ifdef HAVE_EXECINFO_H
#include <execinfo.h>
#endif

#include <errno.h>
#include <sys/stat.h>

#ifdef HAVE_SYS_WAIT_H
#include <sys/wait.h>  /* for WIFEXITED, WEXITSTATUS */
#endif

#ifdef HAVE_DL_ITERATE_PHDR
#include <link.h>
#endif

#include <mono/metadata/tabledefs.h>
#include <mono/metadata/class.h>
#include <mono/metadata/object.h>
#include <mono/metadata/tokentype.h>
#include <mono/metadata/appdomain.h>
#include <mono/metadata/debug-helpers.h>
#include <mono/metadata/assembly.h>
#include <mono/metadata/metadata-internals.h>
#include <mono/metadata/marshal.h>
#include <mono/metadata/gc-internal.h>
#include <mono/metadata/monitor.h>
#include <mono/metadata/threads-types.h>
#include <mono/utils/mono-logger-internal.h>
#include <mono/utils/mono-mmap.h>
#include "mono/utils/mono-compiler.h"
#include <mono/utils/mono-counters.h>

#include "mini.h"
#include "version.h"

#ifndef DISABLE_AOT

#ifdef TARGET_WIN32
#define SHARED_EXT ".dll"
#elif ((defined(__ppc__) || defined(__powerpc__) || defined(__ppc64__)) || defined(__MACH__)) && !defined(__linux__)
#define SHARED_EXT ".dylib"
#else
#define SHARED_EXT ".so"
#endif

#define ALIGN_PTR_TO(ptr,align) (gpointer)((((gssize)(ptr)) + (align - 1)) & (~(align - 1)))
#define ROUND_DOWN(VALUE,SIZE)  ((VALUE) & ~((SIZE) - 1))

typedef struct MonoAotModule {
        char *aot_name;
        /* Pointer to the Global Offset Table */
        gpointer *got;
        GHashTable *name_cache;
        GHashTable *extra_methods;
        /* Maps methods to their code */
        GHashTable *method_to_code;
        /* Maps pointers into the method info to the methods themselves */
        GHashTable *method_ref_to_method;
        MonoAssemblyName *image_names;
        char **image_guids;
        MonoAssembly *assembly;
        MonoImage **image_table;
        guint32 image_table_len;
        gboolean out_of_date;
        gboolean plt_inited;
        guint8 *mem_begin;
        guint8 *mem_end;
        guint8 *code;
        guint8 *code_end;
        guint8 *plt;
        guint8 *plt_end;
        guint8 *blob;
        gint32 *code_offsets;
        /* This contains <offset, index> pairs sorted by offset */
        /* This is needed because LLVM emitted methods can be in any order */
        gint32 *sorted_code_offsets;
        gint32 sorted_code_offsets_len;
        guint32 *method_info_offsets;
        guint32 *got_info_offsets;
        guint32 *ex_info_offsets;
        guint32 *class_info_offsets;
        guint32 *methods_loaded;
        guint16 *class_name_table;
        guint32 *extra_method_table;
        guint32 *extra_method_info_offsets;
        guint8 *unwind_info;

        /* Points to the GNU .eh_frame_hdr section, if it exists */
        guint8 *eh_frame_hdr;

        /* Points to the .ARM.exidx section, if it exists */
        guint8 *arm_exidx;
        guint32 arm_exidx_size;

        /* Points to the trampolines */
        guint8 *trampolines [MONO_AOT_TRAMP_NUM];
        /* The first unused trampoline of each kind */
        guint32 trampoline_index [MONO_AOT_TRAMP_NUM];

        MonoAotFileInfo info;

        gpointer *globals;
        MonoDl *sofile;
} MonoAotModule;

static GHashTable *aot_modules;
#define mono_aot_lock() EnterCriticalSection (&aot_mutex)
#define mono_aot_unlock() LeaveCriticalSection (&aot_mutex)
static CRITICAL_SECTION aot_mutex;

/* 
 * Maps assembly names to the mono_aot_module_<NAME>_info symbols in the
 * AOT modules registered by mono_aot_register_module ().
 */
static GHashTable *static_aot_modules;

/*
 * Maps MonoJitInfo* to the aot module they belong to, this can be different
 * from ji->method->klass->image's aot module for generic instances.
 */
static GHashTable *ji_to_amodule;

/*
 * Whenever to AOT compile loaded assemblies on demand and store them in
 * a cache under $HOME/.mono/aot-cache.
 */
static gboolean use_aot_cache = FALSE;

/*
 * Whenever to spawn a new process to AOT a file or do it in-process. Only relevant if
 * use_aot_cache is TRUE.
 */
static gboolean spawn_compiler = TRUE;

/* For debugging */
static gint32 mono_last_aot_method = -1;

static gboolean make_unreadable = FALSE;
static guint32 name_table_accesses = 0;
static guint32 n_pagefaults = 0;

/* Used to speed-up find_aot_module () */
static gsize aot_code_low_addr = (gssize)-1;
static gsize aot_code_high_addr = 0;

static void
init_plt (MonoAotModule *info);

/*****************************************************/
/*                 AOT RUNTIME                       */
/*****************************************************/

/*
 * load_image:
 *
 *   Load one of the images referenced by AMODULE. Returns NULL if the image is not
 * found, and sets the loader error if SET_ERROR is TRUE.
 */
static MonoImage *
load_image (MonoAotModule *amodule, int index, gboolean set_error)
{
        MonoAssembly *assembly;
        MonoImageOpenStatus status;

        g_assert (index < amodule->image_table_len);

        if (amodule->image_table [index])
                return amodule->image_table [index];
        if (amodule->out_of_date)
                return NULL;

        assembly = mono_assembly_load (&amodule->image_names [index], NULL, &status);
        if (!assembly) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT module %s is unusable because dependency %s is not found.\n", amodule->aot_name, amodule->image_names [index].name);
                amodule->out_of_date = TRUE;

                if (set_error) {
                        char *full_name = mono_stringify_assembly_name (&amodule->image_names [index]);
                        mono_loader_set_error_assembly_load (full_name, FALSE);
                        g_free (full_name);
                }
                return NULL;
        }

        if (strcmp (assembly->image->guid, amodule->image_guids [index])) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT module %s is out of date (Older than dependency %s).\n", amodule->aot_name, amodule->image_names [index].name);
                amodule->out_of_date = TRUE;
                return NULL;
        }

        amodule->image_table [index] = assembly->image;
        return assembly->image;
}

static inline gint32
decode_value (guint8 *ptr, guint8 **rptr)
{
        guint8 b = *ptr;
        gint32 len;
        
        if ((b & 0x80) == 0){
                len = b;
                ++ptr;
        } else if ((b & 0x40) == 0){
                len = ((b & 0x3f) << 8 | ptr [1]);
                ptr += 2;
        } else if (b != 0xff) {
                len = ((b & 0x1f) << 24) |
                        (ptr [1] << 16) |
                        (ptr [2] << 8) |
                        ptr [3];
                ptr += 4;
        }
        else {
                len = (ptr [1] << 24) | (ptr [2] << 16) | (ptr [3] << 8) | ptr [4];
                ptr += 5;
        }
        if (rptr)
                *rptr = ptr;

        //printf ("DECODE: %d.\n", len);
        return len;
}

/*
 * mono_aot_get_method:
 *
 *   Decode an offset table emitted by emit_offset_table (), returning the INDEXth
 * entry.
 */
static guint32
mono_aot_get_offset (guint32 *table, int index)
{
        int i, group, ngroups, index_entry_size;
        int start_offset, offset, noffsets, group_size;
        guint8 *data_start, *p;
        guint32 *index32 = NULL;
        guint16 *index16 = NULL;
        
        noffsets = table [0];
        group_size = table [1];
        ngroups = table [2];
        index_entry_size = table [3];
        group = index / group_size;

        if (index_entry_size == 2) {
                index16 = (guint16*)&table [4];
                data_start = (guint8*)&index16 [ngroups];
                p = data_start + index16 [group];
        } else {
                index32 = (guint32*)&table [4];
                data_start = (guint8*)&index32 [ngroups];
                p = data_start + index32 [group];
        }

        /* offset will contain the value of offsets [group * group_size] */
        offset = start_offset = decode_value (p, &p);
        for (i = group * group_size + 1; i <= index; ++i) {
                offset += decode_value (p, &p);
        }

        //printf ("Offset lookup: %d -> %d, start=%d, p=%d\n", index, offset, start_offset, table [3 + group]);

        return offset;
}

static MonoMethod*
decode_method_ref_2 (MonoAotModule *module, guint8 *buf, guint8 **endbuf);

static MonoClass*
decode_klass_ref (MonoAotModule *module, guint8 *buf, guint8 **endbuf);

static MonoGenericInst*
decode_generic_inst (MonoAotModule *module, guint8 *buf, guint8 **endbuf)
{
        int type_argc, i;
        MonoType **type_argv;
        MonoGenericInst *inst;
        guint8 *p = buf;

        type_argc = decode_value (p, &p);
        type_argv = g_new0 (MonoType*, type_argc);

        for (i = 0; i < type_argc; ++i) {
                MonoClass *pclass = decode_klass_ref (module, p, &p);
                if (!pclass) {
                        g_free (type_argv);
                        return NULL;
                }
                type_argv [i] = &pclass->byval_arg;
        }

        inst = mono_metadata_get_generic_inst (type_argc, type_argv);
        g_free (type_argv);

        *endbuf = p;

        return inst;
}

static gboolean
decode_generic_context (MonoAotModule *module, MonoGenericContext *ctx, guint8 *buf, guint8 **endbuf)
{
        gboolean has_class_inst, has_method_inst;
        guint8 *p = buf;

        has_class_inst = decode_value (p, &p);
        if (has_class_inst) {
                ctx->class_inst = decode_generic_inst (module, p, &p);
                if (!ctx->class_inst)
                        return FALSE;
        }
        has_method_inst = decode_value (p, &p);
        if (has_method_inst) {
                ctx->method_inst = decode_generic_inst (module, p, &p);
                if (!ctx->method_inst)
                        return FALSE;
        }

        *endbuf = p;
        return TRUE;
}

static MonoClass*
decode_klass_ref (MonoAotModule *module, guint8 *buf, guint8 **endbuf)
{
        MonoImage *image;
        MonoClass *klass, *eklass;
        guint32 token, rank;
        guint8 *p = buf;

        token = decode_value (p, &p);
        if (token == 0) {
                *endbuf = p;
                return NULL;
        }
        if (mono_metadata_token_table (token) == 0) {
                image = load_image (module, decode_value (p, &p), TRUE);
                if (!image)
                        return NULL;
                klass = mono_class_get (image, MONO_TOKEN_TYPE_DEF + token);
        } else if (mono_metadata_token_table (token) == MONO_TABLE_TYPESPEC) {
                if (token == MONO_TOKEN_TYPE_SPEC) {
                        MonoTypeEnum type = decode_value (p, &p);

                        if (type == MONO_TYPE_GENERICINST) {
                                MonoClass *gclass;
                                MonoGenericContext ctx;
                                MonoType *type;

                                gclass = decode_klass_ref (module, p, &p);
                                if (!gclass)
                                        return NULL;
                                g_assert (gclass->generic_container);

                                memset (&ctx, 0, sizeof (ctx));
                                ctx.class_inst = decode_generic_inst (module, p, &p);
                                if (!ctx.class_inst)
                                        return NULL;
                                type = mono_class_inflate_generic_type (&gclass->byval_arg, &ctx);
                                klass = mono_class_from_mono_type (type);
                                mono_metadata_free_type (type);
                        } else if ((type == MONO_TYPE_VAR) || (type == MONO_TYPE_MVAR)) {
                                MonoType *t;
                                MonoGenericContainer *container;

                                int num = decode_value (p, &p);
                                gboolean is_method = decode_value (p, &p);

                                if (is_method) {
                                        MonoMethod *method_def;
                                        g_assert (type == MONO_TYPE_MVAR);
                                        method_def = decode_method_ref_2 (module, p, &p);
                                        if (!method_def)
                                                return NULL;

                                        container = mono_method_get_generic_container (method_def);
                                } else {
                                        MonoClass *class_def;
                                        g_assert (type == MONO_TYPE_VAR);
                                        class_def = decode_klass_ref (module, p, &p);
                                        if (!class_def)
                                                return NULL;

                                        container = class_def->generic_container;
                                }

                                g_assert (container);

                                // FIXME: Memory management
                                t = g_new0 (MonoType, 1);
                                t->type = type;
                                t->data.generic_param = mono_generic_container_get_param (container, num);

                                // FIXME: Maybe use types directly to avoid
                                // the overhead of creating MonoClass-es
                                klass = mono_class_from_mono_type (t);

                                g_free (t);
                        } else {
                                g_assert_not_reached ();
                        }
                } else {
                        image = load_image (module, decode_value (p, &p), TRUE);
                        if (!image)
                                return NULL;
                        klass = mono_class_get (image, token);
                }
        } else if (token == MONO_TOKEN_TYPE_DEF) {
                /* Array */
                image = load_image (module, decode_value (p, &p), TRUE);
                if (!image)
                        return NULL;
                rank = decode_value (p, &p);
                eklass = decode_klass_ref (module, p, &p);
                klass = mono_array_class_get (eklass, rank);
        } else {
                g_assert_not_reached ();
        }
        g_assert (klass);

        *endbuf = p;
        return klass;
}

static MonoClassField*
decode_field_info (MonoAotModule *module, guint8 *buf, guint8 **endbuf)
{
        MonoClass *klass = decode_klass_ref (module, buf, &buf);
        guint32 token;
        guint8 *p = buf;

        if (!klass)
                return NULL;

        token = MONO_TOKEN_FIELD_DEF + decode_value (p, &p);

        *endbuf = p;

        return mono_class_get_field (klass, token);
}

/*
 * can_method_ref_match_method:
 *
 *   Determine if calling decode_method_ref_2 on P could return the same method as 
 * METHOD. This is an optimization to avoid calling decode_method_ref_2 () which
 * would create MonoMethods which are not needed etc.
 */
static gboolean
can_method_ref_match_method (MonoAotModule *module, guint8 *buf, MonoMethod *method)
{
        guint8 *p = buf;
        guint32 image_index, value;

        /* Keep this in sync with decode_method_ref () */
        value = decode_value (p, &p);
        image_index = value >> 24;

        if (image_index == MONO_AOT_METHODREF_WRAPPER) {
                guint32 wrapper_type;

                if (!method->wrapper_type)
                        return FALSE;

                wrapper_type = decode_value (p, &p);

                if (method->wrapper_type != wrapper_type)
                        return FALSE;
        } else if (image_index == MONO_AOT_METHODREF_WRAPPER_NAME) {
                return FALSE;
        } else if (image_index < MONO_AOT_METHODREF_MIN || image_index == MONO_AOT_METHODREF_METHODSPEC || image_index == MONO_AOT_METHODREF_GINST) {
                if (method->wrapper_type)
                        return FALSE;
        }

        return TRUE;
}

/*
 * decode_method_ref:
 *
 *   Decode a method reference, and return its image and token. This avoids loading
 * metadata for the method if the caller does not need it. If the method has no token,
 * then it is loaded from metadata and METHOD is set to the method instance.
 */
static MonoImage*
decode_method_ref (MonoAotModule *module, guint32 *token, MonoMethod **method, gboolean *no_aot_trampoline, guint8 *buf, guint8 **endbuf)
{
        guint32 image_index, value;
        MonoImage *image = NULL;
        guint8 *p = buf;

        if (method)
                *method = NULL;
        if (no_aot_trampoline)
                *no_aot_trampoline = FALSE;

        value = decode_value (p, &p);
        image_index = value >> 24;

        if (image_index == MONO_AOT_METHODREF_NO_AOT_TRAMPOLINE) {
                if (no_aot_trampoline)
                        *no_aot_trampoline = TRUE;
                value = decode_value (p, &p);
                image_index = value >> 24;
        }

        if (image_index == MONO_AOT_METHODREF_WRAPPER) {
                guint32 wrapper_type;

                wrapper_type = decode_value (p, &p);

                /* Doesn't matter */
                image = mono_defaults.corlib;

                switch (wrapper_type) {
                case MONO_WRAPPER_REMOTING_INVOKE_WITH_CHECK: {
                        MonoMethod *m = decode_method_ref_2 (module, p, &p);

                        if (!m)
                                return NULL;
                        mono_class_init (m->klass);
                        *method = mono_marshal_get_remoting_invoke_with_check (m);
                        break;
                }
                case MONO_WRAPPER_PROXY_ISINST: {
                        MonoClass *klass = decode_klass_ref (module, p, &p);
                        if (!klass)
                                return NULL;
                        *method = mono_marshal_get_proxy_cancast (klass);
                        break;
                }
                case MONO_WRAPPER_LDFLD:
                case MONO_WRAPPER_LDFLDA:
                case MONO_WRAPPER_STFLD:
                case MONO_WRAPPER_ISINST: {
                        MonoClass *klass = decode_klass_ref (module, p, &p);
                        if (!klass)
                                return NULL;
                        if (wrapper_type == MONO_WRAPPER_LDFLD)
                                *method = mono_marshal_get_ldfld_wrapper (&klass->byval_arg);
                        else if (wrapper_type == MONO_WRAPPER_LDFLDA)
                                *method = mono_marshal_get_ldflda_wrapper (&klass->byval_arg);
                        else if (wrapper_type == MONO_WRAPPER_STFLD)
                                *method = mono_marshal_get_stfld_wrapper (&klass->byval_arg);
                        else if (wrapper_type == MONO_WRAPPER_ISINST)
                                *method = mono_marshal_get_isinst (klass);
                        else
                                g_assert_not_reached ();
                        break;
                }
                case MONO_WRAPPER_LDFLD_REMOTE:
                        *method = mono_marshal_get_ldfld_remote_wrapper (NULL);
                        break;
                case MONO_WRAPPER_STFLD_REMOTE:
                        *method = mono_marshal_get_stfld_remote_wrapper (NULL);
                        break;
                case MONO_WRAPPER_ALLOC: {
                        int atype = decode_value (p, &p);

                        *method = mono_gc_get_managed_allocator_by_type (atype);
                        break;
                }
                case MONO_WRAPPER_WRITE_BARRIER:
                        *method = mono_gc_get_write_barrier ();
                        break;
                case MONO_WRAPPER_STELEMREF:
                        *method = mono_marshal_get_stelemref ();
                        break;
                case MONO_WRAPPER_SYNCHRONIZED: {
                        MonoMethod *m = decode_method_ref_2 (module, p, &p);

                        if (!m)
                                return NULL;
                        *method = mono_marshal_get_synchronized_wrapper (m);
                        break;
                }
                case MONO_WRAPPER_UNKNOWN: {
                        MonoMethodDesc *desc;
                        MonoMethod *orig_method;
                        int subtype = decode_value (p, &p);

                        if (subtype == MONO_AOT_WRAPPER_MONO_ENTER)
                                desc = mono_method_desc_new ("Monitor:Enter", FALSE);
                        else if (subtype == MONO_AOT_WRAPPER_MONO_EXIT)
                                desc = mono_method_desc_new ("Monitor:Exit", FALSE);
                        else
                                g_assert_not_reached ();
                        orig_method = mono_method_desc_search_in_class (desc, mono_defaults.monitor_class);
                        g_assert (orig_method);
                        mono_method_desc_free (desc);
                        *method = mono_monitor_get_fast_path (orig_method);
                        break;
                }
                case MONO_WRAPPER_RUNTIME_INVOKE: {
                        /* Direct wrapper */
                        MonoMethod *m = decode_method_ref_2 (module, p, &p);

                        if (!m)
                                return NULL;
                        *method = mono_marshal_get_runtime_invoke (m, FALSE);
                        break;
                }
                case MONO_WRAPPER_MANAGED_TO_MANAGED: {
                        int subtype = decode_value (p, &p);

                        if (subtype == MONO_AOT_WRAPPER_ELEMENT_ADDR) {
                                int rank = decode_value (p, &p);
                                int elem_size = decode_value (p, &p);

                                *method = mono_marshal_get_array_address (rank, elem_size);
                        } else {
                                g_assert_not_reached ();
                        }
                        break;
                }
                default:
                        g_assert_not_reached ();
                }
        } else if (image_index == MONO_AOT_METHODREF_WRAPPER_NAME) {
                /* Can't decode these */
                g_assert_not_reached ();
        } else if (image_index == MONO_AOT_METHODREF_METHODSPEC) {
                image_index = decode_value (p, &p);
                *token = decode_value (p, &p);

                image = load_image (module, image_index, TRUE);
                if (!image)
                        return NULL;
        } else if (image_index == MONO_AOT_METHODREF_GINST) {
                MonoClass *klass;
                MonoGenericContext ctx;

                /* 
                 * These methods do not have a token which resolves them, so we 
                 * resolve them immediately.
                 */
                klass = decode_klass_ref (module, p, &p);
                if (!klass)
                        return NULL;

                image_index = decode_value (p, &p);
                *token = decode_value (p, &p);

                image = load_image (module, image_index, TRUE);
                if (!image)
                        return NULL;

                *method = mono_get_method_full (image, *token, NULL, NULL);
                if (!(*method))
                        return NULL;

                memset (&ctx, 0, sizeof (ctx));

                if (FALSE && klass->generic_class) {
                        ctx.class_inst = klass->generic_class->context.class_inst;
                        ctx.method_inst = NULL;
 
                        *method = mono_class_inflate_generic_method_full (*method, klass, &ctx);
                }                       

                memset (&ctx, 0, sizeof (ctx));

                if (!decode_generic_context (module, &ctx, p, &p))
                        return NULL;

                *method = mono_class_inflate_generic_method_full (*method, klass, &ctx);
        } else if (image_index == MONO_AOT_METHODREF_ARRAY) {
                MonoClass *klass;
                int method_type;

                klass = decode_klass_ref (module, p, &p);
                if (!klass)
                        return NULL;
                method_type = decode_value (p, &p);
                *token = 0;
                switch (method_type) {
                case 0:
                        *method = mono_class_get_method_from_name (klass, ".ctor", klass->rank);
                        break;
                case 1:
                        *method = mono_class_get_method_from_name (klass, ".ctor", klass->rank * 2);
                        break;
                case 2:
                        *method = mono_class_get_method_from_name (klass, "Get", -1);
                        break;
                case 3:
                        *method = mono_class_get_method_from_name (klass, "Address", -1);
                        break;
                case 4:
                        *method = mono_class_get_method_from_name (klass, "Set", -1);
                        break;
                default:
                        g_assert_not_reached ();
                }
        } else {
                g_assert (image_index < MONO_AOT_METHODREF_MIN);
                *token = MONO_TOKEN_METHOD_DEF | (value & 0xffffff);

                image = load_image (module, image_index, TRUE);
                if (!image)
                        return NULL;
        }

        *endbuf = p;

        return image;
}

/*
 * decode_method_ref_2:
 *
 *   Similar to decode_method_ref, but resolve and return the method itself.
 */
static MonoMethod*
decode_method_ref_2 (MonoAotModule *module, guint8 *buf, guint8 **endbuf)
{
        MonoMethod *method;
        guint32 token;
        MonoImage *image = decode_method_ref (module, &token, &method, NULL, buf, endbuf);

        if (method)
                return method;
        if (!image)
                return NULL;
        method = mono_get_method (image, token, NULL);
        return method;
}

G_GNUC_UNUSED
static void
make_writable (guint8* addr, guint32 len)
{
        guint8 *page_start;
        int pages, err;

        if (mono_aot_only)
                g_error ("Attempt to make AOT memory writable while running in aot-only mode.\n");

        page_start = (guint8 *) (((gssize) (addr)) & ~ (mono_pagesize () - 1));
        pages = (addr + len - page_start + mono_pagesize () - 1) / mono_pagesize ();

        err = mono_mprotect (page_start, pages * mono_pagesize (), MONO_MMAP_READ | MONO_MMAP_WRITE | MONO_MMAP_EXEC);
        g_assert (err == 0);
}

static void
create_cache_structure (void)
{
        const char *home;
        char *tmp;
        int err;

        home = g_get_home_dir ();
        if (!home)
                return;

        tmp = g_build_filename (home, ".mono", NULL);
        if (!g_file_test (tmp, G_FILE_TEST_IS_DIR)) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT creating directory %s", tmp);
#ifdef HOST_WIN32
                err = mkdir (tmp);
#else
                err = mkdir (tmp, 0777);
#endif
                if (err) {
                        mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT failed: %s", g_strerror (errno));
                        g_free (tmp);
                        return;
                }
        }
        g_free (tmp);
        tmp = g_build_filename (home, ".mono", "aot-cache", NULL);
        if (!g_file_test (tmp, G_FILE_TEST_IS_DIR)) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT creating directory %s", tmp);
#ifdef HOST_WIN32
                err = mkdir (tmp);
#else
                err = mkdir (tmp, 0777);
#endif
                if (err) {
                        mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT failed: %s", g_strerror (errno));
                        g_free (tmp);
                        return;
                }
        }
        g_free (tmp);
}

/*
 * load_aot_module_from_cache:
 *
 *  Experimental code to AOT compile loaded assemblies on demand. 
 *
 * FIXME: 
 * - Add environment variable MONO_AOT_CACHE_OPTIONS
 * - Add options for controlling the cache size
 * - Handle full cache by deleting old assemblies lru style
 * - Add options for excluding assemblies during development
 * - Maybe add a threshold after an assembly is AOT compiled
 * - invoking a new mono process is a security risk
 * - recompile the AOT module if one of its dependencies changes
 */
static MonoDl*
load_aot_module_from_cache (MonoAssembly *assembly, char **aot_name)
{
        char *fname, *cmd, *tmp2, *aot_options;
        const char *home;
        MonoDl *module;
        gboolean res;
        gchar *out, *err;
        gint exit_status;

        *aot_name = NULL;

        if (assembly->image->dynamic)
                return NULL;

        create_cache_structure ();

        home = g_get_home_dir ();

        tmp2 = g_strdup_printf ("%s-%s%s", assembly->image->assembly_name, assembly->image->guid, SHARED_EXT);
        fname = g_build_filename (home, ".mono", "aot-cache", tmp2, NULL);
        *aot_name = fname;
        g_free (tmp2);

        mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT trying to load from cache: '%s'.", fname);
        module = mono_dl_open (fname, MONO_DL_LAZY, NULL);

        if (!module) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT not found.");

                mono_trace (G_LOG_LEVEL_MESSAGE, MONO_TRACE_AOT, "AOT precompiling assembly '%s'... ", assembly->image->name);

                aot_options = g_strdup_printf ("outfile=%s", fname);

                if (spawn_compiler) {
                        /* FIXME: security */
                        /* FIXME: Has to pass the assembly loading path to the child process */
                        cmd = g_strdup_printf ("mono -O=all --aot=%s %s", aot_options, assembly->image->name);

                        res = g_spawn_command_line_sync (cmd, &out, &err, &exit_status, NULL);

#if !defined(HOST_WIN32) && !defined(__ppc__) && !defined(__ppc64__) && !defined(__powerpc__)
                        if (res) {
                                if (!WIFEXITED (exit_status) && (WEXITSTATUS (exit_status) == 0))
                                        mono_trace (G_LOG_LEVEL_MESSAGE, MONO_TRACE_AOT, "AOT failed: %s.", err);
                                else
                                        mono_trace (G_LOG_LEVEL_MESSAGE, MONO_TRACE_AOT, "AOT succeeded.");
                                g_free (out);
                                g_free (err);
                        }
#endif
                        g_free (cmd);
                } else {
                        res = mono_compile_assembly (assembly, mono_parse_default_optimizations (NULL), aot_options);
                        if (!res) {
                                mono_trace (G_LOG_LEVEL_MESSAGE, MONO_TRACE_AOT, "AOT failed.");
                        } else {
                                mono_trace (G_LOG_LEVEL_MESSAGE, MONO_TRACE_AOT, "AOT succeeded.");
                        }
                }

                module = mono_dl_open (fname, MONO_DL_LAZY, NULL);

                g_free (aot_options);
        }

        return module;
}

static void
find_symbol (MonoDl *module, gpointer *globals, const char *name, gpointer *value)
{
        if (globals) {
                int global_index;
                guint16 *table, *entry;
                guint16 table_size;
                guint32 hash;           

                /* The first entry points to the hash */
                table = globals [0];
                globals ++;

                table_size = table [0];
                table ++;

                hash = mono_metadata_str_hash (name) % table_size;

                entry = &table [hash * 2];

                /* Search the hash for the index into the globals table */
                global_index = -1;
                while (entry [0] != 0) {
                        guint32 index = entry [0] - 1;
                        guint32 next = entry [1];

                        //printf ("X: %s %s\n", (char*)globals [index * 2], name);

                        if (!strcmp (globals [index * 2], name)) {
                                global_index = index;
                                break;
                        }

                        if (next != 0) {
                                entry = &table [next * 2];
                        } else {
                                break;
                        }
                }

                if (global_index != -1)
                        *value = globals [global_index * 2 + 1];
                else
                        *value = NULL;
        } else {
                char *err = mono_dl_symbol (module, name, value);

                if (err)
                        g_free (err);
        }
}

#ifndef SHT_ARM_EXIDX
#define SHT_ARM_EXIDX 0x70000001
#endif

#if defined(HAVE_DL_ITERATE_PHDR) && defined(PT_GNU_EH_FRAME)
static int
dl_callback (struct dl_phdr_info *info, size_t size, void *data)
{
        int j;
        MonoAotModule *amodule = data;

        if (!strcmp (amodule->aot_name, info->dlpi_name)) {
                for (j = 0; j < info->dlpi_phnum; j++) {
                        if (info->dlpi_phdr [j].p_type == PT_GNU_EH_FRAME)
                                amodule->eh_frame_hdr = (guint8*)(info->dlpi_addr + info->dlpi_phdr [j].p_vaddr);
                        if (info->dlpi_phdr [j].p_type == SHT_ARM_EXIDX) {
                                amodule->arm_exidx = (guint8*)(info->dlpi_addr + info->dlpi_phdr [j].p_vaddr);
                                amodule->arm_exidx_size = info->dlpi_phdr [j].p_filesz;
                        }
                }
                return 1;
        } else {
                return 0;
        }
}
#endif

static void
load_aot_module (MonoAssembly *assembly, gpointer user_data)
{
        char *aot_name;
        MonoAotModule *amodule;
        MonoDl *sofile;
        gboolean usable = TRUE;
        char *saved_guid = NULL;
        char *aot_version = NULL;
        char *runtime_version, *build_info;
        char *opt_flags = NULL;
        gpointer *globals;
        gboolean full_aot = FALSE;
        MonoAotFileInfo *file_info = NULL;
        int i;
        gpointer *got_addr;

        if (mono_compile_aot)
                return;

        if (assembly->image->aot_module)
                /* 
                 * Already loaded. This can happen because the assembly loading code might invoke
                 * the assembly load hooks multiple times for the same assembly.
                 */
                return;

        if (assembly->image->dynamic)
                return;

        if (mono_security_get_mode () == MONO_SECURITY_MODE_CAS)
                return;

        mono_aot_lock ();
        if (static_aot_modules)
                globals = g_hash_table_lookup (static_aot_modules, assembly->aname.name);
        else
                globals = NULL;
        mono_aot_unlock ();

        if (globals) {
                /* Statically linked AOT module */
                sofile = NULL;
                aot_name = g_strdup_printf ("%s", assembly->aname.name);
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "Found statically linked AOT module '%s'.\n", aot_name);
        } else {
                if (use_aot_cache)
                        sofile = load_aot_module_from_cache (assembly, &aot_name);
                else {
                        char *err;
                        aot_name = g_strdup_printf ("%s%s", assembly->image->name, SHARED_EXT);

                        sofile = mono_dl_open (aot_name, MONO_DL_LAZY, &err);

                        if (!sofile) {
                                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT failed to load AOT module %s: %s\n", aot_name, err);
                                g_free (err);
                        }
                }
        }

        if (!sofile && !globals) {
                if (mono_aot_only) {
                        fprintf (stderr, "Failed to load AOT module '%s' in aot-only mode.\n", aot_name);
                        exit (1);
                }
                g_free (aot_name);
                return;
        }

        find_symbol (sofile, globals, "mono_assembly_guid", (gpointer *) &saved_guid);
        find_symbol (sofile, globals, "mono_aot_version", (gpointer *) &aot_version);
        find_symbol (sofile, globals, "mono_aot_opt_flags", (gpointer *)&opt_flags);
        find_symbol (sofile, globals, "mono_runtime_version", (gpointer *)&runtime_version);
        find_symbol (sofile, globals, "mono_aot_got_addr", (gpointer *)&got_addr);

        if (!aot_version || strcmp (aot_version, MONO_AOT_FILE_VERSION)) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT module %s has wrong file format version (expected %s got %s)\n", aot_name, MONO_AOT_FILE_VERSION, aot_version);
                usable = FALSE;
        }
        else {
                if (!saved_guid || strcmp (assembly->image->guid, saved_guid)) {
                        mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT module %s is out of date.\n", aot_name);
                        usable = FALSE;
                }
        }

        build_info = mono_get_runtime_build_info ();
        if (!runtime_version || ((strlen (runtime_version) > 0 && strcmp (runtime_version, build_info)))) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT module %s is compiled against runtime version '%s' while this runtime has version '%s'.\n", aot_name, runtime_version, build_info);
                usable = FALSE;
        }
        g_free (build_info);

        find_symbol (sofile, globals, "mono_aot_file_info", (gpointer*)&file_info);
        g_assert (file_info);

        full_aot = ((MonoAotFileInfo*)file_info)->flags & MONO_AOT_FILE_FLAG_FULL_AOT;

        if (mono_aot_only && !full_aot) {
                fprintf (stderr, "Can't use AOT image '%s' in aot-only mode because it is not compiled with --aot=full.\n", aot_name);
                exit (1);
        }
        if (!mono_aot_only && full_aot) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT module %s is compiled with --aot=full.\n", aot_name);
                usable = FALSE;
        }

        if ((((MonoAotFileInfo*)file_info)->flags & MONO_AOT_FILE_FLAG_WITH_LLVM) && !mono_use_llvm) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT module %s is compiled with LLVM.\n", aot_name);
                usable = FALSE;
        }

        if (!usable) {
                if (mono_aot_only) {
                        fprintf (stderr, "Failed to load AOT module '%s' while running in aot-only mode.\n", aot_name);
                        exit (1);
                }
                g_free (aot_name);
                if (sofile)
                        mono_dl_close (sofile);
                assembly->image->aot_module = NULL;
                return;
        }

        amodule = g_new0 (MonoAotModule, 1);
        amodule->aot_name = aot_name;
        amodule->assembly = assembly;

        memcpy (&amodule->info, file_info, sizeof (*file_info));

        amodule->got = *got_addr;
        amodule->got [0] = assembly->image;
        amodule->globals = globals;
        amodule->sofile = sofile;
        amodule->method_to_code = g_hash_table_new (mono_aligned_addr_hash, NULL);

        /* Read image table */
        {
                guint32 table_len, i;
                char *table = NULL;

                find_symbol (sofile, globals, "mono_image_table", (gpointer *)&table);
                g_assert (table);

                table_len = *(guint32*)table;
                table += sizeof (guint32);
                amodule->image_table = g_new0 (MonoImage*, table_len);
                amodule->image_names = g_new0 (MonoAssemblyName, table_len);
                amodule->image_guids = g_new0 (char*, table_len);
                amodule->image_table_len = table_len;
                for (i = 0; i < table_len; ++i) {
                        MonoAssemblyName *aname = &(amodule->image_names [i]);

                        aname->name = g_strdup (table);
                        table += strlen (table) + 1;
                        amodule->image_guids [i] = g_strdup (table);
                        table += strlen (table) + 1;
                        if (table [0] != 0)
                                aname->culture = g_strdup (table);
                        table += strlen (table) + 1;
                        memcpy (aname->public_key_token, table, strlen (table) + 1);
                        table += strlen (table) + 1;                    

                        table = ALIGN_PTR_TO (table, 8);
                        aname->flags = *(guint32*)table;
                        table += 4;
                        aname->major = *(guint32*)table;
                        table += 4;
                        aname->minor = *(guint32*)table;
                        table += 4;
                        aname->build = *(guint32*)table;
                        table += 4;
                        aname->revision = *(guint32*)table;
                        table += 4;
                }
        }

        /* Read method and method_info tables */
        find_symbol (sofile, globals, "code_offsets", (gpointer*)&amodule->code_offsets);
        find_symbol (sofile, globals, "methods", (gpointer*)&amodule->code);
        find_symbol (sofile, globals, "methods_end", (gpointer*)&amodule->code_end);
        find_symbol (sofile, globals, "method_info_offsets", (gpointer*)&amodule->method_info_offsets);
        find_symbol (sofile, globals, "ex_info_offsets", (gpointer*)&amodule->ex_info_offsets);
        find_symbol (sofile, globals, "blob", (gpointer*)&amodule->blob);
        find_symbol (sofile, globals, "class_info_offsets", (gpointer*)&amodule->class_info_offsets);
        find_symbol (sofile, globals, "class_name_table", (gpointer *)&amodule->class_name_table);
        find_symbol (sofile, globals, "extra_method_table", (gpointer *)&amodule->extra_method_table);
        find_symbol (sofile, globals, "extra_method_info_offsets", (gpointer *)&amodule->extra_method_info_offsets);
        find_symbol (sofile, globals, "got_info_offsets", (gpointer*)&amodule->got_info_offsets);
        find_symbol (sofile, globals, "specific_trampolines", (gpointer*)&(amodule->trampolines [MONO_AOT_TRAMP_SPECIFIC]));
        find_symbol (sofile, globals, "static_rgctx_trampolines", (gpointer*)&(amodule->trampolines [MONO_AOT_TRAMP_STATIC_RGCTX]));
        find_symbol (sofile, globals, "imt_thunks", (gpointer*)&(amodule->trampolines [MONO_AOT_TRAMP_IMT_THUNK]));
        find_symbol (sofile, globals, "unwind_info", (gpointer)&amodule->unwind_info);
        find_symbol (sofile, globals, "mem_end", (gpointer*)&amodule->mem_end);

        amodule->mem_begin = amodule->code;

        find_symbol (sofile, globals, "plt", (gpointer*)&amodule->plt);
        find_symbol (sofile, globals, "plt_end", (gpointer*)&amodule->plt_end);

        if (make_unreadable) {
#ifndef TARGET_WIN32
                guint8 *addr;
                guint8 *page_start, *page_end;
                int err, len;

                addr = amodule->mem_begin;
                len = amodule->mem_end - amodule->mem_begin;

                /* Round down in both directions to avoid modifying data which is not ours */
                page_start = (guint8 *) (((gssize) (addr)) & ~ (mono_pagesize () - 1)) + mono_pagesize ();
                page_end = (guint8 *) (((gssize) (addr + len)) & ~ (mono_pagesize () - 1));
                if (page_end > page_start) {
                        err = mono_mprotect (page_start, (page_end - page_start), MONO_MMAP_NONE);
                        g_assert (err == 0);
                }
#endif
        }

        mono_aot_lock ();

        aot_code_low_addr = MIN (aot_code_low_addr, (gsize)amodule->code);
        aot_code_high_addr = MAX (aot_code_high_addr, (gsize)amodule->code_end);

        g_hash_table_insert (aot_modules, assembly, amodule);
        mono_aot_unlock ();

        mono_jit_info_add_aot_module (assembly->image, amodule->code, amodule->code_end);

        assembly->image->aot_module = amodule;
 
#if defined(HAVE_DL_ITERATE_PHDR) && defined(PT_GNU_EH_FRAME)
        /* Lookup the address of the .eh_frame_hdr () section if available */
        dl_iterate_phdr (dl_callback, amodule);
#endif  

        if (mono_aot_only) {
                if (mono_defaults.corlib) {
                        /* The second got slot contains the mscorlib got addr */
                        MonoAotModule *mscorlib_amodule = mono_defaults.corlib->aot_module;

                        amodule->got [1] = mscorlib_amodule->got;
                } else {
                        amodule->got [1] = amodule->got;
                }
        }

        /*
         * Since we store methoddef and classdef tokens when referring to methods/classes in
         * referenced assemblies, we depend on the exact versions of the referenced assemblies.
         * MS calls this 'hard binding'. This means we have to load all referenced assemblies
         * non-lazily, since we can't handle out-of-date errors later.
         * The cached class info also depends on the exact assemblies.
         */
        for (i = 0; i < amodule->image_table_len; ++i)
                load_image (amodule, i, FALSE);

        if (amodule->out_of_date) {
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT Module %s is unusable because a dependency is out-of-date.\n", assembly->image->name);
                if (mono_aot_only) {
                        fprintf (stderr, "Failed to load AOT module '%s' while running in aot-only mode because a dependency cannot be found or it is out of date.\n", aot_name);
                        exit (1);
                }
        }
        else
                mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_AOT, "AOT loaded AOT Module for %s.\n", assembly->image->name);
}

/*
 * mono_aot_register_globals:
 *
 *   This is called by the ctor function in AOT images compiled with the
 * 'no-dlsym' option.
 */
void
mono_aot_register_globals (gpointer *globals)
{
        g_assert_not_reached ();
}

/*
 * mono_aot_register_module:
 *
 *   This should be called by embedding code to register AOT modules statically linked
 * into the executable. AOT_INFO should be the value of the 
 * 'mono_aot_module_<ASSEMBLY_NAME>_info' global symbol from the AOT module.
 */
void
mono_aot_register_module (gpointer *aot_info)
{
        gpointer *globals;
        char *aname;

        globals = aot_info;
        g_assert (globals);

        /* Determine the assembly name */
        find_symbol (NULL, globals, "mono_aot_assembly_name", (gpointer*)&aname);
        g_assert (aname);

        /* This could be called before startup */
        if (aot_modules)
                mono_aot_lock ();

        if (!static_aot_modules)
                static_aot_modules = g_hash_table_new (g_str_hash, g_str_equal);

        g_hash_table_insert (static_aot_modules, aname, globals);

        if (aot_modules)
                mono_aot_unlock ();
}

void
mono_aot_init (void)
{
        InitializeCriticalSection (&aot_mutex);
        aot_modules = g_hash_table_new (NULL, NULL);

        mono_install_assembly_load_hook (load_aot_module, NULL);

        if (g_getenv ("MONO_LASTAOT"))
                mono_last_aot_method = atoi (g_getenv ("MONO_LASTAOT"));
        if (g_getenv ("MONO_AOT_CACHE"))
                use_aot_cache = TRUE;
}

static gboolean
decode_cached_class_info (MonoAotModule *module, MonoCachedClassInfo *info, guint8 *buf, guint8 **endbuf)
{
        guint32 flags;

        info->vtable_size = decode_value (buf, &buf);
        if (info->vtable_size == -1)
                /* Generic type */
                return FALSE;
        flags = decode_value (buf, &buf);
        info->ghcimpl = (flags >> 0) & 0x1;
        info->has_finalize = (flags >> 1) & 0x1;
        info->has_cctor = (flags >> 2) & 0x1;
        info->has_nested_classes = (flags >> 3) & 0x1;
        info->blittable = (flags >> 4) & 0x1;
        info->has_references = (flags >> 5) & 0x1;
        info->has_static_refs = (flags >> 6) & 0x1;
        info->no_special_static_fields = (flags >> 7) & 0x1;
        info->is_generic_container = (flags >> 8) & 0x1;

        if (info->has_cctor) {
                MonoImage *cctor_image = decode_method_ref (module, &info->cctor_token, NULL, NULL, buf, &buf);
                if (!cctor_image)
                        return FALSE;
        }
        if (info->has_finalize) {
                info->finalize_image = decode_method_ref (module, &info->finalize_token, NULL, NULL, buf, &buf);
                if (!info->finalize_image)
                        return FALSE;
        }

        info->instance_size = decode_value (buf, &buf);
        info->class_size = decode_value (buf, &buf);
        info->packing_size = decode_value (buf, &buf);
        info->min_align = decode_value (buf, &buf);

        *endbuf = buf;

        return TRUE;
}       

gpointer
mono_aot_get_method_from_vt_slot (MonoDomain *domain, MonoVTable *vtable, int slot)
{
        int i;
        MonoClass *klass = vtable->klass;
        MonoAotModule *aot_module = klass->image->aot_module;
        guint8 *info, *p;
        MonoCachedClassInfo class_info;
        gboolean err;
        guint32 token;
        MonoImage *image;
        gboolean no_aot_trampoline;

        if (MONO_CLASS_IS_INTERFACE (klass) || klass->rank || !aot_module)
                return NULL;

        info = &aot_module->blob [mono_aot_get_offset (aot_module->class_info_offsets, mono_metadata_token_index (klass->type_token) - 1)];
        p = info;

        err = decode_cached_class_info (aot_module, &class_info, p, &p);
        if (!err)
                return NULL;

        for (i = 0; i < slot; ++i)
                decode_method_ref (aot_module, &token, NULL, NULL, p, &p);

        image = decode_method_ref (aot_module, &token, NULL, &no_aot_trampoline, p, &p);
        if (!image)
                return NULL;
        if (no_aot_trampoline)
                return NULL;

        if (mono_metadata_token_index (token) == 0)
                return NULL;

        return mono_aot_get_method_from_token (domain, image, token);
}

gboolean
mono_aot_get_cached_class_info (MonoClass *klass, MonoCachedClassInfo *res)
{
        MonoAotModule *aot_module = klass->image->aot_module;
        guint8 *p;
        gboolean err;

        if (klass->rank || !aot_module)
                return FALSE;

        p = (guint8*)&aot_module->blob [mono_aot_get_offset (aot_module->class_info_offsets, mono_metadata_token_index (klass->type_token) - 1)];

        err = decode_cached_class_info (aot_module, res, p, &p);
        if (!err)
                return FALSE;

        return TRUE;
}

/**
 * mono_aot_get_class_from_name:
 *
 *  Obtains a MonoClass with a given namespace and a given name which is located in IMAGE,
 * using a cache stored in the AOT file.
 * Stores the resulting class in *KLASS if found, stores NULL otherwise.
 *
 * Returns: TRUE if the klass was found/not found in the cache, FALSE if no aot file was 
 * found.
 */
gboolean
mono_aot_get_class_from_name (MonoImage *image, const char *name_space, const char *name, MonoClass **klass)
{
        MonoAotModule *aot_module = image->aot_module;
        guint16 *table, *entry;
        guint16 table_size;
        guint32 hash;
        char full_name_buf [1024];
        char *full_name;
        const char *name2, *name_space2;
        MonoTableInfo  *t;
        guint32 cols [MONO_TYPEDEF_SIZE];
        GHashTable *nspace_table;

        if (!aot_module || !aot_module->class_name_table)
                return FALSE;

        mono_aot_lock ();

        *klass = NULL;

        /* First look in the cache */
        if (!aot_module->name_cache)
                aot_module->name_cache = g_hash_table_new (g_str_hash, g_str_equal);
        nspace_table = g_hash_table_lookup (aot_module->name_cache, name_space);
        if (nspace_table) {
                *klass = g_hash_table_lookup (nspace_table, name);
                if (*klass) {
                        mono_aot_unlock ();
                        return TRUE;
                }
        }

        table_size = aot_module->class_name_table [0];
        table = aot_module->class_name_table + 1;

        if (name_space [0] == '\0')
                full_name = g_strdup_printf ("%s", name);
        else {
                if (strlen (name_space) + strlen (name) < 1000) {
                        sprintf (full_name_buf, "%s.%s", name_space, name);
                        full_name = full_name_buf;
                } else {
                        full_name = g_strdup_printf ("%s.%s", name_space, name);
                }
        }
        hash = mono_metadata_str_hash (full_name) % table_size;
        if (full_name != full_name_buf)
                g_free (full_name);

        entry = &table [hash * 2];

        if (entry [0] != 0) {
                t = &image->tables [MONO_TABLE_TYPEDEF];

                while (TRUE) {
                        guint32 index = entry [0];
                        guint32 next = entry [1];
                        guint32 token = mono_metadata_make_token (MONO_TABLE_TYPEDEF, index);

                        name_table_accesses ++;

                        mono_metadata_decode_row (t, index - 1, cols, MONO_TYPEDEF_SIZE);

                        name2 = mono_metadata_string_heap (image, cols [MONO_TYPEDEF_NAME]);
                        name_space2 = mono_metadata_string_heap (image, cols [MONO_TYPEDEF_NAMESPACE]);

                        if (!strcmp (name, name2) && !strcmp (name_space, name_space2)) {
                                mono_aot_unlock ();
                                *klass = mono_class_get (image, token);

                                /* Add to cache */
                                if (*klass) {
                                        mono_aot_lock ();
                                        nspace_table = g_hash_table_lookup (aot_module->name_cache, name_space);
                                        if (!nspace_table) {
                                                nspace_table = g_hash_table_new (g_str_hash, g_str_equal);
                                                g_hash_table_insert (aot_module->name_cache, (char*)name_space2, nspace_table);
                                        }
                                        g_hash_table_insert (nspace_table, (char*)name2, *klass);
                                        mono_aot_unlock ();
                                }
                                return TRUE;
                        }

                        if (next != 0) {
                                entry = &table [next * 2];
                        } else {
                                break;
                        }
                }
        }

        mono_aot_unlock ();
        
        return TRUE;
}

#define DW_EH_PE_omit   0xff
#define DW_EH_PE_uleb128 0x01
#define DW_EH_PE_udata2 0x02
#define DW_EH_PE_udata4 0x03
#define DW_EH_PE_udata8 0x04
#define DW_EH_PE_sleb128 0x09
#define DW_EH_PE_sdata2 0x0A
#define DW_EH_PE_sdata4 0x0B
#define DW_EH_PE_sdata8 0x0C

#define DW_EH_PE_absptr 0x00
#define DW_EH_PE_pcrel  0x10
#define DW_EH_PE_datarel 0x30
#define DW_EH_PE_omit   0xff

typedef struct
{
        guint8 version;
        guint8 eh_frame_ptr_enc;
        guint8 fde_count_enc;
        guint8 table_enc;
        guint8 rest;
} eh_frame_hdr;

/*
 * decode_eh_frame:
 *
 *   Decode the exception handling information in the .eh_frame section of the AOT
 * file belong to CODE, and construct a MonoJitInfo structure from it.
 * LOCKING: Acquires the domain lock.
 */
static G_GNUC_UNUSED MonoJitInfo*
decode_eh_frame (MonoAotModule *amodule, MonoDomain *domain, 
                                 MonoMethod *method, guint8 *code, MonoJitInfo *orig_jinfo,
                                 int extra_size)
{
        eh_frame_hdr *hdr;
        guint8 *p;
        guint8 *eh_frame, *unwind_info;
        guint32 eh_frame_ptr;
        int fde_count;
        gint32 *table;
        int i, pos, left, right, offset, offset1, offset2;
        guint32 unw_len, code_len;
        MonoJitExceptionInfo *ei;
        guint32 ei_len;
        gpointer *type_info;
        MonoJitInfo *jinfo;

        g_assert (amodule->eh_frame_hdr);

        // http://refspecs.freestandards.org/LSB_1.3.0/gLSB/gLSB/ehframehdr.html
        hdr = (eh_frame_hdr*)amodule->eh_frame_hdr;
        g_assert (hdr->version == 1);
        g_assert (hdr->eh_frame_ptr_enc == (DW_EH_PE_pcrel | DW_EH_PE_sdata4));
        g_assert (hdr->fde_count_enc == DW_EH_PE_udata4);
        g_assert (hdr->table_enc == (DW_EH_PE_datarel | DW_EH_PE_sdata4));

        p = &(hdr->rest);
        eh_frame_ptr = *(guint32*)p;
        p += 4;
        fde_count = *(guint32*)p;
        p += 4;
        table = (gint32*)p;

        /* Binary search in the table to find the entry for code */
        offset = code - amodule->eh_frame_hdr;

        left = 0;
        right = fde_count;
        while (TRUE) {
                pos = (left + right) / 2;

                offset1 = table [(pos * 2)];
                if (pos + 1 == fde_count)
                        /* FIXME: */
                        offset2 = amodule->code_end - amodule->code;
                else
                        offset2 = table [(pos + 1) * 2];

                if (offset < offset1)
                        right = pos;
                else if (offset >= offset2)
                        left = pos + 1;
                else
                        break;
        }

        g_assert (code >= amodule->eh_frame_hdr + table [(pos * 2)]);
        if (pos < fde_count)
                g_assert (code < amodule->eh_frame_hdr + table [(pos * 2) + 2]);

        eh_frame = amodule->eh_frame_hdr + table [(pos * 2) + 1];

        unwind_info = mono_unwind_decode_fde (eh_frame, &unw_len, &code_len, &ei, &ei_len, &type_info);

        /*
         * LLVM might represent one IL region with multiple regions, so have to
         * allocate a new JI.
         */
        if (ei_len) {
                jinfo = 
                        mono_domain_alloc0 (domain, MONO_SIZEOF_JIT_INFO + (sizeof (MonoJitExceptionInfo) * ei_len) + extra_size);
        } else {
                jinfo = orig_jinfo;
        }

        jinfo->code_size = code_len;
        jinfo->used_regs = mono_cache_unwind_info (unwind_info, unw_len);
        jinfo->method = method;
        jinfo->code_start = code;
        jinfo->domain_neutral = 0;
        /* This signals that used_regs points to a normal cached unwind info */
        jinfo->from_aot = 0;
        jinfo->num_clauses = ei_len;

        for (i = 0; i < ei_len; ++i) {
                /*
                 * orig_jinfo contains the original IL exception info saved by the AOT
                 * compiler, we have to combine that with the information produced by LLVM
                 */
                /* The type_info entries contain IL clause indexes */
                int clause_index = *(gint32*)type_info [i];
                MonoJitExceptionInfo *jei = &jinfo->clauses [i];
                MonoJitExceptionInfo *orig_jei = &orig_jinfo->clauses [clause_index];

                g_assert (clause_index < orig_jinfo->num_clauses);
                jei->flags = orig_jei->flags;
                jei->data.catch_class = orig_jei->data.catch_class;

                jei->try_start = ei [i].try_start;
                jei->try_end = ei [i].try_end;
                jei->handler_start = ei [i].handler_start;
        }

        return jinfo;
}
 
#ifdef TARGET_ARM

/* The offsets in the table are 31 bits long, have to extend them to 32 */
#define EXTEND_PREL31(val) ((((gint32)(val)) << 1) >> 1)

static inline guint32
decode_uleb128 (guint8 *buf, guint8 **endbuf)
{
        guint8 *p = buf;
        guint32 res = 0;
        int shift = 0;

        while (TRUE) {
                guint8 b = *p;
                p ++;

                res = res | (((int)(b & 0x7f)) << shift);
                if (!(b & 0x80))
                        break;
                shift += 7;
        }

        *endbuf = p;

        return res;
}

static GSList*
decode_arm_eh_ops (guint8 *unwind_ops, int nops)
{
        int i, vsp_reg, vsp_offset;
        GSList *ops;
        gint32 *reg_offsets;

        /*
         * Have to convert the ARM unwind info into DWARF unwind info.
         * The ARM unwind info specifies a simple set of instructions which need to be
         * executed during unwinding. It manipulates a virtual stack pointer (vsp). The
         * connection with DWARF unwind info is the following: after all ARM unwind
         * opcodes have been executed, the stack should be completely unwound, i.e.
         * vsp == DWARF CFA. This allows us to construct the DWARF opcodes corresponding
         * to the ARM opcodes.
         * The ARM unwind info is not instruction precise, i. e. it can't handle
         * async exceptions etc.
         */
        /* The reg used to compute the initial value of vsp */
        vsp_reg = ARMREG_SP;
        /* The offset between vsp_reg and the CFA */
        vsp_offset = 0;

        /* The register save offsets from the initial value of vsp */
        reg_offsets = g_new0 (gint32, 16);
        for (i = 0; i < 16; ++i)
                reg_offsets [i] = -1;

        /* section 9.3 in the ehabi doc */
        for (i = 0; i < nops; ++i) {
                guint8 op = unwind_ops [i];

                if ((op >> 6) == 0) {
                        /* vsp = vsp + (xxxxxx << 2) + 4. */
                        vsp_offset += ((op & 0x3f) << 2) + 4;
                } else if ((op >> 6) == 1) {
                        /* vsp = vsp - (xxxxxx << 2) - 4. */
                        vsp_offset -= ((op & 0x3f) << 2) + 4;
                } else if (op == 0xb2) {
                        /* vsp = vsp = vsp + 0x204 + (uleb128 << 2) */
                        guint8 *p = unwind_ops + i + 1;
                        guint32 v = decode_uleb128 (p, &p);

                        vsp_offset += 0x204 + (v << 2);
                        i = (p - unwind_ops) - 1;
                } else if (op >= 0x80 && op <= 0x8f) {
                        /* pop registers */
                        guint8 op2;
                        GSList *regs;
                        int j;

                        g_assert (i + 1 < nops);
                        op2 = unwind_ops [i + 1];

                        regs = NULL;
                        for (j = 0; j < 8; ++j)
                                if (op2 & (0x1 << j))
                                        regs = g_slist_append (regs, GUINT_TO_POINTER (ARMREG_R4 + j));
                        for (j = 0; j < 4; ++j)
                                if (op & (0x1 << j))
                                        regs = g_slist_append (regs, GUINT_TO_POINTER (ARMREG_R12 + j));
                        g_assert (regs);

                        for (j = 0; j < g_slist_length (regs); ++j)
                                reg_offsets [GPOINTER_TO_UINT (g_slist_nth (regs, j)->data)] = vsp_offset + (j * 4);

                        vsp_offset += g_slist_length (regs) * 4;

                        g_slist_free (regs);

                        i ++;
                } else if (op >= 0xa8 && op <= 0xaf) {
                        GSList *regs;
                        int j;

                        /* pop r4-r[4 + nnn], r14 */

                        regs = NULL;
                        for (j = 0; j <= (op & 0x7); ++j)
                                regs = g_slist_append (regs, GUINT_TO_POINTER (ARMREG_R4 + j));
                        regs = g_slist_append (regs, GUINT_TO_POINTER (ARMREG_R14));

                        for (j = 0; j < g_slist_length (regs); ++j)
                                reg_offsets [GPOINTER_TO_UINT (g_slist_nth (regs, j)->data)] = vsp_offset + (j * 4);

                        vsp_offset += g_slist_length (regs) * 4;

                        g_slist_free (regs);
                } else if (op == 0xb0) {
                        /* finish */
                        break;
                } else if (op >= 0x90 && op <= 0x9f && op != 0x9d && op != 0x9f) {
                        /* vsp = <reg> */
                        vsp_reg = op & 0xf;
                        vsp_offset = 0;
                } else {
                        int j;

                        for (j = 0; j < nops; ++j)
                                printf ("%x ", unwind_ops [j]);
                        printf (" / %d\n", i);
                        g_assert_not_reached ();
                }
        }

        ops = NULL;

        /* vsp_reg + vsp_offset = CFA */
        mono_add_unwind_op_def_cfa (ops, (guint8*)NULL, (guint8*)NULL, vsp_reg, vsp_offset);

        for (i = 0; i < 16; ++i) {
                if (reg_offsets [i] != -1)
                        /* The reg is saved at vsp_reg + reg_offset [i] == CFA - (vsp_offset - reg_offset [i]) */
                        mono_add_unwind_op_offset (ops, (guint8*)NULL, (guint8*)NULL, i, - (vsp_offset - reg_offsets [i]));
        }

        return ops;
}

/*
 * decode_arm_exidx:
 *
 *   Decode the exception handling information in the .ARM.exidx section of the AOT
 * file belong to CODE, and construct a MonoJitInfo structure from it.
 * LOCKING: Acquires the domain lock.
 */
static void
decode_arm_exidx (MonoAotModule *amodule, MonoDomain *domain, 
                                  MonoMethod *method, guint8 *code, guint32 code_len, MonoJitInfo *jinfo)
{
        guint32 *table;
        guint8 *base, *code1, *code2;
        int i, pos, left, right, offset, offset1, offset2, count, nwords, nops;
        guint32 entry;
        guint8 unwind_ops [64];
        GSList *ops;
        guint8 *unwind_info;
        guint32 unw_len;

        g_assert (amodule->arm_exidx);

        table = (guint32*)amodule->arm_exidx;

        /* 
         * The table format is described in:
         * infocenter.arm.com/help/topic/com.arm.doc.../IHI0038A_ehabi.pdf
         */

        base = amodule->arm_exidx;
        count = amodule->arm_exidx_size / 8;

        /* Binary search in the table to find the entry for code */
        offset = code - base;

        left = 0;
        right = count;
        while (TRUE) {
                pos = (left + right) / 2;

                if (left == right)
                        break;

                offset1 = EXTEND_PREL31 (table [(pos * 2)]);
                code1 = (guint8*)&(table [pos * 2]) + offset1;
                if (pos + 1 == count)
                        /* FIXME: */
                        offset2 = amodule->code_end - amodule->code;
                else
                        offset2 = EXTEND_PREL31 (table [(pos + 1) * 2]);
                code2 = (guint8*)&(table [(pos + 1) * 2]) + offset2;

                if (code < code1)
                        right = pos;
                else if (code >= code2)
                        left = pos + 1;
                else
                        break;
        }

        if (code >= code1) {
                /* 
                 * The linker might merge duplicate unwind table entries, so
                 * offset1 and offset2 might point to another method, but this is not a problem.
                 */
                code1 = (guint8*)&(table [pos * 2]) + offset1;
                code2 = (guint8*)&(table [(pos + 1) * 2]) + offset2;

                g_assert (code >= code1);
                if (pos < count)
                        g_assert (code < code2);

                entry = table [(pos * 2) + 1];

                /* inline entry, compact model, personality routine 0 */
                if ((entry & 0xff000000) == 0x80000000) {
                        nops = 3;
                        unwind_ops [0] = (entry & 0x00ff0000) >> 16;
                        unwind_ops [1] = (entry & 0x0000ff00) >> 8;
                        unwind_ops [2] = (entry & 0x000000ff) >> 0;

                        ops = decode_arm_eh_ops (unwind_ops, nops);
                } else if ((entry & 0x80000000) == 0) {
                        /* non-inline entry */
                        guint8 *data = (guint8*)&table [(pos * 2) + 1] + EXTEND_PREL31 (entry);

                        entry = ((guint32*)data) [0];

                        /* compact model, personality routine 1 */
                        g_assert ((entry & 0xff000000) == 0x81000000);

                        nwords = (entry & 0x00ff0000) >> 16;
                        nops = nwords * 4 + 2;
                        g_assert (nops < 64);

                        unwind_ops [0] = (entry & 0x0000ff00) >> 8;
                        unwind_ops [1] = (entry & 0x000000ff) >> 0;

                        for (i = 0; i < nwords; ++i) {
                                entry = ((guint32*)data) [1 + i];
                                unwind_ops [(i * 4) + 2] = (entry & 0xff000000) >> 24;
                                unwind_ops [(i * 4) + 2 + 1] = (entry & 0x00ff0000) >> 16;
                                unwind_ops [(i * 4) + 2 + 2] = (entry & 0x0000ff00) >> 8;
                                unwind_ops [(i * 4) + 2 + 3] = (entry & 0x000000ff) >> 0;
                        }

                        ops = decode_arm_eh_ops (unwind_ops, nops);
                } else {
                        NOT_IMPLEMENTED;
                }

                unwind_info = mono_unwind_ops_encode (ops, &unw_len);
        } else {
                /* The method has no unwind info */
                unwind_info = NULL;
                unw_len = 0;
        }

        jinfo->code_size = code_len;
        jinfo->used_regs = mono_cache_unwind_info (unwind_info, unw_len);
        jinfo->method = method;
        jinfo->code_start = code;
        jinfo->domain_neutral = 0;
        /* This signals that used_regs points to a normal cached unwind info */
        jinfo->from_aot = 0;
}
#endif

/*
 * LOCKING: Acquires the domain lock.
 */
static MonoJitInfo*
decode_exception_debug_info (MonoAotModule *amodule, MonoDomain *domain, 
                                                         MonoMethod *method, guint8* ex_info, guint8 *addr,
                                                         guint8 *code, guint32 code_len)
{
        int i, buf_len;
        MonoJitInfo *jinfo;
        guint used_int_regs, flags;
        gboolean has_generic_jit_info, has_dwarf_unwind_info, has_clauses, has_seq_points, has_try_block_holes;
        gboolean from_llvm;
        guint8 *p;
        int generic_info_size, try_holes_info_size, num_holes;

        /* Load the method info from the AOT file */

        p = ex_info;
        flags = decode_value (p, &p);
        has_generic_jit_info = (flags & 1) != 0;
        has_dwarf_unwind_info = (flags & 2) != 0;
        has_clauses = (flags & 4) != 0;
        has_seq_points = (flags & 8) != 0;
        from_llvm = (flags & 16) != 0;
        has_try_block_holes = (flags & 32) != 0;

        if (has_dwarf_unwind_info) {
                guint32 offset;

                offset = decode_value (p, &p);
                g_assert (offset < (1 << 30));
                used_int_regs = offset;
        } else {
                used_int_regs = decode_value (p, &p);
        }
        if (has_generic_jit_info)
                generic_info_size = sizeof (MonoGenericJitInfo);
        else
                generic_info_size = 0;

        if (has_try_block_holes) {
                num_holes = decode_value (p, &p);
                try_holes_info_size = sizeof (MonoTryBlockHoleTableJitInfo) + num_holes * sizeof (MonoTryBlockHoleJitInfo);
        } else {
                num_holes = try_holes_info_size = 0;
        }
        /* Exception table */
        if (has_clauses) {
                int num_clauses = decode_value (p, &p);

                jinfo = 
                        mono_domain_alloc0 (domain, MONO_SIZEOF_JIT_INFO + (sizeof (MonoJitExceptionInfo) * num_clauses) + generic_info_size + try_holes_info_size);
                jinfo->num_clauses = num_clauses;

                for (i = 0; i < num_clauses; ++i) {
                        MonoJitExceptionInfo *ei = &jinfo->clauses [i];

                        ei->flags = decode_value (p, &p);

                        if (from_llvm) {
                                if (decode_value (p, &p))
                                        ei->data.catch_class = decode_klass_ref (amodule, p, &p);

                                /* The rest of the info is in the DWARF EH section */
                                continue;
                        }

                        ei->exvar_offset = decode_value (p, &p);

                        if (ei->flags == MONO_EXCEPTION_CLAUSE_FILTER || ei->flags == MONO_EXCEPTION_CLAUSE_FINALLY)
                                ei->data.filter = code + decode_value (p, &p);
                        else {
                                if (decode_value (p, &p))
                                        ei->data.catch_class = decode_klass_ref (amodule, p, &p);
                        }

                        ei->try_start = code + decode_value (p, &p);
                        ei->try_end = code + decode_value (p, &p);
                        ei->handler_start = code + decode_value (p, &p);
                }
        }
        else {
                jinfo = mono_domain_alloc0 (domain, MONO_SIZEOF_JIT_INFO + generic_info_size + try_holes_info_size);
        }

        if (from_llvm) {
                /* LLVM compiled method */
                /* The info is in the .eh_frame section */
#ifdef TARGET_ARM
                decode_arm_exidx (amodule, domain, method, code, code_len, jinfo);
#else
                jinfo = decode_eh_frame (amodule, domain, method, code, jinfo, generic_info_size);
#endif
                jinfo->from_llvm = 1;
        } else {
                jinfo->code_size = code_len;
                jinfo->used_regs = used_int_regs;
                jinfo->method = method;
                jinfo->code_start = code;
                jinfo->domain_neutral = 0;
                jinfo->from_aot = 1;
        }

        if (has_generic_jit_info) {
                MonoGenericJitInfo *gi;

                jinfo->has_generic_jit_info = 1;

                gi = mono_jit_info_get_generic_jit_info (jinfo);
                g_assert (gi);

                gi->has_this = decode_value (p, &p);
                gi->this_reg = decode_value (p, &p);
                gi->this_offset = decode_value (p, &p);

                /* This currently contains no data */
                gi->generic_sharing_context = g_new0 (MonoGenericSharingContext, 1);

                jinfo->method = decode_method_ref_2 (amodule, p, &p);
        }

        if (has_try_block_holes) {
                MonoTryBlockHoleTableJitInfo *table;

                jinfo->has_try_block_holes = 1;

                table = mono_jit_info_get_try_block_hole_table_info (jinfo);
                g_assert (table);

                table->num_holes = (guint16)num_holes;
                for (i = 0; i < num_holes; ++i) {
                        MonoTryBlockHoleJitInfo *hole = &table->holes [i];
                        hole->clause = decode_value (p, &p);
                        hole->length = decode_value (p, &p);
                        hole->offset = decode_value (p, &p);
                }
        }

        if (has_seq_points) {
                MonoSeqPointInfo *seq_points;
                int il_offset, native_offset, last_il_offset, last_native_offset, j;

                int len = decode_value (p, &p);

                seq_points = g_malloc0 (sizeof (MonoSeqPointInfo) + (len - MONO_ZERO_LEN_ARRAY) * sizeof (SeqPoint));
                seq_points->len = len;
                last_il_offset = last_native_offset = 0;
                for (i = 0; i < len; ++i) {
                        SeqPoint *sp = &seq_points->seq_points [i];
                        il_offset = last_il_offset + decode_value (p, &p);
                        native_offset = last_native_offset + decode_value (p, &p);

                        sp->il_offset = il_offset;
                        sp->native_offset = native_offset;
                        
                        sp->next_len = decode_value (p, &p);
                        sp->next = g_new (int, sp->next_len);
                        for (j = 0; j < sp->next_len; ++j)
                                sp->next [j] = decode_value (p, &p);

                        last_il_offset = il_offset;
                        last_native_offset = native_offset;
                }

                mono_domain_lock (domain);
                g_hash_table_insert (domain_jit_info (domain)->seq_points, method, seq_points);
                mono_domain_unlock (domain);
        }

        /* Load debug info */
        buf_len = decode_value (p, &p);
        mono_debug_add_aot_method (domain, method, code, p, buf_len);

        if (amodule != jinfo->method->klass->image->aot_module) {
                mono_aot_lock ();
                if (!ji_to_amodule)
                        ji_to_amodule = g_hash_table_new (NULL, NULL);
                g_hash_table_insert (ji_to_amodule, jinfo, amodule);
                mono_aot_unlock ();             
        }
        
        return jinfo;
}

/*
 * mono_aot_get_unwind_info:
 *
 *   Return a pointer to the DWARF unwind info belonging to JI.
 */
guint8*
mono_aot_get_unwind_info (MonoJitInfo *ji, guint32 *unwind_info_len)
{
        MonoAotModule *amodule = ji->method->klass->image->aot_module;
        guint8 *p;
        guint8 *code = ji->code_start;

        g_assert (amodule);
        g_assert (ji->from_aot);

        if (!(code >= amodule->code && code <= amodule->code_end)) {
                /* ji belongs to a different aot module than amodule */
                mono_aot_lock ();
                g_assert (ji_to_amodule);
                amodule = g_hash_table_lookup (ji_to_amodule, ji);
                g_assert (amodule);
                g_assert (code >= amodule->code && code <= amodule->code_end);
                mono_aot_unlock ();
        }

        p = amodule->unwind_info + ji->used_regs;
        *unwind_info_len = decode_value (p, &p);
        return p;
}

static G_GNUC_UNUSED int
compare_ints (const void *a, const void *b)
{
        return *(gint32*)a - *(gint32*)b;
}

static void
msort_code_offsets_internal (gint32 *array, int lo, int hi, gint32 *scratch)
{
        int mid = (lo + hi) / 2;
        int i, t_lo, t_hi;

        if (lo >= hi)
                return;

        if (hi - lo < 32) {
                for (i = lo; i < hi; ++i)
                        if (array [(i * 2)] > array [(i * 2) + 2])
                                break;
                if (i == hi)
                        /* Already sorted */
                        return;
        }

        msort_code_offsets_internal (array, lo, mid, scratch);
        msort_code_offsets_internal (array, mid + 1, hi, scratch);

        if (array [mid * 2] < array [(mid + 1) * 2])
                return;

        /* Merge */
        t_lo = lo;
        t_hi = mid + 1;
        for (i = lo; i <= hi; i ++) {
                if (t_lo <= mid && ((t_hi > hi) || array [t_lo * 2] < array [t_hi * 2])) {
                        scratch [(i * 2)] = array [t_lo * 2];
                        scratch [(i * 2) + 1] = array [(t_lo *2) + 1];
                        t_lo ++;
                } else {
                        scratch [(i * 2)] = array [t_hi * 2];
                        scratch [(i * 2) + 1] = array [(t_hi *2) + 1];
                        t_hi ++;
                }
        }
        for (i = lo; i <= hi; ++i) {
                array [(i * 2)] = scratch [i * 2];
                array [(i * 2) + 1] = scratch [(i * 2) + 1];
        }
}

static void
msort_code_offsets (gint32 *array, int len)
{
        gint32 *scratch;

        scratch = g_new (gint32, len * 2);
        msort_code_offsets_internal (array, 0, len - 1, scratch);
        g_free (scratch);
}

MonoJitInfo *
mono_aot_find_jit_info (MonoDomain *domain, MonoImage *image, gpointer addr)
{
        int pos, left, right, offset, offset1, offset2, code_len;
        int method_index, table_len, is_wrapper;
        guint32 token;
        MonoAotModule *amodule = image->aot_module;
        MonoMethod *method;
        MonoJitInfo *jinfo;
        guint8 *code, *ex_info, *p;
        guint32 *table;
        int nmethods = amodule->info.nmethods;
        gint32 *code_offsets;
        int offsets_len, i;

        if (!amodule)
                return NULL;

        if (domain != mono_get_root_domain ())
                /* FIXME: */
                return NULL;

        offset = (guint8*)addr - amodule->code;

        /* Compute a sorted table mapping code offsets to method indexes. */
        if (!amodule->sorted_code_offsets) {

                code_offsets = g_new0 (gint32, nmethods * 2);
                offsets_len = 0;
                for (i = 0; i < nmethods; ++i) {
                        /* Skip the -1 entries to speed up sorting */
                        if (amodule->code_offsets [i] == 0xffffffff)
                                continue;
                        code_offsets [(offsets_len * 2)] = amodule->code_offsets [i];
                        code_offsets [(offsets_len *2) + 1] = i;
                        offsets_len ++;
                }
                /* Use a merge sort as this is mostly sorted */
                msort_code_offsets (code_offsets, offsets_len);
                //qsort (code_offsets, offsets_len, sizeof (gint32) * 2, compare_ints);
                for (i = 0; i < offsets_len -1; ++i)
                        g_assert (code_offsets [(i * 2)] <= code_offsets [(i + 1) * 2]);

                if (InterlockedCompareExchangePointer ((gpointer*)&amodule->sorted_code_offsets, code_offsets, NULL) != NULL)
                        /* Somebody got in before us */
                        g_free (code_offsets);
                amodule->sorted_code_offsets_len = offsets_len;
        }

        code_offsets = amodule->sorted_code_offsets;
        offsets_len = amodule->sorted_code_offsets_len;

        /* Binary search in the sorted_code_offsets table */
        left = 0;
        right = offsets_len;
        while (TRUE) {
                pos = (left + right) / 2;

                offset1 = code_offsets [(pos * 2)];
                if (pos + 1 == offsets_len)
                        offset2 = amodule->code_end - amodule->code;
                else
                        offset2 = code_offsets [(pos + 1) * 2];

                if (offset < offset1)
                        right = pos;
                else if (offset >= offset2)
                        left = pos + 1;
                else
                        break;
        }

        g_assert (offset >= code_offsets [(pos * 2)]);
        if (pos + 1 < offsets_len)
                g_assert (offset < code_offsets [((pos + 1) * 2)]);
        method_index = code_offsets [(pos * 2) + 1];

        code = &amodule->code [amodule->code_offsets [method_index]];
        ex_info = &amodule->blob [mono_aot_get_offset (amodule->ex_info_offsets, method_index)];

        if (pos == offsets_len - 1)
                code_len = amodule->code_end - code;
        else
                code_len = code_offsets [(pos + 1) * 2] - code_offsets [pos * 2];

        g_assert ((guint8*)code <= (guint8*)addr && (guint8*)addr < (guint8*)code + code_len);

        /* Might be a wrapper/extra method */
        if (amodule->extra_methods) {
                mono_aot_lock ();
                method = g_hash_table_lookup (amodule->extra_methods, GUINT_TO_POINTER (method_index));
                mono_aot_unlock ();
        } else {
                method = NULL;
        }

        if (!method) {
                if (method_index >= image->tables [MONO_TABLE_METHOD].rows) {
                        /* 
                         * This is hit for extra methods which are called directly, so they are
                         * not in amodule->extra_methods.
                         */
                        table_len = amodule->extra_method_info_offsets [0];
                        table = amodule->extra_method_info_offsets + 1;
                        left = 0;
                        right = table_len;
                        pos = 0;

                        /* Binary search */
                        while (TRUE) {
                                pos = ((left + right) / 2);

                                g_assert (pos < table_len);

                                if (table [pos * 2] < method_index)
                                        left = pos + 1;
                                else if (table [pos * 2] > method_index)
                                        right = pos;
                                else
                                        break;
                        }

                        p = amodule->blob + table [(pos * 2) + 1];
                        is_wrapper = decode_value (p, &p);
                        g_assert (!is_wrapper);
                        method = decode_method_ref_2 (amodule, p, &p);
                        g_assert (method);
                } else {
                        token = mono_metadata_make_token (MONO_TABLE_METHOD, method_index + 1);
                        method = mono_get_method (image, token, NULL);
                }
        }

        /* FIXME: */
        g_assert (method);

        //printf ("F: %s\n", mono_method_full_name (method, TRUE));
        
        jinfo = decode_exception_debug_info (amodule, domain, method, ex_info, addr, code, code_len);

        g_assert ((guint8*)addr >= (guint8*)jinfo->code_start);
        g_assert ((guint8*)addr < (guint8*)jinfo->code_start + jinfo->code_size);

        /* Add it to the normal JitInfo tables */
        mono_jit_info_table_add (domain, jinfo);
        
        return jinfo;
}

static gboolean
decode_patch (MonoAotModule *aot_module, MonoMemPool *mp, MonoJumpInfo *ji, guint8 *buf, guint8 **endbuf)
{
        guint8 *p = buf;
        gpointer *table;
        MonoImage *image;
        int i;

        switch (ji->type) {
        case MONO_PATCH_INFO_METHOD:
        case MONO_PATCH_INFO_METHOD_JUMP:
        case MONO_PATCH_INFO_ICALL_ADDR:
        case MONO_PATCH_INFO_METHOD_RGCTX: {
                guint32 token;
                MonoMethod *method;
                gboolean no_aot_trampoline;

                image = decode_method_ref (aot_module, &token, &method, &no_aot_trampoline, p, &p);
                if (!image)
                        goto cleanup;

                if (!method && !mono_aot_only && !no_aot_trampoline && (ji->type == MONO_PATCH_INFO_METHOD) && (mono_metadata_token_table (token) == MONO_TABLE_METHOD)) {
                        ji->data.target = mono_create_ftnptr (mono_domain_get (), mono_create_jit_trampoline_from_token (image, token));
                        ji->type = MONO_PATCH_INFO_ABS;
                }
                else {
                        if (method)
                                ji->data.method = method;
                        else
                                ji->data.method = mono_get_method (image, token, NULL);
                        g_assert (ji->data.method);
                        mono_class_init (ji->data.method->klass);
                }
                break;
        }
        case MONO_PATCH_INFO_INTERNAL_METHOD:
        case MONO_PATCH_INFO_JIT_ICALL_ADDR: {
                guint32 len = decode_value (p, &p);

                ji->data.name = (char*)p;
                p += len + 1;
                break;
        }
        case MONO_PATCH_INFO_METHODCONST:
                /* Shared */
                ji->data.method = decode_method_ref_2 (aot_module, p, &p);
                if (!ji->data.method)
                        goto cleanup;
                break;
        case MONO_PATCH_INFO_VTABLE:
        case MONO_PATCH_INFO_CLASS:
        case MONO_PATCH_INFO_IID:
        case MONO_PATCH_INFO_ADJUSTED_IID:
                /* Shared */
                ji->data.klass = decode_klass_ref (aot_module, p, &p);
                if (!ji->data.klass)
                        goto cleanup;
                break;
        case MONO_PATCH_INFO_CLASS_INIT:
        case MONO_PATCH_INFO_DELEGATE_TRAMPOLINE:
                ji->data.klass = decode_klass_ref (aot_module, p, &p);
                if (!ji->data.klass)
                        goto cleanup;
                break;
        case MONO_PATCH_INFO_IMAGE:
                ji->data.image = load_image (aot_module, decode_value (p, &p), TRUE);
                if (!ji->data.image)
                        goto cleanup;
                break;
        case MONO_PATCH_INFO_FIELD:
        case MONO_PATCH_INFO_SFLDA:
                /* Shared */
                ji->data.field = decode_field_info (aot_module, p, &p);
                if (!ji->data.field)
                        goto cleanup;
                break;
        case MONO_PATCH_INFO_SWITCH:
                ji->data.table = mono_mempool_alloc0 (mp, sizeof (MonoJumpInfoBBTable));
                ji->data.table->table_size = decode_value (p, &p);
                table = mono_domain_alloc (mono_domain_get (), sizeof (gpointer) * ji->data.table->table_size);
                ji->data.table->table = (MonoBasicBlock**)table;
                for (i = 0; i < ji->data.table->table_size; i++)
                        table [i] = (gpointer)(gssize)decode_value (p, &p);
                break;
        case MONO_PATCH_INFO_R4: {
                guint32 val;
                
                ji->data.target = mono_domain_alloc0 (mono_domain_get (), sizeof (float));
                val = decode_value (p, &p);
                *(float*)ji->data.target = *(float*)&val;
                break;
        }
        case MONO_PATCH_INFO_R8: {
                guint32 val [2];
                guint64 v;

                ji->data.target = mono_domain_alloc0 (mono_domain_get (), sizeof (double));

                val [0] = decode_value (p, &p);
                val [1] = decode_value (p, &p);
                v = ((guint64)val [1] << 32) | ((guint64)val [0]);
                *(double*)ji->data.target = *(double*)&v;
                break;
        }
        case MONO_PATCH_INFO_LDSTR:
                image = load_image (aot_module, decode_value (p, &p), TRUE);
                if (!image)
                        goto cleanup;
                ji->data.token = mono_jump_info_token_new (mp, image, MONO_TOKEN_STRING + decode_value (p, &p));
                break;
        case MONO_PATCH_INFO_RVA:
        case MONO_PATCH_INFO_DECLSEC:
        case MONO_PATCH_INFO_LDTOKEN:
        case MONO_PATCH_INFO_TYPE_FROM_HANDLE:
                /* Shared */
                image = load_image (aot_module, decode_value (p, &p), TRUE);
                if (!image)
                        goto cleanup;
                ji->data.token = mono_jump_info_token_new (mp, image, decode_value (p, &p));

                ji->data.token->has_context = decode_value (p, &p);
                if (ji->data.token->has_context) {
                        gboolean res = decode_generic_context (aot_module, &ji->data.token->context, p, &p);
                        if (!res)
                                goto cleanup;
                }
                break;
        case MONO_PATCH_INFO_EXC_NAME:
                ji->data.klass = decode_klass_ref (aot_module, p, &p);
                if (!ji->data.klass)
                        goto cleanup;
                ji->data.name = ji->data.klass->name;
                break;
        case MONO_PATCH_INFO_METHOD_REL:
                ji->data.offset = decode_value (p, &p);
                break;
        case MONO_PATCH_INFO_INTERRUPTION_REQUEST_FLAG:
        case MONO_PATCH_INFO_GENERIC_CLASS_INIT:
        case MONO_PATCH_INFO_MONITOR_ENTER:
        case MONO_PATCH_INFO_MONITOR_EXIT:
                break;
        case MONO_PATCH_INFO_RGCTX_FETCH: {
                gboolean res;
                MonoJumpInfoRgctxEntry *entry;

                entry = mono_mempool_alloc0 (mp, sizeof (MonoJumpInfoRgctxEntry));
                entry->method = decode_method_ref_2 (aot_module, p, &p);
                entry->in_mrgctx = decode_value (p, &p);
                entry->info_type = decode_value (p, &p);
                entry->data = mono_mempool_alloc0 (mp, sizeof (MonoJumpInfo));
                entry->data->type = decode_value (p, &p);
                
                res = decode_patch (aot_module, mp, entry->data, p, &p);
                if (!res)
                        goto cleanup;
                ji->data.rgctx_entry = entry;
                break;
        }
        case MONO_PATCH_INFO_SEQ_POINT_INFO:
                break;
        case MONO_PATCH_INFO_LLVM_IMT_TRAMPOLINE: {
                MonoJumpInfoImtTramp *imt_tramp = mono_mempool_alloc0 (mp, sizeof (MonoJumpInfoImtTramp));

                imt_tramp->method = decode_method_ref_2 (aot_module, p, &p);
                imt_tramp->vt_offset = decode_value (p, &p);
                
                ji->data.imt_tramp = imt_tramp;
                break;
        }
        default:
                g_warning ("unhandled type %d", ji->type);
                g_assert_not_reached ();
        }

        *endbuf = p;

        return TRUE;

 cleanup:
        return FALSE;
}

static MonoJumpInfo*
load_patch_info (MonoAotModule *aot_module, MonoMemPool *mp, int n_patches, 
                                 guint32 **got_slots, 
                                 guint8 *buf, guint8 **endbuf)
{
        MonoJumpInfo *patches;
        int pindex;
        guint8 *p;

        p = buf;

        patches = mono_mempool_alloc0 (mp, sizeof (MonoJumpInfo) * n_patches);

        *got_slots = g_malloc (sizeof (guint32) * n_patches);

        for (pindex = 0; pindex < n_patches; ++pindex) {
                MonoJumpInfo *ji = &patches [pindex];
                guint8 *shared_p;
                gboolean res;
                guint32 got_offset;

                got_offset = decode_value (p, &p);

                if (aot_module->got [got_offset]) {
                        /* Already loaded */
                        //printf ("HIT!\n");
                } else {
                        shared_p = aot_module->blob + mono_aot_get_offset (aot_module->got_info_offsets, got_offset);

                        ji->type = decode_value (shared_p, &shared_p);

                        res = decode_patch (aot_module, mp, ji, shared_p, &shared_p);
                        if (!res)
                                goto cleanup;
                }

                (*got_slots) [pindex] = got_offset;
        }

        *endbuf = p;
        return patches;

 cleanup:
        g_free (*got_slots);
        *got_slots = NULL;

        return NULL;
}

static void
register_jump_target_got_slot (MonoDomain *domain, MonoMethod *method, gpointer *got_slot)
{
        /*
         * Jump addresses cannot be patched by the trampoline code since it
         * does not have access to the caller's address. Instead, we collect
         * the addresses of the GOT slots pointing to a method, and patch
         * them after the method has been compiled.
         */
        MonoJitDomainInfo *info = domain_jit_info (domain);
        GSList *list;
                
        mono_domain_lock (domain);
        if (!info->jump_target_got_slot_hash)
                info->jump_target_got_slot_hash = g_hash_table_new (NULL, NULL);
        list = g_hash_table_lookup (info->jump_target_got_slot_hash, method);
        list = g_slist_prepend (list, got_slot);
        g_hash_table_insert (info->jump_target_got_slot_hash, method, list);
        mono_domain_unlock (domain);
}

/*
 * load_method:
 *
 *   Load the method identified by METHOD_INDEX from the AOT image. Return a
 * pointer to the native code of the method, or NULL if not found.
 * METHOD might not be set if the caller only has the image/token info.
 */
static gpointer
load_method (MonoDomain *domain, MonoAotModule *amodule, MonoImage *image, MonoMethod *method, guint32 token, int method_index)
{
        MonoClass *klass;
        gboolean from_plt = method == NULL;
        MonoMemPool *mp;
        int i, pindex, n_patches, used_strings;
        gboolean keep_patches = TRUE;
        guint8 *p;
        MonoJitInfo *jinfo = NULL;
        guint8 *code, *info;

        if (mono_profiler_get_events () & MONO_PROFILE_ENTER_LEAVE)
                return NULL;

        if ((domain != mono_get_root_domain ()) && (!(amodule->info.opts & MONO_OPT_SHARED)))
                /* Non shared AOT code can't be used in other appdomains */
                return NULL;

        if (amodule->out_of_date)
                return NULL;

        if (amodule->code_offsets [method_index] == 0xffffffff) {
                if (mono_trace_is_traced (G_LOG_LEVEL_DEBUG, MONO_TRACE_AOT)) {
                        char *full_name;

                        if (!method)
                                method = mono_get_method (image, token, NULL);
                        full_name = mono_method_full_name (method, TRUE);
                        mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_AOT, "AOT NOT FOUND: %s.\n", full_name);
                        g_free (full_name);
                }
                return NULL;
        }

        code = &amodule->code [amodule->code_offsets [method_index]];

        info = &amodule->blob [mono_aot_get_offset (amodule->method_info_offsets, method_index)];

        mono_aot_lock ();
        if (!amodule->methods_loaded)
                amodule->methods_loaded = g_new0 (guint32, amodule->info.nmethods + 1);
        mono_aot_unlock ();

        if ((amodule->methods_loaded [method_index / 32] >> (method_index % 32)) & 0x1)
                return code;

        if (mono_last_aot_method != -1) {
                if (mono_jit_stats.methods_aot >= mono_last_aot_method)
                                return NULL;
                else if (mono_jit_stats.methods_aot == mono_last_aot_method - 1) {
                        if (!method)
                                method = mono_get_method (image, token, NULL);
                        if (method) {
                                char *name = mono_method_full_name (method, TRUE);
                                printf ("LAST AOT METHOD: %s.\n", name);
                                g_free (name);
                        } else {
                                printf ("LAST AOT METHOD: %p %d\n", code, method_index);
                        }
                }
        }

        p = info;

        if (method) {
                klass = method->klass;
                decode_klass_ref (amodule, p, &p);
        } else {
                klass = decode_klass_ref (amodule, p, &p);
        }

        if (amodule->info.opts & MONO_OPT_SHARED)
                used_strings = decode_value (p, &p);
        else
                used_strings = 0;

        for (i = 0; i < used_strings; i++) {
                guint token = decode_value (p, &p);
                mono_ldstr (mono_get_root_domain (), image, mono_metadata_token_index (token));
        }

        if (amodule->info.opts & MONO_OPT_SHARED)       
                keep_patches = FALSE;

        n_patches = decode_value (p, &p);

        keep_patches = FALSE;

        if (n_patches) {
                MonoJumpInfo *patches;
                guint32 *got_slots;

                if (keep_patches)
                        mp = domain->mp;
                else
                        mp = mono_mempool_new ();

                patches = load_patch_info (amodule, mp, n_patches, &got_slots, p, &p);
                if (patches == NULL)
                        goto cleanup;

                for (pindex = 0; pindex < n_patches; ++pindex) {
                        MonoJumpInfo *ji = &patches [pindex];

                        if (!amodule->got [got_slots [pindex]]) {
                                amodule->got [got_slots [pindex]] = mono_resolve_patch_target (method, domain, code, ji, TRUE);
                                if (ji->type == MONO_PATCH_INFO_METHOD_JUMP)
                                        amodule->got [got_slots [pindex]] = mono_create_ftnptr (domain, amodule->got [got_slots [pindex]]);
                                if (ji->type == MONO_PATCH_INFO_METHOD_JUMP)
                                        register_jump_target_got_slot (domain, ji->data.method, &(amodule->got [got_slots [pindex]]));
                        }
                        ji->type = MONO_PATCH_INFO_NONE;
                }

                g_free (got_slots);

                if (!keep_patches)
                        mono_mempool_destroy (mp);
        }

        if (mono_trace_is_traced (G_LOG_LEVEL_DEBUG, MONO_TRACE_AOT)) {
                char *full_name;

                if (!method)
                        method = mono_get_method (image, token, NULL);

                full_name = mono_method_full_name (method, TRUE);

                if (!jinfo)
                        jinfo = mono_aot_find_jit_info (domain, amodule->assembly->image, code);

                mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_AOT, "AOT FOUND AOT compiled code for %s %p - %p %p\n", full_name, code, code + jinfo->code_size, info);
                g_free (full_name);
        }

        mono_aot_lock ();

        mono_jit_stats.methods_aot++;

        amodule->methods_loaded [method_index / 32] |= 1 << (method_index % 32);

        init_plt (amodule);

        if (method && method->wrapper_type)
                g_hash_table_insert (amodule->method_to_code, method, code);

        mono_aot_unlock ();

        if (mono_profiler_get_events () & MONO_PROFILE_JIT_COMPILATION) {
                MonoJitInfo *jinfo;

                if (!method) {
                        method = mono_get_method (image, token, NULL);
                        g_assert (method);
                }
                mono_profiler_method_jit (method);
                jinfo = mono_jit_info_table_find (domain, (char*)code);
                g_assert (jinfo);
                mono_profiler_method_end_jit (method, jinfo, MONO_PROFILE_OK);
        }

        if (from_plt && klass && !klass->generic_container)
                mono_runtime_class_init (mono_class_vtable (domain, klass));

        return code;

 cleanup:
        /* FIXME: The space in domain->mp is wasted */  
        if (amodule->info.opts & MONO_OPT_SHARED)
                /* No need to cache patches */
                mono_mempool_destroy (mp);

        if (jinfo)
                g_free (jinfo);

        return NULL;
}

static guint32
find_extra_method_in_amodule (MonoAotModule *amodule, MonoMethod *method, const char *name)
{
        guint32 table_size, entry_size, hash;
        guint32 *table, *entry;
        guint32 index;
        static guint32 n_extra_decodes;

        if (!amodule)
                return 0xffffff;

        table_size = amodule->extra_method_table [0];
        table = amodule->extra_method_table + 1;
        entry_size = 3;

        hash = mono_aot_method_hash (method) % table_size;

        entry = &table [hash * entry_size];

        if (entry [0] == 0)
                return 0xffffff;

        index = 0xffffff;
        while (TRUE) {
                guint32 key = entry [0];
                guint32 value = entry [1];
                guint32 next = entry [entry_size - 1];
                MonoMethod *m;
                guint8 *p;
                int is_wrapper_name;

                p = amodule->blob + key;
                is_wrapper_name = decode_value (p, &p);
                if (is_wrapper_name) {
                        int wrapper_type = decode_value (p, &p);
                        if (wrapper_type == method->wrapper_type && !strcmp (name, (char*)p)) {
                                index = value;
                                break;
                        }
                } else if (can_method_ref_match_method (amodule, p, method)) {
                        mono_aot_lock ();
                        if (!amodule->method_ref_to_method)
                                amodule->method_ref_to_method = g_hash_table_new (NULL, NULL);
                        m = g_hash_table_lookup (amodule->method_ref_to_method, p);
                        mono_aot_unlock ();
                        if (!m) {
                                guint8 *orig_p = p;
                                m = decode_method_ref_2 (amodule, p, &p);
                                if (m) {
                                        mono_aot_lock ();
                                        g_hash_table_insert (amodule->method_ref_to_method, orig_p, m);
                                        mono_aot_unlock ();
                                }
                        }
                        if (m == method) {
                                index = value;
                                break;
                        }

                        /* Special case: wrappers of shared generic methods */
                        if (m && method->wrapper_type && m->wrapper_type == m->wrapper_type &&
                                method->wrapper_type == MONO_WRAPPER_SYNCHRONIZED) {
                                MonoMethod *w1 = mono_marshal_method_from_wrapper (method);
                                MonoMethod *w2 = mono_marshal_method_from_wrapper (m);

                                if (w1->is_inflated && ((MonoMethodInflated *)w1)->declaring == w2) {
                                        index = value;
                                        break;
                                }
                        }

                        /* Methods decoded needlessly */
                        /*
                        if (m)
                                printf ("%d %s %s\n", n_extra_decodes, mono_method_full_name (method, TRUE), mono_method_full_name (m, TRUE));
                        */
                        n_extra_decodes ++;
                }

                if (next != 0)
                        entry = &table [next * entry_size];
                else
                        break;
        }

        return index;
}

static void
add_module_cb (gpointer key, gpointer value, gpointer user_data)
{
        g_ptr_array_add ((GPtrArray*)user_data, value);
}

/*
 * find_extra_method:
 *
 *   Try finding METHOD in the extra_method table in all AOT images.
 * Return its method index, or 0xffffff if not found. Set OUT_AMODULE to the AOT
 * module where the method was found.
 */
static guint32
find_extra_method (MonoMethod *method, MonoAotModule **out_amodule)
{
        guint32 index;
        GPtrArray *modules;
        int i;
        char *name = NULL;

        if (method->wrapper_type)
                name = mono_aot_wrapper_name (method);

        /* Try the method's module first */
        *out_amodule = method->klass->image->aot_module;
        index = find_extra_method_in_amodule (method->klass->image->aot_module, method, name);
        if (index != 0xffffff) {
                g_free (name);
                return index;
        }

        /* 
         * Try all other modules.
         * This is needed because generic instances klass->image points to the image
         * containing the generic definition, but the native code is generated to the
         * AOT image which contains the reference.
         */

        /* Make a copy to avoid doing the search inside the aot lock */
        modules = g_ptr_array_new ();
        mono_aot_lock ();
        g_hash_table_foreach (aot_modules, add_module_cb, modules);
        mono_aot_unlock ();

        index = 0xffffff;
        for (i = 0; i < modules->len; ++i) {
                MonoAotModule *amodule = g_ptr_array_index (modules, i);

                if (amodule != method->klass->image->aot_module)
                        index = find_extra_method_in_amodule (amodule, method, name);
                if (index != 0xffffff) {
                        *out_amodule = amodule;
                        break;
                }
        }
        
        g_ptr_array_free (modules, TRUE);

        g_free (name);
        return index;
}

/*
 * mono_aot_get_method:
 *
 *   Return a pointer to the AOTed native code for METHOD if it can be found,
 * NULL otherwise.
 * On platforms with function pointers, this doesn't return a function pointer.
 */
gpointer
mono_aot_get_method (MonoDomain *domain, MonoMethod *method)
{
        MonoClass *klass = method->klass;
        guint32 method_index;
        MonoAotModule *amodule = klass->image->aot_module;
        guint8 *code;

        if (!amodule)
                return NULL;

        if (amodule->out_of_date)
                return NULL;

        if ((method->iflags & METHOD_IMPL_ATTRIBUTE_INTERNAL_CALL) ||
                (method->flags & METHOD_ATTRIBUTE_PINVOKE_IMPL) ||
                (method->iflags & METHOD_IMPL_ATTRIBUTE_RUNTIME) ||
                (method->flags & METHOD_ATTRIBUTE_ABSTRACT))
                return NULL;

        /*
         * Use the original method instead of its invoke-with-check wrapper.
         * This is not a problem when using full-aot, since it doesn't support
         * remoting.
         */
        if (mono_aot_only && method->wrapper_type == MONO_WRAPPER_REMOTING_INVOKE_WITH_CHECK)
                return mono_aot_get_method (domain, mono_marshal_method_from_wrapper (method));

        g_assert (klass->inited);

        /* Find method index */
        if (method->is_inflated && mono_method_is_generic_sharable_impl_full (method, FALSE, FALSE)) {
                /* 
                 * For generic methods, we store the fully shared instance in place of the
                 * original method.
                 */
                method = mono_method_get_declaring_generic_method (method);
                method_index = mono_metadata_token_index (method->token) - 1;
        } else if (method->is_inflated || !method->token) {
                /* This hash table is used to avoid the slower search in the extra_method_table in the AOT image */
                mono_aot_lock ();
                code = g_hash_table_lookup (amodule->method_to_code, method);
                mono_aot_unlock ();
                if (code)
                        return code;

                method_index = find_extra_method (method, &amodule);
                /*
                 * Special case the ICollection<T> wrappers for arrays, as they cannot
                 * be statically enumerated, and each wrapper ends up calling the same
                 * method in Array.
                 */
                if (method_index == 0xffffff && method->wrapper_type == MONO_WRAPPER_MANAGED_TO_MANAGED && method->klass->rank && strstr (method->name, "System.Collections.Generic")) {
                        MonoMethod *m = mono_aot_get_array_helper_from_wrapper (method);

                        code = mono_aot_get_method (domain, m);
                        if (code) {
                                if (mono_method_needs_static_rgctx_invoke (m, FALSE)) {
                                        code = mono_create_static_rgctx_trampoline (m, mono_create_ftnptr (domain, code));
                                        /* The call above returns an ftnptr */
                                        code = mono_get_addr_from_ftnptr (code);
                                }

                                return code;
                        }
                }

                /*
                 * Special case Array.GetGenericValueImpl which is a generic icall.
                 * Generic sharing currently can't handle it, but the icall returns data using
                 * an out parameter, so the managed-to-native wrappers can share the same code.
                 */
                if (method_index == 0xffffff && method->wrapper_type == MONO_WRAPPER_MANAGED_TO_NATIVE && method->klass == mono_defaults.array_class && !strcmp (method->name, "GetGenericValueImpl")) {
                        MonoMethod *m;
                        MonoGenericContext ctx;
                        MonoType *args [16];

                        if (mono_method_signature (method)->params [1]->type == MONO_TYPE_OBJECT)
                                /* Avoid recursion */
                                return NULL;

                        m = mono_class_get_method_from_name (mono_defaults.array_class, "GetGenericValueImpl", 2);
                        g_assert (m);

                        memset (&ctx, 0, sizeof (ctx));
                        args [0] = &mono_defaults.object_class->byval_arg;
                        ctx.method_inst = mono_metadata_get_generic_inst (1, args);

                        m = mono_marshal_get_native_wrapper (mono_class_inflate_generic_method (m, &ctx), TRUE, TRUE);

                        /* 
                         * Get the code for the <object> instantiation which should be emitted into
                         * the mscorlib aot image by the AOT compiler.
                         */
                        code = mono_aot_get_method (domain, m);
                        if (code)
                                return code;
                }

                if (method_index == 0xffffff && method->is_inflated && mono_method_is_generic_sharable_impl_full (method, FALSE, TRUE)) {
                        /* Partial sharing */
                        method_index = find_extra_method (mini_get_shared_method (method), &amodule);
                }

                if (method_index == 0xffffff) {
                        if (mono_aot_only && mono_trace_is_traced (G_LOG_LEVEL_DEBUG, MONO_TRACE_AOT)) {
                                char *full_name;

                                full_name = mono_method_full_name (method, TRUE);
                                mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_AOT, "AOT NOT FOUND: %s.\n", full_name);
                                g_free (full_name);
                        }
                        return NULL;
                }

                if (method_index == 0xffffff)
                        return NULL;

                /* Needed by find_jit_info */
                mono_aot_lock ();
                if (!amodule->extra_methods)
                        amodule->extra_methods = g_hash_table_new (NULL, NULL);
                g_hash_table_insert (amodule->extra_methods, GUINT_TO_POINTER (method_index), method);
                mono_aot_unlock ();
        } else {
                /* Common case */
                method_index = mono_metadata_token_index (method->token) - 1;
        }

        return load_method (domain, amodule, klass->image, method, method->token, method_index);
}

/**
 * Same as mono_aot_get_method, but we try to avoid loading any metadata from the
 * method.
 */
gpointer
mono_aot_get_method_from_token (MonoDomain *domain, MonoImage *image, guint32 token)
{
        MonoAotModule *aot_module = image->aot_module;
        int method_index;

        if (!aot_module)
                return NULL;

        method_index = mono_metadata_token_index (token) - 1;

        return load_method (domain, aot_module, image, NULL, token, method_index);
}

typedef struct {
        guint8 *addr;
        gboolean res;
} IsGotEntryUserData;

static void
check_is_got_entry (gpointer key, gpointer value, gpointer user_data)
{
        IsGotEntryUserData *data = (IsGotEntryUserData*)user_data;
        MonoAotModule *aot_module = (MonoAotModule*)value;

        if (aot_module->got && (data->addr >= (guint8*)(aot_module->got)) && (data->addr < (guint8*)(aot_module->got + aot_module->info.got_size)))
                data->res = TRUE;
}

gboolean
mono_aot_is_got_entry (guint8 *code, guint8 *addr)
{
        IsGotEntryUserData user_data;

        if (!aot_modules)
                return FALSE;

        user_data.addr = addr;
        user_data.res = FALSE;
        mono_aot_lock ();
        g_hash_table_foreach (aot_modules, check_is_got_entry, &user_data);
        mono_aot_unlock ();
        
        return user_data.res;
}

typedef struct {
        guint8 *addr;
        MonoAotModule *module;
} FindAotModuleUserData;

static void
find_aot_module_cb (gpointer key, gpointer value, gpointer user_data)
{
        FindAotModuleUserData *data = (FindAotModuleUserData*)user_data;
        MonoAotModule *aot_module = (MonoAotModule*)value;

        if ((data->addr >= (guint8*)(aot_module->code)) && (data->addr < (guint8*)(aot_module->code_end)))
                data->module = aot_module;
}

static inline MonoAotModule*
find_aot_module (guint8 *code)
{
        FindAotModuleUserData user_data;

        if (!aot_modules)
                return NULL;

        /* Reading these need no locking */
        if (((gsize)code < aot_code_low_addr) || ((gsize)code > aot_code_high_addr))
                return NULL;

        user_data.addr = code;
        user_data.module = NULL;
                
        mono_aot_lock ();
        g_hash_table_foreach (aot_modules, find_aot_module_cb, &user_data);
        mono_aot_unlock ();
        
        return user_data.module;
}

void
mono_aot_patch_plt_entry (guint8 *code, gpointer *got, mgreg_t *regs, guint8 *addr)
{
        /*
         * Since AOT code is only used in the root domain, 
         * mono_domain_get () != mono_get_root_domain () means the calling method
         * is AppDomain:InvokeInDomain, so this is the same check as in 
         * mono_method_same_domain () but without loading the metadata for the method.
         */
        if (mono_domain_get () == mono_get_root_domain ())
                mono_arch_patch_plt_entry (code, got, regs, addr);
}

/*
 * mono_aot_plt_resolve:
 *
 *   This function is called by the entries in the PLT to resolve the actual method that
 * needs to be called. It returns a trampoline to the method and patches the PLT entry.
 * Returns NULL if the something cannot be loaded.
 */
gpointer
mono_aot_plt_resolve (gpointer aot_module, guint32 plt_info_offset, guint8 *code)
{
#ifdef MONO_ARCH_AOT_SUPPORTED
        guint8 *p, *target, *plt_entry;
        MonoJumpInfo ji;
        MonoAotModule *module = (MonoAotModule*)aot_module;
        gboolean res, no_ftnptr = FALSE;
        MonoMemPool *mp;

        //printf ("DYN: %p %d\n", aot_module, plt_info_offset);

        p = &module->blob [plt_info_offset];

        ji.type = decode_value (p, &p);

        mp = mono_mempool_new_size (512);
        res = decode_patch (module, mp, &ji, p, &p);

        if (!res) {
                mono_mempool_destroy (mp);
                return NULL;
        }

        /* 
         * Avoid calling resolve_patch_target in the full-aot case if possible, since
         * it would create a trampoline, and we don't need that.
         * We could do this only if the method does not need the special handling
         * in mono_magic_trampoline ().
         */
        if (mono_aot_only && ji.type == MONO_PATCH_INFO_METHOD && !ji.data.method->is_generic && !mono_method_check_context_used (ji.data.method) && !(ji.data.method->iflags & METHOD_IMPL_ATTRIBUTE_SYNCHRONIZED) &&
                !mono_method_needs_static_rgctx_invoke (ji.data.method, FALSE)) {
                target = mono_jit_compile_method (ji.data.method);
                no_ftnptr = TRUE;
        } else {
                target = mono_resolve_patch_target (NULL, mono_domain_get (), NULL, &ji, TRUE);
        }

        /*
         * The trampoline expects us to return a function descriptor on platforms which use
         * it, but resolve_patch_target returns a direct function pointer for some type of
         * patches, so have to translate between the two.
         * FIXME: Clean this up, but how ?
         */
        if (ji.type == MONO_PATCH_INFO_ABS || ji.type == MONO_PATCH_INFO_INTERNAL_METHOD || ji.type == MONO_PATCH_INFO_CLASS_INIT || ji.type == MONO_PATCH_INFO_ICALL_ADDR || ji.type == MONO_PATCH_INFO_JIT_ICALL_ADDR || ji.type == MONO_PATCH_INFO_RGCTX_FETCH) {
                /* These should already have a function descriptor */
#ifdef PPC_USES_FUNCTION_DESCRIPTOR
                /* Our function descriptors have a 0 environment, gcc created ones don't */
                if (ji.type != MONO_PATCH_INFO_INTERNAL_METHOD && ji.type != MONO_PATCH_INFO_JIT_ICALL_ADDR && ji.type != MONO_PATCH_INFO_ICALL_ADDR)
                        g_assert (((gpointer*)target) [2] == 0);
#endif
                /* Empty */
        } else if (!no_ftnptr) {
#ifdef PPC_USES_FUNCTION_DESCRIPTOR
                g_assert (((gpointer*)target) [2] != 0);
#endif
                target = mono_create_ftnptr (mono_domain_get (), target);
        }

        mono_mempool_destroy (mp);

        /* Patch the PLT entry with target which might be the actual method not a trampoline */
        plt_entry = mono_aot_get_plt_entry (code);
        g_assert (plt_entry);
        mono_aot_patch_plt_entry (plt_entry, module->got, NULL, target);

        return target;
#else
        g_assert_not_reached ();
        return NULL;
#endif
}

/**
 * init_plt:
 *
 *   Initialize the PLT table of the AOT module. Called lazily when the first AOT
 * method in the module is loaded to avoid committing memory by writing to it.
 * LOCKING: Assumes the AOT lock is held.
 */
static void
init_plt (MonoAotModule *amodule)
{
#ifndef MONO_CROSS_COMPILE

#ifdef MONO_ARCH_AOT_SUPPORTED
#ifdef __i386__
        guint8 *buf = amodule->plt;
#elif defined(__x86_64__) || defined(__arm__) || defined(__mono_ppc__)
        int i;
        gpointer plt_0;
#endif
        gpointer tramp;

        if (amodule->plt_inited)
                return;

        tramp = mono_create_specific_trampoline (amodule, MONO_TRAMPOLINE_AOT_PLT, mono_get_root_domain (), NULL);

#ifdef __i386__
        /* Initialize the first PLT entry */
        make_writable (amodule->plt, amodule->plt_end - amodule->plt);
        x86_jump_code (buf, tramp);
#elif defined(__x86_64__) || defined(__arm__) || defined(__mono_ppc__)
        /*
         * Initialize the PLT entries in the GOT to point to the default targets.
         */

        tramp = mono_create_ftnptr (mono_domain_get (), tramp);
        plt_0 = mono_create_ftnptr (mono_domain_get (), amodule->plt);
         /* The first entry points to the AOT trampoline */
         ((gpointer*)amodule->got)[amodule->info.plt_got_offset_base] = tramp;
         for (i = 1; i < amodule->info.plt_size; ++i)
                 /* All the default entries point to the first entry */
                 ((gpointer*)amodule->got)[amodule->info.plt_got_offset_base + i] = plt_0;
#else
        g_assert_not_reached ();
#endif

        amodule->plt_inited = TRUE;
#endif

#endif /* MONO_CROSS_COMPILE */
}

/*
 * mono_aot_get_plt_entry:
 *
 *   Return the address of the PLT entry called by the code at CODE if exists.
 */
guint8*
mono_aot_get_plt_entry (guint8 *code)
{
        MonoAotModule *aot_module = find_aot_module (code);
#if defined(__arm__) || defined(__mono_ppc__)
        guint32 ins;
#endif

        if (!aot_module)
                return NULL;

#if defined(__i386__) || defined(__x86_64__)
        if (code [-5] == 0xe8) {
                guint32 disp = *(guint32*)(code - 4);
                guint8 *target = code + disp;

                if ((target >= (guint8*)(aot_module->plt)) && (target < (guint8*)(aot_module->plt_end)))
                        return target;
        }
#elif defined(__arm__)
        ins = ((guint32*)(gpointer)code) [-1];

        /* Should be a 'bl' */
        if ((((ins >> 25) & 0x7) == 0x5) && (((ins >> 24) & 0x1) == 0x1)) {
                gint32 disp = ((gint32)ins) & 0xffffff;
                guint8 *target = code - 4 + 8 + (disp * 4);

                if ((target >= (guint8*)(aot_module->plt)) && (target < (guint8*)(aot_module->plt_end)))
                        return target;
        }               
#elif defined(__mono_ppc__)
        /* Should be a bl */
        ins = ((guint32*)(gpointer)code) [-1];

        if ((ins >> 26 == 18) && ((ins & 1) == 1) && ((ins & 2) == 0)) {
                gint32 disp = (((gint32)ins) >> 2) & 0xffffff;
                guint8 *target = code - 4 + (disp * 4);

                if ((target >= (guint8*)(aot_module->plt)) && (target < (guint8*)(aot_module->plt_end)))
                        return target;
        }
#else
        g_assert_not_reached ();
#endif

        return NULL;
}

/*
 * mono_aot_get_plt_info_offset:
 *
 *   Return the PLT info offset belonging to the plt entry called by CODE.
 */
guint32
mono_aot_get_plt_info_offset (mgreg_t *regs, guint8 *code)
{
        guint8 *plt_entry = mono_aot_get_plt_entry (code);

        g_assert (plt_entry);

        /* The offset is embedded inside the code after the plt entry */
#if defined(__i386__)
        return *(guint32*)(plt_entry + 5);
#elif defined(__x86_64__)
        return *(guint32*)(plt_entry + 6);
#elif defined(__arm__)
        /* The offset is stored as the 4th word of the plt entry */
        return ((guint32*)plt_entry) [3];          
#elif defined(__mono_ppc__)
#ifdef PPC_USES_FUNCTION_DESCRIPTOR
        return ((guint32*)plt_entry) [8];
#else
        return ((guint32*)plt_entry) [6];
#endif
#else
        g_assert_not_reached ();
        return 0;
#endif
}

static gpointer
mono_create_ftnptr_malloc (guint8 *code)
{
#ifdef PPC_USES_FUNCTION_DESCRIPTOR
        MonoPPCFunctionDescriptor *ftnptr = g_malloc0 (sizeof (MonoPPCFunctionDescriptor));

        ftnptr->code = code;
        ftnptr->toc = NULL;
        ftnptr->env = NULL;

        return ftnptr;
#else
        return code;
#endif
}

/*
 * load_function:
 *
 *   Load the function named NAME from the aot image. 
 */
static gpointer
load_function (MonoAotModule *amodule, const char *name)
{
        char *symbol;
        guint8 *p;
        int n_patches, pindex;
        MonoMemPool *mp;
        gpointer code;

        /* Load the code */

        symbol = g_strdup_printf ("%s", name);
        find_symbol (amodule->sofile, amodule->globals, symbol, (gpointer *)&code);
        g_free (symbol);
        if (!code)
                g_error ("Symbol '%s' not found in AOT file '%s'.\n", name, amodule->aot_name);

        mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_AOT, "AOT FOUND function '%s' in AOT file '%s'.\n", name, amodule->aot_name);

        /* Load info */

        symbol = g_strdup_printf ("%s_p", name);
        find_symbol (amodule->sofile, amodule->globals, symbol, (gpointer *)&p);
        g_free (symbol);
        if (!p)
                /* Nothing to patch */
                return code;

        p = amodule->blob + *(guint32*)p;

        /* Similar to mono_aot_load_method () */

        n_patches = decode_value (p, &p);

        if (n_patches) {
                MonoJumpInfo *patches;
                guint32 *got_slots;

                mp = mono_mempool_new ();

                patches = load_patch_info (amodule, mp, n_patches, &got_slots, p, &p);
                g_assert (patches);

                for (pindex = 0; pindex < n_patches; ++pindex) {
                        MonoJumpInfo *ji = &patches [pindex];
                        gpointer target;

                        if (amodule->got [got_slots [pindex]])
                                continue;

                        /*
                         * When this code is executed, the runtime may not be initalized yet, so
                         * resolve the patch info by hand.
                         */
                        if (ji->type == MONO_PATCH_INFO_JIT_ICALL_ADDR) {
                                if (!strcmp (ji->data.name, "mono_get_lmf_addr")) {
                                        target = mono_get_lmf_addr;
                                } else if (!strcmp (ji->data.name, "mono_thread_force_interruption_checkpoint")) {
                                        target = mono_thread_force_interruption_checkpoint;
                                } else if (!strcmp (ji->data.name, "mono_exception_from_token")) {
                                        target = mono_exception_from_token;
                                } else if (!strcmp (ji->data.name, "mono_throw_exception")) {
                                        target = mono_get_throw_exception ();
#ifdef __x86_64__
                                } else if (!strcmp (ji->data.name, "mono_amd64_throw_exception")) {
                                        target = mono_amd64_throw_exception;
#endif
#ifdef __x86_64__
                                } else if (!strcmp (ji->data.name, "mono_amd64_get_original_ip")) {
                                        target = mono_amd64_get_original_ip;
#endif
#ifdef __arm__
                                } else if (!strcmp (ji->data.name, "mono_arm_throw_exception")) {
                                        target = mono_arm_throw_exception;
                                } else if (!strcmp (ji->data.name, "mono_arm_throw_exception_by_token")) {
                                        target = mono_arm_throw_exception_by_token;
#endif
#ifdef __mono_ppc__
                                } else if (!strcmp (ji->data.name, "mono_ppc_throw_exception")) {
                                        target = mono_ppc_throw_exception;
#endif
                                } else if (strstr (ji->data.name, "trampoline_func_") == ji->data.name) {
                                        int tramp_type2 = atoi (ji->data.name + strlen ("trampoline_func_"));
                                        target = (gpointer)mono_get_trampoline_func (tramp_type2);
                                } else if (strstr (ji->data.name, "specific_trampoline_lazy_fetch_") == ji->data.name) {
                                        /* atoll is needed because the the offset is unsigned */
                                        guint32 slot;
                                        int res;

                                        res = sscanf (ji->data.name, "specific_trampoline_lazy_fetch_%u", &slot);
                                        g_assert (res == 1);
                                        target = mono_create_specific_trampoline (GUINT_TO_POINTER (slot), MONO_TRAMPOLINE_RGCTX_LAZY_FETCH, mono_get_root_domain (), NULL);
                                        target = mono_create_ftnptr_malloc (target);
                                } else if (!strcmp (ji->data.name, "specific_trampoline_monitor_enter")) {
                                        target = mono_create_specific_trampoline (NULL, MONO_TRAMPOLINE_MONITOR_ENTER, mono_get_root_domain (), NULL);
                                        target = mono_create_ftnptr_malloc (target);
                                } else if (!strcmp (ji->data.name, "specific_trampoline_monitor_exit")) {
                                        target = mono_create_specific_trampoline (NULL, MONO_TRAMPOLINE_MONITOR_EXIT, mono_get_root_domain (), NULL);
                                        target = mono_create_ftnptr_malloc (target);
                                } else if (!strcmp (ji->data.name, "specific_trampoline_generic_class_init")) {
                                        target = mono_create_specific_trampoline (NULL, MONO_TRAMPOLINE_GENERIC_CLASS_INIT, mono_get_root_domain (), NULL);
                                        target = mono_create_ftnptr_malloc (target);
                                } else if (!strcmp (ji->data.name, "mono_thread_get_and_clear_pending_exception")) {
                                        target = mono_thread_get_and_clear_pending_exception;
                                } else {
                                        fprintf (stderr, "Unknown relocation '%s'\n", ji->data.name);
                                        g_assert_not_reached ();
                                        target = NULL;
                                }
                        } else {
                                /* Hopefully the code doesn't have patches which need method or 
                                 * domain to be set.
                                 */
                                target = mono_resolve_patch_target (NULL, NULL, code, ji, FALSE);
                                g_assert (target);
                        }

                        amodule->got [got_slots [pindex]] = target;
                }

                g_free (got_slots);

                mono_mempool_destroy (mp);
        }

        return code;
}

/*
 * Return the piece of code identified by NAME from the mscorlib AOT file.
 * On ppc64, this returns a function descriptor.
 */
gpointer
mono_aot_get_named_code (const char *name)
{
        MonoImage *image;
        MonoAotModule *amodule;

        image = mono_defaults.corlib;
        g_assert (image);

        amodule = image->aot_module;
        g_assert (amodule);

        return mono_create_ftnptr_malloc (load_function (amodule, name));
}

/* Return a given kind of trampoline */
static gpointer
get_numerous_trampoline (MonoAotTrampoline tramp_type, int n_got_slots, MonoAotModule **out_amodule, guint32 *got_offset, guint32 *out_tramp_size)
{
        MonoAotModule *amodule;
        int index, tramp_size;
        MonoImage *image;

        /* Currently, we keep all trampolines in the mscorlib AOT image */
        image = mono_defaults.corlib;
        g_assert (image);

        mono_aot_lock ();

        amodule = image->aot_module;
        g_assert (amodule);

        *out_amodule = amodule;

        if (amodule->trampoline_index [tramp_type] == amodule->info.num_trampolines [tramp_type])
                g_error ("Ran out of trampolines of type %d in '%s' (%d)\n", tramp_type, image->name, amodule->info.num_trampolines [tramp_type]);

        index = amodule->trampoline_index [tramp_type] ++;

        mono_aot_unlock ();

        *got_offset = amodule->info.trampoline_got_offset_base [tramp_type] + (index * n_got_slots);

        tramp_size = amodule->info.trampoline_size [tramp_type];

        if (out_tramp_size)
                *out_tramp_size = tramp_size;

        return amodule->trampolines [tramp_type] + (index * tramp_size);
}

/*
 * Return a specific trampoline from the AOT file.
 */
gpointer
mono_aot_create_specific_trampoline (MonoImage *image, gpointer arg1, MonoTrampolineType tramp_type, MonoDomain *domain, guint32 *code_len)
{
        MonoAotModule *amodule;
        guint32 got_offset, tramp_size;
        guint8 *code, *tramp;
        static gpointer generic_trampolines [MONO_TRAMPOLINE_NUM];
        static gboolean inited;
        static guint32 num_trampolines;

        if (!inited) {
                mono_aot_lock ();

                if (!inited) {
                        mono_counters_register ("Specific trampolines", MONO_COUNTER_JIT | MONO_COUNTER_INT, &num_trampolines);
                        inited = TRUE;
                }

                mono_aot_unlock ();
        }

        num_trampolines ++;

        if (!generic_trampolines [tramp_type]) {
                char *symbol;

                symbol = g_strdup_printf ("generic_trampoline_%d", tramp_type);
                generic_trampolines [tramp_type] = mono_aot_get_named_code (symbol);
                g_free (symbol);
        }

        tramp = generic_trampolines [tramp_type];
        g_assert (tramp);

        code = get_numerous_trampoline (MONO_AOT_TRAMP_SPECIFIC, 2, &amodule, &got_offset, &tramp_size);

        amodule->got [got_offset] = tramp;
        amodule->got [got_offset + 1] = arg1;

        if (code_len)
                *code_len = tramp_size;

        return code;
}

gpointer
mono_aot_get_static_rgctx_trampoline (gpointer ctx, gpointer addr)
{
        MonoAotModule *amodule;
        guint8 *code;
        guint32 got_offset;

        code = get_numerous_trampoline (MONO_AOT_TRAMP_STATIC_RGCTX, 2, &amodule, &got_offset, NULL);

        amodule->got [got_offset] = ctx;
        amodule->got [got_offset + 1] = addr; 

        /* The caller expects an ftnptr */
        return mono_create_ftnptr (mono_domain_get (), code);
}

gpointer
mono_aot_get_unbox_trampoline (MonoMethod *method)
{
        guint32 method_index = mono_metadata_token_index (method->token) - 1;
        MonoAotModule *amodule;
        char *symbol;
        gpointer code;

        if (method->is_inflated && !mono_method_is_generic_sharable_impl (method, FALSE)) {
                guint32 index = find_extra_method (method, &amodule);
                g_assert (index != 0xffffff);
                
                symbol = g_strdup_printf ("ut_e_%d", index);
        } else {
                amodule = method->klass->image->aot_module;
                g_assert (amodule);

                symbol = g_strdup_printf ("ut_%d", method_index);
        }
        code = load_function (amodule, symbol);
        g_free (symbol);

        /* The caller expects an ftnptr */
        return mono_create_ftnptr (mono_domain_get (), code);
}

gpointer
mono_aot_get_lazy_fetch_trampoline (guint32 slot)
{
        char *symbol;
        gpointer code;

        symbol = g_strdup_printf ("rgctx_fetch_trampoline_%u", slot);
        code = load_function (mono_defaults.corlib->aot_module, symbol);
        g_free (symbol);
        /* The caller expects an ftnptr */
        return mono_create_ftnptr (mono_domain_get (), code);
}

gpointer
mono_aot_get_imt_thunk (MonoVTable *vtable, MonoDomain *domain, MonoIMTCheckItem **imt_entries, int count, gpointer fail_tramp)
{
        guint32 got_offset;
        gpointer code;
        gpointer *buf;
        int i;
        MonoAotModule *amodule;

        code = get_numerous_trampoline (MONO_AOT_TRAMP_IMT_THUNK, 1, &amodule, &got_offset, NULL);

        /* Save the entries into an array */
        buf = mono_domain_alloc (domain, (count + 1) * 2 * sizeof (gpointer));
        for (i = 0; i < count; ++i) {
                MonoIMTCheckItem *item = imt_entries [i];               

                g_assert (item->key);
                /* FIXME: */
                g_assert (!item->has_target_code);

                buf [(i * 2)] = item->key;
                buf [(i * 2) + 1] = &(vtable->vtable [item->value.vtable_slot]);
        }
        buf [(count * 2)] = NULL;
        buf [(count * 2) + 1] = fail_tramp;
        
        amodule->got [got_offset] = buf;

        return code;
}
 
/*
 * mono_aot_set_make_unreadable:
 *
 *   Set whenever to make all mmaped memory unreadable. In conjuction with a
 * SIGSEGV handler, this is useful to find out which pages the runtime tries to read.
 */
void
mono_aot_set_make_unreadable (gboolean unreadable)
{
        static int inited;

        make_unreadable = unreadable;

        if (make_unreadable && !inited) {
                mono_counters_register ("AOT pagefaults", MONO_COUNTER_JIT | MONO_COUNTER_INT, &n_pagefaults);
        }               
}

typedef struct {
        MonoAotModule *module;
        guint8 *ptr;
} FindMapUserData;

static void
find_map (gpointer key, gpointer value, gpointer user_data)
{
        MonoAotModule *module = (MonoAotModule*)value;
        FindMapUserData *data = (FindMapUserData*)user_data;

        if (!data->module)
                if ((data->ptr >= module->mem_begin) && (data->ptr < module->mem_end))
                        data->module = module;
}

static MonoAotModule*
find_module_for_addr (void *ptr)
{
        FindMapUserData data;

        if (!make_unreadable)
                return NULL;

        data.module = NULL;
        data.ptr = (guint8*)ptr;

        mono_aot_lock ();
        g_hash_table_foreach (aot_modules, (GHFunc)find_map, &data);
        mono_aot_unlock ();

        return data.module;
}

/*
 * mono_aot_is_pagefault:
 *
 *   Should be called from a SIGSEGV signal handler to find out whenever @ptr is
 * within memory allocated by this module.
 */
gboolean
mono_aot_is_pagefault (void *ptr)
{
        if (!make_unreadable)
                return FALSE;

        /* 
         * Not signal safe, but SIGSEGV's are synchronous, and
         * this is only turned on by a MONO_DEBUG option.
         */
        return find_module_for_addr (ptr) != NULL;
}

/*
 * mono_aot_handle_pagefault:
 *
 *   Handle a pagefault caused by an unreadable page by making it readable again.
 */
void
mono_aot_handle_pagefault (void *ptr)
{
#ifndef PLATFORM_WIN32
        guint8* start = (guint8*)ROUND_DOWN (((gssize)ptr), mono_pagesize ());
        int res;

        mono_aot_lock ();
        res = mono_mprotect (start, mono_pagesize (), MONO_MMAP_READ|MONO_MMAP_WRITE|MONO_MMAP_EXEC);
        g_assert (res == 0);

        n_pagefaults ++;
        mono_aot_unlock ();
#endif
}

#else
/* AOT disabled */

void
mono_aot_init (void)
{
}

gpointer
mono_aot_get_method (MonoDomain *domain, MonoMethod *method)
{
        return NULL;
}

gboolean
mono_aot_is_got_entry (guint8 *code, guint8 *addr)
{
        return FALSE;
}

gboolean
mono_aot_get_cached_class_info (MonoClass *klass, MonoCachedClassInfo *res)
{
        return FALSE;
}

gboolean
mono_aot_get_class_from_name (MonoImage *image, const char *name_space, const char *name, MonoClass **klass)
{
        return FALSE;
}

MonoJitInfo *
mono_aot_find_jit_info (MonoDomain *domain, MonoImage *image, gpointer addr)
{
        return NULL;
}

gpointer
mono_aot_get_method_from_token (MonoDomain *domain, MonoImage *image, guint32 token)
{
        return NULL;
}

guint8*
mono_aot_get_plt_entry (guint8 *code)
{
        return NULL;
}

gpointer
mono_aot_plt_resolve (gpointer aot_module, guint32 plt_info_offset, guint8 *code)
{
        return NULL;
}

void
mono_aot_patch_plt_entry (guint8 *code, gpointer *got, mgreg_t *regs, guint8 *addr)
{
}

gpointer
mono_aot_get_method_from_vt_slot (MonoDomain *domain, MonoVTable *vtable, int slot)
{
        return NULL;
}

guint32
mono_aot_get_plt_info_offset (mgreg_t *regs, guint8 *code)
{
        g_assert_not_reached ();

        return 0;
}

gpointer
mono_aot_create_specific_trampoline (MonoImage *image, gpointer arg1, MonoTrampolineType tramp_type, MonoDomain *domain, guint32 *code_len)
{
        g_assert_not_reached ();
        return NULL;
}

gpointer
mono_aot_get_static_rgctx_trampoline (gpointer ctx, gpointer addr)
{
        g_assert_not_reached ();
        return NULL;
}

gpointer
mono_aot_get_named_code (const char *name)
{
        g_assert_not_reached ();
        return NULL;
}

gpointer
mono_aot_get_unbox_trampoline (MonoMethod *method)
{
        g_assert_not_reached ();
        return NULL;
}

gpointer
mono_aot_get_lazy_fetch_trampoline (guint32 slot)
{
        g_assert_not_reached ();
        return NULL;
}

gpointer
mono_aot_get_imt_thunk (MonoVTable *vtable, MonoDomain *domain, MonoIMTCheckItem **imt_entries, int count, gpointer fail_tramp)
{
        g_assert_not_reached ();
        return NULL;
}       

guint8*
mono_aot_get_unwind_info (MonoJitInfo *ji, guint32 *unwind_info_len)
{
        g_assert_not_reached ();
        return NULL;
}

#endif