kc3-lang/libffi/src/aarch64/ffi.c

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• Hash : 53636634
  Author :
  Date : 2015-01-16T15:19:38
  

  aarch64: implement the trampoline table workaround for ffi closures on Apple systems This is a direct copy/paste port of the ARM code, with changes because of Aarch64 pc-relative addressing restrictions.

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• src/aarch64/ffi.c

• /* Copyright (c) 2009, 2010, 2011, 2012 ARM Ltd.
  
  Permission is hereby granted, free of charge, to any person obtaining
  a copy of this software and associated documentation files (the
  ``Software''), to deal in the Software without restriction, including
  without limitation the rights to use, copy, modify, merge, publish,
  distribute, sublicense, and/or sell copies of the Software, and to
  permit persons to whom the Software is furnished to do so, subject to
  the following conditions:
  
  The above copyright notice and this permission notice shall be
  included in all copies or substantial portions of the Software.
  
  THE SOFTWARE IS PROVIDED ``AS IS'', WITHOUT WARRANTY OF ANY KIND,
  EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
  MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
  IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
  CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
  TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
  SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.  */
  
  #include <stdio.h>
  #include <stdlib.h>
  #include <stdint.h>
  #include <ffi.h>
  #include <ffi_common.h>
  #include "internal.h"
  
  /* Force FFI_TYPE_LONGDOUBLE to be different than FFI_TYPE_DOUBLE;
     all further uses in this file will refer to the 128-bit type.  */
  #if FFI_TYPE_DOUBLE != FFI_TYPE_LONGDOUBLE
  # if FFI_TYPE_LONGDOUBLE != 4
  #  error FFI_TYPE_LONGDOUBLE out of date
  # endif
  #else
  # undef FFI_TYPE_LONGDOUBLE
  # define FFI_TYPE_LONGDOUBLE 4
  #endif
  
  union _d
  {
    UINT64 d;
    UINT32 s[2];
  };
  
  struct _v
  {
    union _d d[2] __attribute__((aligned(16)));
  };
  
  struct call_context
  {
    struct _v v[N_V_ARG_REG];
    UINT64 x[N_X_ARG_REG];
  };
  
  #if defined (__clang__) && defined (__APPLE__)
  extern void sys_icache_invalidate (void *start, size_t len);
  #endif
  
  static inline void
  ffi_clear_cache (void *start, void *end)
  {
  #if defined (__clang__) && defined (__APPLE__)
    sys_icache_invalidate (start, (char *)end - (char *)start);
  #elif defined (__GNUC__)
    __builtin___clear_cache (start, end);
  #else
  #error "Missing builtin to flush instruction cache"
  #endif
  }
  
  /* A subroutine of is_vfp_type.  Given a structure type, return the type code
     of the first non-structure element.  Recurse for structure elements.
     Return -1 if the structure is in fact empty, i.e. no nested elements.  */
  
  static int
  is_hfa0 (const ffi_type *ty)
  {
    ffi_type **elements = ty->elements;
    int i, ret = -1;
  
    if (elements != NULL)
      for (i = 0; elements[i]; ++i)
        {
          ret = elements[i]->type;
          if (ret == FFI_TYPE_STRUCT || ret == FFI_TYPE_COMPLEX)
            {
              ret = is_hfa0 (elements[i]);
              if (ret < 0)
                continue;
            }
          break;
        }
  
    return ret;
  }
  
  /* A subroutine of is_vfp_type.  Given a structure type, return true if all
     of the non-structure elements are the same as CANDIDATE.  */
  
  static int
  is_hfa1 (const ffi_type *ty, int candidate)
  {
    ffi_type **elements = ty->elements;
    int i;
  
    if (elements != NULL)
      for (i = 0; elements[i]; ++i)
        {
          int t = elements[i]->type;
          if (t == FFI_TYPE_STRUCT || t == FFI_TYPE_COMPLEX)
            {
              if (!is_hfa1 (elements[i], candidate))
                return 0;
            }
          else if (t != candidate)
            return 0;
        }
  
    return 1;
  }
  
  /* Determine if TY may be allocated to the FP registers.  This is both an
     fp scalar type as well as an homogenous floating point aggregate (HFA).
     That is, a structure consisting of 1 to 4 members of all the same type,
     where that type is an fp scalar.
  
     Returns non-zero iff TY is an HFA.  The result is the AARCH64_RET_*
     constant for the type.  */
  
  static int
  is_vfp_type (const ffi_type *ty)
  {
    ffi_type **elements;
    int candidate, i;
    size_t size, ele_count;
  
    /* Quickest tests first.  */
    candidate = ty->type;
    switch (candidate)
      {
      default:
        return 0;
      case FFI_TYPE_FLOAT:
      case FFI_TYPE_DOUBLE:
      case FFI_TYPE_LONGDOUBLE:
        ele_count = 1;
        goto done;
      case FFI_TYPE_COMPLEX:
        candidate = ty->elements[0]->type;
        switch (candidate)
  	{
  	case FFI_TYPE_FLOAT:
  	case FFI_TYPE_DOUBLE:
  	case FFI_TYPE_LONGDOUBLE:
  	  ele_count = 2;
  	  goto done;
  	}
        return 0;
      case FFI_TYPE_STRUCT:
        break;
      }
  
    /* No HFA types are smaller than 4 bytes, or larger than 64 bytes.  */
    size = ty->size;
    if (size < 4 || size > 64)
      return 0;
  
    /* Find the type of the first non-structure member.  */
    elements = ty->elements;
    candidate = elements[0]->type;
    if (candidate == FFI_TYPE_STRUCT || candidate == FFI_TYPE_COMPLEX)
      {
        for (i = 0; ; ++i)
          {
            candidate = is_hfa0 (elements[i]);
            if (candidate >= 0)
              break;
          }
      }
  
    /* If the first member is not a floating point type, it's not an HFA.
       Also quickly re-check the size of the structure.  */
    switch (candidate)
      {
      case FFI_TYPE_FLOAT:
        ele_count = size / sizeof(float);
        if (size != ele_count * sizeof(float))
          return 0;
        break;
      case FFI_TYPE_DOUBLE:
        ele_count = size / sizeof(double);
        if (size != ele_count * sizeof(double))
          return 0;
        break;
      case FFI_TYPE_LONGDOUBLE:
        ele_count = size / sizeof(long double);
        if (size != ele_count * sizeof(long double))
          return 0;
        break;
      default:
        return 0;
      }
    if (ele_count > 4)
      return 0;
  
    /* Finally, make sure that all scalar elements are the same type.  */
    for (i = 0; elements[i]; ++i)
      {
        int t = elements[i]->type;
        if (t == FFI_TYPE_STRUCT || t == FFI_TYPE_COMPLEX)
          {
            if (!is_hfa1 (elements[i], candidate))
              return 0;
          }
        else if (t != candidate)
          return 0;
      }
  
    /* All tests succeeded.  Encode the result.  */
   done:
    return candidate * 4 + (4 - ele_count);
  }
  
  /* Representation of the procedure call argument marshalling
     state.
  
     The terse state variable names match the names used in the AARCH64
     PCS. */
  
  struct arg_state
  {
    unsigned ngrn;                /* Next general-purpose register number. */
    unsigned nsrn;                /* Next vector register number. */
    size_t nsaa;                  /* Next stack offset. */
  
  #if defined (__APPLE__)
    unsigned allocating_variadic;
  #endif
  };
  
  /* Initialize a procedure call argument marshalling state.  */
  static void
  arg_init (struct arg_state *state)
  {
    state->ngrn = 0;
    state->nsrn = 0;
    state->nsaa = 0;
  #if defined (__APPLE__)
    state->allocating_variadic = 0;
  #endif
  }
  
  /* Allocate an aligned slot on the stack and return a pointer to it.  */
  static void *
  allocate_to_stack (struct arg_state *state, void *stack,
  		   size_t alignment, size_t size)
  {
    size_t nsaa = state->nsaa;
  
    /* Round up the NSAA to the larger of 8 or the natural
       alignment of the argument's type.  */
  #if defined (__APPLE__)
    if (state->allocating_variadic && alignment < 8)
      alignment = 8;
  #else
    if (alignment < 8)
      alignment = 8;
  #endif
      
    nsaa = ALIGN (nsaa, alignment);
    state->nsaa = nsaa + size;
  
    return (char *)stack + nsaa;
  }
  
  static ffi_arg
  extend_integer_type (void *source, int type)
  {
    switch (type)
      {
      case FFI_TYPE_UINT8:
        return *(UINT8 *) source;
      case FFI_TYPE_SINT8:
        return *(SINT8 *) source;
      case FFI_TYPE_UINT16:
        return *(UINT16 *) source;
      case FFI_TYPE_SINT16:
        return *(SINT16 *) source;
      case FFI_TYPE_UINT32:
        return *(UINT32 *) source;
      case FFI_TYPE_INT:
      case FFI_TYPE_SINT32:
        return *(SINT32 *) source;
      case FFI_TYPE_UINT64:
      case FFI_TYPE_SINT64:
        return *(UINT64 *) source;
        break;
      case FFI_TYPE_POINTER:
        return *(uintptr_t *) source;
      default:
        abort();
      }
  }
  
  static void
  extend_hfa_type (void *dest, void *src, int h)
  {
    int f = h - AARCH64_RET_S4;
    void *x0;
  
    asm volatile (
  	"adr	%0, 0f\n"
  "	add	%0, %0, %1\n"
  "	br	%0\n"
  "0:	ldp	s16, s17, [%3]\n"	/* S4 */
  "	ldp	s18, s19, [%3, #8]\n"
  "	b	4f\n"
  "	ldp	s16, s17, [%3]\n"	/* S3 */
  "	ldr	s18, [%3, #8]\n"
  "	b	3f\n"
  "	ldp	s16, s17, [%3]\n"	/* S2 */
  "	b	2f\n"
  "	nop\n"
  "	ldr	s16, [%3]\n"		/* S1 */
  "	b	1f\n"
  "	nop\n"
  "	ldp	d16, d17, [%3]\n"	/* D4 */
  "	ldp	d18, d19, [%3, #16]\n"
  "	b	4f\n"
  "	ldp	d16, d17, [%3]\n"	/* D3 */
  "	ldr	d18, [%3, #16]\n"
  "	b	3f\n"
  "	ldp	d16, d17, [%3]\n"	/* D2 */
  "	b	2f\n"
  "	nop\n"
  "	ldr	d16, [%3]\n"		/* D1 */
  "	b	1f\n"
  "	nop\n"
  "	ldp	q16, q17, [%3]\n"	/* Q4 */
  "	ldp	q18, q19, [%3, #16]\n"
  "	b	4f\n"
  "	ldp	q16, q17, [%3]\n"	/* Q3 */
  "	ldr	q18, [%3, #16]\n"
  "	b	3f\n"
  "	ldp	q16, q17, [%3]\n"	/* Q2 */
  "	b	2f\n"
  "	nop\n"
  "	ldr	q16, [%3]\n"		/* Q1 */
  "	b	1f\n"
  "4:	str	q19, [%2, #48]\n"
  "3:	str	q18, [%2, #32]\n"
  "2:	str	q17, [%2, #16]\n"
  "1:	str	q16, [%2]"
      : "=&r"(x0)
      : "r"(f * 12), "r"(dest), "r"(src)
      : "memory", "v16", "v17", "v18", "v19");
  }
  
  static void *
  compress_hfa_type (void *dest, void *reg, int h)
  {
    switch (h)
      {
      case AARCH64_RET_S1:
        if (dest == reg)
  	{
  #ifdef __AARCH64EB__
  	  dest += 12;
  #endif
  	}
        else
  	*(float *)dest = *(float *)reg;
        break;
      case AARCH64_RET_S2:
        asm ("ldp q16, q17, [%1]\n\t"
  	   "st2 { v16.s, v17.s }[0], [%0]"
  	   : : "r"(dest), "r"(reg) : "memory", "v16", "v17");
        break;
      case AARCH64_RET_S3:
        asm ("ldp q16, q17, [%1]\n\t"
  	   "ldr q18, [%1, #32]\n\t"
  	   "st3 { v16.s, v17.s, v18.s }[0], [%0]"
  	   : : "r"(dest), "r"(reg) : "memory", "v16", "v17", "v18");
        break;
      case AARCH64_RET_S4:
        asm ("ldp q16, q17, [%1]\n\t"
  	   "ldp q18, q19, [%1, #32]\n\t"
  	   "st4 { v16.s, v17.s, v18.s, v19.s }[0], [%0]"
  	   : : "r"(dest), "r"(reg) : "memory", "v16", "v17", "v18", "v19");
        break;
  
      case AARCH64_RET_D1:
        if (dest == reg)
  	{
  #ifdef __AARCH64EB__
  	  dest += 8;
  #endif
  	}
        else
  	*(double *)dest = *(double *)reg;
        break;
      case AARCH64_RET_D2:
        asm ("ldp q16, q17, [%1]\n\t"
  	   "st2 { v16.d, v17.d }[0], [%0]"
  	   : : "r"(dest), "r"(reg) : "memory", "v16", "v17");
        break;
      case AARCH64_RET_D3:
        asm ("ldp q16, q17, [%1]\n\t"
  	   "ldr q18, [%1, #32]\n\t"
  	   "st3 { v16.d, v17.d, v18.d }[0], [%0]"
  	   : : "r"(dest), "r"(reg) : "memory", "v16", "v17", "v18");
        break;
      case AARCH64_RET_D4:
        asm ("ldp q16, q17, [%1]\n\t"
  	   "ldp q18, q19, [%1, #32]\n\t"
  	   "st4 { v16.d, v17.d, v18.d, v19.d }[0], [%0]"
  	   : : "r"(dest), "r"(reg) : "memory", "v16", "v17", "v18", "v19");
        break;
  
      default:
        if (dest != reg)
  	return memcpy (dest, reg, 16 * (4 - (h & 3)));
        break;
      }
    return dest;
  }
  
  /* Either allocate an appropriate register for the argument type, or if
     none are available, allocate a stack slot and return a pointer
     to the allocated space.  */
  
  static void *
  allocate_int_to_reg_or_stack (struct call_context *context,
  			      struct arg_state *state,
  			      void *stack, size_t size)
  {
    if (state->ngrn < N_X_ARG_REG)
      return &context->x[state->ngrn++];
  
    state->ngrn = N_X_ARG_REG;
    return allocate_to_stack (state, stack, size, size);
  }
  
  ffi_status
  ffi_prep_cif_machdep (ffi_cif *cif)
  {
    ffi_type *rtype = cif->rtype;
    size_t bytes = cif->bytes;
    int flags, i, n;
  
    switch (rtype->type)
      {
      case FFI_TYPE_VOID:
        flags = AARCH64_RET_VOID;
        break;
      case FFI_TYPE_UINT8:
        flags = AARCH64_RET_UINT8;
        break;
      case FFI_TYPE_UINT16:
        flags = AARCH64_RET_UINT16;
        break;
      case FFI_TYPE_UINT32:
        flags = AARCH64_RET_UINT32;
        break;
      case FFI_TYPE_SINT8:
        flags = AARCH64_RET_SINT8;
        break;
      case FFI_TYPE_SINT16:
        flags = AARCH64_RET_SINT16;
        break;
      case FFI_TYPE_INT:
      case FFI_TYPE_SINT32:
        flags = AARCH64_RET_SINT32;
        break;
      case FFI_TYPE_SINT64:
      case FFI_TYPE_UINT64:
        flags = AARCH64_RET_INT64;
        break;
      case FFI_TYPE_POINTER:
        flags = (sizeof(void *) == 4 ? AARCH64_RET_UINT32 : AARCH64_RET_INT64);
        break;
  
      case FFI_TYPE_FLOAT:
      case FFI_TYPE_DOUBLE:
      case FFI_TYPE_LONGDOUBLE:
      case FFI_TYPE_STRUCT:
      case FFI_TYPE_COMPLEX:
        flags = is_vfp_type (rtype);
        if (flags == 0)
  	{
  	  size_t s = rtype->size;
  	  if (s > 16)
  	    {
  	      flags = AARCH64_RET_VOID | AARCH64_RET_IN_MEM;
  	      bytes += 8;
  	    }
  	  else if (s == 16)
  	    flags = AARCH64_RET_INT128;
  	  else if (s == 8)
  	    flags = AARCH64_RET_INT64;
  	  else
  	    flags = AARCH64_RET_INT128 | AARCH64_RET_NEED_COPY;
  	}
        break;
  
      default:
        abort();
      }
  
    for (i = 0, n = cif->nargs; i < n; i++)
      if (is_vfp_type (cif->arg_types[i]))
        {
  	flags |= AARCH64_FLAG_ARG_V;
  	break;
        }
  
    /* Round the stack up to a multiple of the stack alignment requirement. */
    cif->bytes = ALIGN(bytes, 16);
    cif->flags = flags;
  #if defined (__APPLE__)
    cif->aarch64_nfixedargs = 0;
  #endif
  
    return FFI_OK;
  }
  
  #if defined (__APPLE__)
  /* Perform Apple-specific cif processing for variadic calls */
  ffi_status ffi_prep_cif_machdep_var(ffi_cif *cif,
  				    unsigned int nfixedargs,
  				    unsigned int ntotalargs)
  {
    ffi_status status = ffi_prep_cif_machdep (cif);
    cif->aarch64_nfixedargs = nfixedargs;
    return status;
  }
  #endif /* __APPLE__ */
  
  extern void ffi_call_SYSV (struct call_context *context, void *frame,
  			   void (*fn)(void), void *rvalue, int flags,
  			   void *closure) FFI_HIDDEN;
  
  /* Call a function with the provided arguments and capture the return
     value.  */
  static void
  ffi_call_int (ffi_cif *cif, void (*fn)(void), void *orig_rvalue,
  	      void **avalue, void *closure)
  {
    struct call_context *context;
    void *stack, *frame, *rvalue;
    struct arg_state state;
    size_t stack_bytes, rtype_size, rsize;
    int i, nargs, flags;
    ffi_type *rtype;
  
    flags = cif->flags;
    rtype = cif->rtype;
    rtype_size = rtype->size;
    stack_bytes = cif->bytes;
  
    /* If the target function returns a structure via hidden pointer,
       then we cannot allow a null rvalue.  Otherwise, mash a null
       rvalue to void return type.  */
    rsize = 0;
    if (flags & AARCH64_RET_IN_MEM)
      {
        if (orig_rvalue == NULL)
  	rsize = rtype_size;
      }
    else if (orig_rvalue == NULL)
      flags &= AARCH64_FLAG_ARG_V;
    else if (flags & AARCH64_RET_NEED_COPY)
      rsize = 16;
  
    /* Allocate consectutive stack for everything we'll need.  */
    context = alloca (sizeof(struct call_context) + stack_bytes + 32 + rsize);
    stack = context + 1;
    frame = stack + stack_bytes;
    rvalue = (rsize ? frame + 32 : orig_rvalue);
  
    arg_init (&state);
    for (i = 0, nargs = cif->nargs; i < nargs; i++)
      {
        ffi_type *ty = cif->arg_types[i];
        size_t s = ty->size;
        void *a = avalue[i];
        int h, t;
  
        t = ty->type;
        switch (t)
  	{
  	case FFI_TYPE_VOID:
  	  FFI_ASSERT (0);
  	  break;
  
  	/* If the argument is a basic type the argument is allocated to an
  	   appropriate register, or if none are available, to the stack.  */
  	case FFI_TYPE_INT:
  	case FFI_TYPE_UINT8:
  	case FFI_TYPE_SINT8:
  	case FFI_TYPE_UINT16:
  	case FFI_TYPE_SINT16:
  	case FFI_TYPE_UINT32:
  	case FFI_TYPE_SINT32:
  	case FFI_TYPE_UINT64:
  	case FFI_TYPE_SINT64:
  	case FFI_TYPE_POINTER:
  	do_pointer:
  	  {
  	    ffi_arg ext = extend_integer_type (a, t);
  	    if (state.ngrn < N_X_ARG_REG)
  	      context->x[state.ngrn++] = ext;
  	    else
  	      {
  		void *d = allocate_to_stack (&state, stack, ty->alignment, s);
  		state.ngrn = N_X_ARG_REG;
  		/* Note that the default abi extends each argument
  		   to a full 64-bit slot, while the iOS abi allocates
  		   only enough space. */
  #ifdef __APPLE__
  		memcpy(d, a, s);
  #else
  		*(ffi_arg *)d = ext;
  #endif
  	      }
  	  }
  	  break;
  
  	case FFI_TYPE_FLOAT:
  	case FFI_TYPE_DOUBLE:
  	case FFI_TYPE_LONGDOUBLE:
  	case FFI_TYPE_STRUCT:
  	case FFI_TYPE_COMPLEX:
  	  {
  	    void *dest;
  
  	    h = is_vfp_type (ty);
  	    if (h)
  	      {
  		int elems = 4 - (h & 3);
  	        if (state.nsrn + elems <= N_V_ARG_REG)
  		  {
  		    dest = &context->v[state.nsrn];
  		    state.nsrn += elems;
  		    extend_hfa_type (dest, a, h);
  		    break;
  		  }
  		state.nsrn = N_V_ARG_REG;
  		dest = allocate_to_stack (&state, stack, ty->alignment, s);
  	      }
  	    else if (s > 16)
  	      {
  		/* If the argument is a composite type that is larger than 16
  		   bytes, then the argument has been copied to memory, and
  		   the argument is replaced by a pointer to the copy.  */
  		a = &avalue[i];
  		t = FFI_TYPE_POINTER;
  		goto do_pointer;
  	      }
  	    else
  	      {
  		size_t n = (s + 7) / 8;
  		if (state.ngrn + n <= N_X_ARG_REG)
  		  {
  		    /* If the argument is a composite type and the size in
  		       double-words is not more than the number of available
  		       X registers, then the argument is copied into
  		       consecutive X registers.  */
  		    dest = &context->x[state.ngrn];
  		    state.ngrn += n;
  		  }
  		else
  		  {
  		    /* Otherwise, there are insufficient X registers. Further
  		       X register allocations are prevented, the NSAA is
  		       adjusted and the argument is copied to memory at the
  		       adjusted NSAA.  */
  		    state.ngrn = N_X_ARG_REG;
  		    dest = allocate_to_stack (&state, stack, ty->alignment, s);
  		  }
  		}
  	      memcpy (dest, a, s);
  	    }
  	  break;
  
  	default:
  	  abort();
  	}
  
  #if defined (__APPLE__)
        if (i + 1 == cif->aarch64_nfixedargs)
  	{
  	  state.ngrn = N_X_ARG_REG;
  	  state.nsrn = N_V_ARG_REG;
  	  state.allocating_variadic = 1;
  	}
  #endif
      }
  
    ffi_call_SYSV (context, frame, fn, rvalue, flags, closure);
  
    if (flags & AARCH64_RET_NEED_COPY)
      memcpy (orig_rvalue, rvalue, rtype_size);
  }
  
  void
  ffi_call (ffi_cif *cif, void (*fn) (void), void *rvalue, void **avalue)
  {
    ffi_call_int (cif, fn, rvalue, avalue, NULL);
  }
  
  #ifdef FFI_GO_CLOSURES
  void
  ffi_call_go (ffi_cif *cif, void (*fn) (void), void *rvalue,
  	     void **avalue, void *closure)
  {
    ffi_call_int (cif, fn, rvalue, avalue, closure);
  }
  #endif /* FFI_GO_CLOSURES */
  
  /* Build a trampoline.  */
  
  extern void ffi_closure_SYSV (void) FFI_HIDDEN;
  extern void ffi_closure_SYSV_V (void) FFI_HIDDEN;
  
  #if FFI_EXEC_TRAMPOLINE_TABLE
  
  #include <mach/mach.h>
  #include <pthread.h>
  #include <stdio.h>
  #include <stdlib.h>
  
  extern void *ffi_closure_trampoline_table_page;
  
  typedef struct ffi_trampoline_table ffi_trampoline_table;
  typedef struct ffi_trampoline_table_entry ffi_trampoline_table_entry;
  
  struct ffi_trampoline_table
  {
    /* contiguous writable and executable pages */
    vm_address_t config_page;
    vm_address_t trampoline_page;
  
    /* free list tracking */
    uint16_t free_count;
    ffi_trampoline_table_entry *free_list;
    ffi_trampoline_table_entry *free_list_pool;
  
    ffi_trampoline_table *prev;
    ffi_trampoline_table *next;
  };
  
  struct ffi_trampoline_table_entry
  {
    void *(*trampoline) ();
    ffi_trampoline_table_entry *next;
  };
  
  /* The trampoline configuration is placed a page prior to the trampoline's entry point */
  #define FFI_TRAMPOLINE_CODELOC_CONFIG(codeloc) ((void **) (((uint8_t *) codeloc) - PAGE_SIZE));
  
  /* Total number of trampolines that fit in one trampoline table */
  #define FFI_TRAMPOLINE_COUNT (PAGE_SIZE / FFI_TRAMPOLINE_SIZE)
  
  static pthread_mutex_t ffi_trampoline_lock = PTHREAD_MUTEX_INITIALIZER;
  static ffi_trampoline_table *ffi_trampoline_tables = NULL;
  
  static ffi_trampoline_table *
  ffi_trampoline_table_alloc ()
  {
    ffi_trampoline_table *table = NULL;
  
    /* Loop until we can allocate two contiguous pages */
    while (table == NULL)
      {
        vm_address_t config_page = 0x0;
        kern_return_t kt;
  
        /* Try to allocate two pages */
        kt =
  	vm_allocate (mach_task_self (), &config_page, PAGE_SIZE * 2,
  		     VM_FLAGS_ANYWHERE);
        if (kt != KERN_SUCCESS)
  	{
  	  fprintf (stderr, "vm_allocate() failure: %d at %s:%d\n", kt,
  		   __FILE__, __LINE__);
  	  break;
  	}
  
        /* Now drop the second half of the allocation to make room for the trampoline table */
        vm_address_t trampoline_page = config_page + PAGE_SIZE;
        kt = vm_deallocate (mach_task_self (), trampoline_page, PAGE_SIZE);
        if (kt != KERN_SUCCESS)
  	{
  	  fprintf (stderr, "vm_deallocate() failure: %d at %s:%d\n", kt,
  		   __FILE__, __LINE__);
  	  break;
  	}
  
        /* Remap the trampoline table to directly follow the config page */
        vm_prot_t cur_prot;
        vm_prot_t max_prot;
  
        kt =
  	vm_remap (mach_task_self (), &trampoline_page, PAGE_SIZE, 0x0, FALSE,
  		  mach_task_self (),
  		  (vm_address_t) & ffi_closure_trampoline_table_page, FALSE,
  		  &cur_prot, &max_prot, VM_INHERIT_SHARE);
  
        /* If we lost access to the destination trampoline page, drop our config allocation mapping and retry */
        if (kt != KERN_SUCCESS)
  	{
  	  /* Log unexpected failures */
  	  if (kt != KERN_NO_SPACE)
  	    {
  	      fprintf (stderr, "vm_remap() failure: %d at %s:%d\n", kt,
  		       __FILE__, __LINE__);
  	    }
  
  	  vm_deallocate (mach_task_self (), config_page, PAGE_SIZE);
  	  continue;
  	}
  
        /* We have valid trampoline and config pages */
        table = calloc (1, sizeof (ffi_trampoline_table));
        table->free_count = FFI_TRAMPOLINE_COUNT;
        table->config_page = config_page;
        table->trampoline_page = trampoline_page;
  
        /* Create and initialize the free list */
        table->free_list_pool =
  	calloc (FFI_TRAMPOLINE_COUNT, sizeof (ffi_trampoline_table_entry));
  
        uint16_t i;
        for (i = 0; i < table->free_count; i++)
  	{
  	  ffi_trampoline_table_entry *entry = &table->free_list_pool[i];
  	  entry->trampoline =
  	    (void *) (table->trampoline_page + (i * FFI_TRAMPOLINE_SIZE));
  
  	  if (i < table->free_count - 1)
  	    entry->next = &table->free_list_pool[i + 1];
  	}
  
        table->free_list = table->free_list_pool;
      }
  
    return table;
  }
  
  void *
  ffi_closure_alloc (size_t size, void **code)
  {
    /* Create the closure */
    ffi_closure *closure = malloc (size);
    if (closure == NULL)
      return NULL;
  
    pthread_mutex_lock (&ffi_trampoline_lock);
  
    /* Check for an active trampoline table with available entries. */
    ffi_trampoline_table *table = ffi_trampoline_tables;
    if (table == NULL || table->free_list == NULL)
      {
        table = ffi_trampoline_table_alloc ();
        if (table == NULL)
  	{
  	  free (closure);
  	  return NULL;
  	}
  
        /* Insert the new table at the top of the list */
        table->next = ffi_trampoline_tables;
        if (table->next != NULL)
  	table->next->prev = table;
  
        ffi_trampoline_tables = table;
      }
  
    /* Claim the free entry */
    ffi_trampoline_table_entry *entry = ffi_trampoline_tables->free_list;
    ffi_trampoline_tables->free_list = entry->next;
    ffi_trampoline_tables->free_count--;
    entry->next = NULL;
  
    pthread_mutex_unlock (&ffi_trampoline_lock);
  
    /* Initialize the return values */
    *code = entry->trampoline;
    closure->trampoline_table = table;
    closure->trampoline_table_entry = entry;
  
    return closure;
  }
  
  void
  ffi_closure_free (void *ptr)
  {
    ffi_closure *closure = ptr;
  
    pthread_mutex_lock (&ffi_trampoline_lock);
  
    /* Fetch the table and entry references */
    ffi_trampoline_table *table = closure->trampoline_table;
    ffi_trampoline_table_entry *entry = closure->trampoline_table_entry;
  
    /* Return the entry to the free list */
    entry->next = table->free_list;
    table->free_list = entry;
    table->free_count++;
  
    /* If all trampolines within this table are free, and at least one other table exists, deallocate
     * the table */
    if (table->free_count == FFI_TRAMPOLINE_COUNT
        && ffi_trampoline_tables != table)
      {
        /* Remove from the list */
        if (table->prev != NULL)
  	table->prev->next = table->next;
  
        if (table->next != NULL)
  	table->next->prev = table->prev;
  
        /* Deallocate pages */
        kern_return_t kt;
        kt = vm_deallocate (mach_task_self (), table->config_page, PAGE_SIZE);
        if (kt != KERN_SUCCESS)
  	fprintf (stderr, "vm_deallocate() failure: %d at %s:%d\n", kt,
  		 __FILE__, __LINE__);
  
        kt =
  	vm_deallocate (mach_task_self (), table->trampoline_page, PAGE_SIZE);
        if (kt != KERN_SUCCESS)
  	fprintf (stderr, "vm_deallocate() failure: %d at %s:%d\n", kt,
  		 __FILE__, __LINE__);
  
        /* Deallocate free list */
        free (table->free_list_pool);
        free (table);
      }
    else if (ffi_trampoline_tables != table)
      {
        /* Otherwise, bump this table to the top of the list */
        table->prev = NULL;
        table->next = ffi_trampoline_tables;
        if (ffi_trampoline_tables != NULL)
  	ffi_trampoline_tables->prev = table;
  
        ffi_trampoline_tables = table;
      }
  
    pthread_mutex_unlock (&ffi_trampoline_lock);
  
    /* Free the closure */
    free (closure);
  }
  
  #endif
  
  ffi_status
  ffi_prep_closure_loc (ffi_closure *closure,
                        ffi_cif* cif,
                        void (*fun)(ffi_cif*,void*,void**,void*),
                        void *user_data,
                        void *codeloc)
  {
    if (cif->abi != FFI_SYSV)
      return FFI_BAD_ABI;
  
    void (*start)(void);
    
    if (cif->flags & AARCH64_FLAG_ARG_V)
      start = ffi_closure_SYSV_V;
    else
      start = ffi_closure_SYSV;
  
  #if FFI_EXEC_TRAMPOLINE_TABLE
    void **config = FFI_TRAMPOLINE_CODELOC_CONFIG (codeloc);
    config[0] = closure;
    config[1] = start;
  #else
    static const unsigned char trampoline[16] = {
      0x90, 0x00, 0x00, 0x58,	/* ldr	x16, tramp+16	*/
      0xf1, 0xff, 0xff, 0x10,	/* adr	x17, tramp+0	*/
      0x00, 0x02, 0x1f, 0xd6	/* br	x16		*/
    };
    char *tramp = closure->tramp;
    
    memcpy (tramp, trampoline, sizeof(trampoline));
    
    *(UINT64 *)(tramp + 16) = (uintptr_t)start;
  
    ffi_clear_cache(tramp, tramp + FFI_TRAMPOLINE_SIZE);
  #endif
  
    closure->cif = cif;
    closure->fun = fun;
    closure->user_data = user_data;
  
    return FFI_OK;
  }
  
  #ifdef FFI_GO_CLOSURES
  extern void ffi_go_closure_SYSV (void) FFI_HIDDEN;
  extern void ffi_go_closure_SYSV_V (void) FFI_HIDDEN;
  
  ffi_status
  ffi_prep_go_closure (ffi_go_closure *closure, ffi_cif* cif,
                       void (*fun)(ffi_cif*,void*,void**,void*))
  {
    void (*start)(void);
  
    if (cif->abi != FFI_SYSV)
      return FFI_BAD_ABI;
  
    if (cif->flags & AARCH64_FLAG_ARG_V)
      start = ffi_go_closure_SYSV_V;
    else
      start = ffi_go_closure_SYSV;
  
    closure->tramp = start;
    closure->cif = cif;
    closure->fun = fun;
  
    return FFI_OK;
  }
  #endif /* FFI_GO_CLOSURES */
  
  /* Primary handler to setup and invoke a function within a closure.
  
     A closure when invoked enters via the assembler wrapper
     ffi_closure_SYSV(). The wrapper allocates a call context on the
     stack, saves the interesting registers (from the perspective of
     the calling convention) into the context then passes control to
     ffi_closure_SYSV_inner() passing the saved context and a pointer to
     the stack at the point ffi_closure_SYSV() was invoked.
  
     On the return path the assembler wrapper will reload call context
     registers.
  
     ffi_closure_SYSV_inner() marshalls the call context into ffi value
     descriptors, invokes the wrapped function, then marshalls the return
     value back into the call context.  */
  
  int FFI_HIDDEN
  ffi_closure_SYSV_inner (ffi_cif *cif,
  			void (*fun)(ffi_cif*,void*,void**,void*),
  			void *user_data,
  			struct call_context *context,
  			void *stack, void *rvalue, void *struct_rvalue)
  {
    void **avalue = (void**) alloca (cif->nargs * sizeof (void*));
    int i, h, nargs, flags;
    struct arg_state state;
  
    arg_init (&state);
  
    for (i = 0, nargs = cif->nargs; i < nargs; i++)
      {
        ffi_type *ty = cif->arg_types[i];
        int t = ty->type;
        size_t n, s = ty->size;
  
        switch (t)
  	{
  	case FFI_TYPE_VOID:
  	  FFI_ASSERT (0);
  	  break;
  
  	case FFI_TYPE_INT:
  	case FFI_TYPE_UINT8:
  	case FFI_TYPE_SINT8:
  	case FFI_TYPE_UINT16:
  	case FFI_TYPE_SINT16:
  	case FFI_TYPE_UINT32:
  	case FFI_TYPE_SINT32:
  	case FFI_TYPE_UINT64:
  	case FFI_TYPE_SINT64:
  	case FFI_TYPE_POINTER:
  	  avalue[i] = allocate_int_to_reg_or_stack (context, &state, stack, s);
  	  break;
  
  	case FFI_TYPE_FLOAT:
  	case FFI_TYPE_DOUBLE:
  	case FFI_TYPE_LONGDOUBLE:
  	case FFI_TYPE_STRUCT:
  	case FFI_TYPE_COMPLEX:
  	  h = is_vfp_type (ty);
  	  if (h)
  	    {
  	      n = 4 - (h & 3);
  	      if (state.nsrn + n <= N_V_ARG_REG)
  		{
  		  void *reg = &context->v[state.nsrn];
  		  state.nsrn += n;
  
  		  /* Eeek! We need a pointer to the structure, however the
  		     homogeneous float elements are being passed in individual
  		     registers, therefore for float and double the structure
  		     is not represented as a contiguous sequence of bytes in
  		     our saved register context.  We don't need the original
  		     contents of the register storage, so we reformat the
  		     structure into the same memory.  */
  		  avalue[i] = compress_hfa_type (reg, reg, h);
  		}
  	      else
  		{
  		  state.nsrn = N_V_ARG_REG;
  		  avalue[i] = allocate_to_stack (&state, stack,
  						 ty->alignment, s);
  		}
  	    }
  	  else if (s > 16)
  	    {
  	      /* Replace Composite type of size greater than 16 with a
  		 pointer.  */
  	      avalue[i] = *(void **)
  		allocate_int_to_reg_or_stack (context, &state, stack,
  					      sizeof (void *));
  	    }
  	  else
  	    {
  	      n = (s + 7) / 8;
  	      if (state.ngrn + n <= N_X_ARG_REG)
  		{
  		  avalue[i] = &context->x[state.ngrn];
  		  state.ngrn += n;
  		}
  	      else
  		{
  		  state.ngrn = N_X_ARG_REG;
  		  avalue[i] = allocate_to_stack (&state, stack,
  						 ty->alignment, s);
  		}
  	    }
  	  break;
  
  	default:
  	  abort();
  	}
      }
  
    flags = cif->flags;
    if (flags & AARCH64_RET_IN_MEM)
      rvalue = struct_rvalue;
  
    fun (cif, rvalue, avalue, user_data);
  
    return flags;
  }
  

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