rpm/MozillaFirefox
SHA256
1
0
Fork 0
forked from pool/MozillaFirefox
Code Pull Requests Activity
27336c8295
MozillaFirefox/mozilla-ppc64le-libffi.patch
Wolfgang Rosenauer ee63deb207 - update to Firefox 28.0 (bnc#868603) 
* MFSA 2014-15/CVE-2014-1493/CVE-2014-1494
    Miscellaneous memory safety hazards
  * MFSA 2014-17/CVE-2014-1497 (bmo#966311)
    Out of bounds read during WAV file decoding
  * MFSA 2014-18/CVE-2014-1498 (bmo#935618)
    crypto.generateCRMFRequest does not validate type of key
  * MFSA 2014-19/CVE-2014-1499 (bmo#961512)
    Spoofing attack on WebRTC permission prompt
  * MFSA 2014-20/CVE-2014-1500 (bmo#956524)
    onbeforeunload and Javascript navigation DOS
  * MFSA 2014-22/CVE-2014-1502 (bmo#972622)
    WebGL content injection from one domain to rendering in another
  * MFSA 2014-23/CVE-2014-1504 (bmo#911547)
    Content Security Policy for data: documents not preserved by
    session restore
  * MFSA 2014-26/CVE-2014-1508 (bmo#963198)
    Information disclosure through polygon rendering in MathML
  * MFSA 2014-27/CVE-2014-1509 (bmo#966021)
    Memory corruption in Cairo during PDF font rendering
  * MFSA 2014-28/CVE-2014-1505 (bmo#941887)
    SVG filters information disclosure through feDisplacementMap
  * MFSA 2014-29/CVE-2014-1510/CVE-2014-1511 (bmo#982906, bmo#982909)
    Privilege escalation using WebIDL-implemented APIs
  * MFSA 2014-30/CVE-2014-1512 (bmo#982957)
    Use-after-free in TypeObject
  * MFSA 2014-31/CVE-2014-1513 (bmo#982974)
    Out-of-bounds read/write through neutering ArrayBuffer objects
  * MFSA 2014-32/CVE-2014-1514 (bmo#983344)
    Out-of-bounds write through TypedArrayObject after neutering

OBS-URL: https://build.opensuse.org/package/show/mozilla:Factory/MozillaFirefox?expand=0&rev=370
2014-03-18 19:44:32 +00:00

3207 lines
84 KiB
Diff
Raw Blame History

# HG changeset patch
# Parent 16cf73a02802e3b4a77ccd77794346441638e2a7
# User Ulrich Weigand <uweigand@de.ibm.com>
Bug 976648 - powerpc64le-linux support - libffi backport
diff --git a/js/src/ctypes/libffi/aclocal.m4 b/js/src/ctypes/libffi/aclocal.m4
--- a/js/src/ctypes/libffi/aclocal.m4
+++ b/js/src/ctypes/libffi/aclocal.m4
@@ -1277,31 +1277,34 @@ ia64-*-hpux*)
LD="${LD-ld} -64"
;;
esac
fi
fi
rm -rf conftest*
;;
-x86_64-*kfreebsd*-gnu|x86_64-*linux*|ppc*-*linux*|powerpc*-*linux*| \
+x86_64-*kfreebsd*-gnu|x86_64-*linux*|powerpc*-*linux*| \
s390*-*linux*|s390*-*tpf*|sparc*-*linux*)
# Find out which ABI we are using.
echo 'int i;' > conftest.$ac_ext
if AC_TRY_EVAL(ac_compile); then
case `/usr/bin/file conftest.o` in
*32-bit*)
case $host in
x86_64-*kfreebsd*-gnu)
LD="${LD-ld} -m elf_i386_fbsd"
;;
x86_64-*linux*)
LD="${LD-ld} -m elf_i386"
;;
- ppc64-*linux*|powerpc64-*linux*)
+ powerpc64le-*linux*)
+ LD="${LD-ld} -m elf32lppclinux"
+ ;;
+ powerpc64-*linux*)
LD="${LD-ld} -m elf32ppclinux"
;;
s390x-*linux*)
LD="${LD-ld} -m elf_s390"
;;
sparc64-*linux*)
LD="${LD-ld} -m elf32_sparc"
;;
@@ -1310,17 +1313,20 @@ s390*-*linux*|s390*-*tpf*|sparc*-*linux*
*64-bit*)
case $host in
x86_64-*kfreebsd*-gnu)
LD="${LD-ld} -m elf_x86_64_fbsd"
;;
x86_64-*linux*)
LD="${LD-ld} -m elf_x86_64"
;;
- ppc*-*linux*|powerpc*-*linux*)
+ powerpcle-*linux*)
+ LD="${LD-ld} -m elf64lppc"
+ ;;
+ powerpc-*linux*)
LD="${LD-ld} -m elf64ppc"
;;
s390*-*linux*|s390*-*tpf*)
LD="${LD-ld} -m elf64_s390"
;;
sparc*-*linux*)
LD="${LD-ld} -m elf64_sparc"
;;
diff --git a/js/src/ctypes/libffi/configure b/js/src/ctypes/libffi/configure
--- a/js/src/ctypes/libffi/configure
+++ b/js/src/ctypes/libffi/configure
@@ -6293,17 +6293,17 @@ ia64-*-hpux*)
LD="${LD-ld} -64"
;;
esac
fi
fi
rm -rf conftest*
;;
-x86_64-*kfreebsd*-gnu|x86_64-*linux*|ppc*-*linux*|powerpc*-*linux*| \
+x86_64-*kfreebsd*-gnu|x86_64-*linux*|powerpc*-*linux*| \
s390*-*linux*|s390*-*tpf*|sparc*-*linux*)
# Find out which ABI we are using.
echo 'int i;' > conftest.$ac_ext
if { { eval echo "\"\$as_me\":${as_lineno-$LINENO}: \"$ac_compile\""; } >&5
(eval $ac_compile) 2>&5
ac_status=$?
$as_echo "$as_me:${as_lineno-$LINENO}: \$? = $ac_status" >&5
test $ac_status = 0; }; then
@@ -6311,17 +6311,20 @@ s390*-*linux*|s390*-*tpf*|sparc*-*linux*
*32-bit*)
case $host in
x86_64-*kfreebsd*-gnu)
LD="${LD-ld} -m elf_i386_fbsd"
;;
x86_64-*linux*)
LD="${LD-ld} -m elf_i386"
;;
- ppc64-*linux*|powerpc64-*linux*)
+ powerpc64le-*linux*)
+ LD="${LD-ld} -m elf32lppclinux"
+ ;;
+ powerpc64-*linux*)
LD="${LD-ld} -m elf32ppclinux"
;;
s390x-*linux*)
LD="${LD-ld} -m elf_s390"
;;
sparc64-*linux*)
LD="${LD-ld} -m elf32_sparc"
;;
@@ -6330,17 +6333,20 @@ s390*-*linux*|s390*-*tpf*|sparc*-*linux*
*64-bit*)
case $host in
x86_64-*kfreebsd*-gnu)
LD="${LD-ld} -m elf_x86_64_fbsd"
;;
x86_64-*linux*)
LD="${LD-ld} -m elf_x86_64"
;;
- ppc*-*linux*|powerpc*-*linux*)
+ powerpcle-*linux*)
+ LD="${LD-ld} -m elf64lppc"
+ ;;
+ powerpc-*linux*)
LD="${LD-ld} -m elf64ppc"
;;
s390*-*linux*|s390*-*tpf*)
LD="${LD-ld} -m elf64_s390"
;;
sparc*-*linux*)
LD="${LD-ld} -m elf64_sparc"
;;
diff --git a/js/src/ctypes/libffi/m4/libtool.m4 b/js/src/ctypes/libffi/m4/libtool.m4
--- a/js/src/ctypes/libffi/m4/libtool.m4
+++ b/js/src/ctypes/libffi/m4/libtool.m4
@@ -1262,31 +1262,34 @@ ia64-*-hpux*)
LD="${LD-ld} -64"
;;
esac
fi
fi
rm -rf conftest*
;;
-x86_64-*kfreebsd*-gnu|x86_64-*linux*|ppc*-*linux*|powerpc*-*linux*| \
+x86_64-*kfreebsd*-gnu|x86_64-*linux*|powerpc*-*linux*| \
s390*-*linux*|s390*-*tpf*|sparc*-*linux*)
# Find out which ABI we are using.
echo 'int i;' > conftest.$ac_ext
if AC_TRY_EVAL(ac_compile); then
case `/usr/bin/file conftest.o` in
*32-bit*)
case $host in
x86_64-*kfreebsd*-gnu)
LD="${LD-ld} -m elf_i386_fbsd"
;;
x86_64-*linux*)
LD="${LD-ld} -m elf_i386"
;;
- ppc64-*linux*|powerpc64-*linux*)
+ powerpc64le-*linux*)
+ LD="${LD-ld} -m elf32lppclinux"
+ ;;
+ powerpc64-*linux*)
LD="${LD-ld} -m elf32ppclinux"
;;
s390x-*linux*)
LD="${LD-ld} -m elf_s390"
;;
sparc64-*linux*)
LD="${LD-ld} -m elf32_sparc"
;;
@@ -1295,17 +1298,20 @@ s390*-*linux*|s390*-*tpf*|sparc*-*linux*
*64-bit*)
case $host in
x86_64-*kfreebsd*-gnu)
LD="${LD-ld} -m elf_x86_64_fbsd"
;;
x86_64-*linux*)
LD="${LD-ld} -m elf_x86_64"
;;
- ppc*-*linux*|powerpc*-*linux*)
+ powerpcle-*linux*)
+ LD="${LD-ld} -m elf64lppc"
+ ;;
+ powerpc-*linux*)
LD="${LD-ld} -m elf64ppc"
;;
s390*-*linux*|s390*-*tpf*)
LD="${LD-ld} -m elf64_s390"
;;
sparc*-*linux*)
LD="${LD-ld} -m elf64_sparc"
;;
diff --git a/js/src/ctypes/libffi/src/powerpc/ffi.c b/js/src/ctypes/libffi/src/powerpc/ffi.c
--- a/js/src/ctypes/libffi/src/powerpc/ffi.c
+++ b/js/src/ctypes/libffi/src/powerpc/ffi.c
@@ -1,12 +1,14 @@
/* -----------------------------------------------------------------------
- ffi.c - Copyright (c) 1998 Geoffrey Keating
- Copyright (C) 2007, 2008 Free Software Foundation, Inc
- Copyright (C) 2008 Red Hat, Inc
+ ffi.c - Copyright (C) 2011 Anthony Green
+ Copyright (C) 2011 Kyle Moffett
+ Copyright (C) 2008 Red Hat, Inc
+ Copyright (C) 2007, 2008 Free Software Foundation, Inc
+ Copyright (c) 1998 Geoffrey Keating
PowerPC Foreign Function Interface
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
@@ -34,42 +36,39 @@
extern void ffi_closure_SYSV (void);
extern void FFI_HIDDEN ffi_closure_LINUX64 (void);
enum {
/* The assembly depends on these exact flags. */
FLAG_RETURNS_SMST = 1 << (31-31), /* Used for FFI_SYSV small structs. */
FLAG_RETURNS_NOTHING = 1 << (31-30), /* These go in cr7 */
+#ifndef __NO_FPRS__
FLAG_RETURNS_FP = 1 << (31-29),
+#endif
FLAG_RETURNS_64BITS = 1 << (31-28),
FLAG_RETURNS_128BITS = 1 << (31-27), /* cr6 */
- FLAG_SYSV_SMST_R4 = 1 << (31-26), /* use r4 for FFI_SYSV 8 byte
- structs. */
- FLAG_SYSV_SMST_R3 = 1 << (31-25), /* use r3 for FFI_SYSV 4 byte
- structs. */
- /* Bits (31-24) through (31-19) store shift value for SMST */
FLAG_ARG_NEEDS_COPY = 1 << (31- 7),
+ FLAG_ARG_NEEDS_PSAVE = FLAG_ARG_NEEDS_COPY, /* Used by ELFv2 */
+#ifndef __NO_FPRS__
FLAG_FP_ARGUMENTS = 1 << (31- 6), /* cr1.eq; specified by ABI */
+#endif
FLAG_4_GPR_ARGUMENTS = 1 << (31- 5),
FLAG_RETVAL_REFERENCE = 1 << (31- 4)
};
/* About the SYSV ABI. */
-unsigned int NUM_GPR_ARG_REGISTERS = 8;
+#define ASM_NEEDS_REGISTERS 4
+#define NUM_GPR_ARG_REGISTERS 8
#ifndef __NO_FPRS__
-unsigned int NUM_FPR_ARG_REGISTERS = 8;
-#else
-unsigned int NUM_FPR_ARG_REGISTERS = 0;
+# define NUM_FPR_ARG_REGISTERS 8
#endif
-enum { ASM_NEEDS_REGISTERS = 4 };
-
/* ffi_prep_args_SYSV is called by the assembly routine once stack space
has been allocated for the function's arguments.
The stack layout we want looks like this:
| Return address from ffi_call_SYSV 4bytes | higher addresses
|--------------------------------------------|
| Previous backchain pointer 4 | stack pointer here
@@ -108,100 +107,119 @@ ffi_prep_args_SYSV (extended_cif *ecif,
/* 'stacktop' points at the previous backchain pointer. */
valp stacktop;
/* 'gpr_base' points at the space for gpr3, and grows upwards as
we use GPR registers. */
valp gpr_base;
int intarg_count;
+#ifndef __NO_FPRS__
/* 'fpr_base' points at the space for fpr1, and grows upwards as
we use FPR registers. */
valp fpr_base;
int fparg_count;
+#endif
/* 'copy_space' grows down as we put structures in it. It should
stay 16-byte aligned. */
valp copy_space;
/* 'next_arg' grows up as we put parameters in it. */
valp next_arg;
- int i, ii MAYBE_UNUSED;
+ int i;
ffi_type **ptr;
+#ifndef __NO_FPRS__
double double_tmp;
+#endif
union {
void **v;
char **c;
signed char **sc;
unsigned char **uc;
signed short **ss;
unsigned short **us;
unsigned int **ui;
long long **ll;
float **f;
double **d;
} p_argv;
size_t struct_copy_size;
unsigned gprvalue;
- if (ecif->cif->abi == FFI_LINUX_SOFT_FLOAT)
- NUM_FPR_ARG_REGISTERS = 0;
-
stacktop.c = (char *) stack + bytes;
gpr_base.u = stacktop.u - ASM_NEEDS_REGISTERS - NUM_GPR_ARG_REGISTERS;
intarg_count = 0;
+#ifndef __NO_FPRS__
fpr_base.d = gpr_base.d - NUM_FPR_ARG_REGISTERS;
fparg_count = 0;
copy_space.c = ((flags & FLAG_FP_ARGUMENTS) ? fpr_base.c : gpr_base.c);
+#else
+ copy_space.c = gpr_base.c;
+#endif
next_arg.u = stack + 2;
/* Check that everything starts aligned properly. */
- FFI_ASSERT (((unsigned) (char *) stack & 0xF) == 0);
- FFI_ASSERT (((unsigned) copy_space.c & 0xF) == 0);
- FFI_ASSERT (((unsigned) stacktop.c & 0xF) == 0);
+ FFI_ASSERT (((unsigned long) (char *) stack & 0xF) == 0);
+ FFI_ASSERT (((unsigned long) copy_space.c & 0xF) == 0);
+ FFI_ASSERT (((unsigned long) stacktop.c & 0xF) == 0);
FFI_ASSERT ((bytes & 0xF) == 0);
FFI_ASSERT (copy_space.c >= next_arg.c);
/* Deal with return values that are actually pass-by-reference. */
if (flags & FLAG_RETVAL_REFERENCE)
{
*gpr_base.u++ = (unsigned long) (char *) ecif->rvalue;
intarg_count++;
}
/* Now for the arguments. */
p_argv.v = ecif->avalue;
for (ptr = ecif->cif->arg_types, i = ecif->cif->nargs;
i > 0;
i--, ptr++, p_argv.v++)
{
- switch ((*ptr)->type)
- {
+ unsigned short typenum = (*ptr)->type;
+
+ /* We may need to handle some values depending on ABI */
+ if (ecif->cif->abi == FFI_LINUX_SOFT_FLOAT) {
+ if (typenum == FFI_TYPE_FLOAT)
+ typenum = FFI_TYPE_UINT32;
+ if (typenum == FFI_TYPE_DOUBLE)
+ typenum = FFI_TYPE_UINT64;
+ if (typenum == FFI_TYPE_LONGDOUBLE)
+ typenum = FFI_TYPE_UINT128;
+ } else if (ecif->cif->abi != FFI_LINUX) {
+#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
+ if (typenum == FFI_TYPE_LONGDOUBLE)
+ typenum = FFI_TYPE_STRUCT;
+#endif
+ }
+
+ /* Now test the translated value */
+ switch (typenum) {
+#ifndef __NO_FPRS__
case FFI_TYPE_FLOAT:
/* With FFI_LINUX_SOFT_FLOAT floats are handled like UINT32. */
- if (ecif->cif->abi == FFI_LINUX_SOFT_FLOAT)
- goto soft_float_prep;
double_tmp = **p_argv.f;
if (fparg_count >= NUM_FPR_ARG_REGISTERS)
{
*next_arg.f = (float) double_tmp;
next_arg.u += 1;
intarg_count++;
}
else
*fpr_base.d++ = double_tmp;
fparg_count++;
FFI_ASSERT (flags & FLAG_FP_ARGUMENTS);
break;
case FFI_TYPE_DOUBLE:
/* With FFI_LINUX_SOFT_FLOAT doubles are handled like UINT64. */
- if (ecif->cif->abi == FFI_LINUX_SOFT_FLOAT)
- goto soft_double_prep;
double_tmp = **p_argv.d;
if (fparg_count >= NUM_FPR_ARG_REGISTERS)
{
if (intarg_count >= NUM_GPR_ARG_REGISTERS
&& intarg_count % 2 != 0)
{
intarg_count++;
@@ -213,53 +231,16 @@ ffi_prep_args_SYSV (extended_cif *ecif,
else
*fpr_base.d++ = double_tmp;
fparg_count++;
FFI_ASSERT (flags & FLAG_FP_ARGUMENTS);
break;
#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
case FFI_TYPE_LONGDOUBLE:
- if ((ecif->cif->abi != FFI_LINUX)
- && (ecif->cif->abi != FFI_LINUX_SOFT_FLOAT))
- goto do_struct;
- /* The soft float ABI for long doubles works like this,
- a long double is passed in four consecutive gprs if available.
- A maximum of 2 long doubles can be passed in gprs.
- If we do not have 4 gprs left, the long double is passed on the
- stack, 4-byte aligned. */
- if (ecif->cif->abi == FFI_LINUX_SOFT_FLOAT)
- {
- unsigned int int_tmp = (*p_argv.ui)[0];
- if (intarg_count >= NUM_GPR_ARG_REGISTERS - 3)
- {
- if (intarg_count < NUM_GPR_ARG_REGISTERS)
- intarg_count += NUM_GPR_ARG_REGISTERS - intarg_count;
- *next_arg.u = int_tmp;
- next_arg.u++;
- for (ii = 1; ii < 4; ii++)
- {
- int_tmp = (*p_argv.ui)[ii];
- *next_arg.u = int_tmp;
- next_arg.u++;
- }
- }
- else
- {
- *gpr_base.u++ = int_tmp;
- for (ii = 1; ii < 4; ii++)
- {
- int_tmp = (*p_argv.ui)[ii];
- *gpr_base.u++ = int_tmp;
- }
- }
- intarg_count +=4;
- }
- else
- {
double_tmp = (*p_argv.d)[0];
if (fparg_count >= NUM_FPR_ARG_REGISTERS - 1)
{
if (intarg_count >= NUM_GPR_ARG_REGISTERS
&& intarg_count % 2 != 0)
{
intarg_count++;
@@ -275,23 +256,50 @@ ffi_prep_args_SYSV (extended_cif *ecif,
{
*fpr_base.d++ = double_tmp;
double_tmp = (*p_argv.d)[1];
*fpr_base.d++ = double_tmp;
}
fparg_count += 2;
FFI_ASSERT (flags & FLAG_FP_ARGUMENTS);
- }
break;
#endif
+#endif /* have FPRs */
+
+ /*
+ * The soft float ABI for long doubles works like this, a long double
+ * is passed in four consecutive GPRs if available. A maximum of 2
+ * long doubles can be passed in gprs. If we do not have 4 GPRs
+ * left, the long double is passed on the stack, 4-byte aligned.
+ */
+ case FFI_TYPE_UINT128: {
+ unsigned int int_tmp = (*p_argv.ui)[0];
+ unsigned int ii;
+ if (intarg_count >= NUM_GPR_ARG_REGISTERS - 3) {
+ if (intarg_count < NUM_GPR_ARG_REGISTERS)
+ intarg_count += NUM_GPR_ARG_REGISTERS - intarg_count;
+ *(next_arg.u++) = int_tmp;
+ for (ii = 1; ii < 4; ii++) {
+ int_tmp = (*p_argv.ui)[ii];
+ *(next_arg.u++) = int_tmp;
+ }
+ } else {
+ *(gpr_base.u++) = int_tmp;
+ for (ii = 1; ii < 4; ii++) {
+ int_tmp = (*p_argv.ui)[ii];
+ *(gpr_base.u++) = int_tmp;
+ }
+ }
+ intarg_count += 4;
+ break;
+ }
case FFI_TYPE_UINT64:
case FFI_TYPE_SINT64:
- soft_double_prep:
if (intarg_count == NUM_GPR_ARG_REGISTERS-1)
intarg_count++;
if (intarg_count >= NUM_GPR_ARG_REGISTERS)
{
if (intarg_count % 2 != 0)
{
intarg_count++;
next_arg.u++;
@@ -314,19 +322,16 @@ ffi_prep_args_SYSV (extended_cif *ecif,
gpr_base.u++;
}
*gpr_base.ll++ = **p_argv.ll;
}
intarg_count += 2;
break;
case FFI_TYPE_STRUCT:
-#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
- do_struct:
-#endif
struct_copy_size = ((*ptr)->size + 15) & ~0xF;
copy_space.c -= struct_copy_size;
memcpy (copy_space.c, *p_argv.c, (*ptr)->size);
gprvalue = (unsigned long) copy_space.c;
FFI_ASSERT (copy_space.c > next_arg.c);
FFI_ASSERT (flags & FLAG_ARG_NEEDS_COPY);
@@ -344,45 +349,91 @@ ffi_prep_args_SYSV (extended_cif *ecif,
case FFI_TYPE_SINT16:
gprvalue = **p_argv.ss;
goto putgpr;
case FFI_TYPE_INT:
case FFI_TYPE_UINT32:
case FFI_TYPE_SINT32:
case FFI_TYPE_POINTER:
- soft_float_prep:
gprvalue = **p_argv.ui;
putgpr:
if (intarg_count >= NUM_GPR_ARG_REGISTERS)
*next_arg.u++ = gprvalue;
else
*gpr_base.u++ = gprvalue;
intarg_count++;
break;
}
}
/* Check that we didn't overrun the stack... */
FFI_ASSERT (copy_space.c >= next_arg.c);
FFI_ASSERT (gpr_base.u <= stacktop.u - ASM_NEEDS_REGISTERS);
+ /* The assert below is testing that the number of integer arguments agrees
+ with the number found in ffi_prep_cif_machdep(). However, intarg_count
+ is incremented whenever we place an FP arg on the stack, so account for
+ that before our assert test. */
+#ifndef __NO_FPRS__
+ if (fparg_count > NUM_FPR_ARG_REGISTERS)
+ intarg_count -= fparg_count - NUM_FPR_ARG_REGISTERS;
FFI_ASSERT (fpr_base.u
<= stacktop.u - ASM_NEEDS_REGISTERS - NUM_GPR_ARG_REGISTERS);
+#endif
FFI_ASSERT (flags & FLAG_4_GPR_ARGUMENTS || intarg_count <= 4);
}
/* About the LINUX64 ABI. */
enum {
NUM_GPR_ARG_REGISTERS64 = 8,
NUM_FPR_ARG_REGISTERS64 = 13
};
enum { ASM_NEEDS_REGISTERS64 = 4 };
+#if _CALL_ELF == 2
+static unsigned int
+discover_homogeneous_aggregate (const ffi_type *t, unsigned int *elnum)
+{
+ switch (t->type)
+ {
+ case FFI_TYPE_FLOAT:
+ case FFI_TYPE_DOUBLE:
+ *elnum = 1;
+ return (int) t->type;
+
+ case FFI_TYPE_STRUCT:;
+ {
+ unsigned int base_elt = 0, total_elnum = 0;
+ ffi_type **el = t->elements;
+ while (*el)
+ {
+ unsigned int el_elt, el_elnum = 0;
+ el_elt = discover_homogeneous_aggregate (*el, &el_elnum);
+ if (el_elt == 0
+ || (base_elt && base_elt != el_elt))
+ return 0;
+ base_elt = el_elt;
+ total_elnum += el_elnum;
+ if (total_elnum > 8)
+ return 0;
+ el++;
+ }
+ *elnum = total_elnum;
+ return base_elt;
+ }
+
+ default:
+ return 0;
+ }
+}
+#endif
+
+
/* ffi_prep_args64 is called by the assembly routine once stack space
has been allocated for the function's arguments.
The stack layout we want looks like this:
| Ret addr from ffi_call_LINUX64 8bytes | higher addresses
|--------------------------------------------|
| CR save area 8bytes |
@@ -418,141 +469,216 @@ ffi_prep_args64 (extended_cif *ecif, uns
const unsigned long bytes = ecif->cif->bytes;
const unsigned long flags = ecif->cif->flags;
typedef union {
char *c;
unsigned long *ul;
float *f;
double *d;
+ size_t p;
} valp;
/* 'stacktop' points at the previous backchain pointer. */
valp stacktop;
/* 'next_arg' points at the space for gpr3, and grows upwards as
we use GPR registers, then continues at rest. */
valp gpr_base;
valp gpr_end;
valp rest;
valp next_arg;
/* 'fpr_base' points at the space for fpr3, and grows upwards as
we use FPR registers. */
valp fpr_base;
- int fparg_count;
+ unsigned int fparg_count;
- int i, words;
+ unsigned int i, words, nargs, nfixedargs;
ffi_type **ptr;
double double_tmp;
union {
void **v;
char **c;
signed char **sc;
unsigned char **uc;
signed short **ss;
unsigned short **us;
signed int **si;
unsigned int **ui;
unsigned long **ul;
float **f;
double **d;
} p_argv;
unsigned long gprvalue;
+#ifdef __STRUCT_PARM_ALIGN__
+ unsigned long align;
+#endif
stacktop.c = (char *) stack + bytes;
gpr_base.ul = stacktop.ul - ASM_NEEDS_REGISTERS64 - NUM_GPR_ARG_REGISTERS64;
gpr_end.ul = gpr_base.ul + NUM_GPR_ARG_REGISTERS64;
+#if _CALL_ELF == 2
+ rest.ul = stack + 4 + NUM_GPR_ARG_REGISTERS64;
+#else
rest.ul = stack + 6 + NUM_GPR_ARG_REGISTERS64;
+#endif
fpr_base.d = gpr_base.d - NUM_FPR_ARG_REGISTERS64;
fparg_count = 0;
next_arg.ul = gpr_base.ul;
/* Check that everything starts aligned properly. */
FFI_ASSERT (((unsigned long) (char *) stack & 0xF) == 0);
FFI_ASSERT (((unsigned long) stacktop.c & 0xF) == 0);
FFI_ASSERT ((bytes & 0xF) == 0);
/* Deal with return values that are actually pass-by-reference. */
if (flags & FLAG_RETVAL_REFERENCE)
*next_arg.ul++ = (unsigned long) (char *) ecif->rvalue;
/* Now for the arguments. */
p_argv.v = ecif->avalue;
- for (ptr = ecif->cif->arg_types, i = ecif->cif->nargs;
- i > 0;
- i--, ptr++, p_argv.v++)
+ nargs = ecif->cif->nargs;
+ nfixedargs = ecif->cif->nfixedargs;
+ for (ptr = ecif->cif->arg_types, i = 0;
+ i < nargs;
+ i++, ptr++, p_argv.v++)
{
+ unsigned int elt, elnum;
+
switch ((*ptr)->type)
{
case FFI_TYPE_FLOAT:
double_tmp = **p_argv.f;
- *next_arg.f = (float) double_tmp;
+ if (fparg_count < NUM_FPR_ARG_REGISTERS64 && i < nfixedargs)
+ *fpr_base.d++ = double_tmp;
+ else
+ *next_arg.f = (float) double_tmp;
if (++next_arg.ul == gpr_end.ul)
next_arg.ul = rest.ul;
- if (fparg_count < NUM_FPR_ARG_REGISTERS64)
- *fpr_base.d++ = double_tmp;
fparg_count++;
FFI_ASSERT (flags & FLAG_FP_ARGUMENTS);
break;
case FFI_TYPE_DOUBLE:
double_tmp = **p_argv.d;
- *next_arg.d = double_tmp;
+ if (fparg_count < NUM_FPR_ARG_REGISTERS64 && i < nfixedargs)
+ *fpr_base.d++ = double_tmp;
+ else
+ *next_arg.d = double_tmp;
if (++next_arg.ul == gpr_end.ul)
next_arg.ul = rest.ul;
- if (fparg_count < NUM_FPR_ARG_REGISTERS64)
- *fpr_base.d++ = double_tmp;
fparg_count++;
FFI_ASSERT (flags & FLAG_FP_ARGUMENTS);
break;
#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
case FFI_TYPE_LONGDOUBLE:
double_tmp = (*p_argv.d)[0];
- *next_arg.d = double_tmp;
+ if (fparg_count < NUM_FPR_ARG_REGISTERS64 && i < nfixedargs)
+ *fpr_base.d++ = double_tmp;
+ else
+ *next_arg.d = double_tmp;
if (++next_arg.ul == gpr_end.ul)
next_arg.ul = rest.ul;
- if (fparg_count < NUM_FPR_ARG_REGISTERS64)
- *fpr_base.d++ = double_tmp;
fparg_count++;
double_tmp = (*p_argv.d)[1];
- *next_arg.d = double_tmp;
+ if (fparg_count < NUM_FPR_ARG_REGISTERS64 && i < nfixedargs)
+ *fpr_base.d++ = double_tmp;
+ else
+ *next_arg.d = double_tmp;
if (++next_arg.ul == gpr_end.ul)
next_arg.ul = rest.ul;
- if (fparg_count < NUM_FPR_ARG_REGISTERS64)
- *fpr_base.d++ = double_tmp;
fparg_count++;
FFI_ASSERT (__LDBL_MANT_DIG__ == 106);
FFI_ASSERT (flags & FLAG_FP_ARGUMENTS);
break;
#endif
case FFI_TYPE_STRUCT:
- words = ((*ptr)->size + 7) / 8;
- if (next_arg.ul >= gpr_base.ul && next_arg.ul + words > gpr_end.ul)
+#ifdef __STRUCT_PARM_ALIGN__
+ align = (*ptr)->alignment;
+ if (align > __STRUCT_PARM_ALIGN__)
+ align = __STRUCT_PARM_ALIGN__;
+ if (align > 1)
+ next_arg.p = ALIGN (next_arg.p, align);
+#endif
+ elt = 0;
+#if _CALL_ELF == 2
+ elt = discover_homogeneous_aggregate (*ptr, &elnum);
+#endif
+ if (elt)
{
- size_t first = gpr_end.c - next_arg.c;
- memcpy (next_arg.c, *p_argv.c, first);
- memcpy (rest.c, *p_argv.c + first, (*ptr)->size - first);
- next_arg.c = rest.c + words * 8 - first;
+ union {
+ void *v;
+ float *f;
+ double *d;
+ } arg;
+
+ arg.v = *p_argv.v;
+ if (elt == FFI_TYPE_FLOAT)
+ {
+ do
+ {
+ double_tmp = *arg.f++;
+ if (fparg_count < NUM_FPR_ARG_REGISTERS64
+ && i < nfixedargs)
+ *fpr_base.d++ = double_tmp;
+ else
+ *next_arg.f = (float) double_tmp;
+ if (++next_arg.f == gpr_end.f)
+ next_arg.f = rest.f;
+ fparg_count++;
+ }
+ while (--elnum != 0);
+ if ((next_arg.p & 3) != 0)
+ {
+ if (++next_arg.f == gpr_end.f)
+ next_arg.f = rest.f;
+ }
+ }
+ else
+ do
+ {
+ double_tmp = *arg.d++;
+ if (fparg_count < NUM_FPR_ARG_REGISTERS64 && i < nfixedargs)
+ *fpr_base.d++ = double_tmp;
+ else
+ *next_arg.d = double_tmp;
+ if (++next_arg.d == gpr_end.d)
+ next_arg.d = rest.d;
+ fparg_count++;
+ }
+ while (--elnum != 0);
}
else
{
- char *where = next_arg.c;
+ words = ((*ptr)->size + 7) / 8;
+ if (next_arg.ul >= gpr_base.ul && next_arg.ul + words > gpr_end.ul)
+ {
+ size_t first = gpr_end.c - next_arg.c;
+ memcpy (next_arg.c, *p_argv.c, first);
+ memcpy (rest.c, *p_argv.c + first, (*ptr)->size - first);
+ next_arg.c = rest.c + words * 8 - first;
+ }
+ else
+ {
+ char *where = next_arg.c;
- /* Structures with size less than eight bytes are passed
- left-padded. */
- if ((*ptr)->size < 8)
- where += 8 - (*ptr)->size;
-
- memcpy (where, *p_argv.c, (*ptr)->size);
- next_arg.ul += words;
- if (next_arg.ul == gpr_end.ul)
- next_arg.ul = rest.ul;
+#ifndef __LITTLE_ENDIAN__
+ /* Structures with size less than eight bytes are passed
+ left-padded. */
+ if ((*ptr)->size < 8)
+ where += 8 - (*ptr)->size;
+#endif
+ memcpy (where, *p_argv.c, (*ptr)->size);
+ next_arg.ul += words;
+ if (next_arg.ul == gpr_end.ul)
+ next_arg.ul = rest.ul;
+ }
}
break;
case FFI_TYPE_UINT8:
gprvalue = **p_argv.uc;
goto putgpr;
case FFI_TYPE_SINT8:
gprvalue = **p_argv.sc;
@@ -586,53 +712,55 @@ ffi_prep_args64 (extended_cif *ecif, uns
FFI_ASSERT (flags & FLAG_4_GPR_ARGUMENTS
|| (next_arg.ul >= gpr_base.ul
&& next_arg.ul <= gpr_base.ul + 4));
}
/* Perform machine dependent cif processing */
-ffi_status
-ffi_prep_cif_machdep (ffi_cif *cif)
+static ffi_status
+ffi_prep_cif_machdep_core (ffi_cif *cif)
{
/* All this is for the SYSV and LINUX64 ABI. */
- int i;
ffi_type **ptr;
unsigned bytes;
- int fparg_count = 0, intarg_count = 0;
- unsigned flags = 0;
+ unsigned i, fparg_count = 0, intarg_count = 0;
+ unsigned flags = cif->flags;
unsigned struct_copy_size = 0;
unsigned type = cif->rtype->type;
unsigned size = cif->rtype->size;
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- NUM_FPR_ARG_REGISTERS = 0;
-
+ /* The machine-independent calculation of cif->bytes doesn't work
+ for us. Redo the calculation. */
if (cif->abi != FFI_LINUX64)
{
- /* All the machine-independent calculation of cif->bytes will be wrong.
- Redo the calculation for SYSV. */
-
/* Space for the frame pointer, callee's LR, and the asm's temp regs. */
bytes = (2 + ASM_NEEDS_REGISTERS) * sizeof (int);
/* Space for the GPR registers. */
bytes += NUM_GPR_ARG_REGISTERS * sizeof (int);
}
else
{
/* 64-bit ABI. */
+#if _CALL_ELF == 2
+ /* Space for backchain, CR, LR, TOC and the asm's temp regs. */
+ bytes = (4 + ASM_NEEDS_REGISTERS64) * sizeof (long);
+ /* Space for the general registers. */
+ bytes += NUM_GPR_ARG_REGISTERS64 * sizeof (long);
+#else
/* Space for backchain, CR, LR, cc/ld doubleword, TOC and the asm's temp
regs. */
bytes = (6 + ASM_NEEDS_REGISTERS64) * sizeof (long);
/* Space for the mandatory parm save area and general registers. */
bytes += 2 * NUM_GPR_ARG_REGISTERS64 * sizeof (long);
+#endif
}
/* Return value handling. The rules for SYSV are as follows:
- 32-bit (or less) integer values are returned in gpr3;
- Structures of size <= 4 bytes also returned in gpr3;
- 64-bit integer values and structures between 5 and 8 bytes are returned
in gpr3 and gpr4;
- Single/double FP values are returned in fpr1;
@@ -641,71 +769,93 @@ ffi_prep_cif_machdep (ffi_cif *cif)
- long doubles (if not equivalent to double) are returned in
fpr1,fpr2 for Linux and as for large structs for SysV.
For LINUX64:
- integer values in gpr3;
- Structures/Unions by reference;
- Single/double FP values in fpr1, long double in fpr1,fpr2.
- soft-float float/doubles are treated as UINT32/UINT64 respectivley.
- soft-float long doubles are returned in gpr3-gpr6. */
+ /* First translate for softfloat/nonlinux */
+ if (cif->abi == FFI_LINUX_SOFT_FLOAT)
+ {
+ if (type == FFI_TYPE_FLOAT)
+ type = FFI_TYPE_UINT32;
+ if (type == FFI_TYPE_DOUBLE)
+ type = FFI_TYPE_UINT64;
+ if (type == FFI_TYPE_LONGDOUBLE)
+ type = FFI_TYPE_UINT128;
+ }
+ else if (cif->abi != FFI_LINUX
+ && cif->abi != FFI_LINUX64)
+ {
+#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
+ if (type == FFI_TYPE_LONGDOUBLE)
+ type = FFI_TYPE_STRUCT;
+#endif
+ }
+
switch (type)
{
+#ifndef __NO_FPRS__
#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
case FFI_TYPE_LONGDOUBLE:
- if (cif->abi != FFI_LINUX && cif->abi != FFI_LINUX64
- && cif->abi != FFI_LINUX_SOFT_FLOAT)
- goto byref;
flags |= FLAG_RETURNS_128BITS;
/* Fall through. */
#endif
case FFI_TYPE_DOUBLE:
flags |= FLAG_RETURNS_64BITS;
/* Fall through. */
case FFI_TYPE_FLOAT:
- /* With FFI_LINUX_SOFT_FLOAT no fp registers are used. */
- if (cif->abi != FFI_LINUX_SOFT_FLOAT)
- flags |= FLAG_RETURNS_FP;
+ flags |= FLAG_RETURNS_FP;
break;
+#endif
+ case FFI_TYPE_UINT128:
+ flags |= FLAG_RETURNS_128BITS;
+ /* Fall through. */
case FFI_TYPE_UINT64:
case FFI_TYPE_SINT64:
flags |= FLAG_RETURNS_64BITS;
break;
case FFI_TYPE_STRUCT:
- if (cif->abi == FFI_SYSV)
+ /*
+ * The final SYSV ABI says that structures smaller or equal 8 bytes
+ * are returned in r3/r4. The FFI_GCC_SYSV ABI instead returns them
+ * in memory.
+ *
+ * NOTE: The assembly code can safely assume that it just needs to
+ * store both r3 and r4 into a 8-byte word-aligned buffer, as
+ * we allocate a temporary buffer in ffi_call() if this flag is
+ * set.
+ */
+ if (cif->abi == FFI_SYSV && size <= 8)
{
- /* The final SYSV ABI says that structures smaller or equal 8 bytes
- are returned in r3/r4. The FFI_GCC_SYSV ABI instead returns them
- in memory. */
-
- /* Treat structs with size <= 8 bytes. */
- if (size <= 8)
+ flags |= FLAG_RETURNS_SMST;
+ break;
+ }
+#if _CALL_ELF == 2
+ if (cif->abi == FFI_LINUX64)
+ {
+ unsigned int elt, elnum;
+ elt = discover_homogeneous_aggregate (cif->rtype, &elnum);
+ if (elt)
+ {
+ if (elt == FFI_TYPE_DOUBLE)
+ flags |= FLAG_RETURNS_64BITS;
+ flags |= FLAG_RETURNS_FP | FLAG_RETURNS_SMST;
+ break;
+ }
+ if (size <= 16)
{
flags |= FLAG_RETURNS_SMST;
- /* These structs are returned in r3. We pack the type and the
- precalculated shift value (needed in the sysv.S) into flags.
- The same applies for the structs returned in r3/r4. */
- if (size <= 4)
- {
- flags |= FLAG_SYSV_SMST_R3;
- flags |= 8 * (4 - size) << 8;
- break;
- }
- /* These structs are returned in r3 and r4. See above. */
- if (size <= 8)
- {
- flags |= FLAG_SYSV_SMST_R3 | FLAG_SYSV_SMST_R4;
- flags |= 8 * (8 - size) << 8;
- break;
- }
+ break;
}
}
-#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
- byref:
#endif
intarg_count++;
flags |= FLAG_RETVAL_REFERENCE;
/* Fall through. */
case FFI_TYPE_VOID:
flags |= FLAG_RETURNS_NOTHING;
break;
@@ -717,218 +867,334 @@ ffi_prep_cif_machdep (ffi_cif *cif)
if (cif->abi != FFI_LINUX64)
/* The first NUM_GPR_ARG_REGISTERS words of integer arguments, and the
first NUM_FPR_ARG_REGISTERS fp arguments, go in registers; the rest
goes on the stack. Structures and long doubles (if not equivalent
to double) are passed as a pointer to a copy of the structure.
Stuff on the stack needs to keep proper alignment. */
for (ptr = cif->arg_types, i = cif->nargs; i > 0; i--, ptr++)
{
- switch ((*ptr)->type)
- {
+ unsigned short typenum = (*ptr)->type;
+
+ /* We may need to handle some values depending on ABI */
+ if (cif->abi == FFI_LINUX_SOFT_FLOAT) {
+ if (typenum == FFI_TYPE_FLOAT)
+ typenum = FFI_TYPE_UINT32;
+ if (typenum == FFI_TYPE_DOUBLE)
+ typenum = FFI_TYPE_UINT64;
+ if (typenum == FFI_TYPE_LONGDOUBLE)
+ typenum = FFI_TYPE_UINT128;
+ } else if (cif->abi != FFI_LINUX && cif->abi != FFI_LINUX64) {
+#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
+ if (typenum == FFI_TYPE_LONGDOUBLE)
+ typenum = FFI_TYPE_STRUCT;
+#endif
+ }
+
+ switch (typenum) {
+#ifndef __NO_FPRS__
case FFI_TYPE_FLOAT:
- /* With FFI_LINUX_SOFT_FLOAT floats are handled like UINT32. */
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- goto soft_float_cif;
fparg_count++;
/* floating singles are not 8-aligned on stack */
break;
#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
case FFI_TYPE_LONGDOUBLE:
- if (cif->abi != FFI_LINUX && cif->abi != FFI_LINUX_SOFT_FLOAT)
- goto do_struct;
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- {
- if (intarg_count >= NUM_GPR_ARG_REGISTERS - 3
- || intarg_count < NUM_GPR_ARG_REGISTERS)
- /* A long double in FFI_LINUX_SOFT_FLOAT can use only
- a set of four consecutive gprs. If we have not enough,
- we have to adjust the intarg_count value. */
- intarg_count += NUM_GPR_ARG_REGISTERS - intarg_count;
- intarg_count += 4;
- break;
- }
- else
- fparg_count++;
+ fparg_count++;
/* Fall thru */
#endif
case FFI_TYPE_DOUBLE:
- /* With FFI_LINUX_SOFT_FLOAT doubles are handled like UINT64. */
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- goto soft_double_cif;
fparg_count++;
/* If this FP arg is going on the stack, it must be
8-byte-aligned. */
if (fparg_count > NUM_FPR_ARG_REGISTERS
&& intarg_count >= NUM_GPR_ARG_REGISTERS
&& intarg_count % 2 != 0)
intarg_count++;
break;
+#endif
+ case FFI_TYPE_UINT128:
+ /*
+ * A long double in FFI_LINUX_SOFT_FLOAT can use only a set
+ * of four consecutive gprs. If we do not have enough, we
+ * have to adjust the intarg_count value.
+ */
+ if (intarg_count >= NUM_GPR_ARG_REGISTERS - 3
+ && intarg_count < NUM_GPR_ARG_REGISTERS)
+ intarg_count = NUM_GPR_ARG_REGISTERS;
+ intarg_count += 4;
+ break;
case FFI_TYPE_UINT64:
case FFI_TYPE_SINT64:
- soft_double_cif:
/* 'long long' arguments are passed as two words, but
either both words must fit in registers or both go
on the stack. If they go on the stack, they must
be 8-byte-aligned.
Also, only certain register pairs can be used for
passing long long int -- specifically (r3,r4), (r5,r6),
(r7,r8), (r9,r10).
*/
if (intarg_count == NUM_GPR_ARG_REGISTERS-1
|| intarg_count % 2 != 0)
intarg_count++;
intarg_count += 2;
break;
case FFI_TYPE_STRUCT:
-#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
- do_struct:
-#endif
/* We must allocate space for a copy of these to enforce
pass-by-value. Pad the space up to a multiple of 16
bytes (the maximum alignment required for anything under
the SYSV ABI). */
struct_copy_size += ((*ptr)->size + 15) & ~0xF;
/* Fall through (allocate space for the pointer). */
- default:
- soft_float_cif:
+ case FFI_TYPE_POINTER:
+ case FFI_TYPE_INT:
+ case FFI_TYPE_UINT32:
+ case FFI_TYPE_SINT32:
+ case FFI_TYPE_UINT16:
+ case FFI_TYPE_SINT16:
+ case FFI_TYPE_UINT8:
+ case FFI_TYPE_SINT8:
/* Everything else is passed as a 4-byte word in a GPR, either
the object itself or a pointer to it. */
intarg_count++;
break;
+ default:
+ FFI_ASSERT (0);
}
}
else
for (ptr = cif->arg_types, i = cif->nargs; i > 0; i--, ptr++)
{
+ unsigned int elt, elnum;
+#ifdef __STRUCT_PARM_ALIGN__
+ unsigned int align;
+#endif
+
switch ((*ptr)->type)
{
#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
case FFI_TYPE_LONGDOUBLE:
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- intarg_count += 4;
- else
- {
- fparg_count += 2;
- intarg_count += 2;
- }
+ fparg_count += 2;
+ intarg_count += 2;
+ if (fparg_count > NUM_FPR_ARG_REGISTERS64)
+ flags |= FLAG_ARG_NEEDS_PSAVE;
break;
#endif
case FFI_TYPE_FLOAT:
case FFI_TYPE_DOUBLE:
fparg_count++;
intarg_count++;
+ if (fparg_count > NUM_FPR_ARG_REGISTERS64)
+ flags |= FLAG_ARG_NEEDS_PSAVE;
break;
case FFI_TYPE_STRUCT:
+#ifdef __STRUCT_PARM_ALIGN__
+ align = (*ptr)->alignment;
+ if (align > __STRUCT_PARM_ALIGN__)
+ align = __STRUCT_PARM_ALIGN__;
+ align = align / 8;
+ if (align > 1)
+ intarg_count = ALIGN (intarg_count, align);
+#endif
intarg_count += ((*ptr)->size + 7) / 8;
+ elt = 0;
+#if _CALL_ELF == 2
+ elt = discover_homogeneous_aggregate (*ptr, &elnum);
+#endif
+ if (elt)
+ {
+ fparg_count += elnum;
+ if (fparg_count > NUM_FPR_ARG_REGISTERS64)
+ flags |= FLAG_ARG_NEEDS_PSAVE;
+ }
+ else
+ {
+ if (intarg_count > NUM_GPR_ARG_REGISTERS64)
+ flags |= FLAG_ARG_NEEDS_PSAVE;
+ }
break;
- default:
+ case FFI_TYPE_POINTER:
+ case FFI_TYPE_UINT64:
+ case FFI_TYPE_SINT64:
+ case FFI_TYPE_INT:
+ case FFI_TYPE_UINT32:
+ case FFI_TYPE_SINT32:
+ case FFI_TYPE_UINT16:
+ case FFI_TYPE_SINT16:
+ case FFI_TYPE_UINT8:
+ case FFI_TYPE_SINT8:
/* Everything else is passed as a 8-byte word in a GPR, either
the object itself or a pointer to it. */
intarg_count++;
+ if (intarg_count > NUM_GPR_ARG_REGISTERS64)
+ flags |= FLAG_ARG_NEEDS_PSAVE;
break;
+ default:
+ FFI_ASSERT (0);
}
}
+#ifndef __NO_FPRS__
if (fparg_count != 0)
flags |= FLAG_FP_ARGUMENTS;
+#endif
if (intarg_count > 4)
flags |= FLAG_4_GPR_ARGUMENTS;
if (struct_copy_size != 0)
flags |= FLAG_ARG_NEEDS_COPY;
if (cif->abi != FFI_LINUX64)
{
+#ifndef __NO_FPRS__
/* Space for the FPR registers, if needed. */
if (fparg_count != 0)
bytes += NUM_FPR_ARG_REGISTERS * sizeof (double);
+#endif
/* Stack space. */
if (intarg_count > NUM_GPR_ARG_REGISTERS)
bytes += (intarg_count - NUM_GPR_ARG_REGISTERS) * sizeof (int);
+#ifndef __NO_FPRS__
if (fparg_count > NUM_FPR_ARG_REGISTERS)
bytes += (fparg_count - NUM_FPR_ARG_REGISTERS) * sizeof (double);
+#endif
}
else
{
+#ifndef __NO_FPRS__
/* Space for the FPR registers, if needed. */
if (fparg_count != 0)
bytes += NUM_FPR_ARG_REGISTERS64 * sizeof (double);
+#endif
/* Stack space. */
+#if _CALL_ELF == 2
+ if ((flags & FLAG_ARG_NEEDS_PSAVE) != 0)
+ bytes += intarg_count * sizeof (long);
+#else
if (intarg_count > NUM_GPR_ARG_REGISTERS64)
bytes += (intarg_count - NUM_GPR_ARG_REGISTERS64) * sizeof (long);
+#endif
}
/* The stack space allocated needs to be a multiple of 16 bytes. */
bytes = (bytes + 15) & ~0xF;
/* Add in the space for the copied structures. */
bytes += struct_copy_size;
cif->flags = flags;
cif->bytes = bytes;
return FFI_OK;
}
+ffi_status
+ffi_prep_cif_machdep (ffi_cif *cif)
+{
+ cif->nfixedargs = cif->nargs;
+ return ffi_prep_cif_machdep_core (cif);
+}
+
+ffi_status
+ffi_prep_cif_machdep_var (ffi_cif *cif,
+ unsigned int nfixedargs,
+ unsigned int ntotalargs MAYBE_UNUSED)
+{
+ cif->nfixedargs = nfixedargs;
+#if _CALL_ELF == 2
+ if (cif->abi == FFI_LINUX64)
+ cif->flags |= FLAG_ARG_NEEDS_PSAVE;
+#endif
+ return ffi_prep_cif_machdep_core (cif);
+}
+
extern void ffi_call_SYSV(extended_cif *, unsigned, unsigned, unsigned *,
void (*fn)(void));
extern void FFI_HIDDEN ffi_call_LINUX64(extended_cif *, unsigned long,
unsigned long, unsigned long *,
void (*fn)(void));
void
ffi_call(ffi_cif *cif, void (*fn)(void), void *rvalue, void **avalue)
{
+ /*
+ * The final SYSV ABI says that structures smaller or equal 8 bytes
+ * are returned in r3/r4. The FFI_GCC_SYSV ABI instead returns them
+ * in memory.
+ *
+ * We bounce-buffer SYSV small struct return values so that sysv.S
+ * can write r3 and r4 to memory without worrying about struct size.
+ *
+ * For ELFv2 ABI, use a bounce buffer for homogeneous structs too,
+ * for similar reasons.
+ */
+ unsigned long smst_buffer[8];
extended_cif ecif;
ecif.cif = cif;
ecif.avalue = avalue;
- /* If the return value is a struct and we don't have a return */
- /* value address then we need to make one */
-
- if ((rvalue == NULL) && (cif->rtype->type == FFI_TYPE_STRUCT))
- {
- ecif.rvalue = alloca(cif->rtype->size);
- }
- else
- ecif.rvalue = rvalue;
-
+ ecif.rvalue = rvalue;
+ if ((cif->flags & FLAG_RETURNS_SMST) != 0)
+ ecif.rvalue = smst_buffer;
+ /* Ensure that we have a valid struct return value.
+ FIXME: Isn't this just papering over a user problem? */
+ else if (!rvalue && cif->rtype->type == FFI_TYPE_STRUCT)
+ ecif.rvalue = alloca (cif->rtype->size);
switch (cif->abi)
{
#ifndef POWERPC64
+# ifndef __NO_FPRS__
case FFI_SYSV:
case FFI_GCC_SYSV:
case FFI_LINUX:
+# endif
case FFI_LINUX_SOFT_FLOAT:
ffi_call_SYSV (&ecif, -cif->bytes, cif->flags, ecif.rvalue, fn);
break;
#else
case FFI_LINUX64:
ffi_call_LINUX64 (&ecif, -(long) cif->bytes, cif->flags, ecif.rvalue, fn);
break;
#endif
default:
FFI_ASSERT (0);
break;
}
+
+ /* Check for a bounce-buffered return value */
+ if (rvalue && ecif.rvalue == smst_buffer)
+ {
+ unsigned int rsize = cif->rtype->size;
+#ifndef __LITTLE_ENDIAN__
+ /* The SYSV ABI returns a structure of up to 4 bytes in size
+ left-padded in r3. */
+ if (cif->abi == FFI_SYSV && rsize <= 4)
+ memcpy (rvalue, (char *) smst_buffer + 4 - rsize, rsize);
+ /* The SYSV ABI returns a structure of up to 8 bytes in size
+ left-padded in r3/r4, and the ELFv2 ABI similarly returns a
+ structure of up to 8 bytes in size left-padded in r3. */
+ else if (rsize <= 8)
+ memcpy (rvalue, (char *) smst_buffer + 8 - rsize, rsize);
+ else
+#endif
+ memcpy (rvalue, smst_buffer, rsize);
+ }
}
-#ifndef POWERPC64
+#if !defined POWERPC64 || _CALL_ELF == 2
#define MIN_CACHE_LINE_SIZE 8
static void
flush_icache (char *wraddr, char *xaddr, int size)
{
int i;
for (i = 0; i < size; i += MIN_CACHE_LINE_SIZE)
__asm__ volatile ("icbi 0,%0;" "dcbf 0,%1;"
@@ -942,26 +1208,48 @@ flush_icache (char *wraddr, char *xaddr,
ffi_status
ffi_prep_closure_loc (ffi_closure *closure,
ffi_cif *cif,
void (*fun) (ffi_cif *, void *, void **, void *),
void *user_data,
void *codeloc)
{
#ifdef POWERPC64
+# if _CALL_ELF == 2
+ unsigned int *tramp = (unsigned int *) &closure->tramp[0];
+
+ if (cif->abi != FFI_LINUX64)
+ return FFI_BAD_ABI;
+
+ tramp[0] = 0xe96c0018; /* 0: ld 11,2f-0b(12) */
+ tramp[1] = 0xe98c0010; /* ld 12,1f-0b(12) */
+ tramp[2] = 0x7d8903a6; /* mtctr 12 */
+ tramp[3] = 0x4e800420; /* bctr */
+ /* 1: .quad function_addr */
+ /* 2: .quad context */
+ *(void **) &tramp[4] = (void *) ffi_closure_LINUX64;
+ *(void **) &tramp[6] = codeloc;
+ flush_icache ((char *)tramp, (char *)codeloc, FFI_TRAMPOLINE_SIZE);
+# else
void **tramp = (void **) &closure->tramp[0];
- FFI_ASSERT (cif->abi == FFI_LINUX64);
+ if (cif->abi != FFI_LINUX64)
+ return FFI_BAD_ABI;
/* Copy function address and TOC from ffi_closure_LINUX64. */
memcpy (tramp, (char *) ffi_closure_LINUX64, 16);
tramp[2] = codeloc;
+# endif
#else
unsigned int *tramp;
- FFI_ASSERT (cif->abi == FFI_GCC_SYSV || cif->abi == FFI_SYSV);
+ if (! (cif->abi == FFI_GCC_SYSV
+ || cif->abi == FFI_SYSV
+ || cif->abi == FFI_LINUX
+ || cif->abi == FFI_LINUX_SOFT_FLOAT))
+ return FFI_BAD_ABI;
tramp = (unsigned int *) &closure->tramp[0];
tramp[0] = 0x7c0802a6; /* mflr r0 */
tramp[1] = 0x4800000d; /* bl 10 <trampoline_initial+0x10> */
tramp[4] = 0x7d6802a6; /* mflr r11 */
tramp[5] = 0x7c0803a6; /* mtlr r0 */
tramp[6] = 0x800b0000; /* lwz r0,0(r11) */
tramp[7] = 0x816b0004; /* lwz r11,4(r11) */
@@ -1006,110 +1294,215 @@ ffi_closure_helper_SYSV (ffi_closure *cl
/* rvalue is the pointer to space for return value in closure assembly */
/* pgr is the pointer to where r3-r10 are stored in ffi_closure_SYSV */
/* pfr is the pointer to where f1-f8 are stored in ffi_closure_SYSV */
/* pst is the pointer to outgoing parameter stack in original caller */
void ** avalue;
ffi_type ** arg_types;
long i, avn;
- long nf; /* number of floating registers already used */
- long ng; /* number of general registers already used */
- ffi_cif * cif;
- double temp;
- unsigned size;
+#ifndef __NO_FPRS__
+ long nf = 0; /* number of floating registers already used */
+#endif
+ long ng = 0; /* number of general registers already used */
- cif = closure->cif;
+ ffi_cif *cif = closure->cif;
+ unsigned size = cif->rtype->size;
+ unsigned short rtypenum = cif->rtype->type;
+
avalue = alloca (cif->nargs * sizeof (void *));
- size = cif->rtype->size;
- nf = 0;
- ng = 0;
+ /* First translate for softfloat/nonlinux */
+ if (cif->abi == FFI_LINUX_SOFT_FLOAT) {
+ if (rtypenum == FFI_TYPE_FLOAT)
+ rtypenum = FFI_TYPE_UINT32;
+ if (rtypenum == FFI_TYPE_DOUBLE)
+ rtypenum = FFI_TYPE_UINT64;
+ if (rtypenum == FFI_TYPE_LONGDOUBLE)
+ rtypenum = FFI_TYPE_UINT128;
+ } else if (cif->abi != FFI_LINUX && cif->abi != FFI_LINUX64) {
+#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
+ if (rtypenum == FFI_TYPE_LONGDOUBLE)
+ rtypenum = FFI_TYPE_STRUCT;
+#endif
+ }
+
/* Copy the caller's structure return value address so that the closure
returns the data directly to the caller.
For FFI_SYSV the result is passed in r3/r4 if the struct size is less
or equal 8 bytes. */
-
- if ((cif->rtype->type == FFI_TYPE_STRUCT
- && !((cif->abi == FFI_SYSV) && (size <= 8)))
-#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
- || (cif->rtype->type == FFI_TYPE_LONGDOUBLE
- && cif->abi != FFI_LINUX && cif->abi != FFI_LINUX_SOFT_FLOAT)
-#endif
- )
- {
+ if (rtypenum == FFI_TYPE_STRUCT && ((cif->abi != FFI_SYSV) || (size > 8))) {
rvalue = (void *) *pgr;
ng++;
pgr++;
}
i = 0;
avn = cif->nargs;
arg_types = cif->arg_types;
/* Grab the addresses of the arguments from the stack frame. */
- while (i < avn)
- {
- switch (arg_types[i]->type)
- {
+ while (i < avn) {
+ unsigned short typenum = arg_types[i]->type;
+
+ /* We may need to handle some values depending on ABI */
+ if (cif->abi == FFI_LINUX_SOFT_FLOAT) {
+ if (typenum == FFI_TYPE_FLOAT)
+ typenum = FFI_TYPE_UINT32;
+ if (typenum == FFI_TYPE_DOUBLE)
+ typenum = FFI_TYPE_UINT64;
+ if (typenum == FFI_TYPE_LONGDOUBLE)
+ typenum = FFI_TYPE_UINT128;
+ } else if (cif->abi != FFI_LINUX && cif->abi != FFI_LINUX64) {
+#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
+ if (typenum == FFI_TYPE_LONGDOUBLE)
+ typenum = FFI_TYPE_STRUCT;
+#endif
+ }
+
+ switch (typenum) {
+#ifndef __NO_FPRS__
+ case FFI_TYPE_FLOAT:
+ /* unfortunately float values are stored as doubles
+ * in the ffi_closure_SYSV code (since we don't check
+ * the type in that routine).
+ */
+
+ /* there are 8 64bit floating point registers */
+
+ if (nf < 8)
+ {
+ double temp = pfr->d;
+ pfr->f = (float) temp;
+ avalue[i] = pfr;
+ nf++;
+ pfr++;
+ }
+ else
+ {
+ /* FIXME? here we are really changing the values
+ * stored in the original calling routines outgoing
+ * parameter stack. This is probably a really
+ * naughty thing to do but...
+ */
+ avalue[i] = pst;
+ pst += 1;
+ }
+ break;
+
+ case FFI_TYPE_DOUBLE:
+ /* On the outgoing stack all values are aligned to 8 */
+ /* there are 8 64bit floating point registers */
+
+ if (nf < 8)
+ {
+ avalue[i] = pfr;
+ nf++;
+ pfr++;
+ }
+ else
+ {
+ if (((long) pst) & 4)
+ pst++;
+ avalue[i] = pst;
+ pst += 2;
+ }
+ break;
+
+#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
+ case FFI_TYPE_LONGDOUBLE:
+ if (nf < 7)
+ {
+ avalue[i] = pfr;
+ pfr += 2;
+ nf += 2;
+ }
+ else
+ {
+ if (((long) pst) & 4)
+ pst++;
+ avalue[i] = pst;
+ pst += 4;
+ nf = 8;
+ }
+ break;
+#endif
+#endif /* have FPRS */
+
+ case FFI_TYPE_UINT128:
+ /*
+ * Test if for the whole long double, 4 gprs are available.
+ * otherwise the stuff ends up on the stack.
+ */
+ if (ng < 5) {
+ avalue[i] = pgr;
+ pgr += 4;
+ ng += 4;
+ } else {
+ avalue[i] = pst;
+ pst += 4;
+ ng = 8+4;
+ }
+ break;
+
case FFI_TYPE_SINT8:
case FFI_TYPE_UINT8:
+#ifndef __LITTLE_ENDIAN__
/* there are 8 gpr registers used to pass values */
if (ng < 8)
{
avalue[i] = (char *) pgr + 3;
ng++;
pgr++;
}
else
{
avalue[i] = (char *) pst + 3;
pst++;
}
break;
+#endif
case FFI_TYPE_SINT16:
case FFI_TYPE_UINT16:
+#ifndef __LITTLE_ENDIAN__
/* there are 8 gpr registers used to pass values */
if (ng < 8)
{
avalue[i] = (char *) pgr + 2;
ng++;
pgr++;
}
else
{
avalue[i] = (char *) pst + 2;
pst++;
}
break;
+#endif
case FFI_TYPE_SINT32:
case FFI_TYPE_UINT32:
case FFI_TYPE_POINTER:
- soft_float_closure:
/* there are 8 gpr registers used to pass values */
if (ng < 8)
{
avalue[i] = pgr;
ng++;
pgr++;
}
else
{
avalue[i] = pst;
pst++;
}
break;
case FFI_TYPE_STRUCT:
-#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
- do_struct:
-#endif
/* Structs are passed by reference. The address will appear in a
gpr if it is one of the first 8 arguments. */
if (ng < 8)
{
avalue[i] = (void *) *pgr;
ng++;
pgr++;
}
@@ -1117,17 +1510,16 @@ ffi_closure_helper_SYSV (ffi_closure *cl
{
avalue[i] = (void *) *pst;
pst++;
}
break;
case FFI_TYPE_SINT64:
case FFI_TYPE_UINT64:
- soft_double_closure:
/* passing long long ints are complex, they must
* be passed in suitable register pairs such as
* (r3,r4) or (r5,r6) or (r6,r7), or (r7,r8) or (r9,r10)
* and if the entire pair aren't available then the outgoing
* parameter stack is used for both but an alignment of 8
* must will be kept. So we must either look in pgr
* or pst to find the correct address for this type
* of parameter.
@@ -1149,277 +1541,239 @@ ffi_closure_helper_SYSV (ffi_closure *cl
if (((long) pst) & 4)
pst++;
avalue[i] = pst;
pst += 2;
ng = 8;
}
break;
- case FFI_TYPE_FLOAT:
- /* With FFI_LINUX_SOFT_FLOAT floats are handled like UINT32. */
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- goto soft_float_closure;
- /* unfortunately float values are stored as doubles
- * in the ffi_closure_SYSV code (since we don't check
- * the type in that routine).
- */
-
- /* there are 8 64bit floating point registers */
-
- if (nf < 8)
- {
- temp = pfr->d;
- pfr->f = (float) temp;
- avalue[i] = pfr;
- nf++;
- pfr++;
- }
- else
- {
- /* FIXME? here we are really changing the values
- * stored in the original calling routines outgoing
- * parameter stack. This is probably a really
- * naughty thing to do but...
- */
- avalue[i] = pst;
- pst += 1;
- }
- break;
-
- case FFI_TYPE_DOUBLE:
- /* With FFI_LINUX_SOFT_FLOAT doubles are handled like UINT64. */
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- goto soft_double_closure;
- /* On the outgoing stack all values are aligned to 8 */
- /* there are 8 64bit floating point registers */
-
- if (nf < 8)
- {
- avalue[i] = pfr;
- nf++;
- pfr++;
- }
- else
- {
- if (((long) pst) & 4)
- pst++;
- avalue[i] = pst;
- pst += 2;
- }
- break;
-
-#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
- case FFI_TYPE_LONGDOUBLE:
- if (cif->abi != FFI_LINUX && cif->abi != FFI_LINUX_SOFT_FLOAT)
- goto do_struct;
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- { /* Test if for the whole long double, 4 gprs are available.
- otherwise the stuff ends up on the stack. */
- if (ng < 5)
- {
- avalue[i] = pgr;
- pgr += 4;
- ng += 4;
- }
- else
- {
- avalue[i] = pst;
- pst += 4;
- ng = 8;
- }
- break;
- }
- if (nf < 7)
- {
- avalue[i] = pfr;
- pfr += 2;
- nf += 2;
- }
- else
- {
- if (((long) pst) & 4)
- pst++;
- avalue[i] = pst;
- pst += 4;
- nf = 8;
- }
- break;
-#endif
-
default:
- FFI_ASSERT (0);
+ FFI_ASSERT (0);
}
i++;
}
(closure->fun) (cif, rvalue, avalue, closure->user_data);
/* Tell ffi_closure_SYSV how to perform return type promotions.
Because the FFI_SYSV ABI returns the structures <= 8 bytes in r3/r4
we have to tell ffi_closure_SYSV how to treat them. We combine the base
type FFI_SYSV_TYPE_SMALL_STRUCT - 1 with the size of the struct.
So a one byte struct gets the return type 16. Return type 1 to 15 are
already used and we never have a struct with size zero. That is the reason
for the subtraction of 1. See the comment in ffitarget.h about ordering.
*/
- if (cif->abi == FFI_SYSV && cif->rtype->type == FFI_TYPE_STRUCT
- && size <= 8)
+ if (cif->abi == FFI_SYSV && rtypenum == FFI_TYPE_STRUCT && size <= 8)
return (FFI_SYSV_TYPE_SMALL_STRUCT - 1) + size;
-#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
- else if (cif->rtype->type == FFI_TYPE_LONGDOUBLE
- && cif->abi != FFI_LINUX && cif->abi != FFI_LINUX_SOFT_FLOAT)
- return FFI_TYPE_STRUCT;
-#endif
- /* With FFI_LINUX_SOFT_FLOAT floats and doubles are handled like UINT32
- respectivley UINT64. */
- if (cif->abi == FFI_LINUX_SOFT_FLOAT)
- {
- switch (cif->rtype->type)
- {
- case FFI_TYPE_FLOAT:
- return FFI_TYPE_UINT32;
- break;
- case FFI_TYPE_DOUBLE:
- return FFI_TYPE_UINT64;
- break;
-#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
- case FFI_TYPE_LONGDOUBLE:
- return FFI_TYPE_UINT128;
- break;
-#endif
- default:
- return cif->rtype->type;
- }
- }
- else
- {
- return cif->rtype->type;
- }
+ return rtypenum;
}
int FFI_HIDDEN ffi_closure_helper_LINUX64 (ffi_closure *, void *,
unsigned long *, ffi_dblfl *);
int FFI_HIDDEN
ffi_closure_helper_LINUX64 (ffi_closure *closure, void *rvalue,
unsigned long *pst, ffi_dblfl *pfr)
{
/* rvalue is the pointer to space for return value in closure assembly */
/* pst is the pointer to parameter save area
(r3-r10 are stored into its first 8 slots by ffi_closure_LINUX64) */
/* pfr is the pointer to where f1-f13 are stored in ffi_closure_LINUX64 */
void **avalue;
ffi_type **arg_types;
- long i, avn;
+ unsigned long i, avn, nfixedargs;
ffi_cif *cif;
ffi_dblfl *end_pfr = pfr + NUM_FPR_ARG_REGISTERS64;
+#ifdef __STRUCT_PARM_ALIGN__
+ unsigned long align;
+#endif
cif = closure->cif;
avalue = alloca (cif->nargs * sizeof (void *));
- /* Copy the caller's structure return value address so that the closure
- returns the data directly to the caller. */
- if (cif->rtype->type == FFI_TYPE_STRUCT)
+ /* Copy the caller's structure return value address so that the
+ closure returns the data directly to the caller. */
+ if (cif->rtype->type == FFI_TYPE_STRUCT
+ && (cif->flags & FLAG_RETURNS_SMST) == 0)
{
rvalue = (void *) *pst;
pst++;
}
i = 0;
avn = cif->nargs;
+ nfixedargs = cif->nfixedargs;
arg_types = cif->arg_types;
/* Grab the addresses of the arguments from the stack frame. */
while (i < avn)
{
+ unsigned int elt, elnum;
+
switch (arg_types[i]->type)
{
case FFI_TYPE_SINT8:
case FFI_TYPE_UINT8:
+#ifndef __LITTLE_ENDIAN__
avalue[i] = (char *) pst + 7;
pst++;
break;
+#endif
case FFI_TYPE_SINT16:
case FFI_TYPE_UINT16:
+#ifndef __LITTLE_ENDIAN__
avalue[i] = (char *) pst + 6;
pst++;
break;
+#endif
case FFI_TYPE_SINT32:
case FFI_TYPE_UINT32:
+#ifndef __LITTLE_ENDIAN__
avalue[i] = (char *) pst + 4;
pst++;
break;
+#endif
case FFI_TYPE_SINT64:
case FFI_TYPE_UINT64:
case FFI_TYPE_POINTER:
avalue[i] = pst;
pst++;
break;
case FFI_TYPE_STRUCT:
- /* Structures with size less than eight bytes are passed
- left-padded. */
- if (arg_types[i]->size < 8)
- avalue[i] = (char *) pst + 8 - arg_types[i]->size;
+#ifdef __STRUCT_PARM_ALIGN__
+ align = arg_types[i]->alignment;
+ if (align > __STRUCT_PARM_ALIGN__)
+ align = __STRUCT_PARM_ALIGN__;
+ if (align > 1)
+ pst = (unsigned long *) ALIGN ((size_t) pst, align);
+#endif
+ elt = 0;
+#if _CALL_ELF == 2
+ elt = discover_homogeneous_aggregate (arg_types[i], &elnum);
+#endif
+ if (elt)
+ {
+ union {
+ void *v;
+ unsigned long *ul;
+ float *f;
+ double *d;
+ size_t p;
+ } to, from;
+
+ /* Repackage the aggregate from its parts. The
+ aggregate size is not greater than the space taken by
+ the registers so store back to the register/parameter
+ save arrays. */
+ if (pfr + elnum <= end_pfr)
+ to.v = pfr;
+ else
+ to.v = pst;
+
+ avalue[i] = to.v;
+ from.ul = pst;
+ if (elt == FFI_TYPE_FLOAT)
+ {
+ do
+ {
+ if (pfr < end_pfr && i < nfixedargs)
+ {
+ *to.f = (float) pfr->d;
+ pfr++;
+ }
+ else
+ *to.f = *from.f;
+ to.f++;
+ from.f++;
+ }
+ while (--elnum != 0);
+ }
+ else
+ {
+ do
+ {
+ if (pfr < end_pfr && i < nfixedargs)
+ {
+ *to.d = pfr->d;
+ pfr++;
+ }
+ else
+ *to.d = *from.d;
+ to.d++;
+ from.d++;
+ }
+ while (--elnum != 0);
+ }
+ }
else
- avalue[i] = pst;
+ {
+#ifndef __LITTLE_ENDIAN__
+ /* Structures with size less than eight bytes are passed
+ left-padded. */
+ if (arg_types[i]->size < 8)
+ avalue[i] = (char *) pst + 8 - arg_types[i]->size;
+ else
+#endif
+ avalue[i] = pst;
+ }
pst += (arg_types[i]->size + 7) / 8;
break;
case FFI_TYPE_FLOAT:
/* unfortunately float values are stored as doubles
* in the ffi_closure_LINUX64 code (since we don't check
* the type in that routine).
*/
/* there are 13 64bit floating point registers */
- if (pfr < end_pfr)
+ if (pfr < end_pfr && i < nfixedargs)
{
double temp = pfr->d;
pfr->f = (float) temp;
avalue[i] = pfr;
pfr++;
}
else
avalue[i] = pst;
pst++;
break;
case FFI_TYPE_DOUBLE:
/* On the outgoing stack all values are aligned to 8 */
/* there are 13 64bit floating point registers */
- if (pfr < end_pfr)
+ if (pfr < end_pfr && i < nfixedargs)
{
avalue[i] = pfr;
pfr++;
}
else
avalue[i] = pst;
pst++;
break;
#if FFI_TYPE_LONGDOUBLE != FFI_TYPE_DOUBLE
case FFI_TYPE_LONGDOUBLE:
- if (pfr + 1 < end_pfr)
+ if (pfr + 1 < end_pfr && i + 1 < nfixedargs)
{
avalue[i] = pfr;
pfr += 2;
}
else
{
- if (pfr < end_pfr)
+ if (pfr < end_pfr && i < nfixedargs)
{
/* Passed partly in f13 and partly on the stack.
Move it all to the stack. */
*pst = *(unsigned long *) pfr;
pfr++;
}
avalue[i] = pst;
}
@@ -1433,10 +1787,19 @@ ffi_closure_helper_LINUX64 (ffi_closure
i++;
}
(closure->fun) (cif, rvalue, avalue, closure->user_data);
/* Tell ffi_closure_LINUX64 how to perform return type promotions. */
+ if ((cif->flags & FLAG_RETURNS_SMST) != 0)
+ {
+ if ((cif->flags & FLAG_RETURNS_FP) == 0)
+ return FFI_V2_TYPE_SMALL_STRUCT + cif->rtype->size - 1;
+ else if ((cif->flags & FLAG_RETURNS_64BITS) != 0)
+ return FFI_V2_TYPE_DOUBLE_HOMOG;
+ else
+ return FFI_V2_TYPE_FLOAT_HOMOG;
+ }
return cif->rtype->type;
}
diff --git a/js/src/ctypes/libffi/src/powerpc/ffitarget.h b/js/src/ctypes/libffi/src/powerpc/ffitarget.h
--- a/js/src/ctypes/libffi/src/powerpc/ffitarget.h
+++ b/js/src/ctypes/libffi/src/powerpc/ffitarget.h
@@ -1,11 +1,13 @@
/* -----------------------------------------------------------------*-C-*-
- ffitarget.h - Copyright (c) 1996-2003 Red Hat, Inc.
- Copyright (C) 2007, 2008 Free Software Foundation, Inc
+ ffitarget.h - Copyright (c) 2012 Anthony Green
+ Copyright (C) 2007, 2008, 2010 Free Software Foundation, Inc
+ Copyright (c) 1996-2003 Red Hat, Inc.
+
Target configuration macros for PowerPC.
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
@@ -23,16 +25,20 @@
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
DEALINGS IN THE SOFTWARE.
----------------------------------------------------------------------- */
#ifndef LIBFFI_TARGET_H
#define LIBFFI_TARGET_H
+#ifndef LIBFFI_H
+#error "Please do not include ffitarget.h directly into your source. Use ffi.h instead."
+#endif
+
/* ---- System specific configurations ----------------------------------- */
#if defined (POWERPC) && defined (__powerpc64__) /* linux64 */
#ifndef POWERPC64
#define POWERPC64
#endif
#elif defined (POWERPC_DARWIN) && defined (__ppc64__) /* Darwin */
#ifndef POWERPC64
@@ -52,28 +58,24 @@ typedef enum ffi_abi {
FFI_FIRST_ABI = 0,
#ifdef POWERPC
FFI_SYSV,
FFI_GCC_SYSV,
FFI_LINUX64,
FFI_LINUX,
FFI_LINUX_SOFT_FLOAT,
-# ifdef POWERPC64
+# if defined(POWERPC64)
FFI_DEFAULT_ABI = FFI_LINUX64,
+# elif defined(__NO_FPRS__)
+ FFI_DEFAULT_ABI = FFI_LINUX_SOFT_FLOAT,
+# elif (__LDBL_MANT_DIG__ == 106)
+ FFI_DEFAULT_ABI = FFI_LINUX,
# else
-# if (!defined(__NO_FPRS__) && (__LDBL_MANT_DIG__ == 106))
- FFI_DEFAULT_ABI = FFI_LINUX,
-# else
-# ifdef __NO_FPRS__
- FFI_DEFAULT_ABI = FFI_LINUX_SOFT_FLOAT,
-# else
FFI_DEFAULT_ABI = FFI_GCC_SYSV,
-# endif
-# endif
# endif
#endif
#ifdef POWERPC_AIX
FFI_AIX,
FFI_DARWIN,
FFI_DEFAULT_ABI = FFI_AIX,
#endif
@@ -96,32 +98,45 @@ typedef enum ffi_abi {
FFI_LAST_ABI
} ffi_abi;
#endif
/* ---- Definitions for closures ----------------------------------------- */
#define FFI_CLOSURES 1
#define FFI_NATIVE_RAW_API 0
+#if defined (POWERPC) || defined (POWERPC_FREEBSD)
+# define FFI_TARGET_SPECIFIC_VARIADIC 1
+# define FFI_EXTRA_CIF_FIELDS unsigned nfixedargs
+#endif
/* For additional types like the below, take care about the order in
ppc_closures.S. They must follow after the FFI_TYPE_LAST. */
/* Needed for soft-float long-double-128 support. */
#define FFI_TYPE_UINT128 (FFI_TYPE_LAST + 1)
/* Needed for FFI_SYSV small structure returns.
We use two flag bits, (FLAG_SYSV_SMST_R3, FLAG_SYSV_SMST_R4) which are
defined in ffi.c, to determine the exact return type and its size. */
#define FFI_SYSV_TYPE_SMALL_STRUCT (FFI_TYPE_LAST + 2)
-#if defined(POWERPC64) || defined(POWERPC_AIX)
-#define FFI_TRAMPOLINE_SIZE 24
-#else /* POWERPC || POWERPC_AIX */
-#define FFI_TRAMPOLINE_SIZE 40
+/* Used by ELFv2 for homogenous structure returns. */
+#define FFI_V2_TYPE_FLOAT_HOMOG (FFI_TYPE_LAST + 1)
+#define FFI_V2_TYPE_DOUBLE_HOMOG (FFI_TYPE_LAST + 2)
+#define FFI_V2_TYPE_SMALL_STRUCT (FFI_TYPE_LAST + 3)
+
+#if _CALL_ELF == 2
+# define FFI_TRAMPOLINE_SIZE 32
+#else
+# if defined(POWERPC64) || defined(POWERPC_AIX)
+# define FFI_TRAMPOLINE_SIZE 24
+# else /* POWERPC || POWERPC_AIX */
+# define FFI_TRAMPOLINE_SIZE 40
+# endif
#endif
#ifndef LIBFFI_ASM
#if defined(POWERPC_DARWIN) || defined(POWERPC_AIX)
struct ffi_aix_trampoline_struct {
void * code_pointer; /* Pointer to ffi_closure_ASM */
void * toc; /* TOC */
void * static_chain; /* Pointer to closure */
diff --git a/js/src/ctypes/libffi/src/powerpc/linux64.S b/js/src/ctypes/libffi/src/powerpc/linux64.S
--- a/js/src/ctypes/libffi/src/powerpc/linux64.S
+++ b/js/src/ctypes/libffi/src/powerpc/linux64.S
@@ -25,56 +25,86 @@
DEALINGS IN THE SOFTWARE.
----------------------------------------------------------------------- */
#define LIBFFI_ASM
#include <fficonfig.h>
#include <ffi.h>
#ifdef __powerpc64__
- .hidden ffi_call_LINUX64, .ffi_call_LINUX64
- .globl ffi_call_LINUX64, .ffi_call_LINUX64
+ .hidden ffi_call_LINUX64
+ .globl ffi_call_LINUX64
+# if _CALL_ELF == 2
+ .text
+ffi_call_LINUX64:
+ addis %r2, %r12, .TOC.-ffi_call_LINUX64@ha
+ addi %r2, %r2, .TOC.-ffi_call_LINUX64@l
+ .localentry ffi_call_LINUX64, . - ffi_call_LINUX64
+# else
.section ".opd","aw"
.align 3
ffi_call_LINUX64:
+# ifdef _CALL_LINUX
+ .quad .L.ffi_call_LINUX64,.TOC.@tocbase,0
+ .type ffi_call_LINUX64,@function
+ .text
+.L.ffi_call_LINUX64:
+# else
+ .hidden .ffi_call_LINUX64
+ .globl .ffi_call_LINUX64
.quad .ffi_call_LINUX64,.TOC.@tocbase,0
.size ffi_call_LINUX64,24
.type .ffi_call_LINUX64,@function
.text
.ffi_call_LINUX64:
+# endif
+# endif
.LFB1:
mflr %r0
std %r28, -32(%r1)
std %r29, -24(%r1)
std %r30, -16(%r1)
std %r31, -8(%r1)
std %r0, 16(%r1)
mr %r28, %r1 /* our AP. */
.LCFI0:
stdux %r1, %r1, %r4
mr %r31, %r5 /* flags, */
mr %r30, %r6 /* rvalue, */
mr %r29, %r7 /* function address. */
+/* Save toc pointer, not for the ffi_prep_args64 call, but for the later
+ bctrl function call. */
+# if _CALL_ELF == 2
+ std %r2, 24(%r1)
+# else
std %r2, 40(%r1)
+# endif
/* Call ffi_prep_args64. */
mr %r4, %r1
+# if defined _CALL_LINUX || _CALL_ELF == 2
+ bl ffi_prep_args64
+# else
bl .ffi_prep_args64
+# endif
- ld %r0, 0(%r29)
+# if _CALL_ELF == 2
+ mr %r12, %r29
+# else
+ ld %r12, 0(%r29)
ld %r2, 8(%r29)
ld %r11, 16(%r29)
-
+# endif
/* Now do the call. */
/* Set up cr1 with bits 4-7 of the flags. */
mtcrf 0x40, %r31
/* Get the address to call into CTR. */
- mtctr %r0
+ mtctr %r12
/* Load all those argument registers. */
ld %r3, -32-(8*8)(%r28)
ld %r4, -32-(7*8)(%r28)
ld %r5, -32-(6*8)(%r28)
ld %r6, -32-(5*8)(%r28)
bf- 5, 1f
ld %r7, -32-(4*8)(%r28)
ld %r8, -32-(3*8)(%r28)
@@ -99,50 +129,93 @@ 1:
lfd %f13, -32-(9*8)(%r28)
2:
/* Make the call. */
bctrl
/* This must follow the call immediately, the unwinder
uses this to find out if r2 has been saved or not. */
+# if _CALL_ELF == 2
+ ld %r2, 24(%r1)
+# else
ld %r2, 40(%r1)
+# endif
/* Now, deal with the return value. */
mtcrf 0x01, %r31
- bt- 30, .Ldone_return_value
- bt- 29, .Lfp_return_value
+ bt 31, .Lstruct_return_value
+ bt 30, .Ldone_return_value
+ bt 29, .Lfp_return_value
std %r3, 0(%r30)
/* Fall through... */
.Ldone_return_value:
/* Restore the registers we used and return. */
mr %r1, %r28
ld %r0, 16(%r28)
- ld %r28, -32(%r1)
+ ld %r28, -32(%r28)
mtlr %r0
ld %r29, -24(%r1)
ld %r30, -16(%r1)
ld %r31, -8(%r1)
blr
.Lfp_return_value:
bf 28, .Lfloat_return_value
stfd %f1, 0(%r30)
mtcrf 0x02, %r31 /* cr6 */
bf 27, .Ldone_return_value
stfd %f2, 8(%r30)
b .Ldone_return_value
.Lfloat_return_value:
stfs %f1, 0(%r30)
b .Ldone_return_value
+
+.Lstruct_return_value:
+ bf 29, .Lsmall_struct
+ bf 28, .Lfloat_homog_return_value
+ stfd %f1, 0(%r30)
+ stfd %f2, 8(%r30)
+ stfd %f3, 16(%r30)
+ stfd %f4, 24(%r30)
+ stfd %f5, 32(%r30)
+ stfd %f6, 40(%r30)
+ stfd %f7, 48(%r30)
+ stfd %f8, 56(%r30)
+ b .Ldone_return_value
+
+.Lfloat_homog_return_value:
+ stfs %f1, 0(%r30)
+ stfs %f2, 4(%r30)
+ stfs %f3, 8(%r30)
+ stfs %f4, 12(%r30)
+ stfs %f5, 16(%r30)
+ stfs %f6, 20(%r30)
+ stfs %f7, 24(%r30)
+ stfs %f8, 28(%r30)
+ b .Ldone_return_value
+
+.Lsmall_struct:
+ std %r3, 0(%r30)
+ std %r4, 8(%r30)
+ b .Ldone_return_value
+
.LFE1:
.long 0
.byte 0,12,0,1,128,4,0,0
+# if _CALL_ELF == 2
+ .size ffi_call_LINUX64,.-ffi_call_LINUX64
+# else
+# ifdef _CALL_LINUX
+ .size ffi_call_LINUX64,.-.L.ffi_call_LINUX64
+# else
.size .ffi_call_LINUX64,.-.ffi_call_LINUX64
+# endif
+# endif
.section .eh_frame,EH_FRAME_FLAGS,@progbits
.Lframe1:
.4byte .LECIE1-.LSCIE1 # Length of Common Information Entry
.LSCIE1:
.4byte 0x0 # CIE Identifier Tag
.byte 0x1 # CIE Version
.ascii "zR\0" # CIE Augmentation
@@ -175,13 +248,13 @@ 2:
.byte 0x9e # DW_CFA_offset, column 0x1e
.uleb128 0x2
.byte 0x9d # DW_CFA_offset, column 0x1d
.uleb128 0x3
.byte 0x9c # DW_CFA_offset, column 0x1c
.uleb128 0x4
.align 3
.LEFDE1:
+
+# if (defined __ELF__ && defined __linux__) || _CALL_ELF == 2
+ .section .note.GNU-stack,"",@progbits
+# endif
#endif
-
-#if defined __ELF__ && defined __linux__
- .section .note.GNU-stack,"",@progbits
-#endif
diff --git a/js/src/ctypes/libffi/src/powerpc/linux64_closure.S b/js/src/ctypes/libffi/src/powerpc/linux64_closure.S
--- a/js/src/ctypes/libffi/src/powerpc/linux64_closure.S
+++ b/js/src/ctypes/libffi/src/powerpc/linux64_closure.S
@@ -27,179 +27,330 @@
#define LIBFFI_ASM
#include <fficonfig.h>
#include <ffi.h>
.file "linux64_closure.S"
#ifdef __powerpc64__
FFI_HIDDEN (ffi_closure_LINUX64)
- FFI_HIDDEN (.ffi_closure_LINUX64)
- .globl ffi_closure_LINUX64, .ffi_closure_LINUX64
+ .globl ffi_closure_LINUX64
+# if _CALL_ELF == 2
+ .text
+ffi_closure_LINUX64:
+ addis %r2, %r12, .TOC.-ffi_closure_LINUX64@ha
+ addi %r2, %r2, .TOC.-ffi_closure_LINUX64@l
+ .localentry ffi_closure_LINUX64, . - ffi_closure_LINUX64
+# else
.section ".opd","aw"
.align 3
ffi_closure_LINUX64:
+# ifdef _CALL_LINUX
+ .quad .L.ffi_closure_LINUX64,.TOC.@tocbase,0
+ .type ffi_closure_LINUX64,@function
+ .text
+.L.ffi_closure_LINUX64:
+# else
+ FFI_HIDDEN (.ffi_closure_LINUX64)
+ .globl .ffi_closure_LINUX64
.quad .ffi_closure_LINUX64,.TOC.@tocbase,0
.size ffi_closure_LINUX64,24
.type .ffi_closure_LINUX64,@function
.text
.ffi_closure_LINUX64:
+# endif
+# endif
+
+# if _CALL_ELF == 2
+# 32 byte special reg save area + 64 byte parm save area
+# + 64 byte retval area + 13*8 fpr save area + round to 16
+# define STACKFRAME 272
+# define PARMSAVE 32
+# define RETVAL PARMSAVE+64
+# else
+# 48 bytes special reg save area + 64 bytes parm save area
+# + 16 bytes retval area + 13*8 bytes fpr save area + round to 16
+# define STACKFRAME 240
+# define PARMSAVE 48
+# define RETVAL PARMSAVE+64
+# endif
+
.LFB1:
- # save general regs into parm save area
- std %r3, 48(%r1)
- std %r4, 56(%r1)
- std %r5, 64(%r1)
- std %r6, 72(%r1)
+# if _CALL_ELF == 2
+ ld %r12, FFI_TRAMPOLINE_SIZE(%r11) # closure->cif
mflr %r0
+ lwz %r12, 28(%r12) # cif->flags
+ mtcrf 0x40, %r12
+ addi %r12, %r1, PARMSAVE
+ bt 7, .Lparmsave
+ # Our caller has not allocated a parameter save area.
+ # We need to allocate one here and use it to pass gprs to
+ # ffi_closure_helper_LINUX64.
+ addi %r12, %r1, -STACKFRAME+PARMSAVE
+.Lparmsave:
+ std %r0, 16(%r1)
+ # Save general regs into parm save area
+ std %r3, 0(%r12)
+ std %r4, 8(%r12)
+ std %r5, 16(%r12)
+ std %r6, 24(%r12)
+ std %r7, 32(%r12)
+ std %r8, 40(%r12)
+ std %r9, 48(%r12)
+ std %r10, 56(%r12)
- std %r7, 80(%r1)
- std %r8, 88(%r1)
- std %r9, 96(%r1)
- std %r10, 104(%r1)
+ # load up the pointer to the parm save area
+ mr %r5, %r12
+# else
+ mflr %r0
+ # Save general regs into parm save area
+ # This is the parameter save area set up by our caller.
+ std %r3, PARMSAVE+0(%r1)
+ std %r4, PARMSAVE+8(%r1)
+ std %r5, PARMSAVE+16(%r1)
+ std %r6, PARMSAVE+24(%r1)
+ std %r7, PARMSAVE+32(%r1)
+ std %r8, PARMSAVE+40(%r1)
+ std %r9, PARMSAVE+48(%r1)
+ std %r10, PARMSAVE+56(%r1)
+
std %r0, 16(%r1)
- # mandatory 48 bytes special reg save area + 64 bytes parm save area
- # + 16 bytes retval area + 13*8 bytes fpr save area + round to 16
- stdu %r1, -240(%r1)
+ # load up the pointer to the parm save area
+ addi %r5, %r1, PARMSAVE
+# endif
+
+ # next save fpr 1 to fpr 13
+ stfd %f1, -104+(0*8)(%r1)
+ stfd %f2, -104+(1*8)(%r1)
+ stfd %f3, -104+(2*8)(%r1)
+ stfd %f4, -104+(3*8)(%r1)
+ stfd %f5, -104+(4*8)(%r1)
+ stfd %f6, -104+(5*8)(%r1)
+ stfd %f7, -104+(6*8)(%r1)
+ stfd %f8, -104+(7*8)(%r1)
+ stfd %f9, -104+(8*8)(%r1)
+ stfd %f10, -104+(9*8)(%r1)
+ stfd %f11, -104+(10*8)(%r1)
+ stfd %f12, -104+(11*8)(%r1)
+ stfd %f13, -104+(12*8)(%r1)
+
+ # load up the pointer to the saved fpr registers */
+ addi %r6, %r1, -104
+
+ # load up the pointer to the result storage
+ addi %r4, %r1, -STACKFRAME+RETVAL
+
+ stdu %r1, -STACKFRAME(%r1)
.LCFI0:
- # next save fpr 1 to fpr 13
- stfd %f1, 128+(0*8)(%r1)
- stfd %f2, 128+(1*8)(%r1)
- stfd %f3, 128+(2*8)(%r1)
- stfd %f4, 128+(3*8)(%r1)
- stfd %f5, 128+(4*8)(%r1)
- stfd %f6, 128+(5*8)(%r1)
- stfd %f7, 128+(6*8)(%r1)
- stfd %f8, 128+(7*8)(%r1)
- stfd %f9, 128+(8*8)(%r1)
- stfd %f10, 128+(9*8)(%r1)
- stfd %f11, 128+(10*8)(%r1)
- stfd %f12, 128+(11*8)(%r1)
- stfd %f13, 128+(12*8)(%r1)
-
- # set up registers for the routine that actually does the work
# get the context pointer from the trampoline
- mr %r3, %r11
-
- # now load up the pointer to the result storage
- addi %r4, %r1, 112
-
- # now load up the pointer to the parameter save area
- # in the previous frame
- addi %r5, %r1, 240 + 48
-
- # now load up the pointer to the saved fpr registers */
- addi %r6, %r1, 128
+ mr %r3, %r11
# make the call
+# if defined _CALL_LINUX || _CALL_ELF == 2
+ bl ffi_closure_helper_LINUX64
+# else
bl .ffi_closure_helper_LINUX64
+# endif
.Lret:
# now r3 contains the return type
# so use it to look up in a table
# so we know how to deal with each type
# look up the proper starting point in table
# by using return type as offset
+ ld %r0, STACKFRAME+16(%r1)
+ cmpldi %r3, FFI_V2_TYPE_SMALL_STRUCT
+ bge .Lsmall
mflr %r4 # move address of .Lret to r4
sldi %r3, %r3, 4 # now multiply return type by 16
addi %r4, %r4, .Lret_type0 - .Lret
- ld %r0, 240+16(%r1)
add %r3, %r3, %r4 # add contents of table to table address
mtctr %r3
bctr # jump to it
# Each of the ret_typeX code fragments has to be exactly 16 bytes long
# (4 instructions). For cache effectiveness we align to a 16 byte boundary
# first.
.align 4
.Lret_type0:
# case FFI_TYPE_VOID
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
nop
# case FFI_TYPE_INT
- lwa %r3, 112+4(%r1)
+# ifdef __LITTLE_ENDIAN__
+ lwa %r3, RETVAL+0(%r1)
+# else
+ lwa %r3, RETVAL+4(%r1)
+# endif
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_FLOAT
- lfs %f1, 112+0(%r1)
+ lfs %f1, RETVAL+0(%r1)
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_DOUBLE
- lfd %f1, 112+0(%r1)
+ lfd %f1, RETVAL+0(%r1)
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_LONGDOUBLE
- lfd %f1, 112+0(%r1)
+ lfd %f1, RETVAL+0(%r1)
mtlr %r0
- lfd %f2, 112+8(%r1)
+ lfd %f2, RETVAL+8(%r1)
b .Lfinish
# case FFI_TYPE_UINT8
- lbz %r3, 112+7(%r1)
+# ifdef __LITTLE_ENDIAN__
+ lbz %r3, RETVAL+0(%r1)
+# else
+ lbz %r3, RETVAL+7(%r1)
+# endif
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_SINT8
- lbz %r3, 112+7(%r1)
+# ifdef __LITTLE_ENDIAN__
+ lbz %r3, RETVAL+0(%r1)
+# else
+ lbz %r3, RETVAL+7(%r1)
+# endif
extsb %r3,%r3
mtlr %r0
b .Lfinish
# case FFI_TYPE_UINT16
- lhz %r3, 112+6(%r1)
+# ifdef __LITTLE_ENDIAN__
+ lhz %r3, RETVAL+0(%r1)
+# else
+ lhz %r3, RETVAL+6(%r1)
+# endif
mtlr %r0
.Lfinish:
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_SINT16
- lha %r3, 112+6(%r1)
+# ifdef __LITTLE_ENDIAN__
+ lha %r3, RETVAL+0(%r1)
+# else
+ lha %r3, RETVAL+6(%r1)
+# endif
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_UINT32
- lwz %r3, 112+4(%r1)
+# ifdef __LITTLE_ENDIAN__
+ lwz %r3, RETVAL+0(%r1)
+# else
+ lwz %r3, RETVAL+4(%r1)
+# endif
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_SINT32
- lwa %r3, 112+4(%r1)
+# ifdef __LITTLE_ENDIAN__
+ lwa %r3, RETVAL+0(%r1)
+# else
+ lwa %r3, RETVAL+4(%r1)
+# endif
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_UINT64
- ld %r3, 112+0(%r1)
+ ld %r3, RETVAL+0(%r1)
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_SINT64
- ld %r3, 112+0(%r1)
+ ld %r3, RETVAL+0(%r1)
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
# case FFI_TYPE_STRUCT
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
nop
# case FFI_TYPE_POINTER
- ld %r3, 112+0(%r1)
+ ld %r3, RETVAL+0(%r1)
mtlr %r0
- addi %r1, %r1, 240
+ addi %r1, %r1, STACKFRAME
blr
-# esac
+# case FFI_V2_TYPE_FLOAT_HOMOG
+ lfs %f1, RETVAL+0(%r1)
+ lfs %f2, RETVAL+4(%r1)
+ lfs %f3, RETVAL+8(%r1)
+ b .Lmorefloat
+# case FFI_V2_TYPE_DOUBLE_HOMOG
+ lfd %f1, RETVAL+0(%r1)
+ lfd %f2, RETVAL+8(%r1)
+ lfd %f3, RETVAL+16(%r1)
+ lfd %f4, RETVAL+24(%r1)
+ mtlr %r0
+ lfd %f5, RETVAL+32(%r1)
+ lfd %f6, RETVAL+40(%r1)
+ lfd %f7, RETVAL+48(%r1)
+ lfd %f8, RETVAL+56(%r1)
+ addi %r1, %r1, STACKFRAME
+ blr
+.Lmorefloat:
+ lfs %f4, RETVAL+12(%r1)
+ mtlr %r0
+ lfs %f5, RETVAL+16(%r1)
+ lfs %f6, RETVAL+20(%r1)
+ lfs %f7, RETVAL+24(%r1)
+ lfs %f8, RETVAL+28(%r1)
+ addi %r1, %r1, STACKFRAME
+ blr
+.Lsmall:
+# ifdef __LITTLE_ENDIAN__
+ ld %r3,RETVAL+0(%r1)
+ mtlr %r0
+ ld %r4,RETVAL+8(%r1)
+ addi %r1, %r1, STACKFRAME
+ blr
+# else
+ # A struct smaller than a dword is returned in the low bits of r3
+ # ie. right justified. Larger structs are passed left justified
+ # in r3 and r4. The return value area on the stack will have
+ # the structs as they are usually stored in memory.
+ cmpldi %r3, FFI_V2_TYPE_SMALL_STRUCT + 7 # size 8 bytes?
+ neg %r5, %r3
+ ld %r3,RETVAL+0(%r1)
+ blt .Lsmalldown
+ mtlr %r0
+ ld %r4,RETVAL+8(%r1)
+ addi %r1, %r1, STACKFRAME
+ blr
+.Lsmalldown:
+ addi %r5, %r5, FFI_V2_TYPE_SMALL_STRUCT + 7
+ mtlr %r0
+ sldi %r5, %r5, 3
+ addi %r1, %r1, STACKFRAME
+ srd %r3, %r3, %r5
+ blr
+# endif
+
.LFE1:
.long 0
.byte 0,12,0,1,128,0,0,0
+# if _CALL_ELF == 2
+ .size ffi_closure_LINUX64,.-ffi_closure_LINUX64
+# else
+# ifdef _CALL_LINUX
+ .size ffi_closure_LINUX64,.-.L.ffi_closure_LINUX64
+# else
.size .ffi_closure_LINUX64,.-.ffi_closure_LINUX64
+# endif
+# endif
.section .eh_frame,EH_FRAME_FLAGS,@progbits
.Lframe1:
.4byte .LECIE1-.LSCIE1 # Length of Common Information Entry
.LSCIE1:
.4byte 0x0 # CIE Identifier Tag
.byte 0x1 # CIE Version
.ascii "zR\0" # CIE Augmentation
@@ -218,19 +369,19 @@ ffi_closure_LINUX64:
.LASFDE1:
.4byte .LASFDE1-.Lframe1 # FDE CIE offset
.8byte .LFB1-. # FDE initial location
.8byte .LFE1-.LFB1 # FDE address range
.uleb128 0x0 # Augmentation size
.byte 0x2 # DW_CFA_advance_loc1
.byte .LCFI0-.LFB1
.byte 0xe # DW_CFA_def_cfa_offset
- .uleb128 240
+ .uleb128 STACKFRAME
.byte 0x11 # DW_CFA_offset_extended_sf
.uleb128 0x41
.sleb128 -2
.align 3
.LEFDE1:
+
+# if defined __ELF__ && defined __linux__
+ .section .note.GNU-stack,"",@progbits
+# endif
#endif
-
-#if defined __ELF__ && defined __linux__
- .section .note.GNU-stack,"",@progbits
-#endif
diff --git a/js/src/ctypes/libffi/src/powerpc/ppc_closure.S b/js/src/ctypes/libffi/src/powerpc/ppc_closure.S
--- a/js/src/ctypes/libffi/src/powerpc/ppc_closure.S
+++ b/js/src/ctypes/libffi/src/powerpc/ppc_closure.S
@@ -117,53 +117,88 @@ ENTRY(ffi_closure_SYSV)
# case FFI_TYPE_INT
lwz %r3,112+0(%r1)
mtlr %r0
.Lfinish:
addi %r1,%r1,144
blr
# case FFI_TYPE_FLOAT
+#ifndef __NO_FPRS__
lfs %f1,112+0(%r1)
mtlr %r0
addi %r1,%r1,144
+#else
+ nop
+ nop
+ nop
+#endif
blr
# case FFI_TYPE_DOUBLE
+#ifndef __NO_FPRS__
lfd %f1,112+0(%r1)
mtlr %r0
addi %r1,%r1,144
+#else
+ nop
+ nop
+ nop
+#endif
blr
# case FFI_TYPE_LONGDOUBLE
+#ifndef __NO_FPRS__
lfd %f1,112+0(%r1)
lfd %f2,112+8(%r1)
mtlr %r0
b .Lfinish
+#else
+ nop
+ nop
+ nop
+ blr
+#endif
# case FFI_TYPE_UINT8
+#ifdef __LITTLE_ENDIAN__
+ lbz %r3,112+0(%r1)
+#else
lbz %r3,112+3(%r1)
+#endif
mtlr %r0
addi %r1,%r1,144
blr
# case FFI_TYPE_SINT8
+#ifdef __LITTLE_ENDIAN__
+ lbz %r3,112+0(%r1)
+#else
lbz %r3,112+3(%r1)
+#endif
extsb %r3,%r3
mtlr %r0
b .Lfinish
# case FFI_TYPE_UINT16
+#ifdef __LITTLE_ENDIAN__
+ lhz %r3,112+0(%r1)
+#else
lhz %r3,112+2(%r1)
+#endif
mtlr %r0
addi %r1,%r1,144
blr
# case FFI_TYPE_SINT16
+#ifdef __LITTLE_ENDIAN__
+ lha %r3,112+0(%r1)
+#else
lha %r3,112+2(%r1)
+#endif
mtlr %r0
addi %r1,%r1,144
blr
# case FFI_TYPE_UINT32
lwz %r3,112+0(%r1)
mtlr %r0
addi %r1,%r1,144
@@ -198,76 +233,99 @@ ENTRY(ffi_closure_SYSV)
mtlr %r0
addi %r1,%r1,144
blr
# case FFI_TYPE_UINT128
lwz %r3,112+0(%r1)
lwz %r4,112+4(%r1)
lwz %r5,112+8(%r1)
- bl .Luint128
+ b .Luint128
# The return types below are only used when the ABI type is FFI_SYSV.
# case FFI_SYSV_TYPE_SMALL_STRUCT + 1. One byte struct.
lbz %r3,112+0(%r1)
mtlr %r0
addi %r1,%r1,144
blr
# case FFI_SYSV_TYPE_SMALL_STRUCT + 2. Two byte struct.
lhz %r3,112+0(%r1)
mtlr %r0
addi %r1,%r1,144
blr
# case FFI_SYSV_TYPE_SMALL_STRUCT + 3. Three byte struct.
lwz %r3,112+0(%r1)
+#ifdef __LITTLE_ENDIAN__
+ mtlr %r0
+ addi %r1,%r1,144
+ blr
+#else
srwi %r3,%r3,8
mtlr %r0
b .Lfinish
+#endif
# case FFI_SYSV_TYPE_SMALL_STRUCT + 4. Four byte struct.
lwz %r3,112+0(%r1)
mtlr %r0
addi %r1,%r1,144
blr
# case FFI_SYSV_TYPE_SMALL_STRUCT + 5. Five byte struct.
lwz %r3,112+0(%r1)
lwz %r4,112+4(%r1)
+#ifdef __LITTLE_ENDIAN__
+ mtlr %r0
+ b .Lfinish
+#else
li %r5,24
b .Lstruct567
+#endif
# case FFI_SYSV_TYPE_SMALL_STRUCT + 6. Six byte struct.
lwz %r3,112+0(%r1)
lwz %r4,112+4(%r1)
+#ifdef __LITTLE_ENDIAN__
+ mtlr %r0
+ b .Lfinish
+#else
li %r5,16
b .Lstruct567
+#endif
# case FFI_SYSV_TYPE_SMALL_STRUCT + 7. Seven byte struct.
lwz %r3,112+0(%r1)
lwz %r4,112+4(%r1)
+#ifdef __LITTLE_ENDIAN__
+ mtlr %r0
+ b .Lfinish
+#else
li %r5,8
b .Lstruct567
+#endif
# case FFI_SYSV_TYPE_SMALL_STRUCT + 8. Eight byte struct.
lwz %r3,112+0(%r1)
lwz %r4,112+4(%r1)
mtlr %r0
b .Lfinish
+#ifndef __LITTLE_ENDIAN__
.Lstruct567:
subfic %r6,%r5,32
srw %r4,%r4,%r5
slw %r6,%r3,%r6
srw %r3,%r3,%r5
or %r4,%r6,%r4
mtlr %r0
addi %r1,%r1,144
blr
+#endif
.Luint128:
lwz %r6,112+12(%r1)
mtlr %r0
addi %r1,%r1,144
blr
END(ffi_closure_SYSV)
diff --git a/js/src/ctypes/libffi/src/powerpc/sysv.S b/js/src/ctypes/libffi/src/powerpc/sysv.S
--- a/js/src/ctypes/libffi/src/powerpc/sysv.S
+++ b/js/src/ctypes/libffi/src/powerpc/sysv.S
@@ -78,37 +78,41 @@ ENTRY(ffi_call_SYSV)
nop
lwz %r7,-16-(4*4)(%r28)
lwz %r8,-16-(3*4)(%r28)
lwz %r9,-16-(2*4)(%r28)
lwz %r10,-16-(1*4)(%r28)
nop
1:
+#ifndef __NO_FPRS__
/* Load all the FP registers. */
bf- 6,2f
lfd %f1,-16-(8*4)-(8*8)(%r28)
lfd %f2,-16-(8*4)-(7*8)(%r28)
lfd %f3,-16-(8*4)-(6*8)(%r28)
lfd %f4,-16-(8*4)-(5*8)(%r28)
nop
lfd %f5,-16-(8*4)-(4*8)(%r28)
lfd %f6,-16-(8*4)-(3*8)(%r28)
lfd %f7,-16-(8*4)-(2*8)(%r28)
lfd %f8,-16-(8*4)-(1*8)(%r28)
+#endif
2:
/* Make the call. */
bctrl
/* Now, deal with the return value. */
mtcrf 0x01,%r31 /* cr7 */
bt- 31,L(small_struct_return_value)
bt- 30,L(done_return_value)
+#ifndef __NO_FPRS__
bt- 29,L(fp_return_value)
+#endif
stw %r3,0(%r30)
bf+ 28,L(done_return_value)
stw %r4,4(%r30)
mtcrf 0x02,%r31 /* cr6 */
bf 27,L(done_return_value)
stw %r5,8(%r30)
stw %r6,12(%r30)
/* Fall through... */
@@ -119,41 +123,38 @@ L(done_return_value):
lwz %r31, -4(%r28)
mtlr %r9
lwz %r30, -8(%r28)
lwz %r29,-12(%r28)
lwz %r28,-16(%r28)
lwz %r1,0(%r1)
blr
+#ifndef __NO_FPRS__
L(fp_return_value):
bf 28,L(float_return_value)
stfd %f1,0(%r30)
mtcrf 0x02,%r31 /* cr6 */
bf 27,L(done_return_value)
stfd %f2,8(%r30)
b L(done_return_value)
L(float_return_value):
stfs %f1,0(%r30)
b L(done_return_value)
+#endif
L(small_struct_return_value):
- extrwi %r6,%r31,2,19 /* number of bytes padding = shift/8 */
- mtcrf 0x02,%r31 /* copy flags to cr[24:27] (cr6) */
- extrwi %r5,%r31,5,19 /* r5 <- number of bits of padding */
- subfic %r6,%r6,4 /* r6 <- number of useful bytes in r3 */
- bf- 25,L(done_return_value) /* struct in r3 ? if not, done. */
-/* smst_one_register: */
- slw %r3,%r3,%r5 /* Left-justify value in r3 */
- mtxer %r6 /* move byte count to XER ... */
- stswx %r3,0,%r30 /* ... and store that many bytes */
- bf+ 26,L(done_return_value) /* struct in r3:r4 ? */
- add %r6,%r6,%r30 /* adjust pointer */
- stswi %r4,%r6,4 /* store last four bytes */
- b L(done_return_value)
+ /*
+ * The C code always allocates a properly-aligned 8-byte bounce
+ * buffer to make this assembly code very simple. Just write out
+ * r3 and r4 to the buffer to allow the C code to handle the rest.
+ */
+ stw %r3, 0(%r30)
+ stw %r4, 4(%r30)
+ b L(done_return_value)
.LFE1:
END(ffi_call_SYSV)
.section ".eh_frame",EH_FRAME_FLAGS,@progbits
.Lframe1:
.4byte .LECIE1-.LSCIE1 /* Length of Common Information Entry */
.LSCIE1:
View Git Blame Copy Permalink