#include "php_psi.h"
#include "libffi.h"
+#include "engine.h"
#undef PACKAGE
#undef PACKAGE_BUGREPORT
}
return *code;
#else
- return NULL;
+# error "Neither ffi_closure_alloc() nor mmap() available"
#endif
}
+static ffi_status psi_ffi_prep_closure(ffi_closure **closure, void **code, ffi_cif *sig, void (*handler)(ffi_cif*,void*,void**,void*), void *data) {
+ *closure = psi_ffi_closure_alloc(sizeof(ffi_closure), code);
+ ZEND_ASSERT(*closure != NULL);
+
+#if PSI_HAVE_FFI_PREP_CLOSURE_LOC
+ return ffi_prep_closure_loc(*closure, sig, handler, data, *code);
+
+#elif PSI_HAVE_FFI_PREP_CLOSURE
+ return ffi_prep_closure(*code, sig, handler, data);
+#else
+# error "Neither ffi_prep_closure() nor ffi_prep_closure_loc() is available"
+#endif
+
+}
+
static void psi_ffi_closure_free(void *c)
{
#ifdef PSI_HAVE_FFI_CLOSURE_ALLOC
#endif
}
-static void psi_ffi_handler(ffi_cif *signature, void *_result, void **_args, void *_data);
+static void psi_ffi_handler(ffi_cif *_sig, void *_result, void **_args, void *_data)
+{
+ psi_call(*(zend_execute_data **)_args[0], *(zval **)_args[1], _data);
+}
+
+static void psi_ffi_callback(ffi_cif *_sig, void *_result, void **_args, void *_data)
+{
+ size_t i;
+ unsigned argc = _sig->nargs;
+ void **argv = _args;
+ let_callback *cb = _data;
+ decl *decl_cb = cb->decl;
+ impl_arg *iarg = cb->func->var->arg;
+ zval return_value, *zargv = calloc(argc, sizeof(*zargv));
+ void *result, *to_free = NULL;
+
+ ZEND_ASSERT(argc == cb->decl->args->count);
+
+ /* prepare args for the userland call */
+ for (i = 0; i < argc; ++i) {
+ cb->decl->args->args[i]->ptr = argv[i];
+ }
+ for (i = 0; i < cb->args->count; ++i) {
+ psi_do_set(&zargv[i], cb->args->vals[i]);
+ }
+ zend_fcall_info_argp(&iarg->val.zend.cb->fci, cb->args->count, zargv);
+
+ /* callback into userland */
+ ZVAL_UNDEF(&return_value);
+ iarg->_zv = &return_value;
+ zend_fcall_info_call(&iarg->val.zend.cb->fci, &iarg->val.zend.cb->fcc, iarg->_zv, NULL);
+
+ /* marshal return value of the userland call */
+ switch (iarg->type->type) {
+ case PSI_T_BOOL: zend_parse_arg_bool(iarg->_zv, &iarg->val.zend.bval, NULL, 0); break;
+ case PSI_T_LONG: zend_parse_arg_long(iarg->_zv, &iarg->val.zend.lval, NULL, 0, 1); break;
+ case PSI_T_FLOAT:
+ case PSI_T_DOUBLE: zend_parse_arg_double(iarg->_zv, &iarg->val.dval, NULL, 0); break;
+ case PSI_T_STRING: zend_parse_arg_str(iarg->_zv, &iarg->val.zend.str, 0); break;
+ }
+ result = cb->func->handler(_result, decl_cb->func->type, iarg, &to_free);
+
+ if (result != _result) {
+ *(void **)_result = result;
+ }
+
+ zend_fcall_info_args_clear(&iarg->val.zend.cb->fci, 0);
+ for (i = 0; i < cb->args->count; ++i) {
+ zval_ptr_dtor(&zargv[i]);
+ }
+ free(zargv);
+}
+
static inline ffi_type *psi_ffi_decl_arg_type(decl_arg *darg);
+typedef struct PSI_LibffiContext {
+ ffi_cif signature;
+ ffi_type *params[2];
+} PSI_LibffiContext;
+
+typedef struct PSI_LibffiCall {
+ void *code;
+ ffi_closure *closure;
+ ffi_cif signature;
+ void *params[1]; /* [type1, type2, NULL, arg1, arg2] ... */
+} PSI_LibffiCall;
+
static inline ffi_abi psi_ffi_abi(const char *convention) {
return FFI_DEFAULT_ABI;
}
+
+static inline PSI_LibffiCall *PSI_LibffiCallAlloc(PSI_Context *C, decl *decl) {
+ int rc;
+ size_t i, c = decl->args ? decl->args->count : 0;
+ PSI_LibffiCall *call = calloc(1, sizeof(*call) + 2 * c * sizeof(void *));
+
+ for (i = 0; i < c; ++i) {
+ call->params[i] = psi_ffi_decl_arg_type(decl->args->args[i]);
+ }
+ call->params[c] = NULL;
+
+ decl->call.info = call;
+ decl->call.rval = &decl->func->ptr;
+ decl->call.argc = c;
+ decl->call.args = (void **) &call->params[c+1];
+
+ rc = ffi_prep_cif(&call->signature, psi_ffi_abi(decl->abi->convention),
+ c, psi_ffi_decl_arg_type(decl->func), (ffi_type **) call->params);
+ ZEND_ASSERT(FFI_OK == rc);
+
+ return call;
+}
+
+static inline ffi_status PSI_LibffiCallInitClosure(PSI_Context *C, PSI_LibffiCall *call, impl *impl) {
+ PSI_LibffiContext *context = C->context;
+
+ return psi_ffi_prep_closure(&call->closure, &call->code, &context->signature, psi_ffi_handler, impl);
+}
+
+static inline ffi_status PSI_LibffiCallInitCallbackClosure(PSI_Context *C, PSI_LibffiCall *call, let_callback *cb) {
+ return psi_ffi_prep_closure(&call->closure, &call->code, &call->signature, psi_ffi_callback, cb);
+}
+
+static inline void PSI_LibffiCallFree(PSI_LibffiCall *call) {
+ if (call->closure) {
+ psi_ffi_closure_free(call->closure);
+ }
+ free(call);
+}
+
static inline ffi_type *psi_ffi_token_type(token_t t) {
switch (t) {
default:
case PSI_T_BOOL:
return &ffi_type_uchar;
case PSI_T_INT:
+ case PSI_T_ENUM:
return &ffi_type_sint;
case PSI_T_LONG:
return &ffi_type_slong;
return &ffi_type_float;
case PSI_T_DOUBLE:
return &ffi_type_double;
+#ifdef HAVE_LONG_DOUBLE
+ case PSI_T_LONG_DOUBLE:
+ return &ffi_type_longdouble;
+#endif
case PSI_T_POINTER:
+ case PSI_T_FUNCTION:
return &ffi_type_pointer;
}
}
free(strct);
}
+static size_t psi_ffi_struct_type_pad(ffi_type **els, size_t padding) {
+ size_t i;
+
+ for (i = 0; i < padding; ++i) {
+ ffi_type *pad = malloc(sizeof(*pad));
+
+ memcpy(pad, &ffi_type_schar, sizeof(*pad));
+ *els++ = pad;
+ }
+
+ return padding;
+}
+
static ffi_type **psi_ffi_struct_type_elements(decl_struct *strct) {
- size_t i, j, argc = strct->args->count << 2, nels = 0, offset = 0, align, padding;
+ size_t i, argc = strct->args->count, nels = 0, offset = 0, maxalign = 0;
ffi_type **els = calloc(argc + 1, sizeof(*els));
for (i = 0; i < strct->args->count; ++i) {
decl_arg *darg = strct->args->args[i];
ffi_type *type = malloc(sizeof(*type));
+ size_t padding;
memcpy(type, psi_ffi_decl_arg_type(darg), sizeof(*type));
- if (darg->layout->pos > offset) {
- padding = darg->layout->pos - offset;
- align = ((padding - 1) | (type->alignment - 1)) + 1;
- if (align >= padding) {
- padding = 0;
- }
- } else {
- align = 0;
- padding = 0;
- }
+ ZEND_ASSERT(type->size == darg->layout->len);
- if (padding) {
- for (j = 0; j < padding; ++j) {
- ffi_type *pad = malloc(sizeof(*pad));
+ if (type->alignment > maxalign) {
+ maxalign = type->alignment;
+ }
- ZEND_ASSERT(nels + 1 < argc);
- memcpy(pad, &ffi_type_schar, sizeof(*pad));
- els[nels++] = pad;
+ if ((padding = psi_offset_padding(darg->layout->pos - offset, type->alignment))) {
+ if (nels + padding + 1 > argc) {
+ argc += padding;
+ els = realloc(els, (argc + 1) * sizeof(*els));
+ els[argc] = NULL;
}
+ psi_ffi_struct_type_pad(&els[nels], padding);
+ nels += padding;
+ offset += padding;
}
+ ZEND_ASSERT(offset == darg->layout->pos);
- ZEND_ASSERT(nels + 1 < argc);
+ offset = (offset + darg->layout->len + type->alignment - 1) & ~(type->alignment - 1);
els[nels++] = type;
-//fprintf(stderr, "%s o:%d, a:%d, p:%d l:%d\n", darg->var->name, offset, align, padding, darg->layout->len);
- offset += MAX(align, padding) + darg->layout->len;
}
-//fprintf(stderr, "%s s:%d o=%d\n", strct->name, strct->size, offset);
+
+ /* apply struct alignment padding */
+ offset = (offset + maxalign - 1) & ~(maxalign - 1);
+
ZEND_ASSERT(offset <= strct->size);
if (offset < strct->size) {
- padding = strct->size - offset;
- for (j = 0; j < padding; ++j) {
- ffi_type *pad = malloc(sizeof(*pad));
-
- ZEND_ASSERT(nels + 1 < argc);
- memcpy(pad, &ffi_type_schar, sizeof(*pad));
- els[nels++] = pad;
- }
+ psi_ffi_struct_type_pad(&els[nels], strct->size - offset);
}
return els;
static inline ffi_type *psi_ffi_decl_type(decl_type *type) {
decl_type *real = real_decl_type(type);
- if (real->type == PSI_T_STRUCT) {
+ switch (real->type) {
+ case PSI_T_FUNCTION:
+ return &ffi_type_pointer;
+
+ case PSI_T_STRUCT:
if (!real->strct->engine.type) {
ffi_type *strct = calloc(1, sizeof(ffi_type));
strct->type = FFI_TYPE_STRUCT;
- strct->size = 0;//real->strct->size;
+ strct->size = 0;
strct->elements = psi_ffi_struct_type_elements(real->strct);
real->strct->engine.type = strct;
}
return real->strct->engine.type;
+
+ case PSI_T_UNION:
+ return psi_ffi_decl_arg_type(real->unn->args->args[0]);
+
+ default:
+ return psi_ffi_token_type(real->type);
}
- return psi_ffi_token_type(real->type);
}
static inline ffi_type *psi_ffi_decl_arg_type(decl_arg *darg) {
if (darg->var->pointer_level) {
}
}
-typedef struct PSI_LibffiContext {
- ffi_cif signature;
- ffi_type *params[2];
-} PSI_LibffiContext;
-
-typedef struct PSI_LibffiCall {
- void *code;
- ffi_closure *closure;
- ffi_cif signature;
- void *params[1]; /* [type1, type2, NULL, arg1, arg2] ... */
-} PSI_LibffiCall;
-
-static inline PSI_LibffiCall *PSI_LibffiCallAlloc(PSI_Context *C, decl *decl) {
- int rc;
- size_t i, c = decl->args ? decl->args->count : 0;
- PSI_LibffiCall *call = calloc(1, sizeof(*call) + 2 * c * sizeof(void *));
-
- for (i = 0; i < c; ++i) {
- call->params[i] = psi_ffi_decl_arg_type(decl->args->args[i]);
- }
- call->params[c] = NULL;
-
- decl->call.info = call;
- decl->call.rval = &decl->func->ptr;
- decl->call.argc = c;
- decl->call.args = (void **) &call->params[c+1];
-
- rc = ffi_prep_cif(&call->signature, psi_ffi_abi(decl->abi->convention),
- c, psi_ffi_decl_arg_type(decl->func), (ffi_type **) call->params);
- ZEND_ASSERT(FFI_OK == rc);
-
- return call;
-}
-
-static inline void PSI_LibffiCallInitClosure(PSI_Context *C, PSI_LibffiCall *call, impl *impl) {
- PSI_LibffiContext *context = C->context;
- int rc;
-
- call->closure = psi_ffi_closure_alloc(sizeof(ffi_closure), &call->code);
- ZEND_ASSERT(call->closure != NULL);
-
-#if PSI_HAVE_FFI_PREP_CLOSURE_LOC
- rc = ffi_prep_closure_loc(
- call->closure,
- &context->signature,
- psi_ffi_handler,
- impl,
- call->code);
-
-#elif PSI_HAVE_FFI_PREP_CLOSURE
- rc = ffi_prep_closure(call->code, &context->signature, psi_ffi_handler, impl);
-#else
-# error "Neither ffi_prep_closure() nor ffi_prep_closure_loc() available"
-#endif
- ZEND_ASSERT(FFI_OK == rc);
-}
-
-static inline void PSI_LibffiCallFree(PSI_LibffiCall *call) {
- if (call->closure) {
- psi_ffi_closure_free(call->closure);
- }
- free(call);
-}
static inline PSI_LibffiContext *PSI_LibffiContextInit(PSI_LibffiContext *L) {
ffi_status rc;
return L;
}
-static void psi_ffi_handler(ffi_cif *_sig, void *_result, void **_args, void *_data)
-{
- psi_call(*(zend_execute_data **)_args[0], *(zval **)_args[1], _data);
-}
-
static void psi_ffi_init(PSI_Context *C)
{
C->context = PSI_LibffiContextInit(NULL);
PSI_LibffiCallFree(decl->call.info);
}
}
+
+ }
+ if (C->impls) {
+ size_t i, j;
+
+ for (i = 0; i < C->impls->count; ++i) {
+ impl *impl = C->impls->list[i];
+
+ for (j = 0; j < impl->stmts->let.count; ++j) {
+ let_stmt *let = impl->stmts->let.list[j];
+
+ if (let->val && let->val->kind == PSI_LET_CALLBACK) {
+ let_callback *cb = let->val->data.callback;
+
+ if (cb->decl && cb->decl->call.info) {
+ PSI_LibffiCallFree(cb->decl->call.info);
+ }
+ }
+ }
+ }
}
free(C->context);
}
static zend_function_entry *psi_ffi_compile(PSI_Context *C)
{
- size_t i, j = 0;
+ size_t c, i, j = 0;
zend_function_entry *zfe;
if (!C->impls) {
}
call = PSI_LibffiCallAlloc(C, impl->decl);
- PSI_LibffiCallInitClosure(C, call, impl);
+ if (FFI_OK != PSI_LibffiCallInitClosure(C, call, impl)) {
+ PSI_LibffiCallFree(call);
+ continue;
+ }
zf->fname = impl->func->name + (impl->func->name[0] == '\\');
zf->num_args = impl->func->args->count;
zf->handler = call->code;
zf->arg_info = psi_internal_arginfo(impl);
++j;
+
+ for (c = 0; c < impl->stmts->let.count; ++c) {
+ let_stmt *let = impl->stmts->let.list[c];
+
+ if (let->val->kind == PSI_LET_CALLBACK) {
+ let_callback *cb = let->val->data.callback;
+
+ call = PSI_LibffiCallAlloc(C, cb->decl);
+ if (FFI_OK != PSI_LibffiCallInitCallbackClosure(C, call, cb)) {
+ PSI_LibffiCallFree(call);
+ continue;
+ }
+
+ cb->decl->call.sym = call->code;
+ }
+ }
}
for (i = 0; i < C->decls->count; ++i) {
decl *decl = C->decls->list[i];
- if (decl->impl) {
+// if (decl->impl) {
+// continue;
+// }
+ if (decl->call.info) {
continue;
}