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janet/src/core/ffi.c
2022-06-18 09:46:28 -05:00

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/*
* Copyright (c) 2022 Calvin Rose
*
* 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.
*/
#ifndef JANET_AMALG
#include "features.h"
#include <janet.h>
#include "util.h"
#endif
#ifdef JANET_FFI
#ifdef _MSC_VER
#define alloca _alloca
#endif
#define JANET_FFI_MAX_RECUR 64
/* Compiler, OS, and arch detection. Used
* to enable a set of calling conventions. The
* :none calling convention is always enabled. */
#if defined(JANET_WINDOWS) && (defined(__x86_64__) || defined(_M_X64))
#define JANET_FFI_WIN64_ENABLED
#endif
#if (defined(__x86_64__) || defined(_M_X64)) && !defined(JANET_WINDOWS)
#define JANET_FFI_SYSV64_ENABLED
#endif
typedef struct JanetFFIType JanetFFIType;
typedef struct JanetFFIStruct JanetFFIStruct;
typedef enum {
JANET_FFI_TYPE_VOID,
JANET_FFI_TYPE_BOOL,
JANET_FFI_TYPE_PTR,
JANET_FFI_TYPE_FLOAT,
JANET_FFI_TYPE_DOUBLE,
JANET_FFI_TYPE_INT8,
JANET_FFI_TYPE_UINT8,
JANET_FFI_TYPE_INT16,
JANET_FFI_TYPE_UINT16,
JANET_FFI_TYPE_INT32,
JANET_FFI_TYPE_UINT32,
JANET_FFI_TYPE_INT64,
JANET_FFI_TYPE_UINT64,
JANET_FFI_TYPE_STRUCT
} JanetFFIPrimType;
/* Custom alignof since alignof not in c99 standard */
#define ALIGNOF(type) offsetof(struct { char c; type member; }, member)
typedef struct {
size_t size;
size_t align;
} JanetFFIPrimInfo;
static const JanetFFIPrimInfo janet_ffi_type_info[] = {
{0, 0}, /* JANET_FFI_TYPE_VOID */
{sizeof(char), ALIGNOF(char)}, /* JANET_FFI_TYPE_BOOL */
{sizeof(void *), ALIGNOF(void *)}, /* JANET_FFI_TYPE_PTR */
{sizeof(float), ALIGNOF(float)}, /* JANET_FFI_TYPE_FLOAT */
{sizeof(double), ALIGNOF(double)}, /* JANET_FFI_TYPE_DOUBLE */
{sizeof(int8_t), ALIGNOF(int8_t)}, /* JANET_FFI_TYPE_INT8 */
{sizeof(uint8_t), ALIGNOF(uint8_t)}, /* JANET_FFI_TYPE_UINT8 */
{sizeof(int16_t), ALIGNOF(int16_t)}, /* JANET_FFI_TYPE_INT16 */
{sizeof(uint16_t), ALIGNOF(uint16_t)}, /* JANET_FFI_TYPE_UINT16 */
{sizeof(int32_t), ALIGNOF(int32_t)}, /* JANET_FFI_TYPE_INT32 */
{sizeof(uint32_t), ALIGNOF(uint32_t)}, /* JANET_FFI_TYPE_UINT32 */
{sizeof(int64_t), ALIGNOF(int64_t)}, /* JANET_FFI_TYPE_INT64 */
{sizeof(uint64_t), ALIGNOF(uint64_t)}, /* JANET_FFI_TYPE_UINT64 */
{0, ALIGNOF(uint64_t)} /* JANET_FFI_TYPE_STRUCT */
};
struct JanetFFIType {
JanetFFIStruct *st;
JanetFFIPrimType prim;
};
typedef struct {
JanetFFIType type;
size_t offset;
} JanetFFIStructMember;
struct JanetFFIStruct {
uint32_t size;
uint32_t align;
uint32_t field_count;
uint32_t is_aligned;
JanetFFIStructMember fields[];
};
/* Specifies how the registers are classified. This is used
* to determine if a certain argument should be passed in a register,
* on the stack, special floating pointer register, etc. */
typedef enum {
JANET_SYSV64_INTEGER,
JANET_SYSV64_SSE,
JANET_SYSV64_SSEUP,
JANET_SYSV64_X87,
JANET_SYSV64_X87UP,
JANET_SYSV64_COMPLEX_X87,
JANET_SYSV64_NO_CLASS,
JANET_SYSV64_MEMORY,
JANET_WIN64_REGISTER,
JANET_WIN64_STACK,
JANET_WIN64_REGISTER_REF,
JANET_WIN64_STACK_REF
} JanetFFIWordSpec;
/* Describe how each Janet argument is interpreted in terms of machine words
* that will be mapped to registers/stack. */
typedef struct {
JanetFFIType type;
JanetFFIWordSpec spec;
uint32_t offset; /* point to the exact register / stack offset depending on spec. */
uint32_t offset2; /* for reference passing apis (windows), use to allocate reference */
} JanetFFIMapping;
typedef enum {
JANET_FFI_CC_NONE,
JANET_FFI_CC_SYSV_64,
JANET_FFI_CC_WIN_64
} JanetFFICallingConvention;
#ifdef JANET_FFI_WIN64_ENABLED
#define JANET_FFI_CC_DEFAULT JANET_FFI_CC_WIN_64
#elif defined(JANET_FFI_SYSV64_ENABLED)
#define JANET_FFI_CC_DEFAULT JANET_FFI_CC_SYSV_64
#else
#define JANET_FFI_CC_DEFAULT JANET_FFI_CC_NONE
#endif
#define JANET_FFI_MAX_ARGS 32
typedef struct {
uint32_t frame_size;
uint32_t arg_count;
uint32_t word_count;
uint32_t variant;
uint32_t stack_count;
JanetFFICallingConvention cc;
JanetFFIMapping ret;
JanetFFIMapping args[JANET_FFI_MAX_ARGS];
} JanetFFISignature;
int signature_mark(void *p, size_t s) {
(void) s;
JanetFFISignature *sig = p;
for (uint32_t i = 0; i < sig->arg_count; i++) {
JanetFFIType t = sig->args[i].type;
if (t.prim == JANET_FFI_TYPE_STRUCT) {
janet_mark(janet_wrap_abstract(t.st));
}
}
return 0;
}
static const JanetAbstractType janet_signature_type = {
"core/ffi-signature",
NULL,
signature_mark,
JANET_ATEND_GCMARK
};
int struct_mark(void *p, size_t s) {
(void) s;
JanetFFIStruct *st = p;
for (uint32_t i = 0; i < st->field_count; i++) {
JanetFFIType t = st->fields[i].type;
if (t.prim == JANET_FFI_TYPE_STRUCT) {
janet_mark(janet_wrap_abstract(t.st));
}
}
return 0;
}
static const JanetAbstractType janet_struct_type = {
"core/ffi-struct",
NULL,
struct_mark,
JANET_ATEND_GCMARK
};
typedef struct {
Clib clib;
int closed;
} JanetAbstractNative;
static const JanetAbstractType janet_native_type = {
"core/ffi-native",
JANET_ATEND_NAME
};
static JanetFFIType prim_type(JanetFFIPrimType pt) {
JanetFFIType t;
t.prim = pt;
t.st = NULL;
return t;
}
static size_t type_size(JanetFFIType t) {
if (t.prim == JANET_FFI_TYPE_STRUCT) {
return t.st->size;
} else {
return janet_ffi_type_info[t.prim].size;
}
}
static size_t type_align(JanetFFIType t) {
if (t.prim == JANET_FFI_TYPE_STRUCT) {
return t.st->align;
} else {
return janet_ffi_type_info[t.prim].align;
}
}
static JanetFFICallingConvention decode_ffi_cc(const uint8_t *name) {
if (!janet_cstrcmp(name, "none")) return JANET_FFI_CC_NONE;
#ifdef JANET_FFI_WIN64_ENABLED
if (!janet_cstrcmp(name, "win64")) return JANET_FFI_CC_WIN_64;
#endif
#ifdef JANET_FFI_SYSV64_ENABLED
if (!janet_cstrcmp(name, "sysv64")) return JANET_FFI_CC_SYSV_64;
#endif
if (!janet_cstrcmp(name, "default")) return JANET_FFI_CC_DEFAULT;
janet_panicf("unknown calling convention %s", name);
}
static JanetFFIPrimType decode_ffi_prim(const uint8_t *name) {
if (!janet_cstrcmp(name, "void")) return JANET_FFI_TYPE_VOID;
if (!janet_cstrcmp(name, "bool")) return JANET_FFI_TYPE_BOOL;
if (!janet_cstrcmp(name, "ptr")) return JANET_FFI_TYPE_PTR;
if (!janet_cstrcmp(name, "float")) return JANET_FFI_TYPE_FLOAT;
if (!janet_cstrcmp(name, "double")) return JANET_FFI_TYPE_DOUBLE;
if (!janet_cstrcmp(name, "int8")) return JANET_FFI_TYPE_INT8;
if (!janet_cstrcmp(name, "uint8")) return JANET_FFI_TYPE_UINT8;
if (!janet_cstrcmp(name, "int16")) return JANET_FFI_TYPE_INT16;
if (!janet_cstrcmp(name, "uint16")) return JANET_FFI_TYPE_UINT16;
if (!janet_cstrcmp(name, "int32")) return JANET_FFI_TYPE_INT32;
if (!janet_cstrcmp(name, "uint32")) return JANET_FFI_TYPE_UINT32;
if (!janet_cstrcmp(name, "int64")) return JANET_FFI_TYPE_INT64;
if (!janet_cstrcmp(name, "uint64")) return JANET_FFI_TYPE_UINT64;
#ifdef JANET_64
if (!janet_cstrcmp(name, "size")) return JANET_FFI_TYPE_UINT64;
if (!janet_cstrcmp(name, "ssize")) return JANET_FFI_TYPE_INT64;
#else
if (!janet_cstrcmp(name, "size")) return JANET_FFI_TYPE_UINT32;
if (!janet_cstrcmp(name, "ssize")) return JANET_FFI_TYPE_INT32;
#endif
/* aliases */
if (!janet_cstrcmp(name, "r32")) return JANET_FFI_TYPE_FLOAT;
if (!janet_cstrcmp(name, "r64")) return JANET_FFI_TYPE_DOUBLE;
if (!janet_cstrcmp(name, "s8")) return JANET_FFI_TYPE_INT8;
if (!janet_cstrcmp(name, "u8")) return JANET_FFI_TYPE_UINT8;
if (!janet_cstrcmp(name, "s16")) return JANET_FFI_TYPE_INT16;
if (!janet_cstrcmp(name, "u16")) return JANET_FFI_TYPE_UINT16;
if (!janet_cstrcmp(name, "s32")) return JANET_FFI_TYPE_INT32;
if (!janet_cstrcmp(name, "u32")) return JANET_FFI_TYPE_UINT32;
if (!janet_cstrcmp(name, "s64")) return JANET_FFI_TYPE_INT64;
if (!janet_cstrcmp(name, "u64")) return JANET_FFI_TYPE_UINT64;
if (!janet_cstrcmp(name, "char")) return JANET_FFI_TYPE_INT8;
if (!janet_cstrcmp(name, "short")) return JANET_FFI_TYPE_INT16;
if (!janet_cstrcmp(name, "int")) return JANET_FFI_TYPE_INT32;
if (!janet_cstrcmp(name, "long")) return JANET_FFI_TYPE_INT64;
if (!janet_cstrcmp(name, "byte")) return JANET_FFI_TYPE_UINT8;
if (!janet_cstrcmp(name, "ushort")) return JANET_FFI_TYPE_UINT16;
if (!janet_cstrcmp(name, "uint")) return JANET_FFI_TYPE_UINT32;
if (!janet_cstrcmp(name, "ulong")) return JANET_FFI_TYPE_UINT64;
janet_panicf("unknown machine type %s", name);
}
/* A common callback function signature. To avoid runtime code generation, which is prohibited
* on many platforms, often buggy (see libffi), and generally complicated, instead provide
* a single (or small set of commonly used function signatures). All callbacks should
* eventually call this. */
void janet_ffi_trampoline(void *ctx, void *userdata) {
if (NULL == userdata) {
/* Userdata not set. */
janet_eprintf("no userdata found for janet callback");
return;
}
Janet context = janet_wrap_pointer(ctx);
JanetFunction *fun = userdata;
janet_call(fun, 1, &context);
}
static JanetFFIType decode_ffi_type(Janet x);
static JanetFFIStruct *build_struct_type(int32_t argc, const Janet *argv) {
/* Use :pack to indicate a single packed struct member and :pack-all
* to pack the remaining members */
int32_t member_count = argc;
int all_packed = 0;
for (int32_t i = 0; i < argc; i++) {
if (janet_keyeq(argv[i], "pack")) {
member_count--;
} else if (janet_keyeq(argv[i], "pack-all")) {
member_count--;
all_packed = 1;
}
}
JanetFFIStruct *st = janet_abstract(&janet_struct_type,
sizeof(JanetFFIStruct) + argc * sizeof(JanetFFIStructMember));
st->field_count = member_count;
st->size = 0;
st->align = 1;
if (argc == 0) {
janet_panic("invalid empty struct");
}
uint32_t is_aligned = 1;
int32_t i = 0;
for (int32_t j = 0; j < argc; j++) {
int pack_one = 0;
if (janet_keyeq(argv[j], "pack") || janet_keyeq(argv[j], "pack-all")) {
pack_one = 1;
j++;
}
st->fields[i].type = decode_ffi_type(argv[j]);
size_t el_size = type_size(st->fields[i].type);
size_t el_align = type_align(st->fields[i].type);
if (all_packed || pack_one) {
if (st->size % el_align != 0) is_aligned = 0;
st->fields[i].offset = st->size;
st->size += el_size;
} else {
if (el_align > st->align) st->align = el_align;
st->fields[i].offset = (((st->size + el_align - 1) / el_align) * el_align);
st->size = el_size + st->fields[i].offset;
}
i++;
}
st->is_aligned = is_aligned;
return st;
}
static JanetFFIType decode_ffi_type(Janet x) {
if (janet_checktype(x, JANET_KEYWORD)) {
return prim_type(decode_ffi_prim(janet_unwrap_keyword(x)));
}
JanetFFIType ret;
ret.prim = JANET_FFI_TYPE_STRUCT;
if (janet_checkabstract(x, &janet_struct_type)) {
ret.st = janet_unwrap_abstract(x);
return ret;
}
int32_t len;
const Janet *els;
if (janet_indexed_view(x, &els, &len)) {
ret.st = build_struct_type(len, els);
return ret;
} else {
janet_panicf("bad native type %v", x);
}
}
JANET_CORE_FN(cfun_ffi_struct,
"(ffi/struct & types)",
"Create a struct type descriptor that can be used to pass structs into native functions. ") {
janet_arity(argc, 1, -1);
return janet_wrap_abstract(build_struct_type(argc, argv));
}
static void *janet_ffi_getpointer(const Janet *argv, int32_t n) {
switch (janet_type(argv[n])) {
default:
janet_panicf("bad slot #%d, expected ffi pointer convertable type, got %v", argv[n]);
case JANET_POINTER:
case JANET_STRING:
case JANET_KEYWORD:
case JANET_SYMBOL:
case JANET_ABSTRACT:
return janet_unwrap_pointer(argv[n]);
case JANET_BUFFER:
return janet_unwrap_buffer(argv[n])->data;
case JANET_FUNCTION:
/* Users may pass in a function. Any function passed is almost certainly
* being used as a callback, so we add it to the root set. */
janet_gcroot(argv[n]);
return janet_unwrap_pointer(argv[n]);
case JANET_NIL:
return NULL;
}
}
/* Write a value given by some Janet values and an FFI type as it would appear in memory.
* The alignment and space available is assumed to already be sufficient */
static void janet_ffi_write_one(void *to, const Janet *argv, int32_t n, JanetFFIType type, int recur) {
if (recur == 0) janet_panic("recursion too deep");
switch (type.prim) {
case JANET_FFI_TYPE_VOID:
if (!janet_checktype(argv[n], JANET_NIL)) {
janet_panicf("expected nil, got %v", argv[n]);
}
break;
case JANET_FFI_TYPE_STRUCT: {
JanetView els = janet_getindexed(argv, n);
JanetFFIStruct *st = type.st;
if ((uint32_t) els.len != st->field_count) {
janet_panicf("wrong number of fields in struct, expected %d, got %d",
(int32_t) st->field_count, els.len);
}
for (int32_t i = 0; i < els.len; i++) {
JanetFFIType tp = st->fields[i].type;
janet_ffi_write_one(to + st->fields[i].offset, els.items, i, tp, recur - 1);
}
}
break;
case JANET_FFI_TYPE_DOUBLE:
((double *)(to))[0] = janet_getnumber(argv, n);
break;
case JANET_FFI_TYPE_FLOAT:
((float *)(to))[0] = janet_getnumber(argv, n);
break;
case JANET_FFI_TYPE_PTR:
((void **)(to))[0] = janet_ffi_getpointer(argv, n);
break;
case JANET_FFI_TYPE_BOOL:
((bool *)(to))[0] = janet_getboolean(argv, n);
break;
case JANET_FFI_TYPE_INT8:
((int8_t *)(to))[0] = janet_getinteger(argv, n);
break;
case JANET_FFI_TYPE_INT16:
((int16_t *)(to))[0] = janet_getinteger(argv, n);
break;
case JANET_FFI_TYPE_INT32:
((int32_t *)(to))[0] = janet_getinteger(argv, n);
break;
case JANET_FFI_TYPE_INT64:
((int64_t *)(to))[0] = janet_getinteger64(argv, n);
break;
case JANET_FFI_TYPE_UINT8:
((uint8_t *)(to))[0] = janet_getuinteger64(argv, n);
break;
case JANET_FFI_TYPE_UINT16:
((uint16_t *)(to))[0] = janet_getuinteger64(argv, n);
break;
case JANET_FFI_TYPE_UINT32:
((uint32_t *)(to))[0] = janet_getuinteger64(argv, n);
break;
case JANET_FFI_TYPE_UINT64:
((uint64_t *)(to))[0] = janet_getuinteger64(argv, n);
break;
}
}
/* Read a value from memory and construct a Janet data structure that can be passed back into
* the interpreter. This should be the inverse to janet_ffi_write_one. It is assumed that the
* size of the data is correct. */
static Janet janet_ffi_read_one(const uint8_t *from, JanetFFIType type, int recur) {
if (recur == 0) janet_panic("recursion too deep");
switch (type.prim) {
default:
case JANET_FFI_TYPE_VOID:
return janet_wrap_nil();
case JANET_FFI_TYPE_STRUCT: {
JanetFFIStruct *st = type.st;
Janet *tup = janet_tuple_begin(st->field_count);
for (uint32_t i = 0; i < st->field_count; i++) {
JanetFFIType tp = st->fields[i].type;
tup[i] = janet_ffi_read_one(from + st->fields[i].offset, tp, recur - 1);
}
return janet_wrap_tuple(janet_tuple_end(tup));
}
case JANET_FFI_TYPE_DOUBLE:
return janet_wrap_number(((double *)(from))[0]);
case JANET_FFI_TYPE_FLOAT:
return janet_wrap_number(((float *)(from))[0]);
case JANET_FFI_TYPE_PTR:
return janet_wrap_pointer(((void **)(from))[0]);
case JANET_FFI_TYPE_BOOL:
return janet_wrap_boolean(((bool *)(from))[0]);
case JANET_FFI_TYPE_INT8:
return janet_wrap_number(((int8_t *)(from))[0]);
case JANET_FFI_TYPE_INT16:
return janet_wrap_number(((int16_t *)(from))[0]);
case JANET_FFI_TYPE_INT32:
return janet_wrap_number(((int32_t *)(from))[0]);
case JANET_FFI_TYPE_UINT8:
return janet_wrap_number(((uint8_t *)(from))[0]);
case JANET_FFI_TYPE_UINT16:
return janet_wrap_number(((uint16_t *)(from))[0]);
case JANET_FFI_TYPE_UINT32:
return janet_wrap_number(((uint32_t *)(from))[0]);
#ifdef JANET_INT_TYPES
case JANET_FFI_TYPE_INT64:
return janet_wrap_s64(((int64_t *)(from))[0]);
case JANET_FFI_TYPE_UINT64:
return janet_wrap_u64(((uint64_t *)(from))[0]);
#else
case JANET_FFI_TYPE_INT64:
return janet_wrap_number(((int64_t *)(from))[0]);
case JANET_FFI_TYPE_UINT64:
return janet_wrap_number(((uint64_t *)(from))[0]);
#endif
}
}
static JanetFFIMapping void_mapping(void) {
JanetFFIMapping m;
m.type = prim_type(JANET_FFI_TYPE_VOID);
m.spec = JANET_SYSV64_NO_CLASS;
m.offset = 0;
return m;
}
#ifdef JANET_FFI_SYSV64_ENABLED
/* AMD64 ABI Draft 0.99.7 November 17, 2014 15:08
* See section 3.2.3 Parameter Passing */
static JanetFFIWordSpec sysv64_classify(JanetFFIType type) {
switch (type.prim) {
case JANET_FFI_TYPE_PTR:
case JANET_FFI_TYPE_BOOL:
case JANET_FFI_TYPE_INT8:
case JANET_FFI_TYPE_INT16:
case JANET_FFI_TYPE_INT32:
case JANET_FFI_TYPE_INT64:
case JANET_FFI_TYPE_UINT8:
case JANET_FFI_TYPE_UINT16:
case JANET_FFI_TYPE_UINT32:
case JANET_FFI_TYPE_UINT64:
return JANET_SYSV64_INTEGER;
case JANET_FFI_TYPE_DOUBLE:
case JANET_FFI_TYPE_FLOAT:
return JANET_SYSV64_SSE;
case JANET_FFI_TYPE_STRUCT: {
JanetFFIStruct *st = type.st;
if (st->size > 16) return JANET_SYSV64_MEMORY;
if (!st->is_aligned) return JANET_SYSV64_MEMORY;
JanetFFIWordSpec clazz = JANET_SYSV64_NO_CLASS;
for (uint32_t i = 0; i < st->field_count; i++) {
JanetFFIWordSpec next_class = sysv64_classify(st->fields[i].type);
if (next_class != clazz) {
if (clazz == JANET_SYSV64_NO_CLASS) {
clazz = next_class;
} else if (clazz == JANET_SYSV64_MEMORY || next_class == JANET_SYSV64_MEMORY) {
clazz = JANET_SYSV64_MEMORY;
} else if (clazz == JANET_SYSV64_INTEGER || next_class == JANET_SYSV64_INTEGER) {
clazz = JANET_SYSV64_INTEGER;
} else if (next_class == JANET_SYSV64_X87 || next_class == JANET_SYSV64_X87UP
|| next_class == JANET_SYSV64_COMPLEX_X87) {
clazz = JANET_SYSV64_MEMORY;
} else {
clazz = JANET_SYSV64_SSE;
}
}
}
return clazz;
}
case JANET_FFI_TYPE_VOID:
return JANET_SYSV64_NO_CLASS;
default:
janet_panic("nyi");
return JANET_SYSV64_NO_CLASS;
}
}
#endif
JANET_CORE_FN(cfun_ffi_signature,
"(ffi/signature calling-convention ret-type & arg-types)",
"Create a function signature object that can be used to make calls "
"with raw function pointers.") {
janet_arity(argc, 2, -1);
uint32_t frame_size = 0;
uint32_t variant = 0;
uint32_t arg_count = argc - 2;
uint32_t stack_count = 0;
JanetFFICallingConvention cc = decode_ffi_cc(janet_getkeyword(argv, 0));
JanetFFIType ret_type = decode_ffi_type(argv[1]);
JanetFFIMapping ret = {
ret_type,
JANET_SYSV64_NO_CLASS,
0,
0
};
JanetFFIMapping mappings[JANET_FFI_MAX_ARGS];
for (int i = 0; i < JANET_FFI_MAX_ARGS; i++) mappings[i] = void_mapping();
switch (cc) {
default:
case JANET_FFI_CC_NONE: {
/* Even if unsupported, we can check that the signature is valid
* and error at runtime */
for (uint32_t i = 0; i < arg_count; i++) {
decode_ffi_type(argv[i + 2]);
}
}
break;
#ifdef JANET_FFI_WIN64_ENABLED
case JANET_FFI_CC_WIN_64: {
size_t ret_size = type_size(ret.type);
size_t ref_stack_count = 0;
ret.spec = JANET_WIN64_REGISTER;
uint32_t next_register = 0;
if (ret_size != 1 && ret_size != 2 && ret_size != 4 && ret_size != 8) {
ret.spec = JANET_WIN64_REGISTER_REF;
next_register++;
} else if (ret.type.prim == JANET_FFI_TYPE_FLOAT ||
ret.type.prim == JANET_FFI_TYPE_DOUBLE) {
variant += 16;
}
for (uint32_t i = 0; i < arg_count; i++) {
mappings[i].type = decode_ffi_type(argv[i + 2]);
size_t el_size = type_size(mappings[i].type);
int is_register_sized = (el_size == 1 || el_size == 2 || el_size == 4 || el_size == 8);
if (next_register < 4) {
mappings[i].offset = next_register++;
if (is_register_sized) {
mappings[i].spec = JANET_WIN64_REGISTER;
/* Select variant based on position of floating point arguments */
if (mappings[i].type.prim == JANET_FFI_TYPE_FLOAT ||
mappings[i].type.prim == JANET_FFI_TYPE_DOUBLE) {
variant += 1 << next_register;
}
} else {
mappings[i].spec = JANET_WIN64_REGISTER_REF;
mappings[i].offset2 = ref_stack_count;
ref_stack_count += (el_size + 15) / 16;
}
} else {
if (is_register_sized) {
mappings[i].spec = JANET_WIN64_STACK;
mappings[i].offset = stack_count;
stack_count++;
} else {
mappings[i].spec = JANET_WIN64_STACK_REF;
mappings[i].offset = stack_count;
stack_count++;
mappings[i].offset2 = ref_stack_count;
ref_stack_count += (el_size + 15) / 16;
}
}
}
/* Take into account reference arguments and align to 16 bytes just in case */
stack_count += 2 * ref_stack_count;
if (stack_count & 1) {
stack_count++;
}
/* Invert stack
* Offsets are in units of 8-bytes */
for (uint32_t i = 0; i < arg_count; i++) {
uint32_t old_offset = mappings[i].offset;
if (mappings[i].spec == JANET_WIN64_STACK) {
mappings[i].offset = stack_count - 1 - old_offset;
} else if (mappings[i].spec == JANET_WIN64_STACK_REF) {
mappings[i].offset = stack_count - 1 - old_offset;
}
if (mappings[i].spec == JANET_WIN64_STACK_REF || mappings[i].spec == JANET_WIN64_REGISTER_REF) {
/* Align size to 16 bytes */
size_t size = (type_size(mappings[i].type) + 15) & ~0xFUL;
mappings[i].offset2 = stack_count - mappings[i].offset2 - (size / 8);
}
}
}
break;
#endif
#ifdef JANET_FFI_SYSV64_ENABLED
case JANET_FFI_CC_SYSV_64: {
JanetFFIWordSpec ret_spec = sysv64_classify(ret.type);
ret.spec = ret_spec;
if (ret_spec == JANET_SYSV64_SSE) variant = 1;
/* Spill register overflow to memory */
uint32_t next_register = 0;
uint32_t next_fp_register = 0;
const uint32_t max_regs = 6;
const uint32_t max_fp_regs = 8;
if (ret_spec == JANET_SYSV64_MEMORY) {
/* First integer reg is pointer. */
next_register = 1;
}
for (uint32_t i = 0; i < arg_count; i++) {
mappings[i].type = decode_ffi_type(argv[i + 2]);
mappings[i].offset = 0;
mappings[i].spec = sysv64_classify(mappings[i].type);
if (mappings[i].spec == JANET_SYSV64_NO_CLASS) {
janet_panic("unexpected void parameter");
}
size_t el_size = (type_size(mappings[i].type) + 7) / 8;
switch (mappings[i].spec) {
default:
janet_panicf("nyi: %d", mappings[i].spec);
case JANET_SYSV64_INTEGER: {
if (next_register < max_regs) {
mappings[i].offset = next_register++;
} else {
mappings[i].spec = JANET_SYSV64_MEMORY;
mappings[i].offset = stack_count;
stack_count += el_size;
}
break;
}
case JANET_SYSV64_SSE: {
if (next_fp_register < max_fp_regs) {
mappings[i].offset = next_fp_register++;
} else {
mappings[i].spec = JANET_SYSV64_MEMORY;
mappings[i].offset = stack_count;
stack_count += el_size;
}
break;
}
case JANET_SYSV64_MEMORY: {
mappings[i].offset = stack_count;
stack_count += el_size;
}
}
}
/* Invert stack */
for (uint32_t i = 0; i < arg_count; i++) {
if (mappings[i].spec == JANET_SYSV64_MEMORY) {
uint32_t old_offset = mappings[i].offset;
size_t el_size = type_size(mappings[i].type);
mappings[i].offset = stack_count - ((el_size + 7) / 8) - old_offset;
}
}
}
break;
#endif
}
/* Create signature abstract value */
JanetFFISignature *abst = janet_abstract(&janet_signature_type, sizeof(JanetFFISignature));
abst->frame_size = frame_size;
abst->cc = cc;
abst->ret = ret;
abst->arg_count = arg_count;
abst->variant = variant;
abst->stack_count = stack_count;
memcpy(abst->args, mappings, sizeof(JanetFFIMapping) * JANET_FFI_MAX_ARGS);
return janet_wrap_abstract(abst);
}
#ifdef JANET_FFI_SYSV64_ENABLED
static void janet_ffi_sysv64_standard_callback(void *ctx, void *userdata) {
janet_ffi_trampoline(ctx, userdata);
}
/* Functions that set all argument registers. Two variants - one to read rax and rdx returns, another
* to read xmm0 and xmm1 returns. */
typedef struct {
uint64_t x;
uint64_t y;
} sysv64_int_return;
typedef struct {
double x;
double y;
} sysv64_sse_return;
typedef sysv64_int_return janet_sysv64_variant_1(uint64_t a, uint64_t b, uint64_t c, uint64_t d, uint64_t e, uint64_t f,
double r1, double r2, double r3, double r4, double r5, double r6, double r7, double r8);
typedef sysv64_sse_return janet_sysv64_variant_2(uint64_t a, uint64_t b, uint64_t c, uint64_t d, uint64_t e, uint64_t f,
double r1, double r2, double r3, double r4, double r5, double r6, double r7, double r8);
static Janet janet_ffi_sysv64(JanetFFISignature *signature, void *function_pointer, const Janet *argv) {
sysv64_int_return int_return;
sysv64_sse_return sse_return;
uint64_t regs[6];
double fp_regs[8];
JanetFFIWordSpec ret_spec = signature->ret.spec;
void *ret_mem = &int_return;
if (ret_spec == JANET_SYSV64_MEMORY) {
ret_mem = alloca(type_size(signature->ret.type));
regs[0] = (uint64_t) ret_mem;
} else if (ret_spec == JANET_SYSV64_SSE) {
ret_mem = &sse_return;
}
uint64_t *stack = alloca(sizeof(uint64_t) * signature->stack_count);
for (uint32_t i = 0; i < signature->arg_count; i++) {
uint64_t *to;
int32_t n = i + 2;
JanetFFIMapping arg = signature->args[i];
switch (arg.spec) {
default:
janet_panic("nyi");
case JANET_SYSV64_INTEGER:
to = regs + arg.offset;
break;
case JANET_SYSV64_SSE:
to = (uint64_t *)(fp_regs + arg.offset);
break;
case JANET_SYSV64_MEMORY:
to = stack + arg.offset;
break;
}
janet_ffi_write_one(to, argv, n, arg.type, JANET_FFI_MAX_RECUR);
}
if (signature->variant) {
sse_return = ((janet_sysv64_variant_2 *)(function_pointer))(
regs[0], regs[1], regs[2], regs[3], regs[4], regs[5],
fp_regs[0], fp_regs[1], fp_regs[2], fp_regs[3],
fp_regs[4], fp_regs[5], fp_regs[6], fp_regs[7]);
} else {
int_return = ((janet_sysv64_variant_1 *)(function_pointer))(
regs[0], regs[1], regs[2], regs[3], regs[4], regs[5],
fp_regs[0], fp_regs[1], fp_regs[2], fp_regs[3],
fp_regs[4], fp_regs[5], fp_regs[6], fp_regs[7]);
}
return janet_ffi_read_one(ret_mem, signature->ret.type, JANET_FFI_MAX_RECUR);
}
#endif
#ifdef JANET_FFI_WIN64_ENABLED
static void janet_ffi_win64_standard_callback(void *ctx, void *userdata) {
janet_ffi_trampoline(ctx, userdata);
}
/* Variants that allow setting all required registers for 64 bit windows calling convention.
* win64 calling convention has up to 4 arguments on registers, and one register for returns.
* Each register can either be an integer or floating point register, resulting in
* 2^5 = 32 variants. Unlike sysv, there are no function signatures that will fill
* all of the possible registers which is why we have so many variants. If you were using
* assembly, you could manually fill all of the registers and only have a single variant.
* And msvc does not support inline assembly on 64 bit targets, so yeah, we have this hackery. */
typedef uint64_t (win64_variant_i_iiii)(uint64_t, uint64_t, uint64_t, uint64_t);
typedef uint64_t (win64_variant_i_iiif)(uint64_t, uint64_t, uint64_t, double);
typedef uint64_t (win64_variant_i_iifi)(uint64_t, uint64_t, double, uint64_t);
typedef uint64_t (win64_variant_i_iiff)(uint64_t, uint64_t, double, double);
typedef uint64_t (win64_variant_i_ifii)(uint64_t, double, uint64_t, uint64_t);
typedef uint64_t (win64_variant_i_ifif)(uint64_t, double, uint64_t, double);
typedef uint64_t (win64_variant_i_iffi)(uint64_t, double, double, uint64_t);
typedef uint64_t (win64_variant_i_ifff)(uint64_t, double, double, double);
typedef uint64_t (win64_variant_i_fiii)(double, uint64_t, uint64_t, uint64_t);
typedef uint64_t (win64_variant_i_fiif)(double, uint64_t, uint64_t, double);
typedef uint64_t (win64_variant_i_fifi)(double, uint64_t, double, uint64_t);
typedef uint64_t (win64_variant_i_fiff)(double, uint64_t, double, double);
typedef uint64_t (win64_variant_i_ffii)(double, double, uint64_t, uint64_t);
typedef uint64_t (win64_variant_i_ffif)(double, double, uint64_t, double);
typedef uint64_t (win64_variant_i_fffi)(double, double, double, uint64_t);
typedef uint64_t (win64_variant_i_ffff)(double, double, double, double);
typedef double (win64_variant_f_iiii)(uint64_t, uint64_t, uint64_t, uint64_t);
typedef double (win64_variant_f_iiif)(uint64_t, uint64_t, uint64_t, double);
typedef double (win64_variant_f_iifi)(uint64_t, uint64_t, double, uint64_t);
typedef double (win64_variant_f_iiff)(uint64_t, uint64_t, double, double);
typedef double (win64_variant_f_ifii)(uint64_t, double, uint64_t, uint64_t);
typedef double (win64_variant_f_ifif)(uint64_t, double, uint64_t, double);
typedef double (win64_variant_f_iffi)(uint64_t, double, double, uint64_t);
typedef double (win64_variant_f_ifff)(uint64_t, double, double, double);
typedef double (win64_variant_f_fiii)(double, uint64_t, uint64_t, uint64_t);
typedef double (win64_variant_f_fiif)(double, uint64_t, uint64_t, double);
typedef double (win64_variant_f_fifi)(double, uint64_t, double, uint64_t);
typedef double (win64_variant_f_fiff)(double, uint64_t, double, double);
typedef double (win64_variant_f_ffii)(double, double, uint64_t, uint64_t);
typedef double (win64_variant_f_ffif)(double, double, uint64_t, double);
typedef double (win64_variant_f_fffi)(double, double, double, uint64_t);
typedef double (win64_variant_f_ffff)(double, double, double, double);
static Janet janet_ffi_win64(JanetFFISignature *signature, void *function_pointer, const Janet *argv) {
union {
uint64_t integer;
double real;
} regs[4];
union {
uint64_t integer;
double real;
} ret_reg;
JanetFFIWordSpec ret_spec = signature->ret.spec;
void *ret_mem = &ret_reg.integer;
if (ret_spec == JANET_WIN64_STACK) {
ret_mem = alloca(type_size(signature->ret.type));
regs[0].integer = (uint64_t) ret_mem;
}
uint64_t *stack = alloca(signature->stack_count * 8);
for (uint32_t i = 0; i < signature->arg_count; i++) {
int32_t n = i + 2;
JanetFFIMapping arg = signature->args[i];
if (arg.spec == JANET_WIN64_STACK) {
janet_ffi_write_one(stack + arg.offset, argv, n, arg.type, JANET_FFI_MAX_RECUR);
} else if (arg.spec == JANET_WIN64_STACK_REF) {
uint8_t *ptr = (uint8_t *)(stack + args.offset2);
janet_ffi_write_one(ptr, argv, n, arg.type, JANET_FFI_MAX_RECUR);
stack[args.offset] = (uint64_t) ptr;
} else if (arg.spec == JANET_WIN64_REGISTER_REF) {
uint8_t *ptr = (uint8_t *)(stack + args.offset2);
janet_ffi_write_one(ptr, argv, n, arg.type, JANET_FFI_MAX_RECUR);
regs[args.offset].integer = (uint64_t) ptr;
} else {
janet_ffi_write_one((uint8_t *) &regs[arg.offset].integer, argv, n, arg.type, JANET_FFI_MAX_RECUR);
}
}
/* the seasoned programmer who cut their teeth on assembly is probably quietly shaking their head by now... */
switch (signature->variant) {
default:
janet_panic("unknown variant");
case 0:
ret_reg.integer = ((win64_variant_i_iiii *) function_pointer)(regs[0].integer, regs[1].integer, regs[2].integer, regs[3].integer);
break;
case 1:
ret_reg.integer = ((win64_variant_i_iiif *) function_pointer)(regs[0].integer, regs[1].integer, regs[2].integer, regs[3].real);
break;
case 2:
ret_reg.integer = ((win64_variant_i_iifi *) function_pointer)(regs[0].integer, regs[1].integer, regs[2].real, regs[3].integer);
break;
case 3:
ret_reg.integer = ((win64_variant_i_iiff *) function_pointer)(regs[0].integer, regs[1].integer, regs[2].real, regs[3].real);
break;
case 4:
ret_reg.integer = ((win64_variant_i_ifii *) function_pointer)(regs[0].integer, regs[1].real, regs[2].integer, regs[3].integer);
break;
case 5:
ret_reg.integer = ((win64_variant_i_ifif *) function_pointer)(regs[0].integer, regs[1].real, regs[2].integer, regs[3].real);
break;
case 6:
ret_reg.integer = ((win64_variant_i_iffi *) function_pointer)(regs[0].integer, regs[1].real, regs[2].real, regs[3].integer);
break;
case 7:
ret_reg.integer = ((win64_variant_i_ifff *) function_pointer)(regs[0].integer, regs[1].real, regs[2].real, regs[3].real);
break;
case 8:
ret_reg.integer = ((win64_variant_i_fiii *) function_pointer)(regs[0].real, regs[1].integer, regs[2].integer, regs[3].integer);
break;
case 9:
ret_reg.integer = ((win64_variant_i_fiif *) function_pointer)(regs[0].real, regs[1].integer, regs[2].integer, regs[3].real);
break;
case 10:
ret_reg.integer = ((win64_variant_i_fifi *) function_pointer)(regs[0].real, regs[1].integer, regs[2].real, regs[3].integer);
break;
case 11:
ret_reg.integer = ((win64_variant_i_fiff *) function_pointer)(regs[0].real, regs[1].integer, regs[2].real, regs[3].real);
break;
case 12:
ret_reg.integer = ((win64_variant_i_ffii *) function_pointer)(regs[0].real, regs[1].real, regs[2].integer, regs[3].integer);
break;
case 13:
ret_reg.integer = ((win64_variant_i_ffif *) function_pointer)(regs[0].real, regs[1].real, regs[2].integer, regs[3].real);
break;
case 14:
ret_reg.integer = ((win64_variant_i_fffi *) function_pointer)(regs[0].real, regs[1].real, regs[2].real, regs[3].integer);
break;
case 15:
ret_reg.integer = ((win64_variant_i_ffff *) function_pointer)(regs[0].real, regs[1].real, regs[2].real, regs[3].real);
break;
case 16:
ret_reg.real = ((win64_variant_f_iiii *) function_pointer)(regs[0].integer, regs[1].integer, regs[2].integer, regs[3].integer);
break;
case 17:
ret_reg.real = ((win64_variant_f_iiif *) function_pointer)(regs[0].integer, regs[1].integer, regs[2].integer, regs[3].real);
break;
case 18:
ret_reg.real = ((win64_variant_f_iifi *) function_pointer)(regs[0].integer, regs[1].integer, regs[2].real, regs[3].integer);
break;
case 19:
ret_reg.real = ((win64_variant_f_iiff *) function_pointer)(regs[0].integer, regs[1].integer, regs[2].real, regs[3].real);
break;
case 20:
ret_reg.real = ((win64_variant_f_ifii *) function_pointer)(regs[0].integer, regs[1].real, regs[2].integer, regs[3].integer);
break;
case 21:
ret_reg.real = ((win64_variant_f_ifif *) function_pointer)(regs[0].integer, regs[1].real, regs[2].integer, regs[3].real);
break;
case 22:
ret_reg.real = ((win64_variant_f_iffi *) function_pointer)(regs[0].integer, regs[1].real, regs[2].real, regs[3].integer);
break;
case 23:
ret_reg.real = ((win64_variant_f_ifff *) function_pointer)(regs[0].integer, regs[1].real, regs[2].real, regs[3].real);
break;
case 24:
ret_reg.real = ((win64_variant_f_fiii *) function_pointer)(regs[0].real, regs[1].integer, regs[2].integer, regs[3].integer);
break;
case 25:
ret_reg.real = ((win64_variant_f_fiif *) function_pointer)(regs[0].real, regs[1].integer, regs[2].integer, regs[3].real);
break;
case 26:
ret_reg.real = ((win64_variant_f_fifi *) function_pointer)(regs[0].real, regs[1].integer, regs[2].real, regs[3].integer);
break;
case 27:
ret_reg.real = ((win64_variant_f_fiff *) function_pointer)(regs[0].real, regs[1].integer, regs[2].real, regs[3].real);
break;
case 28:
ret_reg.real = ((win64_variant_f_ffii *) function_pointer)(regs[0].real, regs[1].real, regs[2].integer, regs[3].integer);
break;
case 29:
ret_reg.real = ((win64_variant_f_ffif *) function_pointer)(regs[0].real, regs[1].real, regs[2].integer, regs[3].real);
break;
case 30:
ret_reg.real = ((win64_variant_f_fffi *) function_pointer)(regs[0].real, regs[1].real, regs[2].real, regs[3].integer);
break;
case 31:
ret_reg.real = ((win64_variant_f_ffff *) function_pointer)(regs[0].real, regs[1].real, regs[2].real, regs[3].real);
break;
}
return janet_ffi_read_one(ret_mem, signature->ret.type, JANET_FFI_MAX_RECUR);
}
#endif
JANET_CORE_FN(cfun_ffi_call,
"(ffi/call pointer signature & args)",
"Call a raw pointer as a function pointer. The function signature specifies "
"how Janet values in `args` are converted to native machine types.") {
janet_arity(argc, 2, -1);
void *function_pointer = janet_getpointer(argv, 0);
JanetFFISignature *signature = janet_getabstract(argv, 1, &janet_signature_type);
janet_fixarity(argc - 2, signature->arg_count);
switch (signature->cc) {
default:
case JANET_FFI_CC_NONE:
janet_panic("calling convention not supported");
#ifdef JANET_FFI_WIN64_ENABLED
case JANET_FFI_CC_WIN_64:
return janet_ffi_win64(signature, function_pointer, argv);
#endif
#ifdef JANET_FFI_SYSV64_ENABLED
case JANET_FFI_CC_SYSV_64:
return janet_ffi_sysv64(signature, function_pointer, argv);
#endif
}
}
JANET_CORE_FN(cfun_ffi_buffer_write,
"(ffi/write ffi-type data &opt buffer)",
"Append a native tyep to a buffer such as it would appear in memory. This can be used "
"to pass pointers to structs in the ffi, or send C/C++/native structs over the network "
"or to files. Returns a modifed buffer or a new buffer if one is not supplied.") {
janet_arity(argc, 2, 3);
JanetFFIType type = decode_ffi_type(argv[0]);
size_t el_size = type_size(type);
JanetBuffer *buffer = janet_optbuffer(argv, argc, 2, el_size);
janet_buffer_extra(buffer, el_size);
memset(buffer->data, 0, el_size);
janet_ffi_write_one(buffer->data, argv, 1, type, JANET_FFI_MAX_RECUR);
buffer->count += el_size;
return janet_wrap_buffer(buffer);
}
JANET_CORE_FN(cfun_ffi_buffer_read,
"(ffi/read ffi-type bytes &opt offset)",
"Parse a native struct out of a buffer and convert it to normal Janet data structures. "
"This function is the inverse of `ffi/write`. `bytes` can also be a raw pointer, although "
"this is unsafe.") {
janet_arity(argc, 2, 3);
JanetFFIType type = decode_ffi_type(argv[0]);
size_t offset = (size_t) janet_optnat(argv, argc, 2, 0);
if (janet_checktype(argv[1], JANET_POINTER)) {
uint8_t *ptr = janet_unwrap_pointer(argv[1]);
return janet_ffi_read_one(ptr + offset, type, JANET_FFI_MAX_RECUR);
} else {
size_t el_size = type_size(type);
JanetByteView bytes = janet_getbytes(argv, 1);
if ((size_t) bytes.len < offset + el_size) janet_panic("read out of range");
return janet_ffi_read_one(bytes.bytes + offset, type, JANET_FFI_MAX_RECUR);
}
}
JANET_CORE_FN(cfun_ffi_get_callback_trampoline,
"(ffi/trampoline cc)",
"Get a native function pointer that can be used as a callback and passed to C libraries. "
"This callback trampoline has the signature `void trampoline(void *ctx, void *userdata)` in "
"the given calling convention. This is the only function signature supported. "
"It is up to the programmer to ensure that the `userdata` argument contains a janet function "
"the will be called with one argument, `ctx` which is an opaque pointer. This pointer can "
"be further inspected with `ffi/read`.") {
janet_arity(argc, 0, 1);
JanetFFICallingConvention cc = JANET_FFI_CC_DEFAULT;
if (argc >= 1) cc = decode_ffi_cc(janet_getkeyword(argv, 0));
switch (cc) {
default:
case JANET_FFI_CC_NONE:
janet_panic("calling convention not supported");
#ifdef JANET_FFI_WIN64_ENABLED
case JANET_FFI_CC_WIN_64:
return janet_wrap_pointer(janet_ffi_win64_standard_callback);
#endif
#ifdef JANET_FFI_SYSV64_ENABLED
case JANET_FFI_CC_SYSV_64:
return janet_wrap_pointer(janet_ffi_sysv64_standard_callback);
#endif
}
}
JANET_CORE_FN(janet_core_raw_native,
"(ffi/native &opt path)",
"Load a shared object or dll from the given path, and do not extract"
" or run any code from it. This is different than `native`, which will "
"run initialization code to get a module table. If `path` is nil, opens the current running binary. "
"Returns a `core/native`.") {
janet_arity(argc, 0, 1);
const char *path = janet_optcstring(argv, argc, 0, NULL);
char *processed_name = (NULL == path) ? NULL : get_processed_name(path);
Clib lib = load_clib(processed_name);
if (NULL != path && path != processed_name) janet_free(processed_name);
if (!lib) janet_panic(error_clib());
JanetAbstractNative *anative = janet_abstract(&janet_native_type, sizeof(JanetAbstractNative));
anative->clib = lib;
anative->closed = 0;
return janet_wrap_abstract(anative);
}
JANET_CORE_FN(janet_core_native_lookup,
"(ffi/lookup native symbol-name)",
"Lookup a symbol from a native object. All symbol lookups will return a raw pointer "
"if the symbol is found, else nil.") {
janet_fixarity(argc, 2);
JanetAbstractNative *anative = janet_getabstract(argv, 0, &janet_native_type);
const char *sym = janet_getcstring(argv, 1);
if (anative->closed) janet_panic("native object already closed");
void *value = symbol_clib(anative->clib, sym);
if (NULL == value) return janet_wrap_nil();
return janet_wrap_pointer(value);
}
JANET_CORE_FN(janet_core_native_close,
"(ffi/close native)",
"Free a native object. Dereferencing pointers to symbols in the object will have undefined "
"behavior after freeing.") {
janet_fixarity(argc, 1);
JanetAbstractNative *anative = janet_getabstract(argv, 0, &janet_native_type);
if (anative->closed) janet_panic("native object already closed");
anative->closed = 1;
free_clib(anative->clib);
return janet_wrap_nil();
}
void janet_lib_ffi(JanetTable *env) {
JanetRegExt ffi_cfuns[] = {
JANET_CORE_REG("ffi/native", janet_core_raw_native),
JANET_CORE_REG("ffi/lookup", janet_core_native_lookup),
JANET_CORE_REG("ffi/close", janet_core_native_close),
JANET_CORE_REG("ffi/signature", cfun_ffi_signature),
JANET_CORE_REG("ffi/call", cfun_ffi_call),
JANET_CORE_REG("ffi/struct", cfun_ffi_struct),
JANET_CORE_REG("ffi/write", cfun_ffi_buffer_write),
JANET_CORE_REG("ffi/read", cfun_ffi_buffer_read),
JANET_CORE_REG("ffi/trampoline", cfun_ffi_get_callback_trampoline),
JANET_REG_END
};
janet_core_cfuns_ext(env, NULL, ffi_cfuns);
}
#endif