/* Copyright 2008 The Android Open Source Project */ #define LOG_TAG "Binder" #include <errno.h> #include <fcntl.h> #include <inttypes.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <sys/mman.h> #include <unistd.h> #include <log/log.h> #include "binder.h" #define MAX_BIO_SIZE (1 << 30) #define TRACE 0 void bio_init_from_txn(struct binder_io *io, struct binder_transaction_data *txn); #if TRACE void hexdump(void *_data, size_t len) { unsigned char *data = _data; size_t count; for (count = 0; count < len; count++) { if ((count & 15) == 0) fprintf(stderr,"%04zu:", count); fprintf(stderr," %02x %c", *data, (*data < 32) || (*data > 126) ? '.' : *data); data++; if ((count & 15) == 15) fprintf(stderr,"\n"); } if ((count & 15) != 0) fprintf(stderr,"\n"); } void binder_dump_txn(struct binder_transaction_data *txn) { struct flat_binder_object *obj; binder_size_t *offs = (binder_size_t *)(uintptr_t)txn->data.ptr.offsets; size_t count = txn->offsets_size / sizeof(binder_size_t); fprintf(stderr," target %016"PRIx64" cookie %016"PRIx64" code %08x flags %08x\n", (uint64_t)txn->target.ptr, (uint64_t)txn->cookie, txn->code, txn->flags); fprintf(stderr," pid %8d uid %8d data %"PRIu64" offs %"PRIu64"\n", txn->sender_pid, txn->sender_euid, (uint64_t)txn->data_size, (uint64_t)txn->offsets_size); hexdump((void *)(uintptr_t)txn->data.ptr.buffer, txn->data_size); while (count--) { obj = (struct flat_binder_object *) (((char*)(uintptr_t)txn->data.ptr.buffer) + *offs++); fprintf(stderr," - type %08x flags %08x ptr %016"PRIx64" cookie %016"PRIx64"\n", obj->type, obj->flags, (uint64_t)obj->binder, (uint64_t)obj->cookie); } } #define NAME(n) case n: return #n const char *cmd_name(uint32_t cmd) { switch(cmd) { NAME(BR_NOOP); NAME(BR_TRANSACTION_COMPLETE); NAME(BR_INCREFS); NAME(BR_ACQUIRE); NAME(BR_RELEASE); NAME(BR_DECREFS); NAME(BR_TRANSACTION); NAME(BR_REPLY); NAME(BR_FAILED_REPLY); NAME(BR_DEAD_REPLY); NAME(BR_DEAD_BINDER); default: return "???"; } } #else #define hexdump(a,b) do{} while (0) #define binder_dump_txn(txn) do{} while (0) #endif #define BIO_F_SHARED 0x01 /* needs to be buffer freed */ #define BIO_F_OVERFLOW 0x02 /* ran out of space */ #define BIO_F_IOERROR 0x04 #define BIO_F_MALLOCED 0x08 /* needs to be free()'d */ struct binder_state { int fd; void *mapped; size_t mapsize; }; struct binder_state *binder_open(const char* driver, size_t mapsize) { struct binder_state *bs; struct binder_version vers; bs = malloc(sizeof(*bs)); if (!bs) { errno = ENOMEM; return NULL; } bs->fd = open(driver, O_RDWR | O_CLOEXEC); if (bs->fd < 0) { fprintf(stderr,"binder: cannot open %s (%s)\n", driver, strerror(errno)); goto fail_open; } if ((ioctl(bs->fd, BINDER_VERSION, &vers) == -1) || (vers.protocol_version != BINDER_CURRENT_PROTOCOL_VERSION)) { fprintf(stderr, "binder: kernel driver version (%d) differs from user space version (%d)\n", vers.protocol_version, BINDER_CURRENT_PROTOCOL_VERSION); goto fail_open; } bs->mapsize = mapsize; bs->mapped = mmap(NULL, mapsize, PROT_READ, MAP_PRIVATE, bs->fd, 0); if (bs->mapped == MAP_FAILED) { fprintf(stderr,"binder: cannot map device (%s)\n", strerror(errno)); goto fail_map; } return bs; fail_map: close(bs->fd); fail_open: free(bs); return NULL; } void binder_close(struct binder_state *bs) { munmap(bs->mapped, bs->mapsize); close(bs->fd); free(bs); } int binder_become_context_manager(struct binder_state *bs) { return ioctl(bs->fd, BINDER_SET_CONTEXT_MGR, 0); } int binder_write(struct binder_state *bs, void *data, size_t len) { struct binder_write_read bwr; int res; bwr.write_size = len; bwr.write_consumed = 0; bwr.write_buffer = (uintptr_t) data; bwr.read_size = 0; bwr.read_consumed = 0; bwr.read_buffer = 0; res = ioctl(bs->fd, BINDER_WRITE_READ, &bwr); if (res < 0) { fprintf(stderr,"binder_write: ioctl failed (%s)\n", strerror(errno)); } return res; } void binder_free_buffer(struct binder_state *bs, binder_uintptr_t buffer_to_free) { struct { uint32_t cmd_free; binder_uintptr_t buffer; } __attribute__((packed)) data; data.cmd_free = BC_FREE_BUFFER; data.buffer = buffer_to_free; binder_write(bs, &data, sizeof(data)); } void binder_send_reply(struct binder_state *bs, struct binder_io *reply, binder_uintptr_t buffer_to_free, int status) { struct { uint32_t cmd_free; binder_uintptr_t buffer; uint32_t cmd_reply; struct binder_transaction_data txn; } __attribute__((packed)) data; data.cmd_free = BC_FREE_BUFFER; data.buffer = buffer_to_free; data.cmd_reply = BC_REPLY; data.txn.target.ptr = 0; data.txn.cookie = 0; data.txn.code = 0; if (status) { data.txn.flags = TF_STATUS_CODE; data.txn.data_size = sizeof(int); data.txn.offsets_size = 0; data.txn.data.ptr.buffer = (uintptr_t)&status; data.txn.data.ptr.offsets = 0; } else { data.txn.flags = 0; data.txn.data_size = reply->data - reply->data0; data.txn.offsets_size = ((char*) reply->offs) - ((char*) reply->offs0); data.txn.data.ptr.buffer = (uintptr_t)reply->data0; data.txn.data.ptr.offsets = (uintptr_t)reply->offs0; } binder_write(bs, &data, sizeof(data)); } int binder_parse(struct binder_state *bs, struct binder_io *bio, uintptr_t ptr, size_t size, binder_handler func) { int r = 1; uintptr_t end = ptr + (uintptr_t) size; while (ptr < end) { uint32_t cmd = *(uint32_t *) ptr; ptr += sizeof(uint32_t); #if TRACE fprintf(stderr,"%s:\n", cmd_name(cmd)); #endif switch(cmd) { case BR_NOOP: break; case BR_TRANSACTION_COMPLETE: break; case BR_INCREFS: case BR_ACQUIRE: case BR_RELEASE: case BR_DECREFS: #if TRACE fprintf(stderr," %p, %p\n", (void *)ptr, (void *)(ptr + sizeof(void *))); #endif ptr += sizeof(struct binder_ptr_cookie); break; case BR_TRANSACTION: { struct binder_transaction_data *txn = (struct binder_transaction_data *) ptr; if ((end - ptr) < sizeof(*txn)) { ALOGE("parse: txn too small!\n"); return -1; } binder_dump_txn(txn); if (func) { unsigned rdata[256/4]; struct binder_io msg; struct binder_io reply; int res; bio_init(&reply, rdata, sizeof(rdata), 4); bio_init_from_txn(&msg, txn); res = func(bs, txn, &msg, &reply); if (txn->flags & TF_ONE_WAY) { binder_free_buffer(bs, txn->data.ptr.buffer); } else { binder_send_reply(bs, &reply, txn->data.ptr.buffer, res); } } ptr += sizeof(*txn); break; } case BR_REPLY: { struct binder_transaction_data *txn = (struct binder_transaction_data *) ptr; if ((end - ptr) < sizeof(*txn)) { ALOGE("parse: reply too small!\n"); return -1; } binder_dump_txn(txn); if (bio) { bio_init_from_txn(bio, txn); bio = 0; } else { /* todo FREE BUFFER */ } ptr += sizeof(*txn); r = 0; break; } case BR_DEAD_BINDER: { struct binder_death *death = (struct binder_death *)(uintptr_t) *(binder_uintptr_t *)ptr; ptr += sizeof(binder_uintptr_t); death->func(bs, death->ptr); break; } case BR_FAILED_REPLY: r = -1; break; case BR_DEAD_REPLY: r = -1; break; default: ALOGE("parse: OOPS %d\n", cmd); return -1; } } return r; } void binder_acquire(struct binder_state *bs, uint32_t target) { uint32_t cmd[2]; cmd[0] = BC_ACQUIRE; cmd[1] = target; binder_write(bs, cmd, sizeof(cmd)); } void binder_release(struct binder_state *bs, uint32_t target) { uint32_t cmd[2]; cmd[0] = BC_RELEASE; cmd[1] = target; binder_write(bs, cmd, sizeof(cmd)); } void binder_link_to_death(struct binder_state *bs, uint32_t target, struct binder_death *death) { struct { uint32_t cmd; struct binder_handle_cookie payload; } __attribute__((packed)) data; data.cmd = BC_REQUEST_DEATH_NOTIFICATION; data.payload.handle = target; data.payload.cookie = (uintptr_t) death; binder_write(bs, &data, sizeof(data)); } int binder_call(struct binder_state *bs, struct binder_io *msg, struct binder_io *reply, uint32_t target, uint32_t code) { int res; struct binder_write_read bwr; struct { uint32_t cmd; struct binder_transaction_data txn; } __attribute__((packed)) writebuf; unsigned readbuf[32]; if (msg->flags & BIO_F_OVERFLOW) { fprintf(stderr,"binder: txn buffer overflow\n"); goto fail; } writebuf.cmd = BC_TRANSACTION; writebuf.txn.target.handle = target; writebuf.txn.code = code; writebuf.txn.flags = 0; writebuf.txn.data_size = msg->data - msg->data0; writebuf.txn.offsets_size = ((char*) msg->offs) - ((char*) msg->offs0); writebuf.txn.data.ptr.buffer = (uintptr_t)msg->data0; writebuf.txn.data.ptr.offsets = (uintptr_t)msg->offs0; bwr.write_size = sizeof(writebuf); bwr.write_consumed = 0; bwr.write_buffer = (uintptr_t) &writebuf; hexdump(msg->data0, msg->data - msg->data0); for (;;) { bwr.read_size = sizeof(readbuf); bwr.read_consumed = 0; bwr.read_buffer = (uintptr_t) readbuf; res = ioctl(bs->fd, BINDER_WRITE_READ, &bwr); if (res < 0) { fprintf(stderr,"binder: ioctl failed (%s)\n", strerror(errno)); goto fail; } res = binder_parse(bs, reply, (uintptr_t) readbuf, bwr.read_consumed, 0); if (res == 0) return 0; if (res < 0) goto fail; } fail: memset(reply, 0, sizeof(*reply)); reply->flags |= BIO_F_IOERROR; return -1; } void binder_loop(struct binder_state *bs, binder_handler func) { int res; struct binder_write_read bwr; uint32_t readbuf[32]; bwr.write_size = 0; bwr.write_consumed = 0; bwr.write_buffer = 0; readbuf[0] = BC_ENTER_LOOPER; binder_write(bs, readbuf, sizeof(uint32_t)); for (;;) { bwr.read_size = sizeof(readbuf); bwr.read_consumed = 0; bwr.read_buffer = (uintptr_t) readbuf; res = ioctl(bs->fd, BINDER_WRITE_READ, &bwr); if (res < 0) { ALOGE("binder_loop: ioctl failed (%s)\n", strerror(errno)); break; } res = binder_parse(bs, 0, (uintptr_t) readbuf, bwr.read_consumed, func); if (res == 0) { ALOGE("binder_loop: unexpected reply?!\n"); break; } if (res < 0) { ALOGE("binder_loop: io error %d %s\n", res, strerror(errno)); break; } } } void bio_init_from_txn(struct binder_io *bio, struct binder_transaction_data *txn) { bio->data = bio->data0 = (char *)(intptr_t)txn->data.ptr.buffer; bio->offs = bio->offs0 = (binder_size_t *)(intptr_t)txn->data.ptr.offsets; bio->data_avail = txn->data_size; bio->offs_avail = txn->offsets_size / sizeof(size_t); bio->flags = BIO_F_SHARED; } void bio_init(struct binder_io *bio, void *data, size_t maxdata, size_t maxoffs) { size_t n = maxoffs * sizeof(size_t); if (n > maxdata) { bio->flags = BIO_F_OVERFLOW; bio->data_avail = 0; bio->offs_avail = 0; return; } bio->data = bio->data0 = (char *) data + n; bio->offs = bio->offs0 = data; bio->data_avail = maxdata - n; bio->offs_avail = maxoffs; bio->flags = 0; } static void *bio_alloc(struct binder_io *bio, size_t size) { size = (size + 3) & (~3); if (size > bio->data_avail) { bio->flags |= BIO_F_OVERFLOW; return NULL; } else { void *ptr = bio->data; bio->data += size; bio->data_avail -= size; return ptr; } } void binder_done(struct binder_state *bs, __unused struct binder_io *msg, struct binder_io *reply) { struct { uint32_t cmd; uintptr_t buffer; } __attribute__((packed)) data; if (reply->flags & BIO_F_SHARED) { data.cmd = BC_FREE_BUFFER; data.buffer = (uintptr_t) reply->data0; binder_write(bs, &data, sizeof(data)); reply->flags = 0; } } static struct flat_binder_object *bio_alloc_obj(struct binder_io *bio) { struct flat_binder_object *obj; obj = bio_alloc(bio, sizeof(*obj)); if (obj && bio->offs_avail) { bio->offs_avail--; *bio->offs++ = ((char*) obj) - ((char*) bio->data0); return obj; } bio->flags |= BIO_F_OVERFLOW; return NULL; } void bio_put_uint32(struct binder_io *bio, uint32_t n) { uint32_t *ptr = bio_alloc(bio, sizeof(n)); if (ptr) *ptr = n; } void bio_put_obj(struct binder_io *bio, void *ptr) { struct flat_binder_object *obj; obj = bio_alloc_obj(bio); if (!obj) return; obj->flags = 0x7f | FLAT_BINDER_FLAG_ACCEPTS_FDS; obj->type = BINDER_TYPE_BINDER; obj->binder = (uintptr_t)ptr; obj->cookie = 0; } void bio_put_ref(struct binder_io *bio, uint32_t handle) { struct flat_binder_object *obj; if (handle) obj = bio_alloc_obj(bio); else obj = bio_alloc(bio, sizeof(*obj)); if (!obj) return; obj->flags = 0x7f | FLAT_BINDER_FLAG_ACCEPTS_FDS; obj->type = BINDER_TYPE_HANDLE; obj->handle = handle; obj->cookie = 0; } void bio_put_string16(struct binder_io *bio, const uint16_t *str) { size_t len; uint16_t *ptr; if (!str) { bio_put_uint32(bio, 0xffffffff); return; } len = 0; while (str[len]) len++; if (len >= (MAX_BIO_SIZE / sizeof(uint16_t))) { bio_put_uint32(bio, 0xffffffff); return; } /* Note: The payload will carry 32bit size instead of size_t */ bio_put_uint32(bio, (uint32_t) len); len = (len + 1) * sizeof(uint16_t); ptr = bio_alloc(bio, len); if (ptr) memcpy(ptr, str, len); } void bio_put_string16_x(struct binder_io *bio, const char *_str) { unsigned char *str = (unsigned char*) _str; size_t len; uint16_t *ptr; if (!str) { bio_put_uint32(bio, 0xffffffff); return; } len = strlen(_str); if (len >= (MAX_BIO_SIZE / sizeof(uint16_t))) { bio_put_uint32(bio, 0xffffffff); return; } /* Note: The payload will carry 32bit size instead of size_t */ bio_put_uint32(bio, len); ptr = bio_alloc(bio, (len + 1) * sizeof(uint16_t)); if (!ptr) return; while (*str) *ptr++ = *str++; *ptr++ = 0; } static void *bio_get(struct binder_io *bio, size_t size) { size = (size + 3) & (~3); if (bio->data_avail < size){ bio->data_avail = 0; bio->flags |= BIO_F_OVERFLOW; return NULL; } else { void *ptr = bio->data; bio->data += size; bio->data_avail -= size; return ptr; } } uint32_t bio_get_uint32(struct binder_io *bio) { uint32_t *ptr = bio_get(bio, sizeof(*ptr)); return ptr ? *ptr : 0; } uint16_t *bio_get_string16(struct binder_io *bio, size_t *sz) { size_t len; /* Note: The payload will carry 32bit size instead of size_t */ len = (size_t) bio_get_uint32(bio); if (sz) *sz = len; return bio_get(bio, (len + 1) * sizeof(uint16_t)); } static struct flat_binder_object *_bio_get_obj(struct binder_io *bio) { size_t n; size_t off = bio->data - bio->data0; /* TODO: be smarter about this? */ for (n = 0; n < bio->offs_avail; n++) { if (bio->offs[n] == off) return bio_get(bio, sizeof(struct flat_binder_object)); } bio->data_avail = 0; bio->flags |= BIO_F_OVERFLOW; return NULL; } uint32_t bio_get_ref(struct binder_io *bio) { struct flat_binder_object *obj; obj = _bio_get_obj(bio); if (!obj) return 0; if (obj->type == BINDER_TYPE_HANDLE) return obj->handle; return 0; }